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llvm-project/llvm/lib/Target/PowerPC/PPCISelDAGToDAG.cpp

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More PPC32 -> PPC changes, as well as merging some classes that were redundant after the change. llvm-svn: 23759
2005-10-16 13:39:50 +08:00
//===-- PPCISelDAGToDAG.cpp - PPC --pattern matching inst selector --------===//
initial hack at a dag->dag instruction selector. This is obviously woefully incomplete, but it is a start. It handles basic argument/retval stuff, immediates, add and sub. llvm-svn: 22836
2005-08-18 03:33:03 +08:00
//
// The LLVM Compiler Infrastructure
//
Remove attribution from file headers, per discussion on llvmdev. llvm-svn: 45418
2007-12-30 04:36:04 +08:00
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
initial hack at a dag->dag instruction selector. This is obviously woefully incomplete, but it is a start. It handles basic argument/retval stuff, immediates, add and sub. llvm-svn: 22836
2005-08-18 03:33:03 +08:00
//
//===----------------------------------------------------------------------===//
//
More PPC32 -> PPC changes, as well as merging some classes that were redundant after the change. llvm-svn: 23759
2005-10-16 13:39:50 +08:00
// This file defines a pattern matching instruction selector for PowerPC,
initial hack at a dag->dag instruction selector. This is obviously woefully incomplete, but it is a start. It handles basic argument/retval stuff, immediates, add and sub. llvm-svn: 22836
2005-08-18 03:33:03 +08:00
// converting from a legalized dag to a PPC dag.
//
//===----------------------------------------------------------------------===//
Rename PowerPC*.h to PPC*.h llvm-svn: 23743
2005-10-15 07:51:18 +08:00
#include "PPC.h"
Rename TargetAsmParser to MCTargetAsmParser and TargetAsmLexer to MCTargetAsmLexer; rename createAsmLexer to createMCAsmLexer and createAsmParser to createMCAsmParser. llvm-svn: 136027
2011-07-26 08:24:13 +08:00
#include "MCTargetDesc/PPCPredicates.h"
[PowerPC] 32-bit ELF PIC support This adds initial support for PPC32 ELF PIC (Position Independent Code; the -fPIC variety), thus rectifying a long-standing deficiency in the PowerPC backend. Patch by Justin Hibbits! llvm-svn: 213427
2014-07-19 07:29:49 +08:00
#include "PPCMachineFunctionInfo.h"
Use the new script to sort the includes of every file under lib. Sooooo many of these had incorrect or strange main module includes. I have manually inspected all of these, and fixed the main module include to be the nearest plausible thing I could find. If you own or care about any of these source files, I encourage you to take some time and check that these edits were sensible. I can't have broken anything (I strictly added headers, and reordered them, never removed), but they may not be the headers you'd really like to identify as containing the API being implemented. Many forward declarations and missing includes were added to a header files to allow them to parse cleanly when included first. The main module rule does in fact have its merits. =] llvm-svn: 169131
2012-12-04 00:50:05 +08:00
#include "PPCTargetMachine.h"
add support for global address, including PIC support. This REALLY should be lowered by the legalizer! llvm-svn: 22941
2005-08-20 06:38:53 +08:00
#include "llvm/CodeGen/MachineFunction.h"
Use the new script to sort the includes of every file under lib. Sooooo many of these had incorrect or strange main module includes. I have manually inspected all of these, and fixed the main module include to be the nearest plausible thing I could find. If you own or care about any of these source files, I encourage you to take some time and check that these edits were sensible. I can't have broken anything (I strictly added headers, and reordered them, never removed), but they may not be the headers you'd really like to identify as containing the API being implemented. Many forward declarations and missing includes were added to a header files to allow them to parse cleanly when included first. The main module rule does in fact have its merits. =] llvm-svn: 169131
2012-12-04 00:50:05 +08:00
#include "llvm/CodeGen/MachineInstrBuilder.h"
Rename SSARegMap -> MachineRegisterInfo in keeping with the idea that "machine" classes are used to represent the current state of the code being compiled. Given this expanded name, we can start moving other stuff into it. For now, move the UsedPhysRegs and LiveIn/LoveOuts vectors from MachineFunction into it. Update all the clients to match. This also reduces some needless #includes, such as MachineModuleInfo from MachineFunction. llvm-svn: 45467
2007-12-31 12:13:23 +08:00
#include "llvm/CodeGen/MachineRegisterInfo.h"
initial hack at a dag->dag instruction selector. This is obviously woefully incomplete, but it is a start. It handles basic argument/retval stuff, immediates, add and sub. llvm-svn: 22836
2005-08-18 03:33:03 +08:00
#include "llvm/CodeGen/SelectionDAG.h"
#include "llvm/CodeGen/SelectionDAGISel.h"
Move all of the header files which are involved in modelling the LLVM IR into their new header subdirectory: include/llvm/IR. This matches the directory structure of lib, and begins to correct a long standing point of file layout clutter in LLVM. There are still more header files to move here, but I wanted to handle them in separate commits to make tracking what files make sense at each layer easier. The only really questionable files here are the target intrinsic tablegen files. But that's a battle I'd rather not fight today. I've updated both CMake and Makefile build systems (I think, and my tests think, but I may have missed something). I've also re-sorted the includes throughout the project. I'll be committing updates to Clang, DragonEgg, and Polly momentarily. llvm-svn: 171366
2013-01-02 19:36:10 +08:00
#include "llvm/IR/Constants.h"
#include "llvm/IR/Function.h"
Sort all of the includes. Several files got checked in with mis-sorted includes. llvm-svn: 172891
2013-01-19 16:03:47 +08:00
#include "llvm/IR/GlobalAlias.h"
Move all of the header files which are involved in modelling the LLVM IR into their new header subdirectory: include/llvm/IR. This matches the directory structure of lib, and begins to correct a long standing point of file layout clutter in LLVM. There are still more header files to move here, but I wanted to handle them in separate commits to make tracking what files make sense at each layer easier. The only really questionable files here are the target intrinsic tablegen files. But that's a battle I'd rather not fight today. I've updated both CMake and Makefile build systems (I think, and my tests think, but I may have missed something). I've also re-sorted the includes throughout the project. I'll be committing updates to Clang, DragonEgg, and Polly momentarily. llvm-svn: 171366
2013-01-02 19:36:10 +08:00
#include "llvm/IR/GlobalValue.h"
#include "llvm/IR/GlobalVariable.h"
#include "llvm/IR/Intrinsics.h"
Add support for small-model PIC for PowerPC. Summary: Large-model was added first. With the addition of support for multiple PIC models in LLVM, now add small-model PIC for 32-bit PowerPC, SysV4 ABI. This generates more optimal code, for shared libraries with less than about 16380 data objects. Test Plan: Test cases added or updated Reviewers: joerg, hfinkel Reviewed By: hfinkel Subscribers: jholewinski, mcrosier, emaste, llvm-commits Differential Revision: http://reviews.llvm.org/D5399 llvm-svn: 221791
2014-11-12 23:16:30 +08:00
#include "llvm/IR/Module.h"
Add CR-bit tracking to the PowerPC backend for i1 values This change enables tracking i1 values in the PowerPC backend using the condition register bits. These bits can be treated on PowerPC as separate registers; individual bit operations (and, or, xor, etc.) are supported. Tracking booleans in CR bits has several advantages: - Reduction in register pressure (because we no longer need GPRs to store boolean values). - Logical operations on booleans can be handled more efficiently; we used to have to move all results from comparisons into GPRs, perform promoted logical operations in GPRs, and then move the result back into condition register bits to be used by conditional branches. This can be very inefficient, because the throughput of these CR <-> GPR moves have high latency and low throughput (especially when other associated instructions are accounted for). - On the POWER7 and similar cores, we can increase total throughput by using the CR bits. CR bit operations have a dedicated functional unit. Most of this is more-or-less mechanical: Adjustments were needed in the calling-convention code, support was added for spilling/restoring individual condition-register bits, and conditional branch instruction definitions taking specific CR bits were added (plus patterns and code for generating bit-level operations). This is enabled by default when running at -O2 and higher. For -O0 and -O1, where the ability to debug is more important, this feature is disabled by default. Individual CR bits do not have assigned DWARF register numbers, and storing values in CR bits makes them invisible to the debugger. It is critical, however, that we don't move i1 values that have been promoted to larger values (such as those passed as function arguments) into bit registers only to quickly turn around and move the values back into GPRs (such as happens when values are returned by functions). A pair of target-specific DAG combines are added to remove the trunc/extends in: trunc(binary-ops(binary-ops(zext(x), zext(y)), ...) and: zext(binary-ops(binary-ops(trunc(x), trunc(y)), ...) In short, we only want to use CR bits where some of the i1 values come from comparisons or are used by conditional branches or selects. To put it another way, if we can do the entire i1 computation in GPRs, then we probably should (on the POWER7, the GPR-operation throughput is higher, and for all cores, the CR <-> GPR moves are expensive). POWER7 test-suite performance results (from 10 runs in each configuration): SingleSource/Benchmarks/Misc/mandel-2: 35% speedup MultiSource/Benchmarks/Prolangs-C++/city/city: 21% speedup MultiSource/Benchmarks/MiBench/automotive-susan: 23% speedup SingleSource/Benchmarks/CoyoteBench/huffbench: 13% speedup SingleSource/Benchmarks/Misc-C++/Large/sphereflake: 13% speedup SingleSource/Benchmarks/Misc-C++/mandel-text: 10% speedup SingleSource/Benchmarks/Misc-C++-EH/spirit: 10% slowdown MultiSource/Applications/lemon/lemon: 8% slowdown llvm-svn: 202451
2014-02-28 08:27:01 +08:00
#include "llvm/Support/CommandLine.h"
initial hack at a dag->dag instruction selector. This is obviously woefully incomplete, but it is a start. It handles basic argument/retval stuff, immediates, add and sub. llvm-svn: 22836
2005-08-18 03:33:03 +08:00
#include "llvm/Support/Debug.h"
Implement changes from Chris's feedback. Finish converting lib/Target. llvm-svn: 75043
2009-07-09 04:53:28 +08:00
#include "llvm/Support/ErrorHandling.h"
Use the new script to sort the includes of every file under lib. Sooooo many of these had incorrect or strange main module includes. I have manually inspected all of these, and fixed the main module include to be the nearest plausible thing I could find. If you own or care about any of these source files, I encourage you to take some time and check that these edits were sensible. I can't have broken anything (I strictly added headers, and reordered them, never removed), but they may not be the headers you'd really like to identify as containing the API being implemented. Many forward declarations and missing includes were added to a header files to allow them to parse cleanly when included first. The main module rule does in fact have its merits. =] llvm-svn: 169131
2012-12-04 00:50:05 +08:00
#include "llvm/Support/MathExtras.h"
Implement changes from Chris's feedback. Finish converting lib/Target. llvm-svn: 75043
2009-07-09 04:53:28 +08:00
#include "llvm/Support/raw_ostream.h"
Use the new script to sort the includes of every file under lib. Sooooo many of these had incorrect or strange main module includes. I have manually inspected all of these, and fixed the main module include to be the nearest plausible thing I could find. If you own or care about any of these source files, I encourage you to take some time and check that these edits were sensible. I can't have broken anything (I strictly added headers, and reordered them, never removed), but they may not be the headers you'd really like to identify as containing the API being implemented. Many forward declarations and missing includes were added to a header files to allow them to parse cleanly when included first. The main module rule does in fact have its merits. =] llvm-svn: 169131
2012-12-04 00:50:05 +08:00
#include "llvm/Target/TargetOptions.h"
initial hack at a dag->dag instruction selector. This is obviously woefully incomplete, but it is a start. It handles basic argument/retval stuff, immediates, add and sub. llvm-svn: 22836
2005-08-18 03:33:03 +08:00
using namespace llvm;
[Modules] Fix potential ODR violations by sinking the DEBUG_TYPE definition below all of the header #include lines, lib/Target/... edition. llvm-svn: 206842
2014-04-22 10:41:26 +08:00
#define DEBUG_TYPE "ppc-codegen"
Add CR-bit tracking to the PowerPC backend for i1 values This change enables tracking i1 values in the PowerPC backend using the condition register bits. These bits can be treated on PowerPC as separate registers; individual bit operations (and, or, xor, etc.) are supported. Tracking booleans in CR bits has several advantages: - Reduction in register pressure (because we no longer need GPRs to store boolean values). - Logical operations on booleans can be handled more efficiently; we used to have to move all results from comparisons into GPRs, perform promoted logical operations in GPRs, and then move the result back into condition register bits to be used by conditional branches. This can be very inefficient, because the throughput of these CR <-> GPR moves have high latency and low throughput (especially when other associated instructions are accounted for). - On the POWER7 and similar cores, we can increase total throughput by using the CR bits. CR bit operations have a dedicated functional unit. Most of this is more-or-less mechanical: Adjustments were needed in the calling-convention code, support was added for spilling/restoring individual condition-register bits, and conditional branch instruction definitions taking specific CR bits were added (plus patterns and code for generating bit-level operations). This is enabled by default when running at -O2 and higher. For -O0 and -O1, where the ability to debug is more important, this feature is disabled by default. Individual CR bits do not have assigned DWARF register numbers, and storing values in CR bits makes them invisible to the debugger. It is critical, however, that we don't move i1 values that have been promoted to larger values (such as those passed as function arguments) into bit registers only to quickly turn around and move the values back into GPRs (such as happens when values are returned by functions). A pair of target-specific DAG combines are added to remove the trunc/extends in: trunc(binary-ops(binary-ops(zext(x), zext(y)), ...) and: zext(binary-ops(binary-ops(trunc(x), trunc(y)), ...) In short, we only want to use CR bits where some of the i1 values come from comparisons or are used by conditional branches or selects. To put it another way, if we can do the entire i1 computation in GPRs, then we probably should (on the POWER7, the GPR-operation throughput is higher, and for all cores, the CR <-> GPR moves are expensive). POWER7 test-suite performance results (from 10 runs in each configuration): SingleSource/Benchmarks/Misc/mandel-2: 35% speedup MultiSource/Benchmarks/Prolangs-C++/city/city: 21% speedup MultiSource/Benchmarks/MiBench/automotive-susan: 23% speedup SingleSource/Benchmarks/CoyoteBench/huffbench: 13% speedup SingleSource/Benchmarks/Misc-C++/Large/sphereflake: 13% speedup SingleSource/Benchmarks/Misc-C++/mandel-text: 10% speedup SingleSource/Benchmarks/Misc-C++-EH/spirit: 10% slowdown MultiSource/Applications/lemon/lemon: 8% slowdown llvm-svn: 202451
2014-02-28 08:27:01 +08:00
// FIXME: Remove this once the bug has been fixed!
cl::opt<bool> ANDIGlueBug("expose-ppc-andi-glue-bug",
cl::desc("expose the ANDI glue bug on PPC"), cl::Hidden);
Make helper functions/classes/globals static. NFC. llvm-svn: 228410
2015-02-07 01:51:54 +08:00
static cl::opt<bool>
UseBitPermRewriter("ppc-use-bit-perm-rewriter", cl::init(true),
cl::desc("use aggressive ppc isel for bit permutations"),
cl::Hidden);
static cl::opt<bool> BPermRewriterNoMasking(
"ppc-bit-perm-rewriter-stress-rotates",
cl::desc("stress rotate selection in aggressive ppc isel for "
"bit permutations"),
cl::Hidden);
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
Add registration for PPC-specific passes to allow the IR to be dumped via -print-after-all. llvm-svn: 175058
2013-02-14 01:40:07 +08:00
namespace llvm {
void initializePPCDAGToDAGISelPass(PassRegistry&);
}
initial hack at a dag->dag instruction selector. This is obviously woefully incomplete, but it is a start. It handles basic argument/retval stuff, immediates, add and sub. llvm-svn: 22836
2005-08-18 03:33:03 +08:00
namespace {
//===--------------------------------------------------------------------===//
First bits of 64 bit PowerPC stuff, currently disabled. A lot of this is purely mechanical. llvm-svn: 23778
2005-10-18 08:28:58 +08:00
/// PPCDAGToDAGISel - PPC specific code to select PPC machine
initial hack at a dag->dag instruction selector. This is obviously woefully incomplete, but it is a start. It handles basic argument/retval stuff, immediates, add and sub. llvm-svn: 22836
2005-08-18 03:33:03 +08:00
/// instructions for SelectionDAG operations.
///
Remove VISIBILITY_HIDDEN from class/struct found inside anonymous namespaces. Chris claims we should never have visibility_hidden inside any .cpp file but that's still not true even after this commit. llvm-svn: 85042
2009-10-25 14:33:48 +08:00
class PPCDAGToDAGISel : public SelectionDAGISel {
Use const qualifiers with TargetLowering. This eliminates several const_casts, and it reinforces the design of the Target classes being immutable. SelectionDAGISel::IsLegalToFold is now a static member function, because PIC16 uses it in an unconventional way. There is more room for API cleanup here. And PIC16's AsmPrinter no longer uses TargetLowering. llvm-svn: 101635
2010-04-17 23:26:15 +08:00
const PPCTargetMachine &TM;
Reset the subtarget for DAGToDAG on every iteration of runOnMachineFunction. This required updating the generated functions and TD file accordingly to be pointers rather than const references. llvm-svn: 209375
2014-05-22 09:07:24 +08:00
const PPCSubtarget *PPCSubTarget;
Use the cached subtargets and remove calls to getSubtarget/getSubtargetImpl without a Function argument. llvm-svn: 227622
2015-01-31 06:02:31 +08:00
const PPCTargetLowering *PPCLowering;
add support for global address, including PIC support. This REALLY should be lowered by the legalizer! llvm-svn: 22941
2005-08-20 06:38:53 +08:00
unsigned GlobalBaseReg;
initial hack at a dag->dag instruction selector. This is obviously woefully incomplete, but it is a start. It handles basic argument/retval stuff, immediates, add and sub. llvm-svn: 22836
2005-08-18 03:33:03 +08:00
public:
Add explicit keywords. llvm-svn: 53179
2008-07-08 02:00:37 +08:00
explicit PPCDAGToDAGISel(PPCTargetMachine &tm)
Use the cached subtargets and remove calls to getSubtarget/getSubtargetImpl without a Function argument. llvm-svn: 227622
2015-01-31 06:02:31 +08:00
: SelectionDAGISel(tm), TM(tm) {
Add registration for PPC-specific passes to allow the IR to be dumped via -print-after-all. llvm-svn: 175058
2013-02-14 01:40:07 +08:00
initializePPCDAGToDAGISelPass(*PassRegistry::getPassRegistry());
}
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
[C++11] Add 'override' keywords and remove 'virtual'. Additionally add 'final' and leave 'virtual' on some methods that are marked virtual without overriding anything and have no obvious overrides themselves. PowerPC edition llvm-svn: 207504
2014-04-29 15:57:37 +08:00
bool runOnMachineFunction(MachineFunction &MF) override {
add support for global address, including PIC support. This REALLY should be lowered by the legalizer! llvm-svn: 22941
2005-08-20 06:38:53 +08:00
// Make sure we re-emit a set of the global base reg if necessary
GlobalBaseReg = 0;
Use the cached subtargets and remove calls to getSubtarget/getSubtargetImpl without a Function argument. llvm-svn: 227622
2015-01-31 06:02:31 +08:00
PPCSubTarget = &MF.getSubtarget<PPCSubtarget>();
PPCLowering = PPCSubTarget->getTargetLowering();
Reapply r77654 with a fix: MachineFunctionPass's getAnalysisUsage shouldn't do AU.setPreservesCFG(), because even though CodeGen passes don't modify the LLVM IR CFG, they may modify the MachineFunction CFG, and passes like MachineLoop are registered with isCFGOnly set to true. llvm-svn: 77691
2009-08-01 02:16:33 +08:00
SelectionDAGISel::runOnMachineFunction(MF);
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
Reset the subtarget for DAGToDAG on every iteration of runOnMachineFunction. This required updating the generated functions and TD file accordingly to be pointers rather than const references. llvm-svn: 209375
2014-05-22 09:07:24 +08:00
if (!PPCSubTarget->isSVR4ABI())
The PowerPC VRSAVE register has been somewhat of an odd beast since the Altivec extensions were introduced. Its use is optional, and allows the compiler to communicate to the operating system which vector registers should be saved and restored during a context switch. In practice, this information is ignored by the various operating systems using the SVR4 ABI; the kernel saves and restores the entire register state. Setting the VRSAVE register is no longer performed by the AIX XL compilers, the IBM i compilers, or by GCC on Power Linux systems. It seems best to avoid this logic within LLVM as well. This patch avoids generating code to update and restore VRSAVE for the PowerPC SVR4 ABIs (32- and 64-bit). The code remains in place for the Darwin ABI. llvm-svn: 165656
2012-10-11 04:54:15 +08:00
InsertVRSaveCode(MF);
Save/restore VRSAVE once per function, not once per block. llvm-svn: 26793
2006-03-17 02:25:23 +08:00
return true;
add support for global address, including PIC support. This REALLY should be lowered by the legalizer! llvm-svn: 22941
2005-08-20 06:38:53 +08:00
}
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
[PowerPC] Add support for the CMPB instruction Newer POWER cores, and the A2, support the cmpb instruction. This instruction compares its operands, treating each of the 8 bytes in the GPRs separately, returning a 'mask' result of 0 (for false) or -1 (for true) in each byte. Code generation support is added, in the form of a PPCISelDAGToDAG DAG-preprocessing routine, that recognizes patterns close to what the instruction computes (either exactly, or related by a constant masking operation), and generates the cmpb instruction (along with any necessary constant masking operation). This can be expanded if use cases arise. llvm-svn: 225106
2015-01-03 09:16:37 +08:00
void PreprocessISelDAG() override;
[C++11] Add 'override' keywords and remove 'virtual'. Additionally add 'final' and leave 'virtual' on some methods that are marked virtual without overriding anything and have no obvious overrides themselves. PowerPC edition llvm-svn: 207504
2014-04-29 15:57:37 +08:00
void PostprocessISelDAG() override;
PPCDAGToDAGISel::PostprocessISelDAG() This patch implements the PPCDAGToDAGISel::PostprocessISelDAG virtual method to perform post-selection peephole optimizations on the DAG representation. One optimization is implemented here: folds to clean up complex addressing expressions for thread-local storage and medium code model. It will also be useful for large code model sequences when those are added later. I originally thought about doing this on the MI representation prior to register assignment, but it's difficult to do effective global dead code elimination at that point. DCE is trivial on the DAG representation. A typical example of a candidate code sequence in assembly: addis 3, 2, globalvar@toc@ha addi 3, 3, globalvar@toc@l lwz 5, 0(3) When the final instruction is a load or store with an immediate offset of zero, the offset from the add-immediate can replace the zero, provided the relocation information is carried along: addis 3, 2, globalvar@toc@ha lwz 5, globalvar@toc@l(3) Since the addi can in general have multiple uses, we need to only delete the instruction when the last use is removed. llvm-svn: 175697
2013-02-21 08:38:25 +08:00
initial hack at a dag->dag instruction selector. This is obviously woefully incomplete, but it is a start. It handles basic argument/retval stuff, immediates, add and sub. llvm-svn: 22836
2005-08-18 03:33:03 +08:00
/// getI32Imm - Return a target constant with the specified value, of type
/// i32.
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
inline SDValue getI32Imm(unsigned Imm, SDLoc dl) {
return CurDAG->getTargetConstant(Imm, dl, MVT::i32);
initial hack at a dag->dag instruction selector. This is obviously woefully incomplete, but it is a start. It handles basic argument/retval stuff, immediates, add and sub. llvm-svn: 22836
2005-08-18 03:33:03 +08:00
}
add support for global address, including PIC support. This REALLY should be lowered by the legalizer! llvm-svn: 22941
2005-08-20 06:38:53 +08:00
Implement a bunch of 64-bit cleanliness work. With this, treeadd builds (but doesn't work right). llvm-svn: 28921
2006-06-27 08:04:13 +08:00
/// getI64Imm - Return a target constant with the specified value, of type
/// i64.
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
inline SDValue getI64Imm(uint64_t Imm, SDLoc dl) {
return CurDAG->getTargetConstant(Imm, dl, MVT::i64);
Implement a bunch of 64-bit cleanliness work. With this, treeadd builds (but doesn't work right). llvm-svn: 28921
2006-06-27 08:04:13 +08:00
}
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
Implement a bunch of 64-bit cleanliness work. With this, treeadd builds (but doesn't work right). llvm-svn: 28921
2006-06-27 08:04:13 +08:00
/// getSmallIPtrImm - Return a target constant of pointer type.
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
inline SDValue getSmallIPtrImm(unsigned Imm, SDLoc dl) {
Make TargetLowering::getPointerTy() taking DataLayout as an argument Summary: This change is part of a series of commits dedicated to have a single DataLayout during compilation by using always the one owned by the module. Reviewers: echristo Subscribers: jholewinski, ted, yaron.keren, rafael, llvm-commits Differential Revision: http://reviews.llvm.org/D11028 From: Mehdi Amini <mehdi.amini@apple.com> llvm-svn: 241775
2015-07-09 10:09:04 +08:00
return CurDAG->getTargetConstant(
Imm, dl, PPCLowering->getPointerTy(CurDAG->getDataLayout()));
Implement a bunch of 64-bit cleanliness work. With this, treeadd builds (but doesn't work right). llvm-svn: 28921
2006-06-27 08:04:13 +08:00
}
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
Fold AND and ROTL more often llvm-svn: 30577
2006-09-22 13:01:56 +08:00
/// isRotateAndMask - Returns true if Mask and Shift can be folded into a
/// rotate and mask opcode and mask operation.
Make capitalization of names starting "is" more consistent. No functional change. llvm-svn: 89724
2009-11-24 09:09:07 +08:00
static bool isRotateAndMask(SDNode *N, unsigned Mask, bool isShiftMask,
Fold AND and ROTL more often llvm-svn: 30577
2006-09-22 13:01:56 +08:00
unsigned &SH, unsigned &MB, unsigned &ME);
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
add support for global address, including PIC support. This REALLY should be lowered by the legalizer! llvm-svn: 22941
2005-08-20 06:38:53 +08:00
/// getGlobalBaseReg - insert code into the entry mbb to materialize the PIC
/// base register. Return the virtual register that holds this value.
Select() no longer require Result operand by reference. llvm-svn: 29898
2006-08-26 13:34:46 +08:00
SDNode *getGlobalBaseReg();
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
[PowerPC] Better lowering for add/or of a FrameIndex If we have an add (or an or that is really an add), where one operand is a FrameIndex and the other operand is a small constant, we can combine the lowering of the FrameIndex (which is lowered as an add of the FI and a zero offset) with the constant operand. Amusingly, this is an old potential improvement entry from lib/Target/PowerPC/README.txt which had never been resolved. In short, we used to lower: %X = alloca { i32, i32 } %Y = getelementptr {i32,i32}* %X, i32 0, i32 1 ret i32* %Y as: addi 3, 1, -8 ori 3, 3, 4 blr and now we produce: addi 3, 1, -4 blr which is much more sensible. llvm-svn: 224071
2014-12-12 06:51:06 +08:00
SDNode *getFrameIndex(SDNode *SN, SDNode *N, unsigned Offset = 0);
initial hack at a dag->dag instruction selector. This is obviously woefully incomplete, but it is a start. It handles basic argument/retval stuff, immediates, add and sub. llvm-svn: 22836
2005-08-18 03:33:03 +08:00
// Select - Convert the specified operand from a target-independent to a
// target-specific node if it hasn't already been changed.
[C++11] Add 'override' keywords and remove 'virtual'. Additionally add 'final' and leave 'virtual' on some methods that are marked virtual without overriding anything and have no obvious overrides themselves. PowerPC edition llvm-svn: 207504
2014-04-29 15:57:37 +08:00
SDNode *Select(SDNode *N) override;
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
ISD::OR, and it's accompanying SelectBitfieldInsert llvm-svn: 22889
2005-08-19 08:38:14 +08:00
SDNode *SelectBitfieldInsert(SDNode *N);
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
SDNode *SelectBitPermutation(SDNode *N);
ISD::OR, and it's accompanying SelectBitfieldInsert llvm-svn: 22889
2005-08-19 08:38:14 +08:00
Implement selection for branches. llvm-svn: 22951
2005-08-22 02:50:37 +08:00
/// SelectCC - Select a comparison of the specified values with the
/// specified condition code, returning the CR# of the expression.
Track IR ordering of SelectionDAG nodes 2/4. Change SelectionDAG::getXXXNode() interfaces as well as call sites of these functions to pass in SDLoc instead of DebugLoc. llvm-svn: 182703
2013-05-25 10:42:55 +08:00
SDValue SelectCC(SDValue LHS, SDValue RHS, ISD::CondCode CC, SDLoc dl);
Implement selection for branches. llvm-svn: 22951
2005-08-22 02:50:37 +08:00
Convert load/store over to being pattern matched llvm-svn: 24871
2005-12-20 07:25:09 +08:00
/// SelectAddrImm - Returns true if the address N can be represented by
/// a base register plus a signed 16-bit displacement [r+imm].
fix a long standing wart: all the ComplexPattern's were being passed the root of the match, even though only a few patterns actually needed this (one in X86, several in ARM [which should be refactored anyway], and some in CellSPU that I don't feel like detangling). Instead of requiring all ComplexPatterns to take the dead root, have targets opt into getting the root by putting SDNPWantRoot on the ComplexPattern. llvm-svn: 114471
2010-09-22 04:31:19 +08:00
bool SelectAddrImm(SDValue N, SDValue &Disp,
Rename SDOperand to SDValue. llvm-svn: 54128
2008-07-28 05:46:04 +08:00
SDValue &Base) {
Reset the subtarget for DAGToDAG on every iteration of runOnMachineFunction. This required updating the generated functions and TD file accordingly to be pointers rather than const references. llvm-svn: 209375
2014-05-22 09:07:24 +08:00
return PPCLowering->SelectAddressRegImm(N, Disp, Base, *CurDAG, false);
Refactor all the addressing mode selection stuff into the isel lowering class, where it can be used for preinc formation. llvm-svn: 31536
2006-11-08 10:15:41 +08:00
}
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
add patterns for ppc32 preinc stores. ppc64 next. llvm-svn: 31775
2006-11-16 08:41:37 +08:00
/// SelectAddrImmOffs - Return true if the operand is valid for a preinc
Tighten iaddroff ComplexPattern. The iaddroff ComplexPattern is supposed to recognize displacement expressions that have been processed by a SelectAddressRegImm, which means it needs to accept TargetConstant and TargetGlobalAddress nodes. Currently, it erroneously also accepts some other nodes, in particular Constant and PPCISD::Lo. While this problem is currently latent, it would cause wrong-code bugs with a follow-on patch I'm about to commit, so this patch tightens the ComplexPattern. The equivalent change is made in PPCDAGToDAGISel::Select, where pre-inc load patterns are handled (as opposed to store patterns, the loads are handled in C++ code without making use of the .td ComplexPattern). llvm-svn: 177732
2013-03-22 22:58:17 +08:00
/// immediate field. Note that the operand at this point is already the
/// result of a prior SelectAddressRegImm call.
fix a long standing wart: all the ComplexPattern's were being passed the root of the match, even though only a few patterns actually needed this (one in X86, several in ARM [which should be refactored anyway], and some in CellSPU that I don't feel like detangling). Instead of requiring all ComplexPatterns to take the dead root, have targets opt into getting the root by putting SDNPWantRoot on the ComplexPattern. llvm-svn: 114471
2010-09-22 04:31:19 +08:00
bool SelectAddrImmOffs(SDValue N, SDValue &Out) const {
Tighten iaddroff ComplexPattern. The iaddroff ComplexPattern is supposed to recognize displacement expressions that have been processed by a SelectAddressRegImm, which means it needs to accept TargetConstant and TargetGlobalAddress nodes. Currently, it erroneously also accepts some other nodes, in particular Constant and PPCISD::Lo. While this problem is currently latent, it would cause wrong-code bugs with a follow-on patch I'm about to commit, so this patch tightens the ComplexPattern. The equivalent change is made in PPCDAGToDAGISel::Select, where pre-inc load patterns are handled (as opposed to store patterns, the loads are handled in C++ code without making use of the .td ComplexPattern). llvm-svn: 177732
2013-03-22 22:58:17 +08:00
if (N.getOpcode() == ISD::TargetConstant ||
Treat TargetGlobalAddress as a constant for the purpose of matching pre-inc stores on PPC. Thanks to Tobias von Koch for pointing out this problem. llvm-svn: 158932
2012-06-22 04:10:48 +08:00
N.getOpcode() == ISD::TargetGlobalAddress) {
Add support for generating reg+reg preinc stores on PPC. PPC will now generate STWUX and friends. llvm-svn: 158698
2012-06-19 10:34:32 +08:00
Out = N;
return true;
}
return false;
}
Convert load/store over to being pattern matched llvm-svn: 24871
2005-12-20 07:25:09 +08:00
/// SelectAddrIdx - Given the specified addressed, check to see if it can be
/// represented as an indexed [r+r] operation. Returns false if it can
/// be represented by [r+imm], which are preferred.
fix a long standing wart: all the ComplexPattern's were being passed the root of the match, even though only a few patterns actually needed this (one in X86, several in ARM [which should be refactored anyway], and some in CellSPU that I don't feel like detangling). Instead of requiring all ComplexPatterns to take the dead root, have targets opt into getting the root by putting SDNPWantRoot on the ComplexPattern. llvm-svn: 114471
2010-09-22 04:31:19 +08:00
bool SelectAddrIdx(SDValue N, SDValue &Base, SDValue &Index) {
Reset the subtarget for DAGToDAG on every iteration of runOnMachineFunction. This required updating the generated functions and TD file accordingly to be pointers rather than const references. llvm-svn: 209375
2014-05-22 09:07:24 +08:00
return PPCLowering->SelectAddressRegReg(N, Base, Index, *CurDAG);
Refactor all the addressing mode selection stuff into the isel lowering class, where it can be used for preinc formation. llvm-svn: 31536
2006-11-08 10:15:41 +08:00
}
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
Convert load/store over to being pattern matched llvm-svn: 24871
2005-12-20 07:25:09 +08:00
/// SelectAddrIdxOnly - Given the specified addressed, force it to be
/// represented as an indexed [r+r] operation.
fix a long standing wart: all the ComplexPattern's were being passed the root of the match, even though only a few patterns actually needed this (one in X86, several in ARM [which should be refactored anyway], and some in CellSPU that I don't feel like detangling). Instead of requiring all ComplexPatterns to take the dead root, have targets opt into getting the root by putting SDNPWantRoot on the ComplexPattern. llvm-svn: 114471
2010-09-22 04:31:19 +08:00
bool SelectAddrIdxOnly(SDValue N, SDValue &Base, SDValue &Index) {
Reset the subtarget for DAGToDAG on every iteration of runOnMachineFunction. This required updating the generated functions and TD file accordingly to be pointers rather than const references. llvm-svn: 209375
2014-05-22 09:07:24 +08:00
return PPCLowering->SelectAddressRegRegOnly(N, Base, Index, *CurDAG);
Refactor all the addressing mode selection stuff into the isel lowering class, where it can be used for preinc formation. llvm-svn: 31536
2006-11-08 10:15:41 +08:00
}
Implement most of load support. There is still a bug though. llvm-svn: 22959
2005-08-22 06:31:09 +08:00
[PowerPC] Use true offset value in "memrix" machine operands This is the second part of the change to always return "true" offset values from getPreIndexedAddressParts, tackling the case of "memrix" type operands. This is about instructions like LD/STD that only have a 14-bit field to encode immediate offsets, which are implicitly extended by two zero bits by the machine, so that in effect we can access 16-bit offsets as long as they are a multiple of 4. The PowerPC back end currently handles such instructions by carrying the 14-bit value (as it will get encoded into the actual machine instructions) in the machine operand fields for such instructions. This means that those values are in fact not the true offset, but rather the offset divided by 4 (and then truncated to an unsigned 14-bit value). Like in the case fixed in r182012, this makes common code operations on such offset values not work as expected. Furthermore, there doesn't really appear to be any strong reason why we should encode machine operands this way. This patch therefore changes the encoding of "memrix" type machine operands to simply contain the "true" offset value as a signed immediate value, while enforcing the rules that it must fit in a 16-bit signed value and must also be a multiple of 4. This change must be made simultaneously in all places that access machine operands of this type. However, just about all those changes make the code simpler; in many cases we can now just share the same code for memri and memrix operands. llvm-svn: 182032
2013-05-17 01:58:02 +08:00
/// SelectAddrImmX4 - Returns true if the address N can be represented by
/// a base register plus a signed 16-bit displacement that is a multiple of 4.
/// Suitable for use by STD and friends.
bool SelectAddrImmX4(SDValue N, SDValue &Disp, SDValue &Base) {
Reset the subtarget for DAGToDAG on every iteration of runOnMachineFunction. This required updating the generated functions and TD file accordingly to be pointers rather than const references. llvm-svn: 209375
2014-05-22 09:07:24 +08:00
return PPCLowering->SelectAddressRegImm(N, Disp, Base, *CurDAG, true);
Refactor all the addressing mode selection stuff into the isel lowering class, where it can be used for preinc formation. llvm-svn: 31536
2006-11-08 10:15:41 +08:00
}
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
Implement builtin_{setjmp/longjmp} on PPC This implements SJLJ lowering on PPC, making the Clang functions __builtin_{setjmp/longjmp} functional on PPC platforms. The implementation strategy is similar to that on X86, with the exception that a branch-and-link variant is used to get the right jump address. Credit goes to Bill Schmidt for suggesting the use of the unconditional bcl form (instead of the regular bl instruction) to limit return-address-cache pollution. Benchmarking the speed at -O3 of: static jmp_buf env_sigill; void foo() { __builtin_longjmp(env_sigill,1); } main() { ... for (int i = 0; i < c; ++i) { if (__builtin_setjmp(env_sigill)) { goto done; } else { foo(); } done:; } ... } vs. the same code using the libc setjmp/longjmp functions on a P7 shows that this builtin implementation is ~4x faster with Altivec enabled and ~7.25x faster with Altivec disabled. This comparison is somewhat unfair because the libc version must also save/restore the VSX registers which we don't yet support. llvm-svn: 177666
2013-03-22 05:37:52 +08:00
// Select an address into a single register.
bool SelectAddr(SDValue N, SDValue &Base) {
Base = N;
return true;
}
Implement selection of inline asm memory operands llvm-svn: 26348
2006-02-24 10:13:12 +08:00
/// SelectInlineAsmMemoryOperand - Implement addressing mode selection for
PowerPC inline asm was emitting two output operands for a single "m" constraint; this is wrong because the opcode of a load or store would have to change in parallel. This patch makes it always compute addresses into a register, which is correct but not as efficient as possible. 7144566. llvm-svn: 79292
2009-08-18 08:18:39 +08:00
/// inline asm expressions. It is always correct to compute the value into
/// a register. The case of adding a (possibly relocatable) constant to a
/// register can be improved, but it is wrong to substitute Reg+Reg for
/// Reg in an asm, because the load or store opcode would have to change.
[PowerPC] Fix inline asm memory operands not to use r0 On PowerPC, inline asm memory operands might be expanded as 0($r), where $r is a register containing the address. As a result, this register cannot be r0, and we need to enforce this register subclass constraint to prevent miscompiling the code (we'd get this constraint for free with the usual instruction definitions, but that scheme has no knowledge of how we end up printing inline asm memory operands, and so here we need to do it 'by hand'). We can accomplish this within the current address-mode selection framework by introducing an explicit COPY_TO_REGCLASS node. Fixes PR21443. llvm-svn: 223318
2014-12-04 07:40:13 +08:00
bool SelectInlineAsmMemoryOperand(const SDValue &Op,
Recommit r232027 with PR22883 fixed: Add infrastructure for support of multiple memory constraints. The operand flag word for ISD::INLINEASM nodes now contains a 15-bit memory constraint ID when the operand kind is Kind_Mem. This constraint ID is a numeric equivalent to the constraint code string and is converted with a target specific hook in TargetLowering. This patch maps all memory constraints to InlineAsm::Constraint_m so there is no functional change at this point. It just proves that using these previously unused bits in the encoding of the flag word doesn't break anything. The next patch will make each target preserve the current mapping of everything to Constraint_m for itself while changing the target independent implementation of the hook to return Constraint_Unknown appropriately. Each target will then be adapted in separate patches to use appropriate Constraint_* values. PR22883 was caused the matching operands copying the whole of the operand flags for the matched operand. This included the constraint id which needed to be replaced with the operand number. This has been fixed with a conversion function. Following on from this, matching operands also used the operand number as the constraint id. This has been fixed by looking up the matched operand and taking it from there. llvm-svn: 232165
2015-03-13 20:45:09 +08:00
unsigned ConstraintID,
[C++11] Add 'override' keywords and remove 'virtual'. Additionally add 'final' and leave 'virtual' on some methods that are marked virtual without overriding anything and have no obvious overrides themselves. PowerPC edition llvm-svn: 207504
2014-04-29 15:57:37 +08:00
std::vector<SDValue> &OutOps) override {
[ppc] Distinguish the 'es', 'o', 'm', 'Q', 'Z', and 'Zy' inline assembly memory constraints. Summary: But still handle them the same way since I don't know how they differ on this target. Of these, 'es', and 'Q' do not have backend tests but are accepted by clang. No functional change intended. Depends on D8173. Reviewers: hfinkel Reviewed By: hfinkel Subscribers: llvm-commits Differential Revision: http://reviews.llvm.org/D8213 llvm-svn: 232466
2015-03-17 19:09:13 +08:00
switch(ConstraintID) {
default:
errs() << "ConstraintID: " << ConstraintID << "\n";
llvm_unreachable("Unexpected asm memory constraint");
case InlineAsm::Constraint_es:
Fix r232466 by adding 'i' to the mappings for inline assembly memory constraints. It's not completely clear why 'i' has historically been treated as a memory constraint. According to the documentation, it represents a constant immediate. llvm-svn: 232470
2015-03-17 20:00:04 +08:00
case InlineAsm::Constraint_i:
[ppc] Distinguish the 'es', 'o', 'm', 'Q', 'Z', and 'Zy' inline assembly memory constraints. Summary: But still handle them the same way since I don't know how they differ on this target. Of these, 'es', and 'Q' do not have backend tests but are accepted by clang. No functional change intended. Depends on D8173. Reviewers: hfinkel Reviewed By: hfinkel Subscribers: llvm-commits Differential Revision: http://reviews.llvm.org/D8213 llvm-svn: 232466
2015-03-17 19:09:13 +08:00
case InlineAsm::Constraint_m:
case InlineAsm::Constraint_o:
case InlineAsm::Constraint_Q:
case InlineAsm::Constraint_Z:
case InlineAsm::Constraint_Zy:
// We need to make sure that this one operand does not end up in r0
// (because we might end up lowering this as 0(%op)).
const TargetRegisterInfo *TRI = PPCSubTarget->getRegisterInfo();
const TargetRegisterClass *TRC = TRI->getPointerRegClass(*MF, /*Kind=*/1);
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
SDLoc dl(Op);
SDValue RC = CurDAG->getTargetConstant(TRC->getID(), dl, MVT::i32);
[ppc] Distinguish the 'es', 'o', 'm', 'Q', 'Z', and 'Zy' inline assembly memory constraints. Summary: But still handle them the same way since I don't know how they differ on this target. Of these, 'es', and 'Q' do not have backend tests but are accepted by clang. No functional change intended. Depends on D8173. Reviewers: hfinkel Reviewed By: hfinkel Subscribers: llvm-commits Differential Revision: http://reviews.llvm.org/D8213 llvm-svn: 232466
2015-03-17 19:09:13 +08:00
SDValue NewOp =
SDValue(CurDAG->getMachineNode(TargetOpcode::COPY_TO_REGCLASS,
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
dl, Op.getValueType(),
[ppc] Distinguish the 'es', 'o', 'm', 'Q', 'Z', and 'Zy' inline assembly memory constraints. Summary: But still handle them the same way since I don't know how they differ on this target. Of these, 'es', and 'Q' do not have backend tests but are accepted by clang. No functional change intended. Depends on D8173. Reviewers: hfinkel Reviewed By: hfinkel Subscribers: llvm-commits Differential Revision: http://reviews.llvm.org/D8213 llvm-svn: 232466
2015-03-17 19:09:13 +08:00
Op, RC), 0);
OutOps.push_back(NewOp);
return false;
}
return true;
Implement selection of inline asm memory operands llvm-svn: 26348
2006-02-24 10:13:12 +08:00
}
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
Reapply r77654 with a fix: MachineFunctionPass's getAnalysisUsage shouldn't do AU.setPreservesCFG(), because even though CodeGen passes don't modify the LLVM IR CFG, they may modify the MachineFunction CFG, and passes like MachineLoop are registered with isCFGOnly set to true. llvm-svn: 77691
2009-08-01 02:16:33 +08:00
void InsertVRSaveCode(MachineFunction &MF);
Save/restore VRSAVE once per function, not once per block. llvm-svn: 26793
2006-03-17 02:25:23 +08:00
[C++11] Add 'override' keywords and remove 'virtual'. Additionally add 'final' and leave 'virtual' on some methods that are marked virtual without overriding anything and have no obvious overrides themselves. PowerPC edition llvm-svn: 207504
2014-04-29 15:57:37 +08:00
const char *getPassName() const override {
initial hack at a dag->dag instruction selector. This is obviously woefully incomplete, but it is a start. It handles basic argument/retval stuff, immediates, add and sub. llvm-svn: 22836
2005-08-18 03:33:03 +08:00
return "PowerPC DAG->DAG Pattern Instruction Selection";
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
}
move the #include for the generated code into the isel class body so we can use/define class methods llvm-svn: 23339
2005-09-14 06:03:06 +08:00
// Include the pieces autogenerated from the target description.
Eliminate PowerPC.td and PPC32.td, consolidating them into PPC.td llvm-svn: 23738
2005-10-15 07:37:35 +08:00
#include "PPCGenDAGISel.inc"
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
Add a recursive-iterative hybrid stage to attempt to reduce stack space, this helps but not enough. Start pulling cases out of PPC32DAGToDAGISel::Select. With GCC 4, this function required 8512 bytes of stack space for each invocation (GCC 3 required less than 700 bytes). Pulling this first function out gets us down to 8224. More to come :( llvm-svn: 23647
2005-10-07 02:45:51 +08:00
private:
Change SelectCode's argument from SDValue to SDNode *, to make it more clear what information these functions are actually using. This is also a micro-optimization, as passing a SDNode * around is simpler than passing a { SDNode *, int } by value or reference. llvm-svn: 92564
2010-01-05 09:24:18 +08:00
SDNode *SelectSETCC(SDNode *N);
Add CR-bit tracking to the PowerPC backend for i1 values This change enables tracking i1 values in the PowerPC backend using the condition register bits. These bits can be treated on PowerPC as separate registers; individual bit operations (and, or, xor, etc.) are supported. Tracking booleans in CR bits has several advantages: - Reduction in register pressure (because we no longer need GPRs to store boolean values). - Logical operations on booleans can be handled more efficiently; we used to have to move all results from comparisons into GPRs, perform promoted logical operations in GPRs, and then move the result back into condition register bits to be used by conditional branches. This can be very inefficient, because the throughput of these CR <-> GPR moves have high latency and low throughput (especially when other associated instructions are accounted for). - On the POWER7 and similar cores, we can increase total throughput by using the CR bits. CR bit operations have a dedicated functional unit. Most of this is more-or-less mechanical: Adjustments were needed in the calling-convention code, support was added for spilling/restoring individual condition-register bits, and conditional branch instruction definitions taking specific CR bits were added (plus patterns and code for generating bit-level operations). This is enabled by default when running at -O2 and higher. For -O0 and -O1, where the ability to debug is more important, this feature is disabled by default. Individual CR bits do not have assigned DWARF register numbers, and storing values in CR bits makes them invisible to the debugger. It is critical, however, that we don't move i1 values that have been promoted to larger values (such as those passed as function arguments) into bit registers only to quickly turn around and move the values back into GPRs (such as happens when values are returned by functions). A pair of target-specific DAG combines are added to remove the trunc/extends in: trunc(binary-ops(binary-ops(zext(x), zext(y)), ...) and: zext(binary-ops(binary-ops(trunc(x), trunc(y)), ...) In short, we only want to use CR bits where some of the i1 values come from comparisons or are used by conditional branches or selects. To put it another way, if we can do the entire i1 computation in GPRs, then we probably should (on the POWER7, the GPR-operation throughput is higher, and for all cores, the CR <-> GPR moves are expensive). POWER7 test-suite performance results (from 10 runs in each configuration): SingleSource/Benchmarks/Misc/mandel-2: 35% speedup MultiSource/Benchmarks/Prolangs-C++/city/city: 21% speedup MultiSource/Benchmarks/MiBench/automotive-susan: 23% speedup SingleSource/Benchmarks/CoyoteBench/huffbench: 13% speedup SingleSource/Benchmarks/Misc-C++/Large/sphereflake: 13% speedup SingleSource/Benchmarks/Misc-C++/mandel-text: 10% speedup SingleSource/Benchmarks/Misc-C++-EH/spirit: 10% slowdown MultiSource/Applications/lemon/lemon: 8% slowdown llvm-svn: 202451
2014-02-28 08:27:01 +08:00
void PeepholePPC64();
[PowerPC] Add a DAGToDAG peephole to remove unnecessary zero-exts On PPC64, we end up with lots of i32 -> i64 zero extensions, not only from all of the usual places, but also from the ABI, which specifies that values passed are zero extended. Almost all 32-bit PPC instructions in PPC64 mode are defined to do *something* to the higher-order bits, and for some instructions, that action clears those bits (thus providing a zero-extended result). This is especially common after rotate-and-mask instructions. Adding an additional instruction to zero-extend the results of these instructions is unnecessary. This PPCISelDAGToDAG peephole optimization examines these zero-extensions, and looks back through their operands to see if all instructions will implicitly zero extend their results. If so, we convert these instructions to their 64-bit variants (which is an internal change only, the actual encoding of these instructions is the same as the original 32-bit ones) and remove the unnecessary zero-extension (changing where the INSERT_SUBREG instructions are to make everything internally consistent). llvm-svn: 224169
2014-12-13 07:59:36 +08:00
void PeepholePPC64ZExt();
Fix typo in function name. llvm-svn: 208743
2014-05-14 08:31:15 +08:00
void PeepholeCROps();
Swap PPC isel operands to allow for 0-folding The PPC isel instruction can fold 0 into the first operand (thus eliminating the need to materialize a zero-containing register when the 'true' result of the isel is 0). When the isel is fed by a bit register operation that we can invert, do so as part of the bit-register-operation peephole routine. llvm-svn: 202469
2014-02-28 14:11:16 +08:00
[PowerPC] Add support for the CMPB instruction Newer POWER cores, and the A2, support the cmpb instruction. This instruction compares its operands, treating each of the 8 bytes in the GPRs separately, returning a 'mask' result of 0 (for false) or -1 (for true) in each byte. Code generation support is added, in the form of a PPCISelDAGToDAG DAG-preprocessing routine, that recognizes patterns close to what the instruction computes (either exactly, or related by a constant masking operation), and generates the cmpb instruction (along with any necessary constant masking operation). This can be expanded if use cases arise. llvm-svn: 225106
2015-01-03 09:16:37 +08:00
SDValue combineToCMPB(SDNode *N);
[PowerPC] Fold i1 extensions with other ops Consider this function from our README.txt file: int foo(int a, int b) { return (a < b) << 4; } We now explicitly track CR bits by default, so the comment in the README.txt about not really having a SETCC is no longer accurate, but we did generate this somewhat silly code: cmpw 0, 3, 4 li 3, 0 li 12, 1 isel 3, 12, 3, 0 sldi 3, 3, 4 blr which generates the zext as a select between 0 and 1, and then shifts the result by a constant amount. Here we preprocess the DAG in order to fold the results of operations on an extension of an i1 value into the SELECT_I[48] pseudo instruction when the resulting constant can be materialized using one instruction (just like the 0 and 1). This was not implemented as a DAGCombine because the resulting code would have been anti-canonical and depends on replacing chained user nodes, which does not fit well into the lowering paradigm. Now we generate: cmpw 0, 3, 4 li 3, 0 li 12, 16 isel 3, 12, 3, 0 blr which is less silly. llvm-svn: 225203
2015-01-06 05:10:24 +08:00
void foldBoolExts(SDValue &Res, SDNode *&N);
[PowerPC] Add support for the CMPB instruction Newer POWER cores, and the A2, support the cmpb instruction. This instruction compares its operands, treating each of the 8 bytes in the GPRs separately, returning a 'mask' result of 0 (for false) or -1 (for true) in each byte. Code generation support is added, in the form of a PPCISelDAGToDAG DAG-preprocessing routine, that recognizes patterns close to what the instruction computes (either exactly, or related by a constant masking operation), and generates the cmpb instruction (along with any necessary constant masking operation). This can be expanded if use cases arise. llvm-svn: 225106
2015-01-03 09:16:37 +08:00
Swap PPC isel operands to allow for 0-folding The PPC isel instruction can fold 0 into the first operand (thus eliminating the need to materialize a zero-containing register when the 'true' result of the isel is 0). When the isel is fed by a bit register operation that we can invert, do so as part of the bit-register-operation peephole routine. llvm-svn: 202469
2014-02-28 14:11:16 +08:00
bool AllUsersSelectZero(SDNode *N);
void SwapAllSelectUsers(SDNode *N);
[PowerPC] Make LDtocL and friends invariant loads LDtocL, and other loads that roughly correspond to the TOC_ENTRY SDAG node, represent loads from the TOC, which is invariant. As a result, these loads can be hoisted out of loops, etc. In order to do this, we need to generate GOT-style MMOs for TOC_ENTRY, which requires treating it as a legitimate memory intrinsic node type. Once this is done, the MMO transfer is automatically handled for TableGen-driven instruction selection, and for nodes generated directly in PPCISelDAGToDAG, we need to transfer the MMOs manually. Also, we were not transferring MMOs associated with pre-increment loads, so do that too. Lastly, this fixes an exposed bug where R30 was not added as a defined operand of UpdateGBR. This problem was highlighted by an example (used to generate the test case) posted to llvmdev by Francois Pichet. llvm-svn: 230553
2015-02-26 05:36:59 +08:00
SDNode *transferMemOperands(SDNode *N, SDNode *Result);
initial hack at a dag->dag instruction selector. This is obviously woefully incomplete, but it is a start. It handles basic argument/retval stuff, immediates, add and sub. llvm-svn: 22836
2005-08-18 03:33:03 +08:00
};
Revert r240137 (Fixed/added namespace ending comments using clang-tidy. NFC) Apparently, the style needs to be agreed upon first. llvm-svn: 240390
2015-06-23 17:49:53 +08:00
}
initial hack at a dag->dag instruction selector. This is obviously woefully incomplete, but it is a start. It handles basic argument/retval stuff, immediates, add and sub. llvm-svn: 22836
2005-08-18 03:33:03 +08:00
Save/restore VRSAVE once per function, not once per block. llvm-svn: 26793
2006-03-17 02:25:23 +08:00
/// InsertVRSaveCode - Once the entire function has been instruction selected,
/// all virtual registers are created and all machine instructions are built,
/// check to see if we need to save/restore VRSAVE. If so, do it.
Reapply r77654 with a fix: MachineFunctionPass's getAnalysisUsage shouldn't do AU.setPreservesCFG(), because even though CodeGen passes don't modify the LLVM IR CFG, they may modify the MachineFunction CFG, and passes like MachineLoop are registered with isCFGOnly set to true. llvm-svn: 77691
2009-08-01 02:16:33 +08:00
void PPCDAGToDAGISel::InsertVRSaveCode(MachineFunction &Fn) {
For functions that use vector registers, save VRSAVE, mark used registers, and update it on entry to each function, then restore it on exit. This compiles: void func(vfloat *a, vfloat *b, vfloat *c) { *a = *b * *c + *c; } to this: _func: mfspr r2, 256 oris r6, r2, 49152 mtspr 256, r6 lvx v0, 0, r5 lvx v1, 0, r4 vmaddfp v0, v1, v0, v0 stvx v0, 0, r3 mtspr 256, r2 blr GCC produces this (which has additional stack accesses): _func: mfspr r0,256 stw r0,-4(r1) oris r0,r0,0xc000 mtspr 256,r0 lvx v0,0,r5 lvx v1,0,r4 lwz r12,-4(r1) vmaddfp v0,v0,v1,v0 stvx v0,0,r3 mtspr 256,r12 blr llvm-svn: 26733
2006-03-14 05:52:10 +08:00
// Check to see if this function uses vector registers, which means we have to
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
// save and restore the VRSAVE register and update it with the regs we use.
For functions that use vector registers, save VRSAVE, mark used registers, and update it on entry to each function, then restore it on exit. This compiles: void func(vfloat *a, vfloat *b, vfloat *c) { *a = *b * *c + *c; } to this: _func: mfspr r2, 256 oris r6, r2, 49152 mtspr 256, r6 lvx v0, 0, r5 lvx v1, 0, r4 vmaddfp v0, v1, v0, v0 stvx v0, 0, r3 mtspr 256, r2 blr GCC produces this (which has additional stack accesses): _func: mfspr r0,256 stw r0,-4(r1) oris r0,r0,0xc000 mtspr 256,r0 lvx v0,0,r5 lvx v1,0,r4 lwz r12,-4(r1) vmaddfp v0,v0,v1,v0 stvx v0,0,r3 mtspr 256,r12 blr llvm-svn: 26733
2006-03-14 05:52:10 +08:00
//
Fix "the the" and similar typos. llvm-svn: 95781
2010-02-11 00:03:48 +08:00
// In this case, there will be virtual registers of vector type created
For functions that use vector registers, save VRSAVE, mark used registers, and update it on entry to each function, then restore it on exit. This compiles: void func(vfloat *a, vfloat *b, vfloat *c) { *a = *b * *c + *c; } to this: _func: mfspr r2, 256 oris r6, r2, 49152 mtspr 256, r6 lvx v0, 0, r5 lvx v1, 0, r4 vmaddfp v0, v1, v0, v0 stvx v0, 0, r3 mtspr 256, r2 blr GCC produces this (which has additional stack accesses): _func: mfspr r0,256 stw r0,-4(r1) oris r0,r0,0xc000 mtspr 256,r0 lvx v0,0,r5 lvx v1,0,r4 lwz r12,-4(r1) vmaddfp v0,v0,v1,v0 stvx v0,0,r3 mtspr 256,r12 blr llvm-svn: 26733
2006-03-14 05:52:10 +08:00
// by the scheduler. Detect them now.
bool HasVectorVReg = false;
Fix the last virtual register enumerations. llvm-svn: 123102
2011-01-09 07:11:11 +08:00
for (unsigned i = 0, e = RegInfo->getNumVirtRegs(); i != e; ++i) {
unsigned Reg = TargetRegisterInfo::index2VirtReg(i);
if (RegInfo->getRegClass(Reg) == &PPC::VRRCRegClass) {
For functions that use vector registers, save VRSAVE, mark used registers, and update it on entry to each function, then restore it on exit. This compiles: void func(vfloat *a, vfloat *b, vfloat *c) { *a = *b * *c + *c; } to this: _func: mfspr r2, 256 oris r6, r2, 49152 mtspr 256, r6 lvx v0, 0, r5 lvx v1, 0, r4 vmaddfp v0, v1, v0, v0 stvx v0, 0, r3 mtspr 256, r2 blr GCC produces this (which has additional stack accesses): _func: mfspr r0,256 stw r0,-4(r1) oris r0,r0,0xc000 mtspr 256,r0 lvx v0,0,r5 lvx v1,0,r4 lwz r12,-4(r1) vmaddfp v0,v0,v1,v0 stvx v0,0,r3 mtspr 256,r12 blr llvm-svn: 26733
2006-03-14 05:52:10 +08:00
HasVectorVReg = true;
break;
}
Fix the last virtual register enumerations. llvm-svn: 123102
2011-01-09 07:11:11 +08:00
}
Save/restore VRSAVE once per function, not once per block. llvm-svn: 26793
2006-03-17 02:25:23 +08:00
if (!HasVectorVReg) return; // nothing to do.
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
For functions that use vector registers, save VRSAVE, mark used registers, and update it on entry to each function, then restore it on exit. This compiles: void func(vfloat *a, vfloat *b, vfloat *c) { *a = *b * *c + *c; } to this: _func: mfspr r2, 256 oris r6, r2, 49152 mtspr 256, r6 lvx v0, 0, r5 lvx v1, 0, r4 vmaddfp v0, v1, v0, v0 stvx v0, 0, r3 mtspr 256, r2 blr GCC produces this (which has additional stack accesses): _func: mfspr r0,256 stw r0,-4(r1) oris r0,r0,0xc000 mtspr 256,r0 lvx v0,0,r5 lvx v1,0,r4 lwz r12,-4(r1) vmaddfp v0,v0,v1,v0 stvx v0,0,r3 mtspr 256,r12 blr llvm-svn: 26733
2006-03-14 05:52:10 +08:00
// If we have a vector register, we want to emit code into the entry and exit
// blocks to save and restore the VRSAVE register. We do this here (instead
// of marking all vector instructions as clobbering VRSAVE) for two reasons:
//
// 1. This (trivially) reduces the load on the register allocator, by not
// having to represent the live range of the VRSAVE register.
// 2. This (more significantly) allows us to create a temporary virtual
// register to hold the saved VRSAVE value, allowing this temporary to be
// register allocated, instead of forcing it to be spilled to the stack.
Save/restore VRSAVE once per function, not once per block. llvm-svn: 26793
2006-03-17 02:25:23 +08:00
// Create two vregs - one to hold the VRSAVE register that is live-in to the
// function and one for the value after having bits or'd into it.
Rename SSARegMap -> MachineRegisterInfo in keeping with the idea that "machine" classes are used to represent the current state of the code being compiled. Given this expanded name, we can start moving other stuff into it. For now, move the UsedPhysRegs and LiveIn/LoveOuts vectors from MachineFunction into it. Update all the clients to match. This also reduces some needless #includes, such as MachineModuleInfo from MachineFunction. llvm-svn: 45467
2007-12-31 12:13:23 +08:00
unsigned InVRSAVE = RegInfo->createVirtualRegister(&PPC::GPRCRegClass);
unsigned UpdatedVRSAVE = RegInfo->createVirtualRegister(&PPC::GPRCRegClass);
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
Use the cached subtargets and remove calls to getSubtarget/getSubtargetImpl without a Function argument. llvm-svn: 227622
2015-01-31 06:02:31 +08:00
const TargetInstrInfo &TII = *PPCSubTarget->getInstrInfo();
Save/restore VRSAVE once per function, not once per block. llvm-svn: 26793
2006-03-17 02:25:23 +08:00
MachineBasicBlock &EntryBB = *Fn.begin();
use DebugLoc default ctor instead of DebugLoc::getUnknownLoc() llvm-svn: 100214
2010-04-03 04:16:16 +08:00
DebugLoc dl;
Save/restore VRSAVE once per function, not once per block. llvm-svn: 26793
2006-03-17 02:25:23 +08:00
// Emit the following code into the entry block:
// InVRSAVE = MFVRSAVE
// UpdatedVRSAVE = UPDATE_VRSAVE InVRSAVE
// MTVRSAVE UpdatedVRSAVE
MachineBasicBlock::iterator IP = EntryBB.begin(); // Insert Point
Remove refs to non-DebugLoc version of BuildMI from PowerPC. llvm-svn: 64431
2009-02-13 10:27:39 +08:00
BuildMI(EntryBB, IP, dl, TII.get(PPC::MFVRSAVE), InVRSAVE);
BuildMI(EntryBB, IP, dl, TII.get(PPC::UPDATE_VRSAVE),
Rename MachineInstr::getInstrDescriptor -> getDesc(), which reflects that it is cheap and efficient to get. Move a variety of predicates from TargetInstrInfo into TargetInstrDescriptor, which makes it much easier to query a predicate when you don't have TII around. Now you can use MI->getDesc()->isBranch() instead of going through TII, and this is much more efficient anyway. Not all of the predicates have been moved over yet. Update old code that used MI->getInstrDescriptor()->Flags to use the new predicates in many places. llvm-svn: 45674
2008-01-07 09:56:04 +08:00
UpdatedVRSAVE).addReg(InVRSAVE);
Remove refs to non-DebugLoc version of BuildMI from PowerPC. llvm-svn: 64431
2009-02-13 10:27:39 +08:00
BuildMI(EntryBB, IP, dl, TII.get(PPC::MTVRSAVE)).addReg(UpdatedVRSAVE);
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
Save/restore VRSAVE once per function, not once per block. llvm-svn: 26793
2006-03-17 02:25:23 +08:00
// Find all return blocks, outputting a restore in each epilog.
for (MachineFunction::iterator BB = Fn.begin(), E = Fn.end(); BB != E; ++BB) {
MachineBasicBlock: Factor out common code into isReturnBlock() llvm-svn: 248617
2015-09-26 05:25:19 +08:00
if (BB->isReturnBlock()) {
Save/restore VRSAVE once per function, not once per block. llvm-svn: 26793
2006-03-17 02:25:23 +08:00
IP = BB->end(); --IP;
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
Save/restore VRSAVE once per function, not once per block. llvm-svn: 26793
2006-03-17 02:25:23 +08:00
// Skip over all terminator instructions, which are part of the return
// sequence.
MachineBasicBlock::iterator I2 = IP;
Add bundle aware API for querying instruction properties and switch the code generator to it. For non-bundle instructions, these behave exactly the same as the MC layer API. For properties like mayLoad / mayStore, look into the bundle and if any of the bundled instructions has the property it would return true. For properties like isPredicable, only return true if *all* of the bundled instructions have the property. For properties like canFoldAsLoad, isCompare, conservatively return false for bundles. llvm-svn: 146026
2011-12-07 15:15:52 +08:00
while (I2 != BB->begin() && (--I2)->isTerminator())
Save/restore VRSAVE once per function, not once per block. llvm-svn: 26793
2006-03-17 02:25:23 +08:00
IP = I2;
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
Save/restore VRSAVE once per function, not once per block. llvm-svn: 26793
2006-03-17 02:25:23 +08:00
// Emit: MTVRSAVE InVRSave
Remove refs to non-DebugLoc version of BuildMI from PowerPC. llvm-svn: 64431
2009-02-13 10:27:39 +08:00
BuildMI(*BB, IP, dl, TII.get(PPC::MTVRSAVE)).addReg(InVRSAVE);
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
}
For functions that use vector registers, save VRSAVE, mark used registers, and update it on entry to each function, then restore it on exit. This compiles: void func(vfloat *a, vfloat *b, vfloat *c) { *a = *b * *c + *c; } to this: _func: mfspr r2, 256 oris r6, r2, 49152 mtspr 256, r6 lvx v0, 0, r5 lvx v1, 0, r4 vmaddfp v0, v1, v0, v0 stvx v0, 0, r3 mtspr 256, r2 blr GCC produces this (which has additional stack accesses): _func: mfspr r0,256 stw r0,-4(r1) oris r0,r0,0xc000 mtspr 256,r0 lvx v0,0,r5 lvx v1,0,r4 lwz r12,-4(r1) vmaddfp v0,v0,v1,v0 stvx v0,0,r3 mtspr 256,r12 blr llvm-svn: 26733
2006-03-14 05:52:10 +08:00
}
Add a recursive-iterative hybrid stage to attempt to reduce stack space, this helps but not enough. Start pulling cases out of PPC32DAGToDAGISel::Select. With GCC 4, this function required 8512 bytes of stack space for each invocation (GCC 3 required less than 700 bytes). Pulling this first function out gets us down to 8224. More to come :( llvm-svn: 23647
2005-10-07 02:45:51 +08:00
}
include the dag isel fragment llvm-svn: 23239
2005-09-03 09:17:22 +08:00
Save/restore VRSAVE once per function, not once per block. llvm-svn: 26793
2006-03-17 02:25:23 +08:00
add support for global address, including PIC support. This REALLY should be lowered by the legalizer! llvm-svn: 22941
2005-08-20 06:38:53 +08:00
/// getGlobalBaseReg - Output the instructions required to put the
/// base address to use for accessing globals into a register.
///
Select() no longer require Result operand by reference. llvm-svn: 29898
2006-08-26 13:34:46 +08:00
SDNode *PPCDAGToDAGISel::getGlobalBaseReg() {
add support for global address, including PIC support. This REALLY should be lowered by the legalizer! llvm-svn: 22941
2005-08-20 06:38:53 +08:00
if (!GlobalBaseReg) {
Use the cached subtargets and remove calls to getSubtarget/getSubtargetImpl without a Function argument. llvm-svn: 227622
2015-01-31 06:02:31 +08:00
const TargetInstrInfo &TII = *PPCSubTarget->getInstrInfo();
add support for global address, including PIC support. This REALLY should be lowered by the legalizer! llvm-svn: 22941
2005-08-20 06:38:53 +08:00
// Insert the set of GlobalBaseReg into the first MBB of the function
Simplify a few more things, eliminating a few more dependencies on "the current basic block". llvm-svn: 79069
2009-08-15 10:07:36 +08:00
MachineBasicBlock &FirstMBB = MF->front();
add support for global address, including PIC support. This REALLY should be lowered by the legalizer! llvm-svn: 22941
2005-08-20 06:38:53 +08:00
MachineBasicBlock::iterator MBBI = FirstMBB.begin();
Add support for small-model PIC for PowerPC. Summary: Large-model was added first. With the addition of support for multiple PIC models in LLVM, now add small-model PIC for 32-bit PowerPC, SysV4 ABI. This generates more optimal code, for shared libraries with less than about 16380 data objects. Test Plan: Test cases added or updated Reviewers: joerg, hfinkel Reviewed By: hfinkel Subscribers: jholewinski, mcrosier, emaste, llvm-commits Differential Revision: http://reviews.llvm.org/D5399 llvm-svn: 221791
2014-11-12 23:16:30 +08:00
const Module *M = MF->getFunction()->getParent();
use DebugLoc default ctor instead of DebugLoc::getUnknownLoc() llvm-svn: 100214
2010-04-03 04:16:16 +08:00
DebugLoc dl;
Implement a bunch of 64-bit cleanliness work. With this, treeadd builds (but doesn't work right). llvm-svn: 28921
2006-06-27 08:04:13 +08:00
Make TargetLowering::getPointerTy() taking DataLayout as an argument Summary: This change is part of a series of commits dedicated to have a single DataLayout during compilation by using always the one owned by the module. Reviewers: echristo Subscribers: jholewinski, ted, yaron.keren, rafael, llvm-commits Differential Revision: http://reviews.llvm.org/D11028 From: Mehdi Amini <mehdi.amini@apple.com> llvm-svn: 241775
2015-07-09 10:09:04 +08:00
if (PPCLowering->getPointerTy(CurDAG->getDataLayout()) == MVT::i32) {
Add support for small-model PIC for PowerPC. Summary: Large-model was added first. With the addition of support for multiple PIC models in LLVM, now add small-model PIC for 32-bit PowerPC, SysV4 ABI. This generates more optimal code, for shared libraries with less than about 16380 data objects. Test Plan: Test cases added or updated Reviewers: joerg, hfinkel Reviewed By: hfinkel Subscribers: jholewinski, mcrosier, emaste, llvm-commits Differential Revision: http://reviews.llvm.org/D5399 llvm-svn: 221791
2014-11-12 23:16:30 +08:00
if (PPCSubTarget->isTargetELF()) {
[PowerPC] 32-bit ELF PIC support This adds initial support for PPC32 ELF PIC (Position Independent Code; the -fPIC variety), thus rectifying a long-standing deficiency in the PowerPC backend. Patch by Justin Hibbits! llvm-svn: 213427
2014-07-19 07:29:49 +08:00
GlobalBaseReg = PPC::R30;
Add support for small-model PIC for PowerPC. Summary: Large-model was added first. With the addition of support for multiple PIC models in LLVM, now add small-model PIC for 32-bit PowerPC, SysV4 ABI. This generates more optimal code, for shared libraries with less than about 16380 data objects. Test Plan: Test cases added or updated Reviewers: joerg, hfinkel Reviewed By: hfinkel Subscribers: jholewinski, mcrosier, emaste, llvm-commits Differential Revision: http://reviews.llvm.org/D5399 llvm-svn: 221791
2014-11-12 23:16:30 +08:00
if (M->getPICLevel() == PICLevel::Small) {
BuildMI(FirstMBB, MBBI, dl, TII.get(PPC::MoveGOTtoLR));
BuildMI(FirstMBB, MBBI, dl, TII.get(PPC::MFLR), GlobalBaseReg);
Add saving and restoring of r30 to the prologue and epilogue, respectively Summary: The PIC additions didn't update the prologue and epilogue code to save and restore r30 (PIC base register). This does that. Test Plan: Tests updated. Reviewers: hfinkel Reviewed By: hfinkel Subscribers: llvm-commits Differential Revision: http://reviews.llvm.org/D6876 llvm-svn: 225450
2015-01-08 23:47:19 +08:00
MF->getInfo<PPCFunctionInfo>()->setUsesPICBase(true);
Add support for small-model PIC for PowerPC. Summary: Large-model was added first. With the addition of support for multiple PIC models in LLVM, now add small-model PIC for 32-bit PowerPC, SysV4 ABI. This generates more optimal code, for shared libraries with less than about 16380 data objects. Test Plan: Test cases added or updated Reviewers: joerg, hfinkel Reviewed By: hfinkel Subscribers: jholewinski, mcrosier, emaste, llvm-commits Differential Revision: http://reviews.llvm.org/D5399 llvm-svn: 221791
2014-11-12 23:16:30 +08:00
} else {
BuildMI(FirstMBB, MBBI, dl, TII.get(PPC::MovePCtoLR));
BuildMI(FirstMBB, MBBI, dl, TII.get(PPC::MFLR), GlobalBaseReg);
unsigned TempReg = RegInfo->createVirtualRegister(&PPC::GPRCRegClass);
BuildMI(FirstMBB, MBBI, dl,
[PowerPC] Make LDtocL and friends invariant loads LDtocL, and other loads that roughly correspond to the TOC_ENTRY SDAG node, represent loads from the TOC, which is invariant. As a result, these loads can be hoisted out of loops, etc. In order to do this, we need to generate GOT-style MMOs for TOC_ENTRY, which requires treating it as a legitimate memory intrinsic node type. Once this is done, the MMO transfer is automatically handled for TableGen-driven instruction selection, and for nodes generated directly in PPCISelDAGToDAG, we need to transfer the MMOs manually. Also, we were not transferring MMOs associated with pre-increment loads, so do that too. Lastly, this fixes an exposed bug where R30 was not added as a defined operand of UpdateGBR. This problem was highlighted by an example (used to generate the test case) posted to llvmdev by Francois Pichet. llvm-svn: 230553
2015-02-26 05:36:59 +08:00
TII.get(PPC::UpdateGBR), GlobalBaseReg)
Add support for small-model PIC for PowerPC. Summary: Large-model was added first. With the addition of support for multiple PIC models in LLVM, now add small-model PIC for 32-bit PowerPC, SysV4 ABI. This generates more optimal code, for shared libraries with less than about 16380 data objects. Test Plan: Test cases added or updated Reviewers: joerg, hfinkel Reviewed By: hfinkel Subscribers: jholewinski, mcrosier, emaste, llvm-commits Differential Revision: http://reviews.llvm.org/D5399 llvm-svn: 221791
2014-11-12 23:16:30 +08:00
.addReg(TempReg, RegState::Define).addReg(GlobalBaseReg);
MF->getInfo<PPCFunctionInfo>()->setUsesPICBase(true);
}
} else {
[PowerPC] 32-bit ELF PIC support This adds initial support for PPC32 ELF PIC (Position Independent Code; the -fPIC variety), thus rectifying a long-standing deficiency in the PowerPC backend. Patch by Justin Hibbits! llvm-svn: 213427
2014-07-19 07:29:49 +08:00
GlobalBaseReg =
RegInfo->createVirtualRegister(&PPC::GPRC_NOR0RegClass);
Add support for small-model PIC for PowerPC. Summary: Large-model was added first. With the addition of support for multiple PIC models in LLVM, now add small-model PIC for 32-bit PowerPC, SysV4 ABI. This generates more optimal code, for shared libraries with less than about 16380 data objects. Test Plan: Test cases added or updated Reviewers: joerg, hfinkel Reviewed By: hfinkel Subscribers: jholewinski, mcrosier, emaste, llvm-commits Differential Revision: http://reviews.llvm.org/D5399 llvm-svn: 221791
2014-11-12 23:16:30 +08:00
BuildMI(FirstMBB, MBBI, dl, TII.get(PPC::MovePCtoLR));
BuildMI(FirstMBB, MBBI, dl, TII.get(PPC::MFLR), GlobalBaseReg);
[PowerPC] 32-bit ELF PIC support This adds initial support for PPC32 ELF PIC (Position Independent Code; the -fPIC variety), thus rectifying a long-standing deficiency in the PowerPC backend. Patch by Justin Hibbits! llvm-svn: 213427
2014-07-19 07:29:49 +08:00
}
remove a ton of custom selection logic no longer needed llvm-svn: 31733
2006-11-15 02:43:11 +08:00
} else {
The PPC global base register cannot be r0 The global base register cannot be r0 because it might end up as the first argument to addi or addis. Fixes PR18316. I don't have a small stable test case. llvm-svn: 203054
2014-03-06 09:28:23 +08:00
GlobalBaseReg = RegInfo->createVirtualRegister(&PPC::G8RC_NOX0RegClass);
Fix PR8828 by removing the explicit def in MovePCToLR as well as the pointless piclabel operand. The operand in the tablegen definition doesn't actually turn into an MI operand, so it just confuses anything checking the TargetInstrDesc for the number of operands. It suffices to just have an implicit def of LR. llvm-svn: 131626
2011-05-19 10:56:28 +08:00
BuildMI(FirstMBB, MBBI, dl, TII.get(PPC::MovePCtoLR8));
Remove refs to non-DebugLoc version of BuildMI from PowerPC. llvm-svn: 64431
2009-02-13 10:27:39 +08:00
BuildMI(FirstMBB, MBBI, dl, TII.get(PPC::MFLR8), GlobalBaseReg);
remove a ton of custom selection logic no longer needed llvm-svn: 31733
2006-11-15 02:43:11 +08:00
}
add support for global address, including PIC support. This REALLY should be lowered by the legalizer! llvm-svn: 22941
2005-08-20 06:38:53 +08:00
}
fix a bunch of 80-col violations llvm-svn: 55588
2008-08-31 23:37:04 +08:00
return CurDAG->getRegister(GlobalBaseReg,
Make TargetLowering::getPointerTy() taking DataLayout as an argument Summary: This change is part of a series of commits dedicated to have a single DataLayout during compilation by using always the one owned by the module. Reviewers: echristo Subscribers: jholewinski, ted, yaron.keren, rafael, llvm-commits Differential Revision: http://reviews.llvm.org/D11028 From: Mehdi Amini <mehdi.amini@apple.com> llvm-svn: 241775
2015-07-09 10:09:04 +08:00
PPCLowering->getPointerTy(CurDAG->getDataLayout()))
.getNode();
add support for global address, including PIC support. This REALLY should be lowered by the legalizer! llvm-svn: 22941
2005-08-20 06:38:53 +08:00
}
Implement a bunch of 64-bit cleanliness work. With this, treeadd builds (but doesn't work right). llvm-svn: 28921
2006-06-27 08:04:13 +08:00
/// isIntS16Immediate - This method tests to see if the node is either a 32-bit
/// or 64-bit immediate, and if the value can be accurately represented as a
/// sign extension from a 16-bit value. If so, this returns true and the
/// immediate.
static bool isIntS16Immediate(SDNode *N, short &Imm) {
if (N->getOpcode() != ISD::Constant)
return false;
add support for global address, including PIC support. This REALLY should be lowered by the legalizer! llvm-svn: 22941
2005-08-20 06:38:53 +08:00
Rename ConstantSDNode::getValue to getZExtValue, for consistency with ConstantInt. This led to fixing a bug in TargetLowering.cpp using getValue instead of getAPIntValue. llvm-svn: 56159
2008-09-13 00:56:44 +08:00
Imm = (short)cast<ConstantSDNode>(N)->getZExtValue();
Split EVT into MVT and EVT, the former representing _just_ a primitive type, while the latter is capable of representing either a primitive or an extended type. llvm-svn: 78713
2009-08-12 04:47:22 +08:00
if (N->getValueType(0) == MVT::i32)
Rename ConstantSDNode::getValue to getZExtValue, for consistency with ConstantInt. This led to fixing a bug in TargetLowering.cpp using getValue instead of getAPIntValue. llvm-svn: 56159
2008-09-13 00:56:44 +08:00
return Imm == (int32_t)cast<ConstantSDNode>(N)->getZExtValue();
Implement a bunch of 64-bit cleanliness work. With this, treeadd builds (but doesn't work right). llvm-svn: 28921
2006-06-27 08:04:13 +08:00
else
Rename ConstantSDNode::getValue to getZExtValue, for consistency with ConstantInt. This led to fixing a bug in TargetLowering.cpp using getValue instead of getAPIntValue. llvm-svn: 56159
2008-09-13 00:56:44 +08:00
return Imm == (int64_t)cast<ConstantSDNode>(N)->getZExtValue();
Implement a bunch of 64-bit cleanliness work. With this, treeadd builds (but doesn't work right). llvm-svn: 28921
2006-06-27 08:04:13 +08:00
}
Rename SDOperand to SDValue. llvm-svn: 54128
2008-07-28 05:46:04 +08:00
static bool isIntS16Immediate(SDValue Op, short &Imm) {
erect abstraction boundaries for accessing SDValue members, rename Val -> Node to reflect semantics llvm-svn: 55504
2008-08-29 05:40:38 +08:00
return isIntS16Immediate(Op.getNode(), Imm);
Implement a bunch of 64-bit cleanliness work. With this, treeadd builds (but doesn't work right). llvm-svn: 28921
2006-06-27 08:04:13 +08:00
}
/// isInt32Immediate - This method tests to see if the node is a 32-bit constant
/// operand. If so Imm will receive the 32-bit value.
static bool isInt32Immediate(SDNode *N, unsigned &Imm) {
Split EVT into MVT and EVT, the former representing _just_ a primitive type, while the latter is capable of representing either a primitive or an extended type. llvm-svn: 78713
2009-08-12 04:47:22 +08:00
if (N->getOpcode() == ISD::Constant && N->getValueType(0) == MVT::i32) {
Rename ConstantSDNode::getValue to getZExtValue, for consistency with ConstantInt. This led to fixing a bug in TargetLowering.cpp using getValue instead of getAPIntValue. llvm-svn: 56159
2008-09-13 00:56:44 +08:00
Imm = cast<ConstantSDNode>(N)->getZExtValue();
Implement XOR, remove a broken sign_extend_inreg case llvm-svn: 22854
2005-08-18 13:00:13 +08:00
return true;
}
return false;
}
Implement a bunch of 64-bit cleanliness work. With this, treeadd builds (but doesn't work right). llvm-svn: 28921
2006-06-27 08:04:13 +08:00
/// isInt64Immediate - This method tests to see if the node is a 64-bit constant
/// operand. If so Imm will receive the 64-bit value.
static bool isInt64Immediate(SDNode *N, uint64_t &Imm) {
Split EVT into MVT and EVT, the former representing _just_ a primitive type, while the latter is capable of representing either a primitive or an extended type. llvm-svn: 78713
2009-08-12 04:47:22 +08:00
if (N->getOpcode() == ISD::Constant && N->getValueType(0) == MVT::i64) {
Rename ConstantSDNode::getValue to getZExtValue, for consistency with ConstantInt. This led to fixing a bug in TargetLowering.cpp using getValue instead of getAPIntValue. llvm-svn: 56159
2008-09-13 00:56:44 +08:00
Imm = cast<ConstantSDNode>(N)->getZExtValue();
Implement a bunch of 64-bit cleanliness work. With this, treeadd builds (but doesn't work right). llvm-svn: 28921
2006-06-27 08:04:13 +08:00
return true;
}
return false;
}
// isInt32Immediate - This method tests to see if a constant operand.
// If so Imm will receive the 32 bit value.
Rename SDOperand to SDValue. llvm-svn: 54128
2008-07-28 05:46:04 +08:00
static bool isInt32Immediate(SDValue N, unsigned &Imm) {
erect abstraction boundaries for accessing SDValue members, rename Val -> Node to reflect semantics llvm-svn: 55504
2008-08-29 05:40:38 +08:00
return isInt32Immediate(N.getNode(), Imm);
Implement a bunch of 64-bit cleanliness work. With this, treeadd builds (but doesn't work right). llvm-svn: 28921
2006-06-27 08:04:13 +08:00
}
// isOpcWithIntImmediate - This method tests to see if the node is a specific
// opcode and that it has a immediate integer right operand.
// If so Imm will receive the 32 bit value.
static bool isOpcWithIntImmediate(SDNode *N, unsigned Opc, unsigned& Imm) {
fix a bunch of 80-col violations llvm-svn: 55588
2008-08-31 23:37:04 +08:00
return N->getOpcode() == Opc
&& isInt32Immediate(N->getOperand(1).getNode(), Imm);
Implement a bunch of 64-bit cleanliness work. With this, treeadd builds (but doesn't work right). llvm-svn: 28921
2006-06-27 08:04:13 +08:00
}
[PowerPC] Better lowering for add/or of a FrameIndex If we have an add (or an or that is really an add), where one operand is a FrameIndex and the other operand is a small constant, we can combine the lowering of the FrameIndex (which is lowered as an add of the FI and a zero offset) with the constant operand. Amusingly, this is an old potential improvement entry from lib/Target/PowerPC/README.txt which had never been resolved. In short, we used to lower: %X = alloca { i32, i32 } %Y = getelementptr {i32,i32}* %X, i32 0, i32 1 ret i32* %Y as: addi 3, 1, -8 ori 3, 3, 4 blr and now we produce: addi 3, 1, -4 blr which is much more sensible. llvm-svn: 224071
2014-12-12 06:51:06 +08:00
SDNode *PPCDAGToDAGISel::getFrameIndex(SDNode *SN, SDNode *N, unsigned Offset) {
SDLoc dl(SN);
int FI = cast<FrameIndexSDNode>(N)->getIndex();
SDValue TFI = CurDAG->getTargetFrameIndex(FI, N->getValueType(0));
unsigned Opc = N->getValueType(0) == MVT::i32 ? PPC::ADDI : PPC::ADDI8;
if (SN->hasOneUse())
return CurDAG->SelectNodeTo(SN, Opc, N->getValueType(0), TFI,
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
getSmallIPtrImm(Offset, dl));
[PowerPC] Better lowering for add/or of a FrameIndex If we have an add (or an or that is really an add), where one operand is a FrameIndex and the other operand is a small constant, we can combine the lowering of the FrameIndex (which is lowered as an add of the FI and a zero offset) with the constant operand. Amusingly, this is an old potential improvement entry from lib/Target/PowerPC/README.txt which had never been resolved. In short, we used to lower: %X = alloca { i32, i32 } %Y = getelementptr {i32,i32}* %X, i32 0, i32 1 ret i32* %Y as: addi 3, 1, -8 ori 3, 3, 4 blr and now we produce: addi 3, 1, -4 blr which is much more sensible. llvm-svn: 224071
2014-12-12 06:51:06 +08:00
return CurDAG->getMachineNode(Opc, dl, N->getValueType(0), TFI,
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
getSmallIPtrImm(Offset, dl));
[PowerPC] Better lowering for add/or of a FrameIndex If we have an add (or an or that is really an add), where one operand is a FrameIndex and the other operand is a small constant, we can combine the lowering of the FrameIndex (which is lowered as an add of the FI and a zero offset) with the constant operand. Amusingly, this is an old potential improvement entry from lib/Target/PowerPC/README.txt which had never been resolved. In short, we used to lower: %X = alloca { i32, i32 } %Y = getelementptr {i32,i32}* %X, i32 0, i32 1 ret i32* %Y as: addi 3, 1, -8 ori 3, 3, 4 blr and now we produce: addi 3, 1, -4 blr which is much more sensible. llvm-svn: 224071
2014-12-12 06:51:06 +08:00
}
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
bool PPCDAGToDAGISel::isRotateAndMask(SDNode *N, unsigned Mask,
bool isShiftMask, unsigned &SH,
Fold AND and ROTL more often llvm-svn: 30577
2006-09-22 13:01:56 +08:00
unsigned &MB, unsigned &ME) {
Make a new reg class for 64 bit regs that aliases the 32 bit regs. This will have to tide us over until we get real subreg support, but it prevents the PrologEpilogInserter from spilling 8 byte GPRs on a G4 processor. Add some initial support for TRUNCATE and ANY_EXTEND, but they don't currently work due to issues with ScheduleDAG. Something wll have to be figured out. llvm-svn: 23803
2005-10-19 08:05:37 +08:00
// Don't even go down this path for i64, since different logic will be
// necessary for rldicl/rldicr/rldimi.
Split EVT into MVT and EVT, the former representing _just_ a primitive type, while the latter is capable of representing either a primitive or an extended type. llvm-svn: 78713
2009-08-12 04:47:22 +08:00
if (N->getValueType(0) != MVT::i32)
Make a new reg class for 64 bit regs that aliases the 32 bit regs. This will have to tide us over until we get real subreg support, but it prevents the PrologEpilogInserter from spilling 8 byte GPRs on a G4 processor. Add some initial support for TRUNCATE and ANY_EXTEND, but they don't currently work due to issues with ScheduleDAG. Something wll have to be figured out. llvm-svn: 23803
2005-10-19 08:05:37 +08:00
return false;
Add support for ISD::AND, and its various optimized forms. llvm-svn: 22857
2005-08-18 15:30:46 +08:00
unsigned Shift = 32;
unsigned Indeterminant = ~0; // bit mask marking indeterminant results
unsigned Opcode = N->getOpcode();
The first operand to AND does not always have more than two operands. This fixes MediaBench/toast with the dag selector llvm-svn: 23141
2005-08-30 08:59:16 +08:00
if (N->getNumOperands() != 2 ||
erect abstraction boundaries for accessing SDValue members, rename Val -> Node to reflect semantics llvm-svn: 55504
2008-08-29 05:40:38 +08:00
!isInt32Immediate(N->getOperand(1).getNode(), Shift) || (Shift > 31))
Add support for ISD::AND, and its various optimized forms. llvm-svn: 22857
2005-08-18 15:30:46 +08:00
return false;
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
Add support for ISD::AND, and its various optimized forms. llvm-svn: 22857
2005-08-18 15:30:46 +08:00
if (Opcode == ISD::SHL) {
// apply shift left to mask if it comes first
Make capitalization of names starting "is" more consistent. No functional change. llvm-svn: 89724
2009-11-24 09:09:07 +08:00
if (isShiftMask) Mask = Mask << Shift;
Add support for ISD::AND, and its various optimized forms. llvm-svn: 22857
2005-08-18 15:30:46 +08:00
// determine which bits are made indeterminant by shift
Indeterminant = ~(0xFFFFFFFFu << Shift);
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
} else if (Opcode == ISD::SRL) {
Add support for ISD::AND, and its various optimized forms. llvm-svn: 22857
2005-08-18 15:30:46 +08:00
// apply shift right to mask if it comes first
Make capitalization of names starting "is" more consistent. No functional change. llvm-svn: 89724
2009-11-24 09:09:07 +08:00
if (isShiftMask) Mask = Mask >> Shift;
Add support for ISD::AND, and its various optimized forms. llvm-svn: 22857
2005-08-18 15:30:46 +08:00
// determine which bits are made indeterminant by shift
Indeterminant = ~(0xFFFFFFFFu >> Shift);
// adjust for the left rotate
Shift = 32 - Shift;
Fold AND and ROTL more often llvm-svn: 30577
2006-09-22 13:01:56 +08:00
} else if (Opcode == ISD::ROTL) {
Indeterminant = 0;
Add support for ISD::AND, and its various optimized forms. llvm-svn: 22857
2005-08-18 15:30:46 +08:00
} else {
return false;
}
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
Add support for ISD::AND, and its various optimized forms. llvm-svn: 22857
2005-08-18 15:30:46 +08:00
// if the mask doesn't intersect any Indeterminant bits
if (Mask && !(Mask & Indeterminant)) {
Fix PowerPC/2006-05-12-rlwimi-crash.ll Nate, please verify that if InsertMask is 0, rlwimi shouldn't be used. This fixes the crash and causes no PPC testsuite regressions. llvm-svn: 28243
2006-05-13 00:29:37 +08:00
SH = Shift & 31;
Add support for ISD::AND, and its various optimized forms. llvm-svn: 22857
2005-08-18 15:30:46 +08:00
// make sure the mask is still a mask (wrap arounds may not be)
return isRunOfOnes(Mask, MB, ME);
}
return false;
}
ISD::OR, and it's accompanying SelectBitfieldInsert llvm-svn: 22889
2005-08-19 08:38:14 +08:00
/// SelectBitfieldInsert - turn an or of two masked values into
/// the rotate left word immediate then mask insert (rlwimi) instruction.
First bits of 64 bit PowerPC stuff, currently disabled. A lot of this is purely mechanical. llvm-svn: 23778
2005-10-18 08:28:58 +08:00
SDNode *PPCDAGToDAGISel::SelectBitfieldInsert(SDNode *N) {
Rename SDOperand to SDValue. llvm-svn: 54128
2008-07-28 05:46:04 +08:00
SDValue Op0 = N->getOperand(0);
SDValue Op1 = N->getOperand(1);
Track IR ordering of SelectionDAG nodes 2/4. Change SelectionDAG::getXXXNode() interfaces as well as call sites of these functions to pass in SDLoc instead of DebugLoc. llvm-svn: 182703
2013-05-25 10:42:55 +08:00
SDLoc dl(N);
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
Convert the last remaining users of the non-APInt form of ComputeMaskedBits to use the APInt form, and remove the non-APInt form. llvm-svn: 47654
2008-02-27 09:23:58 +08:00
APInt LKZ, LKO, RKZ, RKO;
Rename ComputeMaskedBits to computeKnownBits. "Masked" has been inappropriate since it lost its Mask parameter in r154011. llvm-svn: 208811
2014-05-15 05:14:37 +08:00
CurDAG->computeKnownBits(Op0, LKZ, LKO);
CurDAG->computeKnownBits(Op1, RKZ, RKO);
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
Convert the last remaining users of the non-APInt form of ComputeMaskedBits to use the APInt form, and remove the non-APInt form. llvm-svn: 47654
2008-02-27 09:23:58 +08:00
unsigned TargetMask = LKZ.getZExtValue();
unsigned InsertMask = RKZ.getZExtValue();
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
Fold more shifts into inserts, and update the README llvm-svn: 28168
2006-05-09 01:38:32 +08:00
if ((TargetMask | InsertMask) == 0xFFFFFFFF) {
unsigned Op0Opc = Op0.getOpcode();
unsigned Op1Opc = Op1.getOpcode();
unsigned Value, SH = 0;
TargetMask = ~TargetMask;
InsertMask = ~InsertMask;
New rlwimi implementation, which is superior to the old one. There are still a couple missed optimizations, but we now generate all the possible rlwimis for multiple inserts into the same bitfield. More regression tests to come. llvm-svn: 28156
2006-05-07 08:23:38 +08:00
Fold more shifts into inserts, and update the README llvm-svn: 28168
2006-05-09 01:38:32 +08:00
// If the LHS has a foldable shift and the RHS does not, then swap it to the
// RHS so that we can fold the shift into the insert.
New rlwimi implementation, which is superior to the old one. There are still a couple missed optimizations, but we now generate all the possible rlwimis for multiple inserts into the same bitfield. More regression tests to come. llvm-svn: 28156
2006-05-07 08:23:38 +08:00
if (Op0Opc == ISD::AND && Op1Opc == ISD::AND) {
if (Op0.getOperand(0).getOpcode() == ISD::SHL ||
Op0.getOperand(0).getOpcode() == ISD::SRL) {
if (Op1.getOperand(0).getOpcode() != ISD::SHL &&
Op1.getOperand(0).getOpcode() != ISD::SRL) {
std::swap(Op0, Op1);
std::swap(Op0Opc, Op1Opc);
Fold more shifts into inserts, and update the README llvm-svn: 28168
2006-05-09 01:38:32 +08:00
std::swap(TargetMask, InsertMask);
New rlwimi implementation, which is superior to the old one. There are still a couple missed optimizations, but we now generate all the possible rlwimis for multiple inserts into the same bitfield. More regression tests to come. llvm-svn: 28156
2006-05-07 08:23:38 +08:00
}
}
Fold more shifts into inserts, and update the README llvm-svn: 28168
2006-05-09 01:38:32 +08:00
} else if (Op0Opc == ISD::SHL || Op0Opc == ISD::SRL) {
if (Op1Opc == ISD::AND && Op1.getOperand(0).getOpcode() != ISD::SHL &&
Op1.getOperand(0).getOpcode() != ISD::SRL) {
std::swap(Op0, Op1);
std::swap(Op0Opc, Op1Opc);
std::swap(TargetMask, InsertMask);
}
ISD::OR, and it's accompanying SelectBitfieldInsert llvm-svn: 22889
2005-08-19 08:38:14 +08:00
}
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
New rlwimi implementation, which is superior to the old one. There are still a couple missed optimizations, but we now generate all the possible rlwimis for multiple inserts into the same bitfield. More regression tests to come. llvm-svn: 28156
2006-05-07 08:23:38 +08:00
unsigned MB, ME;
PPCDAGToDAGISel::isRunOfOnes should return false on zero This fixes a bug (found by csmith) at -O0 where we attempt to create a RLWIMI with an out-of-range operand. Most uses of the isRunOfOnes function are guarded by a condition that the value is not zero. This was not true in two places, and in both places a zero input would result in an out-of-rage MB value (= 32). To fix this, isRunOfOnes returns false on a zero input (and I've remove one now-redundant guard). llvm-svn: 186101
2013-07-12 00:31:51 +08:00
if (isRunOfOnes(InsertMask, MB, ME)) {
Remove an incorrect overaggressive optimization (PPC specific). llvm-svn: 89496
2009-11-21 06:16:40 +08:00
SDValue Tmp1, Tmp2;
New rlwimi implementation, which is superior to the old one. There are still a couple missed optimizations, but we now generate all the possible rlwimis for multiple inserts into the same bitfield. More regression tests to come. llvm-svn: 28156
2006-05-07 08:23:38 +08:00
if ((Op1Opc == ISD::SHL || Op1Opc == ISD::SRL) &&
Implement a bunch of 64-bit cleanliness work. With this, treeadd builds (but doesn't work right). llvm-svn: 28921
2006-06-27 08:04:13 +08:00
isInt32Immediate(Op1.getOperand(1), Value)) {
New rlwimi implementation, which is superior to the old one. There are still a couple missed optimizations, but we now generate all the possible rlwimis for multiple inserts into the same bitfield. More regression tests to come. llvm-svn: 28156
2006-05-07 08:23:38 +08:00
Op1 = Op1.getOperand(0);
SH = (Op1Opc == ISD::SHL) ? Value : 32 - Value;
ISD::OR, and it's accompanying SelectBitfieldInsert llvm-svn: 22889
2005-08-19 08:38:14 +08:00
}
New rlwimi implementation, which is superior to the old one. There are still a couple missed optimizations, but we now generate all the possible rlwimis for multiple inserts into the same bitfield. More regression tests to come. llvm-svn: 28156
2006-05-07 08:23:38 +08:00
if (Op1Opc == ISD::AND) {
[PowerPC] Fix rlwimi isel when mask is not constant We had been using the known-zero values of the operand of the or to construct the mask for an rlwimi; this is not quite correct, but fine when the mask is constant. When the mask is constant, then the known zeros of the operand must be a superset of the zeros in the mask. However, when the mask is not a constant, then there might be bits in the operand that are not known to be zero that, at runtime, might be zero in the mask. Therefore, we check that any bits not known to be zero *are* known to be one in the mask. Otherwise, we can't fold the mask with the or and shift. This was revealed as a miscompile of MultiSource/Benchmarks/BitBench/drop3/drop3 when I started experimenting with constant hoisting. llvm-svn: 206136
2014-04-14 01:10:58 +08:00
// The AND mask might not be a constant, and we need to make sure that
// if we're going to fold the masking with the insert, all bits not
// know to be zero in the mask are known to be one.
APInt MKZ, MKO;
Rename ComputeMaskedBits to computeKnownBits. "Masked" has been inappropriate since it lost its Mask parameter in r154011. llvm-svn: 208811
2014-05-15 05:14:37 +08:00
CurDAG->computeKnownBits(Op1.getOperand(1), MKZ, MKO);
[PowerPC] Fix rlwimi isel when mask is not constant We had been using the known-zero values of the operand of the or to construct the mask for an rlwimi; this is not quite correct, but fine when the mask is constant. When the mask is constant, then the known zeros of the operand must be a superset of the zeros in the mask. However, when the mask is not a constant, then there might be bits in the operand that are not known to be zero that, at runtime, might be zero in the mask. Therefore, we check that any bits not known to be zero *are* known to be one in the mask. Otherwise, we can't fold the mask with the or and shift. This was revealed as a miscompile of MultiSource/Benchmarks/BitBench/drop3/drop3 when I started experimenting with constant hoisting. llvm-svn: 206136
2014-04-14 01:10:58 +08:00
bool CanFoldMask = InsertMask == MKO.getZExtValue();
New rlwimi implementation, which is superior to the old one. There are still a couple missed optimizations, but we now generate all the possible rlwimis for multiple inserts into the same bitfield. More regression tests to come. llvm-svn: 28156
2006-05-07 08:23:38 +08:00
unsigned SHOpc = Op1.getOperand(0).getOpcode();
[PowerPC] Fix rlwimi isel when mask is not constant We had been using the known-zero values of the operand of the or to construct the mask for an rlwimi; this is not quite correct, but fine when the mask is constant. When the mask is constant, then the known zeros of the operand must be a superset of the zeros in the mask. However, when the mask is not a constant, then there might be bits in the operand that are not known to be zero that, at runtime, might be zero in the mask. Therefore, we check that any bits not known to be zero *are* known to be one in the mask. Otherwise, we can't fold the mask with the or and shift. This was revealed as a miscompile of MultiSource/Benchmarks/BitBench/drop3/drop3 when I started experimenting with constant hoisting. llvm-svn: 206136
2014-04-14 01:10:58 +08:00
if ((SHOpc == ISD::SHL || SHOpc == ISD::SRL) && CanFoldMask &&
Implement a bunch of 64-bit cleanliness work. With this, treeadd builds (but doesn't work right). llvm-svn: 28921
2006-06-27 08:04:13 +08:00
isInt32Immediate(Op1.getOperand(0).getOperand(1), Value)) {
Fix typo in function name. llvm-svn: 208743
2014-05-14 08:31:15 +08:00
// Note that Value must be in range here (less than 32) because
// otherwise there would not be any bits set in InsertMask.
New rlwimi implementation, which is superior to the old one. There are still a couple missed optimizations, but we now generate all the possible rlwimis for multiple inserts into the same bitfield. More regression tests to come. llvm-svn: 28156
2006-05-07 08:23:38 +08:00
Op1 = Op1.getOperand(0).getOperand(0);
SH = (SHOpc == ISD::SHL) ? Value : 32 - Value;
}
ISD::OR, and it's accompanying SelectBitfieldInsert llvm-svn: 22889
2005-08-19 08:38:14 +08:00
}
Remove an incorrect overaggressive optimization (PPC specific). llvm-svn: 89496
2009-11-21 06:16:40 +08:00
Fix PowerPC/2006-05-12-rlwimi-crash.ll Nate, please verify that if InsertMask is 0, rlwimi shouldn't be used. This fixes the crash and causes no PPC testsuite regressions. llvm-svn: 28243
2006-05-13 00:29:37 +08:00
SH &= 31;
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
SDValue Ops[] = { Op0, Op1, getI32Imm(SH, dl), getI32Imm(MB, dl),
getI32Imm(ME, dl) };
ArrayRefize getMachineNode(). No functionality change. llvm-svn: 179901
2013-04-20 06:22:57 +08:00
return CurDAG->getMachineNode(PPC::RLWIMI, dl, MVT::i32, Ops);
ISD::OR, and it's accompanying SelectBitfieldInsert llvm-svn: 22889
2005-08-19 08:38:14 +08:00
}
}
[C++] Use 'nullptr'. Target edition. llvm-svn: 207197
2014-04-25 13:30:21 +08:00
return nullptr;
ISD::OR, and it's accompanying SelectBitfieldInsert llvm-svn: 22889
2005-08-19 08:38:14 +08:00
}
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
// Predict the number of instructions that would be generated by calling
// SelectInt64(N).
[PowerPC] Materialize i64 constants using bit inversion Materializing full 64-bit constants on PPC64 can be expensive, requiring up to 5 instructions depending on the locations of the non-zero bits. Sometimes materializing the bit-reversed constant, and then flipping the bits, requires fewer instructions than the direct method. If so, do that instead. llvm-svn: 225132
2015-01-04 20:35:03 +08:00
static unsigned SelectInt64CountDirect(int64_t Imm) {
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
// Assume no remaining bits.
unsigned Remainder = 0;
// Assume no shift required.
unsigned Shift = 0;
// If it can't be represented as a 32 bit value.
if (!isInt<32>(Imm)) {
Shift = countTrailingZeros<uint64_t>(Imm);
int64_t ImmSh = static_cast<uint64_t>(Imm) >> Shift;
// If the shifted value fits 32 bits.
if (isInt<32>(ImmSh)) {
// Go with the shifted value.
Imm = ImmSh;
} else {
// Still stuck with a 64 bit value.
Remainder = Imm;
Shift = 32;
Imm >>= 32;
}
}
// Intermediate operand.
unsigned Result = 0;
// Handle first 32 bits.
unsigned Lo = Imm & 0xFFFF;
// Simple value.
if (isInt<16>(Imm)) {
// Just the Lo bits.
++Result;
} else if (Lo) {
// Handle the Hi bits and Lo bits.
Result += 2;
} else {
// Just the Hi bits.
++Result;
}
// If no shift, we're done.
if (!Shift) return Result;
// Shift for next step if the upper 32-bits were not zero.
if (Imm)
++Result;
// Add in the last bits as required.
[PowerPC] Remove redundant code. The local variable Hi is never being read. Issue identified by the Clang static analyzer. llvm-svn: 252600
2015-11-10 20:29:37 +08:00
if ((Remainder >> 16) & 0xFFFF)
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
++Result;
[PowerPC] Remove redundant code. The local variable Hi is never being read. Issue identified by the Clang static analyzer. llvm-svn: 252600
2015-11-10 20:29:37 +08:00
if (Remainder & 0xFFFF)
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
++Result;
return Result;
}
[PowerPC] Materialize i64 constants using rotation Materializing full 64-bit constants on PPC64 can be expensive, requiring up to 5 instructions depending on the locations of the non-zero bits. Sometimes materializing a rotated constant, and then applying the inverse rotation, requires fewer instructions than the direct method. If so, do that instead. In r225132, I added support for forming constants using bit inversion. In effect, this reverts that commit and replaces it with rotation support. The bit inversion is useful for turning constants that are mostly ones into ones that are mostly zeros (thus enabling a more-efficient shift-based materialization), but the same effect can be obtained by using negative constants and a rotate, and that is at least as efficient, if not more. llvm-svn: 225135
2015-01-04 23:43:55 +08:00
static uint64_t Rot64(uint64_t Imm, unsigned R) {
return (Imm << R) | (Imm >> (64 - R));
}
[PowerPC] Materialize i64 constants using bit inversion Materializing full 64-bit constants on PPC64 can be expensive, requiring up to 5 instructions depending on the locations of the non-zero bits. Sometimes materializing the bit-reversed constant, and then flipping the bits, requires fewer instructions than the direct method. If so, do that instead. llvm-svn: 225132
2015-01-04 20:35:03 +08:00
static unsigned SelectInt64Count(int64_t Imm) {
[PowerPC] Materialize i64 constants using rotation Materializing full 64-bit constants on PPC64 can be expensive, requiring up to 5 instructions depending on the locations of the non-zero bits. Sometimes materializing a rotated constant, and then applying the inverse rotation, requires fewer instructions than the direct method. If so, do that instead. In r225132, I added support for forming constants using bit inversion. In effect, this reverts that commit and replaces it with rotation support. The bit inversion is useful for turning constants that are mostly ones into ones that are mostly zeros (thus enabling a more-efficient shift-based materialization), but the same effect can be obtained by using negative constants and a rotate, and that is at least as efficient, if not more. llvm-svn: 225135
2015-01-04 23:43:55 +08:00
unsigned Count = SelectInt64CountDirect(Imm);
[PowerPC] Materialize i64 constants using rotation with masking r225135 added the ability to materialize i64 constants using rotations in order to reduce the instruction count. Sometimes we can use a rotation only with some extra masking, so that we take advantage of the fact that generating a bunch of extra higher-order 1 bits is easy using li/lis. llvm-svn: 225147
2015-01-05 11:41:38 +08:00
if (Count == 1)
return Count;
[PowerPC] Materialize i64 constants using bit inversion Materializing full 64-bit constants on PPC64 can be expensive, requiring up to 5 instructions depending on the locations of the non-zero bits. Sometimes materializing the bit-reversed constant, and then flipping the bits, requires fewer instructions than the direct method. If so, do that instead. llvm-svn: 225132
2015-01-04 20:35:03 +08:00
[PowerPC] Materialize i64 constants using rotation Materializing full 64-bit constants on PPC64 can be expensive, requiring up to 5 instructions depending on the locations of the non-zero bits. Sometimes materializing a rotated constant, and then applying the inverse rotation, requires fewer instructions than the direct method. If so, do that instead. In r225132, I added support for forming constants using bit inversion. In effect, this reverts that commit and replaces it with rotation support. The bit inversion is useful for turning constants that are mostly ones into ones that are mostly zeros (thus enabling a more-efficient shift-based materialization), but the same effect can be obtained by using negative constants and a rotate, and that is at least as efficient, if not more. llvm-svn: 225135
2015-01-04 23:43:55 +08:00
for (unsigned r = 1; r < 63; ++r) {
[PowerPC] Materialize i64 constants using rotation with masking r225135 added the ability to materialize i64 constants using rotations in order to reduce the instruction count. Sometimes we can use a rotation only with some extra masking, so that we take advantage of the fact that generating a bunch of extra higher-order 1 bits is easy using li/lis. llvm-svn: 225147
2015-01-05 11:41:38 +08:00
uint64_t RImm = Rot64(Imm, r);
unsigned RCount = SelectInt64CountDirect(RImm) + 1;
Count = std::min(Count, RCount);
// See comments in SelectInt64 for an explanation of the logic below.
unsigned LS = findLastSet(RImm);
if (LS != r-1)
continue;
uint64_t OnesMask = -(int64_t) (UINT64_C(1) << (LS+1));
uint64_t RImmWithOnes = RImm | OnesMask;
RCount = SelectInt64CountDirect(RImmWithOnes) + 1;
[PowerPC] Materialize i64 constants using rotation Materializing full 64-bit constants on PPC64 can be expensive, requiring up to 5 instructions depending on the locations of the non-zero bits. Sometimes materializing a rotated constant, and then applying the inverse rotation, requires fewer instructions than the direct method. If so, do that instead. In r225132, I added support for forming constants using bit inversion. In effect, this reverts that commit and replaces it with rotation support. The bit inversion is useful for turning constants that are mostly ones into ones that are mostly zeros (thus enabling a more-efficient shift-based materialization), but the same effect can be obtained by using negative constants and a rotate, and that is at least as efficient, if not more. llvm-svn: 225135
2015-01-04 23:43:55 +08:00
Count = std::min(Count, RCount);
}
[PowerPC] Materialize i64 constants using bit inversion Materializing full 64-bit constants on PPC64 can be expensive, requiring up to 5 instructions depending on the locations of the non-zero bits. Sometimes materializing the bit-reversed constant, and then flipping the bits, requires fewer instructions than the direct method. If so, do that instead. llvm-svn: 225132
2015-01-04 20:35:03 +08:00
[PowerPC] Materialize i64 constants using rotation Materializing full 64-bit constants on PPC64 can be expensive, requiring up to 5 instructions depending on the locations of the non-zero bits. Sometimes materializing a rotated constant, and then applying the inverse rotation, requires fewer instructions than the direct method. If so, do that instead. In r225132, I added support for forming constants using bit inversion. In effect, this reverts that commit and replaces it with rotation support. The bit inversion is useful for turning constants that are mostly ones into ones that are mostly zeros (thus enabling a more-efficient shift-based materialization), but the same effect can be obtained by using negative constants and a rotate, and that is at least as efficient, if not more. llvm-svn: 225135
2015-01-04 23:43:55 +08:00
return Count;
[PowerPC] Materialize i64 constants using bit inversion Materializing full 64-bit constants on PPC64 can be expensive, requiring up to 5 instructions depending on the locations of the non-zero bits. Sometimes materializing the bit-reversed constant, and then flipping the bits, requires fewer instructions than the direct method. If so, do that instead. llvm-svn: 225132
2015-01-04 20:35:03 +08:00
}
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
// Select a 64-bit constant. For cost-modeling purposes, SelectInt64Count
// (above) needs to be kept in sync with this function.
[PowerPC] Materialize i64 constants using bit inversion Materializing full 64-bit constants on PPC64 can be expensive, requiring up to 5 instructions depending on the locations of the non-zero bits. Sometimes materializing the bit-reversed constant, and then flipping the bits, requires fewer instructions than the direct method. If so, do that instead. llvm-svn: 225132
2015-01-04 20:35:03 +08:00
static SDNode *SelectInt64Direct(SelectionDAG *CurDAG, SDLoc dl, int64_t Imm) {
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
// Assume no remaining bits.
unsigned Remainder = 0;
// Assume no shift required.
unsigned Shift = 0;
// If it can't be represented as a 32 bit value.
if (!isInt<32>(Imm)) {
Shift = countTrailingZeros<uint64_t>(Imm);
int64_t ImmSh = static_cast<uint64_t>(Imm) >> Shift;
// If the shifted value fits 32 bits.
if (isInt<32>(ImmSh)) {
// Go with the shifted value.
Imm = ImmSh;
} else {
// Still stuck with a 64 bit value.
Remainder = Imm;
Shift = 32;
Imm >>= 32;
}
}
// Intermediate operand.
SDNode *Result;
// Handle first 32 bits.
unsigned Lo = Imm & 0xFFFF;
unsigned Hi = (Imm >> 16) & 0xFFFF;
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
auto getI32Imm = [CurDAG, dl](unsigned Imm) {
return CurDAG->getTargetConstant(Imm, dl, MVT::i32);
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
};
// Simple value.
if (isInt<16>(Imm)) {
// Just the Lo bits.
Result = CurDAG->getMachineNode(PPC::LI8, dl, MVT::i64, getI32Imm(Lo));
} else if (Lo) {
// Handle the Hi bits.
unsigned OpC = Hi ? PPC::LIS8 : PPC::LI8;
Result = CurDAG->getMachineNode(OpC, dl, MVT::i64, getI32Imm(Hi));
// And Lo bits.
Result = CurDAG->getMachineNode(PPC::ORI8, dl, MVT::i64,
SDValue(Result, 0), getI32Imm(Lo));
} else {
// Just the Hi bits.
Result = CurDAG->getMachineNode(PPC::LIS8, dl, MVT::i64, getI32Imm(Hi));
}
// If no shift, we're done.
if (!Shift) return Result;
// Shift for next step if the upper 32-bits were not zero.
if (Imm) {
Result = CurDAG->getMachineNode(PPC::RLDICR, dl, MVT::i64,
SDValue(Result, 0),
getI32Imm(Shift),
getI32Imm(63 - Shift));
}
// Add in the last bits as required.
if ((Hi = (Remainder >> 16) & 0xFFFF)) {
Result = CurDAG->getMachineNode(PPC::ORIS8, dl, MVT::i64,
SDValue(Result, 0), getI32Imm(Hi));
}
if ((Lo = Remainder & 0xFFFF)) {
Result = CurDAG->getMachineNode(PPC::ORI8, dl, MVT::i64,
SDValue(Result, 0), getI32Imm(Lo));
}
return Result;
}
[PowerPC] Materialize i64 constants using bit inversion Materializing full 64-bit constants on PPC64 can be expensive, requiring up to 5 instructions depending on the locations of the non-zero bits. Sometimes materializing the bit-reversed constant, and then flipping the bits, requires fewer instructions than the direct method. If so, do that instead. llvm-svn: 225132
2015-01-04 20:35:03 +08:00
static SDNode *SelectInt64(SelectionDAG *CurDAG, SDLoc dl, int64_t Imm) {
[PowerPC] Materialize i64 constants using rotation Materializing full 64-bit constants on PPC64 can be expensive, requiring up to 5 instructions depending on the locations of the non-zero bits. Sometimes materializing a rotated constant, and then applying the inverse rotation, requires fewer instructions than the direct method. If so, do that instead. In r225132, I added support for forming constants using bit inversion. In effect, this reverts that commit and replaces it with rotation support. The bit inversion is useful for turning constants that are mostly ones into ones that are mostly zeros (thus enabling a more-efficient shift-based materialization), but the same effect can be obtained by using negative constants and a rotate, and that is at least as efficient, if not more. llvm-svn: 225135
2015-01-04 23:43:55 +08:00
unsigned Count = SelectInt64CountDirect(Imm);
[PowerPC] Materialize i64 constants using rotation with masking r225135 added the ability to materialize i64 constants using rotations in order to reduce the instruction count. Sometimes we can use a rotation only with some extra masking, so that we take advantage of the fact that generating a bunch of extra higher-order 1 bits is easy using li/lis. llvm-svn: 225147
2015-01-05 11:41:38 +08:00
if (Count == 1)
return SelectInt64Direct(CurDAG, dl, Imm);
[PowerPC] Materialize i64 constants using rotation Materializing full 64-bit constants on PPC64 can be expensive, requiring up to 5 instructions depending on the locations of the non-zero bits. Sometimes materializing a rotated constant, and then applying the inverse rotation, requires fewer instructions than the direct method. If so, do that instead. In r225132, I added support for forming constants using bit inversion. In effect, this reverts that commit and replaces it with rotation support. The bit inversion is useful for turning constants that are mostly ones into ones that are mostly zeros (thus enabling a more-efficient shift-based materialization), but the same effect can be obtained by using negative constants and a rotate, and that is at least as efficient, if not more. llvm-svn: 225135
2015-01-04 23:43:55 +08:00
unsigned RMin = 0;
[PowerPC] Materialize i64 constants using rotation with masking r225135 added the ability to materialize i64 constants using rotations in order to reduce the instruction count. Sometimes we can use a rotation only with some extra masking, so that we take advantage of the fact that generating a bunch of extra higher-order 1 bits is easy using li/lis. llvm-svn: 225147
2015-01-05 11:41:38 +08:00
int64_t MatImm;
unsigned MaskEnd;
[PowerPC] Materialize i64 constants using rotation Materializing full 64-bit constants on PPC64 can be expensive, requiring up to 5 instructions depending on the locations of the non-zero bits. Sometimes materializing a rotated constant, and then applying the inverse rotation, requires fewer instructions than the direct method. If so, do that instead. In r225132, I added support for forming constants using bit inversion. In effect, this reverts that commit and replaces it with rotation support. The bit inversion is useful for turning constants that are mostly ones into ones that are mostly zeros (thus enabling a more-efficient shift-based materialization), but the same effect can be obtained by using negative constants and a rotate, and that is at least as efficient, if not more. llvm-svn: 225135
2015-01-04 23:43:55 +08:00
for (unsigned r = 1; r < 63; ++r) {
[PowerPC] Materialize i64 constants using rotation with masking r225135 added the ability to materialize i64 constants using rotations in order to reduce the instruction count. Sometimes we can use a rotation only with some extra masking, so that we take advantage of the fact that generating a bunch of extra higher-order 1 bits is easy using li/lis. llvm-svn: 225147
2015-01-05 11:41:38 +08:00
uint64_t RImm = Rot64(Imm, r);
unsigned RCount = SelectInt64CountDirect(RImm) + 1;
if (RCount < Count) {
Count = RCount;
RMin = r;
MatImm = RImm;
MaskEnd = 63;
}
// If the immediate to generate has many trailing zeros, it might be
// worthwhile to generate a rotated value with too many leading ones
// (because that's free with li/lis's sign-extension semantics), and then
// mask them off after rotation.
unsigned LS = findLastSet(RImm);
// We're adding (63-LS) higher-order ones, and we expect to mask them off
// after performing the inverse rotation by (64-r). So we need that:
// 63-LS == 64-r => LS == r-1
if (LS != r-1)
continue;
uint64_t OnesMask = -(int64_t) (UINT64_C(1) << (LS+1));
uint64_t RImmWithOnes = RImm | OnesMask;
RCount = SelectInt64CountDirect(RImmWithOnes) + 1;
[PowerPC] Materialize i64 constants using rotation Materializing full 64-bit constants on PPC64 can be expensive, requiring up to 5 instructions depending on the locations of the non-zero bits. Sometimes materializing a rotated constant, and then applying the inverse rotation, requires fewer instructions than the direct method. If so, do that instead. In r225132, I added support for forming constants using bit inversion. In effect, this reverts that commit and replaces it with rotation support. The bit inversion is useful for turning constants that are mostly ones into ones that are mostly zeros (thus enabling a more-efficient shift-based materialization), but the same effect can be obtained by using negative constants and a rotate, and that is at least as efficient, if not more. llvm-svn: 225135
2015-01-04 23:43:55 +08:00
if (RCount < Count) {
Count = RCount;
RMin = r;
[PowerPC] Materialize i64 constants using rotation with masking r225135 added the ability to materialize i64 constants using rotations in order to reduce the instruction count. Sometimes we can use a rotation only with some extra masking, so that we take advantage of the fact that generating a bunch of extra higher-order 1 bits is easy using li/lis. llvm-svn: 225147
2015-01-05 11:41:38 +08:00
MatImm = RImmWithOnes;
MaskEnd = LS;
[PowerPC] Materialize i64 constants using rotation Materializing full 64-bit constants on PPC64 can be expensive, requiring up to 5 instructions depending on the locations of the non-zero bits. Sometimes materializing a rotated constant, and then applying the inverse rotation, requires fewer instructions than the direct method. If so, do that instead. In r225132, I added support for forming constants using bit inversion. In effect, this reverts that commit and replaces it with rotation support. The bit inversion is useful for turning constants that are mostly ones into ones that are mostly zeros (thus enabling a more-efficient shift-based materialization), but the same effect can be obtained by using negative constants and a rotate, and that is at least as efficient, if not more. llvm-svn: 225135
2015-01-04 23:43:55 +08:00
}
[PowerPC] Materialize i64 constants using bit inversion Materializing full 64-bit constants on PPC64 can be expensive, requiring up to 5 instructions depending on the locations of the non-zero bits. Sometimes materializing the bit-reversed constant, and then flipping the bits, requires fewer instructions than the direct method. If so, do that instead. llvm-svn: 225132
2015-01-04 20:35:03 +08:00
}
[PowerPC] Materialize i64 constants using rotation Materializing full 64-bit constants on PPC64 can be expensive, requiring up to 5 instructions depending on the locations of the non-zero bits. Sometimes materializing a rotated constant, and then applying the inverse rotation, requires fewer instructions than the direct method. If so, do that instead. In r225132, I added support for forming constants using bit inversion. In effect, this reverts that commit and replaces it with rotation support. The bit inversion is useful for turning constants that are mostly ones into ones that are mostly zeros (thus enabling a more-efficient shift-based materialization), but the same effect can be obtained by using negative constants and a rotate, and that is at least as efficient, if not more. llvm-svn: 225135
2015-01-04 23:43:55 +08:00
if (!RMin)
return SelectInt64Direct(CurDAG, dl, Imm);
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
auto getI32Imm = [CurDAG, dl](unsigned Imm) {
return CurDAG->getTargetConstant(Imm, dl, MVT::i32);
[PowerPC] Materialize i64 constants using rotation Materializing full 64-bit constants on PPC64 can be expensive, requiring up to 5 instructions depending on the locations of the non-zero bits. Sometimes materializing a rotated constant, and then applying the inverse rotation, requires fewer instructions than the direct method. If so, do that instead. In r225132, I added support for forming constants using bit inversion. In effect, this reverts that commit and replaces it with rotation support. The bit inversion is useful for turning constants that are mostly ones into ones that are mostly zeros (thus enabling a more-efficient shift-based materialization), but the same effect can be obtained by using negative constants and a rotate, and that is at least as efficient, if not more. llvm-svn: 225135
2015-01-04 23:43:55 +08:00
};
[PowerPC] Materialize i64 constants using rotation with masking r225135 added the ability to materialize i64 constants using rotations in order to reduce the instruction count. Sometimes we can use a rotation only with some extra masking, so that we take advantage of the fact that generating a bunch of extra higher-order 1 bits is easy using li/lis. llvm-svn: 225147
2015-01-05 11:41:38 +08:00
SDValue Val = SDValue(SelectInt64Direct(CurDAG, dl, MatImm), 0);
return CurDAG->getMachineNode(PPC::RLDICR, dl, MVT::i64, Val,
getI32Imm(64 - RMin), getI32Imm(MaskEnd));
[PowerPC] Materialize i64 constants using bit inversion Materializing full 64-bit constants on PPC64 can be expensive, requiring up to 5 instructions depending on the locations of the non-zero bits. Sometimes materializing the bit-reversed constant, and then flipping the bits, requires fewer instructions than the direct method. If so, do that instead. llvm-svn: 225132
2015-01-04 20:35:03 +08:00
}
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
// Select a 64-bit constant.
static SDNode *SelectInt64(SelectionDAG *CurDAG, SDNode *N) {
SDLoc dl(N);
// Get 64 bit value.
int64_t Imm = cast<ConstantSDNode>(N)->getZExtValue();
return SelectInt64(CurDAG, dl, Imm);
}
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
namespace {
class BitPermutationSelector {
struct ValueBit {
SDValue V;
// The bit number in the value, using a convention where bit 0 is the
// lowest-order bit.
unsigned Idx;
enum Kind {
ConstZero,
Variable
} K;
ValueBit(SDValue V, unsigned I, Kind K = Variable)
: V(V), Idx(I), K(K) {}
ValueBit(Kind K = Variable)
: V(SDValue(nullptr, 0)), Idx(UINT32_MAX), K(K) {}
bool isZero() const {
return K == ConstZero;
}
bool hasValue() const {
return K == Variable;
}
SDValue getValue() const {
assert(hasValue() && "Cannot get the value of a constant bit");
return V;
}
unsigned getValueBitIndex() const {
assert(hasValue() && "Cannot get the value bit index of a constant bit");
return Idx;
}
};
// A bit group has the same underlying value and the same rotate factor.
struct BitGroup {
SDValue V;
unsigned RLAmt;
unsigned StartIdx, EndIdx;
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
// This rotation amount assumes that the lower 32 bits of the quantity are
// replicated in the high 32 bits by the rotation operator (which is done
// by rlwinm and friends in 64-bit mode).
bool Repl32;
// Did converting to Repl32 == true change the rotation factor? If it did,
// it decreased it by 32.
bool Repl32CR;
// Was this group coalesced after setting Repl32 to true?
bool Repl32Coalesced;
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
BitGroup(SDValue V, unsigned R, unsigned S, unsigned E)
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
: V(V), RLAmt(R), StartIdx(S), EndIdx(E), Repl32(false), Repl32CR(false),
Repl32Coalesced(false) {
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
DEBUG(dbgs() << "\tbit group for " << V.getNode() << " RLAmt = " << R <<
" [" << S << ", " << E << "]\n");
}
};
// Information on each (Value, RLAmt) pair (like the number of groups
// associated with each) used to choose the lowering method.
struct ValueRotInfo {
SDValue V;
unsigned RLAmt;
unsigned NumGroups;
unsigned FirstGroupStartIdx;
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
bool Repl32;
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
ValueRotInfo()
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
: RLAmt(UINT32_MAX), NumGroups(0), FirstGroupStartIdx(UINT32_MAX),
Repl32(false) {}
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
// For sorting (in reverse order) by NumGroups, and then by
// FirstGroupStartIdx.
bool operator < (const ValueRotInfo &Other) const {
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
// We need to sort so that the non-Repl32 come first because, when we're
// doing masking, the Repl32 bit groups might be subsumed into the 64-bit
// masking operation.
if (Repl32 < Other.Repl32)
return true;
else if (Repl32 > Other.Repl32)
return false;
else if (NumGroups > Other.NumGroups)
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
return true;
else if (NumGroups < Other.NumGroups)
return false;
else if (FirstGroupStartIdx < Other.FirstGroupStartIdx)
return true;
return false;
}
};
// Return true if something interesting was deduced, return false if we're
// providing only a generic representation of V (or something else likewise
// uninteresting for instruction selection).
bool getValueBits(SDValue V, SmallVector<ValueBit, 64> &Bits) {
switch (V.getOpcode()) {
default: break;
case ISD::ROTL:
if (isa<ConstantSDNode>(V.getOperand(1))) {
unsigned RotAmt = V.getConstantOperandVal(1);
SmallVector<ValueBit, 64> LHSBits(Bits.size());
getValueBits(V.getOperand(0), LHSBits);
for (unsigned i = 0; i < Bits.size(); ++i)
Bits[i] = LHSBits[i < RotAmt ? i + (Bits.size() - RotAmt) : i - RotAmt];
return true;
}
break;
case ISD::SHL:
if (isa<ConstantSDNode>(V.getOperand(1))) {
unsigned ShiftAmt = V.getConstantOperandVal(1);
SmallVector<ValueBit, 64> LHSBits(Bits.size());
getValueBits(V.getOperand(0), LHSBits);
for (unsigned i = ShiftAmt; i < Bits.size(); ++i)
Bits[i] = LHSBits[i - ShiftAmt];
for (unsigned i = 0; i < ShiftAmt; ++i)
Bits[i] = ValueBit(ValueBit::ConstZero);
return true;
}
break;
case ISD::SRL:
if (isa<ConstantSDNode>(V.getOperand(1))) {
unsigned ShiftAmt = V.getConstantOperandVal(1);
SmallVector<ValueBit, 64> LHSBits(Bits.size());
getValueBits(V.getOperand(0), LHSBits);
for (unsigned i = 0; i < Bits.size() - ShiftAmt; ++i)
Bits[i] = LHSBits[i + ShiftAmt];
for (unsigned i = Bits.size() - ShiftAmt; i < Bits.size(); ++i)
Bits[i] = ValueBit(ValueBit::ConstZero);
return true;
}
break;
case ISD::AND:
if (isa<ConstantSDNode>(V.getOperand(1))) {
uint64_t Mask = V.getConstantOperandVal(1);
SmallVector<ValueBit, 64> LHSBits(Bits.size());
bool LHSTrivial = getValueBits(V.getOperand(0), LHSBits);
for (unsigned i = 0; i < Bits.size(); ++i)
if (((Mask >> i) & 1) == 1)
Bits[i] = LHSBits[i];
else
Bits[i] = ValueBit(ValueBit::ConstZero);
// Mark this as interesting, only if the LHS was also interesting. This
// prevents the overall procedure from matching a single immediate 'and'
// (which is non-optimal because such an and might be folded with other
// things if we don't select it here).
return LHSTrivial;
}
break;
case ISD::OR: {
SmallVector<ValueBit, 64> LHSBits(Bits.size()), RHSBits(Bits.size());
getValueBits(V.getOperand(0), LHSBits);
getValueBits(V.getOperand(1), RHSBits);
bool AllDisjoint = true;
for (unsigned i = 0; i < Bits.size(); ++i)
if (LHSBits[i].isZero())
Bits[i] = RHSBits[i];
else if (RHSBits[i].isZero())
Bits[i] = LHSBits[i];
else {
AllDisjoint = false;
break;
}
if (!AllDisjoint)
break;
return true;
}
}
for (unsigned i = 0; i < Bits.size(); ++i)
Bits[i] = ValueBit(V, i);
return false;
}
// For each value (except the constant ones), compute the left-rotate amount
// to get it from its original to final position.
void computeRotationAmounts() {
HasZeros = false;
RLAmt.resize(Bits.size());
for (unsigned i = 0; i < Bits.size(); ++i)
if (Bits[i].hasValue()) {
unsigned VBI = Bits[i].getValueBitIndex();
if (i >= VBI)
RLAmt[i] = i - VBI;
else
RLAmt[i] = Bits.size() - (VBI - i);
} else if (Bits[i].isZero()) {
HasZeros = true;
RLAmt[i] = UINT32_MAX;
} else {
llvm_unreachable("Unknown value bit type");
}
}
// Collect groups of consecutive bits with the same underlying value and
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
// rotation factor. If we're doing late masking, we ignore zeros, otherwise
// they break up groups.
void collectBitGroups(bool LateMask) {
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
BitGroups.clear();
unsigned LastRLAmt = RLAmt[0];
SDValue LastValue = Bits[0].hasValue() ? Bits[0].getValue() : SDValue();
unsigned LastGroupStartIdx = 0;
for (unsigned i = 1; i < Bits.size(); ++i) {
unsigned ThisRLAmt = RLAmt[i];
SDValue ThisValue = Bits[i].hasValue() ? Bits[i].getValue() : SDValue();
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
if (LateMask && !ThisValue) {
ThisValue = LastValue;
ThisRLAmt = LastRLAmt;
// If we're doing late masking, then the first bit group always starts
// at zero (even if the first bits were zero).
if (BitGroups.empty())
LastGroupStartIdx = 0;
}
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
// If this bit has the same underlying value and the same rotate factor as
// the last one, then they're part of the same group.
if (ThisRLAmt == LastRLAmt && ThisValue == LastValue)
continue;
if (LastValue.getNode())
BitGroups.push_back(BitGroup(LastValue, LastRLAmt, LastGroupStartIdx,
i-1));
LastRLAmt = ThisRLAmt;
LastValue = ThisValue;
LastGroupStartIdx = i;
}
if (LastValue.getNode())
BitGroups.push_back(BitGroup(LastValue, LastRLAmt, LastGroupStartIdx,
Bits.size()-1));
if (BitGroups.empty())
return;
// We might be able to combine the first and last groups.
if (BitGroups.size() > 1) {
// If the first and last groups are the same, then remove the first group
// in favor of the last group, making the ending index of the last group
// equal to the ending index of the to-be-removed first group.
if (BitGroups[0].StartIdx == 0 &&
BitGroups[BitGroups.size()-1].EndIdx == Bits.size()-1 &&
BitGroups[0].V == BitGroups[BitGroups.size()-1].V &&
BitGroups[0].RLAmt == BitGroups[BitGroups.size()-1].RLAmt) {
Fix some comment typos. llvm-svn: 244402
2015-08-09 02:27:36 +08:00
DEBUG(dbgs() << "\tcombining final bit group with initial one\n");
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
BitGroups[BitGroups.size()-1].EndIdx = BitGroups[0].EndIdx;
BitGroups.erase(BitGroups.begin());
}
}
}
// Take all (SDValue, RLAmt) pairs and sort them by the number of groups
// associated with each. If there is a degeneracy, pick the one that occurs
// first (in the final value).
void collectValueRotInfo() {
ValueRots.clear();
for (auto &BG : BitGroups) {
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
unsigned RLAmtKey = BG.RLAmt + (BG.Repl32 ? 64 : 0);
ValueRotInfo &VRI = ValueRots[std::make_pair(BG.V, RLAmtKey)];
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
VRI.V = BG.V;
VRI.RLAmt = BG.RLAmt;
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
VRI.Repl32 = BG.Repl32;
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
VRI.NumGroups += 1;
VRI.FirstGroupStartIdx = std::min(VRI.FirstGroupStartIdx, BG.StartIdx);
}
// Now that we've collected the various ValueRotInfo instances, we need to
// sort them.
ValueRotsVec.clear();
for (auto &I : ValueRots) {
ValueRotsVec.push_back(I.second);
}
std::sort(ValueRotsVec.begin(), ValueRotsVec.end());
}
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
// In 64-bit mode, rlwinm and friends have a rotation operator that
// replicates the low-order 32 bits into the high-order 32-bits. The mask
// indices of these instructions can only be in the lower 32 bits, so they
// can only represent some 64-bit bit groups. However, when they can be used,
// the 32-bit replication can be used to represent, as a single bit group,
// otherwise separate bit groups. We'll convert to replicated-32-bit bit
// groups when possible. Returns true if any of the bit groups were
// converted.
void assignRepl32BitGroups() {
// If we have bits like this:
//
// Indices: 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0
// V bits: ... 7 6 5 4 3 2 1 0 31 30 29 28 27 26 25 24
// Groups: | RLAmt = 8 | RLAmt = 40 |
//
// But, making use of a 32-bit operation that replicates the low-order 32
// bits into the high-order 32 bits, this can be one bit group with a RLAmt
// of 8.
auto IsAllLow32 = [this](BitGroup & BG) {
if (BG.StartIdx <= BG.EndIdx) {
for (unsigned i = BG.StartIdx; i <= BG.EndIdx; ++i) {
if (!Bits[i].hasValue())
continue;
if (Bits[i].getValueBitIndex() >= 32)
return false;
}
} else {
for (unsigned i = BG.StartIdx; i < Bits.size(); ++i) {
if (!Bits[i].hasValue())
continue;
if (Bits[i].getValueBitIndex() >= 32)
return false;
}
for (unsigned i = 0; i <= BG.EndIdx; ++i) {
if (!Bits[i].hasValue())
continue;
if (Bits[i].getValueBitIndex() >= 32)
return false;
}
}
return true;
};
for (auto &BG : BitGroups) {
if (BG.StartIdx < 32 && BG.EndIdx < 32) {
if (IsAllLow32(BG)) {
if (BG.RLAmt >= 32) {
BG.RLAmt -= 32;
BG.Repl32CR = true;
}
BG.Repl32 = true;
DEBUG(dbgs() << "\t32-bit replicated bit group for " <<
BG.V.getNode() << " RLAmt = " << BG.RLAmt <<
" [" << BG.StartIdx << ", " << BG.EndIdx << "]\n");
}
}
}
// Now walk through the bit groups, consolidating where possible.
for (auto I = BitGroups.begin(); I != BitGroups.end();) {
// We might want to remove this bit group by merging it with the previous
// group (which might be the ending group).
auto IP = (I == BitGroups.begin()) ?
std::prev(BitGroups.end()) : std::prev(I);
if (I->Repl32 && IP->Repl32 && I->V == IP->V && I->RLAmt == IP->RLAmt &&
I->StartIdx == (IP->EndIdx + 1) % 64 && I != IP) {
DEBUG(dbgs() << "\tcombining 32-bit replicated bit group for " <<
I->V.getNode() << " RLAmt = " << I->RLAmt <<
" [" << I->StartIdx << ", " << I->EndIdx <<
"] with group with range [" <<
IP->StartIdx << ", " << IP->EndIdx << "]\n");
IP->EndIdx = I->EndIdx;
IP->Repl32CR = IP->Repl32CR || I->Repl32CR;
IP->Repl32Coalesced = true;
I = BitGroups.erase(I);
continue;
} else {
// There is a special case worth handling: If there is a single group
// covering the entire upper 32 bits, and it can be merged with both
// the next and previous groups (which might be the same group), then
// do so. If it is the same group (so there will be only one group in
// total), then we need to reverse the order of the range so that it
// covers the entire 64 bits.
if (I->StartIdx == 32 && I->EndIdx == 63) {
assert(std::next(I) == BitGroups.end() &&
"bit group ends at index 63 but there is another?");
auto IN = BitGroups.begin();
if (IP->Repl32 && IN->Repl32 && I->V == IP->V && I->V == IN->V &&
(I->RLAmt % 32) == IP->RLAmt && (I->RLAmt % 32) == IN->RLAmt &&
IP->EndIdx == 31 && IN->StartIdx == 0 && I != IP &&
IsAllLow32(*I)) {
DEBUG(dbgs() << "\tcombining bit group for " <<
I->V.getNode() << " RLAmt = " << I->RLAmt <<
" [" << I->StartIdx << ", " << I->EndIdx <<
"] with 32-bit replicated groups with ranges [" <<
IP->StartIdx << ", " << IP->EndIdx << "] and [" <<
IN->StartIdx << ", " << IN->EndIdx << "]\n");
if (IP == IN) {
// There is only one other group; change it to cover the whole
// range (backward, so that it can still be Repl32 but cover the
// whole 64-bit range).
IP->StartIdx = 31;
IP->EndIdx = 30;
IP->Repl32CR = IP->Repl32CR || I->RLAmt >= 32;
IP->Repl32Coalesced = true;
I = BitGroups.erase(I);
} else {
// There are two separate groups, one before this group and one
// after us (at the beginning). We're going to remove this group,
// but also the group at the very beginning.
IP->EndIdx = IN->EndIdx;
IP->Repl32CR = IP->Repl32CR || IN->Repl32CR || I->RLAmt >= 32;
IP->Repl32Coalesced = true;
I = BitGroups.erase(I);
BitGroups.erase(BitGroups.begin());
}
// This must be the last group in the vector (and we might have
// just invalidated the iterator above), so break here.
break;
}
}
}
++I;
}
}
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
SDValue getI32Imm(unsigned Imm, SDLoc dl) {
return CurDAG->getTargetConstant(Imm, dl, MVT::i32);
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
}
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
uint64_t getZerosMask() {
uint64_t Mask = 0;
for (unsigned i = 0; i < Bits.size(); ++i) {
if (Bits[i].hasValue())
continue;
[PowerPC] use UINT64_C instead of ul Attempting to fix PR22078 (building on 32-bit systems) by replacing my careless use of 1ul to be a uint64_t constant with UINT64_C(1). llvm-svn: 225066
2015-01-02 03:33:59 +08:00
Mask |= (UINT64_C(1) << i);
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
}
return ~Mask;
}
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
// Depending on the number of groups for a particular value, it might be
// better to rotate, mask explicitly (using andi/andis), and then or the
// result. Select this part of the result first.
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
void SelectAndParts32(SDLoc dl, SDValue &Res, unsigned *InstCnt) {
if (BPermRewriterNoMasking)
return;
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
for (ValueRotInfo &VRI : ValueRotsVec) {
unsigned Mask = 0;
for (unsigned i = 0; i < Bits.size(); ++i) {
if (!Bits[i].hasValue() || Bits[i].getValue() != VRI.V)
continue;
if (RLAmt[i] != VRI.RLAmt)
continue;
Mask |= (1u << i);
}
// Compute the masks for andi/andis that would be necessary.
unsigned ANDIMask = (Mask & UINT16_MAX), ANDISMask = Mask >> 16;
assert((ANDIMask != 0 || ANDISMask != 0) &&
"No set bits in mask for value bit groups");
bool NeedsRotate = VRI.RLAmt != 0;
// We're trying to minimize the number of instructions. If we have one
// group, using one of andi/andis can break even. If we have three
// groups, we can use both andi and andis and break even (to use both
// andi and andis we also need to or the results together). We need four
// groups if we also need to rotate. To use andi/andis we need to do more
// than break even because rotate-and-mask instructions tend to be easier
// to schedule.
// FIXME: We've biased here against using andi/andis, which is right for
// POWER cores, but not optimal everywhere. For example, on the A2,
// andi/andis have single-cycle latency whereas the rotate-and-mask
// instructions take two cycles, and it would be better to bias toward
// andi/andis in break-even cases.
unsigned NumAndInsts = (unsigned) NeedsRotate +
(unsigned) (ANDIMask != 0) +
(unsigned) (ANDISMask != 0) +
(unsigned) (ANDIMask != 0 && ANDISMask != 0) +
(unsigned) (bool) Res;
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
DEBUG(dbgs() << "\t\trotation groups for " << VRI.V.getNode() <<
" RL: " << VRI.RLAmt << ":" <<
"\n\t\t\tisel using masking: " << NumAndInsts <<
" using rotates: " << VRI.NumGroups << "\n");
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
if (NumAndInsts >= VRI.NumGroups)
continue;
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
DEBUG(dbgs() << "\t\t\t\tusing masking\n");
if (InstCnt) *InstCnt += NumAndInsts;
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
SDValue VRot;
if (VRI.RLAmt) {
SDValue Ops[] =
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
{ VRI.V, getI32Imm(VRI.RLAmt, dl), getI32Imm(0, dl),
getI32Imm(31, dl) };
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
VRot = SDValue(CurDAG->getMachineNode(PPC::RLWINM, dl, MVT::i32,
Ops), 0);
} else {
VRot = VRI.V;
}
SDValue ANDIVal, ANDISVal;
if (ANDIMask != 0)
ANDIVal = SDValue(CurDAG->getMachineNode(PPC::ANDIo, dl, MVT::i32,
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
VRot, getI32Imm(ANDIMask, dl)), 0);
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
if (ANDISMask != 0)
ANDISVal = SDValue(CurDAG->getMachineNode(PPC::ANDISo, dl, MVT::i32,
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
VRot, getI32Imm(ANDISMask, dl)), 0);
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
SDValue TotalVal;
if (!ANDIVal)
TotalVal = ANDISVal;
else if (!ANDISVal)
TotalVal = ANDIVal;
else
TotalVal = SDValue(CurDAG->getMachineNode(PPC::OR, dl, MVT::i32,
ANDIVal, ANDISVal), 0);
if (!Res)
Res = TotalVal;
else
Res = SDValue(CurDAG->getMachineNode(PPC::OR, dl, MVT::i32,
Res, TotalVal), 0);
// Now, remove all groups with this underlying value and rotation
// factor.
[PPC] Factor vector removal into a function and remove O(n^2) behavior. No functionality change intended. llvm-svn: 240222
2015-06-20 23:59:41 +08:00
eraseMatchingBitGroups([VRI](const BitGroup &BG) {
return BG.V == VRI.V && BG.RLAmt == VRI.RLAmt;
});
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
}
}
// Instruction selection for the 32-bit case.
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
SDNode *Select32(SDNode *N, bool LateMask, unsigned *InstCnt) {
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
SDLoc dl(N);
SDValue Res;
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
if (InstCnt) *InstCnt = 0;
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
// Take care of cases that should use andi/andis first.
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
SelectAndParts32(dl, Res, InstCnt);
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
// If we've not yet selected a 'starting' instruction, and we have no zeros
// to fill in, select the (Value, RLAmt) with the highest priority (largest
// number of groups), and start with this rotated value.
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
if ((!HasZeros || LateMask) && !Res) {
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
ValueRotInfo &VRI = ValueRotsVec[0];
if (VRI.RLAmt) {
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
if (InstCnt) *InstCnt += 1;
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
SDValue Ops[] =
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
{ VRI.V, getI32Imm(VRI.RLAmt, dl), getI32Imm(0, dl),
getI32Imm(31, dl) };
Res = SDValue(CurDAG->getMachineNode(PPC::RLWINM, dl, MVT::i32, Ops),
0);
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
} else {
Res = VRI.V;
}
// Now, remove all groups with this underlying value and rotation factor.
[PPC] Factor vector removal into a function and remove O(n^2) behavior. No functionality change intended. llvm-svn: 240222
2015-06-20 23:59:41 +08:00
eraseMatchingBitGroups([VRI](const BitGroup &BG) {
return BG.V == VRI.V && BG.RLAmt == VRI.RLAmt;
});
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
}
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
if (InstCnt) *InstCnt += BitGroups.size();
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
// Insert the other groups (one at a time).
for (auto &BG : BitGroups) {
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
if (!Res) {
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
SDValue Ops[] =
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
{ BG.V, getI32Imm(BG.RLAmt, dl),
getI32Imm(Bits.size() - BG.EndIdx - 1, dl),
getI32Imm(Bits.size() - BG.StartIdx - 1, dl) };
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
Res = SDValue(CurDAG->getMachineNode(PPC::RLWINM, dl, MVT::i32, Ops), 0);
} else {
SDValue Ops[] =
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
{ Res, BG.V, getI32Imm(BG.RLAmt, dl),
getI32Imm(Bits.size() - BG.EndIdx - 1, dl),
getI32Imm(Bits.size() - BG.StartIdx - 1, dl) };
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
Res = SDValue(CurDAG->getMachineNode(PPC::RLWIMI, dl, MVT::i32, Ops), 0);
}
}
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
if (LateMask) {
unsigned Mask = (unsigned) getZerosMask();
unsigned ANDIMask = (Mask & UINT16_MAX), ANDISMask = Mask >> 16;
assert((ANDIMask != 0 || ANDISMask != 0) &&
"No set bits in zeros mask?");
if (InstCnt) *InstCnt += (unsigned) (ANDIMask != 0) +
(unsigned) (ANDISMask != 0) +
(unsigned) (ANDIMask != 0 && ANDISMask != 0);
SDValue ANDIVal, ANDISVal;
if (ANDIMask != 0)
ANDIVal = SDValue(CurDAG->getMachineNode(PPC::ANDIo, dl, MVT::i32,
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
Res, getI32Imm(ANDIMask, dl)), 0);
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
if (ANDISMask != 0)
ANDISVal = SDValue(CurDAG->getMachineNode(PPC::ANDISo, dl, MVT::i32,
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
Res, getI32Imm(ANDISMask, dl)), 0);
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
if (!ANDIVal)
Res = ANDISVal;
else if (!ANDISVal)
Res = ANDIVal;
else
Res = SDValue(CurDAG->getMachineNode(PPC::OR, dl, MVT::i32,
ANDIVal, ANDISVal), 0);
}
return Res.getNode();
}
unsigned SelectRotMask64Count(unsigned RLAmt, bool Repl32,
unsigned MaskStart, unsigned MaskEnd,
bool IsIns) {
// In the notation used by the instructions, 'start' and 'end' are reversed
// because bits are counted from high to low order.
unsigned InstMaskStart = 64 - MaskEnd - 1,
InstMaskEnd = 64 - MaskStart - 1;
if (Repl32)
return 1;
if ((!IsIns && (InstMaskEnd == 63 || InstMaskStart == 0)) ||
InstMaskEnd == 63 - RLAmt)
return 1;
return 2;
}
// For 64-bit values, not all combinations of rotates and masks are
// available. Produce one if it is available.
SDValue SelectRotMask64(SDValue V, SDLoc dl, unsigned RLAmt, bool Repl32,
unsigned MaskStart, unsigned MaskEnd,
unsigned *InstCnt = nullptr) {
// In the notation used by the instructions, 'start' and 'end' are reversed
// because bits are counted from high to low order.
unsigned InstMaskStart = 64 - MaskEnd - 1,
InstMaskEnd = 64 - MaskStart - 1;
if (InstCnt) *InstCnt += 1;
if (Repl32) {
// This rotation amount assumes that the lower 32 bits of the quantity
// are replicated in the high 32 bits by the rotation operator (which is
// done by rlwinm and friends).
assert(InstMaskStart >= 32 && "Mask cannot start out of range");
assert(InstMaskEnd >= 32 && "Mask cannot end out of range");
SDValue Ops[] =
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
{ V, getI32Imm(RLAmt, dl), getI32Imm(InstMaskStart - 32, dl),
getI32Imm(InstMaskEnd - 32, dl) };
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
return SDValue(CurDAG->getMachineNode(PPC::RLWINM8, dl, MVT::i64,
Ops), 0);
}
if (InstMaskEnd == 63) {
SDValue Ops[] =
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
{ V, getI32Imm(RLAmt, dl), getI32Imm(InstMaskStart, dl) };
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
return SDValue(CurDAG->getMachineNode(PPC::RLDICL, dl, MVT::i64, Ops), 0);
}
if (InstMaskStart == 0) {
SDValue Ops[] =
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
{ V, getI32Imm(RLAmt, dl), getI32Imm(InstMaskEnd, dl) };
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
return SDValue(CurDAG->getMachineNode(PPC::RLDICR, dl, MVT::i64, Ops), 0);
}
if (InstMaskEnd == 63 - RLAmt) {
SDValue Ops[] =
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
{ V, getI32Imm(RLAmt, dl), getI32Imm(InstMaskStart, dl) };
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
return SDValue(CurDAG->getMachineNode(PPC::RLDIC, dl, MVT::i64, Ops), 0);
}
// We cannot do this with a single instruction, so we'll use two. The
// problem is that we're not free to choose both a rotation amount and mask
// start and end independently. We can choose an arbitrary mask start and
// end, but then the rotation amount is fixed. Rotation, however, can be
// inverted, and so by applying an "inverse" rotation first, we can get the
// desired result.
if (InstCnt) *InstCnt += 1;
// The rotation mask for the second instruction must be MaskStart.
unsigned RLAmt2 = MaskStart;
// The first instruction must rotate V so that the overall rotation amount
// is RLAmt.
unsigned RLAmt1 = (64 + RLAmt - RLAmt2) % 64;
if (RLAmt1)
V = SelectRotMask64(V, dl, RLAmt1, false, 0, 63);
return SelectRotMask64(V, dl, RLAmt2, false, MaskStart, MaskEnd);
}
// For 64-bit values, not all combinations of rotates and masks are
// available. Produce a rotate-mask-and-insert if one is available.
SDValue SelectRotMaskIns64(SDValue Base, SDValue V, SDLoc dl, unsigned RLAmt,
bool Repl32, unsigned MaskStart,
unsigned MaskEnd, unsigned *InstCnt = nullptr) {
// In the notation used by the instructions, 'start' and 'end' are reversed
// because bits are counted from high to low order.
unsigned InstMaskStart = 64 - MaskEnd - 1,
InstMaskEnd = 64 - MaskStart - 1;
if (InstCnt) *InstCnt += 1;
if (Repl32) {
// This rotation amount assumes that the lower 32 bits of the quantity
// are replicated in the high 32 bits by the rotation operator (which is
// done by rlwinm and friends).
assert(InstMaskStart >= 32 && "Mask cannot start out of range");
assert(InstMaskEnd >= 32 && "Mask cannot end out of range");
SDValue Ops[] =
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
{ Base, V, getI32Imm(RLAmt, dl), getI32Imm(InstMaskStart - 32, dl),
getI32Imm(InstMaskEnd - 32, dl) };
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
return SDValue(CurDAG->getMachineNode(PPC::RLWIMI8, dl, MVT::i64,
Ops), 0);
}
if (InstMaskEnd == 63 - RLAmt) {
SDValue Ops[] =
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
{ Base, V, getI32Imm(RLAmt, dl), getI32Imm(InstMaskStart, dl) };
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
return SDValue(CurDAG->getMachineNode(PPC::RLDIMI, dl, MVT::i64, Ops), 0);
}
// We cannot do this with a single instruction, so we'll use two. The
// problem is that we're not free to choose both a rotation amount and mask
// start and end independently. We can choose an arbitrary mask start and
// end, but then the rotation amount is fixed. Rotation, however, can be
// inverted, and so by applying an "inverse" rotation first, we can get the
// desired result.
if (InstCnt) *InstCnt += 1;
// The rotation mask for the second instruction must be MaskStart.
unsigned RLAmt2 = MaskStart;
// The first instruction must rotate V so that the overall rotation amount
// is RLAmt.
unsigned RLAmt1 = (64 + RLAmt - RLAmt2) % 64;
if (RLAmt1)
V = SelectRotMask64(V, dl, RLAmt1, false, 0, 63);
return SelectRotMaskIns64(Base, V, dl, RLAmt2, false, MaskStart, MaskEnd);
}
void SelectAndParts64(SDLoc dl, SDValue &Res, unsigned *InstCnt) {
if (BPermRewriterNoMasking)
return;
// The idea here is the same as in the 32-bit version, but with additional
// complications from the fact that Repl32 might be true. Because we
// aggressively convert bit groups to Repl32 form (which, for small
// rotation factors, involves no other change), and then coalesce, it might
// be the case that a single 64-bit masking operation could handle both
// some Repl32 groups and some non-Repl32 groups. If converting to Repl32
// form allowed coalescing, then we must use a 32-bit rotaton in order to
// completely capture the new combined bit group.
for (ValueRotInfo &VRI : ValueRotsVec) {
uint64_t Mask = 0;
// We need to add to the mask all bits from the associated bit groups.
// If Repl32 is false, we need to add bits from bit groups that have
// Repl32 true, but are trivially convertable to Repl32 false. Such a
// group is trivially convertable if it overlaps only with the lower 32
// bits, and the group has not been coalesced.
[PPC] Factor vector removal into a function and remove O(n^2) behavior. No functionality change intended. llvm-svn: 240222
2015-06-20 23:59:41 +08:00
auto MatchingBG = [VRI](const BitGroup &BG) {
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
if (VRI.V != BG.V)
return false;
unsigned EffRLAmt = BG.RLAmt;
if (!VRI.Repl32 && BG.Repl32) {
if (BG.StartIdx < 32 && BG.EndIdx < 32 && BG.StartIdx <= BG.EndIdx &&
!BG.Repl32Coalesced) {
if (BG.Repl32CR)
EffRLAmt += 32;
} else {
return false;
}
} else if (VRI.Repl32 != BG.Repl32) {
return false;
}
if (VRI.RLAmt != EffRLAmt)
return false;
return true;
};
for (auto &BG : BitGroups) {
if (!MatchingBG(BG))
continue;
if (BG.StartIdx <= BG.EndIdx) {
for (unsigned i = BG.StartIdx; i <= BG.EndIdx; ++i)
[PowerPC] use UINT64_C instead of ul Attempting to fix PR22078 (building on 32-bit systems) by replacing my careless use of 1ul to be a uint64_t constant with UINT64_C(1). llvm-svn: 225066
2015-01-02 03:33:59 +08:00
Mask |= (UINT64_C(1) << i);
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
} else {
for (unsigned i = BG.StartIdx; i < Bits.size(); ++i)
[PowerPC] use UINT64_C instead of ul Attempting to fix PR22078 (building on 32-bit systems) by replacing my careless use of 1ul to be a uint64_t constant with UINT64_C(1). llvm-svn: 225066
2015-01-02 03:33:59 +08:00
Mask |= (UINT64_C(1) << i);
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
for (unsigned i = 0; i <= BG.EndIdx; ++i)
[PowerPC] use UINT64_C instead of ul Attempting to fix PR22078 (building on 32-bit systems) by replacing my careless use of 1ul to be a uint64_t constant with UINT64_C(1). llvm-svn: 225066
2015-01-02 03:33:59 +08:00
Mask |= (UINT64_C(1) << i);
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
}
}
// We can use the 32-bit andi/andis technique if the mask does not
// require any higher-order bits. This can save an instruction compared
// to always using the general 64-bit technique.
bool Use32BitInsts = isUInt<32>(Mask);
// Compute the masks for andi/andis that would be necessary.
unsigned ANDIMask = (Mask & UINT16_MAX),
ANDISMask = (Mask >> 16) & UINT16_MAX;
bool NeedsRotate = VRI.RLAmt || (VRI.Repl32 && !isUInt<32>(Mask));
unsigned NumAndInsts = (unsigned) NeedsRotate +
(unsigned) (bool) Res;
if (Use32BitInsts)
NumAndInsts += (unsigned) (ANDIMask != 0) + (unsigned) (ANDISMask != 0) +
(unsigned) (ANDIMask != 0 && ANDISMask != 0);
else
NumAndInsts += SelectInt64Count(Mask) + /* and */ 1;
unsigned NumRLInsts = 0;
bool FirstBG = true;
for (auto &BG : BitGroups) {
if (!MatchingBG(BG))
continue;
NumRLInsts +=
SelectRotMask64Count(BG.RLAmt, BG.Repl32, BG.StartIdx, BG.EndIdx,
!FirstBG);
FirstBG = false;
}
DEBUG(dbgs() << "\t\trotation groups for " << VRI.V.getNode() <<
" RL: " << VRI.RLAmt << (VRI.Repl32 ? " (32):" : ":") <<
"\n\t\t\tisel using masking: " << NumAndInsts <<
" using rotates: " << NumRLInsts << "\n");
// When we'd use andi/andis, we bias toward using the rotates (andi only
// has a record form, and is cracked on POWER cores). However, when using
// general 64-bit constant formation, bias toward the constant form,
// because that exposes more opportunities for CSE.
if (NumAndInsts > NumRLInsts)
continue;
if (Use32BitInsts && NumAndInsts == NumRLInsts)
continue;
DEBUG(dbgs() << "\t\t\t\tusing masking\n");
if (InstCnt) *InstCnt += NumAndInsts;
SDValue VRot;
// We actually need to generate a rotation if we have a non-zero rotation
// factor or, in the Repl32 case, if we care about any of the
// higher-order replicated bits. In the latter case, we generate a mask
// backward so that it actually includes the entire 64 bits.
if (VRI.RLAmt || (VRI.Repl32 && !isUInt<32>(Mask)))
VRot = SelectRotMask64(VRI.V, dl, VRI.RLAmt, VRI.Repl32,
VRI.Repl32 ? 31 : 0, VRI.Repl32 ? 30 : 63);
else
VRot = VRI.V;
SDValue TotalVal;
if (Use32BitInsts) {
assert((ANDIMask != 0 || ANDISMask != 0) &&
"No set bits in mask when using 32-bit ands for 64-bit value");
SDValue ANDIVal, ANDISVal;
if (ANDIMask != 0)
ANDIVal = SDValue(CurDAG->getMachineNode(PPC::ANDIo8, dl, MVT::i64,
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
VRot, getI32Imm(ANDIMask, dl)), 0);
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
if (ANDISMask != 0)
ANDISVal = SDValue(CurDAG->getMachineNode(PPC::ANDISo8, dl, MVT::i64,
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
VRot, getI32Imm(ANDISMask, dl)), 0);
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
if (!ANDIVal)
TotalVal = ANDISVal;
else if (!ANDISVal)
TotalVal = ANDIVal;
else
TotalVal = SDValue(CurDAG->getMachineNode(PPC::OR8, dl, MVT::i64,
ANDIVal, ANDISVal), 0);
} else {
TotalVal = SDValue(SelectInt64(CurDAG, dl, Mask), 0);
TotalVal =
SDValue(CurDAG->getMachineNode(PPC::AND8, dl, MVT::i64,
VRot, TotalVal), 0);
}
if (!Res)
Res = TotalVal;
else
Res = SDValue(CurDAG->getMachineNode(PPC::OR8, dl, MVT::i64,
Res, TotalVal), 0);
// Now, remove all groups with this underlying value and rotation
// factor.
[PPC] Factor vector removal into a function and remove O(n^2) behavior. No functionality change intended. llvm-svn: 240222
2015-06-20 23:59:41 +08:00
eraseMatchingBitGroups(MatchingBG);
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
}
}
// Instruction selection for the 64-bit case.
SDNode *Select64(SDNode *N, bool LateMask, unsigned *InstCnt) {
SDLoc dl(N);
SDValue Res;
if (InstCnt) *InstCnt = 0;
// Take care of cases that should use andi/andis first.
SelectAndParts64(dl, Res, InstCnt);
// If we've not yet selected a 'starting' instruction, and we have no zeros
// to fill in, select the (Value, RLAmt) with the highest priority (largest
// number of groups), and start with this rotated value.
if ((!HasZeros || LateMask) && !Res) {
// If we have both Repl32 groups and non-Repl32 groups, the non-Repl32
// groups will come first, and so the VRI representing the largest number
// of groups might not be first (it might be the first Repl32 groups).
unsigned MaxGroupsIdx = 0;
if (!ValueRotsVec[0].Repl32) {
for (unsigned i = 0, ie = ValueRotsVec.size(); i < ie; ++i)
if (ValueRotsVec[i].Repl32) {
if (ValueRotsVec[i].NumGroups > ValueRotsVec[0].NumGroups)
MaxGroupsIdx = i;
break;
}
}
ValueRotInfo &VRI = ValueRotsVec[MaxGroupsIdx];
bool NeedsRotate = false;
if (VRI.RLAmt) {
NeedsRotate = true;
} else if (VRI.Repl32) {
for (auto &BG : BitGroups) {
if (BG.V != VRI.V || BG.RLAmt != VRI.RLAmt ||
BG.Repl32 != VRI.Repl32)
continue;
// We don't need a rotate if the bit group is confined to the lower
// 32 bits.
if (BG.StartIdx < 32 && BG.EndIdx < 32 && BG.StartIdx < BG.EndIdx)
continue;
NeedsRotate = true;
break;
}
}
if (NeedsRotate)
Res = SelectRotMask64(VRI.V, dl, VRI.RLAmt, VRI.Repl32,
VRI.Repl32 ? 31 : 0, VRI.Repl32 ? 30 : 63,
InstCnt);
else
Res = VRI.V;
// Now, remove all groups with this underlying value and rotation factor.
if (Res)
[PPC] Factor vector removal into a function and remove O(n^2) behavior. No functionality change intended. llvm-svn: 240222
2015-06-20 23:59:41 +08:00
eraseMatchingBitGroups([VRI](const BitGroup &BG) {
return BG.V == VRI.V && BG.RLAmt == VRI.RLAmt &&
BG.Repl32 == VRI.Repl32;
});
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
}
// Because 64-bit rotates are more flexible than inserts, we might have a
// preference regarding which one we do first (to save one instruction).
if (!Res)
for (auto I = BitGroups.begin(), IE = BitGroups.end(); I != IE; ++I) {
if (SelectRotMask64Count(I->RLAmt, I->Repl32, I->StartIdx, I->EndIdx,
false) <
SelectRotMask64Count(I->RLAmt, I->Repl32, I->StartIdx, I->EndIdx,
true)) {
if (I != BitGroups.begin()) {
BitGroup BG = *I;
BitGroups.erase(I);
BitGroups.insert(BitGroups.begin(), BG);
}
break;
}
}
// Insert the other groups (one at a time).
for (auto &BG : BitGroups) {
if (!Res)
Res = SelectRotMask64(BG.V, dl, BG.RLAmt, BG.Repl32, BG.StartIdx,
BG.EndIdx, InstCnt);
else
Res = SelectRotMaskIns64(Res, BG.V, dl, BG.RLAmt, BG.Repl32,
BG.StartIdx, BG.EndIdx, InstCnt);
}
if (LateMask) {
uint64_t Mask = getZerosMask();
// We can use the 32-bit andi/andis technique if the mask does not
// require any higher-order bits. This can save an instruction compared
// to always using the general 64-bit technique.
bool Use32BitInsts = isUInt<32>(Mask);
// Compute the masks for andi/andis that would be necessary.
unsigned ANDIMask = (Mask & UINT16_MAX),
ANDISMask = (Mask >> 16) & UINT16_MAX;
if (Use32BitInsts) {
assert((ANDIMask != 0 || ANDISMask != 0) &&
"No set bits in mask when using 32-bit ands for 64-bit value");
if (InstCnt) *InstCnt += (unsigned) (ANDIMask != 0) +
(unsigned) (ANDISMask != 0) +
(unsigned) (ANDIMask != 0 && ANDISMask != 0);
SDValue ANDIVal, ANDISVal;
if (ANDIMask != 0)
ANDIVal = SDValue(CurDAG->getMachineNode(PPC::ANDIo8, dl, MVT::i64,
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
Res, getI32Imm(ANDIMask, dl)), 0);
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
if (ANDISMask != 0)
ANDISVal = SDValue(CurDAG->getMachineNode(PPC::ANDISo8, dl, MVT::i64,
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
Res, getI32Imm(ANDISMask, dl)), 0);
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
if (!ANDIVal)
Res = ANDISVal;
else if (!ANDISVal)
Res = ANDIVal;
else
Res = SDValue(CurDAG->getMachineNode(PPC::OR8, dl, MVT::i64,
ANDIVal, ANDISVal), 0);
} else {
if (InstCnt) *InstCnt += SelectInt64Count(Mask) + /* and */ 1;
SDValue MaskVal = SDValue(SelectInt64(CurDAG, dl, Mask), 0);
Res =
SDValue(CurDAG->getMachineNode(PPC::AND8, dl, MVT::i64,
Res, MaskVal), 0);
}
}
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
return Res.getNode();
}
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
SDNode *Select(SDNode *N, bool LateMask, unsigned *InstCnt = nullptr) {
// Fill in BitGroups.
collectBitGroups(LateMask);
if (BitGroups.empty())
return nullptr;
// For 64-bit values, figure out when we can use 32-bit instructions.
if (Bits.size() == 64)
assignRepl32BitGroups();
// Fill in ValueRotsVec.
collectValueRotInfo();
if (Bits.size() == 32) {
return Select32(N, LateMask, InstCnt);
} else {
assert(Bits.size() == 64 && "Not 64 bits here?");
return Select64(N, LateMask, InstCnt);
}
return nullptr;
}
[PPC] Factor vector removal into a function and remove O(n^2) behavior. No functionality change intended. llvm-svn: 240222
2015-06-20 23:59:41 +08:00
void eraseMatchingBitGroups(function_ref<bool(const BitGroup &)> F) {
BitGroups.erase(std::remove_if(BitGroups.begin(), BitGroups.end(), F),
BitGroups.end());
}
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
SmallVector<ValueBit, 64> Bits;
bool HasZeros;
SmallVector<unsigned, 64> RLAmt;
SmallVector<BitGroup, 16> BitGroups;
DenseMap<std::pair<SDValue, unsigned>, ValueRotInfo> ValueRots;
SmallVector<ValueRotInfo, 16> ValueRotsVec;
SelectionDAG *CurDAG;
public:
BitPermutationSelector(SelectionDAG *DAG)
: CurDAG(DAG) {}
// Here we try to match complex bit permutations into a set of
// rotate-and-shift/shift/and/or instructions, using a set of heuristics
// known to produce optimial code for common cases (like i32 byte swapping).
SDNode *Select(SDNode *N) {
Bits.resize(N->getValueType(0).getSizeInBits());
if (!getValueBits(SDValue(N, 0), Bits))
return nullptr;
DEBUG(dbgs() << "Considering bit-permutation-based instruction"
" selection for: ");
DEBUG(N->dump(CurDAG));
// Fill it RLAmt and set HasZeros.
computeRotationAmounts();
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
if (!HasZeros)
return Select(N, false);
// We currently have two techniques for handling results with zeros: early
// masking (the default) and late masking. Late masking is sometimes more
// efficient, but because the structure of the bit groups is different, it
// is hard to tell without generating both and comparing the results. With
// late masking, we ignore zeros in the resulting value when inserting each
// set of bit groups, and then mask in the zeros at the end. With early
// masking, we only insert the non-zero parts of the result at every step.
unsigned InstCnt, InstCntLateMask;
DEBUG(dbgs() << "\tEarly masking:\n");
SDNode *RN = Select(N, false, &InstCnt);
DEBUG(dbgs() << "\t\tisel would use " << InstCnt << " instructions\n");
DEBUG(dbgs() << "\tLate masking:\n");
SDNode *RNLM = Select(N, true, &InstCntLateMask);
DEBUG(dbgs() << "\t\tisel would use " << InstCntLateMask <<
" instructions\n");
if (InstCnt <= InstCntLateMask) {
DEBUG(dbgs() << "\tUsing early-masking for isel\n");
return RN;
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
}
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
DEBUG(dbgs() << "\tUsing late-masking for isel\n");
return RNLM;
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
}
};
} // anonymous namespace
SDNode *PPCDAGToDAGISel::SelectBitPermutation(SDNode *N) {
if (N->getValueType(0) != MVT::i32 &&
N->getValueType(0) != MVT::i64)
return nullptr;
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
if (!UseBitPermRewriter)
return nullptr;
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
switch (N->getOpcode()) {
default: break;
case ISD::ROTL:
case ISD::SHL:
case ISD::SRL:
case ISD::AND:
case ISD::OR: {
BitPermutationSelector BPS(CurDAG);
return BPS.Select(N);
}
}
return nullptr;
}
Implement selection for branches. llvm-svn: 22951
2005-08-22 02:50:37 +08:00
/// SelectCC - Select a comparison of the specified values with the specified
/// condition code, returning the CR# of the expression.
Rename SDOperand to SDValue. llvm-svn: 54128
2008-07-28 05:46:04 +08:00
SDValue PPCDAGToDAGISel::SelectCC(SDValue LHS, SDValue RHS,
Track IR ordering of SelectionDAG nodes 2/4. Change SelectionDAG::getXXXNode() interfaces as well as call sites of these functions to pass in SDLoc instead of DebugLoc. llvm-svn: 182703
2013-05-25 10:42:55 +08:00
ISD::CondCode CC, SDLoc dl) {
Implement selection for branches. llvm-svn: 22951
2005-08-22 02:50:37 +08:00
// Always select the LHS.
Implement a bunch of 64-bit cleanliness work. With this, treeadd builds (but doesn't work right). llvm-svn: 28921
2006-06-27 08:04:13 +08:00
unsigned Opc;
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
Split EVT into MVT and EVT, the former representing _just_ a primitive type, while the latter is capable of representing either a primitive or an extended type. llvm-svn: 78713
2009-08-12 04:47:22 +08:00
if (LHS.getValueType() == MVT::i32) {
Fix variable shadowing issue llvm-svn: 28922
2006-06-27 08:10:13 +08:00
unsigned Imm;
Two improvements: 1. Codegen this comparison: if (X == 0x8000) as: cmplwi cr0, r3, 32768 bne cr0, LBB1_2 ;cond_next instead of: lis r2, 0 ori r2, r2, 32768 cmpw cr0, r3, r2 bne cr0, LBB1_2 ;cond_next 2. Codegen this comparison: if (X == 0x12345678) as: xoris r2, r3, 4660 cmplwi cr0, r2, 22136 bne cr0, LBB1_2 ;cond_next instead of: lis r2, 4660 ori r2, r2, 22136 cmpw cr0, r3, r2 bne cr0, LBB1_2 ;cond_next llvm-svn: 30509
2006-09-20 12:25:47 +08:00
if (CC == ISD::SETEQ || CC == ISD::SETNE) {
if (isInt32Immediate(RHS, Imm)) {
// SETEQ/SETNE comparison with 16-bit immediate, fold it.
Make isInt?? and isUint?? template specializations of the generic versions. This makes calls a little bit more consistent and allows easy removal of the specializations in the future. Convert all callers to the templated functions. llvm-svn: 99838
2010-03-30 05:13:41 +08:00
if (isUInt<16>(Imm))
Rename getTargetNode to getMachineNode, for consistency with the naming scheme used in SelectionDAG, where there are multiple kinds of "target" nodes, but "machine" nodes are nodes which represent a MachineInstr. llvm-svn: 82790
2009-09-26 02:54:59 +08:00
return SDValue(CurDAG->getMachineNode(PPC::CMPLWI, dl, MVT::i32, LHS,
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
getI32Imm(Imm & 0xFFFF, dl)),
0);
Two improvements: 1. Codegen this comparison: if (X == 0x8000) as: cmplwi cr0, r3, 32768 bne cr0, LBB1_2 ;cond_next instead of: lis r2, 0 ori r2, r2, 32768 cmpw cr0, r3, r2 bne cr0, LBB1_2 ;cond_next 2. Codegen this comparison: if (X == 0x12345678) as: xoris r2, r3, 4660 cmplwi cr0, r2, 22136 bne cr0, LBB1_2 ;cond_next instead of: lis r2, 4660 ori r2, r2, 22136 cmpw cr0, r3, r2 bne cr0, LBB1_2 ;cond_next llvm-svn: 30509
2006-09-20 12:25:47 +08:00
// If this is a 16-bit signed immediate, fold it.
Make isInt?? and isUint?? template specializations of the generic versions. This makes calls a little bit more consistent and allows easy removal of the specializations in the future. Convert all callers to the templated functions. llvm-svn: 99838
2010-03-30 05:13:41 +08:00
if (isInt<16>((int)Imm))
Rename getTargetNode to getMachineNode, for consistency with the naming scheme used in SelectionDAG, where there are multiple kinds of "target" nodes, but "machine" nodes are nodes which represent a MachineInstr. llvm-svn: 82790
2009-09-26 02:54:59 +08:00
return SDValue(CurDAG->getMachineNode(PPC::CMPWI, dl, MVT::i32, LHS,
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
getI32Imm(Imm & 0xFFFF, dl)),
0);
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
Two improvements: 1. Codegen this comparison: if (X == 0x8000) as: cmplwi cr0, r3, 32768 bne cr0, LBB1_2 ;cond_next instead of: lis r2, 0 ori r2, r2, 32768 cmpw cr0, r3, r2 bne cr0, LBB1_2 ;cond_next 2. Codegen this comparison: if (X == 0x12345678) as: xoris r2, r3, 4660 cmplwi cr0, r2, 22136 bne cr0, LBB1_2 ;cond_next instead of: lis r2, 4660 ori r2, r2, 22136 cmpw cr0, r3, r2 bne cr0, LBB1_2 ;cond_next llvm-svn: 30509
2006-09-20 12:25:47 +08:00
// For non-equality comparisons, the default code would materialize the
// constant, then compare against it, like this:
// lis r2, 4660
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
// ori r2, r2, 22136
Two improvements: 1. Codegen this comparison: if (X == 0x8000) as: cmplwi cr0, r3, 32768 bne cr0, LBB1_2 ;cond_next instead of: lis r2, 0 ori r2, r2, 32768 cmpw cr0, r3, r2 bne cr0, LBB1_2 ;cond_next 2. Codegen this comparison: if (X == 0x12345678) as: xoris r2, r3, 4660 cmplwi cr0, r2, 22136 bne cr0, LBB1_2 ;cond_next instead of: lis r2, 4660 ori r2, r2, 22136 cmpw cr0, r3, r2 bne cr0, LBB1_2 ;cond_next llvm-svn: 30509
2006-09-20 12:25:47 +08:00
// cmpw cr0, r3, r2
// Since we are just comparing for equality, we can emit this instead:
// xoris r0,r3,0x1234
// cmplwi cr0,r0,0x5678
// beq cr0,L6
Rename getTargetNode to getMachineNode, for consistency with the naming scheme used in SelectionDAG, where there are multiple kinds of "target" nodes, but "machine" nodes are nodes which represent a MachineInstr. llvm-svn: 82790
2009-09-26 02:54:59 +08:00
SDValue Xor(CurDAG->getMachineNode(PPC::XORIS, dl, MVT::i32, LHS,
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
getI32Imm(Imm >> 16, dl)), 0);
Rename getTargetNode to getMachineNode, for consistency with the naming scheme used in SelectionDAG, where there are multiple kinds of "target" nodes, but "machine" nodes are nodes which represent a MachineInstr. llvm-svn: 82790
2009-09-26 02:54:59 +08:00
return SDValue(CurDAG->getMachineNode(PPC::CMPLWI, dl, MVT::i32, Xor,
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
getI32Imm(Imm & 0xFFFF, dl)), 0);
Two improvements: 1. Codegen this comparison: if (X == 0x8000) as: cmplwi cr0, r3, 32768 bne cr0, LBB1_2 ;cond_next instead of: lis r2, 0 ori r2, r2, 32768 cmpw cr0, r3, r2 bne cr0, LBB1_2 ;cond_next 2. Codegen this comparison: if (X == 0x12345678) as: xoris r2, r3, 4660 cmplwi cr0, r2, 22136 bne cr0, LBB1_2 ;cond_next instead of: lis r2, 4660 ori r2, r2, 22136 cmpw cr0, r3, r2 bne cr0, LBB1_2 ;cond_next llvm-svn: 30509
2006-09-20 12:25:47 +08:00
}
Opc = PPC::CMPLW;
} else if (ISD::isUnsignedIntSetCC(CC)) {
Make isInt?? and isUint?? template specializations of the generic versions. This makes calls a little bit more consistent and allows easy removal of the specializations in the future. Convert all callers to the templated functions. llvm-svn: 99838
2010-03-30 05:13:41 +08:00
if (isInt32Immediate(RHS, Imm) && isUInt<16>(Imm))
Rename getTargetNode to getMachineNode, for consistency with the naming scheme used in SelectionDAG, where there are multiple kinds of "target" nodes, but "machine" nodes are nodes which represent a MachineInstr. llvm-svn: 82790
2009-09-26 02:54:59 +08:00
return SDValue(CurDAG->getMachineNode(PPC::CMPLWI, dl, MVT::i32, LHS,
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
getI32Imm(Imm & 0xFFFF, dl)), 0);
Implement a bunch of 64-bit cleanliness work. With this, treeadd builds (but doesn't work right). llvm-svn: 28921
2006-06-27 08:04:13 +08:00
Opc = PPC::CMPLW;
} else {
short SImm;
if (isIntS16Immediate(RHS, SImm))
Rename getTargetNode to getMachineNode, for consistency with the naming scheme used in SelectionDAG, where there are multiple kinds of "target" nodes, but "machine" nodes are nodes which represent a MachineInstr. llvm-svn: 82790
2009-09-26 02:54:59 +08:00
return SDValue(CurDAG->getMachineNode(PPC::CMPWI, dl, MVT::i32, LHS,
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
getI32Imm((int)SImm & 0xFFFF,
dl)),
Implement a bunch of 64-bit cleanliness work. With this, treeadd builds (but doesn't work right). llvm-svn: 28921
2006-06-27 08:04:13 +08:00
0);
Opc = PPC::CMPW;
}
Split EVT into MVT and EVT, the former representing _just_ a primitive type, while the latter is capable of representing either a primitive or an extended type. llvm-svn: 78713
2009-08-12 04:47:22 +08:00
} else if (LHS.getValueType() == MVT::i64) {
Implement a bunch of 64-bit cleanliness work. With this, treeadd builds (but doesn't work right). llvm-svn: 28921
2006-06-27 08:04:13 +08:00
uint64_t Imm;
Improve PPC64 equality comparisons like PPC32 comparisons. llvm-svn: 30510
2006-09-20 12:33:27 +08:00
if (CC == ISD::SETEQ || CC == ISD::SETNE) {
erect abstraction boundaries for accessing SDValue members, rename Val -> Node to reflect semantics llvm-svn: 55504
2008-08-29 05:40:38 +08:00
if (isInt64Immediate(RHS.getNode(), Imm)) {
Improve PPC64 equality comparisons like PPC32 comparisons. llvm-svn: 30510
2006-09-20 12:33:27 +08:00
// SETEQ/SETNE comparison with 16-bit immediate, fold it.
Make isInt?? and isUint?? template specializations of the generic versions. This makes calls a little bit more consistent and allows easy removal of the specializations in the future. Convert all callers to the templated functions. llvm-svn: 99838
2010-03-30 05:13:41 +08:00
if (isUInt<16>(Imm))
Rename getTargetNode to getMachineNode, for consistency with the naming scheme used in SelectionDAG, where there are multiple kinds of "target" nodes, but "machine" nodes are nodes which represent a MachineInstr. llvm-svn: 82790
2009-09-26 02:54:59 +08:00
return SDValue(CurDAG->getMachineNode(PPC::CMPLDI, dl, MVT::i64, LHS,
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
getI32Imm(Imm & 0xFFFF, dl)),
0);
Improve PPC64 equality comparisons like PPC32 comparisons. llvm-svn: 30510
2006-09-20 12:33:27 +08:00
// If this is a 16-bit signed immediate, fold it.
Make isInt?? and isUint?? template specializations of the generic versions. This makes calls a little bit more consistent and allows easy removal of the specializations in the future. Convert all callers to the templated functions. llvm-svn: 99838
2010-03-30 05:13:41 +08:00
if (isInt<16>(Imm))
Rename getTargetNode to getMachineNode, for consistency with the naming scheme used in SelectionDAG, where there are multiple kinds of "target" nodes, but "machine" nodes are nodes which represent a MachineInstr. llvm-svn: 82790
2009-09-26 02:54:59 +08:00
return SDValue(CurDAG->getMachineNode(PPC::CMPDI, dl, MVT::i64, LHS,
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
getI32Imm(Imm & 0xFFFF, dl)),
0);
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
Improve PPC64 equality comparisons like PPC32 comparisons. llvm-svn: 30510
2006-09-20 12:33:27 +08:00
// For non-equality comparisons, the default code would materialize the
// constant, then compare against it, like this:
// lis r2, 4660
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
// ori r2, r2, 22136
Improve PPC64 equality comparisons like PPC32 comparisons. llvm-svn: 30510
2006-09-20 12:33:27 +08:00
// cmpd cr0, r3, r2
// Since we are just comparing for equality, we can emit this instead:
// xoris r0,r3,0x1234
// cmpldi cr0,r0,0x5678
// beq cr0,L6
Make isInt?? and isUint?? template specializations of the generic versions. This makes calls a little bit more consistent and allows easy removal of the specializations in the future. Convert all callers to the templated functions. llvm-svn: 99838
2010-03-30 05:13:41 +08:00
if (isUInt<32>(Imm)) {
Rename getTargetNode to getMachineNode, for consistency with the naming scheme used in SelectionDAG, where there are multiple kinds of "target" nodes, but "machine" nodes are nodes which represent a MachineInstr. llvm-svn: 82790
2009-09-26 02:54:59 +08:00
SDValue Xor(CurDAG->getMachineNode(PPC::XORIS8, dl, MVT::i64, LHS,
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
getI64Imm(Imm >> 16, dl)), 0);
Rename getTargetNode to getMachineNode, for consistency with the naming scheme used in SelectionDAG, where there are multiple kinds of "target" nodes, but "machine" nodes are nodes which represent a MachineInstr. llvm-svn: 82790
2009-09-26 02:54:59 +08:00
return SDValue(CurDAG->getMachineNode(PPC::CMPLDI, dl, MVT::i64, Xor,
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
getI64Imm(Imm & 0xFFFF, dl)),
0);
Improve PPC64 equality comparisons like PPC32 comparisons. llvm-svn: 30510
2006-09-20 12:33:27 +08:00
}
}
Opc = PPC::CMPLD;
} else if (ISD::isUnsignedIntSetCC(CC)) {
Make isInt?? and isUint?? template specializations of the generic versions. This makes calls a little bit more consistent and allows easy removal of the specializations in the future. Convert all callers to the templated functions. llvm-svn: 99838
2010-03-30 05:13:41 +08:00
if (isInt64Immediate(RHS.getNode(), Imm) && isUInt<16>(Imm))
Rename getTargetNode to getMachineNode, for consistency with the naming scheme used in SelectionDAG, where there are multiple kinds of "target" nodes, but "machine" nodes are nodes which represent a MachineInstr. llvm-svn: 82790
2009-09-26 02:54:59 +08:00
return SDValue(CurDAG->getMachineNode(PPC::CMPLDI, dl, MVT::i64, LHS,
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
getI64Imm(Imm & 0xFFFF, dl)), 0);
Implement a bunch of 64-bit cleanliness work. With this, treeadd builds (but doesn't work right). llvm-svn: 28921
2006-06-27 08:04:13 +08:00
Opc = PPC::CMPLD;
} else {
short SImm;
if (isIntS16Immediate(RHS, SImm))
Rename getTargetNode to getMachineNode, for consistency with the naming scheme used in SelectionDAG, where there are multiple kinds of "target" nodes, but "machine" nodes are nodes which represent a MachineInstr. llvm-svn: 82790
2009-09-26 02:54:59 +08:00
return SDValue(CurDAG->getMachineNode(PPC::CMPDI, dl, MVT::i64, LHS,
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
getI64Imm(SImm & 0xFFFF, dl)),
Implement a bunch of 64-bit cleanliness work. With this, treeadd builds (but doesn't work right). llvm-svn: 28921
2006-06-27 08:04:13 +08:00
0);
Opc = PPC::CMPD;
}
Split EVT into MVT and EVT, the former representing _just_ a primitive type, while the latter is capable of representing either a primitive or an extended type. llvm-svn: 78713
2009-08-12 04:47:22 +08:00
} else if (LHS.getValueType() == MVT::f32) {
Implement a bunch of 64-bit cleanliness work. With this, treeadd builds (but doesn't work right). llvm-svn: 28921
2006-06-27 08:04:13 +08:00
Opc = PPC::FCMPUS;
Implement selection for branches. llvm-svn: 22951
2005-08-22 02:50:37 +08:00
} else {
Split EVT into MVT and EVT, the former representing _just_ a primitive type, while the latter is capable of representing either a primitive or an extended type. llvm-svn: 78713
2009-08-12 04:47:22 +08:00
assert(LHS.getValueType() == MVT::f64 && "Unknown vt!");
Reset the subtarget for DAGToDAG on every iteration of runOnMachineFunction. This required updating the generated functions and TD file accordingly to be pointers rather than const references. llvm-svn: 209375
2014-05-22 09:07:24 +08:00
Opc = PPCSubTarget->hasVSX() ? PPC::XSCMPUDP : PPC::FCMPUD;
Implement selection for branches. llvm-svn: 22951
2005-08-22 02:50:37 +08:00
}
Rename getTargetNode to getMachineNode, for consistency with the naming scheme used in SelectionDAG, where there are multiple kinds of "target" nodes, but "machine" nodes are nodes which represent a MachineInstr. llvm-svn: 82790
2009-09-26 02:54:59 +08:00
return SDValue(CurDAG->getMachineNode(Opc, dl, MVT::i32, LHS, RHS), 0);
Implement selection for branches. llvm-svn: 22951
2005-08-22 02:50:37 +08:00
}
start using PPC predicates more consistently. llvm-svn: 31833
2006-11-18 06:10:59 +08:00
static PPC::Predicate getPredicateForSetCC(ISD::CondCode CC) {
Implement selection for branches. llvm-svn: 22951
2005-08-22 02:50:37 +08:00
switch (CC) {
Fix Benchmarks/MallocBench/cfrac llvm-svn: 28471
2006-05-26 00:54:16 +08:00
case ISD::SETUEQ:
Make FP tests requiring two compares work on PPC (PR 642). This is Chris' patch from the PR, modified to realize that SETUGT/SETULT occur legitimately with integers, plus two fixes in LegalizeDAG to pass a valid result type into LegalizeSetCC. The argument of TLI.getSetCCResultType is ignored on PPC, but I think I'm following usage elsewhere. llvm-svn: 58871
2008-11-08 06:54:33 +08:00
case ISD::SETONE:
case ISD::SETOLE:
case ISD::SETOGE:
llvm_unreachable->llvm_unreachable(0), LLVM_UNREACHABLE->llvm_unreachable. This adds location info for all llvm_unreachable calls (which is a macro now) in !NDEBUG builds. In NDEBUG builds location info and the message is off (it only prints "UREACHABLE executed"). llvm-svn: 75640
2009-07-15 00:55:14 +08:00
llvm_unreachable("Should be lowered by legalize!");
default: llvm_unreachable("Unknown condition!");
Make FP tests requiring two compares work on PPC (PR 642). This is Chris' patch from the PR, modified to realize that SETUGT/SETULT occur legitimately with integers, plus two fixes in LegalizeDAG to pass a valid result type into LegalizeSetCC. The argument of TLI.getSetCCResultType is ignored on PPC, but I think I'm following usage elsewhere. llvm-svn: 58871
2008-11-08 06:54:33 +08:00
case ISD::SETOEQ:
start using PPC predicates more consistently. llvm-svn: 31833
2006-11-18 06:10:59 +08:00
case ISD::SETEQ: return PPC::PRED_EQ;
Fix Benchmarks/MallocBench/cfrac llvm-svn: 28471
2006-05-26 00:54:16 +08:00
case ISD::SETUNE:
start using PPC predicates more consistently. llvm-svn: 31833
2006-11-18 06:10:59 +08:00
case ISD::SETNE: return PPC::PRED_NE;
Make FP tests requiring two compares work on PPC (PR 642). This is Chris' patch from the PR, modified to realize that SETUGT/SETULT occur legitimately with integers, plus two fixes in LegalizeDAG to pass a valid result type into LegalizeSetCC. The argument of TLI.getSetCCResultType is ignored on PPC, but I think I'm following usage elsewhere. llvm-svn: 58871
2008-11-08 06:54:33 +08:00
case ISD::SETOLT:
start using PPC predicates more consistently. llvm-svn: 31833
2006-11-18 06:10:59 +08:00
case ISD::SETLT: return PPC::PRED_LT;
Implement selection for branches. llvm-svn: 22951
2005-08-22 02:50:37 +08:00
case ISD::SETULE:
start using PPC predicates more consistently. llvm-svn: 31833
2006-11-18 06:10:59 +08:00
case ISD::SETLE: return PPC::PRED_LE;
Make FP tests requiring two compares work on PPC (PR 642). This is Chris' patch from the PR, modified to realize that SETUGT/SETULT occur legitimately with integers, plus two fixes in LegalizeDAG to pass a valid result type into LegalizeSetCC. The argument of TLI.getSetCCResultType is ignored on PPC, but I think I'm following usage elsewhere. llvm-svn: 58871
2008-11-08 06:54:33 +08:00
case ISD::SETOGT:
start using PPC predicates more consistently. llvm-svn: 31833
2006-11-18 06:10:59 +08:00
case ISD::SETGT: return PPC::PRED_GT;
Implement selection for branches. llvm-svn: 22951
2005-08-22 02:50:37 +08:00
case ISD::SETUGE:
start using PPC predicates more consistently. llvm-svn: 31833
2006-11-18 06:10:59 +08:00
case ISD::SETGE: return PPC::PRED_GE;
case ISD::SETO: return PPC::PRED_NU;
case ISD::SETUO: return PPC::PRED_UN;
Make FP tests requiring two compares work on PPC (PR 642). This is Chris' patch from the PR, modified to realize that SETUGT/SETULT occur legitimately with integers, plus two fixes in LegalizeDAG to pass a valid result type into LegalizeSetCC. The argument of TLI.getSetCCResultType is ignored on PPC, but I think I'm following usage elsewhere. llvm-svn: 58871
2008-11-08 06:54:33 +08:00
// These two are invalid for floating point. Assume we have int.
case ISD::SETULT: return PPC::PRED_LT;
case ISD::SETUGT: return PPC::PRED_GT;
Implement selection for branches. llvm-svn: 22951
2005-08-22 02:50:37 +08:00
}
}
implement setcc on the G5. We're still missing the non-g5 specific bits, but they will come later. llvm-svn: 23059
2005-08-26 04:08:18 +08:00
/// getCRIdxForSetCC - Return the index of the condition register field
/// associated with the SetCC condition, and whether or not the field is
/// treated as inverted. That is, lt = 0; ge = 0 inverted.
[PowerPC] Remove dead code from PPCDAGToDAGISel::SelectSETCC The subroutine getCRIdxForSetCC has a parameter "Other" and comment: If this returns with Other != -1, then the returned comparison is an or of two simpler comparisons. However for at least the last five years this routine has never returned a value of Other != -1; these cases are now handled differently to begin with. This patch removes the parameter and the code in SelectSETCC that attempted to handle the Other != -1 case. llvm-svn: 185541
2013-07-03 23:13:30 +08:00
static unsigned getCRIdxForSetCC(ISD::CondCode CC, bool &Invert) {
Finally implement correct ordered comparisons for PPC, even though the code generated is not wonderful. This turns a miscompilation into a code quality bug (noted in the ppc readme). This fixes PR642, which is over 2 years old (!). Nate, please review this. llvm-svn: 45742
2008-01-08 14:46:30 +08:00
Invert = false;
implement setcc on the G5. We're still missing the non-g5 specific bits, but they will come later. llvm-svn: 23059
2005-08-26 04:08:18 +08:00
switch (CC) {
llvm_unreachable->llvm_unreachable(0), LLVM_UNREACHABLE->llvm_unreachable. This adds location info for all llvm_unreachable calls (which is a macro now) in !NDEBUG builds. In NDEBUG builds location info and the message is off (it only prints "UREACHABLE executed"). llvm-svn: 75640
2009-07-15 00:55:14 +08:00
default: llvm_unreachable("Unknown condition!");
Finally implement correct ordered comparisons for PPC, even though the code generated is not wonderful. This turns a miscompilation into a code quality bug (noted in the ppc readme). This fixes PR642, which is over 2 years old (!). Nate, please review this. llvm-svn: 45742
2008-01-08 14:46:30 +08:00
case ISD::SETOLT:
case ISD::SETLT: return 0; // Bit #0 = SETOLT
case ISD::SETOGT:
case ISD::SETGT: return 1; // Bit #1 = SETOGT
case ISD::SETOEQ:
case ISD::SETEQ: return 2; // Bit #2 = SETOEQ
case ISD::SETUO: return 3; // Bit #3 = SETUO
implement setcc on the G5. We're still missing the non-g5 specific bits, but they will come later. llvm-svn: 23059
2005-08-26 04:08:18 +08:00
case ISD::SETUGE:
Finally implement correct ordered comparisons for PPC, even though the code generated is not wonderful. This turns a miscompilation into a code quality bug (noted in the ppc readme). This fixes PR642, which is over 2 years old (!). Nate, please review this. llvm-svn: 45742
2008-01-08 14:46:30 +08:00
case ISD::SETGE: Invert = true; return 0; // !Bit #0 = SETUGE
implement setcc on the G5. We're still missing the non-g5 specific bits, but they will come later. llvm-svn: 23059
2005-08-26 04:08:18 +08:00
case ISD::SETULE:
Finally implement correct ordered comparisons for PPC, even though the code generated is not wonderful. This turns a miscompilation into a code quality bug (noted in the ppc readme). This fixes PR642, which is over 2 years old (!). Nate, please review this. llvm-svn: 45742
2008-01-08 14:46:30 +08:00
case ISD::SETLE: Invert = true; return 1; // !Bit #1 = SETULE
Fix build failure of povray llvm-svn: 28473
2006-05-26 02:06:16 +08:00
case ISD::SETUNE:
Finally implement correct ordered comparisons for PPC, even though the code generated is not wonderful. This turns a miscompilation into a code quality bug (noted in the ppc readme). This fixes PR642, which is over 2 years old (!). Nate, please review this. llvm-svn: 45742
2008-01-08 14:46:30 +08:00
case ISD::SETNE: Invert = true; return 2; // !Bit #2 = SETUNE
case ISD::SETO: Invert = true; return 3; // !Bit #3 = SETO
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
case ISD::SETUEQ:
case ISD::SETOGE:
case ISD::SETOLE:
Make FP tests requiring two compares work on PPC (PR 642). This is Chris' patch from the PR, modified to realize that SETUGT/SETULT occur legitimately with integers, plus two fixes in LegalizeDAG to pass a valid result type into LegalizeSetCC. The argument of TLI.getSetCCResultType is ignored on PPC, but I think I'm following usage elsewhere. llvm-svn: 58871
2008-11-08 06:54:33 +08:00
case ISD::SETONE:
llvm_unreachable->llvm_unreachable(0), LLVM_UNREACHABLE->llvm_unreachable. This adds location info for all llvm_unreachable calls (which is a macro now) in !NDEBUG builds. In NDEBUG builds location info and the message is off (it only prints "UREACHABLE executed"). llvm-svn: 75640
2009-07-15 00:55:14 +08:00
llvm_unreachable("Invalid branch code: should be expanded by legalize");
Make FP tests requiring two compares work on PPC (PR 642). This is Chris' patch from the PR, modified to realize that SETUGT/SETULT occur legitimately with integers, plus two fixes in LegalizeDAG to pass a valid result type into LegalizeSetCC. The argument of TLI.getSetCCResultType is ignored on PPC, but I think I'm following usage elsewhere. llvm-svn: 58871
2008-11-08 06:54:33 +08:00
// These are invalid for floating point. Assume integer.
case ISD::SETULT: return 0;
case ISD::SETUGT: return 1;
implement setcc on the G5. We're still missing the non-g5 specific bits, but they will come later. llvm-svn: 23059
2005-08-26 04:08:18 +08:00
}
}
Implement most of load support. There is still a bug though. llvm-svn: 22959
2005-08-22 06:31:09 +08:00
PowerPC: More support for Altivec compare operations This patch adds more support for vector type comparisons using altivec. It adds correct support for v16i8, v8i16, v4i32, and v4f32 vector types for comparison operators ==, !=, >, >=, <, and <=. llvm-svn: 167015
2012-10-30 21:50:19 +08:00
// getVCmpInst: return the vector compare instruction for the specified
// vector type and condition code. Since this is for altivec specific code,
Add the following 64-bit vector integer arithmetic instructions added in POWER8: vaddudm vsubudm vmulesw vmulosw vmuleuw vmulouw vmuluwm vmaxsd vmaxud vminsd vminud vcmpequd vcmpequd. vcmpgtsd vcmpgtsd. vcmpgtud vcmpgtud. vrld vsld vsrd vsrad Phabricator review: http://reviews.llvm.org/D7959 llvm-svn: 231115
2015-03-04 03:55:45 +08:00
// only support the altivec types (v16i8, v8i16, v4i32, v2i64, and v4f32).
[PowerPC] Fix and improve vector comparisons This patch refactors code generation of vector comparisons. This fixes a wrong code-gen bug for ISD::SETGE for floating-point types, and improves generated code for vector comparisons in general. Specifically, the patch moves all logic deciding how to implement vector comparisons into getVCmpInst, which gets two extra boolean outputs indicating to its caller whether its needs to swap the input operands and/or negate the result of the comparison. Apart from implementing these two modifications as directed by getVCmpInst, there is no need to ever implement vector comparisons in any other manner; in particular, there is never a need to perform two separate comparisons (e.g. one for equal and one for greater-than, as code used to do before this patch). Reviewed by Bill Schmidt. llvm-svn: 214714
2014-08-04 21:13:57 +08:00
static unsigned int getVCmpInst(MVT VecVT, ISD::CondCode CC,
bool HasVSX, bool &Swap, bool &Negate) {
Swap = false;
Negate = false;
PowerPC: More support for Altivec compare operations This patch adds more support for vector type comparisons using altivec. It adds correct support for v16i8, v8i16, v4i32, and v4f32 vector types for comparison operators ==, !=, >, >=, <, and <=. llvm-svn: 167015
2012-10-30 21:50:19 +08:00
[PowerPC] Fix and improve vector comparisons This patch refactors code generation of vector comparisons. This fixes a wrong code-gen bug for ISD::SETGE for floating-point types, and improves generated code for vector comparisons in general. Specifically, the patch moves all logic deciding how to implement vector comparisons into getVCmpInst, which gets two extra boolean outputs indicating to its caller whether its needs to swap the input operands and/or negate the result of the comparison. Apart from implementing these two modifications as directed by getVCmpInst, there is no need to ever implement vector comparisons in any other manner; in particular, there is never a need to perform two separate comparisons (e.g. one for equal and one for greater-than, as code used to do before this patch). Reviewed by Bill Schmidt. llvm-svn: 214714
2014-08-04 21:13:57 +08:00
if (VecVT.isFloatingPoint()) {
/* Handle some cases by swapping input operands. */
switch (CC) {
case ISD::SETLE: CC = ISD::SETGE; Swap = true; break;
case ISD::SETLT: CC = ISD::SETGT; Swap = true; break;
case ISD::SETOLE: CC = ISD::SETOGE; Swap = true; break;
case ISD::SETOLT: CC = ISD::SETOGT; Swap = true; break;
case ISD::SETUGE: CC = ISD::SETULE; Swap = true; break;
case ISD::SETUGT: CC = ISD::SETULT; Swap = true; break;
default: break;
}
/* Handle some cases by negating the result. */
switch (CC) {
case ISD::SETNE: CC = ISD::SETEQ; Negate = true; break;
case ISD::SETUNE: CC = ISD::SETOEQ; Negate = true; break;
case ISD::SETULE: CC = ISD::SETOGT; Negate = true; break;
case ISD::SETULT: CC = ISD::SETOGE; Negate = true; break;
default: break;
}
/* We have instructions implementing the remaining cases. */
switch (CC) {
case ISD::SETEQ:
case ISD::SETOEQ:
if (VecVT == MVT::v4f32)
return HasVSX ? PPC::XVCMPEQSP : PPC::VCMPEQFP;
else if (VecVT == MVT::v2f64)
return PPC::XVCMPEQDP;
break;
case ISD::SETGT:
case ISD::SETOGT:
if (VecVT == MVT::v4f32)
return HasVSX ? PPC::XVCMPGTSP : PPC::VCMPGTFP;
else if (VecVT == MVT::v2f64)
return PPC::XVCMPGTDP;
break;
case ISD::SETGE:
case ISD::SETOGE:
if (VecVT == MVT::v4f32)
return HasVSX ? PPC::XVCMPGESP : PPC::VCMPGEFP;
else if (VecVT == MVT::v2f64)
return PPC::XVCMPGEDP;
break;
default:
break;
}
llvm_unreachable("Invalid floating-point vector compare condition");
} else {
/* Handle some cases by swapping input operands. */
switch (CC) {
case ISD::SETGE: CC = ISD::SETLE; Swap = true; break;
case ISD::SETLT: CC = ISD::SETGT; Swap = true; break;
case ISD::SETUGE: CC = ISD::SETULE; Swap = true; break;
case ISD::SETULT: CC = ISD::SETUGT; Swap = true; break;
default: break;
}
/* Handle some cases by negating the result. */
switch (CC) {
case ISD::SETNE: CC = ISD::SETEQ; Negate = true; break;
case ISD::SETUNE: CC = ISD::SETUEQ; Negate = true; break;
case ISD::SETLE: CC = ISD::SETGT; Negate = true; break;
case ISD::SETULE: CC = ISD::SETUGT; Negate = true; break;
default: break;
}
/* We have instructions implementing the remaining cases. */
switch (CC) {
case ISD::SETEQ:
case ISD::SETUEQ:
if (VecVT == MVT::v16i8)
return PPC::VCMPEQUB;
else if (VecVT == MVT::v8i16)
return PPC::VCMPEQUH;
else if (VecVT == MVT::v4i32)
return PPC::VCMPEQUW;
Add the following 64-bit vector integer arithmetic instructions added in POWER8: vaddudm vsubudm vmulesw vmulosw vmuleuw vmulouw vmuluwm vmaxsd vmaxud vminsd vminud vcmpequd vcmpequd. vcmpgtsd vcmpgtsd. vcmpgtud vcmpgtud. vrld vsld vsrd vsrad Phabricator review: http://reviews.llvm.org/D7959 llvm-svn: 231115
2015-03-04 03:55:45 +08:00
else if (VecVT == MVT::v2i64)
return PPC::VCMPEQUD;
[PowerPC] Fix and improve vector comparisons This patch refactors code generation of vector comparisons. This fixes a wrong code-gen bug for ISD::SETGE for floating-point types, and improves generated code for vector comparisons in general. Specifically, the patch moves all logic deciding how to implement vector comparisons into getVCmpInst, which gets two extra boolean outputs indicating to its caller whether its needs to swap the input operands and/or negate the result of the comparison. Apart from implementing these two modifications as directed by getVCmpInst, there is no need to ever implement vector comparisons in any other manner; in particular, there is never a need to perform two separate comparisons (e.g. one for equal and one for greater-than, as code used to do before this patch). Reviewed by Bill Schmidt. llvm-svn: 214714
2014-08-04 21:13:57 +08:00
break;
case ISD::SETGT:
if (VecVT == MVT::v16i8)
return PPC::VCMPGTSB;
else if (VecVT == MVT::v8i16)
return PPC::VCMPGTSH;
else if (VecVT == MVT::v4i32)
return PPC::VCMPGTSW;
Add the following 64-bit vector integer arithmetic instructions added in POWER8: vaddudm vsubudm vmulesw vmulosw vmuleuw vmulouw vmuluwm vmaxsd vmaxud vminsd vminud vcmpequd vcmpequd. vcmpgtsd vcmpgtsd. vcmpgtud vcmpgtud. vrld vsld vsrd vsrad Phabricator review: http://reviews.llvm.org/D7959 llvm-svn: 231115
2015-03-04 03:55:45 +08:00
else if (VecVT == MVT::v2i64)
return PPC::VCMPGTSD;
[PowerPC] Fix and improve vector comparisons This patch refactors code generation of vector comparisons. This fixes a wrong code-gen bug for ISD::SETGE for floating-point types, and improves generated code for vector comparisons in general. Specifically, the patch moves all logic deciding how to implement vector comparisons into getVCmpInst, which gets two extra boolean outputs indicating to its caller whether its needs to swap the input operands and/or negate the result of the comparison. Apart from implementing these two modifications as directed by getVCmpInst, there is no need to ever implement vector comparisons in any other manner; in particular, there is never a need to perform two separate comparisons (e.g. one for equal and one for greater-than, as code used to do before this patch). Reviewed by Bill Schmidt. llvm-svn: 214714
2014-08-04 21:13:57 +08:00
break;
case ISD::SETUGT:
if (VecVT == MVT::v16i8)
return PPC::VCMPGTUB;
else if (VecVT == MVT::v8i16)
return PPC::VCMPGTUH;
else if (VecVT == MVT::v4i32)
return PPC::VCMPGTUW;
Add the following 64-bit vector integer arithmetic instructions added in POWER8: vaddudm vsubudm vmulesw vmulosw vmuleuw vmulouw vmuluwm vmaxsd vmaxud vminsd vminud vcmpequd vcmpequd. vcmpgtsd vcmpgtsd. vcmpgtud vcmpgtud. vrld vsld vsrd vsrad Phabricator review: http://reviews.llvm.org/D7959 llvm-svn: 231115
2015-03-04 03:55:45 +08:00
else if (VecVT == MVT::v2i64)
return PPC::VCMPGTUD;
[PowerPC] Fix and improve vector comparisons This patch refactors code generation of vector comparisons. This fixes a wrong code-gen bug for ISD::SETGE for floating-point types, and improves generated code for vector comparisons in general. Specifically, the patch moves all logic deciding how to implement vector comparisons into getVCmpInst, which gets two extra boolean outputs indicating to its caller whether its needs to swap the input operands and/or negate the result of the comparison. Apart from implementing these two modifications as directed by getVCmpInst, there is no need to ever implement vector comparisons in any other manner; in particular, there is never a need to perform two separate comparisons (e.g. one for equal and one for greater-than, as code used to do before this patch). Reviewed by Bill Schmidt. llvm-svn: 214714
2014-08-04 21:13:57 +08:00
break;
default:
break;
}
llvm_unreachable("Invalid integer vector compare condition");
PowerPC: More support for Altivec compare operations This patch adds more support for vector type comparisons using altivec. It adds correct support for v16i8, v8i16, v4i32, and v4f32 vector types for comparison operators ==, !=, >, >=, <, and <=. llvm-svn: 167015
2012-10-30 21:50:19 +08:00
}
}
Change SelectCode's argument from SDValue to SDNode *, to make it more clear what information these functions are actually using. This is also a micro-optimization, as passing a SDNode * around is simpler than passing a { SDNode *, int } by value or reference. llvm-svn: 92564
2010-01-05 09:24:18 +08:00
SDNode *PPCDAGToDAGISel::SelectSETCC(SDNode *N) {
Track IR ordering of SelectionDAG nodes 2/4. Change SelectionDAG::getXXXNode() interfaces as well as call sites of these functions to pass in SDLoc instead of DebugLoc. llvm-svn: 182703
2013-05-25 10:42:55 +08:00
SDLoc dl(N);
Pull out setcc, this reduces stack frame size from 7520 to 6032 bytes llvm-svn: 23649
2005-10-07 03:03:35 +08:00
unsigned Imm;
ISD::CondCode CC = cast<CondCodeSDNode>(N->getOperand(2))->get();
Make TargetLowering::getPointerTy() taking DataLayout as an argument Summary: This change is part of a series of commits dedicated to have a single DataLayout during compilation by using always the one owned by the module. Reviewers: echristo Subscribers: jholewinski, ted, yaron.keren, rafael, llvm-commits Differential Revision: http://reviews.llvm.org/D11028 From: Mehdi Amini <mehdi.amini@apple.com> llvm-svn: 241775
2015-07-09 10:09:04 +08:00
EVT PtrVT =
CurDAG->getTargetLoweringInfo().getPointerTy(CurDAG->getDataLayout());
Don't apply on PPC64 the 32bit ADDIC optimizations as there's no overflow with 32bit values. llvm-svn: 133439
2011-06-20 23:28:39 +08:00
bool isPPC64 = (PtrVT == MVT::i64);
Reset the subtarget for DAGToDAG on every iteration of runOnMachineFunction. This required updating the generated functions and TD file accordingly to be pointers rather than const references. llvm-svn: 209375
2014-05-22 09:07:24 +08:00
if (!PPCSubTarget->useCRBits() &&
Add CR-bit tracking to the PowerPC backend for i1 values This change enables tracking i1 values in the PowerPC backend using the condition register bits. These bits can be treated on PowerPC as separate registers; individual bit operations (and, or, xor, etc.) are supported. Tracking booleans in CR bits has several advantages: - Reduction in register pressure (because we no longer need GPRs to store boolean values). - Logical operations on booleans can be handled more efficiently; we used to have to move all results from comparisons into GPRs, perform promoted logical operations in GPRs, and then move the result back into condition register bits to be used by conditional branches. This can be very inefficient, because the throughput of these CR <-> GPR moves have high latency and low throughput (especially when other associated instructions are accounted for). - On the POWER7 and similar cores, we can increase total throughput by using the CR bits. CR bit operations have a dedicated functional unit. Most of this is more-or-less mechanical: Adjustments were needed in the calling-convention code, support was added for spilling/restoring individual condition-register bits, and conditional branch instruction definitions taking specific CR bits were added (plus patterns and code for generating bit-level operations). This is enabled by default when running at -O2 and higher. For -O0 and -O1, where the ability to debug is more important, this feature is disabled by default. Individual CR bits do not have assigned DWARF register numbers, and storing values in CR bits makes them invisible to the debugger. It is critical, however, that we don't move i1 values that have been promoted to larger values (such as those passed as function arguments) into bit registers only to quickly turn around and move the values back into GPRs (such as happens when values are returned by functions). A pair of target-specific DAG combines are added to remove the trunc/extends in: trunc(binary-ops(binary-ops(zext(x), zext(y)), ...) and: zext(binary-ops(binary-ops(trunc(x), trunc(y)), ...) In short, we only want to use CR bits where some of the i1 values come from comparisons or are used by conditional branches or selects. To put it another way, if we can do the entire i1 computation in GPRs, then we probably should (on the POWER7, the GPR-operation throughput is higher, and for all cores, the CR <-> GPR moves are expensive). POWER7 test-suite performance results (from 10 runs in each configuration): SingleSource/Benchmarks/Misc/mandel-2: 35% speedup MultiSource/Benchmarks/Prolangs-C++/city/city: 21% speedup MultiSource/Benchmarks/MiBench/automotive-susan: 23% speedup SingleSource/Benchmarks/CoyoteBench/huffbench: 13% speedup SingleSource/Benchmarks/Misc-C++/Large/sphereflake: 13% speedup SingleSource/Benchmarks/Misc-C++/mandel-text: 10% speedup SingleSource/Benchmarks/Misc-C++-EH/spirit: 10% slowdown MultiSource/Applications/lemon/lemon: 8% slowdown llvm-svn: 202451
2014-02-28 08:27:01 +08:00
isInt32Immediate(N->getOperand(1), Imm)) {
Pull out setcc, this reduces stack frame size from 7520 to 6032 bytes llvm-svn: 23649
2005-10-07 03:03:35 +08:00
// We can codegen setcc op, imm very efficiently compared to a brcond.
// Check for those cases here.
// setcc op, 0
if (Imm == 0) {
Rename SDOperand to SDValue. llvm-svn: 54128
2008-07-28 05:46:04 +08:00
SDValue Op = N->getOperand(0);
Pull out setcc, this reduces stack frame size from 7520 to 6032 bytes llvm-svn: 23649
2005-10-07 03:03:35 +08:00
switch (CC) {
Instead of aborting if not a case we can handle specially, break out and let the generic code handle it. This fixes CodeGen/Generic/2005-10-21-longlonggtu.ll on ppc. also, reindent this code llvm-svn: 23874
2005-10-22 05:17:10 +08:00
default: break;
Do not use getTargetNode() and SelectNodeTo() which takes more than 3 SDOperand arguments. Use the variants which take an array and number instead. llvm-svn: 29907
2006-08-27 16:14:06 +08:00
case ISD::SETEQ: {
Rename getTargetNode to getMachineNode, for consistency with the naming scheme used in SelectionDAG, where there are multiple kinds of "target" nodes, but "machine" nodes are nodes which represent a MachineInstr. llvm-svn: 82790
2009-09-26 02:54:59 +08:00
Op = SDValue(CurDAG->getMachineNode(PPC::CNTLZW, dl, MVT::i32, Op), 0);
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
SDValue Ops[] = { Op, getI32Imm(27, dl), getI32Imm(5, dl),
getI32Imm(31, dl) };
Convert SelectionDAG::SelectNodeTo to use ArrayRef. llvm-svn: 207377
2014-04-28 03:21:11 +08:00
return CurDAG->SelectNodeTo(N, PPC::RLWINM, MVT::i32, Ops);
Do not use getTargetNode() and SelectNodeTo() which takes more than 3 SDOperand arguments. Use the variants which take an array and number instead. llvm-svn: 29907
2006-08-27 16:14:06 +08:00
}
Instead of aborting if not a case we can handle specially, break out and let the generic code handle it. This fixes CodeGen/Generic/2005-10-21-longlonggtu.ll on ppc. also, reindent this code llvm-svn: 23874
2005-10-22 05:17:10 +08:00
case ISD::SETNE: {
Don't apply on PPC64 the 32bit ADDIC optimizations as there's no overflow with 32bit values. llvm-svn: 133439
2011-06-20 23:28:39 +08:00
if (isPPC64) break;
Rename SDOperand to SDValue. llvm-svn: 54128
2008-07-28 05:46:04 +08:00
SDValue AD =
rename MVT::Flag to MVT::Glue. "Flag" is a terrible name for something that just glues two nodes together, even if it is sometimes used for flags. llvm-svn: 122310
2010-12-21 10:38:05 +08:00
SDValue(CurDAG->getMachineNode(PPC::ADDIC, dl, MVT::i32, MVT::Glue,
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
Op, getI32Imm(~0U, dl)), 0);
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
return CurDAG->SelectNodeTo(N, PPC::SUBFE, MVT::i32, AD, Op,
SelectNodeTo now returns a SDNode*. llvm-svn: 29901
2006-08-26 16:00:10 +08:00
AD.getValue(1));
Instead of aborting if not a case we can handle specially, break out and let the generic code handle it. This fixes CodeGen/Generic/2005-10-21-longlonggtu.ll on ppc. also, reindent this code llvm-svn: 23874
2005-10-22 05:17:10 +08:00
}
Do not use getTargetNode() and SelectNodeTo() which takes more than 3 SDOperand arguments. Use the variants which take an array and number instead. llvm-svn: 29907
2006-08-27 16:14:06 +08:00
case ISD::SETLT: {
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
SDValue Ops[] = { Op, getI32Imm(1, dl), getI32Imm(31, dl),
getI32Imm(31, dl) };
Convert SelectionDAG::SelectNodeTo to use ArrayRef. llvm-svn: 207377
2014-04-28 03:21:11 +08:00
return CurDAG->SelectNodeTo(N, PPC::RLWINM, MVT::i32, Ops);
Do not use getTargetNode() and SelectNodeTo() which takes more than 3 SDOperand arguments. Use the variants which take an array and number instead. llvm-svn: 29907
2006-08-27 16:14:06 +08:00
}
Instead of aborting if not a case we can handle specially, break out and let the generic code handle it. This fixes CodeGen/Generic/2005-10-21-longlonggtu.ll on ppc. also, reindent this code llvm-svn: 23874
2005-10-22 05:17:10 +08:00
case ISD::SETGT: {
Rename SDOperand to SDValue. llvm-svn: 54128
2008-07-28 05:46:04 +08:00
SDValue T =
Rename getTargetNode to getMachineNode, for consistency with the naming scheme used in SelectionDAG, where there are multiple kinds of "target" nodes, but "machine" nodes are nodes which represent a MachineInstr. llvm-svn: 82790
2009-09-26 02:54:59 +08:00
SDValue(CurDAG->getMachineNode(PPC::NEG, dl, MVT::i32, Op), 0);
T = SDValue(CurDAG->getMachineNode(PPC::ANDC, dl, MVT::i32, T, Op), 0);
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
SDValue Ops[] = { T, getI32Imm(1, dl), getI32Imm(31, dl),
getI32Imm(31, dl) };
Convert SelectionDAG::SelectNodeTo to use ArrayRef. llvm-svn: 207377
2014-04-28 03:21:11 +08:00
return CurDAG->SelectNodeTo(N, PPC::RLWINM, MVT::i32, Ops);
Instead of aborting if not a case we can handle specially, break out and let the generic code handle it. This fixes CodeGen/Generic/2005-10-21-longlonggtu.ll on ppc. also, reindent this code llvm-svn: 23874
2005-10-22 05:17:10 +08:00
}
Pull out setcc, this reduces stack frame size from 7520 to 6032 bytes llvm-svn: 23649
2005-10-07 03:03:35 +08:00
}
} else if (Imm == ~0U) { // setcc op, -1
Rename SDOperand to SDValue. llvm-svn: 54128
2008-07-28 05:46:04 +08:00
SDValue Op = N->getOperand(0);
Pull out setcc, this reduces stack frame size from 7520 to 6032 bytes llvm-svn: 23649
2005-10-07 03:03:35 +08:00
switch (CC) {
Instead of aborting if not a case we can handle specially, break out and let the generic code handle it. This fixes CodeGen/Generic/2005-10-21-longlonggtu.ll on ppc. also, reindent this code llvm-svn: 23874
2005-10-22 05:17:10 +08:00
default: break;
case ISD::SETEQ:
Don't apply on PPC64 the 32bit ADDIC optimizations as there's no overflow with 32bit values. llvm-svn: 133439
2011-06-20 23:28:39 +08:00
if (isPPC64) break;
rename MVT::Flag to MVT::Glue. "Flag" is a terrible name for something that just glues two nodes together, even if it is sometimes used for flags. llvm-svn: 122310
2010-12-21 10:38:05 +08:00
Op = SDValue(CurDAG->getMachineNode(PPC::ADDIC, dl, MVT::i32, MVT::Glue,
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
Op, getI32Imm(1, dl)), 0);
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
return CurDAG->SelectNodeTo(N, PPC::ADDZE, MVT::i32,
SDValue(CurDAG->getMachineNode(PPC::LI, dl,
Rename getTargetNode to getMachineNode, for consistency with the naming scheme used in SelectionDAG, where there are multiple kinds of "target" nodes, but "machine" nodes are nodes which represent a MachineInstr. llvm-svn: 82790
2009-09-26 02:54:59 +08:00
MVT::i32,
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
getI32Imm(0, dl)),
0), Op.getValue(1));
Instead of aborting if not a case we can handle specially, break out and let the generic code handle it. This fixes CodeGen/Generic/2005-10-21-longlonggtu.ll on ppc. also, reindent this code llvm-svn: 23874
2005-10-22 05:17:10 +08:00
case ISD::SETNE: {
Don't apply on PPC64 the 32bit ADDIC optimizations as there's no overflow with 32bit values. llvm-svn: 133439
2011-06-20 23:28:39 +08:00
if (isPPC64) break;
Rename getTargetNode to getMachineNode, for consistency with the naming scheme used in SelectionDAG, where there are multiple kinds of "target" nodes, but "machine" nodes are nodes which represent a MachineInstr. llvm-svn: 82790
2009-09-26 02:54:59 +08:00
Op = SDValue(CurDAG->getMachineNode(PPC::NOR, dl, MVT::i32, Op, Op), 0);
rename MVT::Flag to MVT::Glue. "Flag" is a terrible name for something that just glues two nodes together, even if it is sometimes used for flags. llvm-svn: 122310
2010-12-21 10:38:05 +08:00
SDNode *AD = CurDAG->getMachineNode(PPC::ADDIC, dl, MVT::i32, MVT::Glue,
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
Op, getI32Imm(~0U, dl));
Split EVT into MVT and EVT, the former representing _just_ a primitive type, while the latter is capable of representing either a primitive or an extended type. llvm-svn: 78713
2009-08-12 04:47:22 +08:00
return CurDAG->SelectNodeTo(N, PPC::SUBFE, MVT::i32, SDValue(AD, 0),
Rename SDOperand to SDValue. llvm-svn: 54128
2008-07-28 05:46:04 +08:00
Op, SDValue(AD, 1));
Instead of aborting if not a case we can handle specially, break out and let the generic code handle it. This fixes CodeGen/Generic/2005-10-21-longlonggtu.ll on ppc. also, reindent this code llvm-svn: 23874
2005-10-22 05:17:10 +08:00
}
case ISD::SETLT: {
Rename getTargetNode to getMachineNode, for consistency with the naming scheme used in SelectionDAG, where there are multiple kinds of "target" nodes, but "machine" nodes are nodes which represent a MachineInstr. llvm-svn: 82790
2009-09-26 02:54:59 +08:00
SDValue AD = SDValue(CurDAG->getMachineNode(PPC::ADDI, dl, MVT::i32, Op,
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
getI32Imm(1, dl)), 0);
Rename getTargetNode to getMachineNode, for consistency with the naming scheme used in SelectionDAG, where there are multiple kinds of "target" nodes, but "machine" nodes are nodes which represent a MachineInstr. llvm-svn: 82790
2009-09-26 02:54:59 +08:00
SDValue AN = SDValue(CurDAG->getMachineNode(PPC::AND, dl, MVT::i32, AD,
Op), 0);
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
SDValue Ops[] = { AN, getI32Imm(1, dl), getI32Imm(31, dl),
getI32Imm(31, dl) };
Convert SelectionDAG::SelectNodeTo to use ArrayRef. llvm-svn: 207377
2014-04-28 03:21:11 +08:00
return CurDAG->SelectNodeTo(N, PPC::RLWINM, MVT::i32, Ops);
Instead of aborting if not a case we can handle specially, break out and let the generic code handle it. This fixes CodeGen/Generic/2005-10-21-longlonggtu.ll on ppc. also, reindent this code llvm-svn: 23874
2005-10-22 05:17:10 +08:00
}
Do not use getTargetNode() and SelectNodeTo() which takes more than 3 SDOperand arguments. Use the variants which take an array and number instead. llvm-svn: 29907
2006-08-27 16:14:06 +08:00
case ISD::SETGT: {
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
SDValue Ops[] = { Op, getI32Imm(1, dl), getI32Imm(31, dl),
getI32Imm(31, dl) };
Op = SDValue(CurDAG->getMachineNode(PPC::RLWINM, dl, MVT::i32, Ops), 0);
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
return CurDAG->SelectNodeTo(N, PPC::XORI, MVT::i32, Op,
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
getI32Imm(1, dl));
Pull out setcc, this reduces stack frame size from 7520 to 6032 bytes llvm-svn: 23649
2005-10-07 03:03:35 +08:00
}
Do not use getTargetNode() and SelectNodeTo() which takes more than 3 SDOperand arguments. Use the variants which take an array and number instead. llvm-svn: 29907
2006-08-27 16:14:06 +08:00
}
Pull out setcc, this reduces stack frame size from 7520 to 6032 bytes llvm-svn: 23649
2005-10-07 03:03:35 +08:00
}
}
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
PR12716: PPC crashes on vector compare Vector compare using altivec 'vcmpxxx' instructions have as third argument a vector register instead of CR one, different from integer and float-point compares. This leads to a failure in code generation, where 'SelectSETCC' expects a DAG with a CR register and gets vector register instead. This patch changes the behavior by just returning a DAG with the vector compare instruction based on the type. The patch also adds a testcase for all vector types llvm defines. It also included a fix on signed 5-bits predicates printing, where signed values were not handled correctly as signed (char are unsigned by default for PowerPC). This generates 'vspltisw' (vector splat) instruction with SIM out of range. llvm-svn: 165419
2012-10-09 02:59:53 +08:00
SDValue LHS = N->getOperand(0);
SDValue RHS = N->getOperand(1);
PowerPC: More support for Altivec compare operations This patch adds more support for vector type comparisons using altivec. It adds correct support for v16i8, v8i16, v4i32, and v4f32 vector types for comparison operators ==, !=, >, >=, <, and <=. llvm-svn: 167015
2012-10-30 21:50:19 +08:00
// Altivec Vector compare instructions do not set any CR register by default and
// vector compare operations return the same type as the operands.
PR12716: PPC crashes on vector compare Vector compare using altivec 'vcmpxxx' instructions have as third argument a vector register instead of CR one, different from integer and float-point compares. This leads to a failure in code generation, where 'SelectSETCC' expects a DAG with a CR register and gets vector register instead. This patch changes the behavior by just returning a DAG with the vector compare instruction based on the type. The patch also adds a testcase for all vector types llvm defines. It also included a fix on signed 5-bits predicates printing, where signed values were not handled correctly as signed (char are unsigned by default for PowerPC). This generates 'vspltisw' (vector splat) instruction with SIM out of range. llvm-svn: 165419
2012-10-09 02:59:53 +08:00
if (LHS.getValueType().isVector()) {
[PowerPC] Add support for the QPX vector instruction set This adds support for the QPX vector instruction set, which is used by the enhanced A2 cores on the IBM BG/Q supercomputers. QPX vectors are 256 bytes wide, holding 4 double-precision floating-point values. Boolean values, modeled here as <4 x i1> are actually also represented as floating-point values (essentially { -1, 1 } for { false, true }). QPX shares many features with Altivec and VSX, but is distinct from both of them. One major difference is that, instead of adding completely-separate vector registers, QPX vector registers are extensions of the scalar floating-point registers (lane 0 is the corresponding scalar floating-point value). The operations supported on QPX vectors mirrors that supported on the scalar floating-point values (with some additional ones for permutations and logical/comparison operations). I've been maintaining this support out-of-tree, as part of the bgclang project, for several years. This is not the entire bgclang patch set, but is most of the subset that can be cleanly integrated into LLVM proper at this time. Adding this to the LLVM backend is part of my efforts to rebase bgclang to the current LLVM trunk, but is independently useful (especially for codes that use LLVM as a JIT in library form). The assembler/disassembler test coverage is complete. The CodeGen test coverage is not, but I've included some tests, and more will be added as follow-up work. llvm-svn: 230413
2015-02-25 09:06:45 +08:00
if (PPCSubTarget->hasQPX())
return nullptr;
PowerPC: More support for Altivec compare operations This patch adds more support for vector type comparisons using altivec. It adds correct support for v16i8, v8i16, v4i32, and v4f32 vector types for comparison operators ==, !=, >, >=, <, and <=. llvm-svn: 167015
2012-10-30 21:50:19 +08:00
EVT VecVT = LHS.getValueType();
[PowerPC] Fix and improve vector comparisons This patch refactors code generation of vector comparisons. This fixes a wrong code-gen bug for ISD::SETGE for floating-point types, and improves generated code for vector comparisons in general. Specifically, the patch moves all logic deciding how to implement vector comparisons into getVCmpInst, which gets two extra boolean outputs indicating to its caller whether its needs to swap the input operands and/or negate the result of the comparison. Apart from implementing these two modifications as directed by getVCmpInst, there is no need to ever implement vector comparisons in any other manner; in particular, there is never a need to perform two separate comparisons (e.g. one for equal and one for greater-than, as code used to do before this patch). Reviewed by Bill Schmidt. llvm-svn: 214714
2014-08-04 21:13:57 +08:00
bool Swap, Negate;
unsigned int VCmpInst = getVCmpInst(VecVT.getSimpleVT(), CC,
PPCSubTarget->hasVSX(), Swap, Negate);
if (Swap)
std::swap(LHS, RHS);
[PowerPC] Fix value type on XVCMPEQDP for v2f64 comparisons XVCMPEQDP is used for VSX v2f64 equality comparisons, but the value type needs to be v2i64 (as that's the corresponding SETCC type). Fixes PR24225. llvm-svn: 245535
2015-08-20 11:02:02 +08:00
EVT ResVT = VecVT.changeVectorElementTypeToInteger();
[PowerPC] Fix and improve vector comparisons This patch refactors code generation of vector comparisons. This fixes a wrong code-gen bug for ISD::SETGE for floating-point types, and improves generated code for vector comparisons in general. Specifically, the patch moves all logic deciding how to implement vector comparisons into getVCmpInst, which gets two extra boolean outputs indicating to its caller whether its needs to swap the input operands and/or negate the result of the comparison. Apart from implementing these two modifications as directed by getVCmpInst, there is no need to ever implement vector comparisons in any other manner; in particular, there is never a need to perform two separate comparisons (e.g. one for equal and one for greater-than, as code used to do before this patch). Reviewed by Bill Schmidt. llvm-svn: 214714
2014-08-04 21:13:57 +08:00
if (Negate) {
[PowerPC] Fix value type on XVCMPEQDP for v2f64 comparisons XVCMPEQDP is used for VSX v2f64 equality comparisons, but the value type needs to be v2i64 (as that's the corresponding SETCC type). Fixes PR24225. llvm-svn: 245535
2015-08-20 11:02:02 +08:00
SDValue VCmp(CurDAG->getMachineNode(VCmpInst, dl, ResVT, LHS, RHS), 0);
[PowerPC] Fix and improve vector comparisons This patch refactors code generation of vector comparisons. This fixes a wrong code-gen bug for ISD::SETGE for floating-point types, and improves generated code for vector comparisons in general. Specifically, the patch moves all logic deciding how to implement vector comparisons into getVCmpInst, which gets two extra boolean outputs indicating to its caller whether its needs to swap the input operands and/or negate the result of the comparison. Apart from implementing these two modifications as directed by getVCmpInst, there is no need to ever implement vector comparisons in any other manner; in particular, there is never a need to perform two separate comparisons (e.g. one for equal and one for greater-than, as code used to do before this patch). Reviewed by Bill Schmidt. llvm-svn: 214714
2014-08-04 21:13:57 +08:00
return CurDAG->SelectNodeTo(N, PPCSubTarget->hasVSX() ? PPC::XXLNOR :
PPC::VNOR,
[PowerPC] Fix value type on XVCMPEQDP for v2f64 comparisons XVCMPEQDP is used for VSX v2f64 equality comparisons, but the value type needs to be v2i64 (as that's the corresponding SETCC type). Fixes PR24225. llvm-svn: 245535
2015-08-20 11:02:02 +08:00
ResVT, VCmp, VCmp);
PowerPC: More support for Altivec compare operations This patch adds more support for vector type comparisons using altivec. It adds correct support for v16i8, v8i16, v4i32, and v4f32 vector types for comparison operators ==, !=, >, >=, <, and <=. llvm-svn: 167015
2012-10-30 21:50:19 +08:00
}
[PowerPC] Fix and improve vector comparisons This patch refactors code generation of vector comparisons. This fixes a wrong code-gen bug for ISD::SETGE for floating-point types, and improves generated code for vector comparisons in general. Specifically, the patch moves all logic deciding how to implement vector comparisons into getVCmpInst, which gets two extra boolean outputs indicating to its caller whether its needs to swap the input operands and/or negate the result of the comparison. Apart from implementing these two modifications as directed by getVCmpInst, there is no need to ever implement vector comparisons in any other manner; in particular, there is never a need to perform two separate comparisons (e.g. one for equal and one for greater-than, as code used to do before this patch). Reviewed by Bill Schmidt. llvm-svn: 214714
2014-08-04 21:13:57 +08:00
[PowerPC] Fix value type on XVCMPEQDP for v2f64 comparisons XVCMPEQDP is used for VSX v2f64 equality comparisons, but the value type needs to be v2i64 (as that's the corresponding SETCC type). Fixes PR24225. llvm-svn: 245535
2015-08-20 11:02:02 +08:00
return CurDAG->SelectNodeTo(N, VCmpInst, ResVT, LHS, RHS);
PR12716: PPC crashes on vector compare Vector compare using altivec 'vcmpxxx' instructions have as third argument a vector register instead of CR one, different from integer and float-point compares. This leads to a failure in code generation, where 'SelectSETCC' expects a DAG with a CR register and gets vector register instead. This patch changes the behavior by just returning a DAG with the vector compare instruction based on the type. The patch also adds a testcase for all vector types llvm defines. It also included a fix on signed 5-bits predicates printing, where signed values were not handled correctly as signed (char are unsigned by default for PowerPC). This generates 'vspltisw' (vector splat) instruction with SIM out of range. llvm-svn: 165419
2012-10-09 02:59:53 +08:00
}
Reset the subtarget for DAGToDAG on every iteration of runOnMachineFunction. This required updating the generated functions and TD file accordingly to be pointers rather than const references. llvm-svn: 209375
2014-05-22 09:07:24 +08:00
if (PPCSubTarget->useCRBits())
[C++] Use 'nullptr'. Target edition. llvm-svn: 207197
2014-04-25 13:30:21 +08:00
return nullptr;
Add CR-bit tracking to the PowerPC backend for i1 values This change enables tracking i1 values in the PowerPC backend using the condition register bits. These bits can be treated on PowerPC as separate registers; individual bit operations (and, or, xor, etc.) are supported. Tracking booleans in CR bits has several advantages: - Reduction in register pressure (because we no longer need GPRs to store boolean values). - Logical operations on booleans can be handled more efficiently; we used to have to move all results from comparisons into GPRs, perform promoted logical operations in GPRs, and then move the result back into condition register bits to be used by conditional branches. This can be very inefficient, because the throughput of these CR <-> GPR moves have high latency and low throughput (especially when other associated instructions are accounted for). - On the POWER7 and similar cores, we can increase total throughput by using the CR bits. CR bit operations have a dedicated functional unit. Most of this is more-or-less mechanical: Adjustments were needed in the calling-convention code, support was added for spilling/restoring individual condition-register bits, and conditional branch instruction definitions taking specific CR bits were added (plus patterns and code for generating bit-level operations). This is enabled by default when running at -O2 and higher. For -O0 and -O1, where the ability to debug is more important, this feature is disabled by default. Individual CR bits do not have assigned DWARF register numbers, and storing values in CR bits makes them invisible to the debugger. It is critical, however, that we don't move i1 values that have been promoted to larger values (such as those passed as function arguments) into bit registers only to quickly turn around and move the values back into GPRs (such as happens when values are returned by functions). A pair of target-specific DAG combines are added to remove the trunc/extends in: trunc(binary-ops(binary-ops(zext(x), zext(y)), ...) and: zext(binary-ops(binary-ops(trunc(x), trunc(y)), ...) In short, we only want to use CR bits where some of the i1 values come from comparisons or are used by conditional branches or selects. To put it another way, if we can do the entire i1 computation in GPRs, then we probably should (on the POWER7, the GPR-operation throughput is higher, and for all cores, the CR <-> GPR moves are expensive). POWER7 test-suite performance results (from 10 runs in each configuration): SingleSource/Benchmarks/Misc/mandel-2: 35% speedup MultiSource/Benchmarks/Prolangs-C++/city/city: 21% speedup MultiSource/Benchmarks/MiBench/automotive-susan: 23% speedup SingleSource/Benchmarks/CoyoteBench/huffbench: 13% speedup SingleSource/Benchmarks/Misc-C++/Large/sphereflake: 13% speedup SingleSource/Benchmarks/Misc-C++/mandel-text: 10% speedup SingleSource/Benchmarks/Misc-C++-EH/spirit: 10% slowdown MultiSource/Applications/lemon/lemon: 8% slowdown llvm-svn: 202451
2014-02-28 08:27:01 +08:00
Pull out setcc, this reduces stack frame size from 7520 to 6032 bytes llvm-svn: 23649
2005-10-07 03:03:35 +08:00
bool Inv;
[PowerPC] Remove dead code from PPCDAGToDAGISel::SelectSETCC The subroutine getCRIdxForSetCC has a parameter "Other" and comment: If this returns with Other != -1, then the returned comparison is an or of two simpler comparisons. However for at least the last five years this routine has never returned a value of Other != -1; these cases are now handled differently to begin with. This patch removes the parameter and the code in SelectSETCC that attempted to handle the Other != -1 case. llvm-svn: 185541
2013-07-03 23:13:30 +08:00
unsigned Idx = getCRIdxForSetCC(CC, Inv);
PR12716: PPC crashes on vector compare Vector compare using altivec 'vcmpxxx' instructions have as third argument a vector register instead of CR one, different from integer and float-point compares. This leads to a failure in code generation, where 'SelectSETCC' expects a DAG with a CR register and gets vector register instead. This patch changes the behavior by just returning a DAG with the vector compare instruction based on the type. The patch also adds a testcase for all vector types llvm defines. It also included a fix on signed 5-bits predicates printing, where signed values were not handled correctly as signed (char are unsigned by default for PowerPC). This generates 'vspltisw' (vector splat) instruction with SIM out of range. llvm-svn: 165419
2012-10-09 02:59:53 +08:00
SDValue CCReg = SelectCC(LHS, RHS, CC, dl);
Rename SDOperand to SDValue. llvm-svn: 54128
2008-07-28 05:46:04 +08:00
SDValue IntCR;
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
Pull out setcc, this reduces stack frame size from 7520 to 6032 bytes llvm-svn: 23649
2005-10-07 03:03:35 +08:00
// Force the ccreg into CR7.
Split EVT into MVT and EVT, the former representing _just_ a primitive type, while the latter is capable of representing either a primitive or an extended type. llvm-svn: 78713
2009-08-12 04:47:22 +08:00
SDValue CR7Reg = CurDAG->getRegister(PPC::CR7, MVT::i32);
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
[C++] Use 'nullptr'. Target edition. llvm-svn: 207197
2014-04-25 13:30:21 +08:00
SDValue InFlag(nullptr, 0); // Null incoming flag value.
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
CCReg = CurDAG->getCopyToReg(CurDAG->getEntryNode(), dl, CR7Reg, CCReg,
Fix a regression caused by a patch earlier today llvm-svn: 24561
2005-12-01 11:50:19 +08:00
InFlag).getValue(1);
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
[PowerPC] Always use mfocrf if available When accessing just a single CR register, it is always preferable to use mfocrf instead of mfcr, if the former is available on the CPU. Current code makes that distinction in many, but not all places where a single CR register value is retrieved. One missing location is PPCRegisterInfo::lowerCRSpilling. To fix this and make this simpler in the future, this patch changes the bulk of the back-end to always assume mfocrf is available and simply generate it when needed. On machines that actually do not support mfocrf, the instruction is replaced by mfcr at the very end, in EmitInstruction. This has the additional benefit that we no longer need the MFCRpseud hack, since before EmitInstruction we always have a MFOCRF instruction pattern, which already models data flow as required. The patch also adds the MFOCRF8 version of the instruction, which was missing so far. Except for the PPCRegisterInfo::lowerCRSpilling case, no change in generated code intended. llvm-svn: 185556
2013-07-04 01:05:42 +08:00
IntCR = SDValue(CurDAG->getMachineNode(PPC::MFOCRF, dl, MVT::i32, CR7Reg,
CCReg), 0);
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
SDValue Ops[] = { IntCR, getI32Imm((32 - (3 - Idx)) & 31, dl),
getI32Imm(31, dl), getI32Imm(31, dl) };
[PowerPC] Remove dead code from PPCDAGToDAGISel::SelectSETCC The subroutine getCRIdxForSetCC has a parameter "Other" and comment: If this returns with Other != -1, then the returned comparison is an or of two simpler comparisons. However for at least the last five years this routine has never returned a value of Other != -1; these cases are now handled differently to begin with. This patch removes the parameter and the code in SelectSETCC that attempted to handle the Other != -1 case. llvm-svn: 185541
2013-07-03 23:13:30 +08:00
if (!Inv)
Convert SelectionDAG::SelectNodeTo to use ArrayRef. llvm-svn: 207377
2014-04-28 03:21:11 +08:00
return CurDAG->SelectNodeTo(N, PPC::RLWINM, MVT::i32, Ops);
Finally implement correct ordered comparisons for PPC, even though the code generated is not wonderful. This turns a miscompilation into a code quality bug (noted in the ppc readme). This fixes PR642, which is over 2 years old (!). Nate, please review this. llvm-svn: 45742
2008-01-08 14:46:30 +08:00
// Get the specified bit.
Rename SDOperand to SDValue. llvm-svn: 54128
2008-07-28 05:46:04 +08:00
SDValue Tmp =
ArrayRefize getMachineNode(). No functionality change. llvm-svn: 179901
2013-04-20 06:22:57 +08:00
SDValue(CurDAG->getMachineNode(PPC::RLWINM, dl, MVT::i32, Ops), 0);
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
return CurDAG->SelectNodeTo(N, PPC::XORI, MVT::i32, Tmp, getI32Imm(1, dl));
Pull out setcc, this reduces stack frame size from 7520 to 6032 bytes llvm-svn: 23649
2005-10-07 03:03:35 +08:00
}
Pull two more methods out, reducing stack frame size from 8224 -> 7520 bytes llvm-svn: 23648
2005-10-07 02:56:10 +08:00
[PowerPC] Make LDtocL and friends invariant loads LDtocL, and other loads that roughly correspond to the TOC_ENTRY SDAG node, represent loads from the TOC, which is invariant. As a result, these loads can be hoisted out of loops, etc. In order to do this, we need to generate GOT-style MMOs for TOC_ENTRY, which requires treating it as a legitimate memory intrinsic node type. Once this is done, the MMO transfer is automatically handled for TableGen-driven instruction selection, and for nodes generated directly in PPCISelDAGToDAG, we need to transfer the MMOs manually. Also, we were not transferring MMOs associated with pre-increment loads, so do that too. Lastly, this fixes an exposed bug where R30 was not added as a defined operand of UpdateGBR. This problem was highlighted by an example (used to generate the test case) posted to llvmdev by Francois Pichet. llvm-svn: 230553
2015-02-26 05:36:59 +08:00
SDNode *PPCDAGToDAGISel::transferMemOperands(SDNode *N, SDNode *Result) {
// Transfer memoperands.
MachineSDNode::mmo_iterator MemOp = MF->allocateMemRefsArray(1);
MemOp[0] = cast<MemSDNode>(N)->getMemOperand();
cast<MachineSDNode>(Result)->setMemRefs(MemOp, MemOp + 1);
return Result;
}
Pull out Call, reducing stack frame size from 6032 bytes to 5184 bytes. llvm-svn: 23650
2005-10-07 03:07:45 +08:00
initial hack at a dag->dag instruction selector. This is obviously woefully incomplete, but it is a start. It handles basic argument/retval stuff, immediates, add and sub. llvm-svn: 22836
2005-08-18 03:33:03 +08:00
// Select - Convert the specified operand from a target-independent to a
// target-specific node if it hasn't already been changed.
Change SelectCode's argument from SDValue to SDNode *, to make it more clear what information these functions are actually using. This is also a micro-optimization, as passing a SDNode * around is simpler than passing a { SDNode *, int } by value or reference. llvm-svn: 92564
2010-01-05 09:24:18 +08:00
SDNode *PPCDAGToDAGISel::Select(SDNode *N) {
Track IR ordering of SelectionDAG nodes 2/4. Change SelectionDAG::getXXXNode() interfaces as well as call sites of these functions to pass in SDLoc instead of DebugLoc. llvm-svn: 182703
2013-05-25 10:42:55 +08:00
SDLoc dl(N);
ISelDAG: spot chain cycles involving MachineNodes Previously, the DAGISel function WalkChainUsers was spotting that it had entered already-selected territory by whether a node was a MachineNode (amongst other things). Since it's fairly common practice to insert MachineNodes during ISelLowering, this was not the correct check. Looking around, it seems that other nodes get their NodeId set to -1 upon selection, so this makes sure the same thing happens to all MachineNodes and uses that characteristic to determine whether we should stop looking for a loop during selection. This should fix PR15840. llvm-svn: 191165
2013-09-22 16:21:56 +08:00
if (N->isMachineOpcode()) {
N->setNodeId(-1);
[C++] Use 'nullptr'. Target edition. llvm-svn: 207197
2014-04-25 13:30:21 +08:00
return nullptr; // Already selected.
ISelDAG: spot chain cycles involving MachineNodes Previously, the DAGISel function WalkChainUsers was spotting that it had entered already-selected territory by whether a node was a MachineNode (amongst other things). Since it's fairly common practice to insert MachineNodes during ISelLowering, this was not the correct check. Looking around, it seems that other nodes get their NodeId set to -1 upon selection, so this makes sure the same thing happens to all MachineNodes and uses that characteristic to determine whether we should stop looking for a loop during selection. This should fix PR15840. llvm-svn: 191165
2013-09-22 16:21:56 +08:00
}
Never rely on ReplaceAllUsesWith when selecting, use CodeGenMap instead. ReplaceAllUsesWith does not replace scalars SDOperand floating around on the stack, permitting things to be selected multiple times. llvm-svn: 23515
2005-09-29 08:59:32 +08:00
[PowerPC] Guard against illegal selection of add for TargetConstant operands r208640 was reverted because it caused a self-hosting failure on ppc64. The underlying cause was the formation of ISD::ADD nodes with ISD::TargetConstant operands. Because we have no patterns for 'add' taking 'timm' nodes, these are selected as r+r add instructions (which is a miscompile). Guard against this kind of behavior in the future by making the backend crash should this occur (instead of silently generating invalid output). llvm-svn: 216897
2014-09-02 14:23:54 +08:00
// In case any misguided DAG-level optimizations form an ADD with a
// TargetConstant operand, crash here instead of miscompiling (by selecting
// an r+r add instead of some kind of r+i add).
if (N->getOpcode() == ISD::ADD &&
N->getOperand(1).getOpcode() == ISD::TargetConstant)
llvm_unreachable("Invalid ADD with TargetConstant operand");
[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318
2014-12-16 13:51:41 +08:00
// Try matching complex bit permutations before doing anything else.
if (SDNode *NN = SelectBitPermutation(N))
return NN;
initial hack at a dag->dag instruction selector. This is obviously woefully incomplete, but it is a start. It handles basic argument/retval stuff, immediates, add and sub. llvm-svn: 22836
2005-08-18 03:33:03 +08:00
switch (N->getOpcode()) {
Remove some cases handled by the generated portion of the isel llvm-svn: 23262
2005-09-08 07:45:15 +08:00
default: break;
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
Reduce number of instructions to load 64-bit constants. llvm-svn: 32481
2006-12-12 21:23:43 +08:00
case ISD::Constant: {
[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056
2015-01-01 10:53:29 +08:00
if (N->getValueType(0) == MVT::i64)
return SelectInt64(CurDAG, N);
Reduce number of instructions to load 64-bit constants. llvm-svn: 32481
2006-12-12 21:23:43 +08:00
break;
}
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
Add CR-bit tracking to the PowerPC backend for i1 values This change enables tracking i1 values in the PowerPC backend using the condition register bits. These bits can be treated on PowerPC as separate registers; individual bit operations (and, or, xor, etc.) are supported. Tracking booleans in CR bits has several advantages: - Reduction in register pressure (because we no longer need GPRs to store boolean values). - Logical operations on booleans can be handled more efficiently; we used to have to move all results from comparisons into GPRs, perform promoted logical operations in GPRs, and then move the result back into condition register bits to be used by conditional branches. This can be very inefficient, because the throughput of these CR <-> GPR moves have high latency and low throughput (especially when other associated instructions are accounted for). - On the POWER7 and similar cores, we can increase total throughput by using the CR bits. CR bit operations have a dedicated functional unit. Most of this is more-or-less mechanical: Adjustments were needed in the calling-convention code, support was added for spilling/restoring individual condition-register bits, and conditional branch instruction definitions taking specific CR bits were added (plus patterns and code for generating bit-level operations). This is enabled by default when running at -O2 and higher. For -O0 and -O1, where the ability to debug is more important, this feature is disabled by default. Individual CR bits do not have assigned DWARF register numbers, and storing values in CR bits makes them invisible to the debugger. It is critical, however, that we don't move i1 values that have been promoted to larger values (such as those passed as function arguments) into bit registers only to quickly turn around and move the values back into GPRs (such as happens when values are returned by functions). A pair of target-specific DAG combines are added to remove the trunc/extends in: trunc(binary-ops(binary-ops(zext(x), zext(y)), ...) and: zext(binary-ops(binary-ops(trunc(x), trunc(y)), ...) In short, we only want to use CR bits where some of the i1 values come from comparisons or are used by conditional branches or selects. To put it another way, if we can do the entire i1 computation in GPRs, then we probably should (on the POWER7, the GPR-operation throughput is higher, and for all cores, the CR <-> GPR moves are expensive). POWER7 test-suite performance results (from 10 runs in each configuration): SingleSource/Benchmarks/Misc/mandel-2: 35% speedup MultiSource/Benchmarks/Prolangs-C++/city/city: 21% speedup MultiSource/Benchmarks/MiBench/automotive-susan: 23% speedup SingleSource/Benchmarks/CoyoteBench/huffbench: 13% speedup SingleSource/Benchmarks/Misc-C++/Large/sphereflake: 13% speedup SingleSource/Benchmarks/Misc-C++/mandel-text: 10% speedup SingleSource/Benchmarks/Misc-C++-EH/spirit: 10% slowdown MultiSource/Applications/lemon/lemon: 8% slowdown llvm-svn: 202451
2014-02-28 08:27:01 +08:00
case ISD::SETCC: {
SDNode *SN = SelectSETCC(N);
if (SN)
return SN;
break;
}
Change Select() from SDOperand Select(SDOperand N); to void Select(SDOperand &Result, SDOperand N); llvm-svn: 26067
2006-02-09 08:37:58 +08:00
case PPCISD::GlobalBaseReg:
Select() no longer require Result operand by reference. llvm-svn: 29898
2006-08-26 13:34:46 +08:00
return getGlobalBaseReg();
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
[PowerPC] Better lowering for add/or of a FrameIndex If we have an add (or an or that is really an add), where one operand is a FrameIndex and the other operand is a small constant, we can combine the lowering of the FrameIndex (which is lowered as an add of the FI and a zero offset) with the constant operand. Amusingly, this is an old potential improvement entry from lib/Target/PowerPC/README.txt which had never been resolved. In short, we used to lower: %X = alloca { i32, i32 } %Y = getelementptr {i32,i32}* %X, i32 0, i32 1 ret i32* %Y as: addi 3, 1, -8 ori 3, 3, 4 blr and now we produce: addi 3, 1, -4 blr which is much more sensible. llvm-svn: 224071
2014-12-12 06:51:06 +08:00
case ISD::FrameIndex:
return getFrameIndex(N, N);
Codegen vector predicate compares. llvm-svn: 27151
2006-03-26 18:06:40 +08:00
[PowerPC] Always use mfocrf if available When accessing just a single CR register, it is always preferable to use mfocrf instead of mfcr, if the former is available on the CPU. Current code makes that distinction in many, but not all places where a single CR register value is retrieved. One missing location is PPCRegisterInfo::lowerCRSpilling. To fix this and make this simpler in the future, this patch changes the bulk of the back-end to always assume mfocrf is available and simply generate it when needed. On machines that actually do not support mfocrf, the instruction is replaced by mfcr at the very end, in EmitInstruction. This has the additional benefit that we no longer need the MFCRpseud hack, since before EmitInstruction we always have a MFOCRF instruction pattern, which already models data flow as required. The patch also adds the MFOCRF8 version of the instruction, which was missing so far. Except for the PPCRegisterInfo::lowerCRSpilling case, no change in generated code intended. llvm-svn: 185556
2013-07-04 01:05:42 +08:00
case PPCISD::MFOCRF: {
Rename SDOperand to SDValue. llvm-svn: 54128
2008-07-28 05:46:04 +08:00
SDValue InFlag = N->getOperand(1);
[PowerPC] Always use mfocrf if available When accessing just a single CR register, it is always preferable to use mfocrf instead of mfcr, if the former is available on the CPU. Current code makes that distinction in many, but not all places where a single CR register value is retrieved. One missing location is PPCRegisterInfo::lowerCRSpilling. To fix this and make this simpler in the future, this patch changes the bulk of the back-end to always assume mfocrf is available and simply generate it when needed. On machines that actually do not support mfocrf, the instruction is replaced by mfcr at the very end, in EmitInstruction. This has the additional benefit that we no longer need the MFCRpseud hack, since before EmitInstruction we always have a MFOCRF instruction pattern, which already models data flow as required. The patch also adds the MFOCRF8 version of the instruction, which was missing so far. Except for the PPCRegisterInfo::lowerCRSpilling case, no change in generated code intended. llvm-svn: 185556
2013-07-04 01:05:42 +08:00
return CurDAG->getMachineNode(PPC::MFOCRF, dl, MVT::i32,
N->getOperand(0), InFlag);
Codegen vector predicate compares. llvm-svn: 27151
2006-03-26 18:06:40 +08:00
}
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
[PowerPC] Implement readcyclecounter for PPC32 We've long supported readcyclecounter on PPC64, but it is easier there (the read of the 64-bit time-base register can be accomplished via a single instruction). This now provides an implementation for PPC32 as well. On PPC32, the time-base register is still 64 bits, but can only be read 32 bits at a time via two separate SPRs. The ISA manual explains how to do this properly (it involves re-reading the upper bits and looping if the counter has wrapped while being read). This requires PPC to implement a custom integer splitting legalization for the READCYCLECOUNTER node, turning it into a target-specific SDAG node, which then gets turned into a pseudo-instruction, which is then expanded to the necessary sequence (which has three SPR reads, the comparison and the branch). Thanks to Paul Hargrove for pointing out to me that this was still unimplemented. llvm-svn: 223161
2014-12-03 06:01:00 +08:00
case PPCISD::READ_TIME_BASE: {
return CurDAG->getMachineNode(PPC::ReadTB, dl, MVT::i32, MVT::i32,
MVT::Other, N->getOperand(0));
}
[PowerPC] Implement BuildSDIVPow2, lower i64 pow2 sdiv using sradi PPCISelDAGToDAG contained existing code to lower i32 sdiv by a power-of-2 using srawi/addze, but did not implement the i64 case. DAGCombine now contains a callback specifically designed for this purpose (BuildSDIVPow2), and part of the logic has been moved to an implementation of that callback. Doing this lowering using BuildSDIVPow2 likely does not matter, compared to handling everything in PPCISelDAGToDAG, for the positive divisor case, but the negative divisor case, which generates an additional negation, can potentially benefit from additional folding from DAGCombine. Now, both the i32 and the i64 cases have been implemented. Fixes PR20732. llvm-svn: 224033
2014-12-12 02:37:52 +08:00
case PPCISD::SRA_ADDZE: {
SDValue N0 = N->getOperand(0);
SDValue ShiftAmt =
CurDAG->getTargetConstant(*cast<ConstantSDNode>(N->getOperand(1))->
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
getConstantIntValue(), dl,
N->getValueType(0));
[PowerPC] Implement BuildSDIVPow2, lower i64 pow2 sdiv using sradi PPCISelDAGToDAG contained existing code to lower i32 sdiv by a power-of-2 using srawi/addze, but did not implement the i64 case. DAGCombine now contains a callback specifically designed for this purpose (BuildSDIVPow2), and part of the logic has been moved to an implementation of that callback. Doing this lowering using BuildSDIVPow2 likely does not matter, compared to handling everything in PPCISelDAGToDAG, for the positive divisor case, but the negative divisor case, which generates an additional negation, can potentially benefit from additional folding from DAGCombine. Now, both the i32 and the i64 cases have been implemented. Fixes PR20732. llvm-svn: 224033
2014-12-12 02:37:52 +08:00
if (N->getValueType(0) == MVT::i64) {
SDNode *Op =
CurDAG->getMachineNode(PPC::SRADI, dl, MVT::i64, MVT::Glue,
N0, ShiftAmt);
return CurDAG->SelectNodeTo(N, PPC::ADDZE8, MVT::i64,
SDValue(Op, 0), SDValue(Op, 1));
} else {
assert(N->getValueType(0) == MVT::i32 &&
"Expecting i64 or i32 in PPCISD::SRA_ADDZE");
SDNode *Op =
CurDAG->getMachineNode(PPC::SRAWI, dl, MVT::i32, MVT::Glue,
N0, ShiftAmt);
return CurDAG->SelectNodeTo(N, PPC::ADDZE, MVT::i32,
SDValue(Op, 0), SDValue(Op, 1));
Add support for sdiv by 2^k and -2^k. Producing code like: _test: srawi r2, r3, 2 addze r3, r2 blr llvm-svn: 23052
2005-08-26 01:50:06 +08:00
}
Finish implementing SDIV/UDIV by copying over the majik constant code from ISelPattern llvm-svn: 23062
2005-08-26 06:04:30 +08:00
}
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
add an initial cut at preinc loads for ppc32. This is broken for ppc64 (because the 64-bit reg target versions aren't implemented yet), doesn't support r+r addr modes, and doesn't handle stores, but it works otherwise. :) This is disabled unless -enable-ppc-preinc is passed to llc for now. llvm-svn: 31621
2006-11-10 10:08:47 +08:00
case ISD::LOAD: {
// Handle preincrement loads.
Change SelectCode's argument from SDValue to SDNode *, to make it more clear what information these functions are actually using. This is also a micro-optimization, as passing a SDNode * around is simpler than passing a { SDNode *, int } by value or reference. llvm-svn: 92564
2010-01-05 09:24:18 +08:00
LoadSDNode *LD = cast<LoadSDNode>(N);
Rename MVT to EVT, in preparation for splitting SimpleValueType out into its own struct type. llvm-svn: 78610
2009-08-11 06:56:29 +08:00
EVT LoadedVT = LD->getMemoryVT();
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
add an initial cut at preinc loads for ppc32. This is broken for ppc64 (because the 64-bit reg target versions aren't implemented yet), doesn't support r+r addr modes, and doesn't handle stores, but it works otherwise. :) This is disabled unless -enable-ppc-preinc is passed to llc for now. llvm-svn: 31621
2006-11-10 10:08:47 +08:00
// Normal loads are handled by code generated from the .td file.
if (LD->getAddressingMode() != ISD::PRE_INC)
break;
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
Rename SDOperand to SDValue. llvm-svn: 54128
2008-07-28 05:46:04 +08:00
SDValue Offset = LD->getOffset();
Tighten iaddroff ComplexPattern. The iaddroff ComplexPattern is supposed to recognize displacement expressions that have been processed by a SelectAddressRegImm, which means it needs to accept TargetConstant and TargetGlobalAddress nodes. Currently, it erroneously also accepts some other nodes, in particular Constant and PPCISD::Lo. While this problem is currently latent, it would cause wrong-code bugs with a follow-on patch I'm about to commit, so this patch tightens the ComplexPattern. The equivalent change is made in PPCDAGToDAGISel::Select, where pre-inc load patterns are handled (as opposed to store patterns, the loads are handled in C++ code without making use of the .td ComplexPattern). llvm-svn: 177732
2013-03-22 22:58:17 +08:00
if (Offset.getOpcode() == ISD::TargetConstant ||
allow the offset of a preinc'd load to be the low-part of a global. This produces this clever code: _millisecs: lis r2, ha16(_Time.1182) lwzu r3, lo16(_Time.1182)(r2) lwz r2, 4(r2) addic r4, r2, 1 addze r3, r3 blr instead of this: _millisecs: lis r2, ha16(_Time.1182) la r3, lo16(_Time.1182)(r2) lwz r2, lo16(_Time.1182)(r2) lwz r3, 4(r3) addic r4, r3, 1 addze r3, r2 blr for: long %millisecs() { %tmp = load long* %Time.1182 ; <long> [#uses=1] %tmp1 = add long %tmp, 1 ; <long> [#uses=1] ret long %tmp1 } llvm-svn: 31673
2006-11-11 12:53:30 +08:00
Offset.getOpcode() == ISD::TargetGlobalAddress) {
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
fix ldu/stu jit encoding. Swith 64-bit preinc load instrs to use memri addrmodes. llvm-svn: 31757
2006-11-16 03:55:13 +08:00
unsigned Opcode;
bool isSExt = LD->getExtensionType() == ISD::SEXTLOAD;
Split EVT into MVT and EVT, the former representing _just_ a primitive type, while the latter is capable of representing either a primitive or an extended type. llvm-svn: 78713
2009-08-12 04:47:22 +08:00
if (LD->getValueType(0) != MVT::i64) {
fix ldu/stu jit encoding. Swith 64-bit preinc load instrs to use memri addrmodes. llvm-svn: 31757
2006-11-16 03:55:13 +08:00
// Handle PPC32 integer and normal FP loads.
Split EVT into MVT and EVT, the former representing _just_ a primitive type, while the latter is capable of representing either a primitive or an extended type. llvm-svn: 78713
2009-08-12 04:47:22 +08:00
assert((!isSExt || LoadedVT == MVT::i16) && "Invalid sext update load");
switch (LoadedVT.getSimpleVT().SimpleTy) {
llvm_unreachable->llvm_unreachable(0), LLVM_UNREACHABLE->llvm_unreachable. This adds location info for all llvm_unreachable calls (which is a macro now) in !NDEBUG builds. In NDEBUG builds location info and the message is off (it only prints "UREACHABLE executed"). llvm-svn: 75640
2009-07-15 00:55:14 +08:00
default: llvm_unreachable("Invalid PPC load type!");
Split EVT into MVT and EVT, the former representing _just_ a primitive type, while the latter is capable of representing either a primitive or an extended type. llvm-svn: 78713
2009-08-12 04:47:22 +08:00
case MVT::f64: Opcode = PPC::LFDU; break;
case MVT::f32: Opcode = PPC::LFSU; break;
case MVT::i32: Opcode = PPC::LWZU; break;
case MVT::i16: Opcode = isSExt ? PPC::LHAU : PPC::LHZU; break;
case MVT::i1:
case MVT::i8: Opcode = PPC::LBZU; break;
fix ldu/stu jit encoding. Swith 64-bit preinc load instrs to use memri addrmodes. llvm-svn: 31757
2006-11-16 03:55:13 +08:00
}
} else {
Split EVT into MVT and EVT, the former representing _just_ a primitive type, while the latter is capable of representing either a primitive or an extended type. llvm-svn: 78713
2009-08-12 04:47:22 +08:00
assert(LD->getValueType(0) == MVT::i64 && "Unknown load result type!");
assert((!isSExt || LoadedVT == MVT::i16) && "Invalid sext update load");
switch (LoadedVT.getSimpleVT().SimpleTy) {
llvm_unreachable->llvm_unreachable(0), LLVM_UNREACHABLE->llvm_unreachable. This adds location info for all llvm_unreachable calls (which is a macro now) in !NDEBUG builds. In NDEBUG builds location info and the message is off (it only prints "UREACHABLE executed"). llvm-svn: 75640
2009-07-15 00:55:14 +08:00
default: llvm_unreachable("Invalid PPC load type!");
Split EVT into MVT and EVT, the former representing _just_ a primitive type, while the latter is capable of representing either a primitive or an extended type. llvm-svn: 78713
2009-08-12 04:47:22 +08:00
case MVT::i64: Opcode = PPC::LDU; break;
case MVT::i32: Opcode = PPC::LWZU8; break;
case MVT::i16: Opcode = isSExt ? PPC::LHAU8 : PPC::LHZU8; break;
case MVT::i1:
case MVT::i8: Opcode = PPC::LBZU8; break;
fix ldu/stu jit encoding. Swith 64-bit preinc load instrs to use memri addrmodes. llvm-svn: 31757
2006-11-16 03:55:13 +08:00
}
}
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
Rename SDOperand to SDValue. llvm-svn: 54128
2008-07-28 05:46:04 +08:00
SDValue Chain = LD->getChain();
SDValue Base = LD->getBasePtr();
SDValue Ops[] = { Offset, Base, Chain };
Make TargetLowering::getPointerTy() taking DataLayout as an argument Summary: This change is part of a series of commits dedicated to have a single DataLayout during compilation by using always the one owned by the module. Reviewers: echristo Subscribers: jholewinski, ted, yaron.keren, rafael, llvm-commits Differential Revision: http://reviews.llvm.org/D11028 From: Mehdi Amini <mehdi.amini@apple.com> llvm-svn: 241775
2015-07-09 10:09:04 +08:00
return transferMemOperands(
N, CurDAG->getMachineNode(
Opcode, dl, LD->getValueType(0),
PPCLowering->getPointerTy(CurDAG->getDataLayout()), MVT::Other,
Ops));
add an initial cut at preinc loads for ppc32. This is broken for ppc64 (because the 64-bit reg target versions aren't implemented yet), doesn't support r+r addr modes, and doesn't handle stores, but it works otherwise. :) This is disabled unless -enable-ppc-preinc is passed to llc for now. llvm-svn: 31621
2006-11-10 10:08:47 +08:00
} else {
Add support for generating reg+reg (indexed) pre-inc loads on PPC. llvm-svn: 158823
2012-06-20 23:43:03 +08:00
unsigned Opcode;
bool isSExt = LD->getExtensionType() == ISD::SEXTLOAD;
if (LD->getValueType(0) != MVT::i64) {
// Handle PPC32 integer and normal FP loads.
assert((!isSExt || LoadedVT == MVT::i16) && "Invalid sext update load");
switch (LoadedVT.getSimpleVT().SimpleTy) {
default: llvm_unreachable("Invalid PPC load type!");
[PowerPC] Add support for the QPX vector instruction set This adds support for the QPX vector instruction set, which is used by the enhanced A2 cores on the IBM BG/Q supercomputers. QPX vectors are 256 bytes wide, holding 4 double-precision floating-point values. Boolean values, modeled here as <4 x i1> are actually also represented as floating-point values (essentially { -1, 1 } for { false, true }). QPX shares many features with Altivec and VSX, but is distinct from both of them. One major difference is that, instead of adding completely-separate vector registers, QPX vector registers are extensions of the scalar floating-point registers (lane 0 is the corresponding scalar floating-point value). The operations supported on QPX vectors mirrors that supported on the scalar floating-point values (with some additional ones for permutations and logical/comparison operations). I've been maintaining this support out-of-tree, as part of the bgclang project, for several years. This is not the entire bgclang patch set, but is most of the subset that can be cleanly integrated into LLVM proper at this time. Adding this to the LLVM backend is part of my efforts to rebase bgclang to the current LLVM trunk, but is independently useful (especially for codes that use LLVM as a JIT in library form). The assembler/disassembler test coverage is complete. The CodeGen test coverage is not, but I've included some tests, and more will be added as follow-up work. llvm-svn: 230413
2015-02-25 09:06:45 +08:00
case MVT::v4f64: Opcode = PPC::QVLFDUX; break; // QPX
case MVT::v4f32: Opcode = PPC::QVLFSUX; break; // QPX
Add support for generating reg+reg (indexed) pre-inc loads on PPC. llvm-svn: 158823
2012-06-20 23:43:03 +08:00
case MVT::f64: Opcode = PPC::LFDUX; break;
case MVT::f32: Opcode = PPC::LFSUX; break;
case MVT::i32: Opcode = PPC::LWZUX; break;
case MVT::i16: Opcode = isSExt ? PPC::LHAUX : PPC::LHZUX; break;
case MVT::i1:
case MVT::i8: Opcode = PPC::LBZUX; break;
}
} else {
assert(LD->getValueType(0) == MVT::i64 && "Unknown load result type!");
assert((!isSExt || LoadedVT == MVT::i16 || LoadedVT == MVT::i32) &&
"Invalid sext update load");
switch (LoadedVT.getSimpleVT().SimpleTy) {
default: llvm_unreachable("Invalid PPC load type!");
case MVT::i64: Opcode = PPC::LDUX; break;
case MVT::i32: Opcode = isSExt ? PPC::LWAUX : PPC::LWZUX8; break;
case MVT::i16: Opcode = isSExt ? PPC::LHAUX8 : PPC::LHZUX8; break;
case MVT::i1:
case MVT::i8: Opcode = PPC::LBZUX8; break;
}
}
SDValue Chain = LD->getChain();
SDValue Base = LD->getBasePtr();
Fix swapped BasePtr and Offset in pre-inc memory addresses. PPCTargetLowering::getPreIndexedAddressParts currently provides the base part of a memory address in the offset result, and the offset part in the base result. That swap is then undone again when an MI instruction is generated (in PPCDAGToDAGISel::Select for loads, and using .md Pat patterns for stores). This patch reverts this double swap, to make common code and back-end be in sync as to which part of the address is base and which is offset. To avoid performance regressions in certain cases, target code now checks whether the choice of base register would be rejected for pre-inc accesses by common code, and attempts to swap base and offset again in such cases. (Overall, this means that now pre-ice accesses are generated *more* frequently than before.) llvm-svn: 177733
2013-03-22 22:58:48 +08:00
SDValue Ops[] = { Base, Offset, Chain };
Make TargetLowering::getPointerTy() taking DataLayout as an argument Summary: This change is part of a series of commits dedicated to have a single DataLayout during compilation by using always the one owned by the module. Reviewers: echristo Subscribers: jholewinski, ted, yaron.keren, rafael, llvm-commits Differential Revision: http://reviews.llvm.org/D11028 From: Mehdi Amini <mehdi.amini@apple.com> llvm-svn: 241775
2015-07-09 10:09:04 +08:00
return transferMemOperands(
N, CurDAG->getMachineNode(
Opcode, dl, LD->getValueType(0),
PPCLowering->getPointerTy(CurDAG->getDataLayout()), MVT::Other,
Ops));
add an initial cut at preinc loads for ppc32. This is broken for ppc64 (because the 64-bit reg target versions aren't implemented yet), doesn't support r+r addr modes, and doesn't handle stores, but it works otherwise. :) This is disabled unless -enable-ppc-preinc is passed to llc for now. llvm-svn: 31621
2006-11-10 10:08:47 +08:00
}
}
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
Add support for ISD::AND, and its various optimized forms. llvm-svn: 22857
2005-08-18 15:30:46 +08:00
case ISD::AND: {
Fold AND and ROTL more often llvm-svn: 30577
2006-09-22 13:01:56 +08:00
unsigned Imm, Imm2, SH, MB, ME;
Optimize zext on PPC64. The zeroextend IR instruction is lowered to an 'and' node with an immediate mask operand, which in turn gets legalised to a sequence of ori's & ands. This can be done more efficiently using the rldicl instruction. Patch by Tobias von Koch. llvm-svn: 162724
2012-08-28 10:10:15 +08:00
uint64_t Imm64;
Fold AND and ROTL more often llvm-svn: 30577
2006-09-22 13:01:56 +08:00
Add support for ISD::AND, and its various optimized forms. llvm-svn: 22857
2005-08-18 15:30:46 +08:00
// If this is an and of a value rotated between 0 and 31 bits and then and'd
// with a mask, emit rlwinm
Implement a bunch of 64-bit cleanliness work. With this, treeadd builds (but doesn't work right). llvm-svn: 28921
2006-06-27 08:04:13 +08:00
if (isInt32Immediate(N->getOperand(1), Imm) &&
erect abstraction boundaries for accessing SDValue members, rename Val -> Node to reflect semantics llvm-svn: 55504
2008-08-29 05:40:38 +08:00
isRotateAndMask(N->getOperand(0).getNode(), Imm, false, SH, MB, ME)) {
Rename SDOperand to SDValue. llvm-svn: 54128
2008-07-28 05:46:04 +08:00
SDValue Val = N->getOperand(0).getOperand(0);
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
SDValue Ops[] = { Val, getI32Imm(SH, dl), getI32Imm(MB, dl),
getI32Imm(ME, dl) };
Convert SelectionDAG::SelectNodeTo to use ArrayRef. llvm-svn: 207377
2014-04-28 03:21:11 +08:00
return CurDAG->SelectNodeTo(N, PPC::RLWINM, MVT::i32, Ops);
Add support for ISD::AND, and its various optimized forms. llvm-svn: 22857
2005-08-18 15:30:46 +08:00
}
Fold AND and ROTL more often llvm-svn: 30577
2006-09-22 13:01:56 +08:00
// If this is just a masked value where the input is not handled above, and
// is not a rotate-left (handled by a pattern in the .td file), emit rlwinm
if (isInt32Immediate(N->getOperand(1), Imm) &&
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
isRunOfOnes(Imm, MB, ME) &&
Fold AND and ROTL more often llvm-svn: 30577
2006-09-22 13:01:56 +08:00
N->getOperand(0).getOpcode() != ISD::ROTL) {
Rename SDOperand to SDValue. llvm-svn: 54128
2008-07-28 05:46:04 +08:00
SDValue Val = N->getOperand(0);
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
SDValue Ops[] = { Val, getI32Imm(0, dl), getI32Imm(MB, dl),
getI32Imm(ME, dl) };
Convert SelectionDAG::SelectNodeTo to use ArrayRef. llvm-svn: 207377
2014-04-28 03:21:11 +08:00
return CurDAG->SelectNodeTo(N, PPC::RLWINM, MVT::i32, Ops);
Fold AND and ROTL more often llvm-svn: 30577
2006-09-22 13:01:56 +08:00
}
Optimize zext on PPC64. The zeroextend IR instruction is lowered to an 'and' node with an immediate mask operand, which in turn gets legalised to a sequence of ori's & ands. This can be done more efficiently using the rldicl instruction. Patch by Tobias von Koch. llvm-svn: 162724
2012-08-28 10:10:15 +08:00
// If this is a 64-bit zero-extension mask, emit rldicl.
if (isInt64Immediate(N->getOperand(1).getNode(), Imm64) &&
isMask_64(Imm64)) {
SDValue Val = N->getOperand(0);
MathExtras: Bring Count(Trailing|Leading)Ones and CountPopulation in line with countTrailingZeros Update all callers. llvm-svn: 228930
2015-02-12 23:35:40 +08:00
MB = 64 - countTrailingOnes(Imm64);
PPC: Optimize rldicl generation for masked shifts Masking operations (where only some number of the low bits are being kept) are selected to rldicl(x, 0, mb). If x is a logical right shift (which would become rldicl(y, 64-n, n)), we might be able to fold the two instructions together: rldicl(rldicl(x, 64-n, n), 0, mb) -> rldicl(x, 64-n, mb) for n <= mb The right shift is really a left rotate followed by a mask, and if the explicit mask is a more-restrictive sub-mask of the mask implied by the shift, only one rldicl is needed. llvm-svn: 195185
2013-11-20 09:10:15 +08:00
SH = 0;
// If the operand is a logical right shift, we can fold it into this
// instruction: rldicl(rldicl(x, 64-n, n), 0, mb) -> rldicl(x, 64-n, mb)
// for n <= mb. The right shift is really a left rotate followed by a
// mask, and this mask is a more-restrictive sub-mask of the mask implied
// by the shift.
if (Val.getOpcode() == ISD::SRL &&
isInt32Immediate(Val.getOperand(1).getNode(), Imm) && Imm <= MB) {
assert(Imm < 64 && "Illegal shift amount");
Val = Val.getOperand(0);
SH = 64 - Imm;
}
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
SDValue Ops[] = { Val, getI32Imm(SH, dl), getI32Imm(MB, dl) };
Convert SelectionDAG::SelectNodeTo to use ArrayRef. llvm-svn: 207377
2014-04-28 03:21:11 +08:00
return CurDAG->SelectNodeTo(N, PPC::RLDICL, MVT::i64, Ops);
Optimize zext on PPC64. The zeroextend IR instruction is lowered to an 'and' node with an immediate mask operand, which in turn gets legalised to a sequence of ori's & ands. This can be done more efficiently using the rldicl instruction. Patch by Tobias von Koch. llvm-svn: 162724
2012-08-28 10:10:15 +08:00
}
Fold AND and ROTL more often llvm-svn: 30577
2006-09-22 13:01:56 +08:00
// AND X, 0 -> 0, not "rlwinm 32".
if (isInt32Immediate(N->getOperand(1), Imm) && (Imm == 0)) {
Rename SDOperand to SDValue. llvm-svn: 54128
2008-07-28 05:46:04 +08:00
ReplaceUses(SDValue(N, 0), N->getOperand(1));
[C++] Use 'nullptr'. Target edition. llvm-svn: 207197
2014-04-25 13:30:21 +08:00
return nullptr;
Fold AND and ROTL more often llvm-svn: 30577
2006-09-22 13:01:56 +08:00
}
Fix one of the things in the todo file, and get a bit closer to folding constant offsets from statics into the address arithmetic. llvm-svn: 24999
2005-12-24 09:00:15 +08:00
// ISD::OR doesn't get all the bitfield insertion fun.
[PowerPC] Fix and(or(x, c1), c2) -> rlwimi generation PPCISelDAGToDAG has a transformation that generates a rlwimi instruction from an input pattern that looks like this: and(or(x, c1), c2) but the associated logic does not work if there are bits that are 1 in c1 but 0 in c2 (these are normally canonicalized away, but that can't happen if the 'or' has other users. Make sure we abort the transformation if such bits are discovered. Fixes PR24704. llvm-svn: 246900
2015-09-05 08:02:59 +08:00
// (and (or x, c1), c2) where isRunOfOnes(~(c1^c2)) might be a
// bitfield insert.
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
if (isInt32Immediate(N->getOperand(1), Imm) &&
Fix one of the things in the todo file, and get a bit closer to folding constant offsets from statics into the address arithmetic. llvm-svn: 24999
2005-12-24 09:00:15 +08:00
N->getOperand(0).getOpcode() == ISD::OR &&
Implement a bunch of 64-bit cleanliness work. With this, treeadd builds (but doesn't work right). llvm-svn: 28921
2006-06-27 08:04:13 +08:00
isInt32Immediate(N->getOperand(0).getOperand(1), Imm2)) {
[PowerPC] Fix and(or(x, c1), c2) -> rlwimi generation PPCISelDAGToDAG has a transformation that generates a rlwimi instruction from an input pattern that looks like this: and(or(x, c1), c2) but the associated logic does not work if there are bits that are 1 in c1 but 0 in c2 (these are normally canonicalized away, but that can't happen if the 'or' has other users. Make sure we abort the transformation if such bits are discovered. Fixes PR24704. llvm-svn: 246900
2015-09-05 08:02:59 +08:00
// The idea here is to check whether this is equivalent to:
// (c1 & m) | (x & ~m)
// where m is a run-of-ones mask. The logic here is that, for each bit in
// c1 and c2:
// - if both are 1, then the output will be 1.
// - if both are 0, then the output will be 0.
// - if the bit in c1 is 0, and the bit in c2 is 1, then the output will
// come from x.
// - if the bit in c1 is 1, and the bit in c2 is 0, then the output will
// be 0.
// If that last condition is never the case, then we can form m from the
// bits that are the same between c1 and c2.
Fix a compile crash building MultiSource/Applications/d with the new front-end. The PPC backend was generating random shift counts in this case, due to an uninitialized variable. llvm-svn: 25114
2006-01-06 02:32:49 +08:00
unsigned MB, ME;
[PowerPC] Fix and(or(x, c1), c2) -> rlwimi generation PPCISelDAGToDAG has a transformation that generates a rlwimi instruction from an input pattern that looks like this: and(or(x, c1), c2) but the associated logic does not work if there are bits that are 1 in c1 but 0 in c2 (these are normally canonicalized away, but that can't happen if the 'or' has other users. Make sure we abort the transformation if such bits are discovered. Fixes PR24704. llvm-svn: 246900
2015-09-05 08:02:59 +08:00
if (isRunOfOnes(~(Imm^Imm2), MB, ME) && !(~Imm & Imm2)) {
Rename SDOperand to SDValue. llvm-svn: 54128
2008-07-28 05:46:04 +08:00
SDValue Ops[] = { N->getOperand(0).getOperand(0),
Do not use getTargetNode() and SelectNodeTo() which takes more than 3 SDOperand arguments. Use the variants which take an array and number instead. llvm-svn: 29907
2006-08-27 16:14:06 +08:00
N->getOperand(0).getOperand(1),
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
getI32Imm(0, dl), getI32Imm(MB, dl),
getI32Imm(ME, dl) };
ArrayRefize getMachineNode(). No functionality change. llvm-svn: 179901
2013-04-20 06:22:57 +08:00
return CurDAG->getMachineNode(PPC::RLWIMI, dl, MVT::i32, Ops);
Fix one of the things in the todo file, and get a bit closer to folding constant offsets from statics into the address arithmetic. llvm-svn: 24999
2005-12-24 09:00:15 +08:00
}
}
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
Remove code for patterns that are autogenerated llvm-svn: 23532
2005-09-30 07:33:31 +08:00
// Other cases are autogenerated.
break;
Add support for ISD::AND, and its various optimized forms. llvm-svn: 22857
2005-08-18 15:30:46 +08:00
}
[PowerPC] Better lowering for add/or of a FrameIndex If we have an add (or an or that is really an add), where one operand is a FrameIndex and the other operand is a small constant, we can combine the lowering of the FrameIndex (which is lowered as an add of the FI and a zero offset) with the constant operand. Amusingly, this is an old potential improvement entry from lib/Target/PowerPC/README.txt which had never been resolved. In short, we used to lower: %X = alloca { i32, i32 } %Y = getelementptr {i32,i32}* %X, i32 0, i32 1 ret i32* %Y as: addi 3, 1, -8 ori 3, 3, 4 blr and now we produce: addi 3, 1, -4 blr which is much more sensible. llvm-svn: 224071
2014-12-12 06:51:06 +08:00
case ISD::OR: {
Split EVT into MVT and EVT, the former representing _just_ a primitive type, while the latter is capable of representing either a primitive or an extended type. llvm-svn: 78713
2009-08-12 04:47:22 +08:00
if (N->getValueType(0) == MVT::i32)
Fix PowerPC/2006-08-15-SelectionCrash.ll and simplify selection code. llvm-svn: 29715
2006-08-16 07:48:22 +08:00
if (SDNode *I = SelectBitfieldInsert(N))
return I;
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
[PowerPC] Better lowering for add/or of a FrameIndex If we have an add (or an or that is really an add), where one operand is a FrameIndex and the other operand is a small constant, we can combine the lowering of the FrameIndex (which is lowered as an add of the FI and a zero offset) with the constant operand. Amusingly, this is an old potential improvement entry from lib/Target/PowerPC/README.txt which had never been resolved. In short, we used to lower: %X = alloca { i32, i32 } %Y = getelementptr {i32,i32}* %X, i32 0, i32 1 ret i32* %Y as: addi 3, 1, -8 ori 3, 3, 4 blr and now we produce: addi 3, 1, -4 blr which is much more sensible. llvm-svn: 224071
2014-12-12 06:51:06 +08:00
short Imm;
if (N->getOperand(0)->getOpcode() == ISD::FrameIndex &&
isIntS16Immediate(N->getOperand(1), Imm)) {
APInt LHSKnownZero, LHSKnownOne;
CurDAG->computeKnownBits(N->getOperand(0), LHSKnownZero, LHSKnownOne);
// If this is equivalent to an add, then we can fold it with the
// FrameIndex calculation.
if ((LHSKnownZero.getZExtValue()|~(uint64_t)Imm) == ~0ULL)
return getFrameIndex(N, N->getOperand(0).getNode(), (int)Imm);
}
Remove code for patterns that are autogenerated llvm-svn: 23532
2005-09-30 07:33:31 +08:00
// Other cases are autogenerated.
break;
[PowerPC] Better lowering for add/or of a FrameIndex If we have an add (or an or that is really an add), where one operand is a FrameIndex and the other operand is a small constant, we can combine the lowering of the FrameIndex (which is lowered as an add of the FI and a zero offset) with the constant operand. Amusingly, this is an old potential improvement entry from lib/Target/PowerPC/README.txt which had never been resolved. In short, we used to lower: %X = alloca { i32, i32 } %Y = getelementptr {i32,i32}* %X, i32 0, i32 1 ret i32* %Y as: addi 3, 1, -8 ori 3, 3, 4 blr and now we produce: addi 3, 1, -4 blr which is much more sensible. llvm-svn: 224071
2014-12-12 06:51:06 +08:00
}
case ISD::ADD: {
short Imm;
if (N->getOperand(0)->getOpcode() == ISD::FrameIndex &&
isIntS16Immediate(N->getOperand(1), Imm))
return getFrameIndex(N, N->getOperand(0).getNode(), (int)Imm);
break;
}
Add shifts. llvm-svn: 22884
2005-08-19 07:38:00 +08:00
case ISD::SHL: {
unsigned Imm, SH, MB, ME;
erect abstraction boundaries for accessing SDValue members, rename Val -> Node to reflect semantics llvm-svn: 55504
2008-08-29 05:40:38 +08:00
if (isOpcWithIntImmediate(N->getOperand(0).getNode(), ISD::AND, Imm) &&
Write patterns for the various shl and srl patterns that don't involve doing something clever. llvm-svn: 23824
2005-10-20 02:42:01 +08:00
isRotateAndMask(N, Imm, true, SH, MB, ME)) {
Rename SDOperand to SDValue. llvm-svn: 54128
2008-07-28 05:46:04 +08:00
SDValue Ops[] = { N->getOperand(0).getOperand(0),
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
getI32Imm(SH, dl), getI32Imm(MB, dl),
getI32Imm(ME, dl) };
Convert SelectionDAG::SelectNodeTo to use ArrayRef. llvm-svn: 207377
2014-04-28 03:21:11 +08:00
return CurDAG->SelectNodeTo(N, PPC::RLWINM, MVT::i32, Ops);
Woo, it kinda works. We now generate this atrociously bad, but correct, code for long long foo(long long a, long long b) { return a + b; } _foo: or r2, r3, r3 or r3, r4, r4 or r4, r5, r5 or r5, r6, r6 rldicr r2, r2, 32, 31 rldicl r3, r3, 0, 32 rldicr r4, r4, 32, 31 rldicl r5, r5, 0, 32 or r2, r3, r2 or r3, r5, r4 add r4, r3, r2 rldicl r2, r4, 32, 32 or r4, r4, r4 or r3, r2, r2 blr llvm-svn: 23809
2005-10-19 09:12:32 +08:00
}
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
Write patterns for the various shl and srl patterns that don't involve doing something clever. llvm-svn: 23824
2005-10-20 02:42:01 +08:00
// Other cases are autogenerated.
break;
Add shifts. llvm-svn: 22884
2005-08-19 07:38:00 +08:00
}
case ISD::SRL: {
unsigned Imm, SH, MB, ME;
erect abstraction boundaries for accessing SDValue members, rename Val -> Node to reflect semantics llvm-svn: 55504
2008-08-29 05:40:38 +08:00
if (isOpcWithIntImmediate(N->getOperand(0).getNode(), ISD::AND, Imm) &&
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
isRotateAndMask(N, Imm, true, SH, MB, ME)) {
Rename SDOperand to SDValue. llvm-svn: 54128
2008-07-28 05:46:04 +08:00
SDValue Ops[] = { N->getOperand(0).getOperand(0),
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
getI32Imm(SH, dl), getI32Imm(MB, dl),
getI32Imm(ME, dl) };
Convert SelectionDAG::SelectNodeTo to use ArrayRef. llvm-svn: 207377
2014-04-28 03:21:11 +08:00
return CurDAG->SelectNodeTo(N, PPC::RLWINM, MVT::i32, Ops);
Woo, it kinda works. We now generate this atrociously bad, but correct, code for long long foo(long long a, long long b) { return a + b; } _foo: or r2, r3, r3 or r3, r4, r4 or r4, r5, r5 or r5, r6, r6 rldicr r2, r2, 32, 31 rldicl r3, r3, 0, 32 rldicr r4, r4, 32, 31 rldicl r5, r5, 0, 32 or r2, r3, r2 or r3, r5, r4 add r4, r3, r2 rldicl r2, r4, 32, 32 or r4, r4, r4 or r3, r2, r2 blr llvm-svn: 23809
2005-10-19 09:12:32 +08:00
}
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
Write patterns for the various shl and srl patterns that don't involve doing something clever. llvm-svn: 23824
2005-10-20 02:42:01 +08:00
// Other cases are autogenerated.
break;
Add shifts. llvm-svn: 22884
2005-08-19 07:38:00 +08:00
}
Add CR-bit tracking to the PowerPC backend for i1 values This change enables tracking i1 values in the PowerPC backend using the condition register bits. These bits can be treated on PowerPC as separate registers; individual bit operations (and, or, xor, etc.) are supported. Tracking booleans in CR bits has several advantages: - Reduction in register pressure (because we no longer need GPRs to store boolean values). - Logical operations on booleans can be handled more efficiently; we used to have to move all results from comparisons into GPRs, perform promoted logical operations in GPRs, and then move the result back into condition register bits to be used by conditional branches. This can be very inefficient, because the throughput of these CR <-> GPR moves have high latency and low throughput (especially when other associated instructions are accounted for). - On the POWER7 and similar cores, we can increase total throughput by using the CR bits. CR bit operations have a dedicated functional unit. Most of this is more-or-less mechanical: Adjustments were needed in the calling-convention code, support was added for spilling/restoring individual condition-register bits, and conditional branch instruction definitions taking specific CR bits were added (plus patterns and code for generating bit-level operations). This is enabled by default when running at -O2 and higher. For -O0 and -O1, where the ability to debug is more important, this feature is disabled by default. Individual CR bits do not have assigned DWARF register numbers, and storing values in CR bits makes them invisible to the debugger. It is critical, however, that we don't move i1 values that have been promoted to larger values (such as those passed as function arguments) into bit registers only to quickly turn around and move the values back into GPRs (such as happens when values are returned by functions). A pair of target-specific DAG combines are added to remove the trunc/extends in: trunc(binary-ops(binary-ops(zext(x), zext(y)), ...) and: zext(binary-ops(binary-ops(trunc(x), trunc(y)), ...) In short, we only want to use CR bits where some of the i1 values come from comparisons or are used by conditional branches or selects. To put it another way, if we can do the entire i1 computation in GPRs, then we probably should (on the POWER7, the GPR-operation throughput is higher, and for all cores, the CR <-> GPR moves are expensive). POWER7 test-suite performance results (from 10 runs in each configuration): SingleSource/Benchmarks/Misc/mandel-2: 35% speedup MultiSource/Benchmarks/Prolangs-C++/city/city: 21% speedup MultiSource/Benchmarks/MiBench/automotive-susan: 23% speedup SingleSource/Benchmarks/CoyoteBench/huffbench: 13% speedup SingleSource/Benchmarks/Misc-C++/Large/sphereflake: 13% speedup SingleSource/Benchmarks/Misc-C++/mandel-text: 10% speedup SingleSource/Benchmarks/Misc-C++-EH/spirit: 10% slowdown MultiSource/Applications/lemon/lemon: 8% slowdown llvm-svn: 202451
2014-02-28 08:27:01 +08:00
// FIXME: Remove this once the ANDI glue bug is fixed:
case PPCISD::ANDIo_1_EQ_BIT:
case PPCISD::ANDIo_1_GT_BIT: {
if (!ANDIGlueBug)
break;
EVT InVT = N->getOperand(0).getValueType();
assert((InVT == MVT::i64 || InVT == MVT::i32) &&
"Invalid input type for ANDIo_1_EQ_BIT");
unsigned Opcode = (InVT == MVT::i64) ? PPC::ANDIo8 : PPC::ANDIo;
SDValue AndI(CurDAG->getMachineNode(Opcode, dl, InVT, MVT::Glue,
N->getOperand(0),
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
CurDAG->getTargetConstant(1, dl, InVT)),
0);
Add CR-bit tracking to the PowerPC backend for i1 values This change enables tracking i1 values in the PowerPC backend using the condition register bits. These bits can be treated on PowerPC as separate registers; individual bit operations (and, or, xor, etc.) are supported. Tracking booleans in CR bits has several advantages: - Reduction in register pressure (because we no longer need GPRs to store boolean values). - Logical operations on booleans can be handled more efficiently; we used to have to move all results from comparisons into GPRs, perform promoted logical operations in GPRs, and then move the result back into condition register bits to be used by conditional branches. This can be very inefficient, because the throughput of these CR <-> GPR moves have high latency and low throughput (especially when other associated instructions are accounted for). - On the POWER7 and similar cores, we can increase total throughput by using the CR bits. CR bit operations have a dedicated functional unit. Most of this is more-or-less mechanical: Adjustments were needed in the calling-convention code, support was added for spilling/restoring individual condition-register bits, and conditional branch instruction definitions taking specific CR bits were added (plus patterns and code for generating bit-level operations). This is enabled by default when running at -O2 and higher. For -O0 and -O1, where the ability to debug is more important, this feature is disabled by default. Individual CR bits do not have assigned DWARF register numbers, and storing values in CR bits makes them invisible to the debugger. It is critical, however, that we don't move i1 values that have been promoted to larger values (such as those passed as function arguments) into bit registers only to quickly turn around and move the values back into GPRs (such as happens when values are returned by functions). A pair of target-specific DAG combines are added to remove the trunc/extends in: trunc(binary-ops(binary-ops(zext(x), zext(y)), ...) and: zext(binary-ops(binary-ops(trunc(x), trunc(y)), ...) In short, we only want to use CR bits where some of the i1 values come from comparisons or are used by conditional branches or selects. To put it another way, if we can do the entire i1 computation in GPRs, then we probably should (on the POWER7, the GPR-operation throughput is higher, and for all cores, the CR <-> GPR moves are expensive). POWER7 test-suite performance results (from 10 runs in each configuration): SingleSource/Benchmarks/Misc/mandel-2: 35% speedup MultiSource/Benchmarks/Prolangs-C++/city/city: 21% speedup MultiSource/Benchmarks/MiBench/automotive-susan: 23% speedup SingleSource/Benchmarks/CoyoteBench/huffbench: 13% speedup SingleSource/Benchmarks/Misc-C++/Large/sphereflake: 13% speedup SingleSource/Benchmarks/Misc-C++/mandel-text: 10% speedup SingleSource/Benchmarks/Misc-C++-EH/spirit: 10% slowdown MultiSource/Applications/lemon/lemon: 8% slowdown llvm-svn: 202451
2014-02-28 08:27:01 +08:00
SDValue CR0Reg = CurDAG->getRegister(PPC::CR0, MVT::i32);
SDValue SRIdxVal =
CurDAG->getTargetConstant(N->getOpcode() == PPCISD::ANDIo_1_EQ_BIT ?
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
PPC::sub_eq : PPC::sub_gt, dl, MVT::i32);
Add CR-bit tracking to the PowerPC backend for i1 values This change enables tracking i1 values in the PowerPC backend using the condition register bits. These bits can be treated on PowerPC as separate registers; individual bit operations (and, or, xor, etc.) are supported. Tracking booleans in CR bits has several advantages: - Reduction in register pressure (because we no longer need GPRs to store boolean values). - Logical operations on booleans can be handled more efficiently; we used to have to move all results from comparisons into GPRs, perform promoted logical operations in GPRs, and then move the result back into condition register bits to be used by conditional branches. This can be very inefficient, because the throughput of these CR <-> GPR moves have high latency and low throughput (especially when other associated instructions are accounted for). - On the POWER7 and similar cores, we can increase total throughput by using the CR bits. CR bit operations have a dedicated functional unit. Most of this is more-or-less mechanical: Adjustments were needed in the calling-convention code, support was added for spilling/restoring individual condition-register bits, and conditional branch instruction definitions taking specific CR bits were added (plus patterns and code for generating bit-level operations). This is enabled by default when running at -O2 and higher. For -O0 and -O1, where the ability to debug is more important, this feature is disabled by default. Individual CR bits do not have assigned DWARF register numbers, and storing values in CR bits makes them invisible to the debugger. It is critical, however, that we don't move i1 values that have been promoted to larger values (such as those passed as function arguments) into bit registers only to quickly turn around and move the values back into GPRs (such as happens when values are returned by functions). A pair of target-specific DAG combines are added to remove the trunc/extends in: trunc(binary-ops(binary-ops(zext(x), zext(y)), ...) and: zext(binary-ops(binary-ops(trunc(x), trunc(y)), ...) In short, we only want to use CR bits where some of the i1 values come from comparisons or are used by conditional branches or selects. To put it another way, if we can do the entire i1 computation in GPRs, then we probably should (on the POWER7, the GPR-operation throughput is higher, and for all cores, the CR <-> GPR moves are expensive). POWER7 test-suite performance results (from 10 runs in each configuration): SingleSource/Benchmarks/Misc/mandel-2: 35% speedup MultiSource/Benchmarks/Prolangs-C++/city/city: 21% speedup MultiSource/Benchmarks/MiBench/automotive-susan: 23% speedup SingleSource/Benchmarks/CoyoteBench/huffbench: 13% speedup SingleSource/Benchmarks/Misc-C++/Large/sphereflake: 13% speedup SingleSource/Benchmarks/Misc-C++/mandel-text: 10% speedup SingleSource/Benchmarks/Misc-C++-EH/spirit: 10% slowdown MultiSource/Applications/lemon/lemon: 8% slowdown llvm-svn: 202451
2014-02-28 08:27:01 +08:00
return CurDAG->SelectNodeTo(N, TargetOpcode::EXTRACT_SUBREG, MVT::i1,
CR0Reg, SRIdxVal,
SDValue(AndI.getNode(), 1) /* glue */);
}
implement the fold for: bool %test(int %X, int %Y) { %C = setne int %X, 0 ret bool %C } to: _test: addic r2, r3, -1 subfe r3, r2, r3 blr llvm-svn: 23089
2005-08-27 02:46:49 +08:00
case ISD::SELECT_CC: {
ISD::CondCode CC = cast<CondCodeSDNode>(N->getOperand(4))->get();
Make TargetLowering::getPointerTy() taking DataLayout as an argument Summary: This change is part of a series of commits dedicated to have a single DataLayout during compilation by using always the one owned by the module. Reviewers: echristo Subscribers: jholewinski, ted, yaron.keren, rafael, llvm-commits Differential Revision: http://reviews.llvm.org/D11028 From: Mehdi Amini <mehdi.amini@apple.com> llvm-svn: 241775
2015-07-09 10:09:04 +08:00
EVT PtrVT =
CurDAG->getTargetLoweringInfo().getPointerTy(CurDAG->getDataLayout());
Don't apply on PPC64 the 32bit ADDIC optimizations as there's no overflow with 32bit values. llvm-svn: 133439
2011-06-20 23:28:39 +08:00
bool isPPC64 = (PtrVT == MVT::i64);
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
Add CR-bit tracking to the PowerPC backend for i1 values This change enables tracking i1 values in the PowerPC backend using the condition register bits. These bits can be treated on PowerPC as separate registers; individual bit operations (and, or, xor, etc.) are supported. Tracking booleans in CR bits has several advantages: - Reduction in register pressure (because we no longer need GPRs to store boolean values). - Logical operations on booleans can be handled more efficiently; we used to have to move all results from comparisons into GPRs, perform promoted logical operations in GPRs, and then move the result back into condition register bits to be used by conditional branches. This can be very inefficient, because the throughput of these CR <-> GPR moves have high latency and low throughput (especially when other associated instructions are accounted for). - On the POWER7 and similar cores, we can increase total throughput by using the CR bits. CR bit operations have a dedicated functional unit. Most of this is more-or-less mechanical: Adjustments were needed in the calling-convention code, support was added for spilling/restoring individual condition-register bits, and conditional branch instruction definitions taking specific CR bits were added (plus patterns and code for generating bit-level operations). This is enabled by default when running at -O2 and higher. For -O0 and -O1, where the ability to debug is more important, this feature is disabled by default. Individual CR bits do not have assigned DWARF register numbers, and storing values in CR bits makes them invisible to the debugger. It is critical, however, that we don't move i1 values that have been promoted to larger values (such as those passed as function arguments) into bit registers only to quickly turn around and move the values back into GPRs (such as happens when values are returned by functions). A pair of target-specific DAG combines are added to remove the trunc/extends in: trunc(binary-ops(binary-ops(zext(x), zext(y)), ...) and: zext(binary-ops(binary-ops(trunc(x), trunc(y)), ...) In short, we only want to use CR bits where some of the i1 values come from comparisons or are used by conditional branches or selects. To put it another way, if we can do the entire i1 computation in GPRs, then we probably should (on the POWER7, the GPR-operation throughput is higher, and for all cores, the CR <-> GPR moves are expensive). POWER7 test-suite performance results (from 10 runs in each configuration): SingleSource/Benchmarks/Misc/mandel-2: 35% speedup MultiSource/Benchmarks/Prolangs-C++/city/city: 21% speedup MultiSource/Benchmarks/MiBench/automotive-susan: 23% speedup SingleSource/Benchmarks/CoyoteBench/huffbench: 13% speedup SingleSource/Benchmarks/Misc-C++/Large/sphereflake: 13% speedup SingleSource/Benchmarks/Misc-C++/mandel-text: 10% speedup SingleSource/Benchmarks/Misc-C++-EH/spirit: 10% slowdown MultiSource/Applications/lemon/lemon: 8% slowdown llvm-svn: 202451
2014-02-28 08:27:01 +08:00
// If this is a select of i1 operands, we'll pattern match it.
Reset the subtarget for DAGToDAG on every iteration of runOnMachineFunction. This required updating the generated functions and TD file accordingly to be pointers rather than const references. llvm-svn: 209375
2014-05-22 09:07:24 +08:00
if (PPCSubTarget->useCRBits() &&
Add CR-bit tracking to the PowerPC backend for i1 values This change enables tracking i1 values in the PowerPC backend using the condition register bits. These bits can be treated on PowerPC as separate registers; individual bit operations (and, or, xor, etc.) are supported. Tracking booleans in CR bits has several advantages: - Reduction in register pressure (because we no longer need GPRs to store boolean values). - Logical operations on booleans can be handled more efficiently; we used to have to move all results from comparisons into GPRs, perform promoted logical operations in GPRs, and then move the result back into condition register bits to be used by conditional branches. This can be very inefficient, because the throughput of these CR <-> GPR moves have high latency and low throughput (especially when other associated instructions are accounted for). - On the POWER7 and similar cores, we can increase total throughput by using the CR bits. CR bit operations have a dedicated functional unit. Most of this is more-or-less mechanical: Adjustments were needed in the calling-convention code, support was added for spilling/restoring individual condition-register bits, and conditional branch instruction definitions taking specific CR bits were added (plus patterns and code for generating bit-level operations). This is enabled by default when running at -O2 and higher. For -O0 and -O1, where the ability to debug is more important, this feature is disabled by default. Individual CR bits do not have assigned DWARF register numbers, and storing values in CR bits makes them invisible to the debugger. It is critical, however, that we don't move i1 values that have been promoted to larger values (such as those passed as function arguments) into bit registers only to quickly turn around and move the values back into GPRs (such as happens when values are returned by functions). A pair of target-specific DAG combines are added to remove the trunc/extends in: trunc(binary-ops(binary-ops(zext(x), zext(y)), ...) and: zext(binary-ops(binary-ops(trunc(x), trunc(y)), ...) In short, we only want to use CR bits where some of the i1 values come from comparisons or are used by conditional branches or selects. To put it another way, if we can do the entire i1 computation in GPRs, then we probably should (on the POWER7, the GPR-operation throughput is higher, and for all cores, the CR <-> GPR moves are expensive). POWER7 test-suite performance results (from 10 runs in each configuration): SingleSource/Benchmarks/Misc/mandel-2: 35% speedup MultiSource/Benchmarks/Prolangs-C++/city/city: 21% speedup MultiSource/Benchmarks/MiBench/automotive-susan: 23% speedup SingleSource/Benchmarks/CoyoteBench/huffbench: 13% speedup SingleSource/Benchmarks/Misc-C++/Large/sphereflake: 13% speedup SingleSource/Benchmarks/Misc-C++/mandel-text: 10% speedup SingleSource/Benchmarks/Misc-C++-EH/spirit: 10% slowdown MultiSource/Applications/lemon/lemon: 8% slowdown llvm-svn: 202451
2014-02-28 08:27:01 +08:00
N->getOperand(0).getValueType() == MVT::i1)
break;
Implement a bunch of 64-bit cleanliness work. With this, treeadd builds (but doesn't work right). llvm-svn: 28921
2006-06-27 08:04:13 +08:00
// Handle the setcc cases here. select_cc lhs, 0, 1, 0, cc
Don't apply on PPC64 the 32bit ADDIC optimizations as there's no overflow with 32bit values. llvm-svn: 133439
2011-06-20 23:28:39 +08:00
if (!isPPC64)
if (ConstantSDNode *N1C = dyn_cast<ConstantSDNode>(N->getOperand(1)))
if (ConstantSDNode *N2C = dyn_cast<ConstantSDNode>(N->getOperand(2)))
if (ConstantSDNode *N3C = dyn_cast<ConstantSDNode>(N->getOperand(3)))
if (N1C->isNullValue() && N3C->isNullValue() &&
N2C->getZExtValue() == 1ULL && CC == ISD::SETNE &&
// FIXME: Implement this optzn for PPC64.
N->getValueType(0) == MVT::i32) {
SDNode *Tmp =
CurDAG->getMachineNode(PPC::ADDIC, dl, MVT::i32, MVT::Glue,
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
N->getOperand(0), getI32Imm(~0U, dl));
Don't apply on PPC64 the 32bit ADDIC optimizations as there's no overflow with 32bit values. llvm-svn: 133439
2011-06-20 23:28:39 +08:00
return CurDAG->SelectNodeTo(N, PPC::SUBFE, MVT::i32,
SDValue(Tmp, 0), N->getOperand(0),
SDValue(Tmp, 1));
}
implement SELECT_CC fully for the DAG->DAG isel! llvm-svn: 23101
2005-08-27 05:23:58 +08:00
Eliminate remaining non-DebugLoc version of getTargetNode. llvm-svn: 63951
2009-02-07 03:16:40 +08:00
SDValue CCReg = SelectCC(N->getOperand(0), N->getOperand(1), CC, dl);
Add CR-bit tracking to the PowerPC backend for i1 values This change enables tracking i1 values in the PowerPC backend using the condition register bits. These bits can be treated on PowerPC as separate registers; individual bit operations (and, or, xor, etc.) are supported. Tracking booleans in CR bits has several advantages: - Reduction in register pressure (because we no longer need GPRs to store boolean values). - Logical operations on booleans can be handled more efficiently; we used to have to move all results from comparisons into GPRs, perform promoted logical operations in GPRs, and then move the result back into condition register bits to be used by conditional branches. This can be very inefficient, because the throughput of these CR <-> GPR moves have high latency and low throughput (especially when other associated instructions are accounted for). - On the POWER7 and similar cores, we can increase total throughput by using the CR bits. CR bit operations have a dedicated functional unit. Most of this is more-or-less mechanical: Adjustments were needed in the calling-convention code, support was added for spilling/restoring individual condition-register bits, and conditional branch instruction definitions taking specific CR bits were added (plus patterns and code for generating bit-level operations). This is enabled by default when running at -O2 and higher. For -O0 and -O1, where the ability to debug is more important, this feature is disabled by default. Individual CR bits do not have assigned DWARF register numbers, and storing values in CR bits makes them invisible to the debugger. It is critical, however, that we don't move i1 values that have been promoted to larger values (such as those passed as function arguments) into bit registers only to quickly turn around and move the values back into GPRs (such as happens when values are returned by functions). A pair of target-specific DAG combines are added to remove the trunc/extends in: trunc(binary-ops(binary-ops(zext(x), zext(y)), ...) and: zext(binary-ops(binary-ops(trunc(x), trunc(y)), ...) In short, we only want to use CR bits where some of the i1 values come from comparisons or are used by conditional branches or selects. To put it another way, if we can do the entire i1 computation in GPRs, then we probably should (on the POWER7, the GPR-operation throughput is higher, and for all cores, the CR <-> GPR moves are expensive). POWER7 test-suite performance results (from 10 runs in each configuration): SingleSource/Benchmarks/Misc/mandel-2: 35% speedup MultiSource/Benchmarks/Prolangs-C++/city/city: 21% speedup MultiSource/Benchmarks/MiBench/automotive-susan: 23% speedup SingleSource/Benchmarks/CoyoteBench/huffbench: 13% speedup SingleSource/Benchmarks/Misc-C++/Large/sphereflake: 13% speedup SingleSource/Benchmarks/Misc-C++/mandel-text: 10% speedup SingleSource/Benchmarks/Misc-C++-EH/spirit: 10% slowdown MultiSource/Applications/lemon/lemon: 8% slowdown llvm-svn: 202451
2014-02-28 08:27:01 +08:00
if (N->getValueType(0) == MVT::i1) {
// An i1 select is: (c & t) | (!c & f).
bool Inv;
unsigned Idx = getCRIdxForSetCC(CC, Inv);
unsigned SRI;
switch (Idx) {
default: llvm_unreachable("Invalid CC index");
case 0: SRI = PPC::sub_lt; break;
case 1: SRI = PPC::sub_gt; break;
case 2: SRI = PPC::sub_eq; break;
case 3: SRI = PPC::sub_un; break;
}
SDValue CCBit = CurDAG->getTargetExtractSubreg(SRI, dl, MVT::i1, CCReg);
SDValue NotCCBit(CurDAG->getMachineNode(PPC::CRNOR, dl, MVT::i1,
CCBit, CCBit), 0);
SDValue C = Inv ? NotCCBit : CCBit,
NotC = Inv ? CCBit : NotCCBit;
SDValue CAndT(CurDAG->getMachineNode(PPC::CRAND, dl, MVT::i1,
C, N->getOperand(2)), 0);
SDValue NotCAndF(CurDAG->getMachineNode(PPC::CRAND, dl, MVT::i1,
NotC, N->getOperand(3)), 0);
return CurDAG->SelectNodeTo(N, PPC::CROR, MVT::i1, CAndT, NotCAndF);
}
start using PPC predicates more consistently. llvm-svn: 31833
2006-11-18 06:10:59 +08:00
unsigned BROpc = getPredicateForSetCC(CC);
implement SELECT_CC fully for the DAG->DAG isel! llvm-svn: 23101
2005-08-27 05:23:58 +08:00
Modify the ppc backend to use two register classes for FP: F8RC and F4RC. These are used to represent float and double values, and the two regclasses contain the same physical registers. llvm-svn: 23577
2005-10-01 09:35:02 +08:00
unsigned SelectCCOp;
Split EVT into MVT and EVT, the former representing _just_ a primitive type, while the latter is capable of representing either a primitive or an extended type. llvm-svn: 78713
2009-08-12 04:47:22 +08:00
if (N->getValueType(0) == MVT::i32)
Implement a bunch of 64-bit cleanliness work. With this, treeadd builds (but doesn't work right). llvm-svn: 28921
2006-06-27 08:04:13 +08:00
SelectCCOp = PPC::SELECT_CC_I4;
Split EVT into MVT and EVT, the former representing _just_ a primitive type, while the latter is capable of representing either a primitive or an extended type. llvm-svn: 78713
2009-08-12 04:47:22 +08:00
else if (N->getValueType(0) == MVT::i64)
Implement a bunch of 64-bit cleanliness work. With this, treeadd builds (but doesn't work right). llvm-svn: 28921
2006-06-27 08:04:13 +08:00
SelectCCOp = PPC::SELECT_CC_I8;
Split EVT into MVT and EVT, the former representing _just_ a primitive type, while the latter is capable of representing either a primitive or an extended type. llvm-svn: 78713
2009-08-12 04:47:22 +08:00
else if (N->getValueType(0) == MVT::f32)
Add VSX Scalar loads and stores to the PPC back end This patch corresponds to review: http://reviews.llvm.org/D9440 It adds a new register class to the PPC back end to contain single precision values in VSX registers. Additionally, it adds scalar loads and stores for VSX registers. llvm-svn: 236755
2015-05-08 02:24:05 +08:00
if (PPCSubTarget->hasP8Vector())
SelectCCOp = PPC::SELECT_CC_VSSRC;
else
SelectCCOp = PPC::SELECT_CC_F4;
Split EVT into MVT and EVT, the former representing _just_ a primitive type, while the latter is capable of representing either a primitive or an extended type. llvm-svn: 78713
2009-08-12 04:47:22 +08:00
else if (N->getValueType(0) == MVT::f64)
[PATCH] Support select-cc for VSFRC when VSX is enabled A previous patch enabled SELECT_VSRC and SELECT_CC_VSRC for VSX to handle <2 x double> cases. This patch adds SELECT_VSFRC and SELECT_CC_VSFRC to allow use of all 64 vector-scalar registers for the f64 type when VSX is enabled. The changes are analogous to those in the previous patch. I've added a new variant to vsx.ll to test the code generation. (I also cleaned up a little formatting in PPCInstrVSX.td from the previous patch.) llvm-svn: 220395
2014-10-23 00:58:20 +08:00
if (PPCSubTarget->hasVSX())
SelectCCOp = PPC::SELECT_CC_VSFRC;
else
SelectCCOp = PPC::SELECT_CC_F8;
[PowerPC] Add support for the QPX vector instruction set This adds support for the QPX vector instruction set, which is used by the enhanced A2 cores on the IBM BG/Q supercomputers. QPX vectors are 256 bytes wide, holding 4 double-precision floating-point values. Boolean values, modeled here as <4 x i1> are actually also represented as floating-point values (essentially { -1, 1 } for { false, true }). QPX shares many features with Altivec and VSX, but is distinct from both of them. One major difference is that, instead of adding completely-separate vector registers, QPX vector registers are extensions of the scalar floating-point registers (lane 0 is the corresponding scalar floating-point value). The operations supported on QPX vectors mirrors that supported on the scalar floating-point values (with some additional ones for permutations and logical/comparison operations). I've been maintaining this support out-of-tree, as part of the bgclang project, for several years. This is not the entire bgclang patch set, but is most of the subset that can be cleanly integrated into LLVM proper at this time. Adding this to the LLVM backend is part of my efforts to rebase bgclang to the current LLVM trunk, but is independently useful (especially for codes that use LLVM as a JIT in library form). The assembler/disassembler test coverage is complete. The CodeGen test coverage is not, but I've included some tests, and more will be added as follow-up work. llvm-svn: 230413
2015-02-25 09:06:45 +08:00
else if (PPCSubTarget->hasQPX() && N->getValueType(0) == MVT::v4f64)
SelectCCOp = PPC::SELECT_CC_QFRC;
else if (PPCSubTarget->hasQPX() && N->getValueType(0) == MVT::v4f32)
SelectCCOp = PPC::SELECT_CC_QSRC;
else if (PPCSubTarget->hasQPX() && N->getValueType(0) == MVT::v4i1)
SelectCCOp = PPC::SELECT_CC_QBRC;
[PowerPC] Support select-cc for VSX The tests test/CodeGen/Generic/select-cc.ll and test/CodeGen/PowerPC/select-cc.ll both fail with VSX enabled. The problem is that the lowering logic for the SELECT and SELECT_CC operations doesn't currently support the VSX registers. This patch fixes that. In lib/Target/PowerPC/PPCInstrInfo.td, we have pseudos to handle this for other register classes. Similar pseudos are added in PPCInstrVSX.td (they must be there, because the "vsrc" register class definition appears there) for the VSRC register class. The SELECT_VSRC pseudo is then used in pattern matching for SELECT_CC. The rest of the patch just adds logic for SELECT_VSRC wherever similar logic appears for SELECT_VRRC. There are no new test cases because the existing tests above test this, along with a variant in test/CodeGen/PowerPC/vsx.ll. After discussion with Hal, a future patch will add similar _VSFRC variants to override f64 type handling (currently using F8RC). llvm-svn: 220385
2014-10-22 21:13:40 +08:00
else if (N->getValueType(0) == MVT::v2f64 ||
N->getValueType(0) == MVT::v2i64)
SelectCCOp = PPC::SELECT_CC_VSRC;
Add VRRC select support llvm-svn: 27543
2006-04-09 06:45:08 +08:00
else
SelectCCOp = PPC::SELECT_CC_VRRC;
Rename SDOperand to SDValue. llvm-svn: 54128
2008-07-28 05:46:04 +08:00
SDValue Ops[] = { CCReg, N->getOperand(2), N->getOperand(3),
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
getI32Imm(BROpc, dl) };
Convert SelectionDAG::SelectNodeTo to use ArrayRef. llvm-svn: 207377
2014-04-28 03:21:11 +08:00
return CurDAG->SelectNodeTo(N, SelectCCOp, N->getValueType(0), Ops);
implement the fold for: bool %test(int %X, int %Y) { %C = setne int %X, 0 ret bool %C } to: _test: addic r2, r3, -1 subfe r3, r2, r3 blr llvm-svn: 23089
2005-08-27 02:46:49 +08:00
}
[PowerPC] Lower VSELECT using xxsel when VSX is available With VSX there is a real vector select instruction, and so we should use it. Note that VSELECT will still scalarize for v2f64 because the corresponding SetCC result type (v2i64) is not currently a legal type. llvm-svn: 204801
2014-03-26 20:49:28 +08:00
case ISD::VSELECT:
Reset the subtarget for DAGToDAG on every iteration of runOnMachineFunction. This required updating the generated functions and TD file accordingly to be pointers rather than const references. llvm-svn: 209375
2014-05-22 09:07:24 +08:00
if (PPCSubTarget->hasVSX()) {
[PowerPC] Lower VSELECT using xxsel when VSX is available With VSX there is a real vector select instruction, and so we should use it. Note that VSELECT will still scalarize for v2f64 because the corresponding SetCC result type (v2i64) is not currently a legal type. llvm-svn: 204801
2014-03-26 20:49:28 +08:00
SDValue Ops[] = { N->getOperand(2), N->getOperand(1), N->getOperand(0) };
Convert SelectionDAG::SelectNodeTo to use ArrayRef. llvm-svn: 207377
2014-04-28 03:21:11 +08:00
return CurDAG->SelectNodeTo(N, PPC::XXSEL, N->getValueType(0), Ops);
[PowerPC] Lower VSELECT using xxsel when VSX is available With VSX there is a real vector select instruction, and so we should use it. Note that VSELECT will still scalarize for v2f64 because the corresponding SetCC result type (v2i64) is not currently a legal type. llvm-svn: 204801
2014-03-26 20:49:28 +08:00
}
[PowerPC] Generate VSX permutations for v2[fi]64 vectors llvm-svn: 204873
2014-03-27 06:58:37 +08:00
break;
case ISD::VECTOR_SHUFFLE:
Reset the subtarget for DAGToDAG on every iteration of runOnMachineFunction. This required updating the generated functions and TD file accordingly to be pointers rather than const references. llvm-svn: 209375
2014-05-22 09:07:24 +08:00
if (PPCSubTarget->hasVSX() && (N->getValueType(0) == MVT::v2f64 ||
[PowerPC] Generate VSX permutations for v2[fi]64 vectors llvm-svn: 204873
2014-03-27 06:58:37 +08:00
N->getValueType(0) == MVT::v2i64)) {
ShuffleVectorSDNode *SVN = cast<ShuffleVectorSDNode>(N);
Test Commit: iteratee Remove whitespace from blank lines. NFC llvm-svn: 254531
2015-12-03 02:53:33 +08:00
[PowerPC] Generate VSX permutations for v2[fi]64 vectors llvm-svn: 204873
2014-03-27 06:58:37 +08:00
SDValue Op1 = N->getOperand(SVN->getMaskElt(0) < 2 ? 0 : 1),
Op2 = N->getOperand(SVN->getMaskElt(1) < 2 ? 0 : 1);
unsigned DM[2];
for (int i = 0; i < 2; ++i)
if (SVN->getMaskElt(i) <= 0 || SVN->getMaskElt(i) == 2)
DM[i] = 0;
else
DM[i] = 1;
if (Op1 == Op2 && DM[0] == 0 && DM[1] == 0 &&
Op1.getOpcode() == ISD::SCALAR_TO_VECTOR &&
isa<LoadSDNode>(Op1.getOperand(0))) {
LoadSDNode *LD = cast<LoadSDNode>(Op1.getOperand(0));
SDValue Base, Offset;
Fix for bootstrap bug introduced in r244921 This revision has introduced an issue that only affects bootstrapped compiler when it is printing the ASM. It turns out that the new code path taken due to legalizing a scalar_to_vector of i64 -> v2i64 exposes a missing check in a micro optimization to change a load followed by a scalar_to_vector into a load and splat instruction on PPC. llvm-svn: 251798
2015-11-02 22:01:11 +08:00
if (LD->isUnindexed() && LD->hasOneUse() && Op1.hasOneUse() &&
[PowerPC] Fix invalid lxvdsx optimization (PR25157) PR25157 identifies a bug where a load plus a vector shuffle is incorrectly converted into an LXVDSX instruction. That optimization is only valid if the load is of a doubleword, and in the noted case, it was not. This corrects that problem. Joint patch with Eric Schweitz, who provided the bugpoint-reduced test case. llvm-svn: 250324
2015-10-15 04:45:00 +08:00
(LD->getMemoryVT() == MVT::f64 ||
LD->getMemoryVT() == MVT::i64) &&
[PowerPC] Generate VSX permutations for v2[fi]64 vectors llvm-svn: 204873
2014-03-27 06:58:37 +08:00
SelectAddrIdxOnly(LD->getBasePtr(), Base, Offset)) {
SDValue Chain = LD->getChain();
SDValue Ops[] = { Base, Offset, Chain };
return CurDAG->SelectNodeTo(N, PPC::LXVDSX,
Convert SelectionDAG::SelectNodeTo to use ArrayRef. llvm-svn: 207377
2014-04-28 03:21:11 +08:00
N->getValueType(0), Ops);
[PowerPC] Generate VSX permutations for v2[fi]64 vectors llvm-svn: 204873
2014-03-27 06:58:37 +08:00
}
}
[PPC64LE] Enable missing lxvdsx optimization, and related swap optimization When adding little-endian vector support for PowerPC last year, I inadvertently disabled an optimization that recognizes a load-splat idiom and generates the lxvdsx instruction. This patch moves the offending logic so lxvdsx is once again generated. This pattern is frequently generated by the vectorizer for scalar loads of an effective constant. Previously the lxvdsx instruction was wrongly listed as lane-sensitive for the VSX swap optimization (since both doublewords are identical, swaps are safe). This patch fixes this as well, so that vectorized code using lxvdsx can now have swaps removed from the computation. There is an existing test (@test50) in test/CodeGen/PowerPC/vsx.ll that checks for the missing optimization. However, vsx.ll was only being tested for POWER7 with big-endian code generation. I've added a little-endian RUN statement and expected LE code generation for all the tests in vsx.ll to give us a bit better VSX coverage, including what's needed for this patch. llvm-svn: 241183
2015-07-02 03:40:07 +08:00
// For little endian, we must swap the input operands and adjust
// the mask elements (reverse and invert them).
if (PPCSubTarget->isLittleEndian()) {
std::swap(Op1, Op2);
unsigned tmp = DM[0];
DM[0] = 1 - DM[1];
DM[1] = 1 - tmp;
}
SDValue DMV = CurDAG->getTargetConstant(DM[1] | (DM[0] << 1), dl,
MVT::i32);
[PowerPC] Generate VSX permutations for v2[fi]64 vectors llvm-svn: 204873
2014-03-27 06:58:37 +08:00
SDValue Ops[] = { Op1, Op2, DMV };
Convert SelectionDAG::SelectNodeTo to use ArrayRef. llvm-svn: 207377
2014-04-28 03:21:11 +08:00
return CurDAG->SelectNodeTo(N, PPC::XXPERMDI, N->getValueType(0), Ops);
[PowerPC] Generate VSX permutations for v2[fi]64 vectors llvm-svn: 204873
2014-03-27 06:58:37 +08:00
}
[PowerPC] Lower VSELECT using xxsel when VSX is available With VSX there is a real vector select instruction, and so we should use it. Note that VSELECT will still scalarize for v2f64 because the corresponding SetCC result type (v2i64) is not currently a legal type. llvm-svn: 204801
2014-03-26 20:49:28 +08:00
break;
Implement PPC counter loops as a late IR-level pass The old PPCCTRLoops pass, like the Hexagon pass version from which it was derived, could only handle some simple loops in canonical form. We cannot directly adapt the new Hexagon hardware loops pass, however, because the Hexagon pass contains a fundamental assumption that non-constant-trip-count loops will contain a guard, and this is not always true (the result being that incorrect negative counts can be generated). With this commit, we replace the pass with a late IR-level pass which makes use of SE to calculate the backedge-taken counts and safely generate the loop-count expressions (including any necessary max() parts). This IR level pass inserts custom intrinsics that are lowered into the desired decrement-and-branch instructions. The most fragile part of this new implementation is that interfering uses of the counter register must be detected on the IR level (and, on PPC, this also includes any indirect branches in addition to function calls). Also, to make all of this work, we need a variant of the mtctr instruction that is marked as having side effects. Without this, machine-code level CSE, DCE, etc. illegally transform the resulting code. Hopefully, this can be improved in the future. This new pass is smaller than the original (and much smaller than the new Hexagon hardware loops pass), and can handle many additional cases correctly. In addition, the preheader-creation code has been copied from LoopSimplify, and after we decide on where it belongs, this code will be refactored so that it can be explicitly shared (making this implementation even smaller). The new test-case files ctrloop-{le,lt,ne}.ll have been adapted from tests for the new Hexagon pass. There are a few classes of loops that this pass does not transform (noted by FIXMEs in the files), but these deficiencies can be addressed within the SE infrastructure (thus helping many other passes as well). llvm-svn: 181927
2013-05-16 05:37:41 +08:00
case PPCISD::BDNZ:
case PPCISD::BDZ: {
Reset the subtarget for DAGToDAG on every iteration of runOnMachineFunction. This required updating the generated functions and TD file accordingly to be pointers rather than const references. llvm-svn: 209375
2014-05-22 09:07:24 +08:00
bool IsPPC64 = PPCSubTarget->isPPC64();
Implement PPC counter loops as a late IR-level pass The old PPCCTRLoops pass, like the Hexagon pass version from which it was derived, could only handle some simple loops in canonical form. We cannot directly adapt the new Hexagon hardware loops pass, however, because the Hexagon pass contains a fundamental assumption that non-constant-trip-count loops will contain a guard, and this is not always true (the result being that incorrect negative counts can be generated). With this commit, we replace the pass with a late IR-level pass which makes use of SE to calculate the backedge-taken counts and safely generate the loop-count expressions (including any necessary max() parts). This IR level pass inserts custom intrinsics that are lowered into the desired decrement-and-branch instructions. The most fragile part of this new implementation is that interfering uses of the counter register must be detected on the IR level (and, on PPC, this also includes any indirect branches in addition to function calls). Also, to make all of this work, we need a variant of the mtctr instruction that is marked as having side effects. Without this, machine-code level CSE, DCE, etc. illegally transform the resulting code. Hopefully, this can be improved in the future. This new pass is smaller than the original (and much smaller than the new Hexagon hardware loops pass), and can handle many additional cases correctly. In addition, the preheader-creation code has been copied from LoopSimplify, and after we decide on where it belongs, this code will be refactored so that it can be explicitly shared (making this implementation even smaller). The new test-case files ctrloop-{le,lt,ne}.ll have been adapted from tests for the new Hexagon pass. There are a few classes of loops that this pass does not transform (noted by FIXMEs in the files), but these deficiencies can be addressed within the SE infrastructure (thus helping many other passes as well). llvm-svn: 181927
2013-05-16 05:37:41 +08:00
SDValue Ops[] = { N->getOperand(1), N->getOperand(0) };
return CurDAG->SelectNodeTo(N, N->getOpcode() == PPCISD::BDNZ ?
(IsPPC64 ? PPC::BDNZ8 : PPC::BDNZ) :
(IsPPC64 ? PPC::BDZ8 : PPC::BDZ),
Convert SelectionDAG::SelectNodeTo to use ArrayRef. llvm-svn: 207377
2014-04-28 03:21:11 +08:00
MVT::Other, Ops);
Implement PPC counter loops as a late IR-level pass The old PPCCTRLoops pass, like the Hexagon pass version from which it was derived, could only handle some simple loops in canonical form. We cannot directly adapt the new Hexagon hardware loops pass, however, because the Hexagon pass contains a fundamental assumption that non-constant-trip-count loops will contain a guard, and this is not always true (the result being that incorrect negative counts can be generated). With this commit, we replace the pass with a late IR-level pass which makes use of SE to calculate the backedge-taken counts and safely generate the loop-count expressions (including any necessary max() parts). This IR level pass inserts custom intrinsics that are lowered into the desired decrement-and-branch instructions. The most fragile part of this new implementation is that interfering uses of the counter register must be detected on the IR level (and, on PPC, this also includes any indirect branches in addition to function calls). Also, to make all of this work, we need a variant of the mtctr instruction that is marked as having side effects. Without this, machine-code level CSE, DCE, etc. illegally transform the resulting code. Hopefully, this can be improved in the future. This new pass is smaller than the original (and much smaller than the new Hexagon hardware loops pass), and can handle many additional cases correctly. In addition, the preheader-creation code has been copied from LoopSimplify, and after we decide on where it belongs, this code will be refactored so that it can be explicitly shared (making this implementation even smaller). The new test-case files ctrloop-{le,lt,ne}.ll have been adapted from tests for the new Hexagon pass. There are a few classes of loops that this pass does not transform (noted by FIXMEs in the files), but these deficiencies can be addressed within the SE infrastructure (thus helping many other passes as well). llvm-svn: 181927
2013-05-16 05:37:41 +08:00
}
convert PPC::BCC to use the 'pred' operand instead of separate predicate value and CR reg #. This requires swapping the order of these everywhere that touches BCC and requires us to write custom matching logic for PPCcondbranch :( llvm-svn: 31835
2006-11-18 06:37:34 +08:00
case PPCISD::COND_BRANCH: {
Reintroduce a comment that was removed with the AddToISelQueue changes. llvm-svn: 58760
2008-11-06 01:16:24 +08:00
// Op #0 is the Chain.
convert PPC::BCC to use the 'pred' operand instead of separate predicate value and CR reg #. This requires swapping the order of these everywhere that touches BCC and requires us to write custom matching logic for PPCcondbranch :( llvm-svn: 31835
2006-11-18 06:37:34 +08:00
// Op #1 is the PPC::PRED_* number.
// Op #2 is the CR#
// Op #3 is the Dest MBB
Eliminate the ISel priority queue, which used the topological order for a priority function. Instead, just iterate over the AllNodes list, which is already in topological order. This eliminates a fair amount of bookkeeping, and speeds up the isel phase by about 15% on many testcases. The impact on most targets is that AddToISelQueue calls can be simply removed. In the x86 target, there are two additional notable changes. The rule-bending AND+SHIFT optimization in MatchAddress that creates new pre-isel nodes during isel is now a little more verbose, but more robust. Instead of either creating an invalid DAG or creating an invalid topological sort, as it has historically done, it can now just insert the new nodes into the node list at a position where they will be consistent with the topological ordering. Also, the address-matching code has logic that checked to see if a node was "already selected". However, when a node is selected, it has all its uses taken away via ReplaceAllUsesWith or equivalent, so it won't recieve any further visits from MatchAddress. This code is now removed. llvm-svn: 58748
2008-11-05 12:14:16 +08:00
// Op #4 is the Flag.
Prevent PPC::BCC first operand, the PRED number, from being isel'd into a LI instruction. llvm-svn: 37790
2007-06-29 09:25:06 +08:00
// Prevent PPC::PRED_* from being selected into LI.
Rename SDOperand to SDValue. llvm-svn: 54128
2008-07-28 05:46:04 +08:00
SDValue Pred =
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
getI32Imm(cast<ConstantSDNode>(N->getOperand(1))->getZExtValue(), dl);
Rename SDOperand to SDValue. llvm-svn: 54128
2008-07-28 05:46:04 +08:00
SDValue Ops[] = { Pred, N->getOperand(2), N->getOperand(3),
convert PPC::BCC to use the 'pred' operand instead of separate predicate value and CR reg #. This requires swapping the order of these everywhere that touches BCC and requires us to write custom matching logic for PPCcondbranch :( llvm-svn: 31835
2006-11-18 06:37:34 +08:00
N->getOperand(0), N->getOperand(4) };
Convert SelectionDAG::SelectNodeTo to use ArrayRef. llvm-svn: 207377
2014-04-28 03:21:11 +08:00
return CurDAG->SelectNodeTo(N, PPC::BCC, MVT::Other, Ops);
convert PPC::BCC to use the 'pred' operand instead of separate predicate value and CR reg #. This requires swapping the order of these everywhere that touches BCC and requires us to write custom matching logic for PPCcondbranch :( llvm-svn: 31835
2006-11-18 06:37:34 +08:00
}
Remove BRTWOWAY* Make the PPC backend not dependent on BRTWOWAY_CC and make the branch selector smarter about the code it generates, fixing a case in the readme. llvm-svn: 26814
2006-03-17 09:40:33 +08:00
case ISD::BR_CC: {
Implement selection for branches. llvm-svn: 22951
2005-08-22 02:50:37 +08:00
ISD::CondCode CC = cast<CondCodeSDNode>(N->getOperand(1))->get();
Add CR-bit tracking to the PowerPC backend for i1 values This change enables tracking i1 values in the PowerPC backend using the condition register bits. These bits can be treated on PowerPC as separate registers; individual bit operations (and, or, xor, etc.) are supported. Tracking booleans in CR bits has several advantages: - Reduction in register pressure (because we no longer need GPRs to store boolean values). - Logical operations on booleans can be handled more efficiently; we used to have to move all results from comparisons into GPRs, perform promoted logical operations in GPRs, and then move the result back into condition register bits to be used by conditional branches. This can be very inefficient, because the throughput of these CR <-> GPR moves have high latency and low throughput (especially when other associated instructions are accounted for). - On the POWER7 and similar cores, we can increase total throughput by using the CR bits. CR bit operations have a dedicated functional unit. Most of this is more-or-less mechanical: Adjustments were needed in the calling-convention code, support was added for spilling/restoring individual condition-register bits, and conditional branch instruction definitions taking specific CR bits were added (plus patterns and code for generating bit-level operations). This is enabled by default when running at -O2 and higher. For -O0 and -O1, where the ability to debug is more important, this feature is disabled by default. Individual CR bits do not have assigned DWARF register numbers, and storing values in CR bits makes them invisible to the debugger. It is critical, however, that we don't move i1 values that have been promoted to larger values (such as those passed as function arguments) into bit registers only to quickly turn around and move the values back into GPRs (such as happens when values are returned by functions). A pair of target-specific DAG combines are added to remove the trunc/extends in: trunc(binary-ops(binary-ops(zext(x), zext(y)), ...) and: zext(binary-ops(binary-ops(trunc(x), trunc(y)), ...) In short, we only want to use CR bits where some of the i1 values come from comparisons or are used by conditional branches or selects. To put it another way, if we can do the entire i1 computation in GPRs, then we probably should (on the POWER7, the GPR-operation throughput is higher, and for all cores, the CR <-> GPR moves are expensive). POWER7 test-suite performance results (from 10 runs in each configuration): SingleSource/Benchmarks/Misc/mandel-2: 35% speedup MultiSource/Benchmarks/Prolangs-C++/city/city: 21% speedup MultiSource/Benchmarks/MiBench/automotive-susan: 23% speedup SingleSource/Benchmarks/CoyoteBench/huffbench: 13% speedup SingleSource/Benchmarks/Misc-C++/Large/sphereflake: 13% speedup SingleSource/Benchmarks/Misc-C++/mandel-text: 10% speedup SingleSource/Benchmarks/Misc-C++-EH/spirit: 10% slowdown MultiSource/Applications/lemon/lemon: 8% slowdown llvm-svn: 202451
2014-02-28 08:27:01 +08:00
unsigned PCC = getPredicateForSetCC(CC);
if (N->getOperand(2).getValueType() == MVT::i1) {
unsigned Opc;
bool Swap;
switch (PCC) {
default: llvm_unreachable("Unexpected Boolean-operand predicate");
case PPC::PRED_LT: Opc = PPC::CRANDC; Swap = true; break;
case PPC::PRED_LE: Opc = PPC::CRORC; Swap = true; break;
case PPC::PRED_EQ: Opc = PPC::CREQV; Swap = false; break;
case PPC::PRED_GE: Opc = PPC::CRORC; Swap = false; break;
case PPC::PRED_GT: Opc = PPC::CRANDC; Swap = false; break;
case PPC::PRED_NE: Opc = PPC::CRXOR; Swap = false; break;
}
SDValue BitComp(CurDAG->getMachineNode(Opc, dl, MVT::i1,
N->getOperand(Swap ? 3 : 2),
N->getOperand(Swap ? 2 : 3)), 0);
return CurDAG->SelectNodeTo(N, PPC::BC, MVT::Other,
BitComp, N->getOperand(4), N->getOperand(0));
}
Eliminate remaining non-DebugLoc version of getTargetNode. llvm-svn: 63951
2009-02-07 03:16:40 +08:00
SDValue CondCode = SelectCC(N->getOperand(2), N->getOperand(3), CC, dl);
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
SDValue Ops[] = { getI32Imm(PCC, dl), CondCode,
Do not use getTargetNode() and SelectNodeTo() which takes more than 3 SDOperand arguments. Use the variants which take an array and number instead. llvm-svn: 29907
2006-08-27 16:14:06 +08:00
N->getOperand(4), N->getOperand(0) };
Convert SelectionDAG::SelectNodeTo to use ArrayRef. llvm-svn: 207377
2014-04-28 03:21:11 +08:00
return CurDAG->SelectNodeTo(N, PPC::BCC, MVT::Other, Ops);
Implement selection for branches. llvm-svn: 22951
2005-08-22 02:50:37 +08:00
}
JumpTable support! What this represents is working asm and jit support for x86 and ppc for 100% dense switch statements when relocations are non-PIC. This support will be extended and enhanced in the coming days to support PIC, and less dense forms of jump tables. llvm-svn: 27947
2006-04-23 02:53:45 +08:00
case ISD::BRIND: {
Work around a nasty tblgen bug where it doesn't add operands for varargs nodes correctly. llvm-svn: 28745
2006-06-10 09:15:02 +08:00
// FIXME: Should custom lower this.
Rename SDOperand to SDValue. llvm-svn: 54128
2008-07-28 05:46:04 +08:00
SDValue Chain = N->getOperand(0);
SDValue Target = N->getOperand(1);
Split EVT into MVT and EVT, the former representing _just_ a primitive type, while the latter is capable of representing either a primitive or an extended type. llvm-svn: 78713
2009-08-12 04:47:22 +08:00
unsigned Opc = Target.getValueType() == MVT::i32 ? PPC::MTCTR : PPC::MTCTR8;
Fix wrong usages of CTR/MCTR where CTR8/MCTR8 was meant. - Check for MTCTR8 in addition to MTCTR when looking up a hazard. - When lowering an indirect call use CTR8 when targeting 64bit. - Introduce BCTR8 that uses CTR8 and use it on 64bit when expanding ISD::BRIND. The last change fixes PR8487. With those changes, we are able to compile a running "ls" and "sh" on FreeBSD/PowerPC64. llvm-svn: 132552
2011-06-03 23:47:49 +08:00
unsigned Reg = Target.getValueType() == MVT::i32 ? PPC::BCTR : PPC::BCTR8;
MTCTR needs to be glued to BCTR so that CTR is not marked dead in MTCTR (another find by -verify-machineinstrs) llvm-svn: 146137
2011-12-08 12:36:44 +08:00
Chain = SDValue(CurDAG->getMachineNode(Opc, dl, MVT::Glue, Target,
Rename getTargetNode to getMachineNode, for consistency with the naming scheme used in SelectionDAG, where there are multiple kinds of "target" nodes, but "machine" nodes are nodes which represent a MachineInstr. llvm-svn: 82790
2009-09-26 02:54:59 +08:00
Chain), 0);
Fix wrong usages of CTR/MCTR where CTR8/MCTR8 was meant. - Check for MTCTR8 in addition to MTCTR when looking up a hazard. - When lowering an indirect call use CTR8 when targeting 64bit. - Introduce BCTR8 that uses CTR8 and use it on 64bit when expanding ISD::BRIND. The last change fixes PR8487. With those changes, we are able to compile a running "ls" and "sh" on FreeBSD/PowerPC64. llvm-svn: 132552
2011-06-03 23:47:49 +08:00
return CurDAG->SelectNodeTo(N, Reg, MVT::Other, Chain);
JumpTable support! What this represents is working asm and jit support for x86 and ppc for 100% dense switch statements when relocations are non-PIC. This support will be extended and enhanced in the coming days to support PIC, and less dense forms of jump tables. llvm-svn: 27947
2006-04-23 02:53:45 +08:00
}
This patch implements medium code model support for 64-bit PowerPC. The default for 64-bit PowerPC is small code model, in which TOC entries must be addressable using a 16-bit offset from the TOC pointer. Additionally, only TOC entries are addressed via the TOC pointer. With medium code model, TOC entries and data sections can all be addressed via the TOC pointer using a 32-bit offset. Cooperation with the linker allows 16-bit offsets to be used when these are sufficient, reducing the number of extra instructions that need to be executed. Medium code model also does not generate explicit TOC entries in ".section toc" for variables that are wholly internal to the compilation unit. Consider a load of an external 4-byte integer. With small code model, the compiler generates: ld 3, .LC1@toc(2) lwz 4, 0(3) .section .toc,"aw",@progbits .LC1: .tc ei[TC],ei With medium model, it instead generates: addis 3, 2, .LC1@toc@ha ld 3, .LC1@toc@l(3) lwz 4, 0(3) .section .toc,"aw",@progbits .LC1: .tc ei[TC],ei Here .LC1@toc@ha is a relocation requesting the upper 16 bits of the 32-bit offset of ei's TOC entry from the TOC base pointer. Similarly, .LC1@toc@l is a relocation requesting the lower 16 bits. Note that if the linker determines that ei's TOC entry is within a 16-bit offset of the TOC base pointer, it will replace the "addis" with a "nop", and replace the "ld" with the identical "ld" instruction from the small code model example. Consider next a load of a function-scope static integer. For small code model, the compiler generates: ld 3, .LC1@toc(2) lwz 4, 0(3) .section .toc,"aw",@progbits .LC1: .tc test_fn_static.si[TC],test_fn_static.si .type test_fn_static.si,@object .local test_fn_static.si .comm test_fn_static.si,4,4 For medium code model, the compiler generates: addis 3, 2, test_fn_static.si@toc@ha addi 3, 3, test_fn_static.si@toc@l lwz 4, 0(3) .type test_fn_static.si,@object .local test_fn_static.si .comm test_fn_static.si,4,4 Again, the linker may replace the "addis" with a "nop", calculating only a 16-bit offset when this is sufficient. Note that it would be more efficient for the compiler to generate: addis 3, 2, test_fn_static.si@toc@ha lwz 4, test_fn_static.si@toc@l(3) The current patch does not perform this optimization yet. This will be addressed as a peephole optimization in a later patch. For the moment, the default code model for 64-bit PowerPC will remain the small code model. We plan to eventually change the default to medium code model, which matches current upstream GCC behavior. Note that the different code models are ABI-compatible, so code compiled with different models will be linked and execute correctly. I've tested the regression suite and the application/benchmark test suite in two ways: Once with the patch as submitted here, and once with additional logic to force medium code model as the default. The tests all compile cleanly, with one exception. The mandel-2 application test fails due to an unrelated ABI compatibility with passing complex numbers. It just so happens that small code model was incredibly lucky, in that temporary values in floating-point registers held the expected values needed by the external library routine that was called incorrectly. My current thought is to correct the ABI problems with _Complex before making medium code model the default, to avoid introducing this "regression." Here are a few comments on how the patch works, since the selection code can be difficult to follow: The existing logic for small code model defines three pseudo-instructions: LDtoc for most uses, LDtocJTI for jump table addresses, and LDtocCPT for constant pool addresses. These are expanded by SelectCodeCommon(). The pseudo-instruction approach doesn't work for medium code model, because we need to generate two instructions when we match the same pattern. Instead, new logic in PPCDAGToDAGISel::Select() intercepts the TOC_ENTRY node for medium code model, and generates an ADDIStocHA followed by either a LDtocL or an ADDItocL. These new node types correspond naturally to the sequences described above. The addis/ld sequence is generated for the following cases: * Jump table addresses * Function addresses * External global variables * Tentative definitions of global variables (common linkage) The addis/addi sequence is generated for the following cases: * Constant pool entries * File-scope static global variables * Function-scope static variables Expanding to the two-instruction sequences at select time exposes the instructions to subsequent optimization, particularly scheduling. The rest of the processing occurs at assembly time, in PPCAsmPrinter::EmitInstruction. Each of the instructions is converted to a "real" PowerPC instruction. When a TOC entry needs to be created, this is done here in the same manner as for the existing LDtoc, LDtocJTI, and LDtocCPT pseudo-instructions (I factored out a new routine to handle this). I had originally thought that if a TOC entry was needed for LDtocL or ADDItocL, it would already have been generated for the previous ADDIStocHA. However, at higher optimization levels, the ADDIStocHA may appear in a different block, which may be assembled textually following the block containing the LDtocL or ADDItocL. So it is necessary to include the possibility of creating a new TOC entry for those two instructions. Note that for LDtocL, we generate a new form of LD called LDrs. This allows specifying the @toc@l relocation for the offset field of the LD instruction (i.e., the offset is replaced by a SymbolLo relocation). When the peephole optimization described above is added, we will need to do similar things for all immediate-form load and store operations. The seven "mcm-n.ll" test cases are kept separate because otherwise the intermingling of various TOC entries and so forth makes the tests fragile and hard to understand. The above assumes use of an external assembler. For use of the integrated assembler, new relocations are added and used by PPCELFObjectWriter. Testing is done with "mcm-obj.ll", which tests for proper generation of the various relocations for the same sequences tested with the external assembler. llvm-svn: 168708
2012-11-28 01:35:46 +08:00
case PPCISD::TOC_ENTRY: {
Add support for small-model PIC for PowerPC. Summary: Large-model was added first. With the addition of support for multiple PIC models in LLVM, now add small-model PIC for 32-bit PowerPC, SysV4 ABI. This generates more optimal code, for shared libraries with less than about 16380 data objects. Test Plan: Test cases added or updated Reviewers: joerg, hfinkel Reviewed By: hfinkel Subscribers: jholewinski, mcrosier, emaste, llvm-commits Differential Revision: http://reviews.llvm.org/D5399 llvm-svn: 221791
2014-11-12 23:16:30 +08:00
assert ((PPCSubTarget->isPPC64() || PPCSubTarget->isSVR4ABI()) &&
"Only supported for 64-bit ABI and 32-bit SVR4");
[PowerPC] 32-bit ELF PIC support This adds initial support for PPC32 ELF PIC (Position Independent Code; the -fPIC variety), thus rectifying a long-standing deficiency in the PowerPC backend. Patch by Justin Hibbits! llvm-svn: 213427
2014-07-19 07:29:49 +08:00
if (PPCSubTarget->isSVR4ABI() && !PPCSubTarget->isPPC64()) {
SDValue GA = N->getOperand(0);
[PowerPC] Make LDtocL and friends invariant loads LDtocL, and other loads that roughly correspond to the TOC_ENTRY SDAG node, represent loads from the TOC, which is invariant. As a result, these loads can be hoisted out of loops, etc. In order to do this, we need to generate GOT-style MMOs for TOC_ENTRY, which requires treating it as a legitimate memory intrinsic node type. Once this is done, the MMO transfer is automatically handled for TableGen-driven instruction selection, and for nodes generated directly in PPCISelDAGToDAG, we need to transfer the MMOs manually. Also, we were not transferring MMOs associated with pre-increment loads, so do that too. Lastly, this fixes an exposed bug where R30 was not added as a defined operand of UpdateGBR. This problem was highlighted by an example (used to generate the test case) posted to llvmdev by Francois Pichet. llvm-svn: 230553
2015-02-26 05:36:59 +08:00
return transferMemOperands(N, CurDAG->getMachineNode(PPC::LWZtoc, dl,
MVT::i32, GA, N->getOperand(1)));
Test commit. Fix whitespace from a previous patch of mine. llvm-svn: 216650
2014-08-28 12:40:55 +08:00
}
This patch implements medium code model support for 64-bit PowerPC. The default for 64-bit PowerPC is small code model, in which TOC entries must be addressable using a 16-bit offset from the TOC pointer. Additionally, only TOC entries are addressed via the TOC pointer. With medium code model, TOC entries and data sections can all be addressed via the TOC pointer using a 32-bit offset. Cooperation with the linker allows 16-bit offsets to be used when these are sufficient, reducing the number of extra instructions that need to be executed. Medium code model also does not generate explicit TOC entries in ".section toc" for variables that are wholly internal to the compilation unit. Consider a load of an external 4-byte integer. With small code model, the compiler generates: ld 3, .LC1@toc(2) lwz 4, 0(3) .section .toc,"aw",@progbits .LC1: .tc ei[TC],ei With medium model, it instead generates: addis 3, 2, .LC1@toc@ha ld 3, .LC1@toc@l(3) lwz 4, 0(3) .section .toc,"aw",@progbits .LC1: .tc ei[TC],ei Here .LC1@toc@ha is a relocation requesting the upper 16 bits of the 32-bit offset of ei's TOC entry from the TOC base pointer. Similarly, .LC1@toc@l is a relocation requesting the lower 16 bits. Note that if the linker determines that ei's TOC entry is within a 16-bit offset of the TOC base pointer, it will replace the "addis" with a "nop", and replace the "ld" with the identical "ld" instruction from the small code model example. Consider next a load of a function-scope static integer. For small code model, the compiler generates: ld 3, .LC1@toc(2) lwz 4, 0(3) .section .toc,"aw",@progbits .LC1: .tc test_fn_static.si[TC],test_fn_static.si .type test_fn_static.si,@object .local test_fn_static.si .comm test_fn_static.si,4,4 For medium code model, the compiler generates: addis 3, 2, test_fn_static.si@toc@ha addi 3, 3, test_fn_static.si@toc@l lwz 4, 0(3) .type test_fn_static.si,@object .local test_fn_static.si .comm test_fn_static.si,4,4 Again, the linker may replace the "addis" with a "nop", calculating only a 16-bit offset when this is sufficient. Note that it would be more efficient for the compiler to generate: addis 3, 2, test_fn_static.si@toc@ha lwz 4, test_fn_static.si@toc@l(3) The current patch does not perform this optimization yet. This will be addressed as a peephole optimization in a later patch. For the moment, the default code model for 64-bit PowerPC will remain the small code model. We plan to eventually change the default to medium code model, which matches current upstream GCC behavior. Note that the different code models are ABI-compatible, so code compiled with different models will be linked and execute correctly. I've tested the regression suite and the application/benchmark test suite in two ways: Once with the patch as submitted here, and once with additional logic to force medium code model as the default. The tests all compile cleanly, with one exception. The mandel-2 application test fails due to an unrelated ABI compatibility with passing complex numbers. It just so happens that small code model was incredibly lucky, in that temporary values in floating-point registers held the expected values needed by the external library routine that was called incorrectly. My current thought is to correct the ABI problems with _Complex before making medium code model the default, to avoid introducing this "regression." Here are a few comments on how the patch works, since the selection code can be difficult to follow: The existing logic for small code model defines three pseudo-instructions: LDtoc for most uses, LDtocJTI for jump table addresses, and LDtocCPT for constant pool addresses. These are expanded by SelectCodeCommon(). The pseudo-instruction approach doesn't work for medium code model, because we need to generate two instructions when we match the same pattern. Instead, new logic in PPCDAGToDAGISel::Select() intercepts the TOC_ENTRY node for medium code model, and generates an ADDIStocHA followed by either a LDtocL or an ADDItocL. These new node types correspond naturally to the sequences described above. The addis/ld sequence is generated for the following cases: * Jump table addresses * Function addresses * External global variables * Tentative definitions of global variables (common linkage) The addis/addi sequence is generated for the following cases: * Constant pool entries * File-scope static global variables * Function-scope static variables Expanding to the two-instruction sequences at select time exposes the instructions to subsequent optimization, particularly scheduling. The rest of the processing occurs at assembly time, in PPCAsmPrinter::EmitInstruction. Each of the instructions is converted to a "real" PowerPC instruction. When a TOC entry needs to be created, this is done here in the same manner as for the existing LDtoc, LDtocJTI, and LDtocCPT pseudo-instructions (I factored out a new routine to handle this). I had originally thought that if a TOC entry was needed for LDtocL or ADDItocL, it would already have been generated for the previous ADDIStocHA. However, at higher optimization levels, the ADDIStocHA may appear in a different block, which may be assembled textually following the block containing the LDtocL or ADDItocL. So it is necessary to include the possibility of creating a new TOC entry for those two instructions. Note that for LDtocL, we generate a new form of LD called LDrs. This allows specifying the @toc@l relocation for the offset field of the LD instruction (i.e., the offset is replaced by a SymbolLo relocation). When the peephole optimization described above is added, we will need to do similar things for all immediate-form load and store operations. The seven "mcm-n.ll" test cases are kept separate because otherwise the intermingling of various TOC entries and so forth makes the tests fragile and hard to understand. The above assumes use of an external assembler. For use of the integrated assembler, new relocations are added and used by PPCELFObjectWriter. Testing is done with "mcm-obj.ll", which tests for proper generation of the various relocations for the same sequences tested with the external assembler. llvm-svn: 168708
2012-11-28 01:35:46 +08:00
Large code model support for PowerPC. Large code model is identical to medium code model except that the addis/addi sequence for "local" accesses is never used. All accesses use the addis/ld sequence. The coding changes are straightforward; most of the patch is taken up with creating variants of the medium model tests for large model. llvm-svn: 175767
2013-02-22 01:12:27 +08:00
// For medium and large code model, we generate two instructions as
// described below. Otherwise we allow SelectCodeCommon to handle this,
[PowerPC] Load BlockAddress values from the TOC in 64-bit SVR4 code Since block address values can be larger than 2GB in 64-bit code, they cannot be loaded simply using an @l / @ha pair, but instead must be loaded from the TOC, just like GlobalAddress, ConstantPool, and JumpTable values are. The commit also fixes a bug in PPCLinuxAsmPrinter::doFinalization where temporary labels could not be used as TOC values, since code would attempt (and fail) to use GetOrCreateSymbol to create a symbol of the same name as the temporary label. llvm-svn: 220959
2014-10-31 18:33:14 +08:00
// selecting one of LDtoc, LDtocJTI, LDtocCPT, and LDtocBA.
Large code model support for PowerPC. Large code model is identical to medium code model except that the addis/addi sequence for "local" accesses is never used. All accesses use the addis/ld sequence. The coding changes are straightforward; most of the patch is taken up with creating variants of the medium model tests for large model. llvm-svn: 175767
2013-02-22 01:12:27 +08:00
CodeModel::Model CModel = TM.getCodeModel();
if (CModel != CodeModel::Medium && CModel != CodeModel::Large)
This patch implements medium code model support for 64-bit PowerPC. The default for 64-bit PowerPC is small code model, in which TOC entries must be addressable using a 16-bit offset from the TOC pointer. Additionally, only TOC entries are addressed via the TOC pointer. With medium code model, TOC entries and data sections can all be addressed via the TOC pointer using a 32-bit offset. Cooperation with the linker allows 16-bit offsets to be used when these are sufficient, reducing the number of extra instructions that need to be executed. Medium code model also does not generate explicit TOC entries in ".section toc" for variables that are wholly internal to the compilation unit. Consider a load of an external 4-byte integer. With small code model, the compiler generates: ld 3, .LC1@toc(2) lwz 4, 0(3) .section .toc,"aw",@progbits .LC1: .tc ei[TC],ei With medium model, it instead generates: addis 3, 2, .LC1@toc@ha ld 3, .LC1@toc@l(3) lwz 4, 0(3) .section .toc,"aw",@progbits .LC1: .tc ei[TC],ei Here .LC1@toc@ha is a relocation requesting the upper 16 bits of the 32-bit offset of ei's TOC entry from the TOC base pointer. Similarly, .LC1@toc@l is a relocation requesting the lower 16 bits. Note that if the linker determines that ei's TOC entry is within a 16-bit offset of the TOC base pointer, it will replace the "addis" with a "nop", and replace the "ld" with the identical "ld" instruction from the small code model example. Consider next a load of a function-scope static integer. For small code model, the compiler generates: ld 3, .LC1@toc(2) lwz 4, 0(3) .section .toc,"aw",@progbits .LC1: .tc test_fn_static.si[TC],test_fn_static.si .type test_fn_static.si,@object .local test_fn_static.si .comm test_fn_static.si,4,4 For medium code model, the compiler generates: addis 3, 2, test_fn_static.si@toc@ha addi 3, 3, test_fn_static.si@toc@l lwz 4, 0(3) .type test_fn_static.si,@object .local test_fn_static.si .comm test_fn_static.si,4,4 Again, the linker may replace the "addis" with a "nop", calculating only a 16-bit offset when this is sufficient. Note that it would be more efficient for the compiler to generate: addis 3, 2, test_fn_static.si@toc@ha lwz 4, test_fn_static.si@toc@l(3) The current patch does not perform this optimization yet. This will be addressed as a peephole optimization in a later patch. For the moment, the default code model for 64-bit PowerPC will remain the small code model. We plan to eventually change the default to medium code model, which matches current upstream GCC behavior. Note that the different code models are ABI-compatible, so code compiled with different models will be linked and execute correctly. I've tested the regression suite and the application/benchmark test suite in two ways: Once with the patch as submitted here, and once with additional logic to force medium code model as the default. The tests all compile cleanly, with one exception. The mandel-2 application test fails due to an unrelated ABI compatibility with passing complex numbers. It just so happens that small code model was incredibly lucky, in that temporary values in floating-point registers held the expected values needed by the external library routine that was called incorrectly. My current thought is to correct the ABI problems with _Complex before making medium code model the default, to avoid introducing this "regression." Here are a few comments on how the patch works, since the selection code can be difficult to follow: The existing logic for small code model defines three pseudo-instructions: LDtoc for most uses, LDtocJTI for jump table addresses, and LDtocCPT for constant pool addresses. These are expanded by SelectCodeCommon(). The pseudo-instruction approach doesn't work for medium code model, because we need to generate two instructions when we match the same pattern. Instead, new logic in PPCDAGToDAGISel::Select() intercepts the TOC_ENTRY node for medium code model, and generates an ADDIStocHA followed by either a LDtocL or an ADDItocL. These new node types correspond naturally to the sequences described above. The addis/ld sequence is generated for the following cases: * Jump table addresses * Function addresses * External global variables * Tentative definitions of global variables (common linkage) The addis/addi sequence is generated for the following cases: * Constant pool entries * File-scope static global variables * Function-scope static variables Expanding to the two-instruction sequences at select time exposes the instructions to subsequent optimization, particularly scheduling. The rest of the processing occurs at assembly time, in PPCAsmPrinter::EmitInstruction. Each of the instructions is converted to a "real" PowerPC instruction. When a TOC entry needs to be created, this is done here in the same manner as for the existing LDtoc, LDtocJTI, and LDtocCPT pseudo-instructions (I factored out a new routine to handle this). I had originally thought that if a TOC entry was needed for LDtocL or ADDItocL, it would already have been generated for the previous ADDIStocHA. However, at higher optimization levels, the ADDIStocHA may appear in a different block, which may be assembled textually following the block containing the LDtocL or ADDItocL. So it is necessary to include the possibility of creating a new TOC entry for those two instructions. Note that for LDtocL, we generate a new form of LD called LDrs. This allows specifying the @toc@l relocation for the offset field of the LD instruction (i.e., the offset is replaced by a SymbolLo relocation). When the peephole optimization described above is added, we will need to do similar things for all immediate-form load and store operations. The seven "mcm-n.ll" test cases are kept separate because otherwise the intermingling of various TOC entries and so forth makes the tests fragile and hard to understand. The above assumes use of an external assembler. For use of the integrated assembler, new relocations are added and used by PPCELFObjectWriter. Testing is done with "mcm-obj.ll", which tests for proper generation of the various relocations for the same sequences tested with the external assembler. llvm-svn: 168708
2012-11-28 01:35:46 +08:00
break;
[PPC64] Fix PR19893 - improve code generation for local function addresses Rafael opened http://llvm.org/bugs/show_bug.cgi?id=19893 to track non-optimal code generation for forming a function address that is local to the compile unit. The existing code was treating both local and non-local functions identically. This patch fixes the problem by properly identifying local functions and generating the proper addis/addi code. I also noticed that Rafael's earlier changes to correct the surrounding code in PPCISelLowering.cpp were also needed for fast instruction selection in PPCFastISel.cpp, so this patch fixes that code as well. The existing test/CodeGen/PowerPC/func-addr.ll is modified to test the new code generation. I've added a -O0 run line to test the fast-isel code as well. Tested on powerpc64[le]-unknown-linux-gnu with no regressions. llvm-svn: 211056
2014-06-17 05:36:02 +08:00
// The first source operand is a TargetGlobalAddress or a TargetJumpTable.
Weak non-function symbols were being accessed directly, which is incorrect, as the chosen representative of the weak symbol may not live with the code in question. Always indirect the access through the TOC instead. Patch by Kyle Butt! llvm-svn: 253708
2015-11-21 04:51:31 +08:00
// If it must be toc-referenced according to PPCSubTarget, we generate:
This patch implements medium code model support for 64-bit PowerPC. The default for 64-bit PowerPC is small code model, in which TOC entries must be addressable using a 16-bit offset from the TOC pointer. Additionally, only TOC entries are addressed via the TOC pointer. With medium code model, TOC entries and data sections can all be addressed via the TOC pointer using a 32-bit offset. Cooperation with the linker allows 16-bit offsets to be used when these are sufficient, reducing the number of extra instructions that need to be executed. Medium code model also does not generate explicit TOC entries in ".section toc" for variables that are wholly internal to the compilation unit. Consider a load of an external 4-byte integer. With small code model, the compiler generates: ld 3, .LC1@toc(2) lwz 4, 0(3) .section .toc,"aw",@progbits .LC1: .tc ei[TC],ei With medium model, it instead generates: addis 3, 2, .LC1@toc@ha ld 3, .LC1@toc@l(3) lwz 4, 0(3) .section .toc,"aw",@progbits .LC1: .tc ei[TC],ei Here .LC1@toc@ha is a relocation requesting the upper 16 bits of the 32-bit offset of ei's TOC entry from the TOC base pointer. Similarly, .LC1@toc@l is a relocation requesting the lower 16 bits. Note that if the linker determines that ei's TOC entry is within a 16-bit offset of the TOC base pointer, it will replace the "addis" with a "nop", and replace the "ld" with the identical "ld" instruction from the small code model example. Consider next a load of a function-scope static integer. For small code model, the compiler generates: ld 3, .LC1@toc(2) lwz 4, 0(3) .section .toc,"aw",@progbits .LC1: .tc test_fn_static.si[TC],test_fn_static.si .type test_fn_static.si,@object .local test_fn_static.si .comm test_fn_static.si,4,4 For medium code model, the compiler generates: addis 3, 2, test_fn_static.si@toc@ha addi 3, 3, test_fn_static.si@toc@l lwz 4, 0(3) .type test_fn_static.si,@object .local test_fn_static.si .comm test_fn_static.si,4,4 Again, the linker may replace the "addis" with a "nop", calculating only a 16-bit offset when this is sufficient. Note that it would be more efficient for the compiler to generate: addis 3, 2, test_fn_static.si@toc@ha lwz 4, test_fn_static.si@toc@l(3) The current patch does not perform this optimization yet. This will be addressed as a peephole optimization in a later patch. For the moment, the default code model for 64-bit PowerPC will remain the small code model. We plan to eventually change the default to medium code model, which matches current upstream GCC behavior. Note that the different code models are ABI-compatible, so code compiled with different models will be linked and execute correctly. I've tested the regression suite and the application/benchmark test suite in two ways: Once with the patch as submitted here, and once with additional logic to force medium code model as the default. The tests all compile cleanly, with one exception. The mandel-2 application test fails due to an unrelated ABI compatibility with passing complex numbers. It just so happens that small code model was incredibly lucky, in that temporary values in floating-point registers held the expected values needed by the external library routine that was called incorrectly. My current thought is to correct the ABI problems with _Complex before making medium code model the default, to avoid introducing this "regression." Here are a few comments on how the patch works, since the selection code can be difficult to follow: The existing logic for small code model defines three pseudo-instructions: LDtoc for most uses, LDtocJTI for jump table addresses, and LDtocCPT for constant pool addresses. These are expanded by SelectCodeCommon(). The pseudo-instruction approach doesn't work for medium code model, because we need to generate two instructions when we match the same pattern. Instead, new logic in PPCDAGToDAGISel::Select() intercepts the TOC_ENTRY node for medium code model, and generates an ADDIStocHA followed by either a LDtocL or an ADDItocL. These new node types correspond naturally to the sequences described above. The addis/ld sequence is generated for the following cases: * Jump table addresses * Function addresses * External global variables * Tentative definitions of global variables (common linkage) The addis/addi sequence is generated for the following cases: * Constant pool entries * File-scope static global variables * Function-scope static variables Expanding to the two-instruction sequences at select time exposes the instructions to subsequent optimization, particularly scheduling. The rest of the processing occurs at assembly time, in PPCAsmPrinter::EmitInstruction. Each of the instructions is converted to a "real" PowerPC instruction. When a TOC entry needs to be created, this is done here in the same manner as for the existing LDtoc, LDtocJTI, and LDtocCPT pseudo-instructions (I factored out a new routine to handle this). I had originally thought that if a TOC entry was needed for LDtocL or ADDItocL, it would already have been generated for the previous ADDIStocHA. However, at higher optimization levels, the ADDIStocHA may appear in a different block, which may be assembled textually following the block containing the LDtocL or ADDItocL. So it is necessary to include the possibility of creating a new TOC entry for those two instructions. Note that for LDtocL, we generate a new form of LD called LDrs. This allows specifying the @toc@l relocation for the offset field of the LD instruction (i.e., the offset is replaced by a SymbolLo relocation). When the peephole optimization described above is added, we will need to do similar things for all immediate-form load and store operations. The seven "mcm-n.ll" test cases are kept separate because otherwise the intermingling of various TOC entries and so forth makes the tests fragile and hard to understand. The above assumes use of an external assembler. For use of the integrated assembler, new relocations are added and used by PPCELFObjectWriter. Testing is done with "mcm-obj.ll", which tests for proper generation of the various relocations for the same sequences tested with the external assembler. llvm-svn: 168708
2012-11-28 01:35:46 +08:00
// LDtocL(<ga:@sym>, ADDIStocHA(%X2, <ga:@sym>))
// Otherwise we generate:
// ADDItocL(ADDIStocHA(%X2, <ga:@sym>), <ga:@sym>)
SDValue GA = N->getOperand(0);
SDValue TOCbase = N->getOperand(1);
SDNode *Tmp = CurDAG->getMachineNode(PPC::ADDIStocHA, dl, MVT::i64,
[PowerPC] Make LDtocL and friends invariant loads LDtocL, and other loads that roughly correspond to the TOC_ENTRY SDAG node, represent loads from the TOC, which is invariant. As a result, these loads can be hoisted out of loops, etc. In order to do this, we need to generate GOT-style MMOs for TOC_ENTRY, which requires treating it as a legitimate memory intrinsic node type. Once this is done, the MMO transfer is automatically handled for TableGen-driven instruction selection, and for nodes generated directly in PPCISelDAGToDAG, we need to transfer the MMOs manually. Also, we were not transferring MMOs associated with pre-increment loads, so do that too. Lastly, this fixes an exposed bug where R30 was not added as a defined operand of UpdateGBR. This problem was highlighted by an example (used to generate the test case) posted to llvmdev by Francois Pichet. llvm-svn: 230553
2015-02-26 05:36:59 +08:00
TOCbase, GA);
This patch implements medium code model support for 64-bit PowerPC. The default for 64-bit PowerPC is small code model, in which TOC entries must be addressable using a 16-bit offset from the TOC pointer. Additionally, only TOC entries are addressed via the TOC pointer. With medium code model, TOC entries and data sections can all be addressed via the TOC pointer using a 32-bit offset. Cooperation with the linker allows 16-bit offsets to be used when these are sufficient, reducing the number of extra instructions that need to be executed. Medium code model also does not generate explicit TOC entries in ".section toc" for variables that are wholly internal to the compilation unit. Consider a load of an external 4-byte integer. With small code model, the compiler generates: ld 3, .LC1@toc(2) lwz 4, 0(3) .section .toc,"aw",@progbits .LC1: .tc ei[TC],ei With medium model, it instead generates: addis 3, 2, .LC1@toc@ha ld 3, .LC1@toc@l(3) lwz 4, 0(3) .section .toc,"aw",@progbits .LC1: .tc ei[TC],ei Here .LC1@toc@ha is a relocation requesting the upper 16 bits of the 32-bit offset of ei's TOC entry from the TOC base pointer. Similarly, .LC1@toc@l is a relocation requesting the lower 16 bits. Note that if the linker determines that ei's TOC entry is within a 16-bit offset of the TOC base pointer, it will replace the "addis" with a "nop", and replace the "ld" with the identical "ld" instruction from the small code model example. Consider next a load of a function-scope static integer. For small code model, the compiler generates: ld 3, .LC1@toc(2) lwz 4, 0(3) .section .toc,"aw",@progbits .LC1: .tc test_fn_static.si[TC],test_fn_static.si .type test_fn_static.si,@object .local test_fn_static.si .comm test_fn_static.si,4,4 For medium code model, the compiler generates: addis 3, 2, test_fn_static.si@toc@ha addi 3, 3, test_fn_static.si@toc@l lwz 4, 0(3) .type test_fn_static.si,@object .local test_fn_static.si .comm test_fn_static.si,4,4 Again, the linker may replace the "addis" with a "nop", calculating only a 16-bit offset when this is sufficient. Note that it would be more efficient for the compiler to generate: addis 3, 2, test_fn_static.si@toc@ha lwz 4, test_fn_static.si@toc@l(3) The current patch does not perform this optimization yet. This will be addressed as a peephole optimization in a later patch. For the moment, the default code model for 64-bit PowerPC will remain the small code model. We plan to eventually change the default to medium code model, which matches current upstream GCC behavior. Note that the different code models are ABI-compatible, so code compiled with different models will be linked and execute correctly. I've tested the regression suite and the application/benchmark test suite in two ways: Once with the patch as submitted here, and once with additional logic to force medium code model as the default. The tests all compile cleanly, with one exception. The mandel-2 application test fails due to an unrelated ABI compatibility with passing complex numbers. It just so happens that small code model was incredibly lucky, in that temporary values in floating-point registers held the expected values needed by the external library routine that was called incorrectly. My current thought is to correct the ABI problems with _Complex before making medium code model the default, to avoid introducing this "regression." Here are a few comments on how the patch works, since the selection code can be difficult to follow: The existing logic for small code model defines three pseudo-instructions: LDtoc for most uses, LDtocJTI for jump table addresses, and LDtocCPT for constant pool addresses. These are expanded by SelectCodeCommon(). The pseudo-instruction approach doesn't work for medium code model, because we need to generate two instructions when we match the same pattern. Instead, new logic in PPCDAGToDAGISel::Select() intercepts the TOC_ENTRY node for medium code model, and generates an ADDIStocHA followed by either a LDtocL or an ADDItocL. These new node types correspond naturally to the sequences described above. The addis/ld sequence is generated for the following cases: * Jump table addresses * Function addresses * External global variables * Tentative definitions of global variables (common linkage) The addis/addi sequence is generated for the following cases: * Constant pool entries * File-scope static global variables * Function-scope static variables Expanding to the two-instruction sequences at select time exposes the instructions to subsequent optimization, particularly scheduling. The rest of the processing occurs at assembly time, in PPCAsmPrinter::EmitInstruction. Each of the instructions is converted to a "real" PowerPC instruction. When a TOC entry needs to be created, this is done here in the same manner as for the existing LDtoc, LDtocJTI, and LDtocCPT pseudo-instructions (I factored out a new routine to handle this). I had originally thought that if a TOC entry was needed for LDtocL or ADDItocL, it would already have been generated for the previous ADDIStocHA. However, at higher optimization levels, the ADDIStocHA may appear in a different block, which may be assembled textually following the block containing the LDtocL or ADDItocL. So it is necessary to include the possibility of creating a new TOC entry for those two instructions. Note that for LDtocL, we generate a new form of LD called LDrs. This allows specifying the @toc@l relocation for the offset field of the LD instruction (i.e., the offset is replaced by a SymbolLo relocation). When the peephole optimization described above is added, we will need to do similar things for all immediate-form load and store operations. The seven "mcm-n.ll" test cases are kept separate because otherwise the intermingling of various TOC entries and so forth makes the tests fragile and hard to understand. The above assumes use of an external assembler. For use of the integrated assembler, new relocations are added and used by PPCELFObjectWriter. Testing is done with "mcm-obj.ll", which tests for proper generation of the various relocations for the same sequences tested with the external assembler. llvm-svn: 168708
2012-11-28 01:35:46 +08:00
[PowerPC] Load BlockAddress values from the TOC in 64-bit SVR4 code Since block address values can be larger than 2GB in 64-bit code, they cannot be loaded simply using an @l / @ha pair, but instead must be loaded from the TOC, just like GlobalAddress, ConstantPool, and JumpTable values are. The commit also fixes a bug in PPCLinuxAsmPrinter::doFinalization where temporary labels could not be used as TOC values, since code would attempt (and fail) to use GetOrCreateSymbol to create a symbol of the same name as the temporary label. llvm-svn: 220959
2014-10-31 18:33:14 +08:00
if (isa<JumpTableSDNode>(GA) || isa<BlockAddressSDNode>(GA) ||
CModel == CodeModel::Large)
[PowerPC] Make LDtocL and friends invariant loads LDtocL, and other loads that roughly correspond to the TOC_ENTRY SDAG node, represent loads from the TOC, which is invariant. As a result, these loads can be hoisted out of loops, etc. In order to do this, we need to generate GOT-style MMOs for TOC_ENTRY, which requires treating it as a legitimate memory intrinsic node type. Once this is done, the MMO transfer is automatically handled for TableGen-driven instruction selection, and for nodes generated directly in PPCISelDAGToDAG, we need to transfer the MMOs manually. Also, we were not transferring MMOs associated with pre-increment loads, so do that too. Lastly, this fixes an exposed bug where R30 was not added as a defined operand of UpdateGBR. This problem was highlighted by an example (used to generate the test case) posted to llvmdev by Francois Pichet. llvm-svn: 230553
2015-02-26 05:36:59 +08:00
return transferMemOperands(N, CurDAG->getMachineNode(PPC::LDtocL, dl,
MVT::i64, GA, SDValue(Tmp, 0)));
This patch implements medium code model support for 64-bit PowerPC. The default for 64-bit PowerPC is small code model, in which TOC entries must be addressable using a 16-bit offset from the TOC pointer. Additionally, only TOC entries are addressed via the TOC pointer. With medium code model, TOC entries and data sections can all be addressed via the TOC pointer using a 32-bit offset. Cooperation with the linker allows 16-bit offsets to be used when these are sufficient, reducing the number of extra instructions that need to be executed. Medium code model also does not generate explicit TOC entries in ".section toc" for variables that are wholly internal to the compilation unit. Consider a load of an external 4-byte integer. With small code model, the compiler generates: ld 3, .LC1@toc(2) lwz 4, 0(3) .section .toc,"aw",@progbits .LC1: .tc ei[TC],ei With medium model, it instead generates: addis 3, 2, .LC1@toc@ha ld 3, .LC1@toc@l(3) lwz 4, 0(3) .section .toc,"aw",@progbits .LC1: .tc ei[TC],ei Here .LC1@toc@ha is a relocation requesting the upper 16 bits of the 32-bit offset of ei's TOC entry from the TOC base pointer. Similarly, .LC1@toc@l is a relocation requesting the lower 16 bits. Note that if the linker determines that ei's TOC entry is within a 16-bit offset of the TOC base pointer, it will replace the "addis" with a "nop", and replace the "ld" with the identical "ld" instruction from the small code model example. Consider next a load of a function-scope static integer. For small code model, the compiler generates: ld 3, .LC1@toc(2) lwz 4, 0(3) .section .toc,"aw",@progbits .LC1: .tc test_fn_static.si[TC],test_fn_static.si .type test_fn_static.si,@object .local test_fn_static.si .comm test_fn_static.si,4,4 For medium code model, the compiler generates: addis 3, 2, test_fn_static.si@toc@ha addi 3, 3, test_fn_static.si@toc@l lwz 4, 0(3) .type test_fn_static.si,@object .local test_fn_static.si .comm test_fn_static.si,4,4 Again, the linker may replace the "addis" with a "nop", calculating only a 16-bit offset when this is sufficient. Note that it would be more efficient for the compiler to generate: addis 3, 2, test_fn_static.si@toc@ha lwz 4, test_fn_static.si@toc@l(3) The current patch does not perform this optimization yet. This will be addressed as a peephole optimization in a later patch. For the moment, the default code model for 64-bit PowerPC will remain the small code model. We plan to eventually change the default to medium code model, which matches current upstream GCC behavior. Note that the different code models are ABI-compatible, so code compiled with different models will be linked and execute correctly. I've tested the regression suite and the application/benchmark test suite in two ways: Once with the patch as submitted here, and once with additional logic to force medium code model as the default. The tests all compile cleanly, with one exception. The mandel-2 application test fails due to an unrelated ABI compatibility with passing complex numbers. It just so happens that small code model was incredibly lucky, in that temporary values in floating-point registers held the expected values needed by the external library routine that was called incorrectly. My current thought is to correct the ABI problems with _Complex before making medium code model the default, to avoid introducing this "regression." Here are a few comments on how the patch works, since the selection code can be difficult to follow: The existing logic for small code model defines three pseudo-instructions: LDtoc for most uses, LDtocJTI for jump table addresses, and LDtocCPT for constant pool addresses. These are expanded by SelectCodeCommon(). The pseudo-instruction approach doesn't work for medium code model, because we need to generate two instructions when we match the same pattern. Instead, new logic in PPCDAGToDAGISel::Select() intercepts the TOC_ENTRY node for medium code model, and generates an ADDIStocHA followed by either a LDtocL or an ADDItocL. These new node types correspond naturally to the sequences described above. The addis/ld sequence is generated for the following cases: * Jump table addresses * Function addresses * External global variables * Tentative definitions of global variables (common linkage) The addis/addi sequence is generated for the following cases: * Constant pool entries * File-scope static global variables * Function-scope static variables Expanding to the two-instruction sequences at select time exposes the instructions to subsequent optimization, particularly scheduling. The rest of the processing occurs at assembly time, in PPCAsmPrinter::EmitInstruction. Each of the instructions is converted to a "real" PowerPC instruction. When a TOC entry needs to be created, this is done here in the same manner as for the existing LDtoc, LDtocJTI, and LDtocCPT pseudo-instructions (I factored out a new routine to handle this). I had originally thought that if a TOC entry was needed for LDtocL or ADDItocL, it would already have been generated for the previous ADDIStocHA. However, at higher optimization levels, the ADDIStocHA may appear in a different block, which may be assembled textually following the block containing the LDtocL or ADDItocL. So it is necessary to include the possibility of creating a new TOC entry for those two instructions. Note that for LDtocL, we generate a new form of LD called LDrs. This allows specifying the @toc@l relocation for the offset field of the LD instruction (i.e., the offset is replaced by a SymbolLo relocation). When the peephole optimization described above is added, we will need to do similar things for all immediate-form load and store operations. The seven "mcm-n.ll" test cases are kept separate because otherwise the intermingling of various TOC entries and so forth makes the tests fragile and hard to understand. The above assumes use of an external assembler. For use of the integrated assembler, new relocations are added and used by PPCELFObjectWriter. Testing is done with "mcm-obj.ll", which tests for proper generation of the various relocations for the same sequences tested with the external assembler. llvm-svn: 168708
2012-11-28 01:35:46 +08:00
if (GlobalAddressSDNode *G = dyn_cast<GlobalAddressSDNode>(GA)) {
Weak non-function symbols were being accessed directly, which is incorrect, as the chosen representative of the weak symbol may not live with the code in question. Always indirect the access through the TOC instead. Patch by Kyle Butt! llvm-svn: 253708
2015-11-21 04:51:31 +08:00
const GlobalValue *GV = G->getGlobal();
unsigned char GVFlags = PPCSubTarget->classifyGlobalReference(GV);
if (GVFlags & PPCII::MO_NLP_FLAG) {
[PowerPC] Make LDtocL and friends invariant loads LDtocL, and other loads that roughly correspond to the TOC_ENTRY SDAG node, represent loads from the TOC, which is invariant. As a result, these loads can be hoisted out of loops, etc. In order to do this, we need to generate GOT-style MMOs for TOC_ENTRY, which requires treating it as a legitimate memory intrinsic node type. Once this is done, the MMO transfer is automatically handled for TableGen-driven instruction selection, and for nodes generated directly in PPCISelDAGToDAG, we need to transfer the MMOs manually. Also, we were not transferring MMOs associated with pre-increment loads, so do that too. Lastly, this fixes an exposed bug where R30 was not added as a defined operand of UpdateGBR. This problem was highlighted by an example (used to generate the test case) posted to llvmdev by Francois Pichet. llvm-svn: 230553
2015-02-26 05:36:59 +08:00
return transferMemOperands(N, CurDAG->getMachineNode(PPC::LDtocL, dl,
MVT::i64, GA, SDValue(Tmp, 0)));
Weak non-function symbols were being accessed directly, which is incorrect, as the chosen representative of the weak symbol may not live with the code in question. Always indirect the access through the TOC instead. Patch by Kyle Butt! llvm-svn: 253708
2015-11-21 04:51:31 +08:00
}
This patch implements medium code model support for 64-bit PowerPC. The default for 64-bit PowerPC is small code model, in which TOC entries must be addressable using a 16-bit offset from the TOC pointer. Additionally, only TOC entries are addressed via the TOC pointer. With medium code model, TOC entries and data sections can all be addressed via the TOC pointer using a 32-bit offset. Cooperation with the linker allows 16-bit offsets to be used when these are sufficient, reducing the number of extra instructions that need to be executed. Medium code model also does not generate explicit TOC entries in ".section toc" for variables that are wholly internal to the compilation unit. Consider a load of an external 4-byte integer. With small code model, the compiler generates: ld 3, .LC1@toc(2) lwz 4, 0(3) .section .toc,"aw",@progbits .LC1: .tc ei[TC],ei With medium model, it instead generates: addis 3, 2, .LC1@toc@ha ld 3, .LC1@toc@l(3) lwz 4, 0(3) .section .toc,"aw",@progbits .LC1: .tc ei[TC],ei Here .LC1@toc@ha is a relocation requesting the upper 16 bits of the 32-bit offset of ei's TOC entry from the TOC base pointer. Similarly, .LC1@toc@l is a relocation requesting the lower 16 bits. Note that if the linker determines that ei's TOC entry is within a 16-bit offset of the TOC base pointer, it will replace the "addis" with a "nop", and replace the "ld" with the identical "ld" instruction from the small code model example. Consider next a load of a function-scope static integer. For small code model, the compiler generates: ld 3, .LC1@toc(2) lwz 4, 0(3) .section .toc,"aw",@progbits .LC1: .tc test_fn_static.si[TC],test_fn_static.si .type test_fn_static.si,@object .local test_fn_static.si .comm test_fn_static.si,4,4 For medium code model, the compiler generates: addis 3, 2, test_fn_static.si@toc@ha addi 3, 3, test_fn_static.si@toc@l lwz 4, 0(3) .type test_fn_static.si,@object .local test_fn_static.si .comm test_fn_static.si,4,4 Again, the linker may replace the "addis" with a "nop", calculating only a 16-bit offset when this is sufficient. Note that it would be more efficient for the compiler to generate: addis 3, 2, test_fn_static.si@toc@ha lwz 4, test_fn_static.si@toc@l(3) The current patch does not perform this optimization yet. This will be addressed as a peephole optimization in a later patch. For the moment, the default code model for 64-bit PowerPC will remain the small code model. We plan to eventually change the default to medium code model, which matches current upstream GCC behavior. Note that the different code models are ABI-compatible, so code compiled with different models will be linked and execute correctly. I've tested the regression suite and the application/benchmark test suite in two ways: Once with the patch as submitted here, and once with additional logic to force medium code model as the default. The tests all compile cleanly, with one exception. The mandel-2 application test fails due to an unrelated ABI compatibility with passing complex numbers. It just so happens that small code model was incredibly lucky, in that temporary values in floating-point registers held the expected values needed by the external library routine that was called incorrectly. My current thought is to correct the ABI problems with _Complex before making medium code model the default, to avoid introducing this "regression." Here are a few comments on how the patch works, since the selection code can be difficult to follow: The existing logic for small code model defines three pseudo-instructions: LDtoc for most uses, LDtocJTI for jump table addresses, and LDtocCPT for constant pool addresses. These are expanded by SelectCodeCommon(). The pseudo-instruction approach doesn't work for medium code model, because we need to generate two instructions when we match the same pattern. Instead, new logic in PPCDAGToDAGISel::Select() intercepts the TOC_ENTRY node for medium code model, and generates an ADDIStocHA followed by either a LDtocL or an ADDItocL. These new node types correspond naturally to the sequences described above. The addis/ld sequence is generated for the following cases: * Jump table addresses * Function addresses * External global variables * Tentative definitions of global variables (common linkage) The addis/addi sequence is generated for the following cases: * Constant pool entries * File-scope static global variables * Function-scope static variables Expanding to the two-instruction sequences at select time exposes the instructions to subsequent optimization, particularly scheduling. The rest of the processing occurs at assembly time, in PPCAsmPrinter::EmitInstruction. Each of the instructions is converted to a "real" PowerPC instruction. When a TOC entry needs to be created, this is done here in the same manner as for the existing LDtoc, LDtocJTI, and LDtocCPT pseudo-instructions (I factored out a new routine to handle this). I had originally thought that if a TOC entry was needed for LDtocL or ADDItocL, it would already have been generated for the previous ADDIStocHA. However, at higher optimization levels, the ADDIStocHA may appear in a different block, which may be assembled textually following the block containing the LDtocL or ADDItocL. So it is necessary to include the possibility of creating a new TOC entry for those two instructions. Note that for LDtocL, we generate a new form of LD called LDrs. This allows specifying the @toc@l relocation for the offset field of the LD instruction (i.e., the offset is replaced by a SymbolLo relocation). When the peephole optimization described above is added, we will need to do similar things for all immediate-form load and store operations. The seven "mcm-n.ll" test cases are kept separate because otherwise the intermingling of various TOC entries and so forth makes the tests fragile and hard to understand. The above assumes use of an external assembler. For use of the integrated assembler, new relocations are added and used by PPCELFObjectWriter. Testing is done with "mcm-obj.ll", which tests for proper generation of the various relocations for the same sequences tested with the external assembler. llvm-svn: 168708
2012-11-28 01:35:46 +08:00
}
return CurDAG->getMachineNode(PPC::ADDItocL, dl, MVT::i64,
SDValue(Tmp, 0), GA);
}
[PowerPC] Support TLS on PPC32/ELF Patch by Justin Hibbits! llvm-svn: 213960
2014-07-26 01:47:22 +08:00
case PPCISD::PPC32_PICGOT: {
// Generate a PIC-safe GOT reference.
assert(!PPCSubTarget->isPPC64() && PPCSubTarget->isSVR4ABI() &&
"PPCISD::PPC32_PICGOT is only supported for 32-bit SVR4");
Make TargetLowering::getPointerTy() taking DataLayout as an argument Summary: This change is part of a series of commits dedicated to have a single DataLayout during compilation by using always the one owned by the module. Reviewers: echristo Subscribers: jholewinski, ted, yaron.keren, rafael, llvm-commits Differential Revision: http://reviews.llvm.org/D11028 From: Mehdi Amini <mehdi.amini@apple.com> llvm-svn: 241775
2015-07-09 10:09:04 +08:00
return CurDAG->SelectNodeTo(
N, PPC::PPC32PICGOT, PPCLowering->getPointerTy(CurDAG->getDataLayout()),
MVT::i32);
[PowerPC] Support TLS on PPC32/ELF Patch by Justin Hibbits! llvm-svn: 213960
2014-07-26 01:47:22 +08:00
}
Fix PR15155: lost vadd/vsplat optimization. During lowering of a BUILD_VECTOR, we look for opportunities to use a vector splat. When the splatted value fits in 5 signed bits, a single splat does the job. When it doesn't fit in 5 bits but does fit in 6, and is an even value, we can splat on half the value and add the result to itself. This last optimization hasn't been working recently because of improved constant folding. To circumvent this, create a pseudo VADD_SPLAT that can be expanded during instruction selection. llvm-svn: 175632
2013-02-20 23:50:31 +08:00
case PPCISD::VADD_SPLAT: {
Additional fixes for bug 15155. This handles the cases where the 6-bit splat element is odd, converting to a three-instruction sequence to add or subtract two splats. With this fix, the XFAIL in test/CodeGen/PowerPC/vec_constants.ll is removed. llvm-svn: 175663
2013-02-21 04:41:42 +08:00
// This expands into one of three sequences, depending on whether
// the first operand is odd or even, positive or negative.
Fix PR15155: lost vadd/vsplat optimization. During lowering of a BUILD_VECTOR, we look for opportunities to use a vector splat. When the splatted value fits in 5 signed bits, a single splat does the job. When it doesn't fit in 5 bits but does fit in 6, and is an even value, we can splat on half the value and add the result to itself. This last optimization hasn't been working recently because of improved constant folding. To circumvent this, create a pseudo VADD_SPLAT that can be expanded during instruction selection. llvm-svn: 175632
2013-02-20 23:50:31 +08:00
assert(isa<ConstantSDNode>(N->getOperand(0)) &&
isa<ConstantSDNode>(N->getOperand(1)) &&
"Invalid operand on VADD_SPLAT!");
Additional fixes for bug 15155. This handles the cases where the 6-bit splat element is odd, converting to a three-instruction sequence to add or subtract two splats. With this fix, the XFAIL in test/CodeGen/PowerPC/vec_constants.ll is removed. llvm-svn: 175663
2013-02-21 04:41:42 +08:00
int Elt = N->getConstantOperandVal(0);
Fix PR15155: lost vadd/vsplat optimization. During lowering of a BUILD_VECTOR, we look for opportunities to use a vector splat. When the splatted value fits in 5 signed bits, a single splat does the job. When it doesn't fit in 5 bits but does fit in 6, and is an even value, we can splat on half the value and add the result to itself. This last optimization hasn't been working recently because of improved constant folding. To circumvent this, create a pseudo VADD_SPLAT that can be expanded during instruction selection. llvm-svn: 175632
2013-02-20 23:50:31 +08:00
int EltSize = N->getConstantOperandVal(1);
Additional fixes for bug 15155. This handles the cases where the 6-bit splat element is odd, converting to a three-instruction sequence to add or subtract two splats. With this fix, the XFAIL in test/CodeGen/PowerPC/vec_constants.ll is removed. llvm-svn: 175663
2013-02-21 04:41:42 +08:00
unsigned Opc1, Opc2, Opc3;
Fix PR15155: lost vadd/vsplat optimization. During lowering of a BUILD_VECTOR, we look for opportunities to use a vector splat. When the splatted value fits in 5 signed bits, a single splat does the job. When it doesn't fit in 5 bits but does fit in 6, and is an even value, we can splat on half the value and add the result to itself. This last optimization hasn't been working recently because of improved constant folding. To circumvent this, create a pseudo VADD_SPLAT that can be expanded during instruction selection. llvm-svn: 175632
2013-02-20 23:50:31 +08:00
EVT VT;
Additional fixes for bug 15155. This handles the cases where the 6-bit splat element is odd, converting to a three-instruction sequence to add or subtract two splats. With this fix, the XFAIL in test/CodeGen/PowerPC/vec_constants.ll is removed. llvm-svn: 175663
2013-02-21 04:41:42 +08:00
Fix PR15155: lost vadd/vsplat optimization. During lowering of a BUILD_VECTOR, we look for opportunities to use a vector splat. When the splatted value fits in 5 signed bits, a single splat does the job. When it doesn't fit in 5 bits but does fit in 6, and is an even value, we can splat on half the value and add the result to itself. This last optimization hasn't been working recently because of improved constant folding. To circumvent this, create a pseudo VADD_SPLAT that can be expanded during instruction selection. llvm-svn: 175632
2013-02-20 23:50:31 +08:00
if (EltSize == 1) {
Opc1 = PPC::VSPLTISB;
Opc2 = PPC::VADDUBM;
Additional fixes for bug 15155. This handles the cases where the 6-bit splat element is odd, converting to a three-instruction sequence to add or subtract two splats. With this fix, the XFAIL in test/CodeGen/PowerPC/vec_constants.ll is removed. llvm-svn: 175663
2013-02-21 04:41:42 +08:00
Opc3 = PPC::VSUBUBM;
Fix PR15155: lost vadd/vsplat optimization. During lowering of a BUILD_VECTOR, we look for opportunities to use a vector splat. When the splatted value fits in 5 signed bits, a single splat does the job. When it doesn't fit in 5 bits but does fit in 6, and is an even value, we can splat on half the value and add the result to itself. This last optimization hasn't been working recently because of improved constant folding. To circumvent this, create a pseudo VADD_SPLAT that can be expanded during instruction selection. llvm-svn: 175632
2013-02-20 23:50:31 +08:00
VT = MVT::v16i8;
} else if (EltSize == 2) {
Opc1 = PPC::VSPLTISH;
Opc2 = PPC::VADDUHM;
Additional fixes for bug 15155. This handles the cases where the 6-bit splat element is odd, converting to a three-instruction sequence to add or subtract two splats. With this fix, the XFAIL in test/CodeGen/PowerPC/vec_constants.ll is removed. llvm-svn: 175663
2013-02-21 04:41:42 +08:00
Opc3 = PPC::VSUBUHM;
Fix PR15155: lost vadd/vsplat optimization. During lowering of a BUILD_VECTOR, we look for opportunities to use a vector splat. When the splatted value fits in 5 signed bits, a single splat does the job. When it doesn't fit in 5 bits but does fit in 6, and is an even value, we can splat on half the value and add the result to itself. This last optimization hasn't been working recently because of improved constant folding. To circumvent this, create a pseudo VADD_SPLAT that can be expanded during instruction selection. llvm-svn: 175632
2013-02-20 23:50:31 +08:00
VT = MVT::v8i16;
} else {
assert(EltSize == 4 && "Invalid element size on VADD_SPLAT!");
Opc1 = PPC::VSPLTISW;
Opc2 = PPC::VADDUWM;
Additional fixes for bug 15155. This handles the cases where the 6-bit splat element is odd, converting to a three-instruction sequence to add or subtract two splats. With this fix, the XFAIL in test/CodeGen/PowerPC/vec_constants.ll is removed. llvm-svn: 175663
2013-02-21 04:41:42 +08:00
Opc3 = PPC::VSUBUWM;
Fix PR15155: lost vadd/vsplat optimization. During lowering of a BUILD_VECTOR, we look for opportunities to use a vector splat. When the splatted value fits in 5 signed bits, a single splat does the job. When it doesn't fit in 5 bits but does fit in 6, and is an even value, we can splat on half the value and add the result to itself. This last optimization hasn't been working recently because of improved constant folding. To circumvent this, create a pseudo VADD_SPLAT that can be expanded during instruction selection. llvm-svn: 175632
2013-02-20 23:50:31 +08:00
VT = MVT::v4i32;
}
Additional fixes for bug 15155. This handles the cases where the 6-bit splat element is odd, converting to a three-instruction sequence to add or subtract two splats. With this fix, the XFAIL in test/CodeGen/PowerPC/vec_constants.ll is removed. llvm-svn: 175663
2013-02-21 04:41:42 +08:00
if ((Elt & 1) == 0) {
// Elt is even, in the range [-32,-18] + [16,30].
//
// Convert: VADD_SPLAT elt, size
// Into: tmp = VSPLTIS[BHW] elt
// VADDU[BHW]M tmp, tmp
// Where: [BHW] = B for size = 1, H for size = 2, W for size = 4
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
SDValue EltVal = getI32Imm(Elt >> 1, dl);
Additional fixes for bug 15155. This handles the cases where the 6-bit splat element is odd, converting to a three-instruction sequence to add or subtract two splats. With this fix, the XFAIL in test/CodeGen/PowerPC/vec_constants.ll is removed. llvm-svn: 175663
2013-02-21 04:41:42 +08:00
SDNode *Tmp = CurDAG->getMachineNode(Opc1, dl, VT, EltVal);
SDValue TmpVal = SDValue(Tmp, 0);
return CurDAG->getMachineNode(Opc2, dl, VT, TmpVal, TmpVal);
} else if (Elt > 0) {
// Elt is odd and positive, in the range [17,31].
//
// Convert: VADD_SPLAT elt, size
// Into: tmp1 = VSPLTIS[BHW] elt-16
// tmp2 = VSPLTIS[BHW] -16
// VSUBU[BHW]M tmp1, tmp2
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
SDValue EltVal = getI32Imm(Elt - 16, dl);
Additional fixes for bug 15155. This handles the cases where the 6-bit splat element is odd, converting to a three-instruction sequence to add or subtract two splats. With this fix, the XFAIL in test/CodeGen/PowerPC/vec_constants.ll is removed. llvm-svn: 175663
2013-02-21 04:41:42 +08:00
SDNode *Tmp1 = CurDAG->getMachineNode(Opc1, dl, VT, EltVal);
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
EltVal = getI32Imm(-16, dl);
Additional fixes for bug 15155. This handles the cases where the 6-bit splat element is odd, converting to a three-instruction sequence to add or subtract two splats. With this fix, the XFAIL in test/CodeGen/PowerPC/vec_constants.ll is removed. llvm-svn: 175663
2013-02-21 04:41:42 +08:00
SDNode *Tmp2 = CurDAG->getMachineNode(Opc1, dl, VT, EltVal);
return CurDAG->getMachineNode(Opc3, dl, VT, SDValue(Tmp1, 0),
SDValue(Tmp2, 0));
} else {
// Elt is odd and negative, in the range [-31,-17].
//
// Convert: VADD_SPLAT elt, size
// Into: tmp1 = VSPLTIS[BHW] elt+16
// tmp2 = VSPLTIS[BHW] -16
// VADDU[BHW]M tmp1, tmp2
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
SDValue EltVal = getI32Imm(Elt + 16, dl);
Additional fixes for bug 15155. This handles the cases where the 6-bit splat element is odd, converting to a three-instruction sequence to add or subtract two splats. With this fix, the XFAIL in test/CodeGen/PowerPC/vec_constants.ll is removed. llvm-svn: 175663
2013-02-21 04:41:42 +08:00
SDNode *Tmp1 = CurDAG->getMachineNode(Opc1, dl, VT, EltVal);
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
EltVal = getI32Imm(-16, dl);
Additional fixes for bug 15155. This handles the cases where the 6-bit splat element is odd, converting to a three-instruction sequence to add or subtract two splats. With this fix, the XFAIL in test/CodeGen/PowerPC/vec_constants.ll is removed. llvm-svn: 175663
2013-02-21 04:41:42 +08:00
SDNode *Tmp2 = CurDAG->getMachineNode(Opc1, dl, VT, EltVal);
return CurDAG->getMachineNode(Opc2, dl, VT, SDValue(Tmp1, 0),
SDValue(Tmp2, 0));
}
Fix PR15155: lost vadd/vsplat optimization. During lowering of a BUILD_VECTOR, we look for opportunities to use a vector splat. When the splatted value fits in 5 signed bits, a single splat does the job. When it doesn't fit in 5 bits but does fit in 6, and is an even value, we can splat on half the value and add the result to itself. This last optimization hasn't been working recently because of improved constant folding. To circumvent this, create a pseudo VADD_SPLAT that can be expanded during instruction selection. llvm-svn: 175632
2013-02-20 23:50:31 +08:00
}
initial hack at a dag->dag instruction selector. This is obviously woefully incomplete, but it is a start. It handles basic argument/retval stuff, immediates, add and sub. llvm-svn: 22836
2005-08-18 03:33:03 +08:00
}
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
Change SelectCode's argument from SDValue to SDNode *, to make it more clear what information these functions are actually using. This is also a micro-optimization, as passing a SDNode * around is simpler than passing a { SDNode *, int } by value or reference. llvm-svn: 92564
2010-01-05 09:24:18 +08:00
return SelectCode(N);
initial hack at a dag->dag instruction selector. This is obviously woefully incomplete, but it is a start. It handles basic argument/retval stuff, immediates, add and sub. llvm-svn: 22836
2005-08-18 03:33:03 +08:00
}
[PowerPC] Add support for the CMPB instruction Newer POWER cores, and the A2, support the cmpb instruction. This instruction compares its operands, treating each of the 8 bytes in the GPRs separately, returning a 'mask' result of 0 (for false) or -1 (for true) in each byte. Code generation support is added, in the form of a PPCISelDAGToDAG DAG-preprocessing routine, that recognizes patterns close to what the instruction computes (either exactly, or related by a constant masking operation), and generates the cmpb instruction (along with any necessary constant masking operation). This can be expanded if use cases arise. llvm-svn: 225106
2015-01-03 09:16:37 +08:00
// If the target supports the cmpb instruction, do the idiom recognition here.
// We don't do this as a DAG combine because we don't want to do it as nodes
// are being combined (because we might miss part of the eventual idiom). We
// don't want to do it during instruction selection because we want to reuse
// the logic for lowering the masking operations already part of the
// instruction selector.
SDValue PPCDAGToDAGISel::combineToCMPB(SDNode *N) {
SDLoc dl(N);
assert(N->getOpcode() == ISD::OR &&
"Only OR nodes are supported for CMPB");
SDValue Res;
if (!PPCSubTarget->hasCMPB())
return Res;
if (N->getValueType(0) != MVT::i32 &&
N->getValueType(0) != MVT::i64)
return Res;
EVT VT = N->getValueType(0);
SDValue RHS, LHS;
bool BytesFound[8] = { 0, 0, 0, 0, 0, 0, 0, 0 };
uint64_t Mask = 0, Alt = 0;
auto IsByteSelectCC = [this](SDValue O, unsigned &b,
uint64_t &Mask, uint64_t &Alt,
SDValue &LHS, SDValue &RHS) {
if (O.getOpcode() != ISD::SELECT_CC)
return false;
ISD::CondCode CC = cast<CondCodeSDNode>(O.getOperand(4))->get();
if (!isa<ConstantSDNode>(O.getOperand(2)) ||
!isa<ConstantSDNode>(O.getOperand(3)))
return false;
uint64_t PM = O.getConstantOperandVal(2);
uint64_t PAlt = O.getConstantOperandVal(3);
for (b = 0; b < 8; ++b) {
uint64_t Mask = UINT64_C(0xFF) << (8*b);
if (PM && (PM & Mask) == PM && (PAlt & Mask) == PAlt)
break;
}
if (b == 8)
return false;
Mask |= PM;
Alt |= PAlt;
if (!isa<ConstantSDNode>(O.getOperand(1)) ||
O.getConstantOperandVal(1) != 0) {
SDValue Op0 = O.getOperand(0), Op1 = O.getOperand(1);
if (Op0.getOpcode() == ISD::TRUNCATE)
Op0 = Op0.getOperand(0);
if (Op1.getOpcode() == ISD::TRUNCATE)
Op1 = Op1.getOperand(0);
if (Op0.getOpcode() == ISD::SRL && Op1.getOpcode() == ISD::SRL &&
Op0.getOperand(1) == Op1.getOperand(1) && CC == ISD::SETEQ &&
isa<ConstantSDNode>(Op0.getOperand(1))) {
unsigned Bits = Op0.getValueType().getSizeInBits();
if (b != Bits/8-1)
return false;
if (Op0.getConstantOperandVal(1) != Bits-8)
return false;
LHS = Op0.getOperand(0);
RHS = Op1.getOperand(0);
return true;
}
// When we have small integers (i16 to be specific), the form present
// post-legalization uses SETULT in the SELECT_CC for the
// higher-order byte, depending on the fact that the
// even-higher-order bytes are known to all be zero, for example:
// select_cc (xor $lhs, $rhs), 256, 65280, 0, setult
// (so when the second byte is the same, because all higher-order
// bits from bytes 3 and 4 are known to be zero, the result of the
// xor can be at most 255)
if (Op0.getOpcode() == ISD::XOR && CC == ISD::SETULT &&
isa<ConstantSDNode>(O.getOperand(1))) {
uint64_t ULim = O.getConstantOperandVal(1);
if (ULim != (UINT64_C(1) << b*8))
return false;
// Now we need to make sure that the upper bytes are known to be
// zero.
unsigned Bits = Op0.getValueType().getSizeInBits();
if (!CurDAG->MaskedValueIsZero(Op0,
APInt::getHighBitsSet(Bits, Bits - (b+1)*8)))
return false;
Test Commit: iteratee Remove whitespace from blank lines. NFC llvm-svn: 254531
2015-12-03 02:53:33 +08:00
[PowerPC] Add support for the CMPB instruction Newer POWER cores, and the A2, support the cmpb instruction. This instruction compares its operands, treating each of the 8 bytes in the GPRs separately, returning a 'mask' result of 0 (for false) or -1 (for true) in each byte. Code generation support is added, in the form of a PPCISelDAGToDAG DAG-preprocessing routine, that recognizes patterns close to what the instruction computes (either exactly, or related by a constant masking operation), and generates the cmpb instruction (along with any necessary constant masking operation). This can be expanded if use cases arise. llvm-svn: 225106
2015-01-03 09:16:37 +08:00
LHS = Op0.getOperand(0);
RHS = Op0.getOperand(1);
return true;
}
return false;
}
if (CC != ISD::SETEQ)
return false;
SDValue Op = O.getOperand(0);
if (Op.getOpcode() == ISD::AND) {
if (!isa<ConstantSDNode>(Op.getOperand(1)))
return false;
if (Op.getConstantOperandVal(1) != (UINT64_C(0xFF) << (8*b)))
return false;
SDValue XOR = Op.getOperand(0);
if (XOR.getOpcode() == ISD::TRUNCATE)
XOR = XOR.getOperand(0);
if (XOR.getOpcode() != ISD::XOR)
return false;
LHS = XOR.getOperand(0);
RHS = XOR.getOperand(1);
return true;
} else if (Op.getOpcode() == ISD::SRL) {
if (!isa<ConstantSDNode>(Op.getOperand(1)))
return false;
unsigned Bits = Op.getValueType().getSizeInBits();
if (b != Bits/8-1)
return false;
if (Op.getConstantOperandVal(1) != Bits-8)
return false;
SDValue XOR = Op.getOperand(0);
if (XOR.getOpcode() == ISD::TRUNCATE)
XOR = XOR.getOperand(0);
if (XOR.getOpcode() != ISD::XOR)
return false;
LHS = XOR.getOperand(0);
RHS = XOR.getOperand(1);
return true;
}
return false;
};
SmallVector<SDValue, 8> Queue(1, SDValue(N, 0));
while (!Queue.empty()) {
SDValue V = Queue.pop_back_val();
for (const SDValue &O : V.getNode()->ops()) {
unsigned b;
uint64_t M = 0, A = 0;
SDValue OLHS, ORHS;
if (O.getOpcode() == ISD::OR) {
Queue.push_back(O);
} else if (IsByteSelectCC(O, b, M, A, OLHS, ORHS)) {
if (!LHS) {
LHS = OLHS;
RHS = ORHS;
BytesFound[b] = true;
Mask |= M;
Alt |= A;
} else if ((LHS == ORHS && RHS == OLHS) ||
(RHS == ORHS && LHS == OLHS)) {
BytesFound[b] = true;
Mask |= M;
Alt |= A;
} else {
return Res;
}
} else {
return Res;
}
}
}
unsigned LastB = 0, BCnt = 0;
for (unsigned i = 0; i < 8; ++i)
if (BytesFound[LastB]) {
++BCnt;
LastB = i;
}
if (!LastB || BCnt < 2)
return Res;
// Because we'll be zero-extending the output anyway if don't have a specific
// value for each input byte (via the Mask), we can 'anyext' the inputs.
if (LHS.getValueType() != VT) {
LHS = CurDAG->getAnyExtOrTrunc(LHS, dl, VT);
RHS = CurDAG->getAnyExtOrTrunc(RHS, dl, VT);
}
Res = CurDAG->getNode(PPCISD::CMPB, dl, VT, LHS, RHS);
bool NonTrivialMask = ((int64_t) Mask) != INT64_C(-1);
if (NonTrivialMask && !Alt) {
// Res = Mask & CMPB
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
Res = CurDAG->getNode(ISD::AND, dl, VT, Res,
CurDAG->getConstant(Mask, dl, VT));
[PowerPC] Add support for the CMPB instruction Newer POWER cores, and the A2, support the cmpb instruction. This instruction compares its operands, treating each of the 8 bytes in the GPRs separately, returning a 'mask' result of 0 (for false) or -1 (for true) in each byte. Code generation support is added, in the form of a PPCISelDAGToDAG DAG-preprocessing routine, that recognizes patterns close to what the instruction computes (either exactly, or related by a constant masking operation), and generates the cmpb instruction (along with any necessary constant masking operation). This can be expanded if use cases arise. llvm-svn: 225106
2015-01-03 09:16:37 +08:00
} else if (Alt) {
// Res = (CMPB & Mask) | (~CMPB & Alt)
// Which, as suggested here:
// https://graphics.stanford.edu/~seander/bithacks.html#MaskedMerge
// can be written as:
// Res = Alt ^ ((Alt ^ Mask) & CMPB)
// useful because the (Alt ^ Mask) can be pre-computed.
Res = CurDAG->getNode(ISD::AND, dl, VT, Res,
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
CurDAG->getConstant(Mask ^ Alt, dl, VT));
Res = CurDAG->getNode(ISD::XOR, dl, VT, Res,
CurDAG->getConstant(Alt, dl, VT));
[PowerPC] Add support for the CMPB instruction Newer POWER cores, and the A2, support the cmpb instruction. This instruction compares its operands, treating each of the 8 bytes in the GPRs separately, returning a 'mask' result of 0 (for false) or -1 (for true) in each byte. Code generation support is added, in the form of a PPCISelDAGToDAG DAG-preprocessing routine, that recognizes patterns close to what the instruction computes (either exactly, or related by a constant masking operation), and generates the cmpb instruction (along with any necessary constant masking operation). This can be expanded if use cases arise. llvm-svn: 225106
2015-01-03 09:16:37 +08:00
}
return Res;
}
[PowerPC] Fold i1 extensions with other ops Consider this function from our README.txt file: int foo(int a, int b) { return (a < b) << 4; } We now explicitly track CR bits by default, so the comment in the README.txt about not really having a SETCC is no longer accurate, but we did generate this somewhat silly code: cmpw 0, 3, 4 li 3, 0 li 12, 1 isel 3, 12, 3, 0 sldi 3, 3, 4 blr which generates the zext as a select between 0 and 1, and then shifts the result by a constant amount. Here we preprocess the DAG in order to fold the results of operations on an extension of an i1 value into the SELECT_I[48] pseudo instruction when the resulting constant can be materialized using one instruction (just like the 0 and 1). This was not implemented as a DAGCombine because the resulting code would have been anti-canonical and depends on replacing chained user nodes, which does not fit well into the lowering paradigm. Now we generate: cmpw 0, 3, 4 li 3, 0 li 12, 16 isel 3, 12, 3, 0 blr which is less silly. llvm-svn: 225203
2015-01-06 05:10:24 +08:00
// When CR bit registers are enabled, an extension of an i1 variable to a i32
// or i64 value is lowered in terms of a SELECT_I[48] operation, and thus
// involves constant materialization of a 0 or a 1 or both. If the result of
// the extension is then operated upon by some operator that can be constant
// folded with a constant 0 or 1, and that constant can be materialized using
// only one instruction (like a zero or one), then we should fold in those
// operations with the select.
void PPCDAGToDAGISel::foldBoolExts(SDValue &Res, SDNode *&N) {
if (!PPCSubTarget->useCRBits())
return;
if (N->getOpcode() != ISD::ZERO_EXTEND &&
N->getOpcode() != ISD::SIGN_EXTEND &&
N->getOpcode() != ISD::ANY_EXTEND)
return;
if (N->getOperand(0).getValueType() != MVT::i1)
return;
if (!N->hasOneUse())
return;
SDLoc dl(N);
EVT VT = N->getValueType(0);
SDValue Cond = N->getOperand(0);
SDValue ConstTrue =
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
CurDAG->getConstant(N->getOpcode() == ISD::SIGN_EXTEND ? -1 : 1, dl, VT);
SDValue ConstFalse = CurDAG->getConstant(0, dl, VT);
[PowerPC] Fold i1 extensions with other ops Consider this function from our README.txt file: int foo(int a, int b) { return (a < b) << 4; } We now explicitly track CR bits by default, so the comment in the README.txt about not really having a SETCC is no longer accurate, but we did generate this somewhat silly code: cmpw 0, 3, 4 li 3, 0 li 12, 1 isel 3, 12, 3, 0 sldi 3, 3, 4 blr which generates the zext as a select between 0 and 1, and then shifts the result by a constant amount. Here we preprocess the DAG in order to fold the results of operations on an extension of an i1 value into the SELECT_I[48] pseudo instruction when the resulting constant can be materialized using one instruction (just like the 0 and 1). This was not implemented as a DAGCombine because the resulting code would have been anti-canonical and depends on replacing chained user nodes, which does not fit well into the lowering paradigm. Now we generate: cmpw 0, 3, 4 li 3, 0 li 12, 16 isel 3, 12, 3, 0 blr which is less silly. llvm-svn: 225203
2015-01-06 05:10:24 +08:00
do {
SDNode *User = *N->use_begin();
if (User->getNumOperands() != 2)
break;
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
auto TryFold = [this, N, User, dl](SDValue Val) {
[PowerPC] Fold i1 extensions with other ops Consider this function from our README.txt file: int foo(int a, int b) { return (a < b) << 4; } We now explicitly track CR bits by default, so the comment in the README.txt about not really having a SETCC is no longer accurate, but we did generate this somewhat silly code: cmpw 0, 3, 4 li 3, 0 li 12, 1 isel 3, 12, 3, 0 sldi 3, 3, 4 blr which generates the zext as a select between 0 and 1, and then shifts the result by a constant amount. Here we preprocess the DAG in order to fold the results of operations on an extension of an i1 value into the SELECT_I[48] pseudo instruction when the resulting constant can be materialized using one instruction (just like the 0 and 1). This was not implemented as a DAGCombine because the resulting code would have been anti-canonical and depends on replacing chained user nodes, which does not fit well into the lowering paradigm. Now we generate: cmpw 0, 3, 4 li 3, 0 li 12, 16 isel 3, 12, 3, 0 blr which is less silly. llvm-svn: 225203
2015-01-06 05:10:24 +08:00
SDValue UserO0 = User->getOperand(0), UserO1 = User->getOperand(1);
SDValue O0 = UserO0.getNode() == N ? Val : UserO0;
SDValue O1 = UserO1.getNode() == N ? Val : UserO1;
Reapply r235977 "[DebugInfo] Add debug locations to constant SD nodes" [DebugInfo] Add debug locations to constant SD nodes This adds debug location to constant nodes of Selection DAG and updates all places that create constants to pass debug locations (see PR13269). Can't guarantee that all locations are correct, but in a lot of cases choice is obvious, so most of them should be. At least all tests pass. Tests for these changes do not cover everything, instead just check it for SDNodes, ARM and AArch64 where it's easy to get incorrect locations on constants. This is not complete fix as FastISel contains workaround for wrong debug locations, which drops locations from instructions on processing constants, but there isn't currently a way to use debug locations from constants there as llvm::Constant doesn't cache it (yet). Although this is a bit different issue, not directly related to these changes. Differential Revision: http://reviews.llvm.org/D9084 llvm-svn: 235989
2015-04-28 22:05:47 +08:00
return CurDAG->FoldConstantArithmetic(User->getOpcode(), dl,
[PowerPC] Fold i1 extensions with other ops Consider this function from our README.txt file: int foo(int a, int b) { return (a < b) << 4; } We now explicitly track CR bits by default, so the comment in the README.txt about not really having a SETCC is no longer accurate, but we did generate this somewhat silly code: cmpw 0, 3, 4 li 3, 0 li 12, 1 isel 3, 12, 3, 0 sldi 3, 3, 4 blr which generates the zext as a select between 0 and 1, and then shifts the result by a constant amount. Here we preprocess the DAG in order to fold the results of operations on an extension of an i1 value into the SELECT_I[48] pseudo instruction when the resulting constant can be materialized using one instruction (just like the 0 and 1). This was not implemented as a DAGCombine because the resulting code would have been anti-canonical and depends on replacing chained user nodes, which does not fit well into the lowering paradigm. Now we generate: cmpw 0, 3, 4 li 3, 0 li 12, 16 isel 3, 12, 3, 0 blr which is less silly. llvm-svn: 225203
2015-01-06 05:10:24 +08:00
User->getValueType(0),
O0.getNode(), O1.getNode());
};
SDValue TrueRes = TryFold(ConstTrue);
if (!TrueRes)
break;
SDValue FalseRes = TryFold(ConstFalse);
if (!FalseRes)
break;
// For us to materialize these using one instruction, we must be able to
// represent them as signed 16-bit integers.
uint64_t True = cast<ConstantSDNode>(TrueRes)->getZExtValue(),
False = cast<ConstantSDNode>(FalseRes)->getZExtValue();
if (!isInt<16>(True) || !isInt<16>(False))
break;
// We can replace User with a new SELECT node, and try again to see if we
// can fold the select with its user.
Res = CurDAG->getSelect(dl, User->getValueType(0), Cond, TrueRes, FalseRes);
N = User;
ConstTrue = TrueRes;
ConstFalse = FalseRes;
} while (N->hasOneUse());
}
[PowerPC] Add support for the CMPB instruction Newer POWER cores, and the A2, support the cmpb instruction. This instruction compares its operands, treating each of the 8 bytes in the GPRs separately, returning a 'mask' result of 0 (for false) or -1 (for true) in each byte. Code generation support is added, in the form of a PPCISelDAGToDAG DAG-preprocessing routine, that recognizes patterns close to what the instruction computes (either exactly, or related by a constant masking operation), and generates the cmpb instruction (along with any necessary constant masking operation). This can be expanded if use cases arise. llvm-svn: 225106
2015-01-03 09:16:37 +08:00
void PPCDAGToDAGISel::PreprocessISelDAG() {
SelectionDAG::allnodes_iterator Position(CurDAG->getRoot().getNode());
++Position;
bool MadeChange = false;
while (Position != CurDAG->allnodes_begin()) {
PowerPC: Remove implicit ilist iterator conversions, NFC llvm-svn: 250787
2015-10-20 09:07:37 +08:00
SDNode *N = &*--Position;
[PowerPC] Add support for the CMPB instruction Newer POWER cores, and the A2, support the cmpb instruction. This instruction compares its operands, treating each of the 8 bytes in the GPRs separately, returning a 'mask' result of 0 (for false) or -1 (for true) in each byte. Code generation support is added, in the form of a PPCISelDAGToDAG DAG-preprocessing routine, that recognizes patterns close to what the instruction computes (either exactly, or related by a constant masking operation), and generates the cmpb instruction (along with any necessary constant masking operation). This can be expanded if use cases arise. llvm-svn: 225106
2015-01-03 09:16:37 +08:00
if (N->use_empty())
continue;
SDValue Res;
switch (N->getOpcode()) {
default: break;
case ISD::OR:
Res = combineToCMPB(N);
break;
}
[PowerPC] Fold i1 extensions with other ops Consider this function from our README.txt file: int foo(int a, int b) { return (a < b) << 4; } We now explicitly track CR bits by default, so the comment in the README.txt about not really having a SETCC is no longer accurate, but we did generate this somewhat silly code: cmpw 0, 3, 4 li 3, 0 li 12, 1 isel 3, 12, 3, 0 sldi 3, 3, 4 blr which generates the zext as a select between 0 and 1, and then shifts the result by a constant amount. Here we preprocess the DAG in order to fold the results of operations on an extension of an i1 value into the SELECT_I[48] pseudo instruction when the resulting constant can be materialized using one instruction (just like the 0 and 1). This was not implemented as a DAGCombine because the resulting code would have been anti-canonical and depends on replacing chained user nodes, which does not fit well into the lowering paradigm. Now we generate: cmpw 0, 3, 4 li 3, 0 li 12, 16 isel 3, 12, 3, 0 blr which is less silly. llvm-svn: 225203
2015-01-06 05:10:24 +08:00
if (!Res)
foldBoolExts(Res, N);
[PowerPC] Add support for the CMPB instruction Newer POWER cores, and the A2, support the cmpb instruction. This instruction compares its operands, treating each of the 8 bytes in the GPRs separately, returning a 'mask' result of 0 (for false) or -1 (for true) in each byte. Code generation support is added, in the form of a PPCISelDAGToDAG DAG-preprocessing routine, that recognizes patterns close to what the instruction computes (either exactly, or related by a constant masking operation), and generates the cmpb instruction (along with any necessary constant masking operation). This can be expanded if use cases arise. llvm-svn: 225106
2015-01-03 09:16:37 +08:00
if (Res) {
DEBUG(dbgs() << "PPC DAG preprocessing replacing:\nOld: ");
DEBUG(N->dump(CurDAG));
DEBUG(dbgs() << "\nNew: ");
DEBUG(Res.getNode()->dump(CurDAG));
DEBUG(dbgs() << "\n");
CurDAG->ReplaceAllUsesOfValueWith(SDValue(N, 0), Res);
MadeChange = true;
}
}
if (MadeChange)
CurDAG->RemoveDeadNodes();
}
[PPC] Fix comment to match function name llvm-svn: 198362
2014-01-03 06:09:39 +08:00
/// PostprocessISelDAG - Perform some late peephole optimizations
PPCDAGToDAGISel::PostprocessISelDAG() This patch implements the PPCDAGToDAGISel::PostprocessISelDAG virtual method to perform post-selection peephole optimizations on the DAG representation. One optimization is implemented here: folds to clean up complex addressing expressions for thread-local storage and medium code model. It will also be useful for large code model sequences when those are added later. I originally thought about doing this on the MI representation prior to register assignment, but it's difficult to do effective global dead code elimination at that point. DCE is trivial on the DAG representation. A typical example of a candidate code sequence in assembly: addis 3, 2, globalvar@toc@ha addi 3, 3, globalvar@toc@l lwz 5, 0(3) When the final instruction is a load or store with an immediate offset of zero, the offset from the add-immediate can replace the zero, provided the relocation information is carried along: addis 3, 2, globalvar@toc@ha lwz 5, globalvar@toc@l(3) Since the addi can in general have multiple uses, we need to only delete the instruction when the last use is removed. llvm-svn: 175697
2013-02-21 08:38:25 +08:00
/// on the DAG representation.
void PPCDAGToDAGISel::PostprocessISelDAG() {
// Skip peepholes at -O0.
if (TM.getOptLevel() == CodeGenOpt::None)
return;
Add CR-bit tracking to the PowerPC backend for i1 values This change enables tracking i1 values in the PowerPC backend using the condition register bits. These bits can be treated on PowerPC as separate registers; individual bit operations (and, or, xor, etc.) are supported. Tracking booleans in CR bits has several advantages: - Reduction in register pressure (because we no longer need GPRs to store boolean values). - Logical operations on booleans can be handled more efficiently; we used to have to move all results from comparisons into GPRs, perform promoted logical operations in GPRs, and then move the result back into condition register bits to be used by conditional branches. This can be very inefficient, because the throughput of these CR <-> GPR moves have high latency and low throughput (especially when other associated instructions are accounted for). - On the POWER7 and similar cores, we can increase total throughput by using the CR bits. CR bit operations have a dedicated functional unit. Most of this is more-or-less mechanical: Adjustments were needed in the calling-convention code, support was added for spilling/restoring individual condition-register bits, and conditional branch instruction definitions taking specific CR bits were added (plus patterns and code for generating bit-level operations). This is enabled by default when running at -O2 and higher. For -O0 and -O1, where the ability to debug is more important, this feature is disabled by default. Individual CR bits do not have assigned DWARF register numbers, and storing values in CR bits makes them invisible to the debugger. It is critical, however, that we don't move i1 values that have been promoted to larger values (such as those passed as function arguments) into bit registers only to quickly turn around and move the values back into GPRs (such as happens when values are returned by functions). A pair of target-specific DAG combines are added to remove the trunc/extends in: trunc(binary-ops(binary-ops(zext(x), zext(y)), ...) and: zext(binary-ops(binary-ops(trunc(x), trunc(y)), ...) In short, we only want to use CR bits where some of the i1 values come from comparisons or are used by conditional branches or selects. To put it another way, if we can do the entire i1 computation in GPRs, then we probably should (on the POWER7, the GPR-operation throughput is higher, and for all cores, the CR <-> GPR moves are expensive). POWER7 test-suite performance results (from 10 runs in each configuration): SingleSource/Benchmarks/Misc/mandel-2: 35% speedup MultiSource/Benchmarks/Prolangs-C++/city/city: 21% speedup MultiSource/Benchmarks/MiBench/automotive-susan: 23% speedup SingleSource/Benchmarks/CoyoteBench/huffbench: 13% speedup SingleSource/Benchmarks/Misc-C++/Large/sphereflake: 13% speedup SingleSource/Benchmarks/Misc-C++/mandel-text: 10% speedup SingleSource/Benchmarks/Misc-C++-EH/spirit: 10% slowdown MultiSource/Applications/lemon/lemon: 8% slowdown llvm-svn: 202451
2014-02-28 08:27:01 +08:00
PeepholePPC64();
Fix typo in function name. llvm-svn: 208743
2014-05-14 08:31:15 +08:00
PeepholeCROps();
[PowerPC] Add a DAGToDAG peephole to remove unnecessary zero-exts On PPC64, we end up with lots of i32 -> i64 zero extensions, not only from all of the usual places, but also from the ABI, which specifies that values passed are zero extended. Almost all 32-bit PPC instructions in PPC64 mode are defined to do *something* to the higher-order bits, and for some instructions, that action clears those bits (thus providing a zero-extended result). This is especially common after rotate-and-mask instructions. Adding an additional instruction to zero-extend the results of these instructions is unnecessary. This PPCISelDAGToDAG peephole optimization examines these zero-extensions, and looks back through their operands to see if all instructions will implicitly zero extend their results. If so, we convert these instructions to their 64-bit variants (which is an internal change only, the actual encoding of these instructions is the same as the original 32-bit ones) and remove the unnecessary zero-extension (changing where the INSERT_SUBREG instructions are to make everything internally consistent). llvm-svn: 224169
2014-12-13 07:59:36 +08:00
PeepholePPC64ZExt();
Add CR-bit tracking to the PowerPC backend for i1 values This change enables tracking i1 values in the PowerPC backend using the condition register bits. These bits can be treated on PowerPC as separate registers; individual bit operations (and, or, xor, etc.) are supported. Tracking booleans in CR bits has several advantages: - Reduction in register pressure (because we no longer need GPRs to store boolean values). - Logical operations on booleans can be handled more efficiently; we used to have to move all results from comparisons into GPRs, perform promoted logical operations in GPRs, and then move the result back into condition register bits to be used by conditional branches. This can be very inefficient, because the throughput of these CR <-> GPR moves have high latency and low throughput (especially when other associated instructions are accounted for). - On the POWER7 and similar cores, we can increase total throughput by using the CR bits. CR bit operations have a dedicated functional unit. Most of this is more-or-less mechanical: Adjustments were needed in the calling-convention code, support was added for spilling/restoring individual condition-register bits, and conditional branch instruction definitions taking specific CR bits were added (plus patterns and code for generating bit-level operations). This is enabled by default when running at -O2 and higher. For -O0 and -O1, where the ability to debug is more important, this feature is disabled by default. Individual CR bits do not have assigned DWARF register numbers, and storing values in CR bits makes them invisible to the debugger. It is critical, however, that we don't move i1 values that have been promoted to larger values (such as those passed as function arguments) into bit registers only to quickly turn around and move the values back into GPRs (such as happens when values are returned by functions). A pair of target-specific DAG combines are added to remove the trunc/extends in: trunc(binary-ops(binary-ops(zext(x), zext(y)), ...) and: zext(binary-ops(binary-ops(trunc(x), trunc(y)), ...) In short, we only want to use CR bits where some of the i1 values come from comparisons or are used by conditional branches or selects. To put it another way, if we can do the entire i1 computation in GPRs, then we probably should (on the POWER7, the GPR-operation throughput is higher, and for all cores, the CR <-> GPR moves are expensive). POWER7 test-suite performance results (from 10 runs in each configuration): SingleSource/Benchmarks/Misc/mandel-2: 35% speedup MultiSource/Benchmarks/Prolangs-C++/city/city: 21% speedup MultiSource/Benchmarks/MiBench/automotive-susan: 23% speedup SingleSource/Benchmarks/CoyoteBench/huffbench: 13% speedup SingleSource/Benchmarks/Misc-C++/Large/sphereflake: 13% speedup SingleSource/Benchmarks/Misc-C++/mandel-text: 10% speedup SingleSource/Benchmarks/Misc-C++-EH/spirit: 10% slowdown MultiSource/Applications/lemon/lemon: 8% slowdown llvm-svn: 202451
2014-02-28 08:27:01 +08:00
}
Swap PPC isel operands to allow for 0-folding The PPC isel instruction can fold 0 into the first operand (thus eliminating the need to materialize a zero-containing register when the 'true' result of the isel is 0). When the isel is fed by a bit register operation that we can invert, do so as part of the bit-register-operation peephole routine. llvm-svn: 202469
2014-02-28 14:11:16 +08:00
// Check if all users of this node will become isel where the second operand
// is the constant zero. If this is so, and if we can negate the condition,
// then we can flip the true and false operands. This will allow the zero to
// be folded with the isel so that we don't need to materialize a register
// containing zero.
bool PPCDAGToDAGISel::AllUsersSelectZero(SDNode *N) {
// If we're not using isel, then this does not matter.
Reset the subtarget for DAGToDAG on every iteration of runOnMachineFunction. This required updating the generated functions and TD file accordingly to be pointers rather than const references. llvm-svn: 209375
2014-05-22 09:07:24 +08:00
if (!PPCSubTarget->hasISEL())
Swap PPC isel operands to allow for 0-folding The PPC isel instruction can fold 0 into the first operand (thus eliminating the need to materialize a zero-containing register when the 'true' result of the isel is 0). When the isel is fed by a bit register operation that we can invert, do so as part of the bit-register-operation peephole routine. llvm-svn: 202469
2014-02-28 14:11:16 +08:00
return false;
for (SDNode::use_iterator UI = N->use_begin(), UE = N->use_end();
UI != UE; ++UI) {
SDNode *User = *UI;
if (!User->isMachineOpcode())
return false;
if (User->getMachineOpcode() != PPC::SELECT_I4 &&
User->getMachineOpcode() != PPC::SELECT_I8)
return false;
SDNode *Op2 = User->getOperand(2).getNode();
if (!Op2->isMachineOpcode())
return false;
if (Op2->getMachineOpcode() != PPC::LI &&
Op2->getMachineOpcode() != PPC::LI8)
return false;
ConstantSDNode *C = dyn_cast<ConstantSDNode>(Op2->getOperand(0));
if (!C)
return false;
if (!C->isNullValue())
return false;
}
return true;
}
void PPCDAGToDAGISel::SwapAllSelectUsers(SDNode *N) {
SmallVector<SDNode *, 4> ToReplace;
for (SDNode::use_iterator UI = N->use_begin(), UE = N->use_end();
UI != UE; ++UI) {
SDNode *User = *UI;
assert((User->getMachineOpcode() == PPC::SELECT_I4 ||
User->getMachineOpcode() == PPC::SELECT_I8) &&
"Must have all select users");
ToReplace.push_back(User);
}
for (SmallVector<SDNode *, 4>::iterator UI = ToReplace.begin(),
UE = ToReplace.end(); UI != UE; ++UI) {
SDNode *User = *UI;
SDNode *ResNode =
CurDAG->getMachineNode(User->getMachineOpcode(), SDLoc(User),
User->getValueType(0), User->getOperand(0),
User->getOperand(2),
User->getOperand(1));
DEBUG(dbgs() << "CR Peephole replacing:\nOld: ");
DEBUG(User->dump(CurDAG));
DEBUG(dbgs() << "\nNew: ");
DEBUG(ResNode->dump(CurDAG));
DEBUG(dbgs() << "\n");
ReplaceUses(User, ResNode);
}
}
Fix typo in function name. llvm-svn: 208743
2014-05-14 08:31:15 +08:00
void PPCDAGToDAGISel::PeepholeCROps() {
Add CR-bit tracking to the PowerPC backend for i1 values This change enables tracking i1 values in the PowerPC backend using the condition register bits. These bits can be treated on PowerPC as separate registers; individual bit operations (and, or, xor, etc.) are supported. Tracking booleans in CR bits has several advantages: - Reduction in register pressure (because we no longer need GPRs to store boolean values). - Logical operations on booleans can be handled more efficiently; we used to have to move all results from comparisons into GPRs, perform promoted logical operations in GPRs, and then move the result back into condition register bits to be used by conditional branches. This can be very inefficient, because the throughput of these CR <-> GPR moves have high latency and low throughput (especially when other associated instructions are accounted for). - On the POWER7 and similar cores, we can increase total throughput by using the CR bits. CR bit operations have a dedicated functional unit. Most of this is more-or-less mechanical: Adjustments were needed in the calling-convention code, support was added for spilling/restoring individual condition-register bits, and conditional branch instruction definitions taking specific CR bits were added (plus patterns and code for generating bit-level operations). This is enabled by default when running at -O2 and higher. For -O0 and -O1, where the ability to debug is more important, this feature is disabled by default. Individual CR bits do not have assigned DWARF register numbers, and storing values in CR bits makes them invisible to the debugger. It is critical, however, that we don't move i1 values that have been promoted to larger values (such as those passed as function arguments) into bit registers only to quickly turn around and move the values back into GPRs (such as happens when values are returned by functions). A pair of target-specific DAG combines are added to remove the trunc/extends in: trunc(binary-ops(binary-ops(zext(x), zext(y)), ...) and: zext(binary-ops(binary-ops(trunc(x), trunc(y)), ...) In short, we only want to use CR bits where some of the i1 values come from comparisons or are used by conditional branches or selects. To put it another way, if we can do the entire i1 computation in GPRs, then we probably should (on the POWER7, the GPR-operation throughput is higher, and for all cores, the CR <-> GPR moves are expensive). POWER7 test-suite performance results (from 10 runs in each configuration): SingleSource/Benchmarks/Misc/mandel-2: 35% speedup MultiSource/Benchmarks/Prolangs-C++/city/city: 21% speedup MultiSource/Benchmarks/MiBench/automotive-susan: 23% speedup SingleSource/Benchmarks/CoyoteBench/huffbench: 13% speedup SingleSource/Benchmarks/Misc-C++/Large/sphereflake: 13% speedup SingleSource/Benchmarks/Misc-C++/mandel-text: 10% speedup SingleSource/Benchmarks/Misc-C++-EH/spirit: 10% slowdown MultiSource/Applications/lemon/lemon: 8% slowdown llvm-svn: 202451
2014-02-28 08:27:01 +08:00
bool IsModified;
do {
IsModified = false;
Add allnodes() iterator range to SelectionDAG. NFC. SelectionDAG already had begin/end methods for iterating over all the nodes, but didn't define an iterator_range for us in foreach loops. This adds such a method and uses it in some of the eligible places throughout the backends. llvm-svn: 242212
2015-07-15 06:10:54 +08:00
for (SDNode &Node : CurDAG->allnodes()) {
MachineSDNode *MachineNode = dyn_cast<MachineSDNode>(&Node);
Add CR-bit tracking to the PowerPC backend for i1 values This change enables tracking i1 values in the PowerPC backend using the condition register bits. These bits can be treated on PowerPC as separate registers; individual bit operations (and, or, xor, etc.) are supported. Tracking booleans in CR bits has several advantages: - Reduction in register pressure (because we no longer need GPRs to store boolean values). - Logical operations on booleans can be handled more efficiently; we used to have to move all results from comparisons into GPRs, perform promoted logical operations in GPRs, and then move the result back into condition register bits to be used by conditional branches. This can be very inefficient, because the throughput of these CR <-> GPR moves have high latency and low throughput (especially when other associated instructions are accounted for). - On the POWER7 and similar cores, we can increase total throughput by using the CR bits. CR bit operations have a dedicated functional unit. Most of this is more-or-less mechanical: Adjustments were needed in the calling-convention code, support was added for spilling/restoring individual condition-register bits, and conditional branch instruction definitions taking specific CR bits were added (plus patterns and code for generating bit-level operations). This is enabled by default when running at -O2 and higher. For -O0 and -O1, where the ability to debug is more important, this feature is disabled by default. Individual CR bits do not have assigned DWARF register numbers, and storing values in CR bits makes them invisible to the debugger. It is critical, however, that we don't move i1 values that have been promoted to larger values (such as those passed as function arguments) into bit registers only to quickly turn around and move the values back into GPRs (such as happens when values are returned by functions). A pair of target-specific DAG combines are added to remove the trunc/extends in: trunc(binary-ops(binary-ops(zext(x), zext(y)), ...) and: zext(binary-ops(binary-ops(trunc(x), trunc(y)), ...) In short, we only want to use CR bits where some of the i1 values come from comparisons or are used by conditional branches or selects. To put it another way, if we can do the entire i1 computation in GPRs, then we probably should (on the POWER7, the GPR-operation throughput is higher, and for all cores, the CR <-> GPR moves are expensive). POWER7 test-suite performance results (from 10 runs in each configuration): SingleSource/Benchmarks/Misc/mandel-2: 35% speedup MultiSource/Benchmarks/Prolangs-C++/city/city: 21% speedup MultiSource/Benchmarks/MiBench/automotive-susan: 23% speedup SingleSource/Benchmarks/CoyoteBench/huffbench: 13% speedup SingleSource/Benchmarks/Misc-C++/Large/sphereflake: 13% speedup SingleSource/Benchmarks/Misc-C++/mandel-text: 10% speedup SingleSource/Benchmarks/Misc-C++-EH/spirit: 10% slowdown MultiSource/Applications/lemon/lemon: 8% slowdown llvm-svn: 202451
2014-02-28 08:27:01 +08:00
if (!MachineNode || MachineNode->use_empty())
continue;
SDNode *ResNode = MachineNode;
bool Op1Set = false, Op1Unset = false,
Op1Not = false,
Op2Set = false, Op2Unset = false,
Op2Not = false;
unsigned Opcode = MachineNode->getMachineOpcode();
switch (Opcode) {
default: break;
case PPC::CRAND:
case PPC::CRNAND:
case PPC::CROR:
case PPC::CRXOR:
case PPC::CRNOR:
case PPC::CREQV:
case PPC::CRANDC:
case PPC::CRORC: {
SDValue Op = MachineNode->getOperand(1);
if (Op.isMachineOpcode()) {
if (Op.getMachineOpcode() == PPC::CRSET)
Op2Set = true;
else if (Op.getMachineOpcode() == PPC::CRUNSET)
Op2Unset = true;
else if (Op.getMachineOpcode() == PPC::CRNOR &&
Op.getOperand(0) == Op.getOperand(1))
Op2Not = true;
}
} // fallthrough
case PPC::BC:
case PPC::BCn:
case PPC::SELECT_I4:
case PPC::SELECT_I8:
case PPC::SELECT_F4:
case PPC::SELECT_F8:
[PowerPC] Add support for the QPX vector instruction set This adds support for the QPX vector instruction set, which is used by the enhanced A2 cores on the IBM BG/Q supercomputers. QPX vectors are 256 bytes wide, holding 4 double-precision floating-point values. Boolean values, modeled here as <4 x i1> are actually also represented as floating-point values (essentially { -1, 1 } for { false, true }). QPX shares many features with Altivec and VSX, but is distinct from both of them. One major difference is that, instead of adding completely-separate vector registers, QPX vector registers are extensions of the scalar floating-point registers (lane 0 is the corresponding scalar floating-point value). The operations supported on QPX vectors mirrors that supported on the scalar floating-point values (with some additional ones for permutations and logical/comparison operations). I've been maintaining this support out-of-tree, as part of the bgclang project, for several years. This is not the entire bgclang patch set, but is most of the subset that can be cleanly integrated into LLVM proper at this time. Adding this to the LLVM backend is part of my efforts to rebase bgclang to the current LLVM trunk, but is independently useful (especially for codes that use LLVM as a JIT in library form). The assembler/disassembler test coverage is complete. The CodeGen test coverage is not, but I've included some tests, and more will be added as follow-up work. llvm-svn: 230413
2015-02-25 09:06:45 +08:00
case PPC::SELECT_QFRC:
case PPC::SELECT_QSRC:
case PPC::SELECT_QBRC:
[PowerPC] Support select-cc for VSX The tests test/CodeGen/Generic/select-cc.ll and test/CodeGen/PowerPC/select-cc.ll both fail with VSX enabled. The problem is that the lowering logic for the SELECT and SELECT_CC operations doesn't currently support the VSX registers. This patch fixes that. In lib/Target/PowerPC/PPCInstrInfo.td, we have pseudos to handle this for other register classes. Similar pseudos are added in PPCInstrVSX.td (they must be there, because the "vsrc" register class definition appears there) for the VSRC register class. The SELECT_VSRC pseudo is then used in pattern matching for SELECT_CC. The rest of the patch just adds logic for SELECT_VSRC wherever similar logic appears for SELECT_VRRC. There are no new test cases because the existing tests above test this, along with a variant in test/CodeGen/PowerPC/vsx.ll. After discussion with Hal, a future patch will add similar _VSFRC variants to override f64 type handling (currently using F8RC). llvm-svn: 220385
2014-10-22 21:13:40 +08:00
case PPC::SELECT_VRRC:
[PATCH] Support select-cc for VSFRC when VSX is enabled A previous patch enabled SELECT_VSRC and SELECT_CC_VSRC for VSX to handle <2 x double> cases. This patch adds SELECT_VSFRC and SELECT_CC_VSFRC to allow use of all 64 vector-scalar registers for the f64 type when VSX is enabled. The changes are analogous to those in the previous patch. I've added a new variant to vsx.ll to test the code generation. (I also cleaned up a little formatting in PPCInstrVSX.td from the previous patch.) llvm-svn: 220395
2014-10-23 00:58:20 +08:00
case PPC::SELECT_VSFRC:
Add VSX Scalar loads and stores to the PPC back end This patch corresponds to review: http://reviews.llvm.org/D9440 It adds a new register class to the PPC back end to contain single precision values in VSX registers. Additionally, it adds scalar loads and stores for VSX registers. llvm-svn: 236755
2015-05-08 02:24:05 +08:00
case PPC::SELECT_VSSRC:
[PowerPC] Support select-cc for VSX The tests test/CodeGen/Generic/select-cc.ll and test/CodeGen/PowerPC/select-cc.ll both fail with VSX enabled. The problem is that the lowering logic for the SELECT and SELECT_CC operations doesn't currently support the VSX registers. This patch fixes that. In lib/Target/PowerPC/PPCInstrInfo.td, we have pseudos to handle this for other register classes. Similar pseudos are added in PPCInstrVSX.td (they must be there, because the "vsrc" register class definition appears there) for the VSRC register class. The SELECT_VSRC pseudo is then used in pattern matching for SELECT_CC. The rest of the patch just adds logic for SELECT_VSRC wherever similar logic appears for SELECT_VRRC. There are no new test cases because the existing tests above test this, along with a variant in test/CodeGen/PowerPC/vsx.ll. After discussion with Hal, a future patch will add similar _VSFRC variants to override f64 type handling (currently using F8RC). llvm-svn: 220385
2014-10-22 21:13:40 +08:00
case PPC::SELECT_VSRC: {
Add CR-bit tracking to the PowerPC backend for i1 values This change enables tracking i1 values in the PowerPC backend using the condition register bits. These bits can be treated on PowerPC as separate registers; individual bit operations (and, or, xor, etc.) are supported. Tracking booleans in CR bits has several advantages: - Reduction in register pressure (because we no longer need GPRs to store boolean values). - Logical operations on booleans can be handled more efficiently; we used to have to move all results from comparisons into GPRs, perform promoted logical operations in GPRs, and then move the result back into condition register bits to be used by conditional branches. This can be very inefficient, because the throughput of these CR <-> GPR moves have high latency and low throughput (especially when other associated instructions are accounted for). - On the POWER7 and similar cores, we can increase total throughput by using the CR bits. CR bit operations have a dedicated functional unit. Most of this is more-or-less mechanical: Adjustments were needed in the calling-convention code, support was added for spilling/restoring individual condition-register bits, and conditional branch instruction definitions taking specific CR bits were added (plus patterns and code for generating bit-level operations). This is enabled by default when running at -O2 and higher. For -O0 and -O1, where the ability to debug is more important, this feature is disabled by default. Individual CR bits do not have assigned DWARF register numbers, and storing values in CR bits makes them invisible to the debugger. It is critical, however, that we don't move i1 values that have been promoted to larger values (such as those passed as function arguments) into bit registers only to quickly turn around and move the values back into GPRs (such as happens when values are returned by functions). A pair of target-specific DAG combines are added to remove the trunc/extends in: trunc(binary-ops(binary-ops(zext(x), zext(y)), ...) and: zext(binary-ops(binary-ops(trunc(x), trunc(y)), ...) In short, we only want to use CR bits where some of the i1 values come from comparisons or are used by conditional branches or selects. To put it another way, if we can do the entire i1 computation in GPRs, then we probably should (on the POWER7, the GPR-operation throughput is higher, and for all cores, the CR <-> GPR moves are expensive). POWER7 test-suite performance results (from 10 runs in each configuration): SingleSource/Benchmarks/Misc/mandel-2: 35% speedup MultiSource/Benchmarks/Prolangs-C++/city/city: 21% speedup MultiSource/Benchmarks/MiBench/automotive-susan: 23% speedup SingleSource/Benchmarks/CoyoteBench/huffbench: 13% speedup SingleSource/Benchmarks/Misc-C++/Large/sphereflake: 13% speedup SingleSource/Benchmarks/Misc-C++/mandel-text: 10% speedup SingleSource/Benchmarks/Misc-C++-EH/spirit: 10% slowdown MultiSource/Applications/lemon/lemon: 8% slowdown llvm-svn: 202451
2014-02-28 08:27:01 +08:00
SDValue Op = MachineNode->getOperand(0);
if (Op.isMachineOpcode()) {
if (Op.getMachineOpcode() == PPC::CRSET)
Op1Set = true;
else if (Op.getMachineOpcode() == PPC::CRUNSET)
Op1Unset = true;
else if (Op.getMachineOpcode() == PPC::CRNOR &&
Op.getOperand(0) == Op.getOperand(1))
Op1Not = true;
}
}
break;
}
Swap PPC isel operands to allow for 0-folding The PPC isel instruction can fold 0 into the first operand (thus eliminating the need to materialize a zero-containing register when the 'true' result of the isel is 0). When the isel is fed by a bit register operation that we can invert, do so as part of the bit-register-operation peephole routine. llvm-svn: 202469
2014-02-28 14:11:16 +08:00
bool SelectSwap = false;
Add CR-bit tracking to the PowerPC backend for i1 values This change enables tracking i1 values in the PowerPC backend using the condition register bits. These bits can be treated on PowerPC as separate registers; individual bit operations (and, or, xor, etc.) are supported. Tracking booleans in CR bits has several advantages: - Reduction in register pressure (because we no longer need GPRs to store boolean values). - Logical operations on booleans can be handled more efficiently; we used to have to move all results from comparisons into GPRs, perform promoted logical operations in GPRs, and then move the result back into condition register bits to be used by conditional branches. This can be very inefficient, because the throughput of these CR <-> GPR moves have high latency and low throughput (especially when other associated instructions are accounted for). - On the POWER7 and similar cores, we can increase total throughput by using the CR bits. CR bit operations have a dedicated functional unit. Most of this is more-or-less mechanical: Adjustments were needed in the calling-convention code, support was added for spilling/restoring individual condition-register bits, and conditional branch instruction definitions taking specific CR bits were added (plus patterns and code for generating bit-level operations). This is enabled by default when running at -O2 and higher. For -O0 and -O1, where the ability to debug is more important, this feature is disabled by default. Individual CR bits do not have assigned DWARF register numbers, and storing values in CR bits makes them invisible to the debugger. It is critical, however, that we don't move i1 values that have been promoted to larger values (such as those passed as function arguments) into bit registers only to quickly turn around and move the values back into GPRs (such as happens when values are returned by functions). A pair of target-specific DAG combines are added to remove the trunc/extends in: trunc(binary-ops(binary-ops(zext(x), zext(y)), ...) and: zext(binary-ops(binary-ops(trunc(x), trunc(y)), ...) In short, we only want to use CR bits where some of the i1 values come from comparisons or are used by conditional branches or selects. To put it another way, if we can do the entire i1 computation in GPRs, then we probably should (on the POWER7, the GPR-operation throughput is higher, and for all cores, the CR <-> GPR moves are expensive). POWER7 test-suite performance results (from 10 runs in each configuration): SingleSource/Benchmarks/Misc/mandel-2: 35% speedup MultiSource/Benchmarks/Prolangs-C++/city/city: 21% speedup MultiSource/Benchmarks/MiBench/automotive-susan: 23% speedup SingleSource/Benchmarks/CoyoteBench/huffbench: 13% speedup SingleSource/Benchmarks/Misc-C++/Large/sphereflake: 13% speedup SingleSource/Benchmarks/Misc-C++/mandel-text: 10% speedup SingleSource/Benchmarks/Misc-C++-EH/spirit: 10% slowdown MultiSource/Applications/lemon/lemon: 8% slowdown llvm-svn: 202451
2014-02-28 08:27:01 +08:00
switch (Opcode) {
default: break;
case PPC::CRAND:
if (MachineNode->getOperand(0) == MachineNode->getOperand(1))
// x & x = x
ResNode = MachineNode->getOperand(0).getNode();
else if (Op1Set)
// 1 & y = y
ResNode = MachineNode->getOperand(1).getNode();
else if (Op2Set)
// x & 1 = x
ResNode = MachineNode->getOperand(0).getNode();
else if (Op1Unset || Op2Unset)
// x & 0 = 0 & y = 0
ResNode = CurDAG->getMachineNode(PPC::CRUNSET, SDLoc(MachineNode),
MVT::i1);
else if (Op1Not)
// ~x & y = andc(y, x)
ResNode = CurDAG->getMachineNode(PPC::CRANDC, SDLoc(MachineNode),
MVT::i1, MachineNode->getOperand(1),
MachineNode->getOperand(0).
getOperand(0));
else if (Op2Not)
// x & ~y = andc(x, y)
ResNode = CurDAG->getMachineNode(PPC::CRANDC, SDLoc(MachineNode),
MVT::i1, MachineNode->getOperand(0),
MachineNode->getOperand(1).
getOperand(0));
Swap PPC isel operands to allow for 0-folding The PPC isel instruction can fold 0 into the first operand (thus eliminating the need to materialize a zero-containing register when the 'true' result of the isel is 0). When the isel is fed by a bit register operation that we can invert, do so as part of the bit-register-operation peephole routine. llvm-svn: 202469
2014-02-28 14:11:16 +08:00
else if (AllUsersSelectZero(MachineNode))
ResNode = CurDAG->getMachineNode(PPC::CRNAND, SDLoc(MachineNode),
MVT::i1, MachineNode->getOperand(0),
MachineNode->getOperand(1)),
SelectSwap = true;
Add CR-bit tracking to the PowerPC backend for i1 values This change enables tracking i1 values in the PowerPC backend using the condition register bits. These bits can be treated on PowerPC as separate registers; individual bit operations (and, or, xor, etc.) are supported. Tracking booleans in CR bits has several advantages: - Reduction in register pressure (because we no longer need GPRs to store boolean values). - Logical operations on booleans can be handled more efficiently; we used to have to move all results from comparisons into GPRs, perform promoted logical operations in GPRs, and then move the result back into condition register bits to be used by conditional branches. This can be very inefficient, because the throughput of these CR <-> GPR moves have high latency and low throughput (especially when other associated instructions are accounted for). - On the POWER7 and similar cores, we can increase total throughput by using the CR bits. CR bit operations have a dedicated functional unit. Most of this is more-or-less mechanical: Adjustments were needed in the calling-convention code, support was added for spilling/restoring individual condition-register bits, and conditional branch instruction definitions taking specific CR bits were added (plus patterns and code for generating bit-level operations). This is enabled by default when running at -O2 and higher. For -O0 and -O1, where the ability to debug is more important, this feature is disabled by default. Individual CR bits do not have assigned DWARF register numbers, and storing values in CR bits makes them invisible to the debugger. It is critical, however, that we don't move i1 values that have been promoted to larger values (such as those passed as function arguments) into bit registers only to quickly turn around and move the values back into GPRs (such as happens when values are returned by functions). A pair of target-specific DAG combines are added to remove the trunc/extends in: trunc(binary-ops(binary-ops(zext(x), zext(y)), ...) and: zext(binary-ops(binary-ops(trunc(x), trunc(y)), ...) In short, we only want to use CR bits where some of the i1 values come from comparisons or are used by conditional branches or selects. To put it another way, if we can do the entire i1 computation in GPRs, then we probably should (on the POWER7, the GPR-operation throughput is higher, and for all cores, the CR <-> GPR moves are expensive). POWER7 test-suite performance results (from 10 runs in each configuration): SingleSource/Benchmarks/Misc/mandel-2: 35% speedup MultiSource/Benchmarks/Prolangs-C++/city/city: 21% speedup MultiSource/Benchmarks/MiBench/automotive-susan: 23% speedup SingleSource/Benchmarks/CoyoteBench/huffbench: 13% speedup SingleSource/Benchmarks/Misc-C++/Large/sphereflake: 13% speedup SingleSource/Benchmarks/Misc-C++/mandel-text: 10% speedup SingleSource/Benchmarks/Misc-C++-EH/spirit: 10% slowdown MultiSource/Applications/lemon/lemon: 8% slowdown llvm-svn: 202451
2014-02-28 08:27:01 +08:00
break;
case PPC::CRNAND:
if (MachineNode->getOperand(0) == MachineNode->getOperand(1))
// nand(x, x) -> nor(x, x)
ResNode = CurDAG->getMachineNode(PPC::CRNOR, SDLoc(MachineNode),
MVT::i1, MachineNode->getOperand(0),
MachineNode->getOperand(0));
else if (Op1Set)
// nand(1, y) -> nor(y, y)
ResNode = CurDAG->getMachineNode(PPC::CRNOR, SDLoc(MachineNode),
MVT::i1, MachineNode->getOperand(1),
MachineNode->getOperand(1));
else if (Op2Set)
// nand(x, 1) -> nor(x, x)
ResNode = CurDAG->getMachineNode(PPC::CRNOR, SDLoc(MachineNode),
MVT::i1, MachineNode->getOperand(0),
MachineNode->getOperand(0));
else if (Op1Unset || Op2Unset)
// nand(x, 0) = nand(0, y) = 1
ResNode = CurDAG->getMachineNode(PPC::CRSET, SDLoc(MachineNode),
MVT::i1);
else if (Op1Not)
// nand(~x, y) = ~(~x & y) = x | ~y = orc(x, y)
ResNode = CurDAG->getMachineNode(PPC::CRORC, SDLoc(MachineNode),
MVT::i1, MachineNode->getOperand(0).
getOperand(0),
MachineNode->getOperand(1));
else if (Op2Not)
// nand(x, ~y) = ~x | y = orc(y, x)
ResNode = CurDAG->getMachineNode(PPC::CRORC, SDLoc(MachineNode),
MVT::i1, MachineNode->getOperand(1).
getOperand(0),
MachineNode->getOperand(0));
Swap PPC isel operands to allow for 0-folding The PPC isel instruction can fold 0 into the first operand (thus eliminating the need to materialize a zero-containing register when the 'true' result of the isel is 0). When the isel is fed by a bit register operation that we can invert, do so as part of the bit-register-operation peephole routine. llvm-svn: 202469
2014-02-28 14:11:16 +08:00
else if (AllUsersSelectZero(MachineNode))
ResNode = CurDAG->getMachineNode(PPC::CRAND, SDLoc(MachineNode),
MVT::i1, MachineNode->getOperand(0),
MachineNode->getOperand(1)),
SelectSwap = true;
Add CR-bit tracking to the PowerPC backend for i1 values This change enables tracking i1 values in the PowerPC backend using the condition register bits. These bits can be treated on PowerPC as separate registers; individual bit operations (and, or, xor, etc.) are supported. Tracking booleans in CR bits has several advantages: - Reduction in register pressure (because we no longer need GPRs to store boolean values). - Logical operations on booleans can be handled more efficiently; we used to have to move all results from comparisons into GPRs, perform promoted logical operations in GPRs, and then move the result back into condition register bits to be used by conditional branches. This can be very inefficient, because the throughput of these CR <-> GPR moves have high latency and low throughput (especially when other associated instructions are accounted for). - On the POWER7 and similar cores, we can increase total throughput by using the CR bits. CR bit operations have a dedicated functional unit. Most of this is more-or-less mechanical: Adjustments were needed in the calling-convention code, support was added for spilling/restoring individual condition-register bits, and conditional branch instruction definitions taking specific CR bits were added (plus patterns and code for generating bit-level operations). This is enabled by default when running at -O2 and higher. For -O0 and -O1, where the ability to debug is more important, this feature is disabled by default. Individual CR bits do not have assigned DWARF register numbers, and storing values in CR bits makes them invisible to the debugger. It is critical, however, that we don't move i1 values that have been promoted to larger values (such as those passed as function arguments) into bit registers only to quickly turn around and move the values back into GPRs (such as happens when values are returned by functions). A pair of target-specific DAG combines are added to remove the trunc/extends in: trunc(binary-ops(binary-ops(zext(x), zext(y)), ...) and: zext(binary-ops(binary-ops(trunc(x), trunc(y)), ...) In short, we only want to use CR bits where some of the i1 values come from comparisons or are used by conditional branches or selects. To put it another way, if we can do the entire i1 computation in GPRs, then we probably should (on the POWER7, the GPR-operation throughput is higher, and for all cores, the CR <-> GPR moves are expensive). POWER7 test-suite performance results (from 10 runs in each configuration): SingleSource/Benchmarks/Misc/mandel-2: 35% speedup MultiSource/Benchmarks/Prolangs-C++/city/city: 21% speedup MultiSource/Benchmarks/MiBench/automotive-susan: 23% speedup SingleSource/Benchmarks/CoyoteBench/huffbench: 13% speedup SingleSource/Benchmarks/Misc-C++/Large/sphereflake: 13% speedup SingleSource/Benchmarks/Misc-C++/mandel-text: 10% speedup SingleSource/Benchmarks/Misc-C++-EH/spirit: 10% slowdown MultiSource/Applications/lemon/lemon: 8% slowdown llvm-svn: 202451
2014-02-28 08:27:01 +08:00
break;
case PPC::CROR:
if (MachineNode->getOperand(0) == MachineNode->getOperand(1))
// x | x = x
ResNode = MachineNode->getOperand(0).getNode();
else if (Op1Set || Op2Set)
// x | 1 = 1 | y = 1
ResNode = CurDAG->getMachineNode(PPC::CRSET, SDLoc(MachineNode),
MVT::i1);
else if (Op1Unset)
// 0 | y = y
ResNode = MachineNode->getOperand(1).getNode();
else if (Op2Unset)
// x | 0 = x
ResNode = MachineNode->getOperand(0).getNode();
else if (Op1Not)
// ~x | y = orc(y, x)
ResNode = CurDAG->getMachineNode(PPC::CRORC, SDLoc(MachineNode),
MVT::i1, MachineNode->getOperand(1),
MachineNode->getOperand(0).
getOperand(0));
else if (Op2Not)
// x | ~y = orc(x, y)
ResNode = CurDAG->getMachineNode(PPC::CRORC, SDLoc(MachineNode),
MVT::i1, MachineNode->getOperand(0),
MachineNode->getOperand(1).
getOperand(0));
Swap PPC isel operands to allow for 0-folding The PPC isel instruction can fold 0 into the first operand (thus eliminating the need to materialize a zero-containing register when the 'true' result of the isel is 0). When the isel is fed by a bit register operation that we can invert, do so as part of the bit-register-operation peephole routine. llvm-svn: 202469
2014-02-28 14:11:16 +08:00
else if (AllUsersSelectZero(MachineNode))
ResNode = CurDAG->getMachineNode(PPC::CRNOR, SDLoc(MachineNode),
MVT::i1, MachineNode->getOperand(0),
MachineNode->getOperand(1)),
SelectSwap = true;
Add CR-bit tracking to the PowerPC backend for i1 values This change enables tracking i1 values in the PowerPC backend using the condition register bits. These bits can be treated on PowerPC as separate registers; individual bit operations (and, or, xor, etc.) are supported. Tracking booleans in CR bits has several advantages: - Reduction in register pressure (because we no longer need GPRs to store boolean values). - Logical operations on booleans can be handled more efficiently; we used to have to move all results from comparisons into GPRs, perform promoted logical operations in GPRs, and then move the result back into condition register bits to be used by conditional branches. This can be very inefficient, because the throughput of these CR <-> GPR moves have high latency and low throughput (especially when other associated instructions are accounted for). - On the POWER7 and similar cores, we can increase total throughput by using the CR bits. CR bit operations have a dedicated functional unit. Most of this is more-or-less mechanical: Adjustments were needed in the calling-convention code, support was added for spilling/restoring individual condition-register bits, and conditional branch instruction definitions taking specific CR bits were added (plus patterns and code for generating bit-level operations). This is enabled by default when running at -O2 and higher. For -O0 and -O1, where the ability to debug is more important, this feature is disabled by default. Individual CR bits do not have assigned DWARF register numbers, and storing values in CR bits makes them invisible to the debugger. It is critical, however, that we don't move i1 values that have been promoted to larger values (such as those passed as function arguments) into bit registers only to quickly turn around and move the values back into GPRs (such as happens when values are returned by functions). A pair of target-specific DAG combines are added to remove the trunc/extends in: trunc(binary-ops(binary-ops(zext(x), zext(y)), ...) and: zext(binary-ops(binary-ops(trunc(x), trunc(y)), ...) In short, we only want to use CR bits where some of the i1 values come from comparisons or are used by conditional branches or selects. To put it another way, if we can do the entire i1 computation in GPRs, then we probably should (on the POWER7, the GPR-operation throughput is higher, and for all cores, the CR <-> GPR moves are expensive). POWER7 test-suite performance results (from 10 runs in each configuration): SingleSource/Benchmarks/Misc/mandel-2: 35% speedup MultiSource/Benchmarks/Prolangs-C++/city/city: 21% speedup MultiSource/Benchmarks/MiBench/automotive-susan: 23% speedup SingleSource/Benchmarks/CoyoteBench/huffbench: 13% speedup SingleSource/Benchmarks/Misc-C++/Large/sphereflake: 13% speedup SingleSource/Benchmarks/Misc-C++/mandel-text: 10% speedup SingleSource/Benchmarks/Misc-C++-EH/spirit: 10% slowdown MultiSource/Applications/lemon/lemon: 8% slowdown llvm-svn: 202451
2014-02-28 08:27:01 +08:00
break;
case PPC::CRXOR:
if (MachineNode->getOperand(0) == MachineNode->getOperand(1))
// xor(x, x) = 0
ResNode = CurDAG->getMachineNode(PPC::CRUNSET, SDLoc(MachineNode),
MVT::i1);
else if (Op1Set)
// xor(1, y) -> nor(y, y)
ResNode = CurDAG->getMachineNode(PPC::CRNOR, SDLoc(MachineNode),
MVT::i1, MachineNode->getOperand(1),
MachineNode->getOperand(1));
else if (Op2Set)
// xor(x, 1) -> nor(x, x)
ResNode = CurDAG->getMachineNode(PPC::CRNOR, SDLoc(MachineNode),
MVT::i1, MachineNode->getOperand(0),
MachineNode->getOperand(0));
else if (Op1Unset)
// xor(0, y) = y
ResNode = MachineNode->getOperand(1).getNode();
else if (Op2Unset)
// xor(x, 0) = x
ResNode = MachineNode->getOperand(0).getNode();
else if (Op1Not)
// xor(~x, y) = eqv(x, y)
ResNode = CurDAG->getMachineNode(PPC::CREQV, SDLoc(MachineNode),
MVT::i1, MachineNode->getOperand(0).
getOperand(0),
MachineNode->getOperand(1));
else if (Op2Not)
// xor(x, ~y) = eqv(x, y)
ResNode = CurDAG->getMachineNode(PPC::CREQV, SDLoc(MachineNode),
MVT::i1, MachineNode->getOperand(0),
MachineNode->getOperand(1).
getOperand(0));
Swap PPC isel operands to allow for 0-folding The PPC isel instruction can fold 0 into the first operand (thus eliminating the need to materialize a zero-containing register when the 'true' result of the isel is 0). When the isel is fed by a bit register operation that we can invert, do so as part of the bit-register-operation peephole routine. llvm-svn: 202469
2014-02-28 14:11:16 +08:00
else if (AllUsersSelectZero(MachineNode))
ResNode = CurDAG->getMachineNode(PPC::CREQV, SDLoc(MachineNode),
MVT::i1, MachineNode->getOperand(0),
MachineNode->getOperand(1)),
SelectSwap = true;
Add CR-bit tracking to the PowerPC backend for i1 values This change enables tracking i1 values in the PowerPC backend using the condition register bits. These bits can be treated on PowerPC as separate registers; individual bit operations (and, or, xor, etc.) are supported. Tracking booleans in CR bits has several advantages: - Reduction in register pressure (because we no longer need GPRs to store boolean values). - Logical operations on booleans can be handled more efficiently; we used to have to move all results from comparisons into GPRs, perform promoted logical operations in GPRs, and then move the result back into condition register bits to be used by conditional branches. This can be very inefficient, because the throughput of these CR <-> GPR moves have high latency and low throughput (especially when other associated instructions are accounted for). - On the POWER7 and similar cores, we can increase total throughput by using the CR bits. CR bit operations have a dedicated functional unit. Most of this is more-or-less mechanical: Adjustments were needed in the calling-convention code, support was added for spilling/restoring individual condition-register bits, and conditional branch instruction definitions taking specific CR bits were added (plus patterns and code for generating bit-level operations). This is enabled by default when running at -O2 and higher. For -O0 and -O1, where the ability to debug is more important, this feature is disabled by default. Individual CR bits do not have assigned DWARF register numbers, and storing values in CR bits makes them invisible to the debugger. It is critical, however, that we don't move i1 values that have been promoted to larger values (such as those passed as function arguments) into bit registers only to quickly turn around and move the values back into GPRs (such as happens when values are returned by functions). A pair of target-specific DAG combines are added to remove the trunc/extends in: trunc(binary-ops(binary-ops(zext(x), zext(y)), ...) and: zext(binary-ops(binary-ops(trunc(x), trunc(y)), ...) In short, we only want to use CR bits where some of the i1 values come from comparisons or are used by conditional branches or selects. To put it another way, if we can do the entire i1 computation in GPRs, then we probably should (on the POWER7, the GPR-operation throughput is higher, and for all cores, the CR <-> GPR moves are expensive). POWER7 test-suite performance results (from 10 runs in each configuration): SingleSource/Benchmarks/Misc/mandel-2: 35% speedup MultiSource/Benchmarks/Prolangs-C++/city/city: 21% speedup MultiSource/Benchmarks/MiBench/automotive-susan: 23% speedup SingleSource/Benchmarks/CoyoteBench/huffbench: 13% speedup SingleSource/Benchmarks/Misc-C++/Large/sphereflake: 13% speedup SingleSource/Benchmarks/Misc-C++/mandel-text: 10% speedup SingleSource/Benchmarks/Misc-C++-EH/spirit: 10% slowdown MultiSource/Applications/lemon/lemon: 8% slowdown llvm-svn: 202451
2014-02-28 08:27:01 +08:00
break;
case PPC::CRNOR:
if (Op1Set || Op2Set)
// nor(1, y) -> 0
ResNode = CurDAG->getMachineNode(PPC::CRUNSET, SDLoc(MachineNode),
MVT::i1);
else if (Op1Unset)
// nor(0, y) = ~y -> nor(y, y)
ResNode = CurDAG->getMachineNode(PPC::CRNOR, SDLoc(MachineNode),
MVT::i1, MachineNode->getOperand(1),
MachineNode->getOperand(1));
else if (Op2Unset)
// nor(x, 0) = ~x
ResNode = CurDAG->getMachineNode(PPC::CRNOR, SDLoc(MachineNode),
MVT::i1, MachineNode->getOperand(0),
MachineNode->getOperand(0));
else if (Op1Not)
// nor(~x, y) = andc(x, y)
ResNode = CurDAG->getMachineNode(PPC::CRANDC, SDLoc(MachineNode),
MVT::i1, MachineNode->getOperand(0).
getOperand(0),
MachineNode->getOperand(1));
else if (Op2Not)
// nor(x, ~y) = andc(y, x)
ResNode = CurDAG->getMachineNode(PPC::CRANDC, SDLoc(MachineNode),
MVT::i1, MachineNode->getOperand(1).
getOperand(0),
MachineNode->getOperand(0));
Swap PPC isel operands to allow for 0-folding The PPC isel instruction can fold 0 into the first operand (thus eliminating the need to materialize a zero-containing register when the 'true' result of the isel is 0). When the isel is fed by a bit register operation that we can invert, do so as part of the bit-register-operation peephole routine. llvm-svn: 202469
2014-02-28 14:11:16 +08:00
else if (AllUsersSelectZero(MachineNode))
ResNode = CurDAG->getMachineNode(PPC::CROR, SDLoc(MachineNode),
MVT::i1, MachineNode->getOperand(0),
MachineNode->getOperand(1)),
SelectSwap = true;
Add CR-bit tracking to the PowerPC backend for i1 values This change enables tracking i1 values in the PowerPC backend using the condition register bits. These bits can be treated on PowerPC as separate registers; individual bit operations (and, or, xor, etc.) are supported. Tracking booleans in CR bits has several advantages: - Reduction in register pressure (because we no longer need GPRs to store boolean values). - Logical operations on booleans can be handled more efficiently; we used to have to move all results from comparisons into GPRs, perform promoted logical operations in GPRs, and then move the result back into condition register bits to be used by conditional branches. This can be very inefficient, because the throughput of these CR <-> GPR moves have high latency and low throughput (especially when other associated instructions are accounted for). - On the POWER7 and similar cores, we can increase total throughput by using the CR bits. CR bit operations have a dedicated functional unit. Most of this is more-or-less mechanical: Adjustments were needed in the calling-convention code, support was added for spilling/restoring individual condition-register bits, and conditional branch instruction definitions taking specific CR bits were added (plus patterns and code for generating bit-level operations). This is enabled by default when running at -O2 and higher. For -O0 and -O1, where the ability to debug is more important, this feature is disabled by default. Individual CR bits do not have assigned DWARF register numbers, and storing values in CR bits makes them invisible to the debugger. It is critical, however, that we don't move i1 values that have been promoted to larger values (such as those passed as function arguments) into bit registers only to quickly turn around and move the values back into GPRs (such as happens when values are returned by functions). A pair of target-specific DAG combines are added to remove the trunc/extends in: trunc(binary-ops(binary-ops(zext(x), zext(y)), ...) and: zext(binary-ops(binary-ops(trunc(x), trunc(y)), ...) In short, we only want to use CR bits where some of the i1 values come from comparisons or are used by conditional branches or selects. To put it another way, if we can do the entire i1 computation in GPRs, then we probably should (on the POWER7, the GPR-operation throughput is higher, and for all cores, the CR <-> GPR moves are expensive). POWER7 test-suite performance results (from 10 runs in each configuration): SingleSource/Benchmarks/Misc/mandel-2: 35% speedup MultiSource/Benchmarks/Prolangs-C++/city/city: 21% speedup MultiSource/Benchmarks/MiBench/automotive-susan: 23% speedup SingleSource/Benchmarks/CoyoteBench/huffbench: 13% speedup SingleSource/Benchmarks/Misc-C++/Large/sphereflake: 13% speedup SingleSource/Benchmarks/Misc-C++/mandel-text: 10% speedup SingleSource/Benchmarks/Misc-C++-EH/spirit: 10% slowdown MultiSource/Applications/lemon/lemon: 8% slowdown llvm-svn: 202451
2014-02-28 08:27:01 +08:00
break;
case PPC::CREQV:
if (MachineNode->getOperand(0) == MachineNode->getOperand(1))
// eqv(x, x) = 1
ResNode = CurDAG->getMachineNode(PPC::CRSET, SDLoc(MachineNode),
MVT::i1);
else if (Op1Set)
// eqv(1, y) = y
ResNode = MachineNode->getOperand(1).getNode();
else if (Op2Set)
// eqv(x, 1) = x
ResNode = MachineNode->getOperand(0).getNode();
else if (Op1Unset)
// eqv(0, y) = ~y -> nor(y, y)
ResNode = CurDAG->getMachineNode(PPC::CRNOR, SDLoc(MachineNode),
MVT::i1, MachineNode->getOperand(1),
MachineNode->getOperand(1));
else if (Op2Unset)
// eqv(x, 0) = ~x
ResNode = CurDAG->getMachineNode(PPC::CRNOR, SDLoc(MachineNode),
MVT::i1, MachineNode->getOperand(0),
MachineNode->getOperand(0));
else if (Op1Not)
// eqv(~x, y) = xor(x, y)
ResNode = CurDAG->getMachineNode(PPC::CRXOR, SDLoc(MachineNode),
MVT::i1, MachineNode->getOperand(0).
getOperand(0),
MachineNode->getOperand(1));
else if (Op2Not)
// eqv(x, ~y) = xor(x, y)
ResNode = CurDAG->getMachineNode(PPC::CRXOR, SDLoc(MachineNode),
MVT::i1, MachineNode->getOperand(0),
MachineNode->getOperand(1).
getOperand(0));
Swap PPC isel operands to allow for 0-folding The PPC isel instruction can fold 0 into the first operand (thus eliminating the need to materialize a zero-containing register when the 'true' result of the isel is 0). When the isel is fed by a bit register operation that we can invert, do so as part of the bit-register-operation peephole routine. llvm-svn: 202469
2014-02-28 14:11:16 +08:00
else if (AllUsersSelectZero(MachineNode))
ResNode = CurDAG->getMachineNode(PPC::CRXOR, SDLoc(MachineNode),
MVT::i1, MachineNode->getOperand(0),
MachineNode->getOperand(1)),
SelectSwap = true;
Add CR-bit tracking to the PowerPC backend for i1 values This change enables tracking i1 values in the PowerPC backend using the condition register bits. These bits can be treated on PowerPC as separate registers; individual bit operations (and, or, xor, etc.) are supported. Tracking booleans in CR bits has several advantages: - Reduction in register pressure (because we no longer need GPRs to store boolean values). - Logical operations on booleans can be handled more efficiently; we used to have to move all results from comparisons into GPRs, perform promoted logical operations in GPRs, and then move the result back into condition register bits to be used by conditional branches. This can be very inefficient, because the throughput of these CR <-> GPR moves have high latency and low throughput (especially when other associated instructions are accounted for). - On the POWER7 and similar cores, we can increase total throughput by using the CR bits. CR bit operations have a dedicated functional unit. Most of this is more-or-less mechanical: Adjustments were needed in the calling-convention code, support was added for spilling/restoring individual condition-register bits, and conditional branch instruction definitions taking specific CR bits were added (plus patterns and code for generating bit-level operations). This is enabled by default when running at -O2 and higher. For -O0 and -O1, where the ability to debug is more important, this feature is disabled by default. Individual CR bits do not have assigned DWARF register numbers, and storing values in CR bits makes them invisible to the debugger. It is critical, however, that we don't move i1 values that have been promoted to larger values (such as those passed as function arguments) into bit registers only to quickly turn around and move the values back into GPRs (such as happens when values are returned by functions). A pair of target-specific DAG combines are added to remove the trunc/extends in: trunc(binary-ops(binary-ops(zext(x), zext(y)), ...) and: zext(binary-ops(binary-ops(trunc(x), trunc(y)), ...) In short, we only want to use CR bits where some of the i1 values come from comparisons or are used by conditional branches or selects. To put it another way, if we can do the entire i1 computation in GPRs, then we probably should (on the POWER7, the GPR-operation throughput is higher, and for all cores, the CR <-> GPR moves are expensive). POWER7 test-suite performance results (from 10 runs in each configuration): SingleSource/Benchmarks/Misc/mandel-2: 35% speedup MultiSource/Benchmarks/Prolangs-C++/city/city: 21% speedup MultiSource/Benchmarks/MiBench/automotive-susan: 23% speedup SingleSource/Benchmarks/CoyoteBench/huffbench: 13% speedup SingleSource/Benchmarks/Misc-C++/Large/sphereflake: 13% speedup SingleSource/Benchmarks/Misc-C++/mandel-text: 10% speedup SingleSource/Benchmarks/Misc-C++-EH/spirit: 10% slowdown MultiSource/Applications/lemon/lemon: 8% slowdown llvm-svn: 202451
2014-02-28 08:27:01 +08:00
break;
case PPC::CRANDC:
if (MachineNode->getOperand(0) == MachineNode->getOperand(1))
// andc(x, x) = 0
ResNode = CurDAG->getMachineNode(PPC::CRUNSET, SDLoc(MachineNode),
MVT::i1);
else if (Op1Set)
// andc(1, y) = ~y
ResNode = CurDAG->getMachineNode(PPC::CRNOR, SDLoc(MachineNode),
MVT::i1, MachineNode->getOperand(1),
MachineNode->getOperand(1));
else if (Op1Unset || Op2Set)
// andc(0, y) = andc(x, 1) = 0
ResNode = CurDAG->getMachineNode(PPC::CRUNSET, SDLoc(MachineNode),
MVT::i1);
else if (Op2Unset)
// andc(x, 0) = x
ResNode = MachineNode->getOperand(0).getNode();
else if (Op1Not)
// andc(~x, y) = ~(x | y) = nor(x, y)
ResNode = CurDAG->getMachineNode(PPC::CRNOR, SDLoc(MachineNode),
MVT::i1, MachineNode->getOperand(0).
getOperand(0),
MachineNode->getOperand(1));
else if (Op2Not)
// andc(x, ~y) = x & y
ResNode = CurDAG->getMachineNode(PPC::CRAND, SDLoc(MachineNode),
MVT::i1, MachineNode->getOperand(0),
MachineNode->getOperand(1).
getOperand(0));
Swap PPC isel operands to allow for 0-folding The PPC isel instruction can fold 0 into the first operand (thus eliminating the need to materialize a zero-containing register when the 'true' result of the isel is 0). When the isel is fed by a bit register operation that we can invert, do so as part of the bit-register-operation peephole routine. llvm-svn: 202469
2014-02-28 14:11:16 +08:00
else if (AllUsersSelectZero(MachineNode))
ResNode = CurDAG->getMachineNode(PPC::CRORC, SDLoc(MachineNode),
MVT::i1, MachineNode->getOperand(1),
MachineNode->getOperand(0)),
SelectSwap = true;
Add CR-bit tracking to the PowerPC backend for i1 values This change enables tracking i1 values in the PowerPC backend using the condition register bits. These bits can be treated on PowerPC as separate registers; individual bit operations (and, or, xor, etc.) are supported. Tracking booleans in CR bits has several advantages: - Reduction in register pressure (because we no longer need GPRs to store boolean values). - Logical operations on booleans can be handled more efficiently; we used to have to move all results from comparisons into GPRs, perform promoted logical operations in GPRs, and then move the result back into condition register bits to be used by conditional branches. This can be very inefficient, because the throughput of these CR <-> GPR moves have high latency and low throughput (especially when other associated instructions are accounted for). - On the POWER7 and similar cores, we can increase total throughput by using the CR bits. CR bit operations have a dedicated functional unit. Most of this is more-or-less mechanical: Adjustments were needed in the calling-convention code, support was added for spilling/restoring individual condition-register bits, and conditional branch instruction definitions taking specific CR bits were added (plus patterns and code for generating bit-level operations). This is enabled by default when running at -O2 and higher. For -O0 and -O1, where the ability to debug is more important, this feature is disabled by default. Individual CR bits do not have assigned DWARF register numbers, and storing values in CR bits makes them invisible to the debugger. It is critical, however, that we don't move i1 values that have been promoted to larger values (such as those passed as function arguments) into bit registers only to quickly turn around and move the values back into GPRs (such as happens when values are returned by functions). A pair of target-specific DAG combines are added to remove the trunc/extends in: trunc(binary-ops(binary-ops(zext(x), zext(y)), ...) and: zext(binary-ops(binary-ops(trunc(x), trunc(y)), ...) In short, we only want to use CR bits where some of the i1 values come from comparisons or are used by conditional branches or selects. To put it another way, if we can do the entire i1 computation in GPRs, then we probably should (on the POWER7, the GPR-operation throughput is higher, and for all cores, the CR <-> GPR moves are expensive). POWER7 test-suite performance results (from 10 runs in each configuration): SingleSource/Benchmarks/Misc/mandel-2: 35% speedup MultiSource/Benchmarks/Prolangs-C++/city/city: 21% speedup MultiSource/Benchmarks/MiBench/automotive-susan: 23% speedup SingleSource/Benchmarks/CoyoteBench/huffbench: 13% speedup SingleSource/Benchmarks/Misc-C++/Large/sphereflake: 13% speedup SingleSource/Benchmarks/Misc-C++/mandel-text: 10% speedup SingleSource/Benchmarks/Misc-C++-EH/spirit: 10% slowdown MultiSource/Applications/lemon/lemon: 8% slowdown llvm-svn: 202451
2014-02-28 08:27:01 +08:00
break;
case PPC::CRORC:
if (MachineNode->getOperand(0) == MachineNode->getOperand(1))
// orc(x, x) = 1
ResNode = CurDAG->getMachineNode(PPC::CRSET, SDLoc(MachineNode),
MVT::i1);
else if (Op1Set || Op2Unset)
// orc(1, y) = orc(x, 0) = 1
ResNode = CurDAG->getMachineNode(PPC::CRSET, SDLoc(MachineNode),
MVT::i1);
else if (Op2Set)
// orc(x, 1) = x
ResNode = MachineNode->getOperand(0).getNode();
else if (Op1Unset)
// orc(0, y) = ~y
ResNode = CurDAG->getMachineNode(PPC::CRNOR, SDLoc(MachineNode),
MVT::i1, MachineNode->getOperand(1),
MachineNode->getOperand(1));
else if (Op1Not)
// orc(~x, y) = ~(x & y) = nand(x, y)
ResNode = CurDAG->getMachineNode(PPC::CRNAND, SDLoc(MachineNode),
MVT::i1, MachineNode->getOperand(0).
getOperand(0),
MachineNode->getOperand(1));
else if (Op2Not)
// orc(x, ~y) = x | y
ResNode = CurDAG->getMachineNode(PPC::CROR, SDLoc(MachineNode),
MVT::i1, MachineNode->getOperand(0),
MachineNode->getOperand(1).
getOperand(0));
Swap PPC isel operands to allow for 0-folding The PPC isel instruction can fold 0 into the first operand (thus eliminating the need to materialize a zero-containing register when the 'true' result of the isel is 0). When the isel is fed by a bit register operation that we can invert, do so as part of the bit-register-operation peephole routine. llvm-svn: 202469
2014-02-28 14:11:16 +08:00
else if (AllUsersSelectZero(MachineNode))
ResNode = CurDAG->getMachineNode(PPC::CRANDC, SDLoc(MachineNode),
MVT::i1, MachineNode->getOperand(1),
MachineNode->getOperand(0)),
SelectSwap = true;
Add CR-bit tracking to the PowerPC backend for i1 values This change enables tracking i1 values in the PowerPC backend using the condition register bits. These bits can be treated on PowerPC as separate registers; individual bit operations (and, or, xor, etc.) are supported. Tracking booleans in CR bits has several advantages: - Reduction in register pressure (because we no longer need GPRs to store boolean values). - Logical operations on booleans can be handled more efficiently; we used to have to move all results from comparisons into GPRs, perform promoted logical operations in GPRs, and then move the result back into condition register bits to be used by conditional branches. This can be very inefficient, because the throughput of these CR <-> GPR moves have high latency and low throughput (especially when other associated instructions are accounted for). - On the POWER7 and similar cores, we can increase total throughput by using the CR bits. CR bit operations have a dedicated functional unit. Most of this is more-or-less mechanical: Adjustments were needed in the calling-convention code, support was added for spilling/restoring individual condition-register bits, and conditional branch instruction definitions taking specific CR bits were added (plus patterns and code for generating bit-level operations). This is enabled by default when running at -O2 and higher. For -O0 and -O1, where the ability to debug is more important, this feature is disabled by default. Individual CR bits do not have assigned DWARF register numbers, and storing values in CR bits makes them invisible to the debugger. It is critical, however, that we don't move i1 values that have been promoted to larger values (such as those passed as function arguments) into bit registers only to quickly turn around and move the values back into GPRs (such as happens when values are returned by functions). A pair of target-specific DAG combines are added to remove the trunc/extends in: trunc(binary-ops(binary-ops(zext(x), zext(y)), ...) and: zext(binary-ops(binary-ops(trunc(x), trunc(y)), ...) In short, we only want to use CR bits where some of the i1 values come from comparisons or are used by conditional branches or selects. To put it another way, if we can do the entire i1 computation in GPRs, then we probably should (on the POWER7, the GPR-operation throughput is higher, and for all cores, the CR <-> GPR moves are expensive). POWER7 test-suite performance results (from 10 runs in each configuration): SingleSource/Benchmarks/Misc/mandel-2: 35% speedup MultiSource/Benchmarks/Prolangs-C++/city/city: 21% speedup MultiSource/Benchmarks/MiBench/automotive-susan: 23% speedup SingleSource/Benchmarks/CoyoteBench/huffbench: 13% speedup SingleSource/Benchmarks/Misc-C++/Large/sphereflake: 13% speedup SingleSource/Benchmarks/Misc-C++/mandel-text: 10% speedup SingleSource/Benchmarks/Misc-C++-EH/spirit: 10% slowdown MultiSource/Applications/lemon/lemon: 8% slowdown llvm-svn: 202451
2014-02-28 08:27:01 +08:00
break;
case PPC::SELECT_I4:
case PPC::SELECT_I8:
case PPC::SELECT_F4:
case PPC::SELECT_F8:
[PowerPC] Add support for the QPX vector instruction set This adds support for the QPX vector instruction set, which is used by the enhanced A2 cores on the IBM BG/Q supercomputers. QPX vectors are 256 bytes wide, holding 4 double-precision floating-point values. Boolean values, modeled here as <4 x i1> are actually also represented as floating-point values (essentially { -1, 1 } for { false, true }). QPX shares many features with Altivec and VSX, but is distinct from both of them. One major difference is that, instead of adding completely-separate vector registers, QPX vector registers are extensions of the scalar floating-point registers (lane 0 is the corresponding scalar floating-point value). The operations supported on QPX vectors mirrors that supported on the scalar floating-point values (with some additional ones for permutations and logical/comparison operations). I've been maintaining this support out-of-tree, as part of the bgclang project, for several years. This is not the entire bgclang patch set, but is most of the subset that can be cleanly integrated into LLVM proper at this time. Adding this to the LLVM backend is part of my efforts to rebase bgclang to the current LLVM trunk, but is independently useful (especially for codes that use LLVM as a JIT in library form). The assembler/disassembler test coverage is complete. The CodeGen test coverage is not, but I've included some tests, and more will be added as follow-up work. llvm-svn: 230413
2015-02-25 09:06:45 +08:00
case PPC::SELECT_QFRC:
case PPC::SELECT_QSRC:
case PPC::SELECT_QBRC:
Add CR-bit tracking to the PowerPC backend for i1 values This change enables tracking i1 values in the PowerPC backend using the condition register bits. These bits can be treated on PowerPC as separate registers; individual bit operations (and, or, xor, etc.) are supported. Tracking booleans in CR bits has several advantages: - Reduction in register pressure (because we no longer need GPRs to store boolean values). - Logical operations on booleans can be handled more efficiently; we used to have to move all results from comparisons into GPRs, perform promoted logical operations in GPRs, and then move the result back into condition register bits to be used by conditional branches. This can be very inefficient, because the throughput of these CR <-> GPR moves have high latency and low throughput (especially when other associated instructions are accounted for). - On the POWER7 and similar cores, we can increase total throughput by using the CR bits. CR bit operations have a dedicated functional unit. Most of this is more-or-less mechanical: Adjustments were needed in the calling-convention code, support was added for spilling/restoring individual condition-register bits, and conditional branch instruction definitions taking specific CR bits were added (plus patterns and code for generating bit-level operations). This is enabled by default when running at -O2 and higher. For -O0 and -O1, where the ability to debug is more important, this feature is disabled by default. Individual CR bits do not have assigned DWARF register numbers, and storing values in CR bits makes them invisible to the debugger. It is critical, however, that we don't move i1 values that have been promoted to larger values (such as those passed as function arguments) into bit registers only to quickly turn around and move the values back into GPRs (such as happens when values are returned by functions). A pair of target-specific DAG combines are added to remove the trunc/extends in: trunc(binary-ops(binary-ops(zext(x), zext(y)), ...) and: zext(binary-ops(binary-ops(trunc(x), trunc(y)), ...) In short, we only want to use CR bits where some of the i1 values come from comparisons or are used by conditional branches or selects. To put it another way, if we can do the entire i1 computation in GPRs, then we probably should (on the POWER7, the GPR-operation throughput is higher, and for all cores, the CR <-> GPR moves are expensive). POWER7 test-suite performance results (from 10 runs in each configuration): SingleSource/Benchmarks/Misc/mandel-2: 35% speedup MultiSource/Benchmarks/Prolangs-C++/city/city: 21% speedup MultiSource/Benchmarks/MiBench/automotive-susan: 23% speedup SingleSource/Benchmarks/CoyoteBench/huffbench: 13% speedup SingleSource/Benchmarks/Misc-C++/Large/sphereflake: 13% speedup SingleSource/Benchmarks/Misc-C++/mandel-text: 10% speedup SingleSource/Benchmarks/Misc-C++-EH/spirit: 10% slowdown MultiSource/Applications/lemon/lemon: 8% slowdown llvm-svn: 202451
2014-02-28 08:27:01 +08:00
case PPC::SELECT_VRRC:
[PATCH] Support select-cc for VSFRC when VSX is enabled A previous patch enabled SELECT_VSRC and SELECT_CC_VSRC for VSX to handle <2 x double> cases. This patch adds SELECT_VSFRC and SELECT_CC_VSFRC to allow use of all 64 vector-scalar registers for the f64 type when VSX is enabled. The changes are analogous to those in the previous patch. I've added a new variant to vsx.ll to test the code generation. (I also cleaned up a little formatting in PPCInstrVSX.td from the previous patch.) llvm-svn: 220395
2014-10-23 00:58:20 +08:00
case PPC::SELECT_VSFRC:
Add VSX Scalar loads and stores to the PPC back end This patch corresponds to review: http://reviews.llvm.org/D9440 It adds a new register class to the PPC back end to contain single precision values in VSX registers. Additionally, it adds scalar loads and stores for VSX registers. llvm-svn: 236755
2015-05-08 02:24:05 +08:00
case PPC::SELECT_VSSRC:
[PowerPC] Support select-cc for VSX The tests test/CodeGen/Generic/select-cc.ll and test/CodeGen/PowerPC/select-cc.ll both fail with VSX enabled. The problem is that the lowering logic for the SELECT and SELECT_CC operations doesn't currently support the VSX registers. This patch fixes that. In lib/Target/PowerPC/PPCInstrInfo.td, we have pseudos to handle this for other register classes. Similar pseudos are added in PPCInstrVSX.td (they must be there, because the "vsrc" register class definition appears there) for the VSRC register class. The SELECT_VSRC pseudo is then used in pattern matching for SELECT_CC. The rest of the patch just adds logic for SELECT_VSRC wherever similar logic appears for SELECT_VRRC. There are no new test cases because the existing tests above test this, along with a variant in test/CodeGen/PowerPC/vsx.ll. After discussion with Hal, a future patch will add similar _VSFRC variants to override f64 type handling (currently using F8RC). llvm-svn: 220385
2014-10-22 21:13:40 +08:00
case PPC::SELECT_VSRC:
Add CR-bit tracking to the PowerPC backend for i1 values This change enables tracking i1 values in the PowerPC backend using the condition register bits. These bits can be treated on PowerPC as separate registers; individual bit operations (and, or, xor, etc.) are supported. Tracking booleans in CR bits has several advantages: - Reduction in register pressure (because we no longer need GPRs to store boolean values). - Logical operations on booleans can be handled more efficiently; we used to have to move all results from comparisons into GPRs, perform promoted logical operations in GPRs, and then move the result back into condition register bits to be used by conditional branches. This can be very inefficient, because the throughput of these CR <-> GPR moves have high latency and low throughput (especially when other associated instructions are accounted for). - On the POWER7 and similar cores, we can increase total throughput by using the CR bits. CR bit operations have a dedicated functional unit. Most of this is more-or-less mechanical: Adjustments were needed in the calling-convention code, support was added for spilling/restoring individual condition-register bits, and conditional branch instruction definitions taking specific CR bits were added (plus patterns and code for generating bit-level operations). This is enabled by default when running at -O2 and higher. For -O0 and -O1, where the ability to debug is more important, this feature is disabled by default. Individual CR bits do not have assigned DWARF register numbers, and storing values in CR bits makes them invisible to the debugger. It is critical, however, that we don't move i1 values that have been promoted to larger values (such as those passed as function arguments) into bit registers only to quickly turn around and move the values back into GPRs (such as happens when values are returned by functions). A pair of target-specific DAG combines are added to remove the trunc/extends in: trunc(binary-ops(binary-ops(zext(x), zext(y)), ...) and: zext(binary-ops(binary-ops(trunc(x), trunc(y)), ...) In short, we only want to use CR bits where some of the i1 values come from comparisons or are used by conditional branches or selects. To put it another way, if we can do the entire i1 computation in GPRs, then we probably should (on the POWER7, the GPR-operation throughput is higher, and for all cores, the CR <-> GPR moves are expensive). POWER7 test-suite performance results (from 10 runs in each configuration): SingleSource/Benchmarks/Misc/mandel-2: 35% speedup MultiSource/Benchmarks/Prolangs-C++/city/city: 21% speedup MultiSource/Benchmarks/MiBench/automotive-susan: 23% speedup SingleSource/Benchmarks/CoyoteBench/huffbench: 13% speedup SingleSource/Benchmarks/Misc-C++/Large/sphereflake: 13% speedup SingleSource/Benchmarks/Misc-C++/mandel-text: 10% speedup SingleSource/Benchmarks/Misc-C++-EH/spirit: 10% slowdown MultiSource/Applications/lemon/lemon: 8% slowdown llvm-svn: 202451
2014-02-28 08:27:01 +08:00
if (Op1Set)
ResNode = MachineNode->getOperand(1).getNode();
else if (Op1Unset)
ResNode = MachineNode->getOperand(2).getNode();
else if (Op1Not)
ResNode = CurDAG->getMachineNode(MachineNode->getMachineOpcode(),
SDLoc(MachineNode),
MachineNode->getValueType(0),
MachineNode->getOperand(0).
getOperand(0),
MachineNode->getOperand(2),
MachineNode->getOperand(1));
break;
case PPC::BC:
case PPC::BCn:
if (Op1Not)
ResNode = CurDAG->getMachineNode(Opcode == PPC::BC ? PPC::BCn :
PPC::BC,
SDLoc(MachineNode),
MVT::Other,
MachineNode->getOperand(0).
getOperand(0),
MachineNode->getOperand(1),
MachineNode->getOperand(2));
// FIXME: Handle Op1Set, Op1Unset here too.
break;
}
Swap PPC isel operands to allow for 0-folding The PPC isel instruction can fold 0 into the first operand (thus eliminating the need to materialize a zero-containing register when the 'true' result of the isel is 0). When the isel is fed by a bit register operation that we can invert, do so as part of the bit-register-operation peephole routine. llvm-svn: 202469
2014-02-28 14:11:16 +08:00
// If we're inverting this node because it is used only by selects that
// we'd like to swap, then swap the selects before the node replacement.
if (SelectSwap)
SwapAllSelectUsers(MachineNode);
Add CR-bit tracking to the PowerPC backend for i1 values This change enables tracking i1 values in the PowerPC backend using the condition register bits. These bits can be treated on PowerPC as separate registers; individual bit operations (and, or, xor, etc.) are supported. Tracking booleans in CR bits has several advantages: - Reduction in register pressure (because we no longer need GPRs to store boolean values). - Logical operations on booleans can be handled more efficiently; we used to have to move all results from comparisons into GPRs, perform promoted logical operations in GPRs, and then move the result back into condition register bits to be used by conditional branches. This can be very inefficient, because the throughput of these CR <-> GPR moves have high latency and low throughput (especially when other associated instructions are accounted for). - On the POWER7 and similar cores, we can increase total throughput by using the CR bits. CR bit operations have a dedicated functional unit. Most of this is more-or-less mechanical: Adjustments were needed in the calling-convention code, support was added for spilling/restoring individual condition-register bits, and conditional branch instruction definitions taking specific CR bits were added (plus patterns and code for generating bit-level operations). This is enabled by default when running at -O2 and higher. For -O0 and -O1, where the ability to debug is more important, this feature is disabled by default. Individual CR bits do not have assigned DWARF register numbers, and storing values in CR bits makes them invisible to the debugger. It is critical, however, that we don't move i1 values that have been promoted to larger values (such as those passed as function arguments) into bit registers only to quickly turn around and move the values back into GPRs (such as happens when values are returned by functions). A pair of target-specific DAG combines are added to remove the trunc/extends in: trunc(binary-ops(binary-ops(zext(x), zext(y)), ...) and: zext(binary-ops(binary-ops(trunc(x), trunc(y)), ...) In short, we only want to use CR bits where some of the i1 values come from comparisons or are used by conditional branches or selects. To put it another way, if we can do the entire i1 computation in GPRs, then we probably should (on the POWER7, the GPR-operation throughput is higher, and for all cores, the CR <-> GPR moves are expensive). POWER7 test-suite performance results (from 10 runs in each configuration): SingleSource/Benchmarks/Misc/mandel-2: 35% speedup MultiSource/Benchmarks/Prolangs-C++/city/city: 21% speedup MultiSource/Benchmarks/MiBench/automotive-susan: 23% speedup SingleSource/Benchmarks/CoyoteBench/huffbench: 13% speedup SingleSource/Benchmarks/Misc-C++/Large/sphereflake: 13% speedup SingleSource/Benchmarks/Misc-C++/mandel-text: 10% speedup SingleSource/Benchmarks/Misc-C++-EH/spirit: 10% slowdown MultiSource/Applications/lemon/lemon: 8% slowdown llvm-svn: 202451
2014-02-28 08:27:01 +08:00
if (ResNode != MachineNode) {
DEBUG(dbgs() << "CR Peephole replacing:\nOld: ");
DEBUG(MachineNode->dump(CurDAG));
DEBUG(dbgs() << "\nNew: ");
DEBUG(ResNode->dump(CurDAG));
DEBUG(dbgs() << "\n");
ReplaceUses(MachineNode, ResNode);
IsModified = true;
}
}
if (IsModified)
CurDAG->RemoveDeadNodes();
} while (IsModified);
}
[PowerPC] Add a DAGToDAG peephole to remove unnecessary zero-exts On PPC64, we end up with lots of i32 -> i64 zero extensions, not only from all of the usual places, but also from the ABI, which specifies that values passed are zero extended. Almost all 32-bit PPC instructions in PPC64 mode are defined to do *something* to the higher-order bits, and for some instructions, that action clears those bits (thus providing a zero-extended result). This is especially common after rotate-and-mask instructions. Adding an additional instruction to zero-extend the results of these instructions is unnecessary. This PPCISelDAGToDAG peephole optimization examines these zero-extensions, and looks back through their operands to see if all instructions will implicitly zero extend their results. If so, we convert these instructions to their 64-bit variants (which is an internal change only, the actual encoding of these instructions is the same as the original 32-bit ones) and remove the unnecessary zero-extension (changing where the INSERT_SUBREG instructions are to make everything internally consistent). llvm-svn: 224169
2014-12-13 07:59:36 +08:00
// Gather the set of 32-bit operations that are known to have their
// higher-order 32 bits zero, where ToPromote contains all such operations.
static bool PeepholePPC64ZExtGather(SDValue Op32,
SmallPtrSetImpl<SDNode *> &ToPromote) {
if (!Op32.isMachineOpcode())
return false;
// First, check for the "frontier" instructions (those that will clear the
// higher-order 32 bits.
// For RLWINM and RLWNM, we need to make sure that the mask does not wrap
// around. If it does not, then these instructions will clear the
// higher-order bits.
if ((Op32.getMachineOpcode() == PPC::RLWINM ||
Op32.getMachineOpcode() == PPC::RLWNM) &&
Op32.getConstantOperandVal(2) <= Op32.getConstantOperandVal(3)) {
ToPromote.insert(Op32.getNode());
return true;
}
// SLW and SRW always clear the higher-order bits.
if (Op32.getMachineOpcode() == PPC::SLW ||
Op32.getMachineOpcode() == PPC::SRW) {
ToPromote.insert(Op32.getNode());
return true;
}
// For LI and LIS, we need the immediate to be positive (so that it is not
// sign extended).
if (Op32.getMachineOpcode() == PPC::LI ||
Op32.getMachineOpcode() == PPC::LIS) {
if (!isUInt<15>(Op32.getConstantOperandVal(0)))
return false;
ToPromote.insert(Op32.getNode());
return true;
}
[PowerPC] Remove zexts after byte-swapping loads lhbrx and lwbrx not only load their data with byte swapping, but also clear the upper 32 bits (at least). As a result, they can be added to the PPCISelDAGToDAG peephole optimization as frontier instructions for the removal of unnecessary zero extensions. llvm-svn: 225189
2015-01-06 02:09:06 +08:00
// LHBRX and LWBRX always clear the higher-order bits.
if (Op32.getMachineOpcode() == PPC::LHBRX ||
Op32.getMachineOpcode() == PPC::LWBRX) {
ToPromote.insert(Op32.getNode());
return true;
}
[PowerPC] Remove zexts after i32 ctlz The 64-bit semantics of cntlzw are not special, the 32-bit population count is stored as a 64-bit value in the range [0,32]. As a result, it is always zero extended, and it can be added to the PPCISelDAGToDAG peephole optimization as a frontier instruction for the removal of unnecessary zero extensions. llvm-svn: 225192
2015-01-06 02:52:29 +08:00
// CNTLZW always produces a 64-bit value in [0,32], and so is zero extended.
if (Op32.getMachineOpcode() == PPC::CNTLZW) {
ToPromote.insert(Op32.getNode());
return true;
}
[PowerPC] Add a DAGToDAG peephole to remove unnecessary zero-exts On PPC64, we end up with lots of i32 -> i64 zero extensions, not only from all of the usual places, but also from the ABI, which specifies that values passed are zero extended. Almost all 32-bit PPC instructions in PPC64 mode are defined to do *something* to the higher-order bits, and for some instructions, that action clears those bits (thus providing a zero-extended result). This is especially common after rotate-and-mask instructions. Adding an additional instruction to zero-extend the results of these instructions is unnecessary. This PPCISelDAGToDAG peephole optimization examines these zero-extensions, and looks back through their operands to see if all instructions will implicitly zero extend their results. If so, we convert these instructions to their 64-bit variants (which is an internal change only, the actual encoding of these instructions is the same as the original 32-bit ones) and remove the unnecessary zero-extension (changing where the INSERT_SUBREG instructions are to make everything internally consistent). llvm-svn: 224169
2014-12-13 07:59:36 +08:00
// Next, check for those instructions we can look through.
// Assuming the mask does not wrap around, then the higher-order bits are
// taken directly from the first operand.
if (Op32.getMachineOpcode() == PPC::RLWIMI &&
Op32.getConstantOperandVal(3) <= Op32.getConstantOperandVal(4)) {
SmallPtrSet<SDNode *, 16> ToPromote1;
if (!PeepholePPC64ZExtGather(Op32.getOperand(0), ToPromote1))
return false;
ToPromote.insert(Op32.getNode());
ToPromote.insert(ToPromote1.begin(), ToPromote1.end());
return true;
}
// For OR, the higher-order bits are zero if that is true for both operands.
// For SELECT_I4, the same is true (but the relevant operand numbers are
// shifted by 1).
if (Op32.getMachineOpcode() == PPC::OR ||
Op32.getMachineOpcode() == PPC::SELECT_I4) {
unsigned B = Op32.getMachineOpcode() == PPC::SELECT_I4 ? 1 : 0;
SmallPtrSet<SDNode *, 16> ToPromote1;
if (!PeepholePPC64ZExtGather(Op32.getOperand(B+0), ToPromote1))
return false;
if (!PeepholePPC64ZExtGather(Op32.getOperand(B+1), ToPromote1))
return false;
ToPromote.insert(Op32.getNode());
ToPromote.insert(ToPromote1.begin(), ToPromote1.end());
return true;
}
// For ORI and ORIS, we need the higher-order bits of the first operand to be
// zero, and also for the constant to be positive (so that it is not sign
// extended).
if (Op32.getMachineOpcode() == PPC::ORI ||
Op32.getMachineOpcode() == PPC::ORIS) {
SmallPtrSet<SDNode *, 16> ToPromote1;
if (!PeepholePPC64ZExtGather(Op32.getOperand(0), ToPromote1))
return false;
if (!isUInt<15>(Op32.getConstantOperandVal(1)))
return false;
ToPromote.insert(Op32.getNode());
ToPromote.insert(ToPromote1.begin(), ToPromote1.end());
return true;
}
// The higher-order bits of AND are zero if that is true for at least one of
// the operands.
if (Op32.getMachineOpcode() == PPC::AND) {
SmallPtrSet<SDNode *, 16> ToPromote1, ToPromote2;
bool Op0OK =
PeepholePPC64ZExtGather(Op32.getOperand(0), ToPromote1);
bool Op1OK =
PeepholePPC64ZExtGather(Op32.getOperand(1), ToPromote2);
if (!Op0OK && !Op1OK)
return false;
ToPromote.insert(Op32.getNode());
if (Op0OK)
ToPromote.insert(ToPromote1.begin(), ToPromote1.end());
if (Op1OK)
ToPromote.insert(ToPromote2.begin(), ToPromote2.end());
return true;
}
// For ANDI and ANDIS, the higher-order bits are zero if either that is true
// of the first operand, or if the second operand is positive (so that it is
// not sign extended).
if (Op32.getMachineOpcode() == PPC::ANDIo ||
Op32.getMachineOpcode() == PPC::ANDISo) {
SmallPtrSet<SDNode *, 16> ToPromote1;
bool Op0OK =
PeepholePPC64ZExtGather(Op32.getOperand(0), ToPromote1);
bool Op1OK = isUInt<15>(Op32.getConstantOperandVal(1));
if (!Op0OK && !Op1OK)
return false;
ToPromote.insert(Op32.getNode());
if (Op0OK)
ToPromote.insert(ToPromote1.begin(), ToPromote1.end());
return true;
}
return false;
}
void PPCDAGToDAGISel::PeepholePPC64ZExt() {
if (!PPCSubTarget->isPPC64())
return;
// When we zero-extend from i32 to i64, we use a pattern like this:
// def : Pat<(i64 (zext i32:$in)),
// (RLDICL (INSERT_SUBREG (i64 (IMPLICIT_DEF)), $in, sub_32),
// 0, 32)>;
// There are several 32-bit shift/rotate instructions, however, that will
// clear the higher-order bits of their output, rendering the RLDICL
// unnecessary. When that happens, we remove it here, and redefine the
// relevant 32-bit operation to be a 64-bit operation.
SelectionDAG::allnodes_iterator Position(CurDAG->getRoot().getNode());
++Position;
bool MadeChange = false;
while (Position != CurDAG->allnodes_begin()) {
PowerPC: Remove implicit ilist iterator conversions, NFC llvm-svn: 250787
2015-10-20 09:07:37 +08:00
SDNode *N = &*--Position;
[PowerPC] Add a DAGToDAG peephole to remove unnecessary zero-exts On PPC64, we end up with lots of i32 -> i64 zero extensions, not only from all of the usual places, but also from the ABI, which specifies that values passed are zero extended. Almost all 32-bit PPC instructions in PPC64 mode are defined to do *something* to the higher-order bits, and for some instructions, that action clears those bits (thus providing a zero-extended result). This is especially common after rotate-and-mask instructions. Adding an additional instruction to zero-extend the results of these instructions is unnecessary. This PPCISelDAGToDAG peephole optimization examines these zero-extensions, and looks back through their operands to see if all instructions will implicitly zero extend their results. If so, we convert these instructions to their 64-bit variants (which is an internal change only, the actual encoding of these instructions is the same as the original 32-bit ones) and remove the unnecessary zero-extension (changing where the INSERT_SUBREG instructions are to make everything internally consistent). llvm-svn: 224169
2014-12-13 07:59:36 +08:00
// Skip dead nodes and any non-machine opcodes.
if (N->use_empty() || !N->isMachineOpcode())
continue;
if (N->getMachineOpcode() != PPC::RLDICL)
continue;
if (N->getConstantOperandVal(1) != 0 ||
N->getConstantOperandVal(2) != 32)
continue;
SDValue ISR = N->getOperand(0);
if (!ISR.isMachineOpcode() ||
ISR.getMachineOpcode() != TargetOpcode::INSERT_SUBREG)
continue;
if (!ISR.hasOneUse())
continue;
if (ISR.getConstantOperandVal(2) != PPC::sub_32)
continue;
SDValue IDef = ISR.getOperand(0);
if (!IDef.isMachineOpcode() ||
IDef.getMachineOpcode() != TargetOpcode::IMPLICIT_DEF)
continue;
// We now know that we're looking at a canonical i32 -> i64 zext. See if we
// can get rid of it.
SDValue Op32 = ISR->getOperand(1);
if (!Op32.isMachineOpcode())
continue;
// There are some 32-bit instructions that always clear the high-order 32
// bits, there are also some instructions (like AND) that we can look
// through.
SmallPtrSet<SDNode *, 16> ToPromote;
if (!PeepholePPC64ZExtGather(Op32, ToPromote))
continue;
// If the ToPromote set contains nodes that have uses outside of the set
// (except for the original INSERT_SUBREG), then abort the transformation.
bool OutsideUse = false;
for (SDNode *PN : ToPromote) {
for (SDNode *UN : PN->uses()) {
if (!ToPromote.count(UN) && UN != ISR.getNode()) {
OutsideUse = true;
break;
}
}
if (OutsideUse)
break;
}
if (OutsideUse)
continue;
MadeChange = true;
// We now know that this zero extension can be removed by promoting to
// nodes in ToPromote to 64-bit operations, where for operations in the
// frontier of the set, we need to insert INSERT_SUBREGs for their
// operands.
for (SDNode *PN : ToPromote) {
unsigned NewOpcode;
switch (PN->getMachineOpcode()) {
default:
llvm_unreachable("Don't know the 64-bit variant of this instruction");
case PPC::RLWINM: NewOpcode = PPC::RLWINM8; break;
case PPC::RLWNM: NewOpcode = PPC::RLWNM8; break;
case PPC::SLW: NewOpcode = PPC::SLW8; break;
case PPC::SRW: NewOpcode = PPC::SRW8; break;
case PPC::LI: NewOpcode = PPC::LI8; break;
case PPC::LIS: NewOpcode = PPC::LIS8; break;
[PowerPC] Remove zexts after byte-swapping loads lhbrx and lwbrx not only load their data with byte swapping, but also clear the upper 32 bits (at least). As a result, they can be added to the PPCISelDAGToDAG peephole optimization as frontier instructions for the removal of unnecessary zero extensions. llvm-svn: 225189
2015-01-06 02:09:06 +08:00
case PPC::LHBRX: NewOpcode = PPC::LHBRX8; break;
case PPC::LWBRX: NewOpcode = PPC::LWBRX8; break;
[PowerPC] Remove zexts after i32 ctlz The 64-bit semantics of cntlzw are not special, the 32-bit population count is stored as a 64-bit value in the range [0,32]. As a result, it is always zero extended, and it can be added to the PPCISelDAGToDAG peephole optimization as a frontier instruction for the removal of unnecessary zero extensions. llvm-svn: 225192
2015-01-06 02:52:29 +08:00
case PPC::CNTLZW: NewOpcode = PPC::CNTLZW8; break;
[PowerPC] Add a DAGToDAG peephole to remove unnecessary zero-exts On PPC64, we end up with lots of i32 -> i64 zero extensions, not only from all of the usual places, but also from the ABI, which specifies that values passed are zero extended. Almost all 32-bit PPC instructions in PPC64 mode are defined to do *something* to the higher-order bits, and for some instructions, that action clears those bits (thus providing a zero-extended result). This is especially common after rotate-and-mask instructions. Adding an additional instruction to zero-extend the results of these instructions is unnecessary. This PPCISelDAGToDAG peephole optimization examines these zero-extensions, and looks back through their operands to see if all instructions will implicitly zero extend their results. If so, we convert these instructions to their 64-bit variants (which is an internal change only, the actual encoding of these instructions is the same as the original 32-bit ones) and remove the unnecessary zero-extension (changing where the INSERT_SUBREG instructions are to make everything internally consistent). llvm-svn: 224169
2014-12-13 07:59:36 +08:00
case PPC::RLWIMI: NewOpcode = PPC::RLWIMI8; break;
case PPC::OR: NewOpcode = PPC::OR8; break;
case PPC::SELECT_I4: NewOpcode = PPC::SELECT_I8; break;
case PPC::ORI: NewOpcode = PPC::ORI8; break;
case PPC::ORIS: NewOpcode = PPC::ORIS8; break;
case PPC::AND: NewOpcode = PPC::AND8; break;
case PPC::ANDIo: NewOpcode = PPC::ANDIo8; break;
case PPC::ANDISo: NewOpcode = PPC::ANDISo8; break;
}
// Note: During the replacement process, the nodes will be in an
// inconsistent state (some instructions will have operands with values
// of the wrong type). Once done, however, everything should be right
// again.
SmallVector<SDValue, 4> Ops;
for (const SDValue &V : PN->ops()) {
if (!ToPromote.count(V.getNode()) && V.getValueType() == MVT::i32 &&
!isa<ConstantSDNode>(V)) {
SDValue ReplOpOps[] = { ISR.getOperand(0), V, ISR.getOperand(2) };
SDNode *ReplOp =
CurDAG->getMachineNode(TargetOpcode::INSERT_SUBREG, SDLoc(V),
ISR.getNode()->getVTList(), ReplOpOps);
Ops.push_back(SDValue(ReplOp, 0));
} else {
Ops.push_back(V);
}
}
// Because all to-be-promoted nodes only have users that are other
// promoted nodes (or the original INSERT_SUBREG), we can safely replace
// the i32 result value type with i64.
SmallVector<EVT, 2> NewVTs;
SDVTList VTs = PN->getVTList();
for (unsigned i = 0, ie = VTs.NumVTs; i != ie; ++i)
if (VTs.VTs[i] == MVT::i32)
NewVTs.push_back(MVT::i64);
else
NewVTs.push_back(VTs.VTs[i]);
DEBUG(dbgs() << "PPC64 ZExt Peephole morphing:\nOld: ");
DEBUG(PN->dump(CurDAG));
CurDAG->SelectNodeTo(PN, NewOpcode, CurDAG->getVTList(NewVTs), Ops);
DEBUG(dbgs() << "\nNew: ");
DEBUG(PN->dump(CurDAG));
DEBUG(dbgs() << "\n");
}
// Now we replace the original zero extend and its associated INSERT_SUBREG
// with the value feeding the INSERT_SUBREG (which has now been promoted to
// return an i64).
DEBUG(dbgs() << "PPC64 ZExt Peephole replacing:\nOld: ");
DEBUG(N->dump(CurDAG));
DEBUG(dbgs() << "\nNew: ");
DEBUG(Op32.getNode()->dump(CurDAG));
DEBUG(dbgs() << "\n");
ReplaceUses(N, Op32.getNode());
}
if (MadeChange)
CurDAG->RemoveDeadNodes();
}
Add CR-bit tracking to the PowerPC backend for i1 values This change enables tracking i1 values in the PowerPC backend using the condition register bits. These bits can be treated on PowerPC as separate registers; individual bit operations (and, or, xor, etc.) are supported. Tracking booleans in CR bits has several advantages: - Reduction in register pressure (because we no longer need GPRs to store boolean values). - Logical operations on booleans can be handled more efficiently; we used to have to move all results from comparisons into GPRs, perform promoted logical operations in GPRs, and then move the result back into condition register bits to be used by conditional branches. This can be very inefficient, because the throughput of these CR <-> GPR moves have high latency and low throughput (especially when other associated instructions are accounted for). - On the POWER7 and similar cores, we can increase total throughput by using the CR bits. CR bit operations have a dedicated functional unit. Most of this is more-or-less mechanical: Adjustments were needed in the calling-convention code, support was added for spilling/restoring individual condition-register bits, and conditional branch instruction definitions taking specific CR bits were added (plus patterns and code for generating bit-level operations). This is enabled by default when running at -O2 and higher. For -O0 and -O1, where the ability to debug is more important, this feature is disabled by default. Individual CR bits do not have assigned DWARF register numbers, and storing values in CR bits makes them invisible to the debugger. It is critical, however, that we don't move i1 values that have been promoted to larger values (such as those passed as function arguments) into bit registers only to quickly turn around and move the values back into GPRs (such as happens when values are returned by functions). A pair of target-specific DAG combines are added to remove the trunc/extends in: trunc(binary-ops(binary-ops(zext(x), zext(y)), ...) and: zext(binary-ops(binary-ops(trunc(x), trunc(y)), ...) In short, we only want to use CR bits where some of the i1 values come from comparisons or are used by conditional branches or selects. To put it another way, if we can do the entire i1 computation in GPRs, then we probably should (on the POWER7, the GPR-operation throughput is higher, and for all cores, the CR <-> GPR moves are expensive). POWER7 test-suite performance results (from 10 runs in each configuration): SingleSource/Benchmarks/Misc/mandel-2: 35% speedup MultiSource/Benchmarks/Prolangs-C++/city/city: 21% speedup MultiSource/Benchmarks/MiBench/automotive-susan: 23% speedup SingleSource/Benchmarks/CoyoteBench/huffbench: 13% speedup SingleSource/Benchmarks/Misc-C++/Large/sphereflake: 13% speedup SingleSource/Benchmarks/Misc-C++/mandel-text: 10% speedup SingleSource/Benchmarks/Misc-C++-EH/spirit: 10% slowdown MultiSource/Applications/lemon/lemon: 8% slowdown llvm-svn: 202451
2014-02-28 08:27:01 +08:00
void PPCDAGToDAGISel::PeepholePPC64() {
PPCDAGToDAGISel::PostprocessISelDAG() This patch implements the PPCDAGToDAGISel::PostprocessISelDAG virtual method to perform post-selection peephole optimizations on the DAG representation. One optimization is implemented here: folds to clean up complex addressing expressions for thread-local storage and medium code model. It will also be useful for large code model sequences when those are added later. I originally thought about doing this on the MI representation prior to register assignment, but it's difficult to do effective global dead code elimination at that point. DCE is trivial on the DAG representation. A typical example of a candidate code sequence in assembly: addis 3, 2, globalvar@toc@ha addi 3, 3, globalvar@toc@l lwz 5, 0(3) When the final instruction is a load or store with an immediate offset of zero, the offset from the add-immediate can replace the zero, provided the relocation information is carried along: addis 3, 2, globalvar@toc@ha lwz 5, globalvar@toc@l(3) Since the addi can in general have multiple uses, we need to only delete the instruction when the last use is removed. llvm-svn: 175697
2013-02-21 08:38:25 +08:00
// These optimizations are currently supported only for 64-bit SVR4.
Reset the subtarget for DAGToDAG on every iteration of runOnMachineFunction. This required updating the generated functions and TD file accordingly to be pointers rather than const references. llvm-svn: 209375
2014-05-22 09:07:24 +08:00
if (PPCSubTarget->isDarwin() || !PPCSubTarget->isPPC64())
PPCDAGToDAGISel::PostprocessISelDAG() This patch implements the PPCDAGToDAGISel::PostprocessISelDAG virtual method to perform post-selection peephole optimizations on the DAG representation. One optimization is implemented here: folds to clean up complex addressing expressions for thread-local storage and medium code model. It will also be useful for large code model sequences when those are added later. I originally thought about doing this on the MI representation prior to register assignment, but it's difficult to do effective global dead code elimination at that point. DCE is trivial on the DAG representation. A typical example of a candidate code sequence in assembly: addis 3, 2, globalvar@toc@ha addi 3, 3, globalvar@toc@l lwz 5, 0(3) When the final instruction is a load or store with an immediate offset of zero, the offset from the add-immediate can replace the zero, provided the relocation information is carried along: addis 3, 2, globalvar@toc@ha lwz 5, globalvar@toc@l(3) Since the addi can in general have multiple uses, we need to only delete the instruction when the last use is removed. llvm-svn: 175697
2013-02-21 08:38:25 +08:00
return;
SelectionDAG::allnodes_iterator Position(CurDAG->getRoot().getNode());
++Position;
while (Position != CurDAG->allnodes_begin()) {
PowerPC: Remove implicit ilist iterator conversions, NFC llvm-svn: 250787
2015-10-20 09:07:37 +08:00
SDNode *N = &*--Position;
PPCDAGToDAGISel::PostprocessISelDAG() This patch implements the PPCDAGToDAGISel::PostprocessISelDAG virtual method to perform post-selection peephole optimizations on the DAG representation. One optimization is implemented here: folds to clean up complex addressing expressions for thread-local storage and medium code model. It will also be useful for large code model sequences when those are added later. I originally thought about doing this on the MI representation prior to register assignment, but it's difficult to do effective global dead code elimination at that point. DCE is trivial on the DAG representation. A typical example of a candidate code sequence in assembly: addis 3, 2, globalvar@toc@ha addi 3, 3, globalvar@toc@l lwz 5, 0(3) When the final instruction is a load or store with an immediate offset of zero, the offset from the add-immediate can replace the zero, provided the relocation information is carried along: addis 3, 2, globalvar@toc@ha lwz 5, globalvar@toc@l(3) Since the addi can in general have multiple uses, we need to only delete the instruction when the last use is removed. llvm-svn: 175697
2013-02-21 08:38:25 +08:00
// Skip dead nodes and any non-machine opcodes.
if (N->use_empty() || !N->isMachineOpcode())
continue;
unsigned FirstOp;
unsigned StorageOpcode = N->getMachineOpcode();
switch (StorageOpcode) {
default: continue;
case PPC::LBZ:
case PPC::LBZ8:
case PPC::LD:
case PPC::LFD:
case PPC::LFS:
case PPC::LHA:
case PPC::LHA8:
case PPC::LHZ:
case PPC::LHZ8:
case PPC::LWA:
case PPC::LWZ:
case PPC::LWZ8:
FirstOp = 0;
break;
case PPC::STB:
case PPC::STB8:
case PPC::STD:
case PPC::STFD:
case PPC::STFS:
case PPC::STH:
case PPC::STH8:
case PPC::STW:
case PPC::STW8:
FirstOp = 1;
break;
}
[PPC]: Peephole optimize small accesss to aligned globals. Access to aligned globals gives us a chance to peephole optimize nonzero offsets. If a struct is 4 byte aligned, then accesses to bytes 0-3 won't overflow the available displacement. For example: addis 3, 2, b4v@toc@ha addi 4, 3, b4v@toc@l lbz 5, b4v@toc@l(3) ; This is the result of the current peephole lbz 6, 1(4) ; optimizer lbz 7, 2(4) lbz 8, 3(4) If b4v is 4-byte aligned, we can skip using register 4 because we know that b4v@toc@l+{1,2,3} won't overflow 32K, and instead generate: addis 3, 2, b4v@toc@ha lbz 4, b4v@toc@l(3) lbz 5, b4v@toc@l+1(3) lbz 6, b4v@toc@l+2(3) lbz 7, b4v@toc@l+3(3) Saving a register and an addition. Larger alignments allow larger structures/arrays to be optimized. llvm-svn: 255319
2015-12-11 08:47:36 +08:00
// If this is a load or store with a zero offset, or within the alignment,
// we may be able to fold an add-immediate into the memory operation.
// The check against alignment is below, as it can't occur until we check
// the arguments to N
if (!isa<ConstantSDNode>(N->getOperand(FirstOp)))
PPCDAGToDAGISel::PostprocessISelDAG() This patch implements the PPCDAGToDAGISel::PostprocessISelDAG virtual method to perform post-selection peephole optimizations on the DAG representation. One optimization is implemented here: folds to clean up complex addressing expressions for thread-local storage and medium code model. It will also be useful for large code model sequences when those are added later. I originally thought about doing this on the MI representation prior to register assignment, but it's difficult to do effective global dead code elimination at that point. DCE is trivial on the DAG representation. A typical example of a candidate code sequence in assembly: addis 3, 2, globalvar@toc@ha addi 3, 3, globalvar@toc@l lwz 5, 0(3) When the final instruction is a load or store with an immediate offset of zero, the offset from the add-immediate can replace the zero, provided the relocation information is carried along: addis 3, 2, globalvar@toc@ha lwz 5, globalvar@toc@l(3) Since the addi can in general have multiple uses, we need to only delete the instruction when the last use is removed. llvm-svn: 175697
2013-02-21 08:38:25 +08:00
continue;
SDValue Base = N->getOperand(FirstOp + 1);
if (!Base.isMachineOpcode())
continue;
[PPC]: Peephole optimize small accesss to aligned globals. Access to aligned globals gives us a chance to peephole optimize nonzero offsets. If a struct is 4 byte aligned, then accesses to bytes 0-3 won't overflow the available displacement. For example: addis 3, 2, b4v@toc@ha addi 4, 3, b4v@toc@l lbz 5, b4v@toc@l(3) ; This is the result of the current peephole lbz 6, 1(4) ; optimizer lbz 7, 2(4) lbz 8, 3(4) If b4v is 4-byte aligned, we can skip using register 4 because we know that b4v@toc@l+{1,2,3} won't overflow 32K, and instead generate: addis 3, 2, b4v@toc@ha lbz 4, b4v@toc@l(3) lbz 5, b4v@toc@l+1(3) lbz 6, b4v@toc@l+2(3) lbz 7, b4v@toc@l+3(3) Saving a register and an addition. Larger alignments allow larger structures/arrays to be optimized. llvm-svn: 255319
2015-12-11 08:47:36 +08:00
// On targets with fusion, we don't want this to fire and remove a fusion
// opportunity, unless a) it results in another fusion opportunity or
// b) optimizing for size.
if (PPCSubTarget->hasFusion() &&
Fix build after r255319. llvm-svn: 255322
2015-12-11 08:58:32 +08:00
(!MF->getFunction()->optForSize() && !Base.hasOneUse()))
[PPC]: Peephole optimize small accesss to aligned globals. Access to aligned globals gives us a chance to peephole optimize nonzero offsets. If a struct is 4 byte aligned, then accesses to bytes 0-3 won't overflow the available displacement. For example: addis 3, 2, b4v@toc@ha addi 4, 3, b4v@toc@l lbz 5, b4v@toc@l(3) ; This is the result of the current peephole lbz 6, 1(4) ; optimizer lbz 7, 2(4) lbz 8, 3(4) If b4v is 4-byte aligned, we can skip using register 4 because we know that b4v@toc@l+{1,2,3} won't overflow 32K, and instead generate: addis 3, 2, b4v@toc@ha lbz 4, b4v@toc@l(3) lbz 5, b4v@toc@l+1(3) lbz 6, b4v@toc@l+2(3) lbz 7, b4v@toc@l+3(3) Saving a register and an addition. Larger alignments allow larger structures/arrays to be optimized. llvm-svn: 255319
2015-12-11 08:47:36 +08:00
continue;
PPCDAGToDAGISel::PostprocessISelDAG() This patch implements the PPCDAGToDAGISel::PostprocessISelDAG virtual method to perform post-selection peephole optimizations on the DAG representation. One optimization is implemented here: folds to clean up complex addressing expressions for thread-local storage and medium code model. It will also be useful for large code model sequences when those are added later. I originally thought about doing this on the MI representation prior to register assignment, but it's difficult to do effective global dead code elimination at that point. DCE is trivial on the DAG representation. A typical example of a candidate code sequence in assembly: addis 3, 2, globalvar@toc@ha addi 3, 3, globalvar@toc@l lwz 5, 0(3) When the final instruction is a load or store with an immediate offset of zero, the offset from the add-immediate can replace the zero, provided the relocation information is carried along: addis 3, 2, globalvar@toc@ha lwz 5, globalvar@toc@l(3) Since the addi can in general have multiple uses, we need to only delete the instruction when the last use is removed. llvm-svn: 175697
2013-02-21 08:38:25 +08:00
unsigned Flags = 0;
bool ReplaceFlags = true;
// When the feeding operation is an add-immediate of some sort,
// determine whether we need to add relocation information to the
// target flags on the immediate operand when we fold it into the
// load instruction.
//
// For something like ADDItocL, the relocation information is
// inferred from the opcode; when we process it in the AsmPrinter,
// we add the necessary relocation there. A load, though, can receive
// relocation from various flavors of ADDIxxx, so we need to carry
// the relocation information in the target flags.
switch (Base.getMachineOpcode()) {
default: continue;
case PPC::ADDI8:
PowerPC: Remove ADDIL patterns. The ADDI/ADDI8 patterns are currently duplicated into ADDIL/ADDI8L, which describe the same instruction, except that they accept a symbolLo[64] operand instead of a s16imm[64] operand. This duplication confuses the asm parser, and it actually not really needed, since symbolLo[64] already accepts immediate operands anyway. So this commit removes the duplicate patterns. No change in generated code. llvm-svn: 178004
2013-03-26 18:55:20 +08:00
case PPC::ADDI:
PPCDAGToDAGISel::PostprocessISelDAG() This patch implements the PPCDAGToDAGISel::PostprocessISelDAG virtual method to perform post-selection peephole optimizations on the DAG representation. One optimization is implemented here: folds to clean up complex addressing expressions for thread-local storage and medium code model. It will also be useful for large code model sequences when those are added later. I originally thought about doing this on the MI representation prior to register assignment, but it's difficult to do effective global dead code elimination at that point. DCE is trivial on the DAG representation. A typical example of a candidate code sequence in assembly: addis 3, 2, globalvar@toc@ha addi 3, 3, globalvar@toc@l lwz 5, 0(3) When the final instruction is a load or store with an immediate offset of zero, the offset from the add-immediate can replace the zero, provided the relocation information is carried along: addis 3, 2, globalvar@toc@ha lwz 5, globalvar@toc@l(3) Since the addi can in general have multiple uses, we need to only delete the instruction when the last use is removed. llvm-svn: 175697
2013-02-21 08:38:25 +08:00
// In some cases (such as TLS) the relocation information
// is already in place on the operand, so copying the operand
// is sufficient.
ReplaceFlags = false;
// For these cases, the immediate may not be divisible by 4, in
// which case the fold is illegal for DS-form instructions. (The
// other cases provide aligned addresses and are always safe.)
if ((StorageOpcode == PPC::LWA ||
StorageOpcode == PPC::LD ||
StorageOpcode == PPC::STD) &&
(!isa<ConstantSDNode>(Base.getOperand(1)) ||
Base.getConstantOperandVal(1) % 4 != 0))
continue;
break;
case PPC::ADDIdtprelL:
[PowerPC] Rename some more VK_PPC_ enums This renames more VK_PPC_ enums, to make them more closely reflect the @modifier string they represent. This also prepares for adding a bunch of new VK_PPC_ enums in upcoming patches. For consistency, some MO_ flags related to VK_PPC_ enums are likewise renamed. No change in behaviour. llvm-svn: 184547
2013-06-21 22:42:20 +08:00
Flags = PPCII::MO_DTPREL_LO;
PPCDAGToDAGISel::PostprocessISelDAG() This patch implements the PPCDAGToDAGISel::PostprocessISelDAG virtual method to perform post-selection peephole optimizations on the DAG representation. One optimization is implemented here: folds to clean up complex addressing expressions for thread-local storage and medium code model. It will also be useful for large code model sequences when those are added later. I originally thought about doing this on the MI representation prior to register assignment, but it's difficult to do effective global dead code elimination at that point. DCE is trivial on the DAG representation. A typical example of a candidate code sequence in assembly: addis 3, 2, globalvar@toc@ha addi 3, 3, globalvar@toc@l lwz 5, 0(3) When the final instruction is a load or store with an immediate offset of zero, the offset from the add-immediate can replace the zero, provided the relocation information is carried along: addis 3, 2, globalvar@toc@ha lwz 5, globalvar@toc@l(3) Since the addi can in general have multiple uses, we need to only delete the instruction when the last use is removed. llvm-svn: 175697
2013-02-21 08:38:25 +08:00
break;
case PPC::ADDItlsldL:
[PowerPC] Rename some more VK_PPC_ enums This renames more VK_PPC_ enums, to make them more closely reflect the @modifier string they represent. This also prepares for adding a bunch of new VK_PPC_ enums in upcoming patches. For consistency, some MO_ flags related to VK_PPC_ enums are likewise renamed. No change in behaviour. llvm-svn: 184547
2013-06-21 22:42:20 +08:00
Flags = PPCII::MO_TLSLD_LO;
PPCDAGToDAGISel::PostprocessISelDAG() This patch implements the PPCDAGToDAGISel::PostprocessISelDAG virtual method to perform post-selection peephole optimizations on the DAG representation. One optimization is implemented here: folds to clean up complex addressing expressions for thread-local storage and medium code model. It will also be useful for large code model sequences when those are added later. I originally thought about doing this on the MI representation prior to register assignment, but it's difficult to do effective global dead code elimination at that point. DCE is trivial on the DAG representation. A typical example of a candidate code sequence in assembly: addis 3, 2, globalvar@toc@ha addi 3, 3, globalvar@toc@l lwz 5, 0(3) When the final instruction is a load or store with an immediate offset of zero, the offset from the add-immediate can replace the zero, provided the relocation information is carried along: addis 3, 2, globalvar@toc@ha lwz 5, globalvar@toc@l(3) Since the addi can in general have multiple uses, we need to only delete the instruction when the last use is removed. llvm-svn: 175697
2013-02-21 08:38:25 +08:00
break;
case PPC::ADDItocL:
[PowerPC] Rename some more VK_PPC_ enums This renames more VK_PPC_ enums, to make them more closely reflect the @modifier string they represent. This also prepares for adding a bunch of new VK_PPC_ enums in upcoming patches. For consistency, some MO_ flags related to VK_PPC_ enums are likewise renamed. No change in behaviour. llvm-svn: 184547
2013-06-21 22:42:20 +08:00
Flags = PPCII::MO_TOC_LO;
PPCDAGToDAGISel::PostprocessISelDAG() This patch implements the PPCDAGToDAGISel::PostprocessISelDAG virtual method to perform post-selection peephole optimizations on the DAG representation. One optimization is implemented here: folds to clean up complex addressing expressions for thread-local storage and medium code model. It will also be useful for large code model sequences when those are added later. I originally thought about doing this on the MI representation prior to register assignment, but it's difficult to do effective global dead code elimination at that point. DCE is trivial on the DAG representation. A typical example of a candidate code sequence in assembly: addis 3, 2, globalvar@toc@ha addi 3, 3, globalvar@toc@l lwz 5, 0(3) When the final instruction is a load or store with an immediate offset of zero, the offset from the add-immediate can replace the zero, provided the relocation information is carried along: addis 3, 2, globalvar@toc@ha lwz 5, globalvar@toc@l(3) Since the addi can in general have multiple uses, we need to only delete the instruction when the last use is removed. llvm-svn: 175697
2013-02-21 08:38:25 +08:00
break;
}
[PPC]: Peephole optimize small accesss to aligned globals. Access to aligned globals gives us a chance to peephole optimize nonzero offsets. If a struct is 4 byte aligned, then accesses to bytes 0-3 won't overflow the available displacement. For example: addis 3, 2, b4v@toc@ha addi 4, 3, b4v@toc@l lbz 5, b4v@toc@l(3) ; This is the result of the current peephole lbz 6, 1(4) ; optimizer lbz 7, 2(4) lbz 8, 3(4) If b4v is 4-byte aligned, we can skip using register 4 because we know that b4v@toc@l+{1,2,3} won't overflow 32K, and instead generate: addis 3, 2, b4v@toc@ha lbz 4, b4v@toc@l(3) lbz 5, b4v@toc@l+1(3) lbz 6, b4v@toc@l+2(3) lbz 7, b4v@toc@l+3(3) Saving a register and an addition. Larger alignments allow larger structures/arrays to be optimized. llvm-svn: 255319
2015-12-11 08:47:36 +08:00
SDValue ImmOpnd = Base.getOperand(1);
int MaxDisplacement = 0;
if (GlobalAddressSDNode *GA = dyn_cast<GlobalAddressSDNode>(ImmOpnd)) {
const GlobalValue *GV = GA->getGlobal();
MaxDisplacement = GV->getAlignment() - 1;
}
int Offset = N->getConstantOperandVal(FirstOp);
if (Offset < 0 || Offset > MaxDisplacement)
continue;
PPCDAGToDAGISel::PostprocessISelDAG() This patch implements the PPCDAGToDAGISel::PostprocessISelDAG virtual method to perform post-selection peephole optimizations on the DAG representation. One optimization is implemented here: folds to clean up complex addressing expressions for thread-local storage and medium code model. It will also be useful for large code model sequences when those are added later. I originally thought about doing this on the MI representation prior to register assignment, but it's difficult to do effective global dead code elimination at that point. DCE is trivial on the DAG representation. A typical example of a candidate code sequence in assembly: addis 3, 2, globalvar@toc@ha addi 3, 3, globalvar@toc@l lwz 5, 0(3) When the final instruction is a load or store with an immediate offset of zero, the offset from the add-immediate can replace the zero, provided the relocation information is carried along: addis 3, 2, globalvar@toc@ha lwz 5, globalvar@toc@l(3) Since the addi can in general have multiple uses, we need to only delete the instruction when the last use is removed. llvm-svn: 175697
2013-02-21 08:38:25 +08:00
// We found an opportunity. Reverse the operands from the add
// immediate and substitute them into the load or store. If
// needed, update the target flags for the immediate operand to
// reflect the necessary relocation information.
DEBUG(dbgs() << "Folding add-immediate into mem-op:\nBase: ");
DEBUG(Base->dump(CurDAG));
DEBUG(dbgs() << "\nN: ");
DEBUG(N->dump(CurDAG));
DEBUG(dbgs() << "\n");
// If the relocation information isn't already present on the
// immediate operand, add it now.
if (ReplaceFlags) {
Code review cleanup for r175697 llvm-svn: 175739
2013-02-21 22:35:42 +08:00
if (GlobalAddressSDNode *GA = dyn_cast<GlobalAddressSDNode>(ImmOpnd)) {
Track IR ordering of SelectionDAG nodes 2/4. Change SelectionDAG::getXXXNode() interfaces as well as call sites of these functions to pass in SDLoc instead of DebugLoc. llvm-svn: 182703
2013-05-25 10:42:55 +08:00
SDLoc dl(GA);
PPCDAGToDAGISel::PostprocessISelDAG() This patch implements the PPCDAGToDAGISel::PostprocessISelDAG virtual method to perform post-selection peephole optimizations on the DAG representation. One optimization is implemented here: folds to clean up complex addressing expressions for thread-local storage and medium code model. It will also be useful for large code model sequences when those are added later. I originally thought about doing this on the MI representation prior to register assignment, but it's difficult to do effective global dead code elimination at that point. DCE is trivial on the DAG representation. A typical example of a candidate code sequence in assembly: addis 3, 2, globalvar@toc@ha addi 3, 3, globalvar@toc@l lwz 5, 0(3) When the final instruction is a load or store with an immediate offset of zero, the offset from the add-immediate can replace the zero, provided the relocation information is carried along: addis 3, 2, globalvar@toc@ha lwz 5, globalvar@toc@l(3) Since the addi can in general have multiple uses, we need to only delete the instruction when the last use is removed. llvm-svn: 175697
2013-02-21 08:38:25 +08:00
const GlobalValue *GV = GA->getGlobal();
Index: test/CodeGen/PowerPC/reloc-align.ll =================================================================== --- test/CodeGen/PowerPC/reloc-align.ll (revision 0) +++ test/CodeGen/PowerPC/reloc-align.ll (revision 0) @@ -0,0 +1,34 @@ +; RUN: llc -mcpu=pwr7 -O1 < %s | FileCheck %s + +; This test verifies that the peephole optimization of address accesses +; does not produce a load or store with a relocation that can't be +; satisfied for a given instruction encoding. Reduced from a test supplied +; by Hal Finkel. + +target datalayout = "E-p:64:64:64-i1:8:8-i8:8:8-i16:16:16-i32:32:32-i64:64:64-f32:32:32-f64:64:64-f128:128:128-v128:128:128-n32:64" +target triple = "powerpc64-unknown-linux-gnu" + +%struct.S1 = type { [8 x i8] } + +@main.l_1554 = internal global { i8, i8, i8, i8, i8, i8, i8, i8 } { i8 -1, i8 -6, i8 57, i8 62, i8 -48, i8 0, i8 58, i8 80 }, align 1 + +; Function Attrs: nounwind readonly +define signext i32 @main() #0 { +entry: + %call = tail call fastcc signext i32 @func_90(%struct.S1* byval bitcast ({ i8, i8, i8, i8, i8, i8, i8, i8 }* @main.l_1554 to %struct.S1*)) +; CHECK-NOT: ld {{[0-9]+}}, main.l_1554@toc@l + ret i32 %call +} + +; Function Attrs: nounwind readonly +define internal fastcc signext i32 @func_90(%struct.S1* byval nocapture %p_91) #0 { +entry: + %0 = bitcast %struct.S1* %p_91 to i64* + %bf.load = load i64* %0, align 1 + %bf.shl = shl i64 %bf.load, 26 + %bf.ashr = ashr i64 %bf.shl, 54 + %bf.cast = trunc i64 %bf.ashr to i32 + ret i32 %bf.cast +} + +attributes #0 = { nounwind readonly "less-precise-fpmad"="false" "no-frame-pointer-elim"="true" "no-frame-pointer-elim-non-leaf"="true" "no-infs-fp-math"="false" "no-nans-fp-math"="false" "unsafe-fp-math"="false" "use-soft-float"="false" } Index: lib/Target/PowerPC/PPCAsmPrinter.cpp =================================================================== --- lib/Target/PowerPC/PPCAsmPrinter.cpp (revision 185327) +++ lib/Target/PowerPC/PPCAsmPrinter.cpp (working copy) @@ -679,7 +679,26 @@ void PPCAsmPrinter::EmitInstruction(const MachineI OutStreamer.EmitRawText(StringRef("\tmsync")); return; } + break; + case PPC::LD: + case PPC::STD: + case PPC::LWA: { + // Verify alignment is legal, so we don't create relocations + // that can't be supported. + // FIXME: This test is currently disabled for Darwin. The test + // suite shows a handful of test cases that fail this check for + // Darwin. Those need to be investigated before this sanity test + // can be enabled for those subtargets. + if (!Subtarget.isDarwin()) { + unsigned OpNum = (MI->getOpcode() == PPC::STD) ? 2 : 1; + const MachineOperand &MO = MI->getOperand(OpNum); + if (MO.isGlobal() && MO.getGlobal()->getAlignment() < 4) + llvm_unreachable("Global must be word-aligned for LD, STD, LWA!"); + } + // Now process the instruction normally. + break; } + } LowerPPCMachineInstrToMCInst(MI, TmpInst, *this); OutStreamer.EmitInstruction(TmpInst); Index: lib/Target/PowerPC/PPCISelDAGToDAG.cpp =================================================================== --- lib/Target/PowerPC/PPCISelDAGToDAG.cpp (revision 185327) +++ lib/Target/PowerPC/PPCISelDAGToDAG.cpp (working copy) @@ -1530,6 +1530,14 @@ void PPCDAGToDAGISel::PostprocessISelDAG() { if (GlobalAddressSDNode *GA = dyn_cast<GlobalAddressSDNode>(ImmOpnd)) { SDLoc dl(GA); const GlobalValue *GV = GA->getGlobal(); + // We can't perform this optimization for data whose alignment + // is insufficient for the instruction encoding. + if (GV->getAlignment() < 4 && + (StorageOpcode == PPC::LD || StorageOpcode == PPC::STD || + StorageOpcode == PPC::LWA)) { + DEBUG(dbgs() << "Rejected this candidate for alignment.\n\n"); + continue; + } ImmOpnd = CurDAG->getTargetGlobalAddress(GV, dl, MVT::i64, 0, Flags); } else if (ConstantPoolSDNode *CP = dyn_cast<ConstantPoolSDNode>(ImmOpnd)) { llvm-svn: 185380
2013-07-02 04:52:27 +08:00
// We can't perform this optimization for data whose alignment
// is insufficient for the instruction encoding.
if (GV->getAlignment() < 4 &&
(StorageOpcode == PPC::LD || StorageOpcode == PPC::STD ||
[PPC]: Peephole optimize small accesss to aligned globals. Access to aligned globals gives us a chance to peephole optimize nonzero offsets. If a struct is 4 byte aligned, then accesses to bytes 0-3 won't overflow the available displacement. For example: addis 3, 2, b4v@toc@ha addi 4, 3, b4v@toc@l lbz 5, b4v@toc@l(3) ; This is the result of the current peephole lbz 6, 1(4) ; optimizer lbz 7, 2(4) lbz 8, 3(4) If b4v is 4-byte aligned, we can skip using register 4 because we know that b4v@toc@l+{1,2,3} won't overflow 32K, and instead generate: addis 3, 2, b4v@toc@ha lbz 4, b4v@toc@l(3) lbz 5, b4v@toc@l+1(3) lbz 6, b4v@toc@l+2(3) lbz 7, b4v@toc@l+3(3) Saving a register and an addition. Larger alignments allow larger structures/arrays to be optimized. llvm-svn: 255319
2015-12-11 08:47:36 +08:00
StorageOpcode == PPC::LWA || (Offset % 4) != 0)) {
Index: test/CodeGen/PowerPC/reloc-align.ll =================================================================== --- test/CodeGen/PowerPC/reloc-align.ll (revision 0) +++ test/CodeGen/PowerPC/reloc-align.ll (revision 0) @@ -0,0 +1,34 @@ +; RUN: llc -mcpu=pwr7 -O1 < %s | FileCheck %s + +; This test verifies that the peephole optimization of address accesses +; does not produce a load or store with a relocation that can't be +; satisfied for a given instruction encoding. Reduced from a test supplied +; by Hal Finkel. + +target datalayout = "E-p:64:64:64-i1:8:8-i8:8:8-i16:16:16-i32:32:32-i64:64:64-f32:32:32-f64:64:64-f128:128:128-v128:128:128-n32:64" +target triple = "powerpc64-unknown-linux-gnu" + +%struct.S1 = type { [8 x i8] } + +@main.l_1554 = internal global { i8, i8, i8, i8, i8, i8, i8, i8 } { i8 -1, i8 -6, i8 57, i8 62, i8 -48, i8 0, i8 58, i8 80 }, align 1 + +; Function Attrs: nounwind readonly +define signext i32 @main() #0 { +entry: + %call = tail call fastcc signext i32 @func_90(%struct.S1* byval bitcast ({ i8, i8, i8, i8, i8, i8, i8, i8 }* @main.l_1554 to %struct.S1*)) +; CHECK-NOT: ld {{[0-9]+}}, main.l_1554@toc@l + ret i32 %call +} + +; Function Attrs: nounwind readonly +define internal fastcc signext i32 @func_90(%struct.S1* byval nocapture %p_91) #0 { +entry: + %0 = bitcast %struct.S1* %p_91 to i64* + %bf.load = load i64* %0, align 1 + %bf.shl = shl i64 %bf.load, 26 + %bf.ashr = ashr i64 %bf.shl, 54 + %bf.cast = trunc i64 %bf.ashr to i32 + ret i32 %bf.cast +} + +attributes #0 = { nounwind readonly "less-precise-fpmad"="false" "no-frame-pointer-elim"="true" "no-frame-pointer-elim-non-leaf"="true" "no-infs-fp-math"="false" "no-nans-fp-math"="false" "unsafe-fp-math"="false" "use-soft-float"="false" } Index: lib/Target/PowerPC/PPCAsmPrinter.cpp =================================================================== --- lib/Target/PowerPC/PPCAsmPrinter.cpp (revision 185327) +++ lib/Target/PowerPC/PPCAsmPrinter.cpp (working copy) @@ -679,7 +679,26 @@ void PPCAsmPrinter::EmitInstruction(const MachineI OutStreamer.EmitRawText(StringRef("\tmsync")); return; } + break; + case PPC::LD: + case PPC::STD: + case PPC::LWA: { + // Verify alignment is legal, so we don't create relocations + // that can't be supported. + // FIXME: This test is currently disabled for Darwin. The test + // suite shows a handful of test cases that fail this check for + // Darwin. Those need to be investigated before this sanity test + // can be enabled for those subtargets. + if (!Subtarget.isDarwin()) { + unsigned OpNum = (MI->getOpcode() == PPC::STD) ? 2 : 1; + const MachineOperand &MO = MI->getOperand(OpNum); + if (MO.isGlobal() && MO.getGlobal()->getAlignment() < 4) + llvm_unreachable("Global must be word-aligned for LD, STD, LWA!"); + } + // Now process the instruction normally. + break; } + } LowerPPCMachineInstrToMCInst(MI, TmpInst, *this); OutStreamer.EmitInstruction(TmpInst); Index: lib/Target/PowerPC/PPCISelDAGToDAG.cpp =================================================================== --- lib/Target/PowerPC/PPCISelDAGToDAG.cpp (revision 185327) +++ lib/Target/PowerPC/PPCISelDAGToDAG.cpp (working copy) @@ -1530,6 +1530,14 @@ void PPCDAGToDAGISel::PostprocessISelDAG() { if (GlobalAddressSDNode *GA = dyn_cast<GlobalAddressSDNode>(ImmOpnd)) { SDLoc dl(GA); const GlobalValue *GV = GA->getGlobal(); + // We can't perform this optimization for data whose alignment + // is insufficient for the instruction encoding. + if (GV->getAlignment() < 4 && + (StorageOpcode == PPC::LD || StorageOpcode == PPC::STD || + StorageOpcode == PPC::LWA)) { + DEBUG(dbgs() << "Rejected this candidate for alignment.\n\n"); + continue; + } ImmOpnd = CurDAG->getTargetGlobalAddress(GV, dl, MVT::i64, 0, Flags); } else if (ConstantPoolSDNode *CP = dyn_cast<ConstantPoolSDNode>(ImmOpnd)) { llvm-svn: 185380
2013-07-02 04:52:27 +08:00
DEBUG(dbgs() << "Rejected this candidate for alignment.\n\n");
continue;
}
[PPC]: Peephole optimize small accesss to aligned globals. Access to aligned globals gives us a chance to peephole optimize nonzero offsets. If a struct is 4 byte aligned, then accesses to bytes 0-3 won't overflow the available displacement. For example: addis 3, 2, b4v@toc@ha addi 4, 3, b4v@toc@l lbz 5, b4v@toc@l(3) ; This is the result of the current peephole lbz 6, 1(4) ; optimizer lbz 7, 2(4) lbz 8, 3(4) If b4v is 4-byte aligned, we can skip using register 4 because we know that b4v@toc@l+{1,2,3} won't overflow 32K, and instead generate: addis 3, 2, b4v@toc@ha lbz 4, b4v@toc@l(3) lbz 5, b4v@toc@l+1(3) lbz 6, b4v@toc@l+2(3) lbz 7, b4v@toc@l+3(3) Saving a register and an addition. Larger alignments allow larger structures/arrays to be optimized. llvm-svn: 255319
2015-12-11 08:47:36 +08:00
ImmOpnd = CurDAG->getTargetGlobalAddress(GV, dl, MVT::i64, Offset, Flags);
Trivial cleanup llvm-svn: 175771
2013-02-22 01:26:05 +08:00
} else if (ConstantPoolSDNode *CP =
dyn_cast<ConstantPoolSDNode>(ImmOpnd)) {
Code review cleanup for r175697 llvm-svn: 175739
2013-02-21 22:35:42 +08:00
const Constant *C = CP->getConstVal();
ImmOpnd = CurDAG->getTargetConstantPool(C, MVT::i64,
CP->getAlignment(),
[PPC]: Peephole optimize small accesss to aligned globals. Access to aligned globals gives us a chance to peephole optimize nonzero offsets. If a struct is 4 byte aligned, then accesses to bytes 0-3 won't overflow the available displacement. For example: addis 3, 2, b4v@toc@ha addi 4, 3, b4v@toc@l lbz 5, b4v@toc@l(3) ; This is the result of the current peephole lbz 6, 1(4) ; optimizer lbz 7, 2(4) lbz 8, 3(4) If b4v is 4-byte aligned, we can skip using register 4 because we know that b4v@toc@l+{1,2,3} won't overflow 32K, and instead generate: addis 3, 2, b4v@toc@ha lbz 4, b4v@toc@l(3) lbz 5, b4v@toc@l+1(3) lbz 6, b4v@toc@l+2(3) lbz 7, b4v@toc@l+3(3) Saving a register and an addition. Larger alignments allow larger structures/arrays to be optimized. llvm-svn: 255319
2015-12-11 08:47:36 +08:00
Offset, Flags);
PPCDAGToDAGISel::PostprocessISelDAG() This patch implements the PPCDAGToDAGISel::PostprocessISelDAG virtual method to perform post-selection peephole optimizations on the DAG representation. One optimization is implemented here: folds to clean up complex addressing expressions for thread-local storage and medium code model. It will also be useful for large code model sequences when those are added later. I originally thought about doing this on the MI representation prior to register assignment, but it's difficult to do effective global dead code elimination at that point. DCE is trivial on the DAG representation. A typical example of a candidate code sequence in assembly: addis 3, 2, globalvar@toc@ha addi 3, 3, globalvar@toc@l lwz 5, 0(3) When the final instruction is a load or store with an immediate offset of zero, the offset from the add-immediate can replace the zero, provided the relocation information is carried along: addis 3, 2, globalvar@toc@ha lwz 5, globalvar@toc@l(3) Since the addi can in general have multiple uses, we need to only delete the instruction when the last use is removed. llvm-svn: 175697
2013-02-21 08:38:25 +08:00
}
}
if (FirstOp == 1) // Store
(void)CurDAG->UpdateNodeOperands(N, N->getOperand(0), ImmOpnd,
Base.getOperand(0), N->getOperand(3));
else // Load
(void)CurDAG->UpdateNodeOperands(N, ImmOpnd, Base.getOperand(0),
N->getOperand(2));
// The add-immediate may now be dead, in which case remove it.
if (Base.getNode()->use_empty())
CurDAG->RemoveDeadNode(Base.getNode());
}
}
initial hack at a dag->dag instruction selector. This is obviously woefully incomplete, but it is a start. It handles basic argument/retval stuff, immediates, add and sub. llvm-svn: 22836
2005-08-18 03:33:03 +08:00
Work around a nasty tblgen bug where it doesn't add operands for varargs nodes correctly. llvm-svn: 28745
2006-06-10 09:15:02 +08:00
whitespace llvm-svn: 122539
2010-12-24 12:28:06 +08:00
/// createPPCISelDag - This pass converts a legalized DAG into a
initial hack at a dag->dag instruction selector. This is obviously woefully incomplete, but it is a start. It handles basic argument/retval stuff, immediates, add and sub. llvm-svn: 22836
2005-08-18 03:33:03 +08:00
/// PowerPC-specific DAG, ready for instruction scheduling.
///
Added getTargetLowering() to TargetMachine. Refactored targets to support this. llvm-svn: 26742
2006-03-14 07:20:37 +08:00
FunctionPass *llvm::createPPCISelDag(PPCTargetMachine &TM) {
First bits of 64 bit PowerPC stuff, currently disabled. A lot of this is purely mechanical. llvm-svn: 23778
2005-10-18 08:28:58 +08:00
return new PPCDAGToDAGISel(TM);
initial hack at a dag->dag instruction selector. This is obviously woefully incomplete, but it is a start. It handles basic argument/retval stuff, immediates, add and sub. llvm-svn: 22836
2005-08-18 03:33:03 +08:00
}
Add registration for PPC-specific passes to allow the IR to be dumped via -print-after-all. llvm-svn: 175058
2013-02-14 01:40:07 +08:00
static void initializePassOnce(PassRegistry &Registry) {
const char *Name = "PowerPC DAG->DAG Pattern Instruction Selection";
[C++] Use 'nullptr'. Target edition. llvm-svn: 207197
2014-04-25 13:30:21 +08:00
PassInfo *PI = new PassInfo(Name, "ppc-codegen", &SelectionDAGISel::ID,
nullptr, false, false);
Add registration for PPC-specific passes to allow the IR to be dumped via -print-after-all. llvm-svn: 175058
2013-02-14 01:40:07 +08:00
Registry.registerPass(*PI, true);
}
void llvm::initializePPCDAGToDAGISelPass(PassRegistry &Registry) {
CALL_ONCE_INITIALIZATION(initializePassOnce);
}