llvm-project/llvm/lib/CodeGen/MachineSink.cpp

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//===-- MachineSink.cpp - Sinking for machine instructions ----------------===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This pass moves instructions into successor blocks when possible, so that
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// they aren't executed on paths where their results aren't needed.
//
// This pass is not intended to be a replacement or a complete alternative
// for an LLVM-IR-level sinking pass. It is only designed to sink simple
// constructs that are not exposed before lowering and instruction selection.
//
//===----------------------------------------------------------------------===//
#include "llvm/CodeGen/Passes.h"
[MachineSink] Improve the compile time by preserving the dominance information as long as possible. ** Context ** Each time the dominance information is modified, the dominator tree analysis switches in a slow query mode. After a few queries without any modification on the dominator tree, it performs an expensive update of its internal structure to provide fast queries again. ** Problem ** Prior to this patch, the MachineSink pass was splitting the critical edges on demand while relying heavy on the dominator tree information. In some cases, this leads to pathological behavior where: - We end up in the slow query mode right after splitting an edge. - We update the dominance information. - We break the dominance information again, thus ending up in the slow query mode and so on. ** Proposed Solution ** To mitigate this effect, this patch postpones all the splitting of the edges at the end of each iteration of the main loop. The benefits are: - The dominance information is valid for the life time of an iteration. - This simplifies the code as we do not have to special treat instructions that are sunk on critical edges. Indeed, the related block will be available through the next iteration. The downside is that when edges splitting is required, this incurs an additional iteration of the main loop compared to the previous scheme. ** Performance ** Thanks to this patch, the motivating example compiles in 6+ minutes instead of 10+ minutes. No test case added as the motivating example as nothing special but being huge! I have measured only noise for both the compile time and the runtime on the llvm test-suite + SPECs with Os and O3. Note: The current implementation of MachineBasicBlock::SplitCriticalEdge also uses the dominance information and therefore, hits this problem. A subsequent patch will address that. <rdar://problem/17894619> llvm-svn: 215410
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#include "llvm/ADT/SetVector.h"
#include "llvm/ADT/SmallSet.h"
#include "llvm/ADT/SparseBitVector.h"
#include "llvm/ADT/Statistic.h"
#include "llvm/Analysis/AliasAnalysis.h"
#include "llvm/CodeGen/MachineBlockFrequencyInfo.h"
#include "llvm/CodeGen/MachineDominators.h"
#include "llvm/CodeGen/MachineLoopInfo.h"
#include "llvm/CodeGen/MachinePostDominators.h"
#include "llvm/CodeGen/MachineRegisterInfo.h"
#include "llvm/IR/LLVMContext.h"
#include "llvm/Support/CommandLine.h"
#include "llvm/Support/Debug.h"
#include "llvm/Support/raw_ostream.h"
#include "llvm/Target/TargetInstrInfo.h"
#include "llvm/Target/TargetRegisterInfo.h"
#include "llvm/Target/TargetSubtargetInfo.h"
using namespace llvm;
#define DEBUG_TYPE "machine-sink"
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static cl::opt<bool>
SplitEdges("machine-sink-split",
cl::desc("Split critical edges during machine sinking"),
cl::init(true), cl::Hidden);
static cl::opt<bool>
UseBlockFreqInfo("machine-sink-bfi",
cl::desc("Use block frequency info to find successors to sink"),
cl::init(true), cl::Hidden);
STATISTIC(NumSunk, "Number of machine instructions sunk");
STATISTIC(NumSplit, "Number of critical edges split");
STATISTIC(NumCoalesces, "Number of copies coalesced");
namespace {
class MachineSinking : public MachineFunctionPass {
const TargetInstrInfo *TII;
const TargetRegisterInfo *TRI;
MachineRegisterInfo *MRI; // Machine register information
MachineDominatorTree *DT; // Machine dominator tree
MachinePostDominatorTree *PDT; // Machine post dominator tree
MachineLoopInfo *LI;
const MachineBlockFrequencyInfo *MBFI;
AliasAnalysis *AA;
// Remember which edges have been considered for breaking.
SmallSet<std::pair<MachineBasicBlock*,MachineBasicBlock*>, 8>
CEBCandidates;
[MachineSink] Improve the compile time by preserving the dominance information as long as possible. ** Context ** Each time the dominance information is modified, the dominator tree analysis switches in a slow query mode. After a few queries without any modification on the dominator tree, it performs an expensive update of its internal structure to provide fast queries again. ** Problem ** Prior to this patch, the MachineSink pass was splitting the critical edges on demand while relying heavy on the dominator tree information. In some cases, this leads to pathological behavior where: - We end up in the slow query mode right after splitting an edge. - We update the dominance information. - We break the dominance information again, thus ending up in the slow query mode and so on. ** Proposed Solution ** To mitigate this effect, this patch postpones all the splitting of the edges at the end of each iteration of the main loop. The benefits are: - The dominance information is valid for the life time of an iteration. - This simplifies the code as we do not have to special treat instructions that are sunk on critical edges. Indeed, the related block will be available through the next iteration. The downside is that when edges splitting is required, this incurs an additional iteration of the main loop compared to the previous scheme. ** Performance ** Thanks to this patch, the motivating example compiles in 6+ minutes instead of 10+ minutes. No test case added as the motivating example as nothing special but being huge! I have measured only noise for both the compile time and the runtime on the llvm test-suite + SPECs with Os and O3. Note: The current implementation of MachineBasicBlock::SplitCriticalEdge also uses the dominance information and therefore, hits this problem. A subsequent patch will address that. <rdar://problem/17894619> llvm-svn: 215410
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// Remember which edges we are about to split.
// This is different from CEBCandidates since those edges
// will be split.
SetVector<std::pair<MachineBasicBlock*,MachineBasicBlock*> > ToSplit;
SparseBitVector<> RegsToClearKillFlags;
typedef std::map<MachineBasicBlock *, SmallVector<MachineBasicBlock *, 4>>
AllSuccsCache;
public:
static char ID; // Pass identification
MachineSinking() : MachineFunctionPass(ID) {
initializeMachineSinkingPass(*PassRegistry::getPassRegistry());
}
bool runOnMachineFunction(MachineFunction &MF) override;
void getAnalysisUsage(AnalysisUsage &AU) const override {
AU.setPreservesCFG();
MachineFunctionPass::getAnalysisUsage(AU);
[PM/AA] Rebuild LLVM's alias analysis infrastructure in a way compatible with the new pass manager, and no longer relying on analysis groups. This builds essentially a ground-up new AA infrastructure stack for LLVM. The core ideas are the same that are used throughout the new pass manager: type erased polymorphism and direct composition. The design is as follows: - FunctionAAResults is a type-erasing alias analysis results aggregation interface to walk a single query across a range of results from different alias analyses. Currently this is function-specific as we always assume that aliasing queries are *within* a function. - AAResultBase is a CRTP utility providing stub implementations of various parts of the alias analysis result concept, notably in several cases in terms of other more general parts of the interface. This can be used to implement only a narrow part of the interface rather than the entire interface. This isn't really ideal, this logic should be hoisted into FunctionAAResults as currently it will cause a significant amount of redundant work, but it faithfully models the behavior of the prior infrastructure. - All the alias analysis passes are ported to be wrapper passes for the legacy PM and new-style analysis passes for the new PM with a shared result object. In some cases (most notably CFL), this is an extremely naive approach that we should revisit when we can specialize for the new pass manager. - BasicAA has been restructured to reflect that it is much more fundamentally a function analysis because it uses dominator trees and loop info that need to be constructed for each function. All of the references to getting alias analysis results have been updated to use the new aggregation interface. All the preservation and other pass management code has been updated accordingly. The way the FunctionAAResultsWrapperPass works is to detect the available alias analyses when run, and add them to the results object. This means that we should be able to continue to respect when various passes are added to the pipeline, for example adding CFL or adding TBAA passes should just cause their results to be available and to get folded into this. The exception to this rule is BasicAA which really needs to be a function pass due to using dominator trees and loop info. As a consequence, the FunctionAAResultsWrapperPass directly depends on BasicAA and always includes it in the aggregation. This has significant implications for preserving analyses. Generally, most passes shouldn't bother preserving FunctionAAResultsWrapperPass because rebuilding the results just updates the set of known AA passes. The exception to this rule are LoopPass instances which need to preserve all the function analyses that the loop pass manager will end up needing. This means preserving both BasicAAWrapperPass and the aggregating FunctionAAResultsWrapperPass. Now, when preserving an alias analysis, you do so by directly preserving that analysis. This is only necessary for non-immutable-pass-provided alias analyses though, and there are only three of interest: BasicAA, GlobalsAA (formerly GlobalsModRef), and SCEVAA. Usually BasicAA is preserved when needed because it (like DominatorTree and LoopInfo) is marked as a CFG-only pass. I've expanded GlobalsAA into the preserved set everywhere we previously were preserving all of AliasAnalysis, and I've added SCEVAA in the intersection of that with where we preserve SCEV itself. One significant challenge to all of this is that the CGSCC passes were actually using the alias analysis implementations by taking advantage of a pretty amazing set of loop holes in the old pass manager's analysis management code which allowed analysis groups to slide through in many cases. Moving away from analysis groups makes this problem much more obvious. To fix it, I've leveraged the flexibility the design of the new PM components provides to just directly construct the relevant alias analyses for the relevant functions in the IPO passes that need them. This is a bit hacky, but should go away with the new pass manager, and is already in many ways cleaner than the prior state. Another significant challenge is that various facilities of the old alias analysis infrastructure just don't fit any more. The most significant of these is the alias analysis 'counter' pass. That pass relied on the ability to snoop on AA queries at different points in the analysis group chain. Instead, I'm planning to build printing functionality directly into the aggregation layer. I've not included that in this patch merely to keep it smaller. Note that all of this needs a nearly complete rewrite of the AA documentation. I'm planning to do that, but I'd like to make sure the new design settles, and to flesh out a bit more of what it looks like in the new pass manager first. Differential Revision: http://reviews.llvm.org/D12080 llvm-svn: 247167
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AU.addRequired<AAResultsWrapperPass>();
AU.addRequired<MachineDominatorTree>();
AU.addRequired<MachinePostDominatorTree>();
AU.addRequired<MachineLoopInfo>();
AU.addPreserved<MachineDominatorTree>();
AU.addPreserved<MachinePostDominatorTree>();
AU.addPreserved<MachineLoopInfo>();
if (UseBlockFreqInfo)
AU.addRequired<MachineBlockFrequencyInfo>();
}
void releaseMemory() override {
CEBCandidates.clear();
}
private:
bool ProcessBlock(MachineBasicBlock &MBB);
bool isWorthBreakingCriticalEdge(MachineInstr *MI,
MachineBasicBlock *From,
MachineBasicBlock *To);
[MachineSink] Improve the compile time by preserving the dominance information as long as possible. ** Context ** Each time the dominance information is modified, the dominator tree analysis switches in a slow query mode. After a few queries without any modification on the dominator tree, it performs an expensive update of its internal structure to provide fast queries again. ** Problem ** Prior to this patch, the MachineSink pass was splitting the critical edges on demand while relying heavy on the dominator tree information. In some cases, this leads to pathological behavior where: - We end up in the slow query mode right after splitting an edge. - We update the dominance information. - We break the dominance information again, thus ending up in the slow query mode and so on. ** Proposed Solution ** To mitigate this effect, this patch postpones all the splitting of the edges at the end of each iteration of the main loop. The benefits are: - The dominance information is valid for the life time of an iteration. - This simplifies the code as we do not have to special treat instructions that are sunk on critical edges. Indeed, the related block will be available through the next iteration. The downside is that when edges splitting is required, this incurs an additional iteration of the main loop compared to the previous scheme. ** Performance ** Thanks to this patch, the motivating example compiles in 6+ minutes instead of 10+ minutes. No test case added as the motivating example as nothing special but being huge! I have measured only noise for both the compile time and the runtime on the llvm test-suite + SPECs with Os and O3. Note: The current implementation of MachineBasicBlock::SplitCriticalEdge also uses the dominance information and therefore, hits this problem. A subsequent patch will address that. <rdar://problem/17894619> llvm-svn: 215410
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/// \brief Postpone the splitting of the given critical
/// edge (\p From, \p To).
///
/// We do not split the edges on the fly. Indeed, this invalidates
/// the dominance information and thus triggers a lot of updates
/// of that information underneath.
/// Instead, we postpone all the splits after each iteration of
/// the main loop. That way, the information is at least valid
/// for the lifetime of an iteration.
///
/// \return True if the edge is marked as toSplit, false otherwise.
/// False can be returned if, for instance, this is not profitable.
[MachineSink] Improve the compile time by preserving the dominance information as long as possible. ** Context ** Each time the dominance information is modified, the dominator tree analysis switches in a slow query mode. After a few queries without any modification on the dominator tree, it performs an expensive update of its internal structure to provide fast queries again. ** Problem ** Prior to this patch, the MachineSink pass was splitting the critical edges on demand while relying heavy on the dominator tree information. In some cases, this leads to pathological behavior where: - We end up in the slow query mode right after splitting an edge. - We update the dominance information. - We break the dominance information again, thus ending up in the slow query mode and so on. ** Proposed Solution ** To mitigate this effect, this patch postpones all the splitting of the edges at the end of each iteration of the main loop. The benefits are: - The dominance information is valid for the life time of an iteration. - This simplifies the code as we do not have to special treat instructions that are sunk on critical edges. Indeed, the related block will be available through the next iteration. The downside is that when edges splitting is required, this incurs an additional iteration of the main loop compared to the previous scheme. ** Performance ** Thanks to this patch, the motivating example compiles in 6+ minutes instead of 10+ minutes. No test case added as the motivating example as nothing special but being huge! I have measured only noise for both the compile time and the runtime on the llvm test-suite + SPECs with Os and O3. Note: The current implementation of MachineBasicBlock::SplitCriticalEdge also uses the dominance information and therefore, hits this problem. A subsequent patch will address that. <rdar://problem/17894619> llvm-svn: 215410
2014-08-12 07:52:01 +08:00
bool PostponeSplitCriticalEdge(MachineInstr *MI,
MachineBasicBlock *From,
MachineBasicBlock *To,
bool BreakPHIEdge);
bool SinkInstruction(MachineInstr *MI, bool &SawStore,
AllSuccsCache &AllSuccessors);
bool AllUsesDominatedByBlock(unsigned Reg, MachineBasicBlock *MBB,
MachineBasicBlock *DefMBB,
bool &BreakPHIEdge, bool &LocalUse) const;
MachineBasicBlock *FindSuccToSinkTo(MachineInstr *MI, MachineBasicBlock *MBB,
bool &BreakPHIEdge, AllSuccsCache &AllSuccessors);
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bool isProfitableToSinkTo(unsigned Reg, MachineInstr *MI,
MachineBasicBlock *MBB,
MachineBasicBlock *SuccToSinkTo,
AllSuccsCache &AllSuccessors);
bool PerformTrivialForwardCoalescing(MachineInstr *MI,
MachineBasicBlock *MBB);
SmallVector<MachineBasicBlock *, 4> &
GetAllSortedSuccessors(MachineInstr *MI, MachineBasicBlock *MBB,
AllSuccsCache &AllSuccessors) const;
};
} // end anonymous namespace
char MachineSinking::ID = 0;
char &llvm::MachineSinkingID = MachineSinking::ID;
INITIALIZE_PASS_BEGIN(MachineSinking, "machine-sink",
"Machine code sinking", false, false)
INITIALIZE_PASS_DEPENDENCY(MachineDominatorTree)
INITIALIZE_PASS_DEPENDENCY(MachineLoopInfo)
[PM/AA] Rebuild LLVM's alias analysis infrastructure in a way compatible with the new pass manager, and no longer relying on analysis groups. This builds essentially a ground-up new AA infrastructure stack for LLVM. The core ideas are the same that are used throughout the new pass manager: type erased polymorphism and direct composition. The design is as follows: - FunctionAAResults is a type-erasing alias analysis results aggregation interface to walk a single query across a range of results from different alias analyses. Currently this is function-specific as we always assume that aliasing queries are *within* a function. - AAResultBase is a CRTP utility providing stub implementations of various parts of the alias analysis result concept, notably in several cases in terms of other more general parts of the interface. This can be used to implement only a narrow part of the interface rather than the entire interface. This isn't really ideal, this logic should be hoisted into FunctionAAResults as currently it will cause a significant amount of redundant work, but it faithfully models the behavior of the prior infrastructure. - All the alias analysis passes are ported to be wrapper passes for the legacy PM and new-style analysis passes for the new PM with a shared result object. In some cases (most notably CFL), this is an extremely naive approach that we should revisit when we can specialize for the new pass manager. - BasicAA has been restructured to reflect that it is much more fundamentally a function analysis because it uses dominator trees and loop info that need to be constructed for each function. All of the references to getting alias analysis results have been updated to use the new aggregation interface. All the preservation and other pass management code has been updated accordingly. The way the FunctionAAResultsWrapperPass works is to detect the available alias analyses when run, and add them to the results object. This means that we should be able to continue to respect when various passes are added to the pipeline, for example adding CFL or adding TBAA passes should just cause their results to be available and to get folded into this. The exception to this rule is BasicAA which really needs to be a function pass due to using dominator trees and loop info. As a consequence, the FunctionAAResultsWrapperPass directly depends on BasicAA and always includes it in the aggregation. This has significant implications for preserving analyses. Generally, most passes shouldn't bother preserving FunctionAAResultsWrapperPass because rebuilding the results just updates the set of known AA passes. The exception to this rule are LoopPass instances which need to preserve all the function analyses that the loop pass manager will end up needing. This means preserving both BasicAAWrapperPass and the aggregating FunctionAAResultsWrapperPass. Now, when preserving an alias analysis, you do so by directly preserving that analysis. This is only necessary for non-immutable-pass-provided alias analyses though, and there are only three of interest: BasicAA, GlobalsAA (formerly GlobalsModRef), and SCEVAA. Usually BasicAA is preserved when needed because it (like DominatorTree and LoopInfo) is marked as a CFG-only pass. I've expanded GlobalsAA into the preserved set everywhere we previously were preserving all of AliasAnalysis, and I've added SCEVAA in the intersection of that with where we preserve SCEV itself. One significant challenge to all of this is that the CGSCC passes were actually using the alias analysis implementations by taking advantage of a pretty amazing set of loop holes in the old pass manager's analysis management code which allowed analysis groups to slide through in many cases. Moving away from analysis groups makes this problem much more obvious. To fix it, I've leveraged the flexibility the design of the new PM components provides to just directly construct the relevant alias analyses for the relevant functions in the IPO passes that need them. This is a bit hacky, but should go away with the new pass manager, and is already in many ways cleaner than the prior state. Another significant challenge is that various facilities of the old alias analysis infrastructure just don't fit any more. The most significant of these is the alias analysis 'counter' pass. That pass relied on the ability to snoop on AA queries at different points in the analysis group chain. Instead, I'm planning to build printing functionality directly into the aggregation layer. I've not included that in this patch merely to keep it smaller. Note that all of this needs a nearly complete rewrite of the AA documentation. I'm planning to do that, but I'd like to make sure the new design settles, and to flesh out a bit more of what it looks like in the new pass manager first. Differential Revision: http://reviews.llvm.org/D12080 llvm-svn: 247167
2015-09-10 01:55:00 +08:00
INITIALIZE_PASS_DEPENDENCY(AAResultsWrapperPass)
INITIALIZE_PASS_END(MachineSinking, "machine-sink",
"Machine code sinking", false, false)
bool MachineSinking::PerformTrivialForwardCoalescing(MachineInstr *MI,
MachineBasicBlock *MBB) {
if (!MI->isCopy())
return false;
unsigned SrcReg = MI->getOperand(1).getReg();
unsigned DstReg = MI->getOperand(0).getReg();
if (!TargetRegisterInfo::isVirtualRegister(SrcReg) ||
!TargetRegisterInfo::isVirtualRegister(DstReg) ||
!MRI->hasOneNonDBGUse(SrcReg))
return false;
const TargetRegisterClass *SRC = MRI->getRegClass(SrcReg);
const TargetRegisterClass *DRC = MRI->getRegClass(DstReg);
if (SRC != DRC)
return false;
MachineInstr *DefMI = MRI->getVRegDef(SrcReg);
if (DefMI->isCopyLike())
return false;
DEBUG(dbgs() << "Coalescing: " << *DefMI);
DEBUG(dbgs() << "*** to: " << *MI);
MRI->replaceRegWith(DstReg, SrcReg);
MI->eraseFromParent();
// Conservatively, clear any kill flags, since it's possible that they are no
// longer correct.
MRI->clearKillFlags(SrcReg);
++NumCoalesces;
return true;
}
/// AllUsesDominatedByBlock - Return true if all uses of the specified register
/// occur in blocks dominated by the specified block. If any use is in the
/// definition block, then return false since it is never legal to move def
/// after uses.
bool
MachineSinking::AllUsesDominatedByBlock(unsigned Reg,
MachineBasicBlock *MBB,
MachineBasicBlock *DefMBB,
bool &BreakPHIEdge,
bool &LocalUse) const {
assert(TargetRegisterInfo::isVirtualRegister(Reg) &&
"Only makes sense for vregs");
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// Ignore debug uses because debug info doesn't affect the code.
if (MRI->use_nodbg_empty(Reg))
return true;
// BreakPHIEdge is true if all the uses are in the successor MBB being sunken
// into and they are all PHI nodes. In this case, machine-sink must break
// the critical edge first. e.g.
//
// BB#1: derived from LLVM BB %bb4.preheader
// Predecessors according to CFG: BB#0
// ...
// %reg16385<def> = DEC64_32r %reg16437, %EFLAGS<imp-def,dead>
// ...
// JE_4 <BB#37>, %EFLAGS<imp-use>
// Successors according to CFG: BB#37 BB#2
//
// BB#2: derived from LLVM BB %bb.nph
// Predecessors according to CFG: BB#0 BB#1
// %reg16386<def> = PHI %reg16434, <BB#0>, %reg16385, <BB#1>
BreakPHIEdge = true;
for (MachineOperand &MO : MRI->use_nodbg_operands(Reg)) {
MachineInstr *UseInst = MO.getParent();
unsigned OpNo = &MO - &UseInst->getOperand(0);
MachineBasicBlock *UseBlock = UseInst->getParent();
if (!(UseBlock == MBB && UseInst->isPHI() &&
UseInst->getOperand(OpNo+1).getMBB() == DefMBB)) {
BreakPHIEdge = false;
break;
}
}
if (BreakPHIEdge)
return true;
for (MachineOperand &MO : MRI->use_nodbg_operands(Reg)) {
// Determine the block of the use.
MachineInstr *UseInst = MO.getParent();
unsigned OpNo = &MO - &UseInst->getOperand(0);
MachineBasicBlock *UseBlock = UseInst->getParent();
if (UseInst->isPHI()) {
// PHI nodes use the operand in the predecessor block, not the block with
// the PHI.
UseBlock = UseInst->getOperand(OpNo+1).getMBB();
} else if (UseBlock == DefMBB) {
LocalUse = true;
return false;
}
// Check that it dominates.
if (!DT->dominates(MBB, UseBlock))
return false;
}
return true;
}
bool MachineSinking::runOnMachineFunction(MachineFunction &MF) {
if (skipOptnoneFunction(*MF.getFunction()))
return false;
DEBUG(dbgs() << "******** Machine Sinking ********\n");
TII = MF.getSubtarget().getInstrInfo();
TRI = MF.getSubtarget().getRegisterInfo();
MRI = &MF.getRegInfo();
DT = &getAnalysis<MachineDominatorTree>();
PDT = &getAnalysis<MachinePostDominatorTree>();
LI = &getAnalysis<MachineLoopInfo>();
MBFI = UseBlockFreqInfo ? &getAnalysis<MachineBlockFrequencyInfo>() : nullptr;
[PM/AA] Rebuild LLVM's alias analysis infrastructure in a way compatible with the new pass manager, and no longer relying on analysis groups. This builds essentially a ground-up new AA infrastructure stack for LLVM. The core ideas are the same that are used throughout the new pass manager: type erased polymorphism and direct composition. The design is as follows: - FunctionAAResults is a type-erasing alias analysis results aggregation interface to walk a single query across a range of results from different alias analyses. Currently this is function-specific as we always assume that aliasing queries are *within* a function. - AAResultBase is a CRTP utility providing stub implementations of various parts of the alias analysis result concept, notably in several cases in terms of other more general parts of the interface. This can be used to implement only a narrow part of the interface rather than the entire interface. This isn't really ideal, this logic should be hoisted into FunctionAAResults as currently it will cause a significant amount of redundant work, but it faithfully models the behavior of the prior infrastructure. - All the alias analysis passes are ported to be wrapper passes for the legacy PM and new-style analysis passes for the new PM with a shared result object. In some cases (most notably CFL), this is an extremely naive approach that we should revisit when we can specialize for the new pass manager. - BasicAA has been restructured to reflect that it is much more fundamentally a function analysis because it uses dominator trees and loop info that need to be constructed for each function. All of the references to getting alias analysis results have been updated to use the new aggregation interface. All the preservation and other pass management code has been updated accordingly. The way the FunctionAAResultsWrapperPass works is to detect the available alias analyses when run, and add them to the results object. This means that we should be able to continue to respect when various passes are added to the pipeline, for example adding CFL or adding TBAA passes should just cause their results to be available and to get folded into this. The exception to this rule is BasicAA which really needs to be a function pass due to using dominator trees and loop info. As a consequence, the FunctionAAResultsWrapperPass directly depends on BasicAA and always includes it in the aggregation. This has significant implications for preserving analyses. Generally, most passes shouldn't bother preserving FunctionAAResultsWrapperPass because rebuilding the results just updates the set of known AA passes. The exception to this rule are LoopPass instances which need to preserve all the function analyses that the loop pass manager will end up needing. This means preserving both BasicAAWrapperPass and the aggregating FunctionAAResultsWrapperPass. Now, when preserving an alias analysis, you do so by directly preserving that analysis. This is only necessary for non-immutable-pass-provided alias analyses though, and there are only three of interest: BasicAA, GlobalsAA (formerly GlobalsModRef), and SCEVAA. Usually BasicAA is preserved when needed because it (like DominatorTree and LoopInfo) is marked as a CFG-only pass. I've expanded GlobalsAA into the preserved set everywhere we previously were preserving all of AliasAnalysis, and I've added SCEVAA in the intersection of that with where we preserve SCEV itself. One significant challenge to all of this is that the CGSCC passes were actually using the alias analysis implementations by taking advantage of a pretty amazing set of loop holes in the old pass manager's analysis management code which allowed analysis groups to slide through in many cases. Moving away from analysis groups makes this problem much more obvious. To fix it, I've leveraged the flexibility the design of the new PM components provides to just directly construct the relevant alias analyses for the relevant functions in the IPO passes that need them. This is a bit hacky, but should go away with the new pass manager, and is already in many ways cleaner than the prior state. Another significant challenge is that various facilities of the old alias analysis infrastructure just don't fit any more. The most significant of these is the alias analysis 'counter' pass. That pass relied on the ability to snoop on AA queries at different points in the analysis group chain. Instead, I'm planning to build printing functionality directly into the aggregation layer. I've not included that in this patch merely to keep it smaller. Note that all of this needs a nearly complete rewrite of the AA documentation. I'm planning to do that, but I'd like to make sure the new design settles, and to flesh out a bit more of what it looks like in the new pass manager first. Differential Revision: http://reviews.llvm.org/D12080 llvm-svn: 247167
2015-09-10 01:55:00 +08:00
AA = &getAnalysis<AAResultsWrapperPass>().getAAResults();
bool EverMadeChange = false;
while (1) {
bool MadeChange = false;
// Process all basic blocks.
CEBCandidates.clear();
[MachineSink] Improve the compile time by preserving the dominance information as long as possible. ** Context ** Each time the dominance information is modified, the dominator tree analysis switches in a slow query mode. After a few queries without any modification on the dominator tree, it performs an expensive update of its internal structure to provide fast queries again. ** Problem ** Prior to this patch, the MachineSink pass was splitting the critical edges on demand while relying heavy on the dominator tree information. In some cases, this leads to pathological behavior where: - We end up in the slow query mode right after splitting an edge. - We update the dominance information. - We break the dominance information again, thus ending up in the slow query mode and so on. ** Proposed Solution ** To mitigate this effect, this patch postpones all the splitting of the edges at the end of each iteration of the main loop. The benefits are: - The dominance information is valid for the life time of an iteration. - This simplifies the code as we do not have to special treat instructions that are sunk on critical edges. Indeed, the related block will be available through the next iteration. The downside is that when edges splitting is required, this incurs an additional iteration of the main loop compared to the previous scheme. ** Performance ** Thanks to this patch, the motivating example compiles in 6+ minutes instead of 10+ minutes. No test case added as the motivating example as nothing special but being huge! I have measured only noise for both the compile time and the runtime on the llvm test-suite + SPECs with Os and O3. Note: The current implementation of MachineBasicBlock::SplitCriticalEdge also uses the dominance information and therefore, hits this problem. A subsequent patch will address that. <rdar://problem/17894619> llvm-svn: 215410
2014-08-12 07:52:01 +08:00
ToSplit.clear();
for (auto &MBB: MF)
MadeChange |= ProcessBlock(MBB);
[MachineSink] Improve the compile time by preserving the dominance information as long as possible. ** Context ** Each time the dominance information is modified, the dominator tree analysis switches in a slow query mode. After a few queries without any modification on the dominator tree, it performs an expensive update of its internal structure to provide fast queries again. ** Problem ** Prior to this patch, the MachineSink pass was splitting the critical edges on demand while relying heavy on the dominator tree information. In some cases, this leads to pathological behavior where: - We end up in the slow query mode right after splitting an edge. - We update the dominance information. - We break the dominance information again, thus ending up in the slow query mode and so on. ** Proposed Solution ** To mitigate this effect, this patch postpones all the splitting of the edges at the end of each iteration of the main loop. The benefits are: - The dominance information is valid for the life time of an iteration. - This simplifies the code as we do not have to special treat instructions that are sunk on critical edges. Indeed, the related block will be available through the next iteration. The downside is that when edges splitting is required, this incurs an additional iteration of the main loop compared to the previous scheme. ** Performance ** Thanks to this patch, the motivating example compiles in 6+ minutes instead of 10+ minutes. No test case added as the motivating example as nothing special but being huge! I have measured only noise for both the compile time and the runtime on the llvm test-suite + SPECs with Os and O3. Note: The current implementation of MachineBasicBlock::SplitCriticalEdge also uses the dominance information and therefore, hits this problem. A subsequent patch will address that. <rdar://problem/17894619> llvm-svn: 215410
2014-08-12 07:52:01 +08:00
// If we have anything we marked as toSplit, split it now.
for (auto &Pair : ToSplit) {
auto NewSucc = Pair.first->SplitCriticalEdge(Pair.second, this);
if (NewSucc != nullptr) {
DEBUG(dbgs() << " *** Splitting critical edge:"
" BB#" << Pair.first->getNumber()
<< " -- BB#" << NewSucc->getNumber()
<< " -- BB#" << Pair.second->getNumber() << '\n');
MadeChange = true;
++NumSplit;
} else
DEBUG(dbgs() << " *** Not legal to break critical edge\n");
}
// If this iteration over the code changed anything, keep iterating.
if (!MadeChange) break;
EverMadeChange = true;
}
// Now clear any kill flags for recorded registers.
for (auto I : RegsToClearKillFlags)
MRI->clearKillFlags(I);
RegsToClearKillFlags.clear();
return EverMadeChange;
}
bool MachineSinking::ProcessBlock(MachineBasicBlock &MBB) {
// Can't sink anything out of a block that has less than two successors.
if (MBB.succ_size() <= 1 || MBB.empty()) return false;
// Don't bother sinking code out of unreachable blocks. In addition to being
// unprofitable, it can also lead to infinite looping, because in an
// unreachable loop there may be nowhere to stop.
if (!DT->isReachableFromEntry(&MBB)) return false;
bool MadeChange = false;
// Cache all successors, sorted by frequency info and loop depth.
AllSuccsCache AllSuccessors;
// Walk the basic block bottom-up. Remember if we saw a store.
MachineBasicBlock::iterator I = MBB.end();
--I;
bool ProcessedBegin, SawStore = false;
do {
MachineInstr *MI = I; // The instruction to sink.
// Predecrement I (if it's not begin) so that it isn't invalidated by
// sinking.
ProcessedBegin = I == MBB.begin();
if (!ProcessedBegin)
--I;
if (MI->isDebugValue())
continue;
bool Joined = PerformTrivialForwardCoalescing(MI, &MBB);
if (Joined) {
MadeChange = true;
continue;
}
if (SinkInstruction(MI, SawStore, AllSuccessors))
++NumSunk, MadeChange = true;
// If we just processed the first instruction in the block, we're done.
} while (!ProcessedBegin);
return MadeChange;
}
bool MachineSinking::isWorthBreakingCriticalEdge(MachineInstr *MI,
MachineBasicBlock *From,
MachineBasicBlock *To) {
// FIXME: Need much better heuristics.
// If the pass has already considered breaking this edge (during this pass
// through the function), then let's go ahead and break it. This means
// sinking multiple "cheap" instructions into the same block.
if (!CEBCandidates.insert(std::make_pair(From, To)).second)
return true;
if (!MI->isCopy() && !TII->isAsCheapAsAMove(MI))
return true;
// MI is cheap, we probably don't want to break the critical edge for it.
// However, if this would allow some definitions of its source operands
// to be sunk then it's probably worth it.
for (unsigned i = 0, e = MI->getNumOperands(); i != e; ++i) {
const MachineOperand &MO = MI->getOperand(i);
MachineSink: Fix and tweak critical-edge breaking heuristic. Per original comment, the intention of this loop is to go ahead and break the critical edge (in order to sink this instruction) if there's reason to believe doing so might "unblock" the sinking of additional instructions that define registers used by this one. The idea is that if we have a few instructions to sink "together" breaking the edge might be worthwhile. This commit makes a few small changes to help better realize this goal: First, modify the loop to ignore registers defined by this instruction. We don't sink definitions of physical registers, and sinking an SSA definition isn't going to unblock an upstream instruction. Second, ignore uses of physical registers. Instructions that define physical registers are rejected for sinking, and so moving this one won't enable moving any defining instructions. As an added bonus, while virtual register use-def chains are generally small due to SSA goodness, iteration over the uses and definitions (used by hasOneNonDBGUse) for physical registers like EFLAGS can be rather expensive in practice. (This is the original reason for looking at this) Finally, to keep things simple continue to only consider this trick for registers that have a single use (via hasOneNonDBGUse), but to avoid spuriously breaking critical edges only do so if the definition resides in the same MBB and therefore this one directly blocks it from being sunk as well. If sinking them together is meant to be, let the iterative nature of this pass sink the definition into this block first. Update tests to accomodate this change, add new testcase where sinking avoids pipeline stalls. llvm-svn: 192608
2013-10-15 00:57:17 +08:00
if (!MO.isReg() || !MO.isUse())
continue;
unsigned Reg = MO.getReg();
MachineSink: Fix and tweak critical-edge breaking heuristic. Per original comment, the intention of this loop is to go ahead and break the critical edge (in order to sink this instruction) if there's reason to believe doing so might "unblock" the sinking of additional instructions that define registers used by this one. The idea is that if we have a few instructions to sink "together" breaking the edge might be worthwhile. This commit makes a few small changes to help better realize this goal: First, modify the loop to ignore registers defined by this instruction. We don't sink definitions of physical registers, and sinking an SSA definition isn't going to unblock an upstream instruction. Second, ignore uses of physical registers. Instructions that define physical registers are rejected for sinking, and so moving this one won't enable moving any defining instructions. As an added bonus, while virtual register use-def chains are generally small due to SSA goodness, iteration over the uses and definitions (used by hasOneNonDBGUse) for physical registers like EFLAGS can be rather expensive in practice. (This is the original reason for looking at this) Finally, to keep things simple continue to only consider this trick for registers that have a single use (via hasOneNonDBGUse), but to avoid spuriously breaking critical edges only do so if the definition resides in the same MBB and therefore this one directly blocks it from being sunk as well. If sinking them together is meant to be, let the iterative nature of this pass sink the definition into this block first. Update tests to accomodate this change, add new testcase where sinking avoids pipeline stalls. llvm-svn: 192608
2013-10-15 00:57:17 +08:00
if (Reg == 0)
continue;
MachineSink: Fix and tweak critical-edge breaking heuristic. Per original comment, the intention of this loop is to go ahead and break the critical edge (in order to sink this instruction) if there's reason to believe doing so might "unblock" the sinking of additional instructions that define registers used by this one. The idea is that if we have a few instructions to sink "together" breaking the edge might be worthwhile. This commit makes a few small changes to help better realize this goal: First, modify the loop to ignore registers defined by this instruction. We don't sink definitions of physical registers, and sinking an SSA definition isn't going to unblock an upstream instruction. Second, ignore uses of physical registers. Instructions that define physical registers are rejected for sinking, and so moving this one won't enable moving any defining instructions. As an added bonus, while virtual register use-def chains are generally small due to SSA goodness, iteration over the uses and definitions (used by hasOneNonDBGUse) for physical registers like EFLAGS can be rather expensive in practice. (This is the original reason for looking at this) Finally, to keep things simple continue to only consider this trick for registers that have a single use (via hasOneNonDBGUse), but to avoid spuriously breaking critical edges only do so if the definition resides in the same MBB and therefore this one directly blocks it from being sunk as well. If sinking them together is meant to be, let the iterative nature of this pass sink the definition into this block first. Update tests to accomodate this change, add new testcase where sinking avoids pipeline stalls. llvm-svn: 192608
2013-10-15 00:57:17 +08:00
// We don't move live definitions of physical registers,
// so sinking their uses won't enable any opportunities.
if (TargetRegisterInfo::isPhysicalRegister(Reg))
continue;
// If this instruction is the only user of a virtual register,
// check if breaking the edge will enable sinking
// both this instruction and the defining instruction.
if (MRI->hasOneNonDBGUse(Reg)) {
// If the definition resides in same MBB,
// claim it's likely we can sink these together.
// If definition resides elsewhere, we aren't
// blocking it from being sunk so don't break the edge.
MachineInstr *DefMI = MRI->getVRegDef(Reg);
if (DefMI->getParent() == MI->getParent())
return true;
}
}
return false;
}
[MachineSink] Improve the compile time by preserving the dominance information as long as possible. ** Context ** Each time the dominance information is modified, the dominator tree analysis switches in a slow query mode. After a few queries without any modification on the dominator tree, it performs an expensive update of its internal structure to provide fast queries again. ** Problem ** Prior to this patch, the MachineSink pass was splitting the critical edges on demand while relying heavy on the dominator tree information. In some cases, this leads to pathological behavior where: - We end up in the slow query mode right after splitting an edge. - We update the dominance information. - We break the dominance information again, thus ending up in the slow query mode and so on. ** Proposed Solution ** To mitigate this effect, this patch postpones all the splitting of the edges at the end of each iteration of the main loop. The benefits are: - The dominance information is valid for the life time of an iteration. - This simplifies the code as we do not have to special treat instructions that are sunk on critical edges. Indeed, the related block will be available through the next iteration. The downside is that when edges splitting is required, this incurs an additional iteration of the main loop compared to the previous scheme. ** Performance ** Thanks to this patch, the motivating example compiles in 6+ minutes instead of 10+ minutes. No test case added as the motivating example as nothing special but being huge! I have measured only noise for both the compile time and the runtime on the llvm test-suite + SPECs with Os and O3. Note: The current implementation of MachineBasicBlock::SplitCriticalEdge also uses the dominance information and therefore, hits this problem. A subsequent patch will address that. <rdar://problem/17894619> llvm-svn: 215410
2014-08-12 07:52:01 +08:00
bool MachineSinking::PostponeSplitCriticalEdge(MachineInstr *MI,
MachineBasicBlock *FromBB,
MachineBasicBlock *ToBB,
bool BreakPHIEdge) {
if (!isWorthBreakingCriticalEdge(MI, FromBB, ToBB))
[MachineSink] Improve the compile time by preserving the dominance information as long as possible. ** Context ** Each time the dominance information is modified, the dominator tree analysis switches in a slow query mode. After a few queries without any modification on the dominator tree, it performs an expensive update of its internal structure to provide fast queries again. ** Problem ** Prior to this patch, the MachineSink pass was splitting the critical edges on demand while relying heavy on the dominator tree information. In some cases, this leads to pathological behavior where: - We end up in the slow query mode right after splitting an edge. - We update the dominance information. - We break the dominance information again, thus ending up in the slow query mode and so on. ** Proposed Solution ** To mitigate this effect, this patch postpones all the splitting of the edges at the end of each iteration of the main loop. The benefits are: - The dominance information is valid for the life time of an iteration. - This simplifies the code as we do not have to special treat instructions that are sunk on critical edges. Indeed, the related block will be available through the next iteration. The downside is that when edges splitting is required, this incurs an additional iteration of the main loop compared to the previous scheme. ** Performance ** Thanks to this patch, the motivating example compiles in 6+ minutes instead of 10+ minutes. No test case added as the motivating example as nothing special but being huge! I have measured only noise for both the compile time and the runtime on the llvm test-suite + SPECs with Os and O3. Note: The current implementation of MachineBasicBlock::SplitCriticalEdge also uses the dominance information and therefore, hits this problem. A subsequent patch will address that. <rdar://problem/17894619> llvm-svn: 215410
2014-08-12 07:52:01 +08:00
return false;
// Avoid breaking back edge. From == To means backedge for single BB loop.
if (!SplitEdges || FromBB == ToBB)
[MachineSink] Improve the compile time by preserving the dominance information as long as possible. ** Context ** Each time the dominance information is modified, the dominator tree analysis switches in a slow query mode. After a few queries without any modification on the dominator tree, it performs an expensive update of its internal structure to provide fast queries again. ** Problem ** Prior to this patch, the MachineSink pass was splitting the critical edges on demand while relying heavy on the dominator tree information. In some cases, this leads to pathological behavior where: - We end up in the slow query mode right after splitting an edge. - We update the dominance information. - We break the dominance information again, thus ending up in the slow query mode and so on. ** Proposed Solution ** To mitigate this effect, this patch postpones all the splitting of the edges at the end of each iteration of the main loop. The benefits are: - The dominance information is valid for the life time of an iteration. - This simplifies the code as we do not have to special treat instructions that are sunk on critical edges. Indeed, the related block will be available through the next iteration. The downside is that when edges splitting is required, this incurs an additional iteration of the main loop compared to the previous scheme. ** Performance ** Thanks to this patch, the motivating example compiles in 6+ minutes instead of 10+ minutes. No test case added as the motivating example as nothing special but being huge! I have measured only noise for both the compile time and the runtime on the llvm test-suite + SPECs with Os and O3. Note: The current implementation of MachineBasicBlock::SplitCriticalEdge also uses the dominance information and therefore, hits this problem. A subsequent patch will address that. <rdar://problem/17894619> llvm-svn: 215410
2014-08-12 07:52:01 +08:00
return false;
// Check for backedges of more "complex" loops.
if (LI->getLoopFor(FromBB) == LI->getLoopFor(ToBB) &&
LI->isLoopHeader(ToBB))
[MachineSink] Improve the compile time by preserving the dominance information as long as possible. ** Context ** Each time the dominance information is modified, the dominator tree analysis switches in a slow query mode. After a few queries without any modification on the dominator tree, it performs an expensive update of its internal structure to provide fast queries again. ** Problem ** Prior to this patch, the MachineSink pass was splitting the critical edges on demand while relying heavy on the dominator tree information. In some cases, this leads to pathological behavior where: - We end up in the slow query mode right after splitting an edge. - We update the dominance information. - We break the dominance information again, thus ending up in the slow query mode and so on. ** Proposed Solution ** To mitigate this effect, this patch postpones all the splitting of the edges at the end of each iteration of the main loop. The benefits are: - The dominance information is valid for the life time of an iteration. - This simplifies the code as we do not have to special treat instructions that are sunk on critical edges. Indeed, the related block will be available through the next iteration. The downside is that when edges splitting is required, this incurs an additional iteration of the main loop compared to the previous scheme. ** Performance ** Thanks to this patch, the motivating example compiles in 6+ minutes instead of 10+ minutes. No test case added as the motivating example as nothing special but being huge! I have measured only noise for both the compile time and the runtime on the llvm test-suite + SPECs with Os and O3. Note: The current implementation of MachineBasicBlock::SplitCriticalEdge also uses the dominance information and therefore, hits this problem. A subsequent patch will address that. <rdar://problem/17894619> llvm-svn: 215410
2014-08-12 07:52:01 +08:00
return false;
// It's not always legal to break critical edges and sink the computation
// to the edge.
//
// BB#1:
// v1024
// Beq BB#3
// <fallthrough>
// BB#2:
// ... no uses of v1024
// <fallthrough>
// BB#3:
// ...
// = v1024
//
// If BB#1 -> BB#3 edge is broken and computation of v1024 is inserted:
//
// BB#1:
// ...
// Bne BB#2
// BB#4:
// v1024 =
// B BB#3
// BB#2:
// ... no uses of v1024
// <fallthrough>
// BB#3:
// ...
// = v1024
//
// This is incorrect since v1024 is not computed along the BB#1->BB#2->BB#3
// flow. We need to ensure the new basic block where the computation is
// sunk to dominates all the uses.
// It's only legal to break critical edge and sink the computation to the
// new block if all the predecessors of "To", except for "From", are
// not dominated by "From". Given SSA property, this means these
// predecessors are dominated by "To".
//
// There is no need to do this check if all the uses are PHI nodes. PHI
// sources are only defined on the specific predecessor edges.
if (!BreakPHIEdge) {
for (MachineBasicBlock::pred_iterator PI = ToBB->pred_begin(),
E = ToBB->pred_end(); PI != E; ++PI) {
if (*PI == FromBB)
continue;
if (!DT->dominates(ToBB, *PI))
[MachineSink] Improve the compile time by preserving the dominance information as long as possible. ** Context ** Each time the dominance information is modified, the dominator tree analysis switches in a slow query mode. After a few queries without any modification on the dominator tree, it performs an expensive update of its internal structure to provide fast queries again. ** Problem ** Prior to this patch, the MachineSink pass was splitting the critical edges on demand while relying heavy on the dominator tree information. In some cases, this leads to pathological behavior where: - We end up in the slow query mode right after splitting an edge. - We update the dominance information. - We break the dominance information again, thus ending up in the slow query mode and so on. ** Proposed Solution ** To mitigate this effect, this patch postpones all the splitting of the edges at the end of each iteration of the main loop. The benefits are: - The dominance information is valid for the life time of an iteration. - This simplifies the code as we do not have to special treat instructions that are sunk on critical edges. Indeed, the related block will be available through the next iteration. The downside is that when edges splitting is required, this incurs an additional iteration of the main loop compared to the previous scheme. ** Performance ** Thanks to this patch, the motivating example compiles in 6+ minutes instead of 10+ minutes. No test case added as the motivating example as nothing special but being huge! I have measured only noise for both the compile time and the runtime on the llvm test-suite + SPECs with Os and O3. Note: The current implementation of MachineBasicBlock::SplitCriticalEdge also uses the dominance information and therefore, hits this problem. A subsequent patch will address that. <rdar://problem/17894619> llvm-svn: 215410
2014-08-12 07:52:01 +08:00
return false;
}
}
[MachineSink] Improve the compile time by preserving the dominance information as long as possible. ** Context ** Each time the dominance information is modified, the dominator tree analysis switches in a slow query mode. After a few queries without any modification on the dominator tree, it performs an expensive update of its internal structure to provide fast queries again. ** Problem ** Prior to this patch, the MachineSink pass was splitting the critical edges on demand while relying heavy on the dominator tree information. In some cases, this leads to pathological behavior where: - We end up in the slow query mode right after splitting an edge. - We update the dominance information. - We break the dominance information again, thus ending up in the slow query mode and so on. ** Proposed Solution ** To mitigate this effect, this patch postpones all the splitting of the edges at the end of each iteration of the main loop. The benefits are: - The dominance information is valid for the life time of an iteration. - This simplifies the code as we do not have to special treat instructions that are sunk on critical edges. Indeed, the related block will be available through the next iteration. The downside is that when edges splitting is required, this incurs an additional iteration of the main loop compared to the previous scheme. ** Performance ** Thanks to this patch, the motivating example compiles in 6+ minutes instead of 10+ minutes. No test case added as the motivating example as nothing special but being huge! I have measured only noise for both the compile time and the runtime on the llvm test-suite + SPECs with Os and O3. Note: The current implementation of MachineBasicBlock::SplitCriticalEdge also uses the dominance information and therefore, hits this problem. A subsequent patch will address that. <rdar://problem/17894619> llvm-svn: 215410
2014-08-12 07:52:01 +08:00
ToSplit.insert(std::make_pair(FromBB, ToBB));
return true;
}
static bool AvoidsSinking(MachineInstr *MI, MachineRegisterInfo *MRI) {
return MI->isInsertSubreg() || MI->isSubregToReg() || MI->isRegSequence();
}
2012-02-09 05:22:43 +08:00
/// collectDebgValues - Scan instructions following MI and collect any
/// matching DBG_VALUEs.
2012-02-09 05:22:43 +08:00
static void collectDebugValues(MachineInstr *MI,
SmallVectorImpl<MachineInstr *> &DbgValues) {
DbgValues.clear();
if (!MI->getOperand(0).isReg())
return;
MachineBasicBlock::iterator DI = MI; ++DI;
for (MachineBasicBlock::iterator DE = MI->getParent()->end();
DI != DE; ++DI) {
if (!DI->isDebugValue())
return;
if (DI->getOperand(0).isReg() &&
DI->getOperand(0).getReg() == MI->getOperand(0).getReg())
DbgValues.push_back(DI);
}
}
/// isProfitableToSinkTo - Return true if it is profitable to sink MI.
2012-02-09 05:22:43 +08:00
bool MachineSinking::isProfitableToSinkTo(unsigned Reg, MachineInstr *MI,
MachineBasicBlock *MBB,
MachineBasicBlock *SuccToSinkTo,
AllSuccsCache &AllSuccessors) {
assert (MI && "Invalid MachineInstr!");
assert (SuccToSinkTo && "Invalid SinkTo Candidate BB");
if (MBB == SuccToSinkTo)
return false;
// It is profitable if SuccToSinkTo does not post dominate current block.
if (!PDT->dominates(SuccToSinkTo, MBB))
return true;
// It is profitable to sink an instruction from a deeper loop to a shallower
// loop, even if the latter post-dominates the former (PR21115).
if (LI->getLoopDepth(MBB) > LI->getLoopDepth(SuccToSinkTo))
return true;
// Check if only use in post dominated block is PHI instruction.
bool NonPHIUse = false;
for (MachineInstr &UseInst : MRI->use_nodbg_instructions(Reg)) {
MachineBasicBlock *UseBlock = UseInst.getParent();
if (UseBlock == SuccToSinkTo && !UseInst.isPHI())
NonPHIUse = true;
}
if (!NonPHIUse)
return true;
// If SuccToSinkTo post dominates then also it may be profitable if MI
// can further profitably sinked into another block in next round.
bool BreakPHIEdge = false;
// FIXME - If finding successor is compile time expensive then cache results.
if (MachineBasicBlock *MBB2 =
FindSuccToSinkTo(MI, SuccToSinkTo, BreakPHIEdge, AllSuccessors))
return isProfitableToSinkTo(Reg, MI, SuccToSinkTo, MBB2, AllSuccessors);
// If SuccToSinkTo is final destination and it is a post dominator of current
// block then it is not profitable to sink MI into SuccToSinkTo block.
return false;
}
/// Get the sorted sequence of successors for this MachineBasicBlock, possibly
/// computing it if it was not already cached.
SmallVector<MachineBasicBlock *, 4> &
MachineSinking::GetAllSortedSuccessors(MachineInstr *MI, MachineBasicBlock *MBB,
AllSuccsCache &AllSuccessors) const {
// Do we have the sorted successors in cache ?
auto Succs = AllSuccessors.find(MBB);
if (Succs != AllSuccessors.end())
return Succs->second;
SmallVector<MachineBasicBlock *, 4> AllSuccs(MBB->succ_begin(),
MBB->succ_end());
// Handle cases where sinking can happen but where the sink point isn't a
// successor. For example:
//
// x = computation
// if () {} else {}
// use x
//
const std::vector<MachineDomTreeNode *> &Children =
DT->getNode(MBB)->getChildren();
for (const auto &DTChild : Children)
// DomTree children of MBB that have MBB as immediate dominator are added.
if (DTChild->getIDom()->getBlock() == MI->getParent() &&
// Skip MBBs already added to the AllSuccs vector above.
!MBB->isSuccessor(DTChild->getBlock()))
AllSuccs.push_back(DTChild->getBlock());
// Sort Successors according to their loop depth or block frequency info.
std::stable_sort(
AllSuccs.begin(), AllSuccs.end(),
[this](const MachineBasicBlock *L, const MachineBasicBlock *R) {
uint64_t LHSFreq = MBFI ? MBFI->getBlockFreq(L).getFrequency() : 0;
uint64_t RHSFreq = MBFI ? MBFI->getBlockFreq(R).getFrequency() : 0;
bool HasBlockFreq = LHSFreq != 0 && RHSFreq != 0;
return HasBlockFreq ? LHSFreq < RHSFreq
: LI->getLoopDepth(L) < LI->getLoopDepth(R);
});
auto it = AllSuccessors.insert(std::make_pair(MBB, AllSuccs));
return it.first->second;
}
/// FindSuccToSinkTo - Find a successor to sink this instruction to.
MachineBasicBlock *MachineSinking::FindSuccToSinkTo(MachineInstr *MI,
MachineBasicBlock *MBB,
bool &BreakPHIEdge,
AllSuccsCache &AllSuccessors) {
assert (MI && "Invalid MachineInstr!");
assert (MBB && "Invalid MachineBasicBlock!");
// Loop over all the operands of the specified instruction. If there is
// anything we can't handle, bail out.
// SuccToSinkTo - This is the successor to sink this instruction to, once we
// decide.
MachineBasicBlock *SuccToSinkTo = nullptr;
for (unsigned i = 0, e = MI->getNumOperands(); i != e; ++i) {
const MachineOperand &MO = MI->getOperand(i);
if (!MO.isReg()) continue; // Ignore non-register operands.
unsigned Reg = MO.getReg();
if (Reg == 0) continue;
if (TargetRegisterInfo::isPhysicalRegister(Reg)) {
if (MO.isUse()) {
// If the physreg has no defs anywhere, it's just an ambient register
// and we can freely move its uses. Alternatively, if it's allocatable,
// it could get allocated to something with a def during allocation.
if (!MRI->isConstantPhysReg(Reg, *MBB->getParent()))
return nullptr;
} else if (!MO.isDead()) {
// A def that isn't dead. We can't move it.
return nullptr;
}
} else {
// Virtual register uses are always safe to sink.
if (MO.isUse()) continue;
// If it's not safe to move defs of the register class, then abort.
if (!TII->isSafeToMoveRegClassDefs(MRI->getRegClass(Reg)))
return nullptr;
// Virtual register defs can only be sunk if all their uses are in blocks
// dominated by one of the successors.
if (SuccToSinkTo) {
// If a previous operand picked a block to sink to, then this operand
// must be sinkable to the same block.
bool LocalUse = false;
if (!AllUsesDominatedByBlock(Reg, SuccToSinkTo, MBB,
BreakPHIEdge, LocalUse))
return nullptr;
continue;
}
// Otherwise, we should look at all the successors and decide which one
// we should sink to. If we have reliable block frequency information
// (frequency != 0) available, give successors with smaller frequencies
// higher priority, otherwise prioritize smaller loop depths.
for (MachineBasicBlock *SuccBlock :
GetAllSortedSuccessors(MI, MBB, AllSuccessors)) {
bool LocalUse = false;
if (AllUsesDominatedByBlock(Reg, SuccBlock, MBB,
BreakPHIEdge, LocalUse)) {
SuccToSinkTo = SuccBlock;
break;
}
if (LocalUse)
// Def is used locally, it's never safe to move this def.
return nullptr;
}
// If we couldn't find a block to sink to, ignore this instruction.
if (!SuccToSinkTo)
return nullptr;
if (!isProfitableToSinkTo(Reg, MI, MBB, SuccToSinkTo, AllSuccessors))
return nullptr;
}
}
// It is not possible to sink an instruction into its own block. This can
// happen with loops.
if (MBB == SuccToSinkTo)
return nullptr;
// It's not safe to sink instructions to EH landing pad. Control flow into
// landing pad is implicitly defined.
if (SuccToSinkTo && SuccToSinkTo->isEHPad())
return nullptr;
return SuccToSinkTo;
}
/// \brief Return true if MI is likely to be usable as a memory operation by the
/// implicit null check optimization.
///
/// This is a "best effort" heuristic, and should not be relied upon for
/// correctness. This returning true does not guarantee that the implicit null
/// check optimization is legal over MI, and this returning false does not
/// guarantee MI cannot possibly be used to do a null check.
static bool SinkingPreventsImplicitNullCheck(MachineInstr *MI,
const TargetInstrInfo *TII,
const TargetRegisterInfo *TRI) {
typedef TargetInstrInfo::MachineBranchPredicate MachineBranchPredicate;
auto *MBB = MI->getParent();
if (MBB->pred_size() != 1)
return false;
auto *PredMBB = *MBB->pred_begin();
auto *PredBB = PredMBB->getBasicBlock();
// Frontends that don't use implicit null checks have no reason to emit
// branches with make.implicit metadata, and this function should always
// return false for them.
if (!PredBB ||
!PredBB->getTerminator()->getMetadata(LLVMContext::MD_make_implicit))
return false;
unsigned BaseReg, Offset;
if (!TII->getMemOpBaseRegImmOfs(MI, BaseReg, Offset, TRI))
return false;
if (!(MI->mayLoad() && !MI->isPredicable()))
return false;
MachineBranchPredicate MBP;
if (TII->AnalyzeBranchPredicate(*PredMBB, MBP, false))
return false;
return MBP.LHS.isReg() && MBP.RHS.isImm() && MBP.RHS.getImm() == 0 &&
(MBP.Predicate == MachineBranchPredicate::PRED_NE ||
MBP.Predicate == MachineBranchPredicate::PRED_EQ) &&
MBP.LHS.getReg() == BaseReg;
}
/// SinkInstruction - Determine whether it is safe to sink the specified machine
/// instruction out of its current block into a successor.
bool MachineSinking::SinkInstruction(MachineInstr *MI, bool &SawStore,
AllSuccsCache &AllSuccessors) {
// Don't sink insert_subreg, subreg_to_reg, reg_sequence. These are meant to
// be close to the source to make it easier to coalesce.
if (AvoidsSinking(MI, MRI))
return false;
// Check if it's safe to move the instruction.
if (!MI->isSafeToMove(AA, SawStore))
return false;
// Convergent operations may not be made control-dependent on additional
// values.
if (MI->isConvergent())
return false;
// Don't break implicit null checks. This is a performance heuristic, and not
// required for correctness.
if (SinkingPreventsImplicitNullCheck(MI, TII, TRI))
return false;
// FIXME: This should include support for sinking instructions within the
// block they are currently in to shorten the live ranges. We often get
// instructions sunk into the top of a large block, but it would be better to
// also sink them down before their first use in the block. This xform has to
// be careful not to *increase* register pressure though, e.g. sinking
// "x = y + z" down if it kills y and z would increase the live ranges of y
// and z and only shrink the live range of x.
bool BreakPHIEdge = false;
MachineBasicBlock *ParentBlock = MI->getParent();
MachineBasicBlock *SuccToSinkTo =
FindSuccToSinkTo(MI, ParentBlock, BreakPHIEdge, AllSuccessors);
2008-01-05 09:39:17 +08:00
// If there are no outputs, it must have side-effects.
if (!SuccToSinkTo)
2008-01-05 09:39:17 +08:00
return false;
// If the instruction to move defines a dead physical register which is live
// when leaving the basic block, don't move it because it could turn into a
// "zombie" define of that preg. E.g., EFLAGS. (<rdar://problem/8030636>)
for (unsigned I = 0, E = MI->getNumOperands(); I != E; ++I) {
const MachineOperand &MO = MI->getOperand(I);
if (!MO.isReg()) continue;
unsigned Reg = MO.getReg();
if (Reg == 0 || !TargetRegisterInfo::isPhysicalRegister(Reg)) continue;
if (SuccToSinkTo->isLiveIn(Reg))
return false;
}
DEBUG(dbgs() << "Sink instr " << *MI << "\tinto block " << *SuccToSinkTo);
MachineSink: Fix and tweak critical-edge breaking heuristic. Per original comment, the intention of this loop is to go ahead and break the critical edge (in order to sink this instruction) if there's reason to believe doing so might "unblock" the sinking of additional instructions that define registers used by this one. The idea is that if we have a few instructions to sink "together" breaking the edge might be worthwhile. This commit makes a few small changes to help better realize this goal: First, modify the loop to ignore registers defined by this instruction. We don't sink definitions of physical registers, and sinking an SSA definition isn't going to unblock an upstream instruction. Second, ignore uses of physical registers. Instructions that define physical registers are rejected for sinking, and so moving this one won't enable moving any defining instructions. As an added bonus, while virtual register use-def chains are generally small due to SSA goodness, iteration over the uses and definitions (used by hasOneNonDBGUse) for physical registers like EFLAGS can be rather expensive in practice. (This is the original reason for looking at this) Finally, to keep things simple continue to only consider this trick for registers that have a single use (via hasOneNonDBGUse), but to avoid spuriously breaking critical edges only do so if the definition resides in the same MBB and therefore this one directly blocks it from being sunk as well. If sinking them together is meant to be, let the iterative nature of this pass sink the definition into this block first. Update tests to accomodate this change, add new testcase where sinking avoids pipeline stalls. llvm-svn: 192608
2013-10-15 00:57:17 +08:00
// If the block has multiple predecessors, this is a critical edge.
// Decide if we can sink along it or need to break the edge.
if (SuccToSinkTo->pred_size() > 1) {
// We cannot sink a load across a critical edge - there may be stores in
// other code paths.
bool TryBreak = false;
bool store = true;
if (!MI->isSafeToMove(AA, store)) {
2010-08-20 07:33:02 +08:00
DEBUG(dbgs() << " *** NOTE: Won't sink load along critical edge.\n");
TryBreak = true;
}
// We don't want to sink across a critical edge if we don't dominate the
// successor. We could be introducing calculations to new code paths.
if (!TryBreak && !DT->dominates(ParentBlock, SuccToSinkTo)) {
2010-08-20 07:33:02 +08:00
DEBUG(dbgs() << " *** NOTE: Critical edge found\n");
TryBreak = true;
}
// Don't sink instructions into a loop.
if (!TryBreak && LI->isLoopHeader(SuccToSinkTo)) {
2010-08-20 07:33:02 +08:00
DEBUG(dbgs() << " *** NOTE: Loop header found\n");
TryBreak = true;
}
// Otherwise we are OK with sinking along a critical edge.
if (!TryBreak)
DEBUG(dbgs() << "Sinking along critical edge.\n");
else {
[MachineSink] Improve the compile time by preserving the dominance information as long as possible. ** Context ** Each time the dominance information is modified, the dominator tree analysis switches in a slow query mode. After a few queries without any modification on the dominator tree, it performs an expensive update of its internal structure to provide fast queries again. ** Problem ** Prior to this patch, the MachineSink pass was splitting the critical edges on demand while relying heavy on the dominator tree information. In some cases, this leads to pathological behavior where: - We end up in the slow query mode right after splitting an edge. - We update the dominance information. - We break the dominance information again, thus ending up in the slow query mode and so on. ** Proposed Solution ** To mitigate this effect, this patch postpones all the splitting of the edges at the end of each iteration of the main loop. The benefits are: - The dominance information is valid for the life time of an iteration. - This simplifies the code as we do not have to special treat instructions that are sunk on critical edges. Indeed, the related block will be available through the next iteration. The downside is that when edges splitting is required, this incurs an additional iteration of the main loop compared to the previous scheme. ** Performance ** Thanks to this patch, the motivating example compiles in 6+ minutes instead of 10+ minutes. No test case added as the motivating example as nothing special but being huge! I have measured only noise for both the compile time and the runtime on the llvm test-suite + SPECs with Os and O3. Note: The current implementation of MachineBasicBlock::SplitCriticalEdge also uses the dominance information and therefore, hits this problem. A subsequent patch will address that. <rdar://problem/17894619> llvm-svn: 215410
2014-08-12 07:52:01 +08:00
// Mark this edge as to be split.
// If the edge can actually be split, the next iteration of the main loop
// will sink MI in the newly created block.
bool Status =
PostponeSplitCriticalEdge(MI, ParentBlock, SuccToSinkTo, BreakPHIEdge);
if (!Status)
DEBUG(dbgs() << " *** PUNTING: Not legal or profitable to "
[MachineSink] Improve the compile time by preserving the dominance information as long as possible. ** Context ** Each time the dominance information is modified, the dominator tree analysis switches in a slow query mode. After a few queries without any modification on the dominator tree, it performs an expensive update of its internal structure to provide fast queries again. ** Problem ** Prior to this patch, the MachineSink pass was splitting the critical edges on demand while relying heavy on the dominator tree information. In some cases, this leads to pathological behavior where: - We end up in the slow query mode right after splitting an edge. - We update the dominance information. - We break the dominance information again, thus ending up in the slow query mode and so on. ** Proposed Solution ** To mitigate this effect, this patch postpones all the splitting of the edges at the end of each iteration of the main loop. The benefits are: - The dominance information is valid for the life time of an iteration. - This simplifies the code as we do not have to special treat instructions that are sunk on critical edges. Indeed, the related block will be available through the next iteration. The downside is that when edges splitting is required, this incurs an additional iteration of the main loop compared to the previous scheme. ** Performance ** Thanks to this patch, the motivating example compiles in 6+ minutes instead of 10+ minutes. No test case added as the motivating example as nothing special but being huge! I have measured only noise for both the compile time and the runtime on the llvm test-suite + SPECs with Os and O3. Note: The current implementation of MachineBasicBlock::SplitCriticalEdge also uses the dominance information and therefore, hits this problem. A subsequent patch will address that. <rdar://problem/17894619> llvm-svn: 215410
2014-08-12 07:52:01 +08:00
"break critical edge\n");
// The instruction will not be sunk this time.
return false;
}
}
if (BreakPHIEdge) {
// BreakPHIEdge is true if all the uses are in the successor MBB being
// sunken into and they are all PHI nodes. In this case, machine-sink must
// break the critical edge first.
[MachineSink] Improve the compile time by preserving the dominance information as long as possible. ** Context ** Each time the dominance information is modified, the dominator tree analysis switches in a slow query mode. After a few queries without any modification on the dominator tree, it performs an expensive update of its internal structure to provide fast queries again. ** Problem ** Prior to this patch, the MachineSink pass was splitting the critical edges on demand while relying heavy on the dominator tree information. In some cases, this leads to pathological behavior where: - We end up in the slow query mode right after splitting an edge. - We update the dominance information. - We break the dominance information again, thus ending up in the slow query mode and so on. ** Proposed Solution ** To mitigate this effect, this patch postpones all the splitting of the edges at the end of each iteration of the main loop. The benefits are: - The dominance information is valid for the life time of an iteration. - This simplifies the code as we do not have to special treat instructions that are sunk on critical edges. Indeed, the related block will be available through the next iteration. The downside is that when edges splitting is required, this incurs an additional iteration of the main loop compared to the previous scheme. ** Performance ** Thanks to this patch, the motivating example compiles in 6+ minutes instead of 10+ minutes. No test case added as the motivating example as nothing special but being huge! I have measured only noise for both the compile time and the runtime on the llvm test-suite + SPECs with Os and O3. Note: The current implementation of MachineBasicBlock::SplitCriticalEdge also uses the dominance information and therefore, hits this problem. A subsequent patch will address that. <rdar://problem/17894619> llvm-svn: 215410
2014-08-12 07:52:01 +08:00
bool Status = PostponeSplitCriticalEdge(MI, ParentBlock,
SuccToSinkTo, BreakPHIEdge);
if (!Status)
DEBUG(dbgs() << " *** PUNTING: Not legal or profitable to "
"break critical edge\n");
[MachineSink] Improve the compile time by preserving the dominance information as long as possible. ** Context ** Each time the dominance information is modified, the dominator tree analysis switches in a slow query mode. After a few queries without any modification on the dominator tree, it performs an expensive update of its internal structure to provide fast queries again. ** Problem ** Prior to this patch, the MachineSink pass was splitting the critical edges on demand while relying heavy on the dominator tree information. In some cases, this leads to pathological behavior where: - We end up in the slow query mode right after splitting an edge. - We update the dominance information. - We break the dominance information again, thus ending up in the slow query mode and so on. ** Proposed Solution ** To mitigate this effect, this patch postpones all the splitting of the edges at the end of each iteration of the main loop. The benefits are: - The dominance information is valid for the life time of an iteration. - This simplifies the code as we do not have to special treat instructions that are sunk on critical edges. Indeed, the related block will be available through the next iteration. The downside is that when edges splitting is required, this incurs an additional iteration of the main loop compared to the previous scheme. ** Performance ** Thanks to this patch, the motivating example compiles in 6+ minutes instead of 10+ minutes. No test case added as the motivating example as nothing special but being huge! I have measured only noise for both the compile time and the runtime on the llvm test-suite + SPECs with Os and O3. Note: The current implementation of MachineBasicBlock::SplitCriticalEdge also uses the dominance information and therefore, hits this problem. A subsequent patch will address that. <rdar://problem/17894619> llvm-svn: 215410
2014-08-12 07:52:01 +08:00
// The instruction will not be sunk this time.
return false;
}
// Determine where to insert into. Skip phi nodes.
MachineBasicBlock::iterator InsertPos = SuccToSinkTo->begin();
while (InsertPos != SuccToSinkTo->end() && InsertPos->isPHI())
++InsertPos;
// collect matching debug values.
SmallVector<MachineInstr *, 2> DbgValuesToSink;
collectDebugValues(MI, DbgValuesToSink);
// Move the instruction.
SuccToSinkTo->splice(InsertPos, ParentBlock, MI,
++MachineBasicBlock::iterator(MI));
// Move debug values.
for (SmallVectorImpl<MachineInstr *>::iterator DBI = DbgValuesToSink.begin(),
DBE = DbgValuesToSink.end(); DBI != DBE; ++DBI) {
MachineInstr *DbgMI = *DBI;
SuccToSinkTo->splice(InsertPos, ParentBlock, DbgMI,
++MachineBasicBlock::iterator(DbgMI));
}
// Conservatively, clear any kill flags, since it's possible that they are no
// longer correct.
// Note that we have to clear the kill flags for any register this instruction
// uses as we may sink over another instruction which currently kills the
// used registers.
for (MachineOperand &MO : MI->operands()) {
if (MO.isReg() && MO.isUse())
RegsToClearKillFlags.set(MO.getReg()); // Remember to clear kill flags.
}
return true;
}