//===------- VectorCombine.cpp - Optimize partial vector operations -------===// // // 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 // //===----------------------------------------------------------------------===// // // This pass optimizes scalar/vector interactions using target cost models. The // transforms implemented here may not fit in traditional loop-based or SLP // vectorization passes. // //===----------------------------------------------------------------------===// #include "llvm/Transforms/Vectorize/VectorCombine.h" #include "llvm/ADT/DenseMap.h" #include "llvm/ADT/STLExtras.h" #include "llvm/ADT/ScopeExit.h" #include "llvm/ADT/Statistic.h" #include "llvm/Analysis/AssumptionCache.h" #include "llvm/Analysis/BasicAliasAnalysis.h" #include "llvm/Analysis/GlobalsModRef.h" #include "llvm/Analysis/Loads.h" #include "llvm/Analysis/TargetTransformInfo.h" #include "llvm/Analysis/ValueTracking.h" #include "llvm/Analysis/VectorUtils.h" #include "llvm/IR/Dominators.h" #include "llvm/IR/Function.h" #include "llvm/IR/IRBuilder.h" #include "llvm/IR/PatternMatch.h" #include "llvm/Support/CommandLine.h" #include "llvm/Transforms/Utils/Local.h" #include "llvm/Transforms/Utils/LoopUtils.h" #include #include #define DEBUG_TYPE "vector-combine" #include "llvm/Transforms/Utils/InstructionWorklist.h" using namespace llvm; using namespace llvm::PatternMatch; STATISTIC(NumVecLoad, "Number of vector loads formed"); STATISTIC(NumVecCmp, "Number of vector compares formed"); STATISTIC(NumVecBO, "Number of vector binops formed"); STATISTIC(NumVecCmpBO, "Number of vector compare + binop formed"); STATISTIC(NumShufOfBitcast, "Number of shuffles moved after bitcast"); STATISTIC(NumScalarBO, "Number of scalar binops formed"); STATISTIC(NumScalarCmp, "Number of scalar compares formed"); static cl::opt DisableVectorCombine( "disable-vector-combine", cl::init(false), cl::Hidden, cl::desc("Disable all vector combine transforms")); static cl::opt DisableBinopExtractShuffle( "disable-binop-extract-shuffle", cl::init(false), cl::Hidden, cl::desc("Disable binop extract to shuffle transforms")); static cl::opt MaxInstrsToScan( "vector-combine-max-scan-instrs", cl::init(30), cl::Hidden, cl::desc("Max number of instructions to scan for vector combining.")); static const unsigned InvalidIndex = std::numeric_limits::max(); namespace { class VectorCombine { public: VectorCombine(Function &F, const TargetTransformInfo &TTI, const DominatorTree &DT, AAResults &AA, AssumptionCache &AC, const DataLayout *DL, bool TryEarlyFoldsOnly) : F(F), Builder(F.getContext()), TTI(TTI), DT(DT), AA(AA), AC(AC), DL(DL), TryEarlyFoldsOnly(TryEarlyFoldsOnly) {} bool run(); private: Function &F; IRBuilder<> Builder; const TargetTransformInfo &TTI; const DominatorTree &DT; AAResults &AA; AssumptionCache &AC; const DataLayout *DL; /// If true, only perform beneficial early IR transforms. Do not introduce new /// vector operations. bool TryEarlyFoldsOnly; InstructionWorklist Worklist; // TODO: Direct calls from the top-level "run" loop use a plain "Instruction" // parameter. That should be updated to specific sub-classes because the // run loop was changed to dispatch on opcode. bool vectorizeLoadInsert(Instruction &I); bool widenSubvectorLoad(Instruction &I); ExtractElementInst *getShuffleExtract(ExtractElementInst *Ext0, ExtractElementInst *Ext1, unsigned PreferredExtractIndex) const; bool isExtractExtractCheap(ExtractElementInst *Ext0, ExtractElementInst *Ext1, const Instruction &I, ExtractElementInst *&ConvertToShuffle, unsigned PreferredExtractIndex); void foldExtExtCmp(ExtractElementInst *Ext0, ExtractElementInst *Ext1, Instruction &I); void foldExtExtBinop(ExtractElementInst *Ext0, ExtractElementInst *Ext1, Instruction &I); bool foldExtractExtract(Instruction &I); bool foldInsExtFNeg(Instruction &I); bool foldBitcastShuffle(Instruction &I); bool scalarizeBinopOrCmp(Instruction &I); bool scalarizeVPIntrinsic(Instruction &I); bool foldExtractedCmps(Instruction &I); bool foldSingleElementStore(Instruction &I); bool scalarizeLoadExtract(Instruction &I); bool foldShuffleOfBinops(Instruction &I); bool foldShuffleOfCastops(Instruction &I); bool foldShuffleOfShuffles(Instruction &I); bool foldShuffleToIdentity(Instruction &I); bool foldShuffleFromReductions(Instruction &I); bool foldCastFromReductions(Instruction &I); bool foldSelectShuffle(Instruction &I, bool FromReduction = false); void replaceValue(Value &Old, Value &New) { Old.replaceAllUsesWith(&New); if (auto *NewI = dyn_cast(&New)) { New.takeName(&Old); Worklist.pushUsersToWorkList(*NewI); Worklist.pushValue(NewI); } Worklist.pushValue(&Old); } void eraseInstruction(Instruction &I) { for (Value *Op : I.operands()) Worklist.pushValue(Op); Worklist.remove(&I); I.eraseFromParent(); } }; } // namespace /// Return the source operand of a potentially bitcasted value. If there is no /// bitcast, return the input value itself. static Value *peekThroughBitcasts(Value *V) { while (auto *BitCast = dyn_cast(V)) V = BitCast->getOperand(0); return V; } static bool canWidenLoad(LoadInst *Load, const TargetTransformInfo &TTI) { // Do not widen load if atomic/volatile or under asan/hwasan/memtag/tsan. // The widened load may load data from dirty regions or create data races // non-existent in the source. if (!Load || !Load->isSimple() || !Load->hasOneUse() || Load->getFunction()->hasFnAttribute(Attribute::SanitizeMemTag) || mustSuppressSpeculation(*Load)) return false; // We are potentially transforming byte-sized (8-bit) memory accesses, so make // sure we have all of our type-based constraints in place for this target. Type *ScalarTy = Load->getType()->getScalarType(); uint64_t ScalarSize = ScalarTy->getPrimitiveSizeInBits(); unsigned MinVectorSize = TTI.getMinVectorRegisterBitWidth(); if (!ScalarSize || !MinVectorSize || MinVectorSize % ScalarSize != 0 || ScalarSize % 8 != 0) return false; return true; } bool VectorCombine::vectorizeLoadInsert(Instruction &I) { // Match insert into fixed vector of scalar value. // TODO: Handle non-zero insert index. Value *Scalar; if (!match(&I, m_InsertElt(m_Undef(), m_Value(Scalar), m_ZeroInt())) || !Scalar->hasOneUse()) return false; // Optionally match an extract from another vector. Value *X; bool HasExtract = match(Scalar, m_ExtractElt(m_Value(X), m_ZeroInt())); if (!HasExtract) X = Scalar; auto *Load = dyn_cast(X); if (!canWidenLoad(Load, TTI)) return false; Type *ScalarTy = Scalar->getType(); uint64_t ScalarSize = ScalarTy->getPrimitiveSizeInBits(); unsigned MinVectorSize = TTI.getMinVectorRegisterBitWidth(); // Check safety of replacing the scalar load with a larger vector load. // We use minimal alignment (maximum flexibility) because we only care about // the dereferenceable region. When calculating cost and creating a new op, // we may use a larger value based on alignment attributes. Value *SrcPtr = Load->getPointerOperand()->stripPointerCasts(); assert(isa(SrcPtr->getType()) && "Expected a pointer type"); unsigned MinVecNumElts = MinVectorSize / ScalarSize; auto *MinVecTy = VectorType::get(ScalarTy, MinVecNumElts, false); unsigned OffsetEltIndex = 0; Align Alignment = Load->getAlign(); if (!isSafeToLoadUnconditionally(SrcPtr, MinVecTy, Align(1), *DL, Load, &AC, &DT)) { // It is not safe to load directly from the pointer, but we can still peek // through gep offsets and check if it safe to load from a base address with // updated alignment. If it is, we can shuffle the element(s) into place // after loading. unsigned OffsetBitWidth = DL->getIndexTypeSizeInBits(SrcPtr->getType()); APInt Offset(OffsetBitWidth, 0); SrcPtr = SrcPtr->stripAndAccumulateInBoundsConstantOffsets(*DL, Offset); // We want to shuffle the result down from a high element of a vector, so // the offset must be positive. if (Offset.isNegative()) return false; // The offset must be a multiple of the scalar element to shuffle cleanly // in the element's size. uint64_t ScalarSizeInBytes = ScalarSize / 8; if (Offset.urem(ScalarSizeInBytes) != 0) return false; // If we load MinVecNumElts, will our target element still be loaded? OffsetEltIndex = Offset.udiv(ScalarSizeInBytes).getZExtValue(); if (OffsetEltIndex >= MinVecNumElts) return false; if (!isSafeToLoadUnconditionally(SrcPtr, MinVecTy, Align(1), *DL, Load, &AC, &DT)) return false; // Update alignment with offset value. Note that the offset could be negated // to more accurately represent "(new) SrcPtr - Offset = (old) SrcPtr", but // negation does not change the result of the alignment calculation. Alignment = commonAlignment(Alignment, Offset.getZExtValue()); } // Original pattern: insertelt undef, load [free casts of] PtrOp, 0 // Use the greater of the alignment on the load or its source pointer. Alignment = std::max(SrcPtr->getPointerAlignment(*DL), Alignment); Type *LoadTy = Load->getType(); unsigned AS = Load->getPointerAddressSpace(); InstructionCost OldCost = TTI.getMemoryOpCost(Instruction::Load, LoadTy, Alignment, AS); APInt DemandedElts = APInt::getOneBitSet(MinVecNumElts, 0); TTI::TargetCostKind CostKind = TTI::TCK_RecipThroughput; OldCost += TTI.getScalarizationOverhead(MinVecTy, DemandedElts, /* Insert */ true, HasExtract, CostKind); // New pattern: load VecPtr InstructionCost NewCost = TTI.getMemoryOpCost(Instruction::Load, MinVecTy, Alignment, AS); // Optionally, we are shuffling the loaded vector element(s) into place. // For the mask set everything but element 0 to undef to prevent poison from // propagating from the extra loaded memory. This will also optionally // shrink/grow the vector from the loaded size to the output size. // We assume this operation has no cost in codegen if there was no offset. // Note that we could use freeze to avoid poison problems, but then we might // still need a shuffle to change the vector size. auto *Ty = cast(I.getType()); unsigned OutputNumElts = Ty->getNumElements(); SmallVector Mask(OutputNumElts, PoisonMaskElem); assert(OffsetEltIndex < MinVecNumElts && "Address offset too big"); Mask[0] = OffsetEltIndex; if (OffsetEltIndex) NewCost += TTI.getShuffleCost(TTI::SK_PermuteSingleSrc, MinVecTy, Mask); // We can aggressively convert to the vector form because the backend can // invert this transform if it does not result in a performance win. if (OldCost < NewCost || !NewCost.isValid()) return false; // It is safe and potentially profitable to load a vector directly: // inselt undef, load Scalar, 0 --> load VecPtr IRBuilder<> Builder(Load); Value *CastedPtr = Builder.CreatePointerBitCastOrAddrSpaceCast(SrcPtr, Builder.getPtrTy(AS)); Value *VecLd = Builder.CreateAlignedLoad(MinVecTy, CastedPtr, Alignment); VecLd = Builder.CreateShuffleVector(VecLd, Mask); replaceValue(I, *VecLd); ++NumVecLoad; return true; } /// If we are loading a vector and then inserting it into a larger vector with /// undefined elements, try to load the larger vector and eliminate the insert. /// This removes a shuffle in IR and may allow combining of other loaded values. bool VectorCombine::widenSubvectorLoad(Instruction &I) { // Match subvector insert of fixed vector. auto *Shuf = cast(&I); if (!Shuf->isIdentityWithPadding()) return false; // Allow a non-canonical shuffle mask that is choosing elements from op1. unsigned NumOpElts = cast(Shuf->getOperand(0)->getType())->getNumElements(); unsigned OpIndex = any_of(Shuf->getShuffleMask(), [&NumOpElts](int M) { return M >= (int)(NumOpElts); }); auto *Load = dyn_cast(Shuf->getOperand(OpIndex)); if (!canWidenLoad(Load, TTI)) return false; // We use minimal alignment (maximum flexibility) because we only care about // the dereferenceable region. When calculating cost and creating a new op, // we may use a larger value based on alignment attributes. auto *Ty = cast(I.getType()); Value *SrcPtr = Load->getPointerOperand()->stripPointerCasts(); assert(isa(SrcPtr->getType()) && "Expected a pointer type"); Align Alignment = Load->getAlign(); if (!isSafeToLoadUnconditionally(SrcPtr, Ty, Align(1), *DL, Load, &AC, &DT)) return false; Alignment = std::max(SrcPtr->getPointerAlignment(*DL), Alignment); Type *LoadTy = Load->getType(); unsigned AS = Load->getPointerAddressSpace(); // Original pattern: insert_subvector (load PtrOp) // This conservatively assumes that the cost of a subvector insert into an // undef value is 0. We could add that cost if the cost model accurately // reflects the real cost of that operation. InstructionCost OldCost = TTI.getMemoryOpCost(Instruction::Load, LoadTy, Alignment, AS); // New pattern: load PtrOp InstructionCost NewCost = TTI.getMemoryOpCost(Instruction::Load, Ty, Alignment, AS); // We can aggressively convert to the vector form because the backend can // invert this transform if it does not result in a performance win. if (OldCost < NewCost || !NewCost.isValid()) return false; IRBuilder<> Builder(Load); Value *CastedPtr = Builder.CreatePointerBitCastOrAddrSpaceCast(SrcPtr, Builder.getPtrTy(AS)); Value *VecLd = Builder.CreateAlignedLoad(Ty, CastedPtr, Alignment); replaceValue(I, *VecLd); ++NumVecLoad; return true; } /// Determine which, if any, of the inputs should be replaced by a shuffle /// followed by extract from a different index. ExtractElementInst *VectorCombine::getShuffleExtract( ExtractElementInst *Ext0, ExtractElementInst *Ext1, unsigned PreferredExtractIndex = InvalidIndex) const { auto *Index0C = dyn_cast(Ext0->getIndexOperand()); auto *Index1C = dyn_cast(Ext1->getIndexOperand()); assert(Index0C && Index1C && "Expected constant extract indexes"); unsigned Index0 = Index0C->getZExtValue(); unsigned Index1 = Index1C->getZExtValue(); // If the extract indexes are identical, no shuffle is needed. if (Index0 == Index1) return nullptr; Type *VecTy = Ext0->getVectorOperand()->getType(); TTI::TargetCostKind CostKind = TTI::TCK_RecipThroughput; assert(VecTy == Ext1->getVectorOperand()->getType() && "Need matching types"); InstructionCost Cost0 = TTI.getVectorInstrCost(*Ext0, VecTy, CostKind, Index0); InstructionCost Cost1 = TTI.getVectorInstrCost(*Ext1, VecTy, CostKind, Index1); // If both costs are invalid no shuffle is needed if (!Cost0.isValid() && !Cost1.isValid()) return nullptr; // We are extracting from 2 different indexes, so one operand must be shuffled // before performing a vector operation and/or extract. The more expensive // extract will be replaced by a shuffle. if (Cost0 > Cost1) return Ext0; if (Cost1 > Cost0) return Ext1; // If the costs are equal and there is a preferred extract index, shuffle the // opposite operand. if (PreferredExtractIndex == Index0) return Ext1; if (PreferredExtractIndex == Index1) return Ext0; // Otherwise, replace the extract with the higher index. return Index0 > Index1 ? Ext0 : Ext1; } /// Compare the relative costs of 2 extracts followed by scalar operation vs. /// vector operation(s) followed by extract. Return true if the existing /// instructions are cheaper than a vector alternative. Otherwise, return false /// and if one of the extracts should be transformed to a shufflevector, set /// \p ConvertToShuffle to that extract instruction. bool VectorCombine::isExtractExtractCheap(ExtractElementInst *Ext0, ExtractElementInst *Ext1, const Instruction &I, ExtractElementInst *&ConvertToShuffle, unsigned PreferredExtractIndex) { auto *Ext0IndexC = dyn_cast(Ext0->getOperand(1)); auto *Ext1IndexC = dyn_cast(Ext1->getOperand(1)); assert(Ext0IndexC && Ext1IndexC && "Expected constant extract indexes"); unsigned Opcode = I.getOpcode(); Type *ScalarTy = Ext0->getType(); auto *VecTy = cast(Ext0->getOperand(0)->getType()); InstructionCost ScalarOpCost, VectorOpCost; // Get cost estimates for scalar and vector versions of the operation. bool IsBinOp = Instruction::isBinaryOp(Opcode); if (IsBinOp) { ScalarOpCost = TTI.getArithmeticInstrCost(Opcode, ScalarTy); VectorOpCost = TTI.getArithmeticInstrCost(Opcode, VecTy); } else { assert((Opcode == Instruction::ICmp || Opcode == Instruction::FCmp) && "Expected a compare"); CmpInst::Predicate Pred = cast(I).getPredicate(); ScalarOpCost = TTI.getCmpSelInstrCost( Opcode, ScalarTy, CmpInst::makeCmpResultType(ScalarTy), Pred); VectorOpCost = TTI.getCmpSelInstrCost( Opcode, VecTy, CmpInst::makeCmpResultType(VecTy), Pred); } // Get cost estimates for the extract elements. These costs will factor into // both sequences. unsigned Ext0Index = Ext0IndexC->getZExtValue(); unsigned Ext1Index = Ext1IndexC->getZExtValue(); TTI::TargetCostKind CostKind = TTI::TCK_RecipThroughput; InstructionCost Extract0Cost = TTI.getVectorInstrCost(*Ext0, VecTy, CostKind, Ext0Index); InstructionCost Extract1Cost = TTI.getVectorInstrCost(*Ext1, VecTy, CostKind, Ext1Index); // A more expensive extract will always be replaced by a splat shuffle. // For example, if Ext0 is more expensive: // opcode (extelt V0, Ext0), (ext V1, Ext1) --> // extelt (opcode (splat V0, Ext0), V1), Ext1 // TODO: Evaluate whether that always results in lowest cost. Alternatively, // check the cost of creating a broadcast shuffle and shuffling both // operands to element 0. InstructionCost CheapExtractCost = std::min(Extract0Cost, Extract1Cost); // Extra uses of the extracts mean that we include those costs in the // vector total because those instructions will not be eliminated. InstructionCost OldCost, NewCost; if (Ext0->getOperand(0) == Ext1->getOperand(0) && Ext0Index == Ext1Index) { // Handle a special case. If the 2 extracts are identical, adjust the // formulas to account for that. The extra use charge allows for either the // CSE'd pattern or an unoptimized form with identical values: // opcode (extelt V, C), (extelt V, C) --> extelt (opcode V, V), C bool HasUseTax = Ext0 == Ext1 ? !Ext0->hasNUses(2) : !Ext0->hasOneUse() || !Ext1->hasOneUse(); OldCost = CheapExtractCost + ScalarOpCost; NewCost = VectorOpCost + CheapExtractCost + HasUseTax * CheapExtractCost; } else { // Handle the general case. Each extract is actually a different value: // opcode (extelt V0, C0), (extelt V1, C1) --> extelt (opcode V0, V1), C OldCost = Extract0Cost + Extract1Cost + ScalarOpCost; NewCost = VectorOpCost + CheapExtractCost + !Ext0->hasOneUse() * Extract0Cost + !Ext1->hasOneUse() * Extract1Cost; } ConvertToShuffle = getShuffleExtract(Ext0, Ext1, PreferredExtractIndex); if (ConvertToShuffle) { if (IsBinOp && DisableBinopExtractShuffle) return true; // If we are extracting from 2 different indexes, then one operand must be // shuffled before performing the vector operation. The shuffle mask is // poison except for 1 lane that is being translated to the remaining // extraction lane. Therefore, it is a splat shuffle. Ex: // ShufMask = { poison, poison, 0, poison } // TODO: The cost model has an option for a "broadcast" shuffle // (splat-from-element-0), but no option for a more general splat. NewCost += TTI.getShuffleCost(TargetTransformInfo::SK_PermuteSingleSrc, VecTy); } // Aggressively form a vector op if the cost is equal because the transform // may enable further optimization. // Codegen can reverse this transform (scalarize) if it was not profitable. return OldCost < NewCost; } /// Create a shuffle that translates (shifts) 1 element from the input vector /// to a new element location. static Value *createShiftShuffle(Value *Vec, unsigned OldIndex, unsigned NewIndex, IRBuilder<> &Builder) { // The shuffle mask is poison except for 1 lane that is being translated // to the new element index. Example for OldIndex == 2 and NewIndex == 0: // ShufMask = { 2, poison, poison, poison } auto *VecTy = cast(Vec->getType()); SmallVector ShufMask(VecTy->getNumElements(), PoisonMaskElem); ShufMask[NewIndex] = OldIndex; return Builder.CreateShuffleVector(Vec, ShufMask, "shift"); } /// Given an extract element instruction with constant index operand, shuffle /// the source vector (shift the scalar element) to a NewIndex for extraction. /// Return null if the input can be constant folded, so that we are not creating /// unnecessary instructions. static ExtractElementInst *translateExtract(ExtractElementInst *ExtElt, unsigned NewIndex, IRBuilder<> &Builder) { // Shufflevectors can only be created for fixed-width vectors. if (!isa(ExtElt->getOperand(0)->getType())) return nullptr; // If the extract can be constant-folded, this code is unsimplified. Defer // to other passes to handle that. Value *X = ExtElt->getVectorOperand(); Value *C = ExtElt->getIndexOperand(); assert(isa(C) && "Expected a constant index operand"); if (isa(X)) return nullptr; Value *Shuf = createShiftShuffle(X, cast(C)->getZExtValue(), NewIndex, Builder); return cast(Builder.CreateExtractElement(Shuf, NewIndex)); } /// Try to reduce extract element costs by converting scalar compares to vector /// compares followed by extract. /// cmp (ext0 V0, C), (ext1 V1, C) void VectorCombine::foldExtExtCmp(ExtractElementInst *Ext0, ExtractElementInst *Ext1, Instruction &I) { assert(isa(&I) && "Expected a compare"); assert(cast(Ext0->getIndexOperand())->getZExtValue() == cast(Ext1->getIndexOperand())->getZExtValue() && "Expected matching constant extract indexes"); // cmp Pred (extelt V0, C), (extelt V1, C) --> extelt (cmp Pred V0, V1), C ++NumVecCmp; CmpInst::Predicate Pred = cast(&I)->getPredicate(); Value *V0 = Ext0->getVectorOperand(), *V1 = Ext1->getVectorOperand(); Value *VecCmp = Builder.CreateCmp(Pred, V0, V1); Value *NewExt = Builder.CreateExtractElement(VecCmp, Ext0->getIndexOperand()); replaceValue(I, *NewExt); } /// Try to reduce extract element costs by converting scalar binops to vector /// binops followed by extract. /// bo (ext0 V0, C), (ext1 V1, C) void VectorCombine::foldExtExtBinop(ExtractElementInst *Ext0, ExtractElementInst *Ext1, Instruction &I) { assert(isa(&I) && "Expected a binary operator"); assert(cast(Ext0->getIndexOperand())->getZExtValue() == cast(Ext1->getIndexOperand())->getZExtValue() && "Expected matching constant extract indexes"); // bo (extelt V0, C), (extelt V1, C) --> extelt (bo V0, V1), C ++NumVecBO; Value *V0 = Ext0->getVectorOperand(), *V1 = Ext1->getVectorOperand(); Value *VecBO = Builder.CreateBinOp(cast(&I)->getOpcode(), V0, V1); // All IR flags are safe to back-propagate because any potential poison // created in unused vector elements is discarded by the extract. if (auto *VecBOInst = dyn_cast(VecBO)) VecBOInst->copyIRFlags(&I); Value *NewExt = Builder.CreateExtractElement(VecBO, Ext0->getIndexOperand()); replaceValue(I, *NewExt); } /// Match an instruction with extracted vector operands. bool VectorCombine::foldExtractExtract(Instruction &I) { // It is not safe to transform things like div, urem, etc. because we may // create undefined behavior when executing those on unknown vector elements. if (!isSafeToSpeculativelyExecute(&I)) return false; Instruction *I0, *I1; CmpInst::Predicate Pred = CmpInst::BAD_ICMP_PREDICATE; if (!match(&I, m_Cmp(Pred, m_Instruction(I0), m_Instruction(I1))) && !match(&I, m_BinOp(m_Instruction(I0), m_Instruction(I1)))) return false; Value *V0, *V1; uint64_t C0, C1; if (!match(I0, m_ExtractElt(m_Value(V0), m_ConstantInt(C0))) || !match(I1, m_ExtractElt(m_Value(V1), m_ConstantInt(C1))) || V0->getType() != V1->getType()) return false; // If the scalar value 'I' is going to be re-inserted into a vector, then try // to create an extract to that same element. The extract/insert can be // reduced to a "select shuffle". // TODO: If we add a larger pattern match that starts from an insert, this // probably becomes unnecessary. auto *Ext0 = cast(I0); auto *Ext1 = cast(I1); uint64_t InsertIndex = InvalidIndex; if (I.hasOneUse()) match(I.user_back(), m_InsertElt(m_Value(), m_Value(), m_ConstantInt(InsertIndex))); ExtractElementInst *ExtractToChange; if (isExtractExtractCheap(Ext0, Ext1, I, ExtractToChange, InsertIndex)) return false; if (ExtractToChange) { unsigned CheapExtractIdx = ExtractToChange == Ext0 ? C1 : C0; ExtractElementInst *NewExtract = translateExtract(ExtractToChange, CheapExtractIdx, Builder); if (!NewExtract) return false; if (ExtractToChange == Ext0) Ext0 = NewExtract; else Ext1 = NewExtract; } if (Pred != CmpInst::BAD_ICMP_PREDICATE) foldExtExtCmp(Ext0, Ext1, I); else foldExtExtBinop(Ext0, Ext1, I); Worklist.push(Ext0); Worklist.push(Ext1); return true; } /// Try to replace an extract + scalar fneg + insert with a vector fneg + /// shuffle. bool VectorCombine::foldInsExtFNeg(Instruction &I) { // Match an insert (op (extract)) pattern. Value *DestVec; uint64_t Index; Instruction *FNeg; if (!match(&I, m_InsertElt(m_Value(DestVec), m_OneUse(m_Instruction(FNeg)), m_ConstantInt(Index)))) return false; // Note: This handles the canonical fneg instruction and "fsub -0.0, X". Value *SrcVec; Instruction *Extract; if (!match(FNeg, m_FNeg(m_CombineAnd( m_Instruction(Extract), m_ExtractElt(m_Value(SrcVec), m_SpecificInt(Index)))))) return false; // TODO: We could handle this with a length-changing shuffle. auto *VecTy = cast(I.getType()); if (SrcVec->getType() != VecTy) return false; // Ignore bogus insert/extract index. unsigned NumElts = VecTy->getNumElements(); if (Index >= NumElts) return false; // We are inserting the negated element into the same lane that we extracted // from. This is equivalent to a select-shuffle that chooses all but the // negated element from the destination vector. SmallVector Mask(NumElts); std::iota(Mask.begin(), Mask.end(), 0); Mask[Index] = Index + NumElts; Type *ScalarTy = VecTy->getScalarType(); TTI::TargetCostKind CostKind = TTI::TCK_RecipThroughput; InstructionCost OldCost = TTI.getArithmeticInstrCost(Instruction::FNeg, ScalarTy) + TTI.getVectorInstrCost(I, VecTy, CostKind, Index); // If the extract has one use, it will be eliminated, so count it in the // original cost. If it has more than one use, ignore the cost because it will // be the same before/after. if (Extract->hasOneUse()) OldCost += TTI.getVectorInstrCost(*Extract, VecTy, CostKind, Index); InstructionCost NewCost = TTI.getArithmeticInstrCost(Instruction::FNeg, VecTy) + TTI.getShuffleCost(TargetTransformInfo::SK_Select, VecTy, Mask); if (NewCost > OldCost) return false; // insertelt DestVec, (fneg (extractelt SrcVec, Index)), Index --> // shuffle DestVec, (fneg SrcVec), Mask Value *VecFNeg = Builder.CreateFNegFMF(SrcVec, FNeg); Value *Shuf = Builder.CreateShuffleVector(DestVec, VecFNeg, Mask); replaceValue(I, *Shuf); return true; } /// If this is a bitcast of a shuffle, try to bitcast the source vector to the /// destination type followed by shuffle. This can enable further transforms by /// moving bitcasts or shuffles together. bool VectorCombine::foldBitcastShuffle(Instruction &I) { Value *V0, *V1; ArrayRef Mask; if (!match(&I, m_BitCast(m_OneUse( m_Shuffle(m_Value(V0), m_Value(V1), m_Mask(Mask)))))) return false; // 1) Do not fold bitcast shuffle for scalable type. First, shuffle cost for // scalable type is unknown; Second, we cannot reason if the narrowed shuffle // mask for scalable type is a splat or not. // 2) Disallow non-vector casts. // TODO: We could allow any shuffle. auto *DestTy = dyn_cast(I.getType()); auto *SrcTy = dyn_cast(V0->getType()); if (!DestTy || !SrcTy) return false; unsigned DestEltSize = DestTy->getScalarSizeInBits(); unsigned SrcEltSize = SrcTy->getScalarSizeInBits(); if (SrcTy->getPrimitiveSizeInBits() % DestEltSize != 0) return false; bool IsUnary = isa(V1); // For binary shuffles, only fold bitcast(shuffle(X,Y)) // if it won't increase the number of bitcasts. if (!IsUnary) { auto *BCTy0 = dyn_cast(peekThroughBitcasts(V0)->getType()); auto *BCTy1 = dyn_cast(peekThroughBitcasts(V1)->getType()); if (!(BCTy0 && BCTy0->getElementType() == DestTy->getElementType()) && !(BCTy1 && BCTy1->getElementType() == DestTy->getElementType())) return false; } SmallVector NewMask; if (DestEltSize <= SrcEltSize) { // The bitcast is from wide to narrow/equal elements. The shuffle mask can // always be expanded to the equivalent form choosing narrower elements. assert(SrcEltSize % DestEltSize == 0 && "Unexpected shuffle mask"); unsigned ScaleFactor = SrcEltSize / DestEltSize; narrowShuffleMaskElts(ScaleFactor, Mask, NewMask); } else { // The bitcast is from narrow elements to wide elements. The shuffle mask // must choose consecutive elements to allow casting first. assert(DestEltSize % SrcEltSize == 0 && "Unexpected shuffle mask"); unsigned ScaleFactor = DestEltSize / SrcEltSize; if (!widenShuffleMaskElts(ScaleFactor, Mask, NewMask)) return false; } // Bitcast the shuffle src - keep its original width but using the destination // scalar type. unsigned NumSrcElts = SrcTy->getPrimitiveSizeInBits() / DestEltSize; auto *NewShuffleTy = FixedVectorType::get(DestTy->getScalarType(), NumSrcElts); auto *OldShuffleTy = FixedVectorType::get(SrcTy->getScalarType(), Mask.size()); unsigned NumOps = IsUnary ? 1 : 2; // The new shuffle must not cost more than the old shuffle. TargetTransformInfo::TargetCostKind CK = TargetTransformInfo::TCK_RecipThroughput; TargetTransformInfo::ShuffleKind SK = IsUnary ? TargetTransformInfo::SK_PermuteSingleSrc : TargetTransformInfo::SK_PermuteTwoSrc; InstructionCost DestCost = TTI.getShuffleCost(SK, NewShuffleTy, NewMask, CK) + (NumOps * TTI.getCastInstrCost(Instruction::BitCast, NewShuffleTy, SrcTy, TargetTransformInfo::CastContextHint::None, CK)); InstructionCost SrcCost = TTI.getShuffleCost(SK, SrcTy, Mask, CK) + TTI.getCastInstrCost(Instruction::BitCast, DestTy, OldShuffleTy, TargetTransformInfo::CastContextHint::None, CK); if (DestCost > SrcCost || !DestCost.isValid()) return false; // bitcast (shuf V0, V1, MaskC) --> shuf (bitcast V0), (bitcast V1), MaskC' ++NumShufOfBitcast; Value *CastV0 = Builder.CreateBitCast(peekThroughBitcasts(V0), NewShuffleTy); Value *CastV1 = Builder.CreateBitCast(peekThroughBitcasts(V1), NewShuffleTy); Value *Shuf = Builder.CreateShuffleVector(CastV0, CastV1, NewMask); replaceValue(I, *Shuf); return true; } /// VP Intrinsics whose vector operands are both splat values may be simplified /// into the scalar version of the operation and the result splatted. This /// can lead to scalarization down the line. bool VectorCombine::scalarizeVPIntrinsic(Instruction &I) { if (!isa(I)) return false; VPIntrinsic &VPI = cast(I); Value *Op0 = VPI.getArgOperand(0); Value *Op1 = VPI.getArgOperand(1); if (!isSplatValue(Op0) || !isSplatValue(Op1)) return false; // Check getSplatValue early in this function, to avoid doing unnecessary // work. Value *ScalarOp0 = getSplatValue(Op0); Value *ScalarOp1 = getSplatValue(Op1); if (!ScalarOp0 || !ScalarOp1) return false; // For the binary VP intrinsics supported here, the result on disabled lanes // is a poison value. For now, only do this simplification if all lanes // are active. // TODO: Relax the condition that all lanes are active by using insertelement // on inactive lanes. auto IsAllTrueMask = [](Value *MaskVal) { if (Value *SplattedVal = getSplatValue(MaskVal)) if (auto *ConstValue = dyn_cast(SplattedVal)) return ConstValue->isAllOnesValue(); return false; }; if (!IsAllTrueMask(VPI.getArgOperand(2))) return false; // Check to make sure we support scalarization of the intrinsic Intrinsic::ID IntrID = VPI.getIntrinsicID(); if (!VPBinOpIntrinsic::isVPBinOp(IntrID)) return false; // Calculate cost of splatting both operands into vectors and the vector // intrinsic VectorType *VecTy = cast(VPI.getType()); TTI::TargetCostKind CostKind = TTI::TCK_RecipThroughput; SmallVector Mask; if (auto *FVTy = dyn_cast(VecTy)) Mask.resize(FVTy->getNumElements(), 0); InstructionCost SplatCost = TTI.getVectorInstrCost(Instruction::InsertElement, VecTy, CostKind, 0) + TTI.getShuffleCost(TargetTransformInfo::SK_Broadcast, VecTy, Mask); // Calculate the cost of the VP Intrinsic SmallVector Args; for (Value *V : VPI.args()) Args.push_back(V->getType()); IntrinsicCostAttributes Attrs(IntrID, VecTy, Args); InstructionCost VectorOpCost = TTI.getIntrinsicInstrCost(Attrs, CostKind); InstructionCost OldCost = 2 * SplatCost + VectorOpCost; // Determine scalar opcode std::optional FunctionalOpcode = VPI.getFunctionalOpcode(); std::optional ScalarIntrID = std::nullopt; if (!FunctionalOpcode) { ScalarIntrID = VPI.getFunctionalIntrinsicID(); if (!ScalarIntrID) return false; } // Calculate cost of scalarizing InstructionCost ScalarOpCost = 0; if (ScalarIntrID) { IntrinsicCostAttributes Attrs(*ScalarIntrID, VecTy->getScalarType(), Args); ScalarOpCost = TTI.getIntrinsicInstrCost(Attrs, CostKind); } else { ScalarOpCost = TTI.getArithmeticInstrCost(*FunctionalOpcode, VecTy->getScalarType()); } // The existing splats may be kept around if other instructions use them. InstructionCost CostToKeepSplats = (SplatCost * !Op0->hasOneUse()) + (SplatCost * !Op1->hasOneUse()); InstructionCost NewCost = ScalarOpCost + SplatCost + CostToKeepSplats; LLVM_DEBUG(dbgs() << "Found a VP Intrinsic to scalarize: " << VPI << "\n"); LLVM_DEBUG(dbgs() << "Cost of Intrinsic: " << OldCost << ", Cost of scalarizing:" << NewCost << "\n"); // We want to scalarize unless the vector variant actually has lower cost. if (OldCost < NewCost || !NewCost.isValid()) return false; // Scalarize the intrinsic ElementCount EC = cast(Op0->getType())->getElementCount(); Value *EVL = VPI.getArgOperand(3); // If the VP op might introduce UB or poison, we can scalarize it provided // that we know the EVL > 0: If the EVL is zero, then the original VP op // becomes a no-op and thus won't be UB, so make sure we don't introduce UB by // scalarizing it. bool SafeToSpeculate; if (ScalarIntrID) SafeToSpeculate = Intrinsic::getAttributes(I.getContext(), *ScalarIntrID) .hasFnAttr(Attribute::AttrKind::Speculatable); else SafeToSpeculate = isSafeToSpeculativelyExecuteWithOpcode( *FunctionalOpcode, &VPI, nullptr, &AC, &DT); if (!SafeToSpeculate && !isKnownNonZero(EVL, SimplifyQuery(*DL, &DT, &AC, &VPI))) return false; Value *ScalarVal = ScalarIntrID ? Builder.CreateIntrinsic(VecTy->getScalarType(), *ScalarIntrID, {ScalarOp0, ScalarOp1}) : Builder.CreateBinOp((Instruction::BinaryOps)(*FunctionalOpcode), ScalarOp0, ScalarOp1); replaceValue(VPI, *Builder.CreateVectorSplat(EC, ScalarVal)); return true; } /// Match a vector binop or compare instruction with at least one inserted /// scalar operand and convert to scalar binop/cmp followed by insertelement. bool VectorCombine::scalarizeBinopOrCmp(Instruction &I) { CmpInst::Predicate Pred = CmpInst::BAD_ICMP_PREDICATE; Value *Ins0, *Ins1; if (!match(&I, m_BinOp(m_Value(Ins0), m_Value(Ins1))) && !match(&I, m_Cmp(Pred, m_Value(Ins0), m_Value(Ins1)))) return false; // Do not convert the vector condition of a vector select into a scalar // condition. That may cause problems for codegen because of differences in // boolean formats and register-file transfers. // TODO: Can we account for that in the cost model? bool IsCmp = Pred != CmpInst::Predicate::BAD_ICMP_PREDICATE; if (IsCmp) for (User *U : I.users()) if (match(U, m_Select(m_Specific(&I), m_Value(), m_Value()))) return false; // Match against one or both scalar values being inserted into constant // vectors: // vec_op VecC0, (inselt VecC1, V1, Index) // vec_op (inselt VecC0, V0, Index), VecC1 // vec_op (inselt VecC0, V0, Index), (inselt VecC1, V1, Index) // TODO: Deal with mismatched index constants and variable indexes? Constant *VecC0 = nullptr, *VecC1 = nullptr; Value *V0 = nullptr, *V1 = nullptr; uint64_t Index0 = 0, Index1 = 0; if (!match(Ins0, m_InsertElt(m_Constant(VecC0), m_Value(V0), m_ConstantInt(Index0))) && !match(Ins0, m_Constant(VecC0))) return false; if (!match(Ins1, m_InsertElt(m_Constant(VecC1), m_Value(V1), m_ConstantInt(Index1))) && !match(Ins1, m_Constant(VecC1))) return false; bool IsConst0 = !V0; bool IsConst1 = !V1; if (IsConst0 && IsConst1) return false; if (!IsConst0 && !IsConst1 && Index0 != Index1) return false; // Bail for single insertion if it is a load. // TODO: Handle this once getVectorInstrCost can cost for load/stores. auto *I0 = dyn_cast_or_null(V0); auto *I1 = dyn_cast_or_null(V1); if ((IsConst0 && I1 && I1->mayReadFromMemory()) || (IsConst1 && I0 && I0->mayReadFromMemory())) return false; uint64_t Index = IsConst0 ? Index1 : Index0; Type *ScalarTy = IsConst0 ? V1->getType() : V0->getType(); Type *VecTy = I.getType(); assert(VecTy->isVectorTy() && (IsConst0 || IsConst1 || V0->getType() == V1->getType()) && (ScalarTy->isIntegerTy() || ScalarTy->isFloatingPointTy() || ScalarTy->isPointerTy()) && "Unexpected types for insert element into binop or cmp"); unsigned Opcode = I.getOpcode(); InstructionCost ScalarOpCost, VectorOpCost; if (IsCmp) { CmpInst::Predicate Pred = cast(I).getPredicate(); ScalarOpCost = TTI.getCmpSelInstrCost( Opcode, ScalarTy, CmpInst::makeCmpResultType(ScalarTy), Pred); VectorOpCost = TTI.getCmpSelInstrCost( Opcode, VecTy, CmpInst::makeCmpResultType(VecTy), Pred); } else { ScalarOpCost = TTI.getArithmeticInstrCost(Opcode, ScalarTy); VectorOpCost = TTI.getArithmeticInstrCost(Opcode, VecTy); } // Get cost estimate for the insert element. This cost will factor into // both sequences. TTI::TargetCostKind CostKind = TTI::TCK_RecipThroughput; InstructionCost InsertCost = TTI.getVectorInstrCost( Instruction::InsertElement, VecTy, CostKind, Index); InstructionCost OldCost = (IsConst0 ? 0 : InsertCost) + (IsConst1 ? 0 : InsertCost) + VectorOpCost; InstructionCost NewCost = ScalarOpCost + InsertCost + (IsConst0 ? 0 : !Ins0->hasOneUse() * InsertCost) + (IsConst1 ? 0 : !Ins1->hasOneUse() * InsertCost); // We want to scalarize unless the vector variant actually has lower cost. if (OldCost < NewCost || !NewCost.isValid()) return false; // vec_op (inselt VecC0, V0, Index), (inselt VecC1, V1, Index) --> // inselt NewVecC, (scalar_op V0, V1), Index if (IsCmp) ++NumScalarCmp; else ++NumScalarBO; // For constant cases, extract the scalar element, this should constant fold. if (IsConst0) V0 = ConstantExpr::getExtractElement(VecC0, Builder.getInt64(Index)); if (IsConst1) V1 = ConstantExpr::getExtractElement(VecC1, Builder.getInt64(Index)); Value *Scalar = IsCmp ? Builder.CreateCmp(Pred, V0, V1) : Builder.CreateBinOp((Instruction::BinaryOps)Opcode, V0, V1); Scalar->setName(I.getName() + ".scalar"); // All IR flags are safe to back-propagate. There is no potential for extra // poison to be created by the scalar instruction. if (auto *ScalarInst = dyn_cast(Scalar)) ScalarInst->copyIRFlags(&I); // Fold the vector constants in the original vectors into a new base vector. Value *NewVecC = IsCmp ? Builder.CreateCmp(Pred, VecC0, VecC1) : Builder.CreateBinOp((Instruction::BinaryOps)Opcode, VecC0, VecC1); Value *Insert = Builder.CreateInsertElement(NewVecC, Scalar, Index); replaceValue(I, *Insert); return true; } /// Try to combine a scalar binop + 2 scalar compares of extracted elements of /// a vector into vector operations followed by extract. Note: The SLP pass /// may miss this pattern because of implementation problems. bool VectorCombine::foldExtractedCmps(Instruction &I) { // We are looking for a scalar binop of booleans. // binop i1 (cmp Pred I0, C0), (cmp Pred I1, C1) if (!I.isBinaryOp() || !I.getType()->isIntegerTy(1)) return false; // The compare predicates should match, and each compare should have a // constant operand. // TODO: Relax the one-use constraints. Value *B0 = I.getOperand(0), *B1 = I.getOperand(1); Instruction *I0, *I1; Constant *C0, *C1; CmpInst::Predicate P0, P1; if (!match(B0, m_OneUse(m_Cmp(P0, m_Instruction(I0), m_Constant(C0)))) || !match(B1, m_OneUse(m_Cmp(P1, m_Instruction(I1), m_Constant(C1)))) || P0 != P1) return false; // The compare operands must be extracts of the same vector with constant // extract indexes. // TODO: Relax the one-use constraints. Value *X; uint64_t Index0, Index1; if (!match(I0, m_OneUse(m_ExtractElt(m_Value(X), m_ConstantInt(Index0)))) || !match(I1, m_OneUse(m_ExtractElt(m_Specific(X), m_ConstantInt(Index1))))) return false; auto *Ext0 = cast(I0); auto *Ext1 = cast(I1); ExtractElementInst *ConvertToShuf = getShuffleExtract(Ext0, Ext1); if (!ConvertToShuf) return false; // The original scalar pattern is: // binop i1 (cmp Pred (ext X, Index0), C0), (cmp Pred (ext X, Index1), C1) CmpInst::Predicate Pred = P0; unsigned CmpOpcode = CmpInst::isFPPredicate(Pred) ? Instruction::FCmp : Instruction::ICmp; auto *VecTy = dyn_cast(X->getType()); if (!VecTy) return false; TTI::TargetCostKind CostKind = TTI::TCK_RecipThroughput; InstructionCost OldCost = TTI.getVectorInstrCost(*Ext0, VecTy, CostKind, Index0); OldCost += TTI.getVectorInstrCost(*Ext1, VecTy, CostKind, Index1); OldCost += TTI.getCmpSelInstrCost(CmpOpcode, I0->getType(), CmpInst::makeCmpResultType(I0->getType()), Pred) * 2; OldCost += TTI.getArithmeticInstrCost(I.getOpcode(), I.getType()); // The proposed vector pattern is: // vcmp = cmp Pred X, VecC // ext (binop vNi1 vcmp, (shuffle vcmp, Index1)), Index0 int CheapIndex = ConvertToShuf == Ext0 ? Index1 : Index0; int ExpensiveIndex = ConvertToShuf == Ext0 ? Index0 : Index1; auto *CmpTy = cast(CmpInst::makeCmpResultType(X->getType())); InstructionCost NewCost = TTI.getCmpSelInstrCost( CmpOpcode, X->getType(), CmpInst::makeCmpResultType(X->getType()), Pred); SmallVector ShufMask(VecTy->getNumElements(), PoisonMaskElem); ShufMask[CheapIndex] = ExpensiveIndex; NewCost += TTI.getShuffleCost(TargetTransformInfo::SK_PermuteSingleSrc, CmpTy, ShufMask); NewCost += TTI.getArithmeticInstrCost(I.getOpcode(), CmpTy); NewCost += TTI.getVectorInstrCost(*Ext0, CmpTy, CostKind, CheapIndex); // Aggressively form vector ops if the cost is equal because the transform // may enable further optimization. // Codegen can reverse this transform (scalarize) if it was not profitable. if (OldCost < NewCost || !NewCost.isValid()) return false; // Create a vector constant from the 2 scalar constants. SmallVector CmpC(VecTy->getNumElements(), PoisonValue::get(VecTy->getElementType())); CmpC[Index0] = C0; CmpC[Index1] = C1; Value *VCmp = Builder.CreateCmp(Pred, X, ConstantVector::get(CmpC)); Value *Shuf = createShiftShuffle(VCmp, ExpensiveIndex, CheapIndex, Builder); Value *VecLogic = Builder.CreateBinOp(cast(I).getOpcode(), VCmp, Shuf); Value *NewExt = Builder.CreateExtractElement(VecLogic, CheapIndex); replaceValue(I, *NewExt); ++NumVecCmpBO; return true; } // Check if memory loc modified between two instrs in the same BB static bool isMemModifiedBetween(BasicBlock::iterator Begin, BasicBlock::iterator End, const MemoryLocation &Loc, AAResults &AA) { unsigned NumScanned = 0; return std::any_of(Begin, End, [&](const Instruction &Instr) { return isModSet(AA.getModRefInfo(&Instr, Loc)) || ++NumScanned > MaxInstrsToScan; }); } namespace { /// Helper class to indicate whether a vector index can be safely scalarized and /// if a freeze needs to be inserted. class ScalarizationResult { enum class StatusTy { Unsafe, Safe, SafeWithFreeze }; StatusTy Status; Value *ToFreeze; ScalarizationResult(StatusTy Status, Value *ToFreeze = nullptr) : Status(Status), ToFreeze(ToFreeze) {} public: ScalarizationResult(const ScalarizationResult &Other) = default; ~ScalarizationResult() { assert(!ToFreeze && "freeze() not called with ToFreeze being set"); } static ScalarizationResult unsafe() { return {StatusTy::Unsafe}; } static ScalarizationResult safe() { return {StatusTy::Safe}; } static ScalarizationResult safeWithFreeze(Value *ToFreeze) { return {StatusTy::SafeWithFreeze, ToFreeze}; } /// Returns true if the index can be scalarize without requiring a freeze. bool isSafe() const { return Status == StatusTy::Safe; } /// Returns true if the index cannot be scalarized. bool isUnsafe() const { return Status == StatusTy::Unsafe; } /// Returns true if the index can be scalarize, but requires inserting a /// freeze. bool isSafeWithFreeze() const { return Status == StatusTy::SafeWithFreeze; } /// Reset the state of Unsafe and clear ToFreze if set. void discard() { ToFreeze = nullptr; Status = StatusTy::Unsafe; } /// Freeze the ToFreeze and update the use in \p User to use it. void freeze(IRBuilder<> &Builder, Instruction &UserI) { assert(isSafeWithFreeze() && "should only be used when freezing is required"); assert(is_contained(ToFreeze->users(), &UserI) && "UserI must be a user of ToFreeze"); IRBuilder<>::InsertPointGuard Guard(Builder); Builder.SetInsertPoint(cast(&UserI)); Value *Frozen = Builder.CreateFreeze(ToFreeze, ToFreeze->getName() + ".frozen"); for (Use &U : make_early_inc_range((UserI.operands()))) if (U.get() == ToFreeze) U.set(Frozen); ToFreeze = nullptr; } }; } // namespace /// Check if it is legal to scalarize a memory access to \p VecTy at index \p /// Idx. \p Idx must access a valid vector element. static ScalarizationResult canScalarizeAccess(VectorType *VecTy, Value *Idx, Instruction *CtxI, AssumptionCache &AC, const DominatorTree &DT) { // We do checks for both fixed vector types and scalable vector types. // This is the number of elements of fixed vector types, // or the minimum number of elements of scalable vector types. uint64_t NumElements = VecTy->getElementCount().getKnownMinValue(); if (auto *C = dyn_cast(Idx)) { if (C->getValue().ult(NumElements)) return ScalarizationResult::safe(); return ScalarizationResult::unsafe(); } unsigned IntWidth = Idx->getType()->getScalarSizeInBits(); APInt Zero(IntWidth, 0); APInt MaxElts(IntWidth, NumElements); ConstantRange ValidIndices(Zero, MaxElts); ConstantRange IdxRange(IntWidth, true); if (isGuaranteedNotToBePoison(Idx, &AC)) { if (ValidIndices.contains(computeConstantRange(Idx, /* ForSigned */ false, true, &AC, CtxI, &DT))) return ScalarizationResult::safe(); return ScalarizationResult::unsafe(); } // If the index may be poison, check if we can insert a freeze before the // range of the index is restricted. Value *IdxBase; ConstantInt *CI; if (match(Idx, m_And(m_Value(IdxBase), m_ConstantInt(CI)))) { IdxRange = IdxRange.binaryAnd(CI->getValue()); } else if (match(Idx, m_URem(m_Value(IdxBase), m_ConstantInt(CI)))) { IdxRange = IdxRange.urem(CI->getValue()); } if (ValidIndices.contains(IdxRange)) return ScalarizationResult::safeWithFreeze(IdxBase); return ScalarizationResult::unsafe(); } /// The memory operation on a vector of \p ScalarType had alignment of /// \p VectorAlignment. Compute the maximal, but conservatively correct, /// alignment that will be valid for the memory operation on a single scalar /// element of the same type with index \p Idx. static Align computeAlignmentAfterScalarization(Align VectorAlignment, Type *ScalarType, Value *Idx, const DataLayout &DL) { if (auto *C = dyn_cast(Idx)) return commonAlignment(VectorAlignment, C->getZExtValue() * DL.getTypeStoreSize(ScalarType)); return commonAlignment(VectorAlignment, DL.getTypeStoreSize(ScalarType)); } // Combine patterns like: // %0 = load <4 x i32>, <4 x i32>* %a // %1 = insertelement <4 x i32> %0, i32 %b, i32 1 // store <4 x i32> %1, <4 x i32>* %a // to: // %0 = bitcast <4 x i32>* %a to i32* // %1 = getelementptr inbounds i32, i32* %0, i64 0, i64 1 // store i32 %b, i32* %1 bool VectorCombine::foldSingleElementStore(Instruction &I) { auto *SI = cast(&I); if (!SI->isSimple() || !isa(SI->getValueOperand()->getType())) return false; // TODO: Combine more complicated patterns (multiple insert) by referencing // TargetTransformInfo. Instruction *Source; Value *NewElement; Value *Idx; if (!match(SI->getValueOperand(), m_InsertElt(m_Instruction(Source), m_Value(NewElement), m_Value(Idx)))) return false; if (auto *Load = dyn_cast(Source)) { auto VecTy = cast(SI->getValueOperand()->getType()); Value *SrcAddr = Load->getPointerOperand()->stripPointerCasts(); // Don't optimize for atomic/volatile load or store. Ensure memory is not // modified between, vector type matches store size, and index is inbounds. if (!Load->isSimple() || Load->getParent() != SI->getParent() || !DL->typeSizeEqualsStoreSize(Load->getType()->getScalarType()) || SrcAddr != SI->getPointerOperand()->stripPointerCasts()) return false; auto ScalarizableIdx = canScalarizeAccess(VecTy, Idx, Load, AC, DT); if (ScalarizableIdx.isUnsafe() || isMemModifiedBetween(Load->getIterator(), SI->getIterator(), MemoryLocation::get(SI), AA)) return false; if (ScalarizableIdx.isSafeWithFreeze()) ScalarizableIdx.freeze(Builder, *cast(Idx)); Value *GEP = Builder.CreateInBoundsGEP( SI->getValueOperand()->getType(), SI->getPointerOperand(), {ConstantInt::get(Idx->getType(), 0), Idx}); StoreInst *NSI = Builder.CreateStore(NewElement, GEP); NSI->copyMetadata(*SI); Align ScalarOpAlignment = computeAlignmentAfterScalarization( std::max(SI->getAlign(), Load->getAlign()), NewElement->getType(), Idx, *DL); NSI->setAlignment(ScalarOpAlignment); replaceValue(I, *NSI); eraseInstruction(I); return true; } return false; } /// Try to scalarize vector loads feeding extractelement instructions. bool VectorCombine::scalarizeLoadExtract(Instruction &I) { Value *Ptr; if (!match(&I, m_Load(m_Value(Ptr)))) return false; auto *VecTy = cast(I.getType()); auto *LI = cast(&I); if (LI->isVolatile() || !DL->typeSizeEqualsStoreSize(VecTy->getScalarType())) return false; InstructionCost OriginalCost = TTI.getMemoryOpCost(Instruction::Load, VecTy, LI->getAlign(), LI->getPointerAddressSpace()); InstructionCost ScalarizedCost = 0; Instruction *LastCheckedInst = LI; unsigned NumInstChecked = 0; DenseMap NeedFreeze; auto FailureGuard = make_scope_exit([&]() { // If the transform is aborted, discard the ScalarizationResults. for (auto &Pair : NeedFreeze) Pair.second.discard(); }); // Check if all users of the load are extracts with no memory modifications // between the load and the extract. Compute the cost of both the original // code and the scalarized version. for (User *U : LI->users()) { auto *UI = dyn_cast(U); if (!UI || UI->getParent() != LI->getParent()) return false; // Check if any instruction between the load and the extract may modify // memory. if (LastCheckedInst->comesBefore(UI)) { for (Instruction &I : make_range(std::next(LI->getIterator()), UI->getIterator())) { // Bail out if we reached the check limit or the instruction may write // to memory. if (NumInstChecked == MaxInstrsToScan || I.mayWriteToMemory()) return false; NumInstChecked++; } LastCheckedInst = UI; } auto ScalarIdx = canScalarizeAccess(VecTy, UI->getOperand(1), &I, AC, DT); if (ScalarIdx.isUnsafe()) return false; if (ScalarIdx.isSafeWithFreeze()) { NeedFreeze.try_emplace(UI, ScalarIdx); ScalarIdx.discard(); } auto *Index = dyn_cast(UI->getOperand(1)); TTI::TargetCostKind CostKind = TTI::TCK_RecipThroughput; OriginalCost += TTI.getVectorInstrCost(Instruction::ExtractElement, VecTy, CostKind, Index ? Index->getZExtValue() : -1); ScalarizedCost += TTI.getMemoryOpCost(Instruction::Load, VecTy->getElementType(), Align(1), LI->getPointerAddressSpace()); ScalarizedCost += TTI.getAddressComputationCost(VecTy->getElementType()); } if (ScalarizedCost >= OriginalCost) return false; // Replace extracts with narrow scalar loads. for (User *U : LI->users()) { auto *EI = cast(U); Value *Idx = EI->getOperand(1); // Insert 'freeze' for poison indexes. auto It = NeedFreeze.find(EI); if (It != NeedFreeze.end()) It->second.freeze(Builder, *cast(Idx)); Builder.SetInsertPoint(EI); Value *GEP = Builder.CreateInBoundsGEP(VecTy, Ptr, {Builder.getInt32(0), Idx}); auto *NewLoad = cast(Builder.CreateLoad( VecTy->getElementType(), GEP, EI->getName() + ".scalar")); Align ScalarOpAlignment = computeAlignmentAfterScalarization( LI->getAlign(), VecTy->getElementType(), Idx, *DL); NewLoad->setAlignment(ScalarOpAlignment); replaceValue(*EI, *NewLoad); } FailureGuard.release(); return true; } /// Try to convert "shuffle (binop), (binop)" into "binop (shuffle), (shuffle)". bool VectorCombine::foldShuffleOfBinops(Instruction &I) { BinaryOperator *B0, *B1; ArrayRef OldMask; if (!match(&I, m_Shuffle(m_OneUse(m_BinOp(B0)), m_OneUse(m_BinOp(B1)), m_Mask(OldMask)))) return false; // Don't introduce poison into div/rem. if (any_of(OldMask, [](int M) { return M == PoisonMaskElem; }) && B0->isIntDivRem()) return false; // TODO: Add support for addlike etc. Instruction::BinaryOps Opcode = B0->getOpcode(); if (Opcode != B1->getOpcode()) return false; auto *ShuffleDstTy = dyn_cast(I.getType()); auto *BinOpTy = dyn_cast(B0->getType()); if (!ShuffleDstTy || !BinOpTy) return false; unsigned NumSrcElts = BinOpTy->getNumElements(); // If we have something like "add X, Y" and "add Z, X", swap ops to match. Value *X = B0->getOperand(0), *Y = B0->getOperand(1); Value *Z = B1->getOperand(0), *W = B1->getOperand(1); if (BinaryOperator::isCommutative(Opcode) && X != Z && Y != W && (X == W || Y == Z)) std::swap(X, Y); auto ConvertToUnary = [NumSrcElts](int &M) { if (M >= (int)NumSrcElts) M -= NumSrcElts; }; SmallVector NewMask0(OldMask.begin(), OldMask.end()); TargetTransformInfo::ShuffleKind SK0 = TargetTransformInfo::SK_PermuteTwoSrc; if (X == Z) { llvm::for_each(NewMask0, ConvertToUnary); SK0 = TargetTransformInfo::SK_PermuteSingleSrc; Z = PoisonValue::get(BinOpTy); } SmallVector NewMask1(OldMask.begin(), OldMask.end()); TargetTransformInfo::ShuffleKind SK1 = TargetTransformInfo::SK_PermuteTwoSrc; if (Y == W) { llvm::for_each(NewMask1, ConvertToUnary); SK1 = TargetTransformInfo::SK_PermuteSingleSrc; W = PoisonValue::get(BinOpTy); } // Try to replace a binop with a shuffle if the shuffle is not costly. TTI::TargetCostKind CostKind = TTI::TCK_RecipThroughput; InstructionCost OldCost = TTI.getArithmeticInstrCost(B0->getOpcode(), BinOpTy, CostKind) + TTI.getArithmeticInstrCost(B1->getOpcode(), BinOpTy, CostKind) + TTI.getShuffleCost(TargetTransformInfo::SK_PermuteTwoSrc, BinOpTy, OldMask, CostKind, 0, nullptr, {B0, B1}, &I); InstructionCost NewCost = TTI.getShuffleCost(SK0, BinOpTy, NewMask0, CostKind, 0, nullptr, {X, Z}) + TTI.getShuffleCost(SK1, BinOpTy, NewMask1, CostKind, 0, nullptr, {Y, W}) + TTI.getArithmeticInstrCost(Opcode, ShuffleDstTy, CostKind); LLVM_DEBUG(dbgs() << "Found a shuffle feeding two binops: " << I << "\n OldCost: " << OldCost << " vs NewCost: " << NewCost << "\n"); if (NewCost >= OldCost) return false; Value *Shuf0 = Builder.CreateShuffleVector(X, Z, NewMask0); Value *Shuf1 = Builder.CreateShuffleVector(Y, W, NewMask1); Value *NewBO = Builder.CreateBinOp(Opcode, Shuf0, Shuf1); // Intersect flags from the old binops. if (auto *NewInst = dyn_cast(NewBO)) { NewInst->copyIRFlags(B0); NewInst->andIRFlags(B1); } Worklist.pushValue(Shuf0); Worklist.pushValue(Shuf1); replaceValue(I, *NewBO); return true; } /// Try to convert "shuffle (castop), (castop)" with a shared castop operand /// into "castop (shuffle)". bool VectorCombine::foldShuffleOfCastops(Instruction &I) { Value *V0, *V1; ArrayRef OldMask; if (!match(&I, m_Shuffle(m_Value(V0), m_Value(V1), m_Mask(OldMask)))) return false; auto *C0 = dyn_cast(V0); auto *C1 = dyn_cast(V1); if (!C0 || !C1) return false; Instruction::CastOps Opcode = C0->getOpcode(); if (C0->getSrcTy() != C1->getSrcTy()) return false; // Handle shuffle(zext_nneg(x), sext(y)) -> sext(shuffle(x,y)) folds. if (Opcode != C1->getOpcode()) { if (match(C0, m_SExtLike(m_Value())) && match(C1, m_SExtLike(m_Value()))) Opcode = Instruction::SExt; else return false; } auto *ShuffleDstTy = dyn_cast(I.getType()); auto *CastDstTy = dyn_cast(C0->getDestTy()); auto *CastSrcTy = dyn_cast(C0->getSrcTy()); if (!ShuffleDstTy || !CastDstTy || !CastSrcTy) return false; unsigned NumSrcElts = CastSrcTy->getNumElements(); unsigned NumDstElts = CastDstTy->getNumElements(); assert((NumDstElts == NumSrcElts || Opcode == Instruction::BitCast) && "Only bitcasts expected to alter src/dst element counts"); // Check for bitcasting of unscalable vector types. // e.g. <32 x i40> -> <40 x i32> if (NumDstElts != NumSrcElts && (NumSrcElts % NumDstElts) != 0 && (NumDstElts % NumSrcElts) != 0) return false; SmallVector NewMask; if (NumSrcElts >= NumDstElts) { // The bitcast is from wide to narrow/equal elements. The shuffle mask can // always be expanded to the equivalent form choosing narrower elements. assert(NumSrcElts % NumDstElts == 0 && "Unexpected shuffle mask"); unsigned ScaleFactor = NumSrcElts / NumDstElts; narrowShuffleMaskElts(ScaleFactor, OldMask, NewMask); } else { // The bitcast is from narrow elements to wide elements. The shuffle mask // must choose consecutive elements to allow casting first. assert(NumDstElts % NumSrcElts == 0 && "Unexpected shuffle mask"); unsigned ScaleFactor = NumDstElts / NumSrcElts; if (!widenShuffleMaskElts(ScaleFactor, OldMask, NewMask)) return false; } auto *NewShuffleDstTy = FixedVectorType::get(CastSrcTy->getScalarType(), NewMask.size()); // Try to replace a castop with a shuffle if the shuffle is not costly. TTI::TargetCostKind CostKind = TTI::TCK_RecipThroughput; InstructionCost CostC0 = TTI.getCastInstrCost(C0->getOpcode(), CastDstTy, CastSrcTy, TTI::CastContextHint::None, CostKind); InstructionCost CostC1 = TTI.getCastInstrCost(C1->getOpcode(), CastDstTy, CastSrcTy, TTI::CastContextHint::None, CostKind); InstructionCost OldCost = CostC0 + CostC1; OldCost += TTI.getShuffleCost(TargetTransformInfo::SK_PermuteTwoSrc, CastDstTy, OldMask, CostKind, 0, nullptr, std::nullopt, &I); InstructionCost NewCost = TTI.getShuffleCost( TargetTransformInfo::SK_PermuteTwoSrc, CastSrcTy, NewMask, CostKind); NewCost += TTI.getCastInstrCost(Opcode, ShuffleDstTy, NewShuffleDstTy, TTI::CastContextHint::None, CostKind); if (!C0->hasOneUse()) NewCost += CostC0; if (!C1->hasOneUse()) NewCost += CostC1; LLVM_DEBUG(dbgs() << "Found a shuffle feeding two casts: " << I << "\n OldCost: " << OldCost << " vs NewCost: " << NewCost << "\n"); if (NewCost > OldCost) return false; Value *Shuf = Builder.CreateShuffleVector(C0->getOperand(0), C1->getOperand(0), NewMask); Value *Cast = Builder.CreateCast(Opcode, Shuf, ShuffleDstTy); // Intersect flags from the old casts. if (auto *NewInst = dyn_cast(Cast)) { NewInst->copyIRFlags(C0); NewInst->andIRFlags(C1); } Worklist.pushValue(Shuf); replaceValue(I, *Cast); return true; } /// Try to convert "shuffle (shuffle x, undef), (shuffle y, undef)" /// into "shuffle x, y". bool VectorCombine::foldShuffleOfShuffles(Instruction &I) { Value *V0, *V1; UndefValue *U0, *U1; ArrayRef OuterMask, InnerMask0, InnerMask1; if (!match(&I, m_Shuffle(m_OneUse(m_Shuffle(m_Value(V0), m_UndefValue(U0), m_Mask(InnerMask0))), m_OneUse(m_Shuffle(m_Value(V1), m_UndefValue(U1), m_Mask(InnerMask1))), m_Mask(OuterMask)))) return false; auto *ShufI0 = dyn_cast(I.getOperand(0)); auto *ShufI1 = dyn_cast(I.getOperand(1)); auto *ShuffleDstTy = dyn_cast(I.getType()); auto *ShuffleSrcTy = dyn_cast(V0->getType()); auto *ShuffleImmTy = dyn_cast(I.getOperand(0)->getType()); if (!ShuffleDstTy || !ShuffleSrcTy || !ShuffleImmTy || V0->getType() != V1->getType()) return false; unsigned NumSrcElts = ShuffleSrcTy->getNumElements(); unsigned NumImmElts = ShuffleImmTy->getNumElements(); // Bail if either inner masks reference a RHS undef arg. if ((!isa(U0) && any_of(InnerMask0, [&](int M) { return M >= (int)NumSrcElts; })) || (!isa(U1) && any_of(InnerMask1, [&](int M) { return M >= (int)NumSrcElts; }))) return false; // Merge shuffles - replace index to the RHS poison arg with PoisonMaskElem, SmallVector NewMask(OuterMask.begin(), OuterMask.end()); for (int &M : NewMask) { if (0 <= M && M < (int)NumImmElts) { M = (InnerMask0[M] >= (int)NumSrcElts) ? PoisonMaskElem : InnerMask0[M]; } else if (M >= (int)NumImmElts) { if (InnerMask1[M - NumImmElts] >= (int)NumSrcElts) M = PoisonMaskElem; else M = InnerMask1[M - NumImmElts] + (V0 == V1 ? 0 : NumSrcElts); } } // Have we folded to an Identity shuffle? if (ShuffleVectorInst::isIdentityMask(NewMask, NumSrcElts)) { replaceValue(I, *V0); return true; } // Try to merge the shuffles if the new shuffle is not costly. TTI::TargetCostKind CostKind = TTI::TCK_RecipThroughput; InstructionCost OldCost = TTI.getShuffleCost(TargetTransformInfo::SK_PermuteSingleSrc, ShuffleSrcTy, InnerMask0, CostKind, 0, nullptr, {V0, U0}, ShufI0) + TTI.getShuffleCost(TargetTransformInfo::SK_PermuteSingleSrc, ShuffleSrcTy, InnerMask1, CostKind, 0, nullptr, {V1, U1}, ShufI1) + TTI.getShuffleCost(TargetTransformInfo::SK_PermuteTwoSrc, ShuffleImmTy, OuterMask, CostKind, 0, nullptr, {ShufI0, ShufI1}, &I); InstructionCost NewCost = TTI.getShuffleCost(TargetTransformInfo::SK_PermuteTwoSrc, ShuffleSrcTy, NewMask, CostKind, 0, nullptr, {V0, V1}); LLVM_DEBUG(dbgs() << "Found a shuffle feeding two shuffles: " << I << "\n OldCost: " << OldCost << " vs NewCost: " << NewCost << "\n"); if (NewCost > OldCost) return false; // Clear unused sources to poison. if (none_of(NewMask, [&](int M) { return 0 <= M && M < (int)NumSrcElts; })) V0 = PoisonValue::get(ShuffleSrcTy); if (none_of(NewMask, [&](int M) { return (int)NumSrcElts <= M; })) V1 = PoisonValue::get(ShuffleSrcTy); Value *Shuf = Builder.CreateShuffleVector(V0, V1, NewMask); replaceValue(I, *Shuf); return true; } using InstLane = std::pair; static InstLane lookThroughShuffles(Use *U, int Lane) { while (auto *SV = dyn_cast(U->get())) { unsigned NumElts = cast(SV->getOperand(0)->getType())->getNumElements(); int M = SV->getMaskValue(Lane); if (M < 0) return {nullptr, PoisonMaskElem}; if (static_cast(M) < NumElts) { U = &SV->getOperandUse(0); Lane = M; } else { U = &SV->getOperandUse(1); Lane = M - NumElts; } } return InstLane{U, Lane}; } static SmallVector generateInstLaneVectorFromOperand(ArrayRef Item, int Op) { SmallVector NItem; for (InstLane IL : Item) { auto [U, Lane] = IL; InstLane OpLane = U ? lookThroughShuffles(&cast(U->get())->getOperandUse(Op), Lane) : InstLane{nullptr, PoisonMaskElem}; NItem.emplace_back(OpLane); } return NItem; } /// Detect concat of multiple values into a vector static bool isFreeConcat(ArrayRef Item, const TargetTransformInfo &TTI) { auto *Ty = cast(Item.front().first->get()->getType()); unsigned NumElts = Ty->getNumElements(); if (Item.size() == NumElts || NumElts == 1 || Item.size() % NumElts != 0) return false; // Check that the concat is free, usually meaning that the type will be split // during legalization. SmallVector ConcatMask(NumElts * 2); std::iota(ConcatMask.begin(), ConcatMask.end(), 0); if (TTI.getShuffleCost(TTI::SK_PermuteTwoSrc, Ty, ConcatMask, TTI::TCK_RecipThroughput) != 0) return false; unsigned NumSlices = Item.size() / NumElts; // Currently we generate a tree of shuffles for the concats, which limits us // to a power2. if (!isPowerOf2_32(NumSlices)) return false; for (unsigned Slice = 0; Slice < NumSlices; ++Slice) { Use *SliceV = Item[Slice * NumElts].first; if (!SliceV || SliceV->get()->getType() != Ty) return false; for (unsigned Elt = 0; Elt < NumElts; ++Elt) { auto [V, Lane] = Item[Slice * NumElts + Elt]; if (Lane != static_cast(Elt) || SliceV->get() != V->get()) return false; } } return true; } static Value *generateNewInstTree(ArrayRef Item, FixedVectorType *Ty, const SmallPtrSet &IdentityLeafs, const SmallPtrSet &SplatLeafs, const SmallPtrSet &ConcatLeafs, IRBuilder<> &Builder) { auto [FrontU, FrontLane] = Item.front(); if (IdentityLeafs.contains(FrontU)) { return FrontU->get(); } if (SplatLeafs.contains(FrontU)) { SmallVector Mask(Ty->getNumElements(), FrontLane); return Builder.CreateShuffleVector(FrontU->get(), Mask); } if (ConcatLeafs.contains(FrontU)) { unsigned NumElts = cast(FrontU->get()->getType())->getNumElements(); SmallVector Values(Item.size() / NumElts, nullptr); for (unsigned S = 0; S < Values.size(); ++S) Values[S] = Item[S * NumElts].first->get(); while (Values.size() > 1) { NumElts *= 2; SmallVector Mask(NumElts, 0); std::iota(Mask.begin(), Mask.end(), 0); SmallVector NewValues(Values.size() / 2, nullptr); for (unsigned S = 0; S < NewValues.size(); ++S) NewValues[S] = Builder.CreateShuffleVector(Values[S * 2], Values[S * 2 + 1], Mask); Values = NewValues; } return Values[0]; } auto *I = cast(FrontU->get()); auto *II = dyn_cast(I); unsigned NumOps = I->getNumOperands() - (II ? 1 : 0); SmallVector Ops(NumOps); for (unsigned Idx = 0; Idx < NumOps; Idx++) { if (II && isVectorIntrinsicWithScalarOpAtArg(II->getIntrinsicID(), Idx)) { Ops[Idx] = II->getOperand(Idx); continue; } Ops[Idx] = generateNewInstTree(generateInstLaneVectorFromOperand(Item, Idx), Ty, IdentityLeafs, SplatLeafs, ConcatLeafs, Builder); } SmallVector ValueList; for (const auto &Lane : Item) if (Lane.first) ValueList.push_back(Lane.first->get()); Type *DstTy = FixedVectorType::get(I->getType()->getScalarType(), Ty->getNumElements()); if (auto *BI = dyn_cast(I)) { auto *Value = Builder.CreateBinOp((Instruction::BinaryOps)BI->getOpcode(), Ops[0], Ops[1]); propagateIRFlags(Value, ValueList); return Value; } if (auto *CI = dyn_cast(I)) { auto *Value = Builder.CreateCmp(CI->getPredicate(), Ops[0], Ops[1]); propagateIRFlags(Value, ValueList); return Value; } if (auto *SI = dyn_cast(I)) { auto *Value = Builder.CreateSelect(Ops[0], Ops[1], Ops[2], "", SI); propagateIRFlags(Value, ValueList); return Value; } if (auto *CI = dyn_cast(I)) { auto *Value = Builder.CreateCast((Instruction::CastOps)CI->getOpcode(), Ops[0], DstTy); propagateIRFlags(Value, ValueList); return Value; } if (II) { auto *Value = Builder.CreateIntrinsic(DstTy, II->getIntrinsicID(), Ops); propagateIRFlags(Value, ValueList); return Value; } assert(isa(I) && "Unexpected instruction type in Generate"); auto *Value = Builder.CreateUnOp((Instruction::UnaryOps)I->getOpcode(), Ops[0]); propagateIRFlags(Value, ValueList); return Value; } // Starting from a shuffle, look up through operands tracking the shuffled index // of each lane. If we can simplify away the shuffles to identities then // do so. bool VectorCombine::foldShuffleToIdentity(Instruction &I) { auto *Ty = dyn_cast(I.getType()); if (!Ty || I.use_empty()) return false; SmallVector Start(Ty->getNumElements()); for (unsigned M = 0, E = Ty->getNumElements(); M < E; ++M) Start[M] = lookThroughShuffles(&*I.use_begin(), M); SmallVector> Worklist; Worklist.push_back(Start); SmallPtrSet IdentityLeafs, SplatLeafs, ConcatLeafs; unsigned NumVisited = 0; while (!Worklist.empty()) { if (++NumVisited > MaxInstrsToScan) return false; SmallVector Item = Worklist.pop_back_val(); auto [FrontU, FrontLane] = Item.front(); // If we found an undef first lane then bail out to keep things simple. if (!FrontU) return false; // Helper to peek through bitcasts to the same value. auto IsEquiv = [&](Value *X, Value *Y) { return X->getType() == Y->getType() && peekThroughBitcasts(X) == peekThroughBitcasts(Y); }; // Look for an identity value. if (FrontLane == 0 && cast(FrontU->get()->getType())->getNumElements() == Ty->getNumElements() && all_of(drop_begin(enumerate(Item)), [IsEquiv, Item](const auto &E) { Value *FrontV = Item.front().first->get(); return !E.value().first || (IsEquiv(E.value().first->get(), FrontV) && E.value().second == (int)E.index()); })) { IdentityLeafs.insert(FrontU); continue; } // Look for constants, for the moment only supporting constant splats. if (auto *C = dyn_cast(FrontU); C && C->getSplatValue() && all_of(drop_begin(Item), [Item](InstLane &IL) { Value *FrontV = Item.front().first->get(); Use *U = IL.first; return !U || U->get() == FrontV; })) { SplatLeafs.insert(FrontU); continue; } // Look for a splat value. if (all_of(drop_begin(Item), [Item](InstLane &IL) { auto [FrontU, FrontLane] = Item.front(); auto [U, Lane] = IL; return !U || (U->get() == FrontU->get() && Lane == FrontLane); })) { SplatLeafs.insert(FrontU); continue; } // We need each element to be the same type of value, and check that each // element has a single use. auto CheckLaneIsEquivalentToFirst = [Item](InstLane IL) { Value *FrontV = Item.front().first->get(); if (!IL.first) return true; Value *V = IL.first->get(); if (auto *I = dyn_cast(V); I && !I->hasOneUse()) return false; if (V->getValueID() != FrontV->getValueID()) return false; if (auto *CI = dyn_cast(V)) if (CI->getPredicate() != cast(FrontV)->getPredicate()) return false; if (auto *CI = dyn_cast(V)) if (CI->getSrcTy() != cast(FrontV)->getSrcTy()) return false; if (auto *SI = dyn_cast(V)) if (!isa(SI->getOperand(0)->getType()) || SI->getOperand(0)->getType() != cast(FrontV)->getOperand(0)->getType()) return false; if (isa(V) && !isa(V)) return false; auto *II = dyn_cast(V); return !II || (isa(FrontV) && II->getIntrinsicID() == cast(FrontV)->getIntrinsicID() && !II->hasOperandBundles()); }; if (all_of(drop_begin(Item), CheckLaneIsEquivalentToFirst)) { // Check the operator is one that we support. if (isa(FrontU)) { // We exclude div/rem in case they hit UB from poison lanes. if (auto *BO = dyn_cast(FrontU); BO && BO->isIntDivRem()) return false; Worklist.push_back(generateInstLaneVectorFromOperand(Item, 0)); Worklist.push_back(generateInstLaneVectorFromOperand(Item, 1)); continue; } else if (isa(FrontU)) { Worklist.push_back(generateInstLaneVectorFromOperand(Item, 0)); continue; } else if (auto *BitCast = dyn_cast(FrontU)) { // TODO: Handle vector widening/narrowing bitcasts. auto *DstTy = dyn_cast(BitCast->getDestTy()); auto *SrcTy = dyn_cast(BitCast->getSrcTy()); if (DstTy && SrcTy && SrcTy->getNumElements() == DstTy->getNumElements()) { Worklist.push_back(generateInstLaneVectorFromOperand(Item, 0)); continue; } } else if (isa(FrontU)) { Worklist.push_back(generateInstLaneVectorFromOperand(Item, 0)); Worklist.push_back(generateInstLaneVectorFromOperand(Item, 1)); Worklist.push_back(generateInstLaneVectorFromOperand(Item, 2)); continue; } else if (auto *II = dyn_cast(FrontU); II && isTriviallyVectorizable(II->getIntrinsicID()) && !II->hasOperandBundles()) { for (unsigned Op = 0, E = II->getNumOperands() - 1; Op < E; Op++) { if (isVectorIntrinsicWithScalarOpAtArg(II->getIntrinsicID(), Op)) { if (!all_of(drop_begin(Item), [Item, Op](InstLane &IL) { Value *FrontV = Item.front().first->get(); Use *U = IL.first; return !U || (cast(U->get())->getOperand(Op) == cast(FrontV)->getOperand(Op)); })) return false; continue; } Worklist.push_back(generateInstLaneVectorFromOperand(Item, Op)); } continue; } } if (isFreeConcat(Item, TTI)) { ConcatLeafs.insert(FrontU); continue; } return false; } if (NumVisited <= 1) return false; // If we got this far, we know the shuffles are superfluous and can be // removed. Scan through again and generate the new tree of instructions. Builder.SetInsertPoint(&I); Value *V = generateNewInstTree(Start, Ty, IdentityLeafs, SplatLeafs, ConcatLeafs, Builder); replaceValue(I, *V); return true; } /// Given a commutative reduction, the order of the input lanes does not alter /// the results. We can use this to remove certain shuffles feeding the /// reduction, removing the need to shuffle at all. bool VectorCombine::foldShuffleFromReductions(Instruction &I) { auto *II = dyn_cast(&I); if (!II) return false; switch (II->getIntrinsicID()) { case Intrinsic::vector_reduce_add: case Intrinsic::vector_reduce_mul: case Intrinsic::vector_reduce_and: case Intrinsic::vector_reduce_or: case Intrinsic::vector_reduce_xor: case Intrinsic::vector_reduce_smin: case Intrinsic::vector_reduce_smax: case Intrinsic::vector_reduce_umin: case Intrinsic::vector_reduce_umax: break; default: return false; } // Find all the inputs when looking through operations that do not alter the // lane order (binops, for example). Currently we look for a single shuffle, // and can ignore splat values. std::queue Worklist; SmallPtrSet Visited; ShuffleVectorInst *Shuffle = nullptr; if (auto *Op = dyn_cast(I.getOperand(0))) Worklist.push(Op); while (!Worklist.empty()) { Value *CV = Worklist.front(); Worklist.pop(); if (Visited.contains(CV)) continue; // Splats don't change the order, so can be safely ignored. if (isSplatValue(CV)) continue; Visited.insert(CV); if (auto *CI = dyn_cast(CV)) { if (CI->isBinaryOp()) { for (auto *Op : CI->operand_values()) Worklist.push(Op); continue; } else if (auto *SV = dyn_cast(CI)) { if (Shuffle && Shuffle != SV) return false; Shuffle = SV; continue; } } // Anything else is currently an unknown node. return false; } if (!Shuffle) return false; // Check all uses of the binary ops and shuffles are also included in the // lane-invariant operations (Visited should be the list of lanewise // instructions, including the shuffle that we found). for (auto *V : Visited) for (auto *U : V->users()) if (!Visited.contains(U) && U != &I) return false; FixedVectorType *VecType = dyn_cast(II->getOperand(0)->getType()); if (!VecType) return false; FixedVectorType *ShuffleInputType = dyn_cast(Shuffle->getOperand(0)->getType()); if (!ShuffleInputType) return false; unsigned NumInputElts = ShuffleInputType->getNumElements(); // Find the mask from sorting the lanes into order. This is most likely to // become a identity or concat mask. Undef elements are pushed to the end. SmallVector ConcatMask; Shuffle->getShuffleMask(ConcatMask); sort(ConcatMask, [](int X, int Y) { return (unsigned)X < (unsigned)Y; }); // In the case of a truncating shuffle it's possible for the mask // to have an index greater than the size of the resulting vector. // This requires special handling. bool IsTruncatingShuffle = VecType->getNumElements() < NumInputElts; bool UsesSecondVec = any_of(ConcatMask, [&](int M) { return M >= (int)NumInputElts; }); FixedVectorType *VecTyForCost = (UsesSecondVec && !IsTruncatingShuffle) ? VecType : ShuffleInputType; InstructionCost OldCost = TTI.getShuffleCost( UsesSecondVec ? TTI::SK_PermuteTwoSrc : TTI::SK_PermuteSingleSrc, VecTyForCost, Shuffle->getShuffleMask()); InstructionCost NewCost = TTI.getShuffleCost( UsesSecondVec ? TTI::SK_PermuteTwoSrc : TTI::SK_PermuteSingleSrc, VecTyForCost, ConcatMask); LLVM_DEBUG(dbgs() << "Found a reduction feeding from a shuffle: " << *Shuffle << "\n"); LLVM_DEBUG(dbgs() << " OldCost: " << OldCost << " vs NewCost: " << NewCost << "\n"); if (NewCost < OldCost) { Builder.SetInsertPoint(Shuffle); Value *NewShuffle = Builder.CreateShuffleVector( Shuffle->getOperand(0), Shuffle->getOperand(1), ConcatMask); LLVM_DEBUG(dbgs() << "Created new shuffle: " << *NewShuffle << "\n"); replaceValue(*Shuffle, *NewShuffle); } // See if we can re-use foldSelectShuffle, getting it to reduce the size of // the shuffle into a nicer order, as it can ignore the order of the shuffles. return foldSelectShuffle(*Shuffle, true); } /// Determine if its more efficient to fold: /// reduce(trunc(x)) -> trunc(reduce(x)). /// reduce(sext(x)) -> sext(reduce(x)). /// reduce(zext(x)) -> zext(reduce(x)). bool VectorCombine::foldCastFromReductions(Instruction &I) { auto *II = dyn_cast(&I); if (!II) return false; bool TruncOnly = false; Intrinsic::ID IID = II->getIntrinsicID(); switch (IID) { case Intrinsic::vector_reduce_add: case Intrinsic::vector_reduce_mul: TruncOnly = true; break; case Intrinsic::vector_reduce_and: case Intrinsic::vector_reduce_or: case Intrinsic::vector_reduce_xor: break; default: return false; } unsigned ReductionOpc = getArithmeticReductionInstruction(IID); Value *ReductionSrc = I.getOperand(0); Value *Src; if (!match(ReductionSrc, m_OneUse(m_Trunc(m_Value(Src)))) && (TruncOnly || !match(ReductionSrc, m_OneUse(m_ZExtOrSExt(m_Value(Src)))))) return false; auto CastOpc = (Instruction::CastOps)cast(ReductionSrc)->getOpcode(); auto *SrcTy = cast(Src->getType()); auto *ReductionSrcTy = cast(ReductionSrc->getType()); Type *ResultTy = I.getType(); TTI::TargetCostKind CostKind = TTI::TCK_RecipThroughput; InstructionCost OldCost = TTI.getArithmeticReductionCost( ReductionOpc, ReductionSrcTy, std::nullopt, CostKind); OldCost += TTI.getCastInstrCost(CastOpc, ReductionSrcTy, SrcTy, TTI::CastContextHint::None, CostKind, cast(ReductionSrc)); InstructionCost NewCost = TTI.getArithmeticReductionCost(ReductionOpc, SrcTy, std::nullopt, CostKind) + TTI.getCastInstrCost(CastOpc, ResultTy, ReductionSrcTy->getScalarType(), TTI::CastContextHint::None, CostKind); if (OldCost <= NewCost || !NewCost.isValid()) return false; Value *NewReduction = Builder.CreateIntrinsic(SrcTy->getScalarType(), II->getIntrinsicID(), {Src}); Value *NewCast = Builder.CreateCast(CastOpc, NewReduction, ResultTy); replaceValue(I, *NewCast); return true; } /// This method looks for groups of shuffles acting on binops, of the form: /// %x = shuffle ... /// %y = shuffle ... /// %a = binop %x, %y /// %b = binop %x, %y /// shuffle %a, %b, selectmask /// We may, especially if the shuffle is wider than legal, be able to convert /// the shuffle to a form where only parts of a and b need to be computed. On /// architectures with no obvious "select" shuffle, this can reduce the total /// number of operations if the target reports them as cheaper. bool VectorCombine::foldSelectShuffle(Instruction &I, bool FromReduction) { auto *SVI = cast(&I); auto *VT = cast(I.getType()); auto *Op0 = dyn_cast(SVI->getOperand(0)); auto *Op1 = dyn_cast(SVI->getOperand(1)); if (!Op0 || !Op1 || Op0 == Op1 || !Op0->isBinaryOp() || !Op1->isBinaryOp() || VT != Op0->getType()) return false; auto *SVI0A = dyn_cast(Op0->getOperand(0)); auto *SVI0B = dyn_cast(Op0->getOperand(1)); auto *SVI1A = dyn_cast(Op1->getOperand(0)); auto *SVI1B = dyn_cast(Op1->getOperand(1)); SmallPtrSet InputShuffles({SVI0A, SVI0B, SVI1A, SVI1B}); auto checkSVNonOpUses = [&](Instruction *I) { if (!I || I->getOperand(0)->getType() != VT) return true; return any_of(I->users(), [&](User *U) { return U != Op0 && U != Op1 && !(isa(U) && (InputShuffles.contains(cast(U)) || isInstructionTriviallyDead(cast(U)))); }); }; if (checkSVNonOpUses(SVI0A) || checkSVNonOpUses(SVI0B) || checkSVNonOpUses(SVI1A) || checkSVNonOpUses(SVI1B)) return false; // Collect all the uses that are shuffles that we can transform together. We // may not have a single shuffle, but a group that can all be transformed // together profitably. SmallVector Shuffles; auto collectShuffles = [&](Instruction *I) { for (auto *U : I->users()) { auto *SV = dyn_cast(U); if (!SV || SV->getType() != VT) return false; if ((SV->getOperand(0) != Op0 && SV->getOperand(0) != Op1) || (SV->getOperand(1) != Op0 && SV->getOperand(1) != Op1)) return false; if (!llvm::is_contained(Shuffles, SV)) Shuffles.push_back(SV); } return true; }; if (!collectShuffles(Op0) || !collectShuffles(Op1)) return false; // From a reduction, we need to be processing a single shuffle, otherwise the // other uses will not be lane-invariant. if (FromReduction && Shuffles.size() > 1) return false; // Add any shuffle uses for the shuffles we have found, to include them in our // cost calculations. if (!FromReduction) { for (ShuffleVectorInst *SV : Shuffles) { for (auto *U : SV->users()) { ShuffleVectorInst *SSV = dyn_cast(U); if (SSV && isa(SSV->getOperand(1)) && SSV->getType() == VT) Shuffles.push_back(SSV); } } } // For each of the output shuffles, we try to sort all the first vector // elements to the beginning, followed by the second array elements at the // end. If the binops are legalized to smaller vectors, this may reduce total // number of binops. We compute the ReconstructMask mask needed to convert // back to the original lane order. SmallVector> V1, V2; SmallVector> OrigReconstructMasks; int MaxV1Elt = 0, MaxV2Elt = 0; unsigned NumElts = VT->getNumElements(); for (ShuffleVectorInst *SVN : Shuffles) { SmallVector Mask; SVN->getShuffleMask(Mask); // Check the operands are the same as the original, or reversed (in which // case we need to commute the mask). Value *SVOp0 = SVN->getOperand(0); Value *SVOp1 = SVN->getOperand(1); if (isa(SVOp1)) { auto *SSV = cast(SVOp0); SVOp0 = SSV->getOperand(0); SVOp1 = SSV->getOperand(1); for (unsigned I = 0, E = Mask.size(); I != E; I++) { if (Mask[I] >= static_cast(SSV->getShuffleMask().size())) return false; Mask[I] = Mask[I] < 0 ? Mask[I] : SSV->getMaskValue(Mask[I]); } } if (SVOp0 == Op1 && SVOp1 == Op0) { std::swap(SVOp0, SVOp1); ShuffleVectorInst::commuteShuffleMask(Mask, NumElts); } if (SVOp0 != Op0 || SVOp1 != Op1) return false; // Calculate the reconstruction mask for this shuffle, as the mask needed to // take the packed values from Op0/Op1 and reconstructing to the original // order. SmallVector ReconstructMask; for (unsigned I = 0; I < Mask.size(); I++) { if (Mask[I] < 0) { ReconstructMask.push_back(-1); } else if (Mask[I] < static_cast(NumElts)) { MaxV1Elt = std::max(MaxV1Elt, Mask[I]); auto It = find_if(V1, [&](const std::pair &A) { return Mask[I] == A.first; }); if (It != V1.end()) ReconstructMask.push_back(It - V1.begin()); else { ReconstructMask.push_back(V1.size()); V1.emplace_back(Mask[I], V1.size()); } } else { MaxV2Elt = std::max(MaxV2Elt, Mask[I] - NumElts); auto It = find_if(V2, [&](const std::pair &A) { return Mask[I] - static_cast(NumElts) == A.first; }); if (It != V2.end()) ReconstructMask.push_back(NumElts + It - V2.begin()); else { ReconstructMask.push_back(NumElts + V2.size()); V2.emplace_back(Mask[I] - NumElts, NumElts + V2.size()); } } } // For reductions, we know that the lane ordering out doesn't alter the // result. In-order can help simplify the shuffle away. if (FromReduction) sort(ReconstructMask); OrigReconstructMasks.push_back(std::move(ReconstructMask)); } // If the Maximum element used from V1 and V2 are not larger than the new // vectors, the vectors are already packes and performing the optimization // again will likely not help any further. This also prevents us from getting // stuck in a cycle in case the costs do not also rule it out. if (V1.empty() || V2.empty() || (MaxV1Elt == static_cast(V1.size()) - 1 && MaxV2Elt == static_cast(V2.size()) - 1)) return false; // GetBaseMaskValue takes one of the inputs, which may either be a shuffle, a // shuffle of another shuffle, or not a shuffle (that is treated like a // identity shuffle). auto GetBaseMaskValue = [&](Instruction *I, int M) { auto *SV = dyn_cast(I); if (!SV) return M; if (isa(SV->getOperand(1))) if (auto *SSV = dyn_cast(SV->getOperand(0))) if (InputShuffles.contains(SSV)) return SSV->getMaskValue(SV->getMaskValue(M)); return SV->getMaskValue(M); }; // Attempt to sort the inputs my ascending mask values to make simpler input // shuffles and push complex shuffles down to the uses. We sort on the first // of the two input shuffle orders, to try and get at least one input into a // nice order. auto SortBase = [&](Instruction *A, std::pair X, std::pair Y) { int MXA = GetBaseMaskValue(A, X.first); int MYA = GetBaseMaskValue(A, Y.first); return MXA < MYA; }; stable_sort(V1, [&](std::pair A, std::pair B) { return SortBase(SVI0A, A, B); }); stable_sort(V2, [&](std::pair A, std::pair B) { return SortBase(SVI1A, A, B); }); // Calculate our ReconstructMasks from the OrigReconstructMasks and the // modified order of the input shuffles. SmallVector> ReconstructMasks; for (const auto &Mask : OrigReconstructMasks) { SmallVector ReconstructMask; for (int M : Mask) { auto FindIndex = [](const SmallVector> &V, int M) { auto It = find_if(V, [M](auto A) { return A.second == M; }); assert(It != V.end() && "Expected all entries in Mask"); return std::distance(V.begin(), It); }; if (M < 0) ReconstructMask.push_back(-1); else if (M < static_cast(NumElts)) { ReconstructMask.push_back(FindIndex(V1, M)); } else { ReconstructMask.push_back(NumElts + FindIndex(V2, M)); } } ReconstructMasks.push_back(std::move(ReconstructMask)); } // Calculate the masks needed for the new input shuffles, which get padded // with undef SmallVector V1A, V1B, V2A, V2B; for (unsigned I = 0; I < V1.size(); I++) { V1A.push_back(GetBaseMaskValue(SVI0A, V1[I].first)); V1B.push_back(GetBaseMaskValue(SVI0B, V1[I].first)); } for (unsigned I = 0; I < V2.size(); I++) { V2A.push_back(GetBaseMaskValue(SVI1A, V2[I].first)); V2B.push_back(GetBaseMaskValue(SVI1B, V2[I].first)); } while (V1A.size() < NumElts) { V1A.push_back(PoisonMaskElem); V1B.push_back(PoisonMaskElem); } while (V2A.size() < NumElts) { V2A.push_back(PoisonMaskElem); V2B.push_back(PoisonMaskElem); } auto AddShuffleCost = [&](InstructionCost C, Instruction *I) { auto *SV = dyn_cast(I); if (!SV) return C; return C + TTI.getShuffleCost(isa(SV->getOperand(1)) ? TTI::SK_PermuteSingleSrc : TTI::SK_PermuteTwoSrc, VT, SV->getShuffleMask()); }; auto AddShuffleMaskCost = [&](InstructionCost C, ArrayRef Mask) { return C + TTI.getShuffleCost(TTI::SK_PermuteTwoSrc, VT, Mask); }; // Get the costs of the shuffles + binops before and after with the new // shuffle masks. InstructionCost CostBefore = TTI.getArithmeticInstrCost(Op0->getOpcode(), VT) + TTI.getArithmeticInstrCost(Op1->getOpcode(), VT); CostBefore += std::accumulate(Shuffles.begin(), Shuffles.end(), InstructionCost(0), AddShuffleCost); CostBefore += std::accumulate(InputShuffles.begin(), InputShuffles.end(), InstructionCost(0), AddShuffleCost); // The new binops will be unused for lanes past the used shuffle lengths. // These types attempt to get the correct cost for that from the target. FixedVectorType *Op0SmallVT = FixedVectorType::get(VT->getScalarType(), V1.size()); FixedVectorType *Op1SmallVT = FixedVectorType::get(VT->getScalarType(), V2.size()); InstructionCost CostAfter = TTI.getArithmeticInstrCost(Op0->getOpcode(), Op0SmallVT) + TTI.getArithmeticInstrCost(Op1->getOpcode(), Op1SmallVT); CostAfter += std::accumulate(ReconstructMasks.begin(), ReconstructMasks.end(), InstructionCost(0), AddShuffleMaskCost); std::set> OutputShuffleMasks({V1A, V1B, V2A, V2B}); CostAfter += std::accumulate(OutputShuffleMasks.begin(), OutputShuffleMasks.end(), InstructionCost(0), AddShuffleMaskCost); LLVM_DEBUG(dbgs() << "Found a binop select shuffle pattern: " << I << "\n"); LLVM_DEBUG(dbgs() << " CostBefore: " << CostBefore << " vs CostAfter: " << CostAfter << "\n"); if (CostBefore <= CostAfter) return false; // The cost model has passed, create the new instructions. auto GetShuffleOperand = [&](Instruction *I, unsigned Op) -> Value * { auto *SV = dyn_cast(I); if (!SV) return I; if (isa(SV->getOperand(1))) if (auto *SSV = dyn_cast(SV->getOperand(0))) if (InputShuffles.contains(SSV)) return SSV->getOperand(Op); return SV->getOperand(Op); }; Builder.SetInsertPoint(*SVI0A->getInsertionPointAfterDef()); Value *NSV0A = Builder.CreateShuffleVector(GetShuffleOperand(SVI0A, 0), GetShuffleOperand(SVI0A, 1), V1A); Builder.SetInsertPoint(*SVI0B->getInsertionPointAfterDef()); Value *NSV0B = Builder.CreateShuffleVector(GetShuffleOperand(SVI0B, 0), GetShuffleOperand(SVI0B, 1), V1B); Builder.SetInsertPoint(*SVI1A->getInsertionPointAfterDef()); Value *NSV1A = Builder.CreateShuffleVector(GetShuffleOperand(SVI1A, 0), GetShuffleOperand(SVI1A, 1), V2A); Builder.SetInsertPoint(*SVI1B->getInsertionPointAfterDef()); Value *NSV1B = Builder.CreateShuffleVector(GetShuffleOperand(SVI1B, 0), GetShuffleOperand(SVI1B, 1), V2B); Builder.SetInsertPoint(Op0); Value *NOp0 = Builder.CreateBinOp((Instruction::BinaryOps)Op0->getOpcode(), NSV0A, NSV0B); if (auto *I = dyn_cast(NOp0)) I->copyIRFlags(Op0, true); Builder.SetInsertPoint(Op1); Value *NOp1 = Builder.CreateBinOp((Instruction::BinaryOps)Op1->getOpcode(), NSV1A, NSV1B); if (auto *I = dyn_cast(NOp1)) I->copyIRFlags(Op1, true); for (int S = 0, E = ReconstructMasks.size(); S != E; S++) { Builder.SetInsertPoint(Shuffles[S]); Value *NSV = Builder.CreateShuffleVector(NOp0, NOp1, ReconstructMasks[S]); replaceValue(*Shuffles[S], *NSV); } Worklist.pushValue(NSV0A); Worklist.pushValue(NSV0B); Worklist.pushValue(NSV1A); Worklist.pushValue(NSV1B); for (auto *S : Shuffles) Worklist.add(S); return true; } /// This is the entry point for all transforms. Pass manager differences are /// handled in the callers of this function. bool VectorCombine::run() { if (DisableVectorCombine) return false; // Don't attempt vectorization if the target does not support vectors. if (!TTI.getNumberOfRegisters(TTI.getRegisterClassForType(/*Vector*/ true))) return false; bool MadeChange = false; auto FoldInst = [this, &MadeChange](Instruction &I) { Builder.SetInsertPoint(&I); bool IsFixedVectorType = isa(I.getType()); auto Opcode = I.getOpcode(); // These folds should be beneficial regardless of when this pass is run // in the optimization pipeline. // The type checking is for run-time efficiency. We can avoid wasting time // dispatching to folding functions if there's no chance of matching. if (IsFixedVectorType) { switch (Opcode) { case Instruction::InsertElement: MadeChange |= vectorizeLoadInsert(I); break; case Instruction::ShuffleVector: MadeChange |= widenSubvectorLoad(I); break; default: break; } } // This transform works with scalable and fixed vectors // TODO: Identify and allow other scalable transforms if (isa(I.getType())) { MadeChange |= scalarizeBinopOrCmp(I); MadeChange |= scalarizeLoadExtract(I); MadeChange |= scalarizeVPIntrinsic(I); } if (Opcode == Instruction::Store) MadeChange |= foldSingleElementStore(I); // If this is an early pipeline invocation of this pass, we are done. if (TryEarlyFoldsOnly) return; // Otherwise, try folds that improve codegen but may interfere with // early IR canonicalizations. // The type checking is for run-time efficiency. We can avoid wasting time // dispatching to folding functions if there's no chance of matching. if (IsFixedVectorType) { switch (Opcode) { case Instruction::InsertElement: MadeChange |= foldInsExtFNeg(I); break; case Instruction::ShuffleVector: MadeChange |= foldShuffleOfBinops(I); MadeChange |= foldShuffleOfCastops(I); MadeChange |= foldShuffleOfShuffles(I); MadeChange |= foldSelectShuffle(I); MadeChange |= foldShuffleToIdentity(I); break; case Instruction::BitCast: MadeChange |= foldBitcastShuffle(I); break; } } else { switch (Opcode) { case Instruction::Call: MadeChange |= foldShuffleFromReductions(I); MadeChange |= foldCastFromReductions(I); break; case Instruction::ICmp: case Instruction::FCmp: MadeChange |= foldExtractExtract(I); break; default: if (Instruction::isBinaryOp(Opcode)) { MadeChange |= foldExtractExtract(I); MadeChange |= foldExtractedCmps(I); } break; } } }; for (BasicBlock &BB : F) { // Ignore unreachable basic blocks. if (!DT.isReachableFromEntry(&BB)) continue; // Use early increment range so that we can erase instructions in loop. for (Instruction &I : make_early_inc_range(BB)) { if (I.isDebugOrPseudoInst()) continue; FoldInst(I); } } while (!Worklist.isEmpty()) { Instruction *I = Worklist.removeOne(); if (!I) continue; if (isInstructionTriviallyDead(I)) { eraseInstruction(*I); continue; } FoldInst(*I); } return MadeChange; } PreservedAnalyses VectorCombinePass::run(Function &F, FunctionAnalysisManager &FAM) { auto &AC = FAM.getResult(F); TargetTransformInfo &TTI = FAM.getResult(F); DominatorTree &DT = FAM.getResult(F); AAResults &AA = FAM.getResult(F); const DataLayout *DL = &F.getDataLayout(); VectorCombine Combiner(F, TTI, DT, AA, AC, DL, TryEarlyFoldsOnly); if (!Combiner.run()) return PreservedAnalyses::all(); PreservedAnalyses PA; PA.preserveSet(); return PA; }