forked from OSchip/llvm-project
88a7a2eac7
The SystemZ linkers provide an optimization to transform a general- or local-dynamic TLS sequence into an initial-exec sequence if possible. Do do that, the compiler generates a function call to __tls_get_offset, which is a brasl instruction annotated with *two* relocations: - a R_390_PLT32DBL to install __tls_get_offset as branch target - a R_390_TLS_GDCALL / R_390_TLS_LDCALL to inform the linker that the TLS optimization should be performed if possible If the optimization is performed, the brasl is replaced by an ld load instruction. However, *both* relocs are processed independently by the linker. Therefore it is crucial that the R_390_PLT32DBL is processed *first* (installing the branch target for the brasl) and the R_390_TLS_GDCALL is processed *second* (replacing the whole brasl with an ld). If the relocs are swapped, the linker will first replace the brasl with an ld, and *then* install the __tls_get_offset branch target offset. Since ld has a different layout than brasl, this may even result in a completely different (or invalid) instruction; in any case, the resulting code is corrupted. Unfortunately, the way the MC common code sorts relocations causes these two to *always* end up the wrong way around, resulting in wrong code generation by the linker and crashes. This patch overrides the sortRelocs routine to detect this particular pair of relocs and enforce the required order. llvm-svn: 255787 |
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|---|---|---|
| .. | ||
| AsmParser | ||
| Disassembler | ||
| InstPrinter | ||
| MCTargetDesc | ||
| TargetInfo | ||
| CMakeLists.txt | ||
| LLVMBuild.txt | ||
| Makefile | ||
| README.txt | ||
| SystemZ.h | ||
| SystemZ.td | ||
| SystemZAsmPrinter.cpp | ||
| SystemZAsmPrinter.h | ||
| SystemZCallingConv.cpp | ||
| SystemZCallingConv.h | ||
| SystemZCallingConv.td | ||
| SystemZConstantPoolValue.cpp | ||
| SystemZConstantPoolValue.h | ||
| SystemZElimCompare.cpp | ||
| SystemZFrameLowering.cpp | ||
| SystemZFrameLowering.h | ||
| SystemZISelDAGToDAG.cpp | ||
| SystemZISelLowering.cpp | ||
| SystemZISelLowering.h | ||
| SystemZInstrBuilder.h | ||
| SystemZInstrFP.td | ||
| SystemZInstrFormats.td | ||
| SystemZInstrInfo.cpp | ||
| SystemZInstrInfo.h | ||
| SystemZInstrInfo.td | ||
| SystemZInstrVector.td | ||
| SystemZLDCleanup.cpp | ||
| SystemZLongBranch.cpp | ||
| SystemZMCInstLower.cpp | ||
| SystemZMCInstLower.h | ||
| SystemZMachineFunctionInfo.cpp | ||
| SystemZMachineFunctionInfo.h | ||
| SystemZOperands.td | ||
| SystemZOperators.td | ||
| SystemZPatterns.td | ||
| SystemZProcessors.td | ||
| SystemZRegisterInfo.cpp | ||
| SystemZRegisterInfo.h | ||
| SystemZRegisterInfo.td | ||
| SystemZSelectionDAGInfo.cpp | ||
| SystemZSelectionDAGInfo.h | ||
| SystemZShortenInst.cpp | ||
| SystemZSubtarget.cpp | ||
| SystemZSubtarget.h | ||
| SystemZTargetMachine.cpp | ||
| SystemZTargetMachine.h | ||
| SystemZTargetTransformInfo.cpp | ||
| SystemZTargetTransformInfo.h | ||
README.txt
//===---------------------------------------------------------------------===//
// Random notes about and ideas for the SystemZ backend.
//===---------------------------------------------------------------------===//
The initial backend is deliberately restricted to z10. We should add support
for later architectures at some point.
--
SystemZDAGToDAGISel::SelectInlineAsmMemoryOperand() is passed "m" for all
inline asm memory constraints; it doesn't get to see the original constraint.
This means that it must conservatively treat all inline asm constraints
as the most restricted type, "R".
--
If an inline asm ties an i32 "r" result to an i64 input, the input
will be treated as an i32, leaving the upper bits uninitialised.
For example:
define void @f4(i32 *%dst) {
%val = call i32 asm "blah $0", "=r,0" (i64 103)
store i32 %val, i32 *%dst
ret void
}
from CodeGen/SystemZ/asm-09.ll will use LHI rather than LGHI.
to load 103. This seems to be a general target-independent problem.
--
The tuning of the choice between LOAD ADDRESS (LA) and addition in
SystemZISelDAGToDAG.cpp is suspect. It should be tweaked based on
performance measurements.
--
There is no scheduling support.
--
We don't use the BRANCH ON INDEX instructions.
--
We might want to use BRANCH ON CONDITION for conditional indirect calls
and conditional returns.
--
We don't use the TEST DATA CLASS instructions.
--
We only use MVC, XC and CLC for constant-length block operations.
We could extend them to variable-length operations too,
using EXECUTE RELATIVE LONG.
MVCIN, MVCLE and CLCLE may be worthwhile too.
--
We don't use CUSE or the TRANSLATE family of instructions for string
operations. The TRANSLATE ones are probably more difficult to exploit.
--
We don't take full advantage of builtins like fabsl because the calling
conventions require f128s to be returned by invisible reference.
--
ADD LOGICAL WITH SIGNED IMMEDIATE could be useful when we need to
produce a carry. SUBTRACT LOGICAL IMMEDIATE could be useful when we
need to produce a borrow. (Note that there are no memory forms of
ADD LOGICAL WITH CARRY and SUBTRACT LOGICAL WITH BORROW, so the high
part of 128-bit memory operations would probably need to be done
via a register.)
--
We don't use the halfword forms of LOAD REVERSED and STORE REVERSED
(LRVH and STRVH).
--
We don't use ICM or STCM.
--
DAGCombiner doesn't yet fold truncations of extended loads. Functions like:
unsigned long f (unsigned long x, unsigned short *y)
{
return (x << 32) | *y;
}
therefore end up as:
sllg %r2, %r2, 32
llgh %r0, 0(%r3)
lr %r2, %r0
br %r14
but truncating the load would give:
sllg %r2, %r2, 32
lh %r2, 0(%r3)
br %r14
--
Functions like:
define i64 @f1(i64 %a) {
%and = and i64 %a, 1
ret i64 %and
}
ought to be implemented as:
lhi %r0, 1
ngr %r2, %r0
br %r14
but two-address optimisations reverse the order of the AND and force:
lhi %r0, 1
ngr %r0, %r2
lgr %r2, %r0
br %r14
CodeGen/SystemZ/and-04.ll has several examples of this.
--
Out-of-range displacements are usually handled by loading the full
address into a register. In many cases it would be better to create
an anchor point instead. E.g. for:
define void @f4a(i128 *%aptr, i64 %base) {
%addr = add i64 %base, 524288
%bptr = inttoptr i64 %addr to i128 *
%a = load volatile i128 *%aptr
%b = load i128 *%bptr
%add = add i128 %a, %b
store i128 %add, i128 *%aptr
ret void
}
(from CodeGen/SystemZ/int-add-08.ll) we load %base+524288 and %base+524296
into separate registers, rather than using %base+524288 as a base for both.
--
Dynamic stack allocations round the size to 8 bytes and then allocate
that rounded amount. It would be simpler to subtract the unrounded
size from the copy of the stack pointer and then align the result.
See CodeGen/SystemZ/alloca-01.ll for an example.
--
If needed, we can support 16-byte atomics using LPQ, STPQ and CSDG.
--
We might want to model all access registers and use them to spill
32-bit values.