//===---- CGLoopInfo.cpp - LLVM CodeGen for loop metadata -*- C++ -*-------===// // // 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 "CGLoopInfo.h" #include "clang/AST/ASTContext.h" #include "clang/AST/Attr.h" #include "clang/AST/Expr.h" #include "clang/Basic/CodeGenOptions.h" #include "llvm/IR/BasicBlock.h" #include "llvm/IR/CFG.h" #include "llvm/IR/Constants.h" #include "llvm/IR/InstrTypes.h" #include "llvm/IR/Instructions.h" #include "llvm/IR/Metadata.h" #include using namespace clang::CodeGen; using namespace llvm; MDNode * LoopInfo::createLoopPropertiesMetadata(ArrayRef LoopProperties) { LLVMContext &Ctx = Header->getContext(); SmallVector NewLoopProperties; NewLoopProperties.push_back(nullptr); NewLoopProperties.append(LoopProperties.begin(), LoopProperties.end()); MDNode *LoopID = MDNode::getDistinct(Ctx, NewLoopProperties); LoopID->replaceOperandWith(0, LoopID); return LoopID; } MDNode *LoopInfo::createPipeliningMetadata(const LoopAttributes &Attrs, ArrayRef LoopProperties, bool &HasUserTransforms) { LLVMContext &Ctx = Header->getContext(); std::optional Enabled; if (Attrs.PipelineDisabled) Enabled = false; else if (Attrs.PipelineInitiationInterval != 0) Enabled = true; if (Enabled != true) { SmallVector NewLoopProperties; if (Enabled == false) { NewLoopProperties.append(LoopProperties.begin(), LoopProperties.end()); NewLoopProperties.push_back( MDNode::get(Ctx, {MDString::get(Ctx, "llvm.loop.pipeline.disable"), ConstantAsMetadata::get(ConstantInt::get( llvm::Type::getInt1Ty(Ctx), 1))})); LoopProperties = NewLoopProperties; } return createLoopPropertiesMetadata(LoopProperties); } SmallVector Args; Args.push_back(nullptr); Args.append(LoopProperties.begin(), LoopProperties.end()); if (Attrs.PipelineInitiationInterval > 0) { Metadata *Vals[] = { MDString::get(Ctx, "llvm.loop.pipeline.initiationinterval"), ConstantAsMetadata::get(ConstantInt::get( llvm::Type::getInt32Ty(Ctx), Attrs.PipelineInitiationInterval))}; Args.push_back(MDNode::get(Ctx, Vals)); } // No follow-up: This is the last transformation. MDNode *LoopID = MDNode::getDistinct(Ctx, Args); LoopID->replaceOperandWith(0, LoopID); HasUserTransforms = true; return LoopID; } MDNode * LoopInfo::createPartialUnrollMetadata(const LoopAttributes &Attrs, ArrayRef LoopProperties, bool &HasUserTransforms) { LLVMContext &Ctx = Header->getContext(); std::optional Enabled; if (Attrs.UnrollEnable == LoopAttributes::Disable) Enabled = false; else if (Attrs.UnrollEnable == LoopAttributes::Full) Enabled = std::nullopt; else if (Attrs.UnrollEnable != LoopAttributes::Unspecified || Attrs.UnrollCount != 0) Enabled = true; if (Enabled != true) { // createFullUnrollMetadata will already have added llvm.loop.unroll.disable // if unrolling is disabled. return createPipeliningMetadata(Attrs, LoopProperties, HasUserTransforms); } SmallVector FollowupLoopProperties; // Apply all loop properties to the unrolled loop. FollowupLoopProperties.append(LoopProperties.begin(), LoopProperties.end()); // Don't unroll an already unrolled loop. FollowupLoopProperties.push_back( MDNode::get(Ctx, MDString::get(Ctx, "llvm.loop.unroll.disable"))); bool FollowupHasTransforms = false; MDNode *Followup = createPipeliningMetadata(Attrs, FollowupLoopProperties, FollowupHasTransforms); SmallVector Args; Args.push_back(nullptr); Args.append(LoopProperties.begin(), LoopProperties.end()); // Setting unroll.count if (Attrs.UnrollCount > 0) { Metadata *Vals[] = {MDString::get(Ctx, "llvm.loop.unroll.count"), ConstantAsMetadata::get(ConstantInt::get( llvm::Type::getInt32Ty(Ctx), Attrs.UnrollCount))}; Args.push_back(MDNode::get(Ctx, Vals)); } // Setting unroll.full or unroll.disable if (Attrs.UnrollEnable == LoopAttributes::Enable) { Metadata *Vals[] = {MDString::get(Ctx, "llvm.loop.unroll.enable")}; Args.push_back(MDNode::get(Ctx, Vals)); } if (FollowupHasTransforms) Args.push_back(MDNode::get( Ctx, {MDString::get(Ctx, "llvm.loop.unroll.followup_all"), Followup})); MDNode *LoopID = MDNode::getDistinct(Ctx, Args); LoopID->replaceOperandWith(0, LoopID); HasUserTransforms = true; return LoopID; } MDNode * LoopInfo::createUnrollAndJamMetadata(const LoopAttributes &Attrs, ArrayRef LoopProperties, bool &HasUserTransforms) { LLVMContext &Ctx = Header->getContext(); std::optional Enabled; if (Attrs.UnrollAndJamEnable == LoopAttributes::Disable) Enabled = false; else if (Attrs.UnrollAndJamEnable == LoopAttributes::Enable || Attrs.UnrollAndJamCount != 0) Enabled = true; if (Enabled != true) { SmallVector NewLoopProperties; if (Enabled == false) { NewLoopProperties.append(LoopProperties.begin(), LoopProperties.end()); NewLoopProperties.push_back(MDNode::get( Ctx, MDString::get(Ctx, "llvm.loop.unroll_and_jam.disable"))); LoopProperties = NewLoopProperties; } return createPartialUnrollMetadata(Attrs, LoopProperties, HasUserTransforms); } SmallVector FollowupLoopProperties; FollowupLoopProperties.append(LoopProperties.begin(), LoopProperties.end()); FollowupLoopProperties.push_back( MDNode::get(Ctx, MDString::get(Ctx, "llvm.loop.unroll_and_jam.disable"))); bool FollowupHasTransforms = false; MDNode *Followup = createPartialUnrollMetadata(Attrs, FollowupLoopProperties, FollowupHasTransforms); SmallVector Args; Args.push_back(nullptr); Args.append(LoopProperties.begin(), LoopProperties.end()); // Setting unroll_and_jam.count if (Attrs.UnrollAndJamCount > 0) { Metadata *Vals[] = { MDString::get(Ctx, "llvm.loop.unroll_and_jam.count"), ConstantAsMetadata::get(ConstantInt::get(llvm::Type::getInt32Ty(Ctx), Attrs.UnrollAndJamCount))}; Args.push_back(MDNode::get(Ctx, Vals)); } if (Attrs.UnrollAndJamEnable == LoopAttributes::Enable) { Metadata *Vals[] = {MDString::get(Ctx, "llvm.loop.unroll_and_jam.enable")}; Args.push_back(MDNode::get(Ctx, Vals)); } if (FollowupHasTransforms) Args.push_back(MDNode::get( Ctx, {MDString::get(Ctx, "llvm.loop.unroll_and_jam.followup_outer"), Followup})); if (UnrollAndJamInnerFollowup) Args.push_back(MDNode::get( Ctx, {MDString::get(Ctx, "llvm.loop.unroll_and_jam.followup_inner"), UnrollAndJamInnerFollowup})); MDNode *LoopID = MDNode::getDistinct(Ctx, Args); LoopID->replaceOperandWith(0, LoopID); HasUserTransforms = true; return LoopID; } MDNode * LoopInfo::createLoopVectorizeMetadata(const LoopAttributes &Attrs, ArrayRef LoopProperties, bool &HasUserTransforms) { LLVMContext &Ctx = Header->getContext(); std::optional Enabled; if (Attrs.VectorizeEnable == LoopAttributes::Disable) Enabled = false; else if (Attrs.VectorizeEnable != LoopAttributes::Unspecified || Attrs.VectorizePredicateEnable != LoopAttributes::Unspecified || Attrs.InterleaveCount != 0 || Attrs.VectorizeWidth != 0 || Attrs.VectorizeScalable != LoopAttributes::Unspecified) Enabled = true; if (Enabled != true) { SmallVector NewLoopProperties; if (Enabled == false) { NewLoopProperties.append(LoopProperties.begin(), LoopProperties.end()); NewLoopProperties.push_back( MDNode::get(Ctx, {MDString::get(Ctx, "llvm.loop.vectorize.enable"), ConstantAsMetadata::get(ConstantInt::get( llvm::Type::getInt1Ty(Ctx), 0))})); LoopProperties = NewLoopProperties; } return createUnrollAndJamMetadata(Attrs, LoopProperties, HasUserTransforms); } // Apply all loop properties to the vectorized loop. SmallVector FollowupLoopProperties; FollowupLoopProperties.append(LoopProperties.begin(), LoopProperties.end()); // Don't vectorize an already vectorized loop. FollowupLoopProperties.push_back( MDNode::get(Ctx, MDString::get(Ctx, "llvm.loop.isvectorized"))); bool FollowupHasTransforms = false; MDNode *Followup = createUnrollAndJamMetadata(Attrs, FollowupLoopProperties, FollowupHasTransforms); SmallVector Args; Args.push_back(nullptr); Args.append(LoopProperties.begin(), LoopProperties.end()); // Setting vectorize.predicate when it has been specified and vectorization // has not been disabled. bool IsVectorPredicateEnabled = false; if (Attrs.VectorizePredicateEnable != LoopAttributes::Unspecified) { IsVectorPredicateEnabled = (Attrs.VectorizePredicateEnable == LoopAttributes::Enable); Metadata *Vals[] = { MDString::get(Ctx, "llvm.loop.vectorize.predicate.enable"), ConstantAsMetadata::get(ConstantInt::get(llvm::Type::getInt1Ty(Ctx), IsVectorPredicateEnabled))}; Args.push_back(MDNode::get(Ctx, Vals)); } // Setting vectorize.width if (Attrs.VectorizeWidth > 0) { Metadata *Vals[] = { MDString::get(Ctx, "llvm.loop.vectorize.width"), ConstantAsMetadata::get(ConstantInt::get(llvm::Type::getInt32Ty(Ctx), Attrs.VectorizeWidth))}; Args.push_back(MDNode::get(Ctx, Vals)); } if (Attrs.VectorizeScalable != LoopAttributes::Unspecified) { bool IsScalable = Attrs.VectorizeScalable == LoopAttributes::Enable; Metadata *Vals[] = { MDString::get(Ctx, "llvm.loop.vectorize.scalable.enable"), ConstantAsMetadata::get( ConstantInt::get(llvm::Type::getInt1Ty(Ctx), IsScalable))}; Args.push_back(MDNode::get(Ctx, Vals)); } // Setting interleave.count if (Attrs.InterleaveCount > 0) { Metadata *Vals[] = { MDString::get(Ctx, "llvm.loop.interleave.count"), ConstantAsMetadata::get(ConstantInt::get(llvm::Type::getInt32Ty(Ctx), Attrs.InterleaveCount))}; Args.push_back(MDNode::get(Ctx, Vals)); } // vectorize.enable is set if: // 1) loop hint vectorize.enable is set, or // 2) it is implied when vectorize.predicate is set, or // 3) it is implied when vectorize.width is set to a value > 1 // 4) it is implied when vectorize.scalable.enable is true // 5) it is implied when vectorize.width is unset (0) and the user // explicitly requested fixed-width vectorization, i.e. // vectorize.scalable.enable is false. if (Attrs.VectorizeEnable != LoopAttributes::Unspecified || (IsVectorPredicateEnabled && Attrs.VectorizeWidth != 1) || Attrs.VectorizeWidth > 1 || Attrs.VectorizeScalable == LoopAttributes::Enable || (Attrs.VectorizeScalable == LoopAttributes::Disable && Attrs.VectorizeWidth != 1)) { bool AttrVal = Attrs.VectorizeEnable != LoopAttributes::Disable; Args.push_back( MDNode::get(Ctx, {MDString::get(Ctx, "llvm.loop.vectorize.enable"), ConstantAsMetadata::get(ConstantInt::get( llvm::Type::getInt1Ty(Ctx), AttrVal))})); } if (FollowupHasTransforms) Args.push_back(MDNode::get( Ctx, {MDString::get(Ctx, "llvm.loop.vectorize.followup_all"), Followup})); MDNode *LoopID = MDNode::getDistinct(Ctx, Args); LoopID->replaceOperandWith(0, LoopID); HasUserTransforms = true; return LoopID; } MDNode * LoopInfo::createLoopDistributeMetadata(const LoopAttributes &Attrs, ArrayRef LoopProperties, bool &HasUserTransforms) { LLVMContext &Ctx = Header->getContext(); std::optional Enabled; if (Attrs.DistributeEnable == LoopAttributes::Disable) Enabled = false; if (Attrs.DistributeEnable == LoopAttributes::Enable) Enabled = true; if (Enabled != true) { SmallVector NewLoopProperties; if (Enabled == false) { NewLoopProperties.append(LoopProperties.begin(), LoopProperties.end()); NewLoopProperties.push_back( MDNode::get(Ctx, {MDString::get(Ctx, "llvm.loop.distribute.enable"), ConstantAsMetadata::get(ConstantInt::get( llvm::Type::getInt1Ty(Ctx), 0))})); LoopProperties = NewLoopProperties; } return createLoopVectorizeMetadata(Attrs, LoopProperties, HasUserTransforms); } bool FollowupHasTransforms = false; MDNode *Followup = createLoopVectorizeMetadata(Attrs, LoopProperties, FollowupHasTransforms); SmallVector Args; Args.push_back(nullptr); Args.append(LoopProperties.begin(), LoopProperties.end()); Metadata *Vals[] = {MDString::get(Ctx, "llvm.loop.distribute.enable"), ConstantAsMetadata::get(ConstantInt::get( llvm::Type::getInt1Ty(Ctx), (Attrs.DistributeEnable == LoopAttributes::Enable)))}; Args.push_back(MDNode::get(Ctx, Vals)); if (FollowupHasTransforms) Args.push_back(MDNode::get( Ctx, {MDString::get(Ctx, "llvm.loop.distribute.followup_all"), Followup})); MDNode *LoopID = MDNode::getDistinct(Ctx, Args); LoopID->replaceOperandWith(0, LoopID); HasUserTransforms = true; return LoopID; } MDNode *LoopInfo::createFullUnrollMetadata(const LoopAttributes &Attrs, ArrayRef LoopProperties, bool &HasUserTransforms) { LLVMContext &Ctx = Header->getContext(); std::optional Enabled; if (Attrs.UnrollEnable == LoopAttributes::Disable) Enabled = false; else if (Attrs.UnrollEnable == LoopAttributes::Full) Enabled = true; if (Enabled != true) { SmallVector NewLoopProperties; if (Enabled == false) { NewLoopProperties.append(LoopProperties.begin(), LoopProperties.end()); NewLoopProperties.push_back( MDNode::get(Ctx, MDString::get(Ctx, "llvm.loop.unroll.disable"))); LoopProperties = NewLoopProperties; } return createLoopDistributeMetadata(Attrs, LoopProperties, HasUserTransforms); } SmallVector Args; Args.push_back(nullptr); Args.append(LoopProperties.begin(), LoopProperties.end()); Args.push_back(MDNode::get(Ctx, MDString::get(Ctx, "llvm.loop.unroll.full"))); // No follow-up: there is no loop after full unrolling. // TODO: Warn if there are transformations after full unrolling. MDNode *LoopID = MDNode::getDistinct(Ctx, Args); LoopID->replaceOperandWith(0, LoopID); HasUserTransforms = true; return LoopID; } MDNode *LoopInfo::createMetadata( const LoopAttributes &Attrs, llvm::ArrayRef AdditionalLoopProperties, bool &HasUserTransforms) { SmallVector LoopProperties; // If we have a valid start debug location for the loop, add it. if (StartLoc) { LoopProperties.push_back(StartLoc.getAsMDNode()); // If we also have a valid end debug location for the loop, add it. if (EndLoc) LoopProperties.push_back(EndLoc.getAsMDNode()); } LLVMContext &Ctx = Header->getContext(); if (Attrs.MustProgress) LoopProperties.push_back( MDNode::get(Ctx, MDString::get(Ctx, "llvm.loop.mustprogress"))); assert(!!AccGroup == Attrs.IsParallel && "There must be an access group iff the loop is parallel"); if (Attrs.IsParallel) { LoopProperties.push_back(MDNode::get( Ctx, {MDString::get(Ctx, "llvm.loop.parallel_accesses"), AccGroup})); } LoopProperties.insert(LoopProperties.end(), AdditionalLoopProperties.begin(), AdditionalLoopProperties.end()); return createFullUnrollMetadata(Attrs, LoopProperties, HasUserTransforms); } LoopAttributes::LoopAttributes(bool IsParallel) : IsParallel(IsParallel), VectorizeEnable(LoopAttributes::Unspecified), UnrollEnable(LoopAttributes::Unspecified), UnrollAndJamEnable(LoopAttributes::Unspecified), VectorizePredicateEnable(LoopAttributes::Unspecified), VectorizeWidth(0), VectorizeScalable(LoopAttributes::Unspecified), InterleaveCount(0), UnrollCount(0), UnrollAndJamCount(0), DistributeEnable(LoopAttributes::Unspecified), PipelineDisabled(false), PipelineInitiationInterval(0), MustProgress(false) {} void LoopAttributes::clear() { IsParallel = false; VectorizeWidth = 0; VectorizeScalable = LoopAttributes::Unspecified; InterleaveCount = 0; UnrollCount = 0; UnrollAndJamCount = 0; VectorizeEnable = LoopAttributes::Unspecified; UnrollEnable = LoopAttributes::Unspecified; UnrollAndJamEnable = LoopAttributes::Unspecified; VectorizePredicateEnable = LoopAttributes::Unspecified; DistributeEnable = LoopAttributes::Unspecified; PipelineDisabled = false; PipelineInitiationInterval = 0; MustProgress = false; } LoopInfo::LoopInfo(BasicBlock *Header, const LoopAttributes &Attrs, const llvm::DebugLoc &StartLoc, const llvm::DebugLoc &EndLoc, LoopInfo *Parent) : Header(Header), Attrs(Attrs), StartLoc(StartLoc), EndLoc(EndLoc), Parent(Parent) { if (Attrs.IsParallel) { // Create an access group for this loop. LLVMContext &Ctx = Header->getContext(); AccGroup = MDNode::getDistinct(Ctx, {}); } if (!Attrs.IsParallel && Attrs.VectorizeWidth == 0 && Attrs.VectorizeScalable == LoopAttributes::Unspecified && Attrs.InterleaveCount == 0 && Attrs.UnrollCount == 0 && Attrs.UnrollAndJamCount == 0 && !Attrs.PipelineDisabled && Attrs.PipelineInitiationInterval == 0 && Attrs.VectorizePredicateEnable == LoopAttributes::Unspecified && Attrs.VectorizeEnable == LoopAttributes::Unspecified && Attrs.UnrollEnable == LoopAttributes::Unspecified && Attrs.UnrollAndJamEnable == LoopAttributes::Unspecified && Attrs.DistributeEnable == LoopAttributes::Unspecified && !StartLoc && !EndLoc && !Attrs.MustProgress) return; TempLoopID = MDNode::getTemporary(Header->getContext(), std::nullopt); } void LoopInfo::finish() { // We did not annotate the loop body instructions because there are no // attributes for this loop. if (!TempLoopID) return; MDNode *LoopID; LoopAttributes CurLoopAttr = Attrs; LLVMContext &Ctx = Header->getContext(); if (Parent && (Parent->Attrs.UnrollAndJamEnable || Parent->Attrs.UnrollAndJamCount != 0)) { // Parent unroll-and-jams this loop. // Split the transformations in those that happens before the unroll-and-jam // and those after. LoopAttributes BeforeJam, AfterJam; BeforeJam.IsParallel = AfterJam.IsParallel = Attrs.IsParallel; BeforeJam.VectorizeWidth = Attrs.VectorizeWidth; BeforeJam.VectorizeScalable = Attrs.VectorizeScalable; BeforeJam.InterleaveCount = Attrs.InterleaveCount; BeforeJam.VectorizeEnable = Attrs.VectorizeEnable; BeforeJam.DistributeEnable = Attrs.DistributeEnable; BeforeJam.VectorizePredicateEnable = Attrs.VectorizePredicateEnable; switch (Attrs.UnrollEnable) { case LoopAttributes::Unspecified: case LoopAttributes::Disable: BeforeJam.UnrollEnable = Attrs.UnrollEnable; AfterJam.UnrollEnable = Attrs.UnrollEnable; break; case LoopAttributes::Full: BeforeJam.UnrollEnable = LoopAttributes::Full; break; case LoopAttributes::Enable: AfterJam.UnrollEnable = LoopAttributes::Enable; break; } AfterJam.VectorizePredicateEnable = Attrs.VectorizePredicateEnable; AfterJam.UnrollCount = Attrs.UnrollCount; AfterJam.PipelineDisabled = Attrs.PipelineDisabled; AfterJam.PipelineInitiationInterval = Attrs.PipelineInitiationInterval; // If this loop is subject of an unroll-and-jam by the parent loop, and has // an unroll-and-jam annotation itself, we have to decide whether to first // apply the parent's unroll-and-jam or this loop's unroll-and-jam. The // UnrollAndJam pass processes loops from inner to outer, so we apply the // inner first. BeforeJam.UnrollAndJamCount = Attrs.UnrollAndJamCount; BeforeJam.UnrollAndJamEnable = Attrs.UnrollAndJamEnable; // Set the inner followup metadata to process by the outer loop. Only // consider the first inner loop. if (!Parent->UnrollAndJamInnerFollowup) { // Splitting the attributes into a BeforeJam and an AfterJam part will // stop 'llvm.loop.isvectorized' (generated by vectorization in BeforeJam) // to be forwarded to the AfterJam part. We detect the situation here and // add it manually. SmallVector BeforeLoopProperties; if (BeforeJam.VectorizeEnable != LoopAttributes::Unspecified || BeforeJam.VectorizePredicateEnable != LoopAttributes::Unspecified || BeforeJam.InterleaveCount != 0 || BeforeJam.VectorizeWidth != 0 || BeforeJam.VectorizeScalable == LoopAttributes::Enable) BeforeLoopProperties.push_back( MDNode::get(Ctx, MDString::get(Ctx, "llvm.loop.isvectorized"))); bool InnerFollowupHasTransform = false; MDNode *InnerFollowup = createMetadata(AfterJam, BeforeLoopProperties, InnerFollowupHasTransform); if (InnerFollowupHasTransform) Parent->UnrollAndJamInnerFollowup = InnerFollowup; } CurLoopAttr = BeforeJam; } bool HasUserTransforms = false; LoopID = createMetadata(CurLoopAttr, {}, HasUserTransforms); TempLoopID->replaceAllUsesWith(LoopID); } void LoopInfoStack::push(BasicBlock *Header, const llvm::DebugLoc &StartLoc, const llvm::DebugLoc &EndLoc) { Active.emplace_back( new LoopInfo(Header, StagedAttrs, StartLoc, EndLoc, Active.empty() ? nullptr : Active.back().get())); // Clear the attributes so nested loops do not inherit them. StagedAttrs.clear(); } void LoopInfoStack::push(BasicBlock *Header, clang::ASTContext &Ctx, const clang::CodeGenOptions &CGOpts, ArrayRef Attrs, const llvm::DebugLoc &StartLoc, const llvm::DebugLoc &EndLoc, bool MustProgress) { // Identify loop hint attributes from Attrs. for (const auto *Attr : Attrs) { const LoopHintAttr *LH = dyn_cast(Attr); const OpenCLUnrollHintAttr *OpenCLHint = dyn_cast(Attr); // Skip non loop hint attributes if (!LH && !OpenCLHint) { continue; } LoopHintAttr::OptionType Option = LoopHintAttr::Unroll; LoopHintAttr::LoopHintState State = LoopHintAttr::Disable; unsigned ValueInt = 1; // Translate opencl_unroll_hint attribute argument to // equivalent LoopHintAttr enums. // OpenCL v2.0 s6.11.5: // 0 - enable unroll (no argument). // 1 - disable unroll. // other positive integer n - unroll by n. if (OpenCLHint) { ValueInt = OpenCLHint->getUnrollHint(); if (ValueInt == 0) { State = LoopHintAttr::Enable; } else if (ValueInt != 1) { Option = LoopHintAttr::UnrollCount; State = LoopHintAttr::Numeric; } } else if (LH) { auto *ValueExpr = LH->getValue(); if (ValueExpr) { llvm::APSInt ValueAPS = ValueExpr->EvaluateKnownConstInt(Ctx); ValueInt = ValueAPS.getSExtValue(); } Option = LH->getOption(); State = LH->getState(); } switch (State) { case LoopHintAttr::Disable: switch (Option) { case LoopHintAttr::Vectorize: // Disable vectorization by specifying a width of 1. setVectorizeWidth(1); setVectorizeScalable(LoopAttributes::Unspecified); break; case LoopHintAttr::Interleave: // Disable interleaving by speciyfing a count of 1. setInterleaveCount(1); break; case LoopHintAttr::Unroll: setUnrollState(LoopAttributes::Disable); break; case LoopHintAttr::UnrollAndJam: setUnrollAndJamState(LoopAttributes::Disable); break; case LoopHintAttr::VectorizePredicate: setVectorizePredicateState(LoopAttributes::Disable); break; case LoopHintAttr::Distribute: setDistributeState(false); break; case LoopHintAttr::PipelineDisabled: setPipelineDisabled(true); break; case LoopHintAttr::UnrollCount: case LoopHintAttr::UnrollAndJamCount: case LoopHintAttr::VectorizeWidth: case LoopHintAttr::InterleaveCount: case LoopHintAttr::PipelineInitiationInterval: llvm_unreachable("Options cannot be disabled."); break; } break; case LoopHintAttr::Enable: switch (Option) { case LoopHintAttr::Vectorize: case LoopHintAttr::Interleave: setVectorizeEnable(true); break; case LoopHintAttr::Unroll: setUnrollState(LoopAttributes::Enable); break; case LoopHintAttr::UnrollAndJam: setUnrollAndJamState(LoopAttributes::Enable); break; case LoopHintAttr::VectorizePredicate: setVectorizePredicateState(LoopAttributes::Enable); break; case LoopHintAttr::Distribute: setDistributeState(true); break; case LoopHintAttr::UnrollCount: case LoopHintAttr::UnrollAndJamCount: case LoopHintAttr::VectorizeWidth: case LoopHintAttr::InterleaveCount: case LoopHintAttr::PipelineDisabled: case LoopHintAttr::PipelineInitiationInterval: llvm_unreachable("Options cannot enabled."); break; } break; case LoopHintAttr::AssumeSafety: switch (Option) { case LoopHintAttr::Vectorize: case LoopHintAttr::Interleave: // Apply "llvm.mem.parallel_loop_access" metadata to load/stores. setParallel(true); setVectorizeEnable(true); break; case LoopHintAttr::Unroll: case LoopHintAttr::UnrollAndJam: case LoopHintAttr::VectorizePredicate: case LoopHintAttr::UnrollCount: case LoopHintAttr::UnrollAndJamCount: case LoopHintAttr::VectorizeWidth: case LoopHintAttr::InterleaveCount: case LoopHintAttr::Distribute: case LoopHintAttr::PipelineDisabled: case LoopHintAttr::PipelineInitiationInterval: llvm_unreachable("Options cannot be used to assume mem safety."); break; } break; case LoopHintAttr::Full: switch (Option) { case LoopHintAttr::Unroll: setUnrollState(LoopAttributes::Full); break; case LoopHintAttr::UnrollAndJam: setUnrollAndJamState(LoopAttributes::Full); break; case LoopHintAttr::Vectorize: case LoopHintAttr::Interleave: case LoopHintAttr::UnrollCount: case LoopHintAttr::UnrollAndJamCount: case LoopHintAttr::VectorizeWidth: case LoopHintAttr::InterleaveCount: case LoopHintAttr::Distribute: case LoopHintAttr::PipelineDisabled: case LoopHintAttr::PipelineInitiationInterval: case LoopHintAttr::VectorizePredicate: llvm_unreachable("Options cannot be used with 'full' hint."); break; } break; case LoopHintAttr::FixedWidth: case LoopHintAttr::ScalableWidth: switch (Option) { case LoopHintAttr::VectorizeWidth: setVectorizeScalable(State == LoopHintAttr::ScalableWidth ? LoopAttributes::Enable : LoopAttributes::Disable); if (LH->getValue()) setVectorizeWidth(ValueInt); break; default: llvm_unreachable("Options cannot be used with 'scalable' hint."); break; } break; case LoopHintAttr::Numeric: switch (Option) { case LoopHintAttr::InterleaveCount: setInterleaveCount(ValueInt); break; case LoopHintAttr::UnrollCount: setUnrollCount(ValueInt); break; case LoopHintAttr::UnrollAndJamCount: setUnrollAndJamCount(ValueInt); break; case LoopHintAttr::PipelineInitiationInterval: setPipelineInitiationInterval(ValueInt); break; case LoopHintAttr::Unroll: case LoopHintAttr::UnrollAndJam: case LoopHintAttr::VectorizePredicate: case LoopHintAttr::Vectorize: case LoopHintAttr::VectorizeWidth: case LoopHintAttr::Interleave: case LoopHintAttr::Distribute: case LoopHintAttr::PipelineDisabled: llvm_unreachable("Options cannot be assigned a value."); break; } break; } } setMustProgress(MustProgress); if (CGOpts.OptimizationLevel > 0) // Disable unrolling for the loop, if unrolling is disabled (via // -fno-unroll-loops) and no pragmas override the decision. if (!CGOpts.UnrollLoops && (StagedAttrs.UnrollEnable == LoopAttributes::Unspecified && StagedAttrs.UnrollCount == 0)) setUnrollState(LoopAttributes::Disable); /// Stage the attributes. push(Header, StartLoc, EndLoc); } void LoopInfoStack::pop() { assert(!Active.empty() && "No active loops to pop"); Active.back()->finish(); Active.pop_back(); } void LoopInfoStack::InsertHelper(Instruction *I) const { if (I->mayReadOrWriteMemory()) { SmallVector AccessGroups; for (const auto &AL : Active) { // Here we assume that every loop that has an access group is parallel. if (MDNode *Group = AL->getAccessGroup()) AccessGroups.push_back(Group); } MDNode *UnionMD = nullptr; if (AccessGroups.size() == 1) UnionMD = cast(AccessGroups[0]); else if (AccessGroups.size() >= 2) UnionMD = MDNode::get(I->getContext(), AccessGroups); I->setMetadata("llvm.access.group", UnionMD); } if (!hasInfo()) return; const LoopInfo &L = getInfo(); if (!L.getLoopID()) return; if (I->isTerminator()) { for (BasicBlock *Succ : successors(I)) if (Succ == L.getHeader()) { I->setMetadata(llvm::LLVMContext::MD_loop, L.getLoopID()); break; } return; } }