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//===-- lib/CodeGen/GlobalISel/GICombinerHelper.cpp -----------------------===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
#include "llvm/CodeGen/GlobalISel/CombinerHelper.h"
#include "llvm/CodeGen/GlobalISel/Combiner.h"
#include "llvm/CodeGen/GlobalISel/GISelChangeObserver.h"
#include "llvm/CodeGen/GlobalISel/GISelKnownBits.h"
#include "llvm/CodeGen/GlobalISel/MachineIRBuilder.h"
#include "llvm/CodeGen/GlobalISel/Utils.h"
#include "llvm/CodeGen/MachineDominators.h"
#include "llvm/CodeGen/MachineFrameInfo.h"
#include "llvm/CodeGen/MachineInstr.h"
#include "llvm/CodeGen/MachineRegisterInfo.h"
#include "llvm/CodeGen/TargetInstrInfo.h"
#include "llvm/CodeGen/TargetLowering.h"
#include "llvm/Target/TargetMachine.h"
#define DEBUG_TYPE "gi-combiner"
using namespace llvm;
// Option to allow testing of the combiner while no targets know about indexed
// addressing.
static cl::opt<bool>
ForceLegalIndexing("force-legal-indexing", cl::Hidden, cl::init(false),
cl::desc("Force all indexed operations to be "
"legal for the GlobalISel combiner"));
CombinerHelper::CombinerHelper(GISelChangeObserver &Observer,
MachineIRBuilder &B, GISelKnownBits *KB,
MachineDominatorTree *MDT)
: Builder(B), MRI(Builder.getMF().getRegInfo()), Observer(Observer),
KB(KB), MDT(MDT) {
(void)this->KB;
}
void CombinerHelper::replaceRegWith(MachineRegisterInfo &MRI, Register FromReg,
Register ToReg) const {
Observer.changingAllUsesOfReg(MRI, FromReg);
if (MRI.constrainRegAttrs(ToReg, FromReg))
MRI.replaceRegWith(FromReg, ToReg);
else
Builder.buildCopy(ToReg, FromReg);
Observer.finishedChangingAllUsesOfReg();
}
void CombinerHelper::replaceRegOpWith(MachineRegisterInfo &MRI,
MachineOperand &FromRegOp,
Register ToReg) const {
assert(FromRegOp.getParent() && "Expected an operand in an MI");
Observer.changingInstr(*FromRegOp.getParent());
FromRegOp.setReg(ToReg);
Observer.changedInstr(*FromRegOp.getParent());
}
bool CombinerHelper::tryCombineCopy(MachineInstr &MI) {
if (matchCombineCopy(MI)) {
applyCombineCopy(MI);
return true;
}
return false;
}
bool CombinerHelper::matchCombineCopy(MachineInstr &MI) {
if (MI.getOpcode() != TargetOpcode::COPY)
return false;
Register DstReg = MI.getOperand(0).getReg();
Register SrcReg = MI.getOperand(1).getReg();
// Give up if either DstReg or SrcReg is a physical register.
if (Register::isPhysicalRegister(DstReg) ||
Register::isPhysicalRegister(SrcReg))
return false;
// Give up the types don't match.
LLT DstTy = MRI.getType(DstReg);
LLT SrcTy = MRI.getType(SrcReg);
// Give up if one has a valid LLT, but the other doesn't.
if (DstTy.isValid() != SrcTy.isValid())
return false;
// Give up if the types don't match.
if (DstTy.isValid() && SrcTy.isValid() && DstTy != SrcTy)
return false;
// Get the register banks and classes.
const RegisterBank *DstBank = MRI.getRegBankOrNull(DstReg);
const RegisterBank *SrcBank = MRI.getRegBankOrNull(SrcReg);
const TargetRegisterClass *DstRC = MRI.getRegClassOrNull(DstReg);
const TargetRegisterClass *SrcRC = MRI.getRegClassOrNull(SrcReg);
// Replace if the register constraints match.
if ((SrcRC == DstRC) && (SrcBank == DstBank))
return true;
// Replace if DstReg has no constraints.
if (!DstBank && !DstRC)
return true;
return false;
}
void CombinerHelper::applyCombineCopy(MachineInstr &MI) {
Register DstReg = MI.getOperand(0).getReg();
Register SrcReg = MI.getOperand(1).getReg();
MI.eraseFromParent();
replaceRegWith(MRI, DstReg, SrcReg);
}
bool CombinerHelper::tryCombineConcatVectors(MachineInstr &MI) {
bool IsUndef = false;
SmallVector<Register, 4> Ops;
if (matchCombineConcatVectors(MI, IsUndef, Ops)) {
applyCombineConcatVectors(MI, IsUndef, Ops);
return true;
}
return false;
}
bool CombinerHelper::matchCombineConcatVectors(MachineInstr &MI, bool &IsUndef,
SmallVectorImpl<Register> &Ops) {
assert(MI.getOpcode() == TargetOpcode::G_CONCAT_VECTORS &&
"Invalid instruction");
IsUndef = true;
MachineInstr *Undef = nullptr;
// Walk over all the operands of concat vectors and check if they are
// build_vector themselves or undef.
// Then collect their operands in Ops.
for (const MachineOperand &MO : MI.uses()) {
Register Reg = MO.getReg();
MachineInstr *Def = MRI.getVRegDef(Reg);
assert(Def && "Operand not defined");
switch (Def->getOpcode()) {
case TargetOpcode::G_BUILD_VECTOR:
IsUndef = false;
// Remember the operands of the build_vector to fold
// them into the yet-to-build flattened concat vectors.
for (const MachineOperand &BuildVecMO : Def->uses())
Ops.push_back(BuildVecMO.getReg());
break;
case TargetOpcode::G_IMPLICIT_DEF: {
LLT OpType = MRI.getType(Reg);
// Keep one undef value for all the undef operands.
if (!Undef) {
Builder.setInsertPt(*MI.getParent(), MI);
Undef = Builder.buildUndef(OpType.getScalarType());
}
assert(MRI.getType(Undef->getOperand(0).getReg()) ==
OpType.getScalarType() &&
"All undefs should have the same type");
// Break the undef vector in as many scalar elements as needed
// for the flattening.
for (unsigned EltIdx = 0, EltEnd = OpType.getNumElements();
EltIdx != EltEnd; ++EltIdx)
Ops.push_back(Undef->getOperand(0).getReg());
break;
}
default:
return false;
}
}
return true;
}
void CombinerHelper::applyCombineConcatVectors(
MachineInstr &MI, bool IsUndef, const ArrayRef<Register> Ops) {
// We determined that the concat_vectors can be flatten.
// Generate the flattened build_vector.
Register DstReg = MI.getOperand(0).getReg();
Builder.setInsertPt(*MI.getParent(), MI);
Register NewDstReg = MRI.cloneVirtualRegister(DstReg);
// Note: IsUndef is sort of redundant. We could have determine it by
// checking that at all Ops are undef. Alternatively, we could have
// generate a build_vector of undefs and rely on another combine to
// clean that up. For now, given we already gather this information
// in tryCombineConcatVectors, just save compile time and issue the
// right thing.
if (IsUndef)
Builder.buildUndef(NewDstReg);
else
Builder.buildBuildVector(NewDstReg, Ops);
MI.eraseFromParent();
replaceRegWith(MRI, DstReg, NewDstReg);
}
bool CombinerHelper::tryCombineShuffleVector(MachineInstr &MI) {
SmallVector<Register, 4> Ops;
if (matchCombineShuffleVector(MI, Ops)) {
applyCombineShuffleVector(MI, Ops);
return true;
}
return false;
}
bool CombinerHelper::matchCombineShuffleVector(MachineInstr &MI,
SmallVectorImpl<Register> &Ops) {
assert(MI.getOpcode() == TargetOpcode::G_SHUFFLE_VECTOR &&
"Invalid instruction kind");
LLT DstType = MRI.getType(MI.getOperand(0).getReg());
Register Src1 = MI.getOperand(1).getReg();
LLT SrcType = MRI.getType(Src1);
// As bizarre as it may look, shuffle vector can actually produce
// scalar! This is because at the IR level a <1 x ty> shuffle
// vector is perfectly valid.
unsigned DstNumElts = DstType.isVector() ? DstType.getNumElements() : 1;
unsigned SrcNumElts = SrcType.isVector() ? SrcType.getNumElements() : 1;
// If the resulting vector is smaller than the size of the source
// vectors being concatenated, we won't be able to replace the
// shuffle vector into a concat_vectors.
//
// Note: We may still be able to produce a concat_vectors fed by
// extract_vector_elt and so on. It is less clear that would
// be better though, so don't bother for now.
//
// If the destination is a scalar, the size of the sources doesn't
// matter. we will lower the shuffle to a plain copy. This will
// work only if the source and destination have the same size. But
// that's covered by the next condition.
//
// TODO: If the size between the source and destination don't match
// we could still emit an extract vector element in that case.
if (DstNumElts < 2 * SrcNumElts && DstNumElts != 1)
return false;
// Check that the shuffle mask can be broken evenly between the
// different sources.
if (DstNumElts % SrcNumElts != 0)
return false;
// Mask length is a multiple of the source vector length.
// Check if the shuffle is some kind of concatenation of the input
// vectors.
unsigned NumConcat = DstNumElts / SrcNumElts;
SmallVector<int, 8> ConcatSrcs(NumConcat, -1);
ArrayRef<int> Mask = MI.getOperand(3).getShuffleMask();
for (unsigned i = 0; i != DstNumElts; ++i) {
int Idx = Mask[i];
// Undef value.
if (Idx < 0)
continue;
// Ensure the indices in each SrcType sized piece are sequential and that
// the same source is used for the whole piece.
if ((Idx % SrcNumElts != (i % SrcNumElts)) ||
(ConcatSrcs[i / SrcNumElts] >= 0 &&
ConcatSrcs[i / SrcNumElts] != (int)(Idx / SrcNumElts)))
return false;
// Remember which source this index came from.
ConcatSrcs[i / SrcNumElts] = Idx / SrcNumElts;
}
// The shuffle is concatenating multiple vectors together.
// Collect the different operands for that.
Register UndefReg;
Register Src2 = MI.getOperand(2).getReg();
for (auto Src : ConcatSrcs) {
if (Src < 0) {
if (!UndefReg) {
Builder.setInsertPt(*MI.getParent(), MI);
UndefReg = Builder.buildUndef(SrcType).getReg(0);
}
Ops.push_back(UndefReg);
} else if (Src == 0)
Ops.push_back(Src1);
else
Ops.push_back(Src2);
}
return true;
}
void CombinerHelper::applyCombineShuffleVector(MachineInstr &MI,
const ArrayRef<Register> Ops) {
Register DstReg = MI.getOperand(0).getReg();
Builder.setInsertPt(*MI.getParent(), MI);
Register NewDstReg = MRI.cloneVirtualRegister(DstReg);
if (Ops.size() == 1)
Builder.buildCopy(NewDstReg, Ops[0]);
else
Builder.buildMerge(NewDstReg, Ops);
MI.eraseFromParent();
replaceRegWith(MRI, DstReg, NewDstReg);
}
namespace {
/// Select a preference between two uses. CurrentUse is the current preference
/// while *ForCandidate is attributes of the candidate under consideration.
PreferredTuple ChoosePreferredUse(PreferredTuple &CurrentUse,
const LLT &TyForCandidate,
unsigned OpcodeForCandidate,
MachineInstr *MIForCandidate) {
if (!CurrentUse.Ty.isValid()) {
if (CurrentUse.ExtendOpcode == OpcodeForCandidate ||
CurrentUse.ExtendOpcode == TargetOpcode::G_ANYEXT)
return {TyForCandidate, OpcodeForCandidate, MIForCandidate};
return CurrentUse;
}
// We permit the extend to hoist through basic blocks but this is only
// sensible if the target has extending loads. If you end up lowering back
// into a load and extend during the legalizer then the end result is
// hoisting the extend up to the load.
// Prefer defined extensions to undefined extensions as these are more
// likely to reduce the number of instructions.
if (OpcodeForCandidate == TargetOpcode::G_ANYEXT &&
CurrentUse.ExtendOpcode != TargetOpcode::G_ANYEXT)
return CurrentUse;
else if (CurrentUse.ExtendOpcode == TargetOpcode::G_ANYEXT &&
OpcodeForCandidate != TargetOpcode::G_ANYEXT)
return {TyForCandidate, OpcodeForCandidate, MIForCandidate};
// Prefer sign extensions to zero extensions as sign-extensions tend to be
// more expensive.
if (CurrentUse.Ty == TyForCandidate) {
if (CurrentUse.ExtendOpcode == TargetOpcode::G_SEXT &&
OpcodeForCandidate == TargetOpcode::G_ZEXT)
return CurrentUse;
else if (CurrentUse.ExtendOpcode == TargetOpcode::G_ZEXT &&
OpcodeForCandidate == TargetOpcode::G_SEXT)
return {TyForCandidate, OpcodeForCandidate, MIForCandidate};
}
// This is potentially target specific. We've chosen the largest type
// because G_TRUNC is usually free. One potential catch with this is that
// some targets have a reduced number of larger registers than smaller
// registers and this choice potentially increases the live-range for the
// larger value.
if (TyForCandidate.getSizeInBits() > CurrentUse.Ty.getSizeInBits()) {
return {TyForCandidate, OpcodeForCandidate, MIForCandidate};
}
return CurrentUse;
}
/// Find a suitable place to insert some instructions and insert them. This
/// function accounts for special cases like inserting before a PHI node.
/// The current strategy for inserting before PHI's is to duplicate the
/// instructions for each predecessor. However, while that's ok for G_TRUNC
/// on most targets since it generally requires no code, other targets/cases may
/// want to try harder to find a dominating block.
static void InsertInsnsWithoutSideEffectsBeforeUse(
MachineIRBuilder &Builder, MachineInstr &DefMI, MachineOperand &UseMO,
std::function<void(MachineBasicBlock *, MachineBasicBlock::iterator,
MachineOperand &UseMO)>
Inserter) {
MachineInstr &UseMI = *UseMO.getParent();
MachineBasicBlock *InsertBB = UseMI.getParent();
// If the use is a PHI then we want the predecessor block instead.
if (UseMI.isPHI()) {
MachineOperand *PredBB = std::next(&UseMO);
InsertBB = PredBB->getMBB();
}
// If the block is the same block as the def then we want to insert just after
// the def instead of at the start of the block.
if (InsertBB == DefMI.getParent()) {
MachineBasicBlock::iterator InsertPt = &DefMI;
Inserter(InsertBB, std::next(InsertPt), UseMO);
return;
}
// Otherwise we want the start of the BB
Inserter(InsertBB, InsertBB->getFirstNonPHI(), UseMO);
}
} // end anonymous namespace
bool CombinerHelper::tryCombineExtendingLoads(MachineInstr &MI) {
PreferredTuple Preferred;
if (matchCombineExtendingLoads(MI, Preferred)) {
applyCombineExtendingLoads(MI, Preferred);
return true;
}
return false;
}
bool CombinerHelper::matchCombineExtendingLoads(MachineInstr &MI,
PreferredTuple &Preferred) {
// We match the loads and follow the uses to the extend instead of matching
// the extends and following the def to the load. This is because the load
// must remain in the same position for correctness (unless we also add code
// to find a safe place to sink it) whereas the extend is freely movable.
// It also prevents us from duplicating the load for the volatile case or just
// for performance.
if (MI.getOpcode() != TargetOpcode::G_LOAD &&
MI.getOpcode() != TargetOpcode::G_SEXTLOAD &&
MI.getOpcode() != TargetOpcode::G_ZEXTLOAD)
return false;
auto &LoadValue = MI.getOperand(0);
assert(LoadValue.isReg() && "Result wasn't a register?");
LLT LoadValueTy = MRI.getType(LoadValue.getReg());
if (!LoadValueTy.isScalar())
return false;
// Most architectures are going to legalize <s8 loads into at least a 1 byte
// load, and the MMOs can only describe memory accesses in multiples of bytes.
// If we try to perform extload combining on those, we can end up with
// %a(s8) = extload %ptr (load 1 byte from %ptr)
// ... which is an illegal extload instruction.
if (LoadValueTy.getSizeInBits() < 8)
return false;
// For non power-of-2 types, they will very likely be legalized into multiple
// loads. Don't bother trying to match them into extending loads.
if (!isPowerOf2_32(LoadValueTy.getSizeInBits()))
return false;
// Find the preferred type aside from the any-extends (unless it's the only
// one) and non-extending ops. We'll emit an extending load to that type and
// and emit a variant of (extend (trunc X)) for the others according to the
// relative type sizes. At the same time, pick an extend to use based on the
// extend involved in the chosen type.
unsigned PreferredOpcode = MI.getOpcode() == TargetOpcode::G_LOAD
? TargetOpcode::G_ANYEXT
: MI.getOpcode() == TargetOpcode::G_SEXTLOAD
? TargetOpcode::G_SEXT
: TargetOpcode::G_ZEXT;
Preferred = {LLT(), PreferredOpcode, nullptr};
for (auto &UseMI : MRI.use_instructions(LoadValue.getReg())) {
if (UseMI.getOpcode() == TargetOpcode::G_SEXT ||
UseMI.getOpcode() == TargetOpcode::G_ZEXT ||
UseMI.getOpcode() == TargetOpcode::G_ANYEXT) {
Preferred = ChoosePreferredUse(Preferred,
MRI.getType(UseMI.getOperand(0).getReg()),
UseMI.getOpcode(), &UseMI);
}
}
// There were no extends
if (!Preferred.MI)
return false;
// It should be impossible to chose an extend without selecting a different
// type since by definition the result of an extend is larger.
assert(Preferred.Ty != LoadValueTy && "Extending to same type?");
LLVM_DEBUG(dbgs() << "Preferred use is: " << *Preferred.MI);
return true;
}
void CombinerHelper::applyCombineExtendingLoads(MachineInstr &MI,
PreferredTuple &Preferred) {
// Rewrite the load to the chosen extending load.
Register ChosenDstReg = Preferred.MI->getOperand(0).getReg();
// Inserter to insert a truncate back to the original type at a given point
// with some basic CSE to limit truncate duplication to one per BB.
DenseMap<MachineBasicBlock *, MachineInstr *> EmittedInsns;
auto InsertTruncAt = [&](MachineBasicBlock *InsertIntoBB,
MachineBasicBlock::iterator InsertBefore,
MachineOperand &UseMO) {
MachineInstr *PreviouslyEmitted = EmittedInsns.lookup(InsertIntoBB);
if (PreviouslyEmitted) {
Observer.changingInstr(*UseMO.getParent());
UseMO.setReg(PreviouslyEmitted->getOperand(0).getReg());
Observer.changedInstr(*UseMO.getParent());
return;
}
Builder.setInsertPt(*InsertIntoBB, InsertBefore);
Register NewDstReg = MRI.cloneVirtualRegister(MI.getOperand(0).getReg());
MachineInstr *NewMI = Builder.buildTrunc(NewDstReg, ChosenDstReg);
EmittedInsns[InsertIntoBB] = NewMI;
replaceRegOpWith(MRI, UseMO, NewDstReg);
};
Observer.changingInstr(MI);
MI.setDesc(
Builder.getTII().get(Preferred.ExtendOpcode == TargetOpcode::G_SEXT
? TargetOpcode::G_SEXTLOAD
: Preferred.ExtendOpcode == TargetOpcode::G_ZEXT
? TargetOpcode::G_ZEXTLOAD
: TargetOpcode::G_LOAD));
// Rewrite all the uses to fix up the types.
auto &LoadValue = MI.getOperand(0);
SmallVector<MachineOperand *, 4> Uses;
for (auto &UseMO : MRI.use_operands(LoadValue.getReg()))
Uses.push_back(&UseMO);
for (auto *UseMO : Uses) {
MachineInstr *UseMI = UseMO->getParent();
// If the extend is compatible with the preferred extend then we should fix
// up the type and extend so that it uses the preferred use.
if (UseMI->getOpcode() == Preferred.ExtendOpcode ||
UseMI->getOpcode() == TargetOpcode::G_ANYEXT) {
Register UseDstReg = UseMI->getOperand(0).getReg();
MachineOperand &UseSrcMO = UseMI->getOperand(1);
const LLT &UseDstTy = MRI.getType(UseDstReg);
if (UseDstReg != ChosenDstReg) {
if (Preferred.Ty == UseDstTy) {
// If the use has the same type as the preferred use, then merge
// the vregs and erase the extend. For example:
// %1:_(s8) = G_LOAD ...
// %2:_(s32) = G_SEXT %1(s8)
// %3:_(s32) = G_ANYEXT %1(s8)
// ... = ... %3(s32)
// rewrites to:
// %2:_(s32) = G_SEXTLOAD ...
// ... = ... %2(s32)
replaceRegWith(MRI, UseDstReg, ChosenDstReg);
Observer.erasingInstr(*UseMO->getParent());
UseMO->getParent()->eraseFromParent();
} else if (Preferred.Ty.getSizeInBits() < UseDstTy.getSizeInBits()) {
// If the preferred size is smaller, then keep the extend but extend
// from the result of the extending load. For example:
// %1:_(s8) = G_LOAD ...
// %2:_(s32) = G_SEXT %1(s8)
// %3:_(s64) = G_ANYEXT %1(s8)
// ... = ... %3(s64)
/// rewrites to:
// %2:_(s32) = G_SEXTLOAD ...
// %3:_(s64) = G_ANYEXT %2:_(s32)
// ... = ... %3(s64)
replaceRegOpWith(MRI, UseSrcMO, ChosenDstReg);
} else {
// If the preferred size is large, then insert a truncate. For
// example:
// %1:_(s8) = G_LOAD ...
// %2:_(s64) = G_SEXT %1(s8)
// %3:_(s32) = G_ZEXT %1(s8)
// ... = ... %3(s32)
/// rewrites to:
// %2:_(s64) = G_SEXTLOAD ...
// %4:_(s8) = G_TRUNC %2:_(s32)
// %3:_(s64) = G_ZEXT %2:_(s8)
// ... = ... %3(s64)
InsertInsnsWithoutSideEffectsBeforeUse(Builder, MI, *UseMO,
InsertTruncAt);
}
continue;
}
// The use is (one of) the uses of the preferred use we chose earlier.
// We're going to update the load to def this value later so just erase
// the old extend.
Observer.erasingInstr(*UseMO->getParent());
UseMO->getParent()->eraseFromParent();
continue;
}
// The use isn't an extend. Truncate back to the type we originally loaded.
// This is free on many targets.
InsertInsnsWithoutSideEffectsBeforeUse(Builder, MI, *UseMO, InsertTruncAt);
}
MI.getOperand(0).setReg(ChosenDstReg);
Observer.changedInstr(MI);
}
bool CombinerHelper::isPredecessor(MachineInstr &DefMI, MachineInstr &UseMI) {
assert(DefMI.getParent() == UseMI.getParent());
if (&DefMI == &UseMI)
return false;
// Loop through the basic block until we find one of the instructions.
MachineBasicBlock::const_iterator I = DefMI.getParent()->begin();
for (; &*I != &DefMI && &*I != &UseMI; ++I)
return &*I == &DefMI;
llvm_unreachable("Block must contain instructions");
}
bool CombinerHelper::dominates(MachineInstr &DefMI, MachineInstr &UseMI) {
if (MDT)
return MDT->dominates(&DefMI, &UseMI);
else if (DefMI.getParent() != UseMI.getParent())
return false;
return isPredecessor(DefMI, UseMI);
}
bool CombinerHelper::findPostIndexCandidate(MachineInstr &MI, Register &Addr,
Register &Base, Register &Offset) {
auto &MF = *MI.getParent()->getParent();
const auto &TLI = *MF.getSubtarget().getTargetLowering();
#ifndef NDEBUG
unsigned Opcode = MI.getOpcode();
assert(Opcode == TargetOpcode::G_LOAD || Opcode == TargetOpcode::G_SEXTLOAD ||
Opcode == TargetOpcode::G_ZEXTLOAD || Opcode == TargetOpcode::G_STORE);
#endif
Base = MI.getOperand(1).getReg();
MachineInstr *BaseDef = MRI.getUniqueVRegDef(Base);
if (BaseDef && BaseDef->getOpcode() == TargetOpcode::G_FRAME_INDEX)
return false;
LLVM_DEBUG(dbgs() << "Searching for post-indexing opportunity for: " << MI);
for (auto &Use : MRI.use_instructions(Base)) {
if (Use.getOpcode() != TargetOpcode::G_PTR_ADD)
continue;
Offset = Use.getOperand(2).getReg();
if (!ForceLegalIndexing &&
!TLI.isIndexingLegal(MI, Base, Offset, /*IsPre*/ false, MRI)) {
LLVM_DEBUG(dbgs() << " Ignoring candidate with illegal addrmode: "
<< Use);
continue;
}
// Make sure the offset calculation is before the potentially indexed op.
// FIXME: we really care about dependency here. The offset calculation might
// be movable.
MachineInstr *OffsetDef = MRI.getUniqueVRegDef(Offset);
if (!OffsetDef || !dominates(*OffsetDef, MI)) {
LLVM_DEBUG(dbgs() << " Ignoring candidate with offset after mem-op: "
<< Use);
continue;
}
// FIXME: check whether all uses of Base are load/store with foldable
// addressing modes. If so, using the normal addr-modes is better than
// forming an indexed one.
bool MemOpDominatesAddrUses = true;
for (auto &PtrAddUse : MRI.use_instructions(Use.getOperand(0).getReg())) {
if (!dominates(MI, PtrAddUse)) {
MemOpDominatesAddrUses = false;
break;
}
}
if (!MemOpDominatesAddrUses) {
LLVM_DEBUG(
dbgs() << " Ignoring candidate as memop does not dominate uses: "
<< Use);
continue;
}
LLVM_DEBUG(dbgs() << " Found match: " << Use);
Addr = Use.getOperand(0).getReg();
return true;
}
return false;
}
bool CombinerHelper::findPreIndexCandidate(MachineInstr &MI, Register &Addr,
Register &Base, Register &Offset) {
auto &MF = *MI.getParent()->getParent();
const auto &TLI = *MF.getSubtarget().getTargetLowering();
#ifndef NDEBUG
unsigned Opcode = MI.getOpcode();
assert(Opcode == TargetOpcode::G_LOAD || Opcode == TargetOpcode::G_SEXTLOAD ||
Opcode == TargetOpcode::G_ZEXTLOAD || Opcode == TargetOpcode::G_STORE);
#endif
Addr = MI.getOperand(1).getReg();
MachineInstr *AddrDef = getOpcodeDef(TargetOpcode::G_PTR_ADD, Addr, MRI);
if (!AddrDef || MRI.hasOneUse(Addr))
return false;
Base = AddrDef->getOperand(1).getReg();
Offset = AddrDef->getOperand(2).getReg();
LLVM_DEBUG(dbgs() << "Found potential pre-indexed load_store: " << MI);
if (!ForceLegalIndexing &&
!TLI.isIndexingLegal(MI, Base, Offset, /*IsPre*/ true, MRI)) {
LLVM_DEBUG(dbgs() << " Skipping, not legal for target");
return false;
}
MachineInstr *BaseDef = getDefIgnoringCopies(Base, MRI);
if (BaseDef->getOpcode() == TargetOpcode::G_FRAME_INDEX) {
LLVM_DEBUG(dbgs() << " Skipping, frame index would need copy anyway.");
return false;
}
if (MI.getOpcode() == TargetOpcode::G_STORE) {
// Would require a copy.
if (Base == MI.getOperand(0).getReg()) {
LLVM_DEBUG(dbgs() << " Skipping, storing base so need copy anyway.");
return false;
}
// We're expecting one use of Addr in MI, but it could also be the
// value stored, which isn't actually dominated by the instruction.
if (MI.getOperand(0).getReg() == Addr) {
LLVM_DEBUG(dbgs() << " Skipping, does not dominate all addr uses");
return false;
}
}
// FIXME: check whether all uses of the base pointer are constant PtrAdds.
// That might allow us to end base's liveness here by adjusting the constant.
for (auto &UseMI : MRI.use_instructions(Addr)) {
if (!dominates(MI, UseMI)) {
LLVM_DEBUG(dbgs() << " Skipping, does not dominate all addr uses.");
return false;
}
}
return true;
}
bool CombinerHelper::tryCombineIndexedLoadStore(MachineInstr &MI) {
IndexedLoadStoreMatchInfo MatchInfo;
if (matchCombineIndexedLoadStore(MI, MatchInfo)) {
applyCombineIndexedLoadStore(MI, MatchInfo);
return true;
}
return false;
}
bool CombinerHelper::matchCombineIndexedLoadStore(MachineInstr &MI, IndexedLoadStoreMatchInfo &MatchInfo) {
unsigned Opcode = MI.getOpcode();
if (Opcode != TargetOpcode::G_LOAD && Opcode != TargetOpcode::G_SEXTLOAD &&
Opcode != TargetOpcode::G_ZEXTLOAD && Opcode != TargetOpcode::G_STORE)
return false;
MatchInfo.IsPre = findPreIndexCandidate(MI, MatchInfo.Addr, MatchInfo.Base,
MatchInfo.Offset);
if (!MatchInfo.IsPre &&
!findPostIndexCandidate(MI, MatchInfo.Addr, MatchInfo.Base,
MatchInfo.Offset))
return false;
return true;
}
void CombinerHelper::applyCombineIndexedLoadStore(
MachineInstr &MI, IndexedLoadStoreMatchInfo &MatchInfo) {
MachineInstr &AddrDef = *MRI.getUniqueVRegDef(MatchInfo.Addr);
MachineIRBuilder MIRBuilder(MI);
unsigned Opcode = MI.getOpcode();
bool IsStore = Opcode == TargetOpcode::G_STORE;
unsigned NewOpcode;
switch (Opcode) {
case TargetOpcode::G_LOAD:
NewOpcode = TargetOpcode::G_INDEXED_LOAD;
break;
case TargetOpcode::G_SEXTLOAD:
NewOpcode = TargetOpcode::G_INDEXED_SEXTLOAD;
break;
case TargetOpcode::G_ZEXTLOAD:
NewOpcode = TargetOpcode::G_INDEXED_ZEXTLOAD;
break;
case TargetOpcode::G_STORE:
NewOpcode = TargetOpcode::G_INDEXED_STORE;
break;
default:
llvm_unreachable("Unknown load/store opcode");
}
auto MIB = MIRBuilder.buildInstr(NewOpcode);
if (IsStore) {
MIB.addDef(MatchInfo.Addr);
MIB.addUse(MI.getOperand(0).getReg());
} else {
MIB.addDef(MI.getOperand(0).getReg());
MIB.addDef(MatchInfo.Addr);
}
MIB.addUse(MatchInfo.Base);
MIB.addUse(MatchInfo.Offset);
MIB.addImm(MatchInfo.IsPre);
MI.eraseFromParent();
AddrDef.eraseFromParent();
LLVM_DEBUG(dbgs() << " Combinined to indexed operation");
}
bool CombinerHelper::matchElideBrByInvertingCond(MachineInstr &MI) {
if (MI.getOpcode() != TargetOpcode::G_BR)
return false;
// Try to match the following:
// bb1:
// %c(s32) = G_ICMP pred, %a, %b
// %c1(s1) = G_TRUNC %c(s32)
// G_BRCOND %c1, %bb2
// G_BR %bb3
// bb2:
// ...
// bb3:
// The above pattern does not have a fall through to the successor bb2, always
// resulting in a branch no matter which path is taken. Here we try to find
// and replace that pattern with conditional branch to bb3 and otherwise
// fallthrough to bb2.
MachineBasicBlock *MBB = MI.getParent();
MachineBasicBlock::iterator BrIt(MI);
if (BrIt == MBB->begin())
return false;
assert(std::next(BrIt) == MBB->end() && "expected G_BR to be a terminator");
MachineInstr *BrCond = &*std::prev(BrIt);
if (BrCond->getOpcode() != TargetOpcode::G_BRCOND)
return false;
// Check that the next block is the conditional branch target.
if (!MBB->isLayoutSuccessor(BrCond->getOperand(1).getMBB()))
return false;
MachineInstr *CmpMI = MRI.getVRegDef(BrCond->getOperand(0).getReg());
if (!CmpMI || CmpMI->getOpcode() != TargetOpcode::G_ICMP ||
!MRI.hasOneUse(CmpMI->getOperand(0).getReg()))
return false;
return true;
}
bool CombinerHelper::tryElideBrByInvertingCond(MachineInstr &MI) {
if (!matchElideBrByInvertingCond(MI))
return false;
applyElideBrByInvertingCond(MI);
return true;
}
void CombinerHelper::applyElideBrByInvertingCond(MachineInstr &MI) {
MachineBasicBlock *BrTarget = MI.getOperand(0).getMBB();
MachineBasicBlock::iterator BrIt(MI);
MachineInstr *BrCond = &*std::prev(BrIt);
MachineInstr *CmpMI = MRI.getVRegDef(BrCond->getOperand(0).getReg());
CmpInst::Predicate InversePred = CmpInst::getInversePredicate(
(CmpInst::Predicate)CmpMI->getOperand(1).getPredicate());
// Invert the G_ICMP condition.
Observer.changingInstr(*CmpMI);
CmpMI->getOperand(1).setPredicate(InversePred);
Observer.changedInstr(*CmpMI);
// Change the conditional branch target.
Observer.changingInstr(*BrCond);
BrCond->getOperand(1).setMBB(BrTarget);
Observer.changedInstr(*BrCond);
MI.eraseFromParent();
}
static bool shouldLowerMemFuncForSize(const MachineFunction &MF) {
// On Darwin, -Os means optimize for size without hurting performance, so
// only really optimize for size when -Oz (MinSize) is used.
if (MF.getTarget().getTargetTriple().isOSDarwin())
return MF.getFunction().hasMinSize();
return MF.getFunction().hasOptSize();
}
// Returns a list of types to use for memory op lowering in MemOps. A partial
// port of findOptimalMemOpLowering in TargetLowering.
static bool findGISelOptimalMemOpLowering(
std::vector<LLT> &MemOps, unsigned Limit, uint64_t Size, unsigned DstAlign,
unsigned SrcAlign, bool IsMemset, bool ZeroMemset, bool MemcpyStrSrc,
bool AllowOverlap, unsigned DstAS, unsigned SrcAS,
const AttributeList &FuncAttributes, const TargetLowering &TLI) {
// If 'SrcAlign' is zero, that means the memory operation does not need to
// load the value, i.e. memset or memcpy from constant string. Otherwise,
// it's the inferred alignment of the source. 'DstAlign', on the other hand,
// is the specified alignment of the memory operation. If it is zero, that
// means it's possible to change the alignment of the destination.
// 'MemcpyStrSrc' indicates whether the memcpy source is constant so it does
// not need to be loaded.
if (SrcAlign != 0 && SrcAlign < DstAlign)
return false;
LLT Ty = TLI.getOptimalMemOpLLT(Size, DstAlign, SrcAlign, IsMemset,
ZeroMemset, MemcpyStrSrc, FuncAttributes);
if (Ty == LLT()) {
// Use the largest scalar type whose alignment constraints are satisfied.
// We only need to check DstAlign here as SrcAlign is always greater or
// equal to DstAlign (or zero).
Ty = LLT::scalar(64);
while (DstAlign && DstAlign < Ty.getSizeInBytes() &&
!TLI.allowsMisalignedMemoryAccesses(Ty, DstAS, DstAlign))
Ty = LLT::scalar(Ty.getSizeInBytes());
assert(Ty.getSizeInBits() > 0 && "Could not find valid type");
// FIXME: check for the largest legal type we can load/store to.
}
unsigned NumMemOps = 0;
while (Size != 0) {
unsigned TySize = Ty.getSizeInBytes();
while (TySize > Size) {
// For now, only use non-vector load / store's for the left-over pieces.
LLT NewTy = Ty;
// FIXME: check for mem op safety and legality of the types. Not all of
// SDAGisms map cleanly to GISel concepts.
if (NewTy.isVector())
NewTy = NewTy.getSizeInBits() > 64 ? LLT::scalar(64) : LLT::scalar(32);
NewTy = LLT::scalar(PowerOf2Floor(NewTy.getSizeInBits() - 1));
unsigned NewTySize = NewTy.getSizeInBytes();
assert(NewTySize > 0 && "Could not find appropriate type");
// If the new LLT cannot cover all of the remaining bits, then consider
// issuing a (or a pair of) unaligned and overlapping load / store.
bool Fast;
// Need to get a VT equivalent for allowMisalignedMemoryAccesses().
MVT VT = getMVTForLLT(Ty);
if (NumMemOps && AllowOverlap && NewTySize < Size &&
TLI.allowsMisalignedMemoryAccesses(
VT, DstAS, DstAlign, MachineMemOperand::MONone, &Fast) &&
Fast)
TySize = Size;
else {
Ty = NewTy;
TySize = NewTySize;
}
}
if (++NumMemOps > Limit)
return false;
MemOps.push_back(Ty);
Size -= TySize;
}
return true;
}
static Type *getTypeForLLT(LLT Ty, LLVMContext &C) {
if (Ty.isVector())
return VectorType::get(IntegerType::get(C, Ty.getScalarSizeInBits()),
Ty.getNumElements());
return IntegerType::get(C, Ty.getSizeInBits());
}
// Get a vectorized representation of the memset value operand, GISel edition.
static Register getMemsetValue(Register Val, LLT Ty, MachineIRBuilder &MIB) {
MachineRegisterInfo &MRI = *MIB.getMRI();
unsigned NumBits = Ty.getScalarSizeInBits();
auto ValVRegAndVal = getConstantVRegValWithLookThrough(Val, MRI);
if (!Ty.isVector() && ValVRegAndVal) {
unsigned KnownVal = ValVRegAndVal->Value;
APInt Scalar = APInt(8, KnownVal);
APInt SplatVal = APInt::getSplat(NumBits, Scalar);
return MIB.buildConstant(Ty, SplatVal).getReg(0);
}
// FIXME: for vector types create a G_BUILD_VECTOR.
if (Ty.isVector())
return Register();
// Extend the byte value to the larger type, and then multiply by a magic
// value 0x010101... in order to replicate it across every byte.
LLT ExtType = Ty.getScalarType();
auto ZExt = MIB.buildZExtOrTrunc(ExtType, Val);
if (NumBits > 8) {
APInt Magic = APInt::getSplat(NumBits, APInt(8, 0x01));
auto MagicMI = MIB.buildConstant(ExtType, Magic);
Val = MIB.buildMul(ExtType, ZExt, MagicMI).getReg(0);
}
assert(ExtType == Ty && "Vector memset value type not supported yet");
return Val;
}
bool CombinerHelper::optimizeMemset(MachineInstr &MI, Register Dst, Register Val,
unsigned KnownLen, unsigned Align,
bool IsVolatile) {
auto &MF = *MI.getParent()->getParent();
const auto &TLI = *MF.getSubtarget().getTargetLowering();
auto &DL = MF.getDataLayout();
LLVMContext &C = MF.getFunction().getContext();
assert(KnownLen != 0 && "Have a zero length memset length!");
bool DstAlignCanChange = false;
MachineFrameInfo &MFI = MF.getFrameInfo();
bool OptSize = shouldLowerMemFuncForSize(MF);
MachineInstr *FIDef = getOpcodeDef(TargetOpcode::G_FRAME_INDEX, Dst, MRI);
if (FIDef && !MFI.isFixedObjectIndex(FIDef->getOperand(1).getIndex()))
DstAlignCanChange = true;
unsigned Limit = TLI.getMaxStoresPerMemset(OptSize);
std::vector<LLT> MemOps;
const auto &DstMMO = **MI.memoperands_begin();
MachinePointerInfo DstPtrInfo = DstMMO.getPointerInfo();
auto ValVRegAndVal = getConstantVRegValWithLookThrough(Val, MRI);
bool IsZeroVal = ValVRegAndVal && ValVRegAndVal->Value == 0;
if (!findGISelOptimalMemOpLowering(
MemOps, Limit, KnownLen, (DstAlignCanChange ? 0 : Align), 0,
/*IsMemset=*/true,
/*ZeroMemset=*/IsZeroVal, /*MemcpyStrSrc=*/false,
/*AllowOverlap=*/!IsVolatile, DstPtrInfo.getAddrSpace(), ~0u,
MF.getFunction().getAttributes(), TLI))
return false;
if (DstAlignCanChange) {
// Get an estimate of the type from the LLT.
Type *IRTy = getTypeForLLT(MemOps[0], C);
unsigned NewAlign = (unsigned)DL.getABITypeAlignment(IRTy);
if (NewAlign > Align) {
Align = NewAlign;
unsigned FI = FIDef->getOperand(1).getIndex();
// Give the stack frame object a larger alignment if needed.
if (MFI.getObjectAlignment(FI) < Align)
MFI.setObjectAlignment(FI, Align);
}
}
MachineIRBuilder MIB(MI);
// Find the largest store and generate the bit pattern for it.
LLT LargestTy = MemOps[0];
for (unsigned i = 1; i < MemOps.size(); i++)
if (MemOps[i].getSizeInBits() > LargestTy.getSizeInBits())
LargestTy = MemOps[i];
// The memset stored value is always defined as an s8, so in order to make it
// work with larger store types we need to repeat the bit pattern across the
// wider type.
Register MemSetValue = getMemsetValue(Val, LargestTy, MIB);
if (!MemSetValue)
return false;
// Generate the stores. For each store type in the list, we generate the
// matching store of that type to the destination address.
LLT PtrTy = MRI.getType(Dst);
unsigned DstOff = 0;
unsigned Size = KnownLen;
for (unsigned I = 0; I < MemOps.size(); I++) {
LLT Ty = MemOps[I];
unsigned TySize = Ty.getSizeInBytes();
if (TySize > Size) {
// Issuing an unaligned load / store pair that overlaps with the previous
// pair. Adjust the offset accordingly.
assert(I == MemOps.size() - 1 && I != 0);
DstOff -= TySize - Size;
}
// If this store is smaller than the largest store see whether we can get
// the smaller value for free with a truncate.
Register Value = MemSetValue;
if (Ty.getSizeInBits() < LargestTy.getSizeInBits()) {
MVT VT = getMVTForLLT(Ty);
MVT LargestVT = getMVTForLLT(LargestTy);
if (!LargestTy.isVector() && !Ty.isVector() &&
TLI.isTruncateFree(LargestVT, VT))
Value = MIB.buildTrunc(Ty, MemSetValue).getReg(0);
else
Value = getMemsetValue(Val, Ty, MIB);
if (!Value)
return false;
}
auto *StoreMMO =
MF.getMachineMemOperand(&DstMMO, DstOff, Ty.getSizeInBytes());
Register Ptr = Dst;
if (DstOff != 0) {
auto Offset =
MIB.buildConstant(LLT::scalar(PtrTy.getSizeInBits()), DstOff);
Ptr = MIB.buildPtrAdd(PtrTy, Dst, Offset).getReg(0);
}
MIB.buildStore(Value, Ptr, *StoreMMO);
DstOff += Ty.getSizeInBytes();
Size -= TySize;
}
MI.eraseFromParent();
return true;
}
bool CombinerHelper::optimizeMemcpy(MachineInstr &MI, Register Dst,
Register Src, unsigned KnownLen,
unsigned DstAlign, unsigned SrcAlign,
bool IsVolatile) {
auto &MF = *MI.getParent()->getParent();
const auto &TLI = *MF.getSubtarget().getTargetLowering();
auto &DL = MF.getDataLayout();
LLVMContext &C = MF.getFunction().getContext();
assert(KnownLen != 0 && "Have a zero length memcpy length!");
bool DstAlignCanChange = false;
MachineFrameInfo &MFI = MF.getFrameInfo();
bool OptSize = shouldLowerMemFuncForSize(MF);
unsigned Alignment = MinAlign(DstAlign, SrcAlign);
MachineInstr *FIDef = getOpcodeDef(TargetOpcode::G_FRAME_INDEX, Dst, MRI);
if (FIDef && !MFI.isFixedObjectIndex(FIDef->getOperand(1).getIndex()))
DstAlignCanChange = true;
// FIXME: infer better src pointer alignment like SelectionDAG does here.
// FIXME: also use the equivalent of isMemSrcFromConstant and alwaysinlining
// if the memcpy is in a tail call position.
unsigned Limit = TLI.getMaxStoresPerMemcpy(OptSize);
std::vector<LLT> MemOps;
const auto &DstMMO = **MI.memoperands_begin();
const auto &SrcMMO = **std::next(MI.memoperands_begin());
MachinePointerInfo DstPtrInfo = DstMMO.getPointerInfo();
MachinePointerInfo SrcPtrInfo = SrcMMO.getPointerInfo();
if (!findGISelOptimalMemOpLowering(
MemOps, Limit, KnownLen, (DstAlignCanChange ? 0 : Alignment),
SrcAlign,
/*IsMemset=*/false,
/*ZeroMemset=*/false, /*MemcpyStrSrc=*/false,
/*AllowOverlap=*/!IsVolatile, DstPtrInfo.getAddrSpace(),
SrcPtrInfo.getAddrSpace(), MF.getFunction().getAttributes(), TLI))
return false;
if (DstAlignCanChange) {
// Get an estimate of the type from the LLT.
Type *IRTy = getTypeForLLT(MemOps[0], C);
unsigned NewAlign = (unsigned)DL.getABITypeAlignment(IRTy);
// Don't promote to an alignment that would require dynamic stack
// realignment.
const TargetRegisterInfo *TRI = MF.getSubtarget().getRegisterInfo();
if (!TRI->needsStackRealignment(MF))
while (NewAlign > Alignment &&
DL.exceedsNaturalStackAlignment(Align(NewAlign)))
NewAlign /= 2;
if (NewAlign > Alignment) {
Alignment = NewAlign;
unsigned FI = FIDef->getOperand(1).getIndex();
// Give the stack frame object a larger alignment if needed.
if (MFI.getObjectAlignment(FI) < Alignment)
MFI.setObjectAlignment(FI, Alignment);
}
}
LLVM_DEBUG(dbgs() << "Inlining memcpy: " << MI << " into loads & stores\n");
MachineIRBuilder MIB(MI);
// Now we need to emit a pair of load and stores for each of the types we've
// collected. I.e. for each type, generate a load from the source pointer of
// that type width, and then generate a corresponding store to the dest buffer
// of that value loaded. This can result in a sequence of loads and stores
// mixed types, depending on what the target specifies as good types to use.
unsigned CurrOffset = 0;
LLT PtrTy = MRI.getType(Src);
unsigned Size = KnownLen;
for (auto CopyTy : MemOps) {
// Issuing an unaligned load / store pair that overlaps with the previous
// pair. Adjust the offset accordingly.
if (CopyTy.getSizeInBytes() > Size)
CurrOffset -= CopyTy.getSizeInBytes() - Size;
// Construct MMOs for the accesses.
auto *LoadMMO =
MF.getMachineMemOperand(&SrcMMO, CurrOffset, CopyTy.getSizeInBytes());
auto *StoreMMO =
MF.getMachineMemOperand(&DstMMO, CurrOffset, CopyTy.getSizeInBytes());
// Create the load.
Register LoadPtr = Src;
Register Offset;
if (CurrOffset != 0) {
Offset = MIB.buildConstant(LLT::scalar(PtrTy.getSizeInBits()), CurrOffset)
.getReg(0);
LoadPtr = MIB.buildPtrAdd(PtrTy, Src, Offset).getReg(0);
}
auto LdVal = MIB.buildLoad(CopyTy, LoadPtr, *LoadMMO);
// Create the store.
Register StorePtr =
CurrOffset == 0 ? Dst : MIB.buildPtrAdd(PtrTy, Dst, Offset).getReg(0);
MIB.buildStore(LdVal, StorePtr, *StoreMMO);
CurrOffset += CopyTy.getSizeInBytes();
Size -= CopyTy.getSizeInBytes();
}
MI.eraseFromParent();
return true;
}
bool CombinerHelper::optimizeMemmove(MachineInstr &MI, Register Dst,
Register Src, unsigned KnownLen,
unsigned DstAlign, unsigned SrcAlign,
bool IsVolatile) {
auto &MF = *MI.getParent()->getParent();
const auto &TLI = *MF.getSubtarget().getTargetLowering();
auto &DL = MF.getDataLayout();
LLVMContext &C = MF.getFunction().getContext();
assert(KnownLen != 0 && "Have a zero length memmove length!");
bool DstAlignCanChange = false;
MachineFrameInfo &MFI = MF.getFrameInfo();
bool OptSize = shouldLowerMemFuncForSize(MF);
unsigned Alignment = MinAlign(DstAlign, SrcAlign);
MachineInstr *FIDef = getOpcodeDef(TargetOpcode::G_FRAME_INDEX, Dst, MRI);
if (FIDef && !MFI.isFixedObjectIndex(FIDef->getOperand(1).getIndex()))
DstAlignCanChange = true;
unsigned Limit = TLI.getMaxStoresPerMemmove(OptSize);
std::vector<LLT> MemOps;
const auto &DstMMO = **MI.memoperands_begin();
const auto &SrcMMO = **std::next(MI.memoperands_begin());
MachinePointerInfo DstPtrInfo = DstMMO.getPointerInfo();
MachinePointerInfo SrcPtrInfo = SrcMMO.getPointerInfo();
// FIXME: SelectionDAG always passes false for 'AllowOverlap', apparently due
// to a bug in it's findOptimalMemOpLowering implementation. For now do the
// same thing here.
if (!findGISelOptimalMemOpLowering(
MemOps, Limit, KnownLen, (DstAlignCanChange ? 0 : Alignment),
SrcAlign,
/*IsMemset=*/false,
/*ZeroMemset=*/false, /*MemcpyStrSrc=*/false,
/*AllowOverlap=*/false, DstPtrInfo.getAddrSpace(),
SrcPtrInfo.getAddrSpace(), MF.getFunction().getAttributes(), TLI))
return false;
if (DstAlignCanChange) {
// Get an estimate of the type from the LLT.
Type *IRTy = getTypeForLLT(MemOps[0], C);
unsigned NewAlign = (unsigned)DL.getABITypeAlignment(IRTy);
// Don't promote to an alignment that would require dynamic stack
// realignment.
const TargetRegisterInfo *TRI = MF.getSubtarget().getRegisterInfo();
if (!TRI->needsStackRealignment(MF))
while (NewAlign > Alignment &&
DL.exceedsNaturalStackAlignment(Align(NewAlign)))
NewAlign /= 2;
if (NewAlign > Alignment) {
Alignment = NewAlign;
unsigned FI = FIDef->getOperand(1).getIndex();
// Give the stack frame object a larger alignment if needed.
if (MFI.getObjectAlignment(FI) < Alignment)
MFI.setObjectAlignment(FI, Alignment);
}
}
LLVM_DEBUG(dbgs() << "Inlining memmove: " << MI << " into loads & stores\n");
MachineIRBuilder MIB(MI);
// Memmove requires that we perform the loads first before issuing the stores.
// Apart from that, this loop is pretty much doing the same thing as the
// memcpy codegen function.
unsigned CurrOffset = 0;
LLT PtrTy = MRI.getType(Src);
SmallVector<Register, 16> LoadVals;
for (auto CopyTy : MemOps) {
// Construct MMO for the load.
auto *LoadMMO =
MF.getMachineMemOperand(&SrcMMO, CurrOffset, CopyTy.getSizeInBytes());
// Create the load.
Register LoadPtr = Src;
if (CurrOffset != 0) {
auto Offset =
MIB.buildConstant(LLT::scalar(PtrTy.getSizeInBits()), CurrOffset);
LoadPtr = MIB.buildPtrAdd(PtrTy, Src, Offset).getReg(0);
}
LoadVals.push_back(MIB.buildLoad(CopyTy, LoadPtr, *LoadMMO).getReg(0));
CurrOffset += CopyTy.getSizeInBytes();
}
CurrOffset = 0;
for (unsigned I = 0; I < MemOps.size(); ++I) {
LLT CopyTy = MemOps[I];
// Now store the values loaded.
auto *StoreMMO =
MF.getMachineMemOperand(&DstMMO, CurrOffset, CopyTy.getSizeInBytes());
Register StorePtr = Dst;
if (CurrOffset != 0) {
auto Offset =
MIB.buildConstant(LLT::scalar(PtrTy.getSizeInBits()), CurrOffset);
StorePtr = MIB.buildPtrAdd(PtrTy, Dst, Offset).getReg(0);
}
MIB.buildStore(LoadVals[I], StorePtr, *StoreMMO);
CurrOffset += CopyTy.getSizeInBytes();
}
MI.eraseFromParent();
return true;
}
bool CombinerHelper::tryCombineMemCpyFamily(MachineInstr &MI, unsigned MaxLen) {
// This combine is fairly complex so it's not written with a separate
// matcher function.
assert(MI.getOpcode() == TargetOpcode::G_INTRINSIC_W_SIDE_EFFECTS);
Intrinsic::ID ID = (Intrinsic::ID)MI.getIntrinsicID();
assert((ID == Intrinsic::memcpy || ID == Intrinsic::memmove ||
ID == Intrinsic::memset) &&
"Expected a memcpy like intrinsic");
auto MMOIt = MI.memoperands_begin();
const MachineMemOperand *MemOp = *MMOIt;
bool IsVolatile = MemOp->isVolatile();
// Don't try to optimize volatile.
if (IsVolatile)
return false;
unsigned DstAlign = MemOp->getBaseAlignment();
unsigned SrcAlign = 0;
Register Dst = MI.getOperand(1).getReg();
Register Src = MI.getOperand(2).getReg();
Register Len = MI.getOperand(3).getReg();
if (ID != Intrinsic::memset) {
assert(MMOIt != MI.memoperands_end() && "Expected a second MMO on MI");
MemOp = *(++MMOIt);
SrcAlign = MemOp->getBaseAlignment();
}
// See if this is a constant length copy
auto LenVRegAndVal = getConstantVRegValWithLookThrough(Len, MRI);
if (!LenVRegAndVal)
return false; // Leave it to the legalizer to lower it to a libcall.
unsigned KnownLen = LenVRegAndVal->Value;
if (KnownLen == 0) {
MI.eraseFromParent();
return true;
}
if (MaxLen && KnownLen > MaxLen)
return false;
if (ID == Intrinsic::memcpy)
return optimizeMemcpy(MI, Dst, Src, KnownLen, DstAlign, SrcAlign, IsVolatile);
if (ID == Intrinsic::memmove)
return optimizeMemmove(MI, Dst, Src, KnownLen, DstAlign, SrcAlign, IsVolatile);
if (ID == Intrinsic::memset)
return optimizeMemset(MI, Dst, Src, KnownLen, DstAlign, IsVolatile);
return false;
}
bool CombinerHelper::matchPtrAddImmedChain(MachineInstr &MI,
PtrAddChain &MatchInfo) {
// We're trying to match the following pattern:
// %t1 = G_PTR_ADD %base, G_CONSTANT imm1
// %root = G_PTR_ADD %t1, G_CONSTANT imm2
// -->
// %root = G_PTR_ADD %base, G_CONSTANT (imm1 + imm2)
if (MI.getOpcode() != TargetOpcode::G_PTR_ADD)
return false;
Register Add2 = MI.getOperand(1).getReg();
Register Imm1 = MI.getOperand(2).getReg();
auto MaybeImmVal = getConstantVRegValWithLookThrough(Imm1, MRI);
if (!MaybeImmVal)
return false;
MachineInstr *Add2Def = MRI.getUniqueVRegDef(Add2);
if (!Add2Def || Add2Def->getOpcode() != TargetOpcode::G_PTR_ADD)
return false;
Register Base = Add2Def->getOperand(1).getReg();
Register Imm2 = Add2Def->getOperand(2).getReg();
auto MaybeImm2Val = getConstantVRegValWithLookThrough(Imm2, MRI);
if (!MaybeImm2Val)
return false;
// Pass the combined immediate to the apply function.
MatchInfo.Imm = MaybeImmVal->Value + MaybeImm2Val->Value;
MatchInfo.Base = Base;
return true;
}
bool CombinerHelper::applyPtrAddImmedChain(MachineInstr &MI,
PtrAddChain &MatchInfo) {
assert(MI.getOpcode() == TargetOpcode::G_PTR_ADD && "Expected G_PTR_ADD");
MachineIRBuilder MIB(MI);
LLT OffsetTy = MRI.getType(MI.getOperand(2).getReg());
auto NewOffset = MIB.buildConstant(OffsetTy, MatchInfo.Imm);
Observer.changingInstr(MI);
MI.getOperand(1).setReg(MatchInfo.Base);
MI.getOperand(2).setReg(NewOffset.getReg(0));
Observer.changedInstr(MI);
return true;
}
bool CombinerHelper::tryCombine(MachineInstr &MI) {
if (tryCombineCopy(MI))
return true;
if (tryCombineExtendingLoads(MI))
return true;
if (tryCombineIndexedLoadStore(MI))
return true;
return false;
}