//===- Parsing, selection, and construction of pass pipelines -------------===// // // 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 // //===----------------------------------------------------------------------===// /// \file /// /// This file provides the implementation of the PassBuilder based on our /// static pass registry as well as related functionality. It also provides /// helpers to aid in analyzing, debugging, and testing passes and pass /// pipelines. /// //===----------------------------------------------------------------------===// #include "llvm/Passes/PassBuilder.h" #include "llvm/ADT/StringSwitch.h" #include "llvm/Analysis/AliasAnalysisEvaluator.h" #include "llvm/Analysis/AliasSetTracker.h" #include "llvm/Analysis/AssumptionCache.h" #include "llvm/Analysis/BasicAliasAnalysis.h" #include "llvm/Analysis/BlockFrequencyInfo.h" #include "llvm/Analysis/BranchProbabilityInfo.h" #include "llvm/Analysis/CFGPrinter.h" #include "llvm/Analysis/CFLAndersAliasAnalysis.h" #include "llvm/Analysis/CFLSteensAliasAnalysis.h" #include "llvm/Analysis/CGSCCPassManager.h" #include "llvm/Analysis/CallGraph.h" #include "llvm/Analysis/DDG.h" #include "llvm/Analysis/DDGPrinter.h" #include "llvm/Analysis/Delinearization.h" #include "llvm/Analysis/DemandedBits.h" #include "llvm/Analysis/DependenceAnalysis.h" #include "llvm/Analysis/DivergenceAnalysis.h" #include "llvm/Analysis/DominanceFrontier.h" #include "llvm/Analysis/FunctionPropertiesAnalysis.h" #include "llvm/Analysis/GlobalsModRef.h" #include "llvm/Analysis/IRSimilarityIdentifier.h" #include "llvm/Analysis/IVUsers.h" #include "llvm/Analysis/InlineAdvisor.h" #include "llvm/Analysis/InlineSizeEstimatorAnalysis.h" #include "llvm/Analysis/InstCount.h" #include "llvm/Analysis/LazyCallGraph.h" #include "llvm/Analysis/LazyValueInfo.h" #include "llvm/Analysis/Lint.h" #include "llvm/Analysis/LoopAccessAnalysis.h" #include "llvm/Analysis/LoopCacheAnalysis.h" #include "llvm/Analysis/LoopInfo.h" #include "llvm/Analysis/LoopNestAnalysis.h" #include "llvm/Analysis/MemDerefPrinter.h" #include "llvm/Analysis/MemoryDependenceAnalysis.h" #include "llvm/Analysis/MemorySSA.h" #include "llvm/Analysis/ModuleDebugInfoPrinter.h" #include "llvm/Analysis/ModuleSummaryAnalysis.h" #include "llvm/Analysis/MustExecute.h" #include "llvm/Analysis/ObjCARCAliasAnalysis.h" #include "llvm/Analysis/OptimizationRemarkEmitter.h" #include "llvm/Analysis/PhiValues.h" #include "llvm/Analysis/PostDominators.h" #include "llvm/Analysis/ProfileSummaryInfo.h" #include "llvm/Analysis/RegionInfo.h" #include "llvm/Analysis/ScalarEvolution.h" #include "llvm/Analysis/ScalarEvolutionAliasAnalysis.h" #include "llvm/Analysis/ScopedNoAliasAA.h" #include "llvm/Analysis/StackLifetime.h" #include "llvm/Analysis/StackSafetyAnalysis.h" #include "llvm/Analysis/TargetLibraryInfo.h" #include "llvm/Analysis/TargetTransformInfo.h" #include "llvm/Analysis/TypeBasedAliasAnalysis.h" #include "llvm/IR/Dominators.h" #include "llvm/IR/IRPrintingPasses.h" #include "llvm/IR/PassManager.h" #include "llvm/IR/PrintPasses.h" #include "llvm/IR/SafepointIRVerifier.h" #include "llvm/IR/Verifier.h" #include "llvm/Support/CommandLine.h" #include "llvm/Support/Debug.h" #include "llvm/Support/ErrorHandling.h" #include "llvm/Support/FormatVariadic.h" #include "llvm/Support/Regex.h" #include "llvm/Target/TargetMachine.h" #include "llvm/Transforms/AggressiveInstCombine/AggressiveInstCombine.h" #include "llvm/Transforms/Coroutines/CoroCleanup.h" #include "llvm/Transforms/Coroutines/CoroEarly.h" #include "llvm/Transforms/Coroutines/CoroElide.h" #include "llvm/Transforms/Coroutines/CoroSplit.h" #include "llvm/Transforms/IPO/AlwaysInliner.h" #include "llvm/Transforms/IPO/Annotation2Metadata.h" #include "llvm/Transforms/IPO/ArgumentPromotion.h" #include "llvm/Transforms/IPO/Attributor.h" #include "llvm/Transforms/IPO/BlockExtractor.h" #include "llvm/Transforms/IPO/CalledValuePropagation.h" #include "llvm/Transforms/IPO/ConstantMerge.h" #include "llvm/Transforms/IPO/CrossDSOCFI.h" #include "llvm/Transforms/IPO/DeadArgumentElimination.h" #include "llvm/Transforms/IPO/ElimAvailExtern.h" #include "llvm/Transforms/IPO/ForceFunctionAttrs.h" #include "llvm/Transforms/IPO/FunctionAttrs.h" #include "llvm/Transforms/IPO/FunctionImport.h" #include "llvm/Transforms/IPO/GlobalDCE.h" #include "llvm/Transforms/IPO/GlobalOpt.h" #include "llvm/Transforms/IPO/GlobalSplit.h" #include "llvm/Transforms/IPO/HotColdSplitting.h" #include "llvm/Transforms/IPO/IROutliner.h" #include "llvm/Transforms/IPO/InferFunctionAttrs.h" #include "llvm/Transforms/IPO/Inliner.h" #include "llvm/Transforms/IPO/Internalize.h" #include "llvm/Transforms/IPO/LoopExtractor.h" #include "llvm/Transforms/IPO/LowerTypeTests.h" #include "llvm/Transforms/IPO/MergeFunctions.h" #include "llvm/Transforms/IPO/OpenMPOpt.h" #include "llvm/Transforms/IPO/PartialInlining.h" #include "llvm/Transforms/IPO/SCCP.h" #include "llvm/Transforms/IPO/SampleProfile.h" #include "llvm/Transforms/IPO/SampleProfileProbe.h" #include "llvm/Transforms/IPO/StripDeadPrototypes.h" #include "llvm/Transforms/IPO/StripSymbols.h" #include "llvm/Transforms/IPO/SyntheticCountsPropagation.h" #include "llvm/Transforms/IPO/WholeProgramDevirt.h" #include "llvm/Transforms/InstCombine/InstCombine.h" #include "llvm/Transforms/Instrumentation.h" #include "llvm/Transforms/Instrumentation/AddressSanitizer.h" #include "llvm/Transforms/Instrumentation/BoundsChecking.h" #include "llvm/Transforms/Instrumentation/CGProfile.h" #include "llvm/Transforms/Instrumentation/ControlHeightReduction.h" #include "llvm/Transforms/Instrumentation/DataFlowSanitizer.h" #include "llvm/Transforms/Instrumentation/GCOVProfiler.h" #include "llvm/Transforms/Instrumentation/HWAddressSanitizer.h" #include "llvm/Transforms/Instrumentation/InstrOrderFile.h" #include "llvm/Transforms/Instrumentation/InstrProfiling.h" #include "llvm/Transforms/Instrumentation/MemProfiler.h" #include "llvm/Transforms/Instrumentation/MemorySanitizer.h" #include "llvm/Transforms/Instrumentation/PGOInstrumentation.h" #include "llvm/Transforms/Instrumentation/PoisonChecking.h" #include "llvm/Transforms/Instrumentation/SanitizerCoverage.h" #include "llvm/Transforms/Instrumentation/ThreadSanitizer.h" #include "llvm/Transforms/ObjCARC.h" #include "llvm/Transforms/Scalar/ADCE.h" #include "llvm/Transforms/Scalar/AlignmentFromAssumptions.h" #include "llvm/Transforms/Scalar/AnnotationRemarks.h" #include "llvm/Transforms/Scalar/BDCE.h" #include "llvm/Transforms/Scalar/CallSiteSplitting.h" #include "llvm/Transforms/Scalar/ConstantHoisting.h" #include "llvm/Transforms/Scalar/ConstraintElimination.h" #include "llvm/Transforms/Scalar/CorrelatedValuePropagation.h" #include "llvm/Transforms/Scalar/DCE.h" #include "llvm/Transforms/Scalar/DeadStoreElimination.h" #include "llvm/Transforms/Scalar/DivRemPairs.h" #include "llvm/Transforms/Scalar/EarlyCSE.h" #include "llvm/Transforms/Scalar/Float2Int.h" #include "llvm/Transforms/Scalar/GVN.h" #include "llvm/Transforms/Scalar/GuardWidening.h" #include "llvm/Transforms/Scalar/IVUsersPrinter.h" #include "llvm/Transforms/Scalar/IndVarSimplify.h" #include "llvm/Transforms/Scalar/InductiveRangeCheckElimination.h" #include "llvm/Transforms/Scalar/InferAddressSpaces.h" #include "llvm/Transforms/Scalar/InstSimplifyPass.h" #include "llvm/Transforms/Scalar/JumpThreading.h" #include "llvm/Transforms/Scalar/LICM.h" #include "llvm/Transforms/Scalar/LoopAccessAnalysisPrinter.h" #include "llvm/Transforms/Scalar/LoopDataPrefetch.h" #include "llvm/Transforms/Scalar/LoopDeletion.h" #include "llvm/Transforms/Scalar/LoopDistribute.h" #include "llvm/Transforms/Scalar/LoopFlatten.h" #include "llvm/Transforms/Scalar/LoopFuse.h" #include "llvm/Transforms/Scalar/LoopIdiomRecognize.h" #include "llvm/Transforms/Scalar/LoopInstSimplify.h" #include "llvm/Transforms/Scalar/LoopInterchange.h" #include "llvm/Transforms/Scalar/LoopLoadElimination.h" #include "llvm/Transforms/Scalar/LoopPassManager.h" #include "llvm/Transforms/Scalar/LoopPredication.h" #include "llvm/Transforms/Scalar/LoopReroll.h" #include "llvm/Transforms/Scalar/LoopRotation.h" #include "llvm/Transforms/Scalar/LoopSimplifyCFG.h" #include "llvm/Transforms/Scalar/LoopSink.h" #include "llvm/Transforms/Scalar/LoopStrengthReduce.h" #include "llvm/Transforms/Scalar/LoopUnrollAndJamPass.h" #include "llvm/Transforms/Scalar/LoopUnrollPass.h" #include "llvm/Transforms/Scalar/LoopVersioningLICM.h" #include "llvm/Transforms/Scalar/LowerAtomic.h" #include "llvm/Transforms/Scalar/LowerConstantIntrinsics.h" #include "llvm/Transforms/Scalar/LowerExpectIntrinsic.h" #include "llvm/Transforms/Scalar/LowerGuardIntrinsic.h" #include "llvm/Transforms/Scalar/LowerMatrixIntrinsics.h" #include "llvm/Transforms/Scalar/LowerWidenableCondition.h" #include "llvm/Transforms/Scalar/MakeGuardsExplicit.h" #include "llvm/Transforms/Scalar/MemCpyOptimizer.h" #include "llvm/Transforms/Scalar/MergeICmps.h" #include "llvm/Transforms/Scalar/MergedLoadStoreMotion.h" #include "llvm/Transforms/Scalar/NaryReassociate.h" #include "llvm/Transforms/Scalar/NewGVN.h" #include "llvm/Transforms/Scalar/PartiallyInlineLibCalls.h" #include "llvm/Transforms/Scalar/Reassociate.h" #include "llvm/Transforms/Scalar/Reg2Mem.h" #include "llvm/Transforms/Scalar/RewriteStatepointsForGC.h" #include "llvm/Transforms/Scalar/SCCP.h" #include "llvm/Transforms/Scalar/SROA.h" #include "llvm/Transforms/Scalar/ScalarizeMaskedMemIntrin.h" #include "llvm/Transforms/Scalar/Scalarizer.h" #include "llvm/Transforms/Scalar/SeparateConstOffsetFromGEP.h" #include "llvm/Transforms/Scalar/SimpleLoopUnswitch.h" #include "llvm/Transforms/Scalar/SimplifyCFG.h" #include "llvm/Transforms/Scalar/Sink.h" #include "llvm/Transforms/Scalar/SpeculateAroundPHIs.h" #include "llvm/Transforms/Scalar/SpeculativeExecution.h" #include "llvm/Transforms/Scalar/StraightLineStrengthReduce.h" #include "llvm/Transforms/Scalar/StructurizeCFG.h" #include "llvm/Transforms/Scalar/TailRecursionElimination.h" #include "llvm/Transforms/Scalar/WarnMissedTransforms.h" #include "llvm/Transforms/Utils/AddDiscriminators.h" #include "llvm/Transforms/Utils/AssumeBundleBuilder.h" #include "llvm/Transforms/Utils/BreakCriticalEdges.h" #include "llvm/Transforms/Utils/CanonicalizeAliases.h" #include "llvm/Transforms/Utils/CanonicalizeFreezeInLoops.h" #include "llvm/Transforms/Utils/EntryExitInstrumenter.h" #include "llvm/Transforms/Utils/FixIrreducible.h" #include "llvm/Transforms/Utils/HelloWorld.h" #include "llvm/Transforms/Utils/InjectTLIMappings.h" #include "llvm/Transforms/Utils/InstructionNamer.h" #include "llvm/Transforms/Utils/LCSSA.h" #include "llvm/Transforms/Utils/LibCallsShrinkWrap.h" #include "llvm/Transforms/Utils/LoopSimplify.h" #include "llvm/Transforms/Utils/LoopVersioning.h" #include "llvm/Transforms/Utils/LowerInvoke.h" #include "llvm/Transforms/Utils/LowerSwitch.h" #include "llvm/Transforms/Utils/Mem2Reg.h" #include "llvm/Transforms/Utils/MetaRenamer.h" #include "llvm/Transforms/Utils/NameAnonGlobals.h" #include "llvm/Transforms/Utils/RelLookupTableConverter.h" #include "llvm/Transforms/Utils/StripGCRelocates.h" #include "llvm/Transforms/Utils/StripNonLineTableDebugInfo.h" #include "llvm/Transforms/Utils/SymbolRewriter.h" #include "llvm/Transforms/Utils/UnifyFunctionExitNodes.h" #include "llvm/Transforms/Utils/UnifyLoopExits.h" #include "llvm/Transforms/Vectorize/LoadStoreVectorizer.h" #include "llvm/Transforms/Vectorize/LoopVectorize.h" #include "llvm/Transforms/Vectorize/SLPVectorizer.h" #include "llvm/Transforms/Vectorize/VectorCombine.h" using namespace llvm; static cl::opt UseInlineAdvisor( "enable-ml-inliner", cl::init(InliningAdvisorMode::Default), cl::Hidden, cl::desc("Enable ML policy for inliner. Currently trained for -Oz only"), cl::values(clEnumValN(InliningAdvisorMode::Default, "default", "Heuristics-based inliner version."), clEnumValN(InliningAdvisorMode::Development, "development", "Use development mode (runtime-loadable model)."), clEnumValN(InliningAdvisorMode::Release, "release", "Use release mode (AOT-compiled model)."))); static cl::opt EnableSyntheticCounts( "enable-npm-synthetic-counts", cl::init(false), cl::Hidden, cl::ZeroOrMore, cl::desc("Run synthetic function entry count generation " "pass")); static const Regex DefaultAliasRegex( "^(default|thinlto-pre-link|thinlto|lto-pre-link|lto)<(O[0123sz])>$"); /// Flag to enable inline deferral during PGO. static cl::opt EnablePGOInlineDeferral("enable-npm-pgo-inline-deferral", cl::init(true), cl::Hidden, cl::desc("Enable inline deferral during PGO")); static cl::opt EnableMemProfiler("enable-mem-prof", cl::init(false), cl::Hidden, cl::ZeroOrMore, cl::desc("Enable memory profiler")); static cl::opt PerformMandatoryInliningsFirst( "mandatory-inlining-first", cl::init(true), cl::Hidden, cl::ZeroOrMore, cl::desc("Perform mandatory inlinings module-wide, before performing " "inlining.")); static cl::opt EnableO3NonTrivialUnswitching( "enable-npm-O3-nontrivial-unswitch", cl::init(true), cl::Hidden, cl::ZeroOrMore, cl::desc("Enable non-trivial loop unswitching for -O3")); static cl::opt DoNotRerunFunctionPasses( "cgscc-npm-no-fp-rerun", cl::init(false), cl::desc("Do not rerun function passes wrapped by the scc pass adapter, if " "they were run already and the function hasn't changed.")); PipelineTuningOptions::PipelineTuningOptions() { LoopInterleaving = true; LoopVectorization = true; SLPVectorization = false; LoopUnrolling = true; ForgetAllSCEVInLoopUnroll = ForgetSCEVInLoopUnroll; Coroutines = false; LicmMssaOptCap = SetLicmMssaOptCap; LicmMssaNoAccForPromotionCap = SetLicmMssaNoAccForPromotionCap; CallGraphProfile = true; MergeFunctions = false; } namespace llvm { extern cl::opt MaxDevirtIterations; extern cl::opt EnableConstraintElimination; extern cl::opt EnableGVNHoist; extern cl::opt EnableGVNSink; extern cl::opt EnableHotColdSplit; extern cl::opt EnableIROutliner; extern cl::opt EnableOrderFileInstrumentation; extern cl::opt EnableCHR; extern cl::opt EnableLoopInterchange; extern cl::opt EnableUnrollAndJam; extern cl::opt EnableLoopFlatten; extern cl::opt RunNewGVN; extern cl::opt RunPartialInlining; extern cl::opt ExtraVectorizerPasses; extern cl::opt FlattenedProfileUsed; extern cl::opt AttributorRun; extern cl::opt EnableKnowledgeRetention; extern cl::opt EnableMatrix; extern cl::opt DisablePreInliner; extern cl::opt PreInlineThreshold; } // namespace llvm const PassBuilder::OptimizationLevel PassBuilder::OptimizationLevel::O0 = { /*SpeedLevel*/ 0, /*SizeLevel*/ 0}; const PassBuilder::OptimizationLevel PassBuilder::OptimizationLevel::O1 = { /*SpeedLevel*/ 1, /*SizeLevel*/ 0}; const PassBuilder::OptimizationLevel PassBuilder::OptimizationLevel::O2 = { /*SpeedLevel*/ 2, /*SizeLevel*/ 0}; const PassBuilder::OptimizationLevel PassBuilder::OptimizationLevel::O3 = { /*SpeedLevel*/ 3, /*SizeLevel*/ 0}; const PassBuilder::OptimizationLevel PassBuilder::OptimizationLevel::Os = { /*SpeedLevel*/ 2, /*SizeLevel*/ 1}; const PassBuilder::OptimizationLevel PassBuilder::OptimizationLevel::Oz = { /*SpeedLevel*/ 2, /*SizeLevel*/ 2}; namespace { // The following passes/analyses have custom names, otherwise their name will // include `(anonymous namespace)`. These are special since they are only for // testing purposes and don't live in a header file. /// No-op module pass which does nothing. struct NoOpModulePass : PassInfoMixin { PreservedAnalyses run(Module &M, ModuleAnalysisManager &) { return PreservedAnalyses::all(); } static StringRef name() { return "NoOpModulePass"; } }; /// No-op module analysis. class NoOpModuleAnalysis : public AnalysisInfoMixin { friend AnalysisInfoMixin; static AnalysisKey Key; public: struct Result {}; Result run(Module &, ModuleAnalysisManager &) { return Result(); } static StringRef name() { return "NoOpModuleAnalysis"; } }; /// No-op CGSCC pass which does nothing. struct NoOpCGSCCPass : PassInfoMixin { PreservedAnalyses run(LazyCallGraph::SCC &C, CGSCCAnalysisManager &, LazyCallGraph &, CGSCCUpdateResult &UR) { return PreservedAnalyses::all(); } static StringRef name() { return "NoOpCGSCCPass"; } }; /// No-op CGSCC analysis. class NoOpCGSCCAnalysis : public AnalysisInfoMixin { friend AnalysisInfoMixin; static AnalysisKey Key; public: struct Result {}; Result run(LazyCallGraph::SCC &, CGSCCAnalysisManager &, LazyCallGraph &G) { return Result(); } static StringRef name() { return "NoOpCGSCCAnalysis"; } }; /// No-op function pass which does nothing. struct NoOpFunctionPass : PassInfoMixin { PreservedAnalyses run(Function &F, FunctionAnalysisManager &) { return PreservedAnalyses::all(); } static StringRef name() { return "NoOpFunctionPass"; } }; /// No-op function analysis. class NoOpFunctionAnalysis : public AnalysisInfoMixin { friend AnalysisInfoMixin; static AnalysisKey Key; public: struct Result {}; Result run(Function &, FunctionAnalysisManager &) { return Result(); } static StringRef name() { return "NoOpFunctionAnalysis"; } }; /// No-op loop pass which does nothing. struct NoOpLoopPass : PassInfoMixin { PreservedAnalyses run(Loop &L, LoopAnalysisManager &, LoopStandardAnalysisResults &, LPMUpdater &) { return PreservedAnalyses::all(); } static StringRef name() { return "NoOpLoopPass"; } }; /// No-op loop analysis. class NoOpLoopAnalysis : public AnalysisInfoMixin { friend AnalysisInfoMixin; static AnalysisKey Key; public: struct Result {}; Result run(Loop &, LoopAnalysisManager &, LoopStandardAnalysisResults &) { return Result(); } static StringRef name() { return "NoOpLoopAnalysis"; } }; AnalysisKey NoOpModuleAnalysis::Key; AnalysisKey NoOpCGSCCAnalysis::Key; AnalysisKey NoOpFunctionAnalysis::Key; AnalysisKey NoOpLoopAnalysis::Key; /// Whether or not we should populate a PassInstrumentationCallbacks's class to /// pass name map. /// /// This is for optimization purposes so we don't populate it if we never use /// it. This should be updated if new pass instrumentation wants to use the map. /// We currently only use this for --print-before/after. bool shouldPopulateClassToPassNames() { return !printBeforePasses().empty() || !printAfterPasses().empty(); } } // namespace PassBuilder::PassBuilder(TargetMachine *TM, PipelineTuningOptions PTO, Optional PGOOpt, PassInstrumentationCallbacks *PIC) : TM(TM), PTO(PTO), PGOOpt(PGOOpt), PIC(PIC) { if (TM) TM->registerPassBuilderCallbacks(*this); if (PIC && shouldPopulateClassToPassNames()) { #define MODULE_PASS(NAME, CREATE_PASS) \ PIC->addClassToPassName(decltype(CREATE_PASS)::name(), NAME); #define MODULE_ANALYSIS(NAME, CREATE_PASS) \ PIC->addClassToPassName(decltype(CREATE_PASS)::name(), NAME); #define FUNCTION_PASS(NAME, CREATE_PASS) \ PIC->addClassToPassName(decltype(CREATE_PASS)::name(), NAME); #define FUNCTION_ANALYSIS(NAME, CREATE_PASS) \ PIC->addClassToPassName(decltype(CREATE_PASS)::name(), NAME); #define LOOP_PASS(NAME, CREATE_PASS) \ PIC->addClassToPassName(decltype(CREATE_PASS)::name(), NAME); #define LOOP_ANALYSIS(NAME, CREATE_PASS) \ PIC->addClassToPassName(decltype(CREATE_PASS)::name(), NAME); #define CGSCC_PASS(NAME, CREATE_PASS) \ PIC->addClassToPassName(decltype(CREATE_PASS)::name(), NAME); #define CGSCC_ANALYSIS(NAME, CREATE_PASS) \ PIC->addClassToPassName(decltype(CREATE_PASS)::name(), NAME); #include "PassRegistry.def" } } void PassBuilder::invokePeepholeEPCallbacks( FunctionPassManager &FPM, PassBuilder::OptimizationLevel Level) { for (auto &C : PeepholeEPCallbacks) C(FPM, Level); } void PassBuilder::registerModuleAnalyses(ModuleAnalysisManager &MAM) { #define MODULE_ANALYSIS(NAME, CREATE_PASS) \ MAM.registerPass([&] { return CREATE_PASS; }); #include "PassRegistry.def" for (auto &C : ModuleAnalysisRegistrationCallbacks) C(MAM); } void PassBuilder::registerCGSCCAnalyses(CGSCCAnalysisManager &CGAM) { #define CGSCC_ANALYSIS(NAME, CREATE_PASS) \ CGAM.registerPass([&] { return CREATE_PASS; }); #include "PassRegistry.def" for (auto &C : CGSCCAnalysisRegistrationCallbacks) C(CGAM); } void PassBuilder::registerFunctionAnalyses(FunctionAnalysisManager &FAM) { #define FUNCTION_ANALYSIS(NAME, CREATE_PASS) \ FAM.registerPass([&] { return CREATE_PASS; }); #include "PassRegistry.def" for (auto &C : FunctionAnalysisRegistrationCallbacks) C(FAM); } void PassBuilder::registerLoopAnalyses(LoopAnalysisManager &LAM) { #define LOOP_ANALYSIS(NAME, CREATE_PASS) \ LAM.registerPass([&] { return CREATE_PASS; }); #include "PassRegistry.def" for (auto &C : LoopAnalysisRegistrationCallbacks) C(LAM); } // Helper to add AnnotationRemarksPass. static void addAnnotationRemarksPass(ModulePassManager &MPM) { FunctionPassManager FPM; FPM.addPass(AnnotationRemarksPass()); MPM.addPass(createModuleToFunctionPassAdaptor(std::move(FPM))); } // Helper to check if the current compilation phase is preparing for LTO static bool isLTOPreLink(ThinOrFullLTOPhase Phase) { return Phase == ThinOrFullLTOPhase::ThinLTOPreLink || Phase == ThinOrFullLTOPhase::FullLTOPreLink; } // TODO: Investigate the cost/benefit of tail call elimination on debugging. FunctionPassManager PassBuilder::buildO1FunctionSimplificationPipeline(OptimizationLevel Level, ThinOrFullLTOPhase Phase) { FunctionPassManager FPM; // Form SSA out of local memory accesses after breaking apart aggregates into // scalars. FPM.addPass(SROA()); // Catch trivial redundancies FPM.addPass(EarlyCSEPass(true /* Enable mem-ssa. */)); // Hoisting of scalars and load expressions. FPM.addPass(SimplifyCFGPass()); FPM.addPass(InstCombinePass()); FPM.addPass(LibCallsShrinkWrapPass()); invokePeepholeEPCallbacks(FPM, Level); FPM.addPass(SimplifyCFGPass()); // Form canonically associated expression trees, and simplify the trees using // basic mathematical properties. For example, this will form (nearly) // minimal multiplication trees. FPM.addPass(ReassociatePass()); // Add the primary loop simplification pipeline. // FIXME: Currently this is split into two loop pass pipelines because we run // some function passes in between them. These can and should be removed // and/or replaced by scheduling the loop pass equivalents in the correct // positions. But those equivalent passes aren't powerful enough yet. // Specifically, `SimplifyCFGPass` and `InstCombinePass` are currently still // used. We have `LoopSimplifyCFGPass` which isn't yet powerful enough yet to // fully replace `SimplifyCFGPass`, and the closest to the other we have is // `LoopInstSimplify`. LoopPassManager LPM1, LPM2; // Simplify the loop body. We do this initially to clean up after other loop // passes run, either when iterating on a loop or on inner loops with // implications on the outer loop. LPM1.addPass(LoopInstSimplifyPass()); LPM1.addPass(LoopSimplifyCFGPass()); // Try to remove as much code from the loop header as possible, // to reduce amount of IR that will have to be duplicated. // TODO: Investigate promotion cap for O1. LPM1.addPass(LICMPass(PTO.LicmMssaOptCap, PTO.LicmMssaNoAccForPromotionCap)); LPM1.addPass(LoopRotatePass(/* Disable header duplication */ true, isLTOPreLink(Phase))); // TODO: Investigate promotion cap for O1. LPM1.addPass(LICMPass(PTO.LicmMssaOptCap, PTO.LicmMssaNoAccForPromotionCap)); LPM1.addPass(SimpleLoopUnswitchPass()); LPM2.addPass(LoopIdiomRecognizePass()); LPM2.addPass(IndVarSimplifyPass()); for (auto &C : LateLoopOptimizationsEPCallbacks) C(LPM2, Level); LPM2.addPass(LoopDeletionPass()); if (EnableLoopInterchange) LPM2.addPass(LoopInterchangePass()); // Do not enable unrolling in PreLinkThinLTO phase during sample PGO // because it changes IR to makes profile annotation in back compile // inaccurate. The normal unroller doesn't pay attention to forced full unroll // attributes so we need to make sure and allow the full unroll pass to pay // attention to it. if (Phase != ThinOrFullLTOPhase::ThinLTOPreLink || !PGOOpt || PGOOpt->Action != PGOOptions::SampleUse) LPM2.addPass(LoopFullUnrollPass(Level.getSpeedupLevel(), /* OnlyWhenForced= */ !PTO.LoopUnrolling, PTO.ForgetAllSCEVInLoopUnroll)); for (auto &C : LoopOptimizerEndEPCallbacks) C(LPM2, Level); // We provide the opt remark emitter pass for LICM to use. We only need to do // this once as it is immutable. FPM.addPass( RequireAnalysisPass()); FPM.addPass(createFunctionToLoopPassAdaptor(std::move(LPM1), EnableMSSALoopDependency, /*UseBlockFrequencyInfo=*/true)); FPM.addPass(SimplifyCFGPass()); FPM.addPass(InstCombinePass()); if (EnableLoopFlatten) FPM.addPass(LoopFlattenPass()); // The loop passes in LPM2 (LoopFullUnrollPass) do not preserve MemorySSA. // *All* loop passes must preserve it, in order to be able to use it. FPM.addPass(createFunctionToLoopPassAdaptor(std::move(LPM2), /*UseMemorySSA=*/false, /*UseBlockFrequencyInfo=*/false)); // Delete small array after loop unroll. FPM.addPass(SROA()); // Specially optimize memory movement as it doesn't look like dataflow in SSA. FPM.addPass(MemCpyOptPass()); // Sparse conditional constant propagation. // FIXME: It isn't clear why we do this *after* loop passes rather than // before... FPM.addPass(SCCPPass()); // Delete dead bit computations (instcombine runs after to fold away the dead // computations, and then ADCE will run later to exploit any new DCE // opportunities that creates). FPM.addPass(BDCEPass()); // Run instcombine after redundancy and dead bit elimination to exploit // opportunities opened up by them. FPM.addPass(InstCombinePass()); invokePeepholeEPCallbacks(FPM, Level); if (PTO.Coroutines) FPM.addPass(CoroElidePass()); for (auto &C : ScalarOptimizerLateEPCallbacks) C(FPM, Level); // Finally, do an expensive DCE pass to catch all the dead code exposed by // the simplifications and basic cleanup after all the simplifications. // TODO: Investigate if this is too expensive. FPM.addPass(ADCEPass()); FPM.addPass(SimplifyCFGPass()); FPM.addPass(InstCombinePass()); invokePeepholeEPCallbacks(FPM, Level); return FPM; } FunctionPassManager PassBuilder::buildFunctionSimplificationPipeline(OptimizationLevel Level, ThinOrFullLTOPhase Phase) { assert(Level != OptimizationLevel::O0 && "Must request optimizations!"); // The O1 pipeline has a separate pipeline creation function to simplify // construction readability. if (Level.getSpeedupLevel() == 1) return buildO1FunctionSimplificationPipeline(Level, Phase); FunctionPassManager FPM; // Form SSA out of local memory accesses after breaking apart aggregates into // scalars. FPM.addPass(SROA()); // Catch trivial redundancies FPM.addPass(EarlyCSEPass(true /* Enable mem-ssa. */)); if (EnableKnowledgeRetention) FPM.addPass(AssumeSimplifyPass()); // Hoisting of scalars and load expressions. if (EnableGVNHoist) FPM.addPass(GVNHoistPass()); // Global value numbering based sinking. if (EnableGVNSink) { FPM.addPass(GVNSinkPass()); FPM.addPass(SimplifyCFGPass()); } if (EnableConstraintElimination) FPM.addPass(ConstraintEliminationPass()); // Speculative execution if the target has divergent branches; otherwise nop. FPM.addPass(SpeculativeExecutionPass(/* OnlyIfDivergentTarget =*/true)); // Optimize based on known information about branches, and cleanup afterward. FPM.addPass(JumpThreadingPass()); FPM.addPass(CorrelatedValuePropagationPass()); FPM.addPass(SimplifyCFGPass()); if (Level == OptimizationLevel::O3) FPM.addPass(AggressiveInstCombinePass()); FPM.addPass(InstCombinePass()); if (!Level.isOptimizingForSize()) FPM.addPass(LibCallsShrinkWrapPass()); invokePeepholeEPCallbacks(FPM, Level); // For PGO use pipeline, try to optimize memory intrinsics such as memcpy // using the size value profile. Don't perform this when optimizing for size. if (PGOOpt && PGOOpt->Action == PGOOptions::IRUse && !Level.isOptimizingForSize()) FPM.addPass(PGOMemOPSizeOpt()); FPM.addPass(TailCallElimPass()); FPM.addPass(SimplifyCFGPass()); // Form canonically associated expression trees, and simplify the trees using // basic mathematical properties. For example, this will form (nearly) // minimal multiplication trees. FPM.addPass(ReassociatePass()); // Add the primary loop simplification pipeline. // FIXME: Currently this is split into two loop pass pipelines because we run // some function passes in between them. These can and should be removed // and/or replaced by scheduling the loop pass equivalents in the correct // positions. But those equivalent passes aren't powerful enough yet. // Specifically, `SimplifyCFGPass` and `InstCombinePass` are currently still // used. We have `LoopSimplifyCFGPass` which isn't yet powerful enough yet to // fully replace `SimplifyCFGPass`, and the closest to the other we have is // `LoopInstSimplify`. LoopPassManager LPM1, LPM2; // Simplify the loop body. We do this initially to clean up after other loop // passes run, either when iterating on a loop or on inner loops with // implications on the outer loop. LPM1.addPass(LoopInstSimplifyPass()); LPM1.addPass(LoopSimplifyCFGPass()); // Try to remove as much code from the loop header as possible, // to reduce amount of IR that will have to be duplicated. // TODO: Investigate promotion cap for O1. LPM1.addPass(LICMPass(PTO.LicmMssaOptCap, PTO.LicmMssaNoAccForPromotionCap)); // Disable header duplication in loop rotation at -Oz. LPM1.addPass( LoopRotatePass(Level != OptimizationLevel::Oz, isLTOPreLink(Phase))); // TODO: Investigate promotion cap for O1. LPM1.addPass(LICMPass(PTO.LicmMssaOptCap, PTO.LicmMssaNoAccForPromotionCap)); LPM1.addPass( SimpleLoopUnswitchPass(/* NonTrivial */ Level == OptimizationLevel::O3 && EnableO3NonTrivialUnswitching)); LPM2.addPass(LoopIdiomRecognizePass()); LPM2.addPass(IndVarSimplifyPass()); for (auto &C : LateLoopOptimizationsEPCallbacks) C(LPM2, Level); LPM2.addPass(LoopDeletionPass()); if (EnableLoopInterchange) LPM2.addPass(LoopInterchangePass()); // Do not enable unrolling in PreLinkThinLTO phase during sample PGO // because it changes IR to makes profile annotation in back compile // inaccurate. The normal unroller doesn't pay attention to forced full unroll // attributes so we need to make sure and allow the full unroll pass to pay // attention to it. if (Phase != ThinOrFullLTOPhase::ThinLTOPreLink || !PGOOpt || PGOOpt->Action != PGOOptions::SampleUse) LPM2.addPass(LoopFullUnrollPass(Level.getSpeedupLevel(), /* OnlyWhenForced= */ !PTO.LoopUnrolling, PTO.ForgetAllSCEVInLoopUnroll)); for (auto &C : LoopOptimizerEndEPCallbacks) C(LPM2, Level); // We provide the opt remark emitter pass for LICM to use. We only need to do // this once as it is immutable. FPM.addPass( RequireAnalysisPass()); FPM.addPass(createFunctionToLoopPassAdaptor(std::move(LPM1), EnableMSSALoopDependency, /*UseBlockFrequencyInfo=*/true)); FPM.addPass(SimplifyCFGPass()); FPM.addPass(InstCombinePass()); if (EnableLoopFlatten) FPM.addPass(LoopFlattenPass()); // The loop passes in LPM2 (LoopIdiomRecognizePass, IndVarSimplifyPass, // LoopDeletionPass and LoopFullUnrollPass) do not preserve MemorySSA. // *All* loop passes must preserve it, in order to be able to use it. FPM.addPass(createFunctionToLoopPassAdaptor(std::move(LPM2), /*UseMemorySSA=*/false, /*UseBlockFrequencyInfo=*/false)); // Delete small array after loop unroll. FPM.addPass(SROA()); // Eliminate redundancies. FPM.addPass(MergedLoadStoreMotionPass()); if (RunNewGVN) FPM.addPass(NewGVNPass()); else FPM.addPass(GVN()); // Sparse conditional constant propagation. // FIXME: It isn't clear why we do this *after* loop passes rather than // before... FPM.addPass(SCCPPass()); // Delete dead bit computations (instcombine runs after to fold away the dead // computations, and then ADCE will run later to exploit any new DCE // opportunities that creates). FPM.addPass(BDCEPass()); // Run instcombine after redundancy and dead bit elimination to exploit // opportunities opened up by them. FPM.addPass(InstCombinePass()); invokePeepholeEPCallbacks(FPM, Level); // Re-consider control flow based optimizations after redundancy elimination, // redo DCE, etc. FPM.addPass(JumpThreadingPass()); FPM.addPass(CorrelatedValuePropagationPass()); // Finally, do an expensive DCE pass to catch all the dead code exposed by // the simplifications and basic cleanup after all the simplifications. // TODO: Investigate if this is too expensive. FPM.addPass(ADCEPass()); // Specially optimize memory movement as it doesn't look like dataflow in SSA. FPM.addPass(MemCpyOptPass()); FPM.addPass(DSEPass()); FPM.addPass(createFunctionToLoopPassAdaptor( LICMPass(PTO.LicmMssaOptCap, PTO.LicmMssaNoAccForPromotionCap), EnableMSSALoopDependency, /*UseBlockFrequencyInfo=*/true)); if (PTO.Coroutines) FPM.addPass(CoroElidePass()); for (auto &C : ScalarOptimizerLateEPCallbacks) C(FPM, Level); FPM.addPass(SimplifyCFGPass( SimplifyCFGOptions().hoistCommonInsts(true).sinkCommonInsts(true))); FPM.addPass(InstCombinePass()); invokePeepholeEPCallbacks(FPM, Level); if (EnableCHR && Level == OptimizationLevel::O3 && PGOOpt && (PGOOpt->Action == PGOOptions::IRUse || PGOOpt->Action == PGOOptions::SampleUse)) FPM.addPass(ControlHeightReductionPass()); return FPM; } void PassBuilder::addRequiredLTOPreLinkPasses(ModulePassManager &MPM) { MPM.addPass(CanonicalizeAliasesPass()); MPM.addPass(NameAnonGlobalPass()); } void PassBuilder::addPGOInstrPasses(ModulePassManager &MPM, PassBuilder::OptimizationLevel Level, bool RunProfileGen, bool IsCS, std::string ProfileFile, std::string ProfileRemappingFile) { assert(Level != OptimizationLevel::O0 && "Not expecting O0 here!"); if (!IsCS && !DisablePreInliner) { InlineParams IP; IP.DefaultThreshold = PreInlineThreshold; // FIXME: The hint threshold has the same value used by the regular inliner // when not optimzing for size. This should probably be lowered after // performance testing. // FIXME: this comment is cargo culted from the old pass manager, revisit). IP.HintThreshold = Level.isOptimizingForSize() ? PreInlineThreshold : 325; ModuleInlinerWrapperPass MIWP(IP); CGSCCPassManager &CGPipeline = MIWP.getPM(); FunctionPassManager FPM; FPM.addPass(SROA()); FPM.addPass(EarlyCSEPass()); // Catch trivial redundancies. FPM.addPass(SimplifyCFGPass()); // Merge & remove basic blocks. FPM.addPass(InstCombinePass()); // Combine silly sequences. invokePeepholeEPCallbacks(FPM, Level); CGPipeline.addPass(createCGSCCToFunctionPassAdaptor(std::move(FPM))); MPM.addPass(std::move(MIWP)); // Delete anything that is now dead to make sure that we don't instrument // dead code. Instrumentation can end up keeping dead code around and // dramatically increase code size. MPM.addPass(GlobalDCEPass()); } if (!RunProfileGen) { assert(!ProfileFile.empty() && "Profile use expecting a profile file!"); MPM.addPass(PGOInstrumentationUse(ProfileFile, ProfileRemappingFile, IsCS)); // Cache ProfileSummaryAnalysis once to avoid the potential need to insert // RequireAnalysisPass for PSI before subsequent non-module passes. MPM.addPass(RequireAnalysisPass()); return; } // Perform PGO instrumentation. MPM.addPass(PGOInstrumentationGen(IsCS)); FunctionPassManager FPM; // Disable header duplication in loop rotation at -Oz. FPM.addPass(createFunctionToLoopPassAdaptor( LoopRotatePass(Level != OptimizationLevel::Oz), EnableMSSALoopDependency, /*UseBlockFrequencyInfo=*/false)); MPM.addPass(createModuleToFunctionPassAdaptor(std::move(FPM))); // Add the profile lowering pass. InstrProfOptions Options; if (!ProfileFile.empty()) Options.InstrProfileOutput = ProfileFile; // Do counter promotion at Level greater than O0. Options.DoCounterPromotion = true; Options.UseBFIInPromotion = IsCS; MPM.addPass(InstrProfiling(Options, IsCS)); } void PassBuilder::addPGOInstrPassesForO0(ModulePassManager &MPM, bool RunProfileGen, bool IsCS, std::string ProfileFile, std::string ProfileRemappingFile) { if (!RunProfileGen) { assert(!ProfileFile.empty() && "Profile use expecting a profile file!"); MPM.addPass(PGOInstrumentationUse(ProfileFile, ProfileRemappingFile, IsCS)); // Cache ProfileSummaryAnalysis once to avoid the potential need to insert // RequireAnalysisPass for PSI before subsequent non-module passes. MPM.addPass(RequireAnalysisPass()); return; } // Perform PGO instrumentation. MPM.addPass(PGOInstrumentationGen(IsCS)); // Add the profile lowering pass. InstrProfOptions Options; if (!ProfileFile.empty()) Options.InstrProfileOutput = ProfileFile; // Do not do counter promotion at O0. Options.DoCounterPromotion = false; Options.UseBFIInPromotion = IsCS; MPM.addPass(InstrProfiling(Options, IsCS)); } static InlineParams getInlineParamsFromOptLevel(PassBuilder::OptimizationLevel Level) { return getInlineParams(Level.getSpeedupLevel(), Level.getSizeLevel()); } ModuleInlinerWrapperPass PassBuilder::buildInlinerPipeline(OptimizationLevel Level, ThinOrFullLTOPhase Phase) { InlineParams IP = getInlineParamsFromOptLevel(Level); if (Phase == ThinOrFullLTOPhase::ThinLTOPreLink && PGOOpt && PGOOpt->Action == PGOOptions::SampleUse) IP.HotCallSiteThreshold = 0; if (PGOOpt) IP.EnableDeferral = EnablePGOInlineDeferral; ModuleInlinerWrapperPass MIWP(IP, PerformMandatoryInliningsFirst, UseInlineAdvisor, MaxDevirtIterations); // Require the GlobalsAA analysis for the module so we can query it within // the CGSCC pipeline. MIWP.addModulePass(RequireAnalysisPass()); // Invalidate AAManager so it can be recreated and pick up the newly available // GlobalsAA. MIWP.addModulePass( createModuleToFunctionPassAdaptor(InvalidateAnalysisPass())); // Require the ProfileSummaryAnalysis for the module so we can query it within // the inliner pass. MIWP.addModulePass(RequireAnalysisPass()); // Now begin the main postorder CGSCC pipeline. // FIXME: The current CGSCC pipeline has its origins in the legacy pass // manager and trying to emulate its precise behavior. Much of this doesn't // make a lot of sense and we should revisit the core CGSCC structure. CGSCCPassManager &MainCGPipeline = MIWP.getPM(); // Note: historically, the PruneEH pass was run first to deduce nounwind and // generally clean up exception handling overhead. It isn't clear this is // valuable as the inliner doesn't currently care whether it is inlining an // invoke or a call. if (AttributorRun & AttributorRunOption::CGSCC) MainCGPipeline.addPass(AttributorCGSCCPass()); if (PTO.Coroutines) MainCGPipeline.addPass(CoroSplitPass(Level != OptimizationLevel::O0)); // Now deduce any function attributes based in the current code. MainCGPipeline.addPass(PostOrderFunctionAttrsPass()); // When at O3 add argument promotion to the pass pipeline. // FIXME: It isn't at all clear why this should be limited to O3. if (Level == OptimizationLevel::O3) MainCGPipeline.addPass(ArgumentPromotionPass()); // Try to perform OpenMP specific optimizations. This is a (quick!) no-op if // there are no OpenMP runtime calls present in the module. if (Level == OptimizationLevel::O2 || Level == OptimizationLevel::O3) MainCGPipeline.addPass(OpenMPOptCGSCCPass()); for (auto &C : CGSCCOptimizerLateEPCallbacks) C(MainCGPipeline, Level); // Lastly, add the core function simplification pipeline nested inside the // CGSCC walk. auto FSP = buildFunctionSimplificationPipeline(Level, Phase); if (DoNotRerunFunctionPasses) FSP.addPass(RequireAnalysisPass()); MainCGPipeline.addPass(createCGSCCToFunctionPassAdaptor(std::move(FSP))); return MIWP; } ModulePassManager PassBuilder::buildModuleSimplificationPipeline(OptimizationLevel Level, ThinOrFullLTOPhase Phase) { ModulePassManager MPM; // Place pseudo probe instrumentation as the first pass of the pipeline to // minimize the impact of optimization changes. if (PGOOpt && PGOOpt->PseudoProbeForProfiling && Phase != ThinOrFullLTOPhase::ThinLTOPostLink) MPM.addPass(SampleProfileProbePass(TM)); bool HasSampleProfile = PGOOpt && (PGOOpt->Action == PGOOptions::SampleUse); // In ThinLTO mode, when flattened profile is used, all the available // profile information will be annotated in PreLink phase so there is // no need to load the profile again in PostLink. bool LoadSampleProfile = HasSampleProfile && !(FlattenedProfileUsed && Phase == ThinOrFullLTOPhase::ThinLTOPostLink); // During the ThinLTO backend phase we perform early indirect call promotion // here, before globalopt. Otherwise imported available_externally functions // look unreferenced and are removed. If we are going to load the sample // profile then defer until later. // TODO: See if we can move later and consolidate with the location where // we perform ICP when we are loading a sample profile. // TODO: We pass HasSampleProfile (whether there was a sample profile file // passed to the compile) to the SamplePGO flag of ICP. This is used to // determine whether the new direct calls are annotated with prof metadata. // Ideally this should be determined from whether the IR is annotated with // sample profile, and not whether the a sample profile was provided on the // command line. E.g. for flattened profiles where we will not be reloading // the sample profile in the ThinLTO backend, we ideally shouldn't have to // provide the sample profile file. if (Phase == ThinOrFullLTOPhase::ThinLTOPostLink && !LoadSampleProfile) MPM.addPass(PGOIndirectCallPromotion(true /* InLTO */, HasSampleProfile)); // Do basic inference of function attributes from known properties of system // libraries and other oracles. MPM.addPass(InferFunctionAttrsPass()); // Create an early function pass manager to cleanup the output of the // frontend. FunctionPassManager EarlyFPM; // Lower llvm.expect to metadata before attempting transforms. // Compare/branch metadata may alter the behavior of passes like SimplifyCFG. EarlyFPM.addPass(LowerExpectIntrinsicPass()); EarlyFPM.addPass(SimplifyCFGPass()); EarlyFPM.addPass(SROA()); EarlyFPM.addPass(EarlyCSEPass()); if (PTO.Coroutines) EarlyFPM.addPass(CoroEarlyPass()); if (Level == OptimizationLevel::O3) EarlyFPM.addPass(CallSiteSplittingPass()); // In SamplePGO ThinLTO backend, we need instcombine before profile annotation // to convert bitcast to direct calls so that they can be inlined during the // profile annotation prepration step. // More details about SamplePGO design can be found in: // https://research.google.com/pubs/pub45290.html // FIXME: revisit how SampleProfileLoad/Inliner/ICP is structured. if (LoadSampleProfile) EarlyFPM.addPass(InstCombinePass()); MPM.addPass(createModuleToFunctionPassAdaptor(std::move(EarlyFPM))); if (LoadSampleProfile) { // Annotate sample profile right after early FPM to ensure freshness of // the debug info. MPM.addPass(SampleProfileLoaderPass(PGOOpt->ProfileFile, PGOOpt->ProfileRemappingFile, Phase)); // Cache ProfileSummaryAnalysis once to avoid the potential need to insert // RequireAnalysisPass for PSI before subsequent non-module passes. MPM.addPass(RequireAnalysisPass()); // Do not invoke ICP in the LTOPrelink phase as it makes it hard // for the profile annotation to be accurate in the LTO backend. if (Phase != ThinOrFullLTOPhase::ThinLTOPreLink && Phase != ThinOrFullLTOPhase::FullLTOPreLink) // We perform early indirect call promotion here, before globalopt. // This is important for the ThinLTO backend phase because otherwise // imported available_externally functions look unreferenced and are // removed. MPM.addPass( PGOIndirectCallPromotion(true /* IsInLTO */, true /* SamplePGO */)); } // Try to perform OpenMP specific optimizations on the module. This is a // (quick!) no-op if there are no OpenMP runtime calls present in the module. if (Level == OptimizationLevel::O2 || Level == OptimizationLevel::O3) MPM.addPass(OpenMPOptPass()); if (AttributorRun & AttributorRunOption::MODULE) MPM.addPass(AttributorPass()); // Lower type metadata and the type.test intrinsic in the ThinLTO // post link pipeline after ICP. This is to enable usage of the type // tests in ICP sequences. if (Phase == ThinOrFullLTOPhase::ThinLTOPostLink) MPM.addPass(LowerTypeTestsPass(nullptr, nullptr, true)); for (auto &C : PipelineEarlySimplificationEPCallbacks) C(MPM, Level); // Interprocedural constant propagation now that basic cleanup has occurred // and prior to optimizing globals. // FIXME: This position in the pipeline hasn't been carefully considered in // years, it should be re-analyzed. MPM.addPass(IPSCCPPass()); // Attach metadata to indirect call sites indicating the set of functions // they may target at run-time. This should follow IPSCCP. MPM.addPass(CalledValuePropagationPass()); // Optimize globals to try and fold them into constants. MPM.addPass(GlobalOptPass()); // Promote any localized globals to SSA registers. // FIXME: Should this instead by a run of SROA? // FIXME: We should probably run instcombine and simplify-cfg afterward to // delete control flows that are dead once globals have been folded to // constants. MPM.addPass(createModuleToFunctionPassAdaptor(PromotePass())); // Remove any dead arguments exposed by cleanups and constant folding // globals. MPM.addPass(DeadArgumentEliminationPass()); // Create a small function pass pipeline to cleanup after all the global // optimizations. FunctionPassManager GlobalCleanupPM; GlobalCleanupPM.addPass(InstCombinePass()); invokePeepholeEPCallbacks(GlobalCleanupPM, Level); GlobalCleanupPM.addPass(SimplifyCFGPass()); MPM.addPass(createModuleToFunctionPassAdaptor(std::move(GlobalCleanupPM))); // Add all the requested passes for instrumentation PGO, if requested. if (PGOOpt && Phase != ThinOrFullLTOPhase::ThinLTOPostLink && (PGOOpt->Action == PGOOptions::IRInstr || PGOOpt->Action == PGOOptions::IRUse)) { addPGOInstrPasses(MPM, Level, /* RunProfileGen */ PGOOpt->Action == PGOOptions::IRInstr, /* IsCS */ false, PGOOpt->ProfileFile, PGOOpt->ProfileRemappingFile); MPM.addPass(PGOIndirectCallPromotion(false, false)); } if (PGOOpt && Phase != ThinOrFullLTOPhase::ThinLTOPostLink && PGOOpt->CSAction == PGOOptions::CSIRInstr) MPM.addPass(PGOInstrumentationGenCreateVar(PGOOpt->CSProfileGenFile)); // Synthesize function entry counts for non-PGO compilation. if (EnableSyntheticCounts && !PGOOpt) MPM.addPass(SyntheticCountsPropagation()); MPM.addPass(buildInlinerPipeline(Level, Phase)); if (DoNotRerunFunctionPasses) MPM.addPass(createModuleToFunctionPassAdaptor( InvalidateAnalysisPass())); if (EnableMemProfiler && Phase != ThinOrFullLTOPhase::ThinLTOPreLink) { MPM.addPass(createModuleToFunctionPassAdaptor(MemProfilerPass())); MPM.addPass(ModuleMemProfilerPass()); } return MPM; } /// TODO: Should LTO cause any differences to this set of passes? void PassBuilder::addVectorPasses(OptimizationLevel Level, FunctionPassManager &FPM, bool IsLTO) { FPM.addPass(LoopVectorizePass( LoopVectorizeOptions(!PTO.LoopInterleaving, !PTO.LoopVectorization))); if (IsLTO) { // The vectorizer may have significantly shortened a loop body; unroll // again. Unroll small loops to hide loop backedge latency and saturate any // parallel execution resources of an out-of-order processor. We also then // need to clean up redundancies and loop invariant code. // FIXME: It would be really good to use a loop-integrated instruction // combiner for cleanup here so that the unrolling and LICM can be pipelined // across the loop nests. // We do UnrollAndJam in a separate LPM to ensure it happens before unroll if (EnableUnrollAndJam && PTO.LoopUnrolling) FPM.addPass(createFunctionToLoopPassAdaptor( LoopUnrollAndJamPass(Level.getSpeedupLevel()))); FPM.addPass(LoopUnrollPass(LoopUnrollOptions( Level.getSpeedupLevel(), /*OnlyWhenForced=*/!PTO.LoopUnrolling, PTO.ForgetAllSCEVInLoopUnroll))); FPM.addPass(WarnMissedTransformationsPass()); } if (!IsLTO) { // Eliminate loads by forwarding stores from the previous iteration to loads // of the current iteration. FPM.addPass(LoopLoadEliminationPass()); } // Cleanup after the loop optimization passes. FPM.addPass(InstCombinePass()); if (Level.getSpeedupLevel() > 1 && ExtraVectorizerPasses) { // At higher optimization levels, try to clean up any runtime overlap and // alignment checks inserted by the vectorizer. We want to track correlated // runtime checks for two inner loops in the same outer loop, fold any // common computations, hoist loop-invariant aspects out of any outer loop, // and unswitch the runtime checks if possible. Once hoisted, we may have // dead (or speculatable) control flows or more combining opportunities. FPM.addPass(EarlyCSEPass()); FPM.addPass(CorrelatedValuePropagationPass()); FPM.addPass(InstCombinePass()); LoopPassManager LPM; LPM.addPass(LICMPass(PTO.LicmMssaOptCap, PTO.LicmMssaNoAccForPromotionCap)); LPM.addPass(SimpleLoopUnswitchPass(/* NonTrivial */ Level == OptimizationLevel::O3)); FPM.addPass( RequireAnalysisPass()); FPM.addPass(createFunctionToLoopPassAdaptor( std::move(LPM), EnableMSSALoopDependency, /*UseBlockFrequencyInfo=*/true)); FPM.addPass(SimplifyCFGPass()); FPM.addPass(InstCombinePass()); } if (IsLTO) { FPM.addPass(SimplifyCFGPass(SimplifyCFGOptions().hoistCommonInsts(true))); } else { // Now that we've formed fast to execute loop structures, we do further // optimizations. These are run afterward as they might block doing complex // analyses and transforms such as what are needed for loop vectorization. // Cleanup after loop vectorization, etc. Simplification passes like CVP and // GVN, loop transforms, and others have already run, so it's now better to // convert to more optimized IR using more aggressive simplify CFG options. // The extra sinking transform can create larger basic blocks, so do this // before SLP vectorization. FPM.addPass(SimplifyCFGPass(SimplifyCFGOptions() .forwardSwitchCondToPhi(true) .convertSwitchToLookupTable(true) .needCanonicalLoops(false) .hoistCommonInsts(true) .sinkCommonInsts(true))); } if (IsLTO) { FPM.addPass(SCCPPass()); FPM.addPass(InstCombinePass()); FPM.addPass(BDCEPass()); } // Optimize parallel scalar instruction chains into SIMD instructions. if (PTO.SLPVectorization) { FPM.addPass(SLPVectorizerPass()); if (Level.getSpeedupLevel() > 1 && ExtraVectorizerPasses) { FPM.addPass(EarlyCSEPass()); } } // Enhance/cleanup vector code. FPM.addPass(VectorCombinePass()); if (!IsLTO) { FPM.addPass(InstCombinePass()); // Unroll small loops to hide loop backedge latency and saturate any // parallel execution resources of an out-of-order processor. We also then // need to clean up redundancies and loop invariant code. // FIXME: It would be really good to use a loop-integrated instruction // combiner for cleanup here so that the unrolling and LICM can be pipelined // across the loop nests. // We do UnrollAndJam in a separate LPM to ensure it happens before unroll if (EnableUnrollAndJam && PTO.LoopUnrolling) { FPM.addPass(createFunctionToLoopPassAdaptor( LoopUnrollAndJamPass(Level.getSpeedupLevel()))); } FPM.addPass(LoopUnrollPass(LoopUnrollOptions( Level.getSpeedupLevel(), /*OnlyWhenForced=*/!PTO.LoopUnrolling, PTO.ForgetAllSCEVInLoopUnroll))); FPM.addPass(WarnMissedTransformationsPass()); FPM.addPass(InstCombinePass()); FPM.addPass( RequireAnalysisPass()); FPM.addPass(createFunctionToLoopPassAdaptor( LICMPass(PTO.LicmMssaOptCap, PTO.LicmMssaNoAccForPromotionCap), EnableMSSALoopDependency, /*UseBlockFrequencyInfo=*/true)); } // Now that we've vectorized and unrolled loops, we may have more refined // alignment information, try to re-derive it here. FPM.addPass(AlignmentFromAssumptionsPass()); if (IsLTO) FPM.addPass(InstCombinePass()); } ModulePassManager PassBuilder::buildModuleOptimizationPipeline(OptimizationLevel Level, bool LTOPreLink) { ModulePassManager MPM; // Optimize globals now that the module is fully simplified. MPM.addPass(GlobalOptPass()); MPM.addPass(GlobalDCEPass()); // Run partial inlining pass to partially inline functions that have // large bodies. if (RunPartialInlining) MPM.addPass(PartialInlinerPass()); // Remove avail extern fns and globals definitions since we aren't compiling // an object file for later LTO. For LTO we want to preserve these so they // are eligible for inlining at link-time. Note if they are unreferenced they // will be removed by GlobalDCE later, so this only impacts referenced // available externally globals. Eventually they will be suppressed during // codegen, but eliminating here enables more opportunity for GlobalDCE as it // may make globals referenced by available external functions dead and saves // running remaining passes on the eliminated functions. These should be // preserved during prelinking for link-time inlining decisions. if (!LTOPreLink) MPM.addPass(EliminateAvailableExternallyPass()); if (EnableOrderFileInstrumentation) MPM.addPass(InstrOrderFilePass()); // Do RPO function attribute inference across the module to forward-propagate // attributes where applicable. // FIXME: Is this really an optimization rather than a canonicalization? MPM.addPass(ReversePostOrderFunctionAttrsPass()); // Do a post inline PGO instrumentation and use pass. This is a context // sensitive PGO pass. We don't want to do this in LTOPreLink phrase as // cross-module inline has not been done yet. The context sensitive // instrumentation is after all the inlines are done. if (!LTOPreLink && PGOOpt) { if (PGOOpt->CSAction == PGOOptions::CSIRInstr) addPGOInstrPasses(MPM, Level, /* RunProfileGen */ true, /* IsCS */ true, PGOOpt->CSProfileGenFile, PGOOpt->ProfileRemappingFile); else if (PGOOpt->CSAction == PGOOptions::CSIRUse) addPGOInstrPasses(MPM, Level, /* RunProfileGen */ false, /* IsCS */ true, PGOOpt->ProfileFile, PGOOpt->ProfileRemappingFile); } // Re-require GloblasAA here prior to function passes. This is particularly // useful as the above will have inlined, DCE'ed, and function-attr // propagated everything. We should at this point have a reasonably minimal // and richly annotated call graph. By computing aliasing and mod/ref // information for all local globals here, the late loop passes and notably // the vectorizer will be able to use them to help recognize vectorizable // memory operations. MPM.addPass(RequireAnalysisPass()); FunctionPassManager OptimizePM; OptimizePM.addPass(Float2IntPass()); OptimizePM.addPass(LowerConstantIntrinsicsPass()); if (EnableMatrix) { OptimizePM.addPass(LowerMatrixIntrinsicsPass()); OptimizePM.addPass(EarlyCSEPass()); } // FIXME: We need to run some loop optimizations to re-rotate loops after // simplify-cfg and others undo their rotation. // Optimize the loop execution. These passes operate on entire loop nests // rather than on each loop in an inside-out manner, and so they are actually // function passes. for (auto &C : VectorizerStartEPCallbacks) C(OptimizePM, Level); // First rotate loops that may have been un-rotated by prior passes. // Disable header duplication at -Oz. OptimizePM.addPass(createFunctionToLoopPassAdaptor( LoopRotatePass(Level != OptimizationLevel::Oz, LTOPreLink), EnableMSSALoopDependency, /*UseBlockFrequencyInfo=*/false)); // Distribute loops to allow partial vectorization. I.e. isolate dependences // into separate loop that would otherwise inhibit vectorization. This is // currently only performed for loops marked with the metadata // llvm.loop.distribute=true or when -enable-loop-distribute is specified. OptimizePM.addPass(LoopDistributePass()); // Populates the VFABI attribute with the scalar-to-vector mappings // from the TargetLibraryInfo. OptimizePM.addPass(InjectTLIMappings()); addVectorPasses(Level, OptimizePM, /* IsLTO */ false); // Split out cold code. Splitting is done late to avoid hiding context from // other optimizations and inadvertently regressing performance. The tradeoff // is that this has a higher code size cost than splitting early. if (EnableHotColdSplit && !LTOPreLink) MPM.addPass(HotColdSplittingPass()); // Search the code for similar regions of code. If enough similar regions can // be found where extracting the regions into their own function will decrease // the size of the program, we extract the regions, a deduplicate the // structurally similar regions. if (EnableIROutliner) MPM.addPass(IROutlinerPass()); // Merge functions if requested. if (PTO.MergeFunctions) MPM.addPass(MergeFunctionsPass()); // LoopSink pass sinks instructions hoisted by LICM, which serves as a // canonicalization pass that enables other optimizations. As a result, // LoopSink pass needs to be a very late IR pass to avoid undoing LICM // result too early. OptimizePM.addPass(LoopSinkPass()); // And finally clean up LCSSA form before generating code. OptimizePM.addPass(InstSimplifyPass()); // This hoists/decomposes div/rem ops. It should run after other sink/hoist // passes to avoid re-sinking, but before SimplifyCFG because it can allow // flattening of blocks. OptimizePM.addPass(DivRemPairsPass()); // LoopSink (and other loop passes since the last simplifyCFG) might have // resulted in single-entry-single-exit or empty blocks. Clean up the CFG. OptimizePM.addPass(SimplifyCFGPass()); // Optimize PHIs by speculating around them when profitable. Note that this // pass needs to be run after any PRE or similar pass as it is essentially // inserting redundancies into the program. This even includes SimplifyCFG. OptimizePM.addPass(SpeculateAroundPHIsPass()); if (PTO.Coroutines) OptimizePM.addPass(CoroCleanupPass()); // Add the core optimizing pipeline. MPM.addPass(createModuleToFunctionPassAdaptor(std::move(OptimizePM))); for (auto &C : OptimizerLastEPCallbacks) C(MPM, Level); if (PTO.CallGraphProfile) MPM.addPass(CGProfilePass()); // Now we need to do some global optimization transforms. // FIXME: It would seem like these should come first in the optimization // pipeline and maybe be the bottom of the canonicalization pipeline? Weird // ordering here. MPM.addPass(GlobalDCEPass()); MPM.addPass(ConstantMergePass()); // TODO: Relative look table converter pass caused an issue when full lto is // enabled. See https://reviews.llvm.org/D94355 for more details. // Until the issue fixed, disable this pass during pre-linking phase. if (!LTOPreLink) MPM.addPass(RelLookupTableConverterPass()); return MPM; } ModulePassManager PassBuilder::buildPerModuleDefaultPipeline(OptimizationLevel Level, bool LTOPreLink) { assert(Level != OptimizationLevel::O0 && "Must request optimizations for the default pipeline!"); ModulePassManager MPM; // Convert @llvm.global.annotations to !annotation metadata. MPM.addPass(Annotation2MetadataPass()); // Force any function attributes we want the rest of the pipeline to observe. MPM.addPass(ForceFunctionAttrsPass()); // Apply module pipeline start EP callback. for (auto &C : PipelineStartEPCallbacks) C(MPM, Level); if (PGOOpt && PGOOpt->DebugInfoForProfiling) MPM.addPass(createModuleToFunctionPassAdaptor(AddDiscriminatorsPass())); // Add the core simplification pipeline. MPM.addPass(buildModuleSimplificationPipeline( Level, LTOPreLink ? ThinOrFullLTOPhase::FullLTOPreLink : ThinOrFullLTOPhase::None)); // Now add the optimization pipeline. MPM.addPass(buildModuleOptimizationPipeline(Level, LTOPreLink)); if (PGOOpt && PGOOpt->PseudoProbeForProfiling) MPM.addPass(PseudoProbeUpdatePass()); // Emit annotation remarks. addAnnotationRemarksPass(MPM); if (LTOPreLink) addRequiredLTOPreLinkPasses(MPM); return MPM; } ModulePassManager PassBuilder::buildThinLTOPreLinkDefaultPipeline(OptimizationLevel Level) { assert(Level != OptimizationLevel::O0 && "Must request optimizations for the default pipeline!"); ModulePassManager MPM; // Convert @llvm.global.annotations to !annotation metadata. MPM.addPass(Annotation2MetadataPass()); // Force any function attributes we want the rest of the pipeline to observe. MPM.addPass(ForceFunctionAttrsPass()); if (PGOOpt && PGOOpt->DebugInfoForProfiling) MPM.addPass(createModuleToFunctionPassAdaptor(AddDiscriminatorsPass())); // Apply module pipeline start EP callback. for (auto &C : PipelineStartEPCallbacks) C(MPM, Level); // If we are planning to perform ThinLTO later, we don't bloat the code with // unrolling/vectorization/... now. Just simplify the module as much as we // can. MPM.addPass(buildModuleSimplificationPipeline( Level, ThinOrFullLTOPhase::ThinLTOPreLink)); // Run partial inlining pass to partially inline functions that have // large bodies. // FIXME: It isn't clear whether this is really the right place to run this // in ThinLTO. Because there is another canonicalization and simplification // phase that will run after the thin link, running this here ends up with // less information than will be available later and it may grow functions in // ways that aren't beneficial. if (RunPartialInlining) MPM.addPass(PartialInlinerPass()); // Reduce the size of the IR as much as possible. MPM.addPass(GlobalOptPass()); // Module simplification splits coroutines, but does not fully clean up // coroutine intrinsics. To ensure ThinLTO optimization passes don't trip up // on these, we schedule the cleanup here. if (PTO.Coroutines) MPM.addPass(createModuleToFunctionPassAdaptor(CoroCleanupPass())); if (PGOOpt && PGOOpt->PseudoProbeForProfiling) MPM.addPass(PseudoProbeUpdatePass()); // Handle OptimizerLastEPCallbacks added by clang on PreLink. Actual // optimization is going to be done in PostLink stage, but clang can't // add callbacks there in case of in-process ThinLTO called by linker. for (auto &C : OptimizerLastEPCallbacks) C(MPM, Level); // Emit annotation remarks. addAnnotationRemarksPass(MPM); addRequiredLTOPreLinkPasses(MPM); return MPM; } ModulePassManager PassBuilder::buildThinLTODefaultPipeline( OptimizationLevel Level, const ModuleSummaryIndex *ImportSummary) { ModulePassManager MPM; // Convert @llvm.global.annotations to !annotation metadata. MPM.addPass(Annotation2MetadataPass()); if (ImportSummary) { // These passes import type identifier resolutions for whole-program // devirtualization and CFI. They must run early because other passes may // disturb the specific instruction patterns that these passes look for, // creating dependencies on resolutions that may not appear in the summary. // // For example, GVN may transform the pattern assume(type.test) appearing in // two basic blocks into assume(phi(type.test, type.test)), which would // transform a dependency on a WPD resolution into a dependency on a type // identifier resolution for CFI. // // Also, WPD has access to more precise information than ICP and can // devirtualize more effectively, so it should operate on the IR first. // // The WPD and LowerTypeTest passes need to run at -O0 to lower type // metadata and intrinsics. MPM.addPass(WholeProgramDevirtPass(nullptr, ImportSummary)); MPM.addPass(LowerTypeTestsPass(nullptr, ImportSummary)); } if (Level == OptimizationLevel::O0) { // Run a second time to clean up any type tests left behind by WPD for use // in ICP. MPM.addPass(LowerTypeTestsPass(nullptr, nullptr, true)); // Drop available_externally and unreferenced globals. This is necessary // with ThinLTO in order to avoid leaving undefined references to dead // globals in the object file. MPM.addPass(EliminateAvailableExternallyPass()); MPM.addPass(GlobalDCEPass()); return MPM; } // Force any function attributes we want the rest of the pipeline to observe. MPM.addPass(ForceFunctionAttrsPass()); // Add the core simplification pipeline. MPM.addPass(buildModuleSimplificationPipeline( Level, ThinOrFullLTOPhase::ThinLTOPostLink)); // Now add the optimization pipeline. MPM.addPass(buildModuleOptimizationPipeline(Level)); // Emit annotation remarks. addAnnotationRemarksPass(MPM); return MPM; } ModulePassManager PassBuilder::buildLTOPreLinkDefaultPipeline(OptimizationLevel Level) { assert(Level != OptimizationLevel::O0 && "Must request optimizations for the default pipeline!"); // FIXME: We should use a customized pre-link pipeline! return buildPerModuleDefaultPipeline(Level, /* LTOPreLink */ true); } ModulePassManager PassBuilder::buildLTODefaultPipeline(OptimizationLevel Level, ModuleSummaryIndex *ExportSummary) { ModulePassManager MPM; // Convert @llvm.global.annotations to !annotation metadata. MPM.addPass(Annotation2MetadataPass()); if (Level == OptimizationLevel::O0) { // The WPD and LowerTypeTest passes need to run at -O0 to lower type // metadata and intrinsics. MPM.addPass(WholeProgramDevirtPass(ExportSummary, nullptr)); MPM.addPass(LowerTypeTestsPass(ExportSummary, nullptr)); // Run a second time to clean up any type tests left behind by WPD for use // in ICP. MPM.addPass(LowerTypeTestsPass(nullptr, nullptr, true)); // Emit annotation remarks. addAnnotationRemarksPass(MPM); return MPM; } if (PGOOpt && PGOOpt->Action == PGOOptions::SampleUse) { // Load sample profile before running the LTO optimization pipeline. MPM.addPass(SampleProfileLoaderPass(PGOOpt->ProfileFile, PGOOpt->ProfileRemappingFile, ThinOrFullLTOPhase::FullLTOPostLink)); // Cache ProfileSummaryAnalysis once to avoid the potential need to insert // RequireAnalysisPass for PSI before subsequent non-module passes. MPM.addPass(RequireAnalysisPass()); } // Remove unused virtual tables to improve the quality of code generated by // whole-program devirtualization and bitset lowering. MPM.addPass(GlobalDCEPass()); // Force any function attributes we want the rest of the pipeline to observe. MPM.addPass(ForceFunctionAttrsPass()); // Do basic inference of function attributes from known properties of system // libraries and other oracles. MPM.addPass(InferFunctionAttrsPass()); if (Level.getSpeedupLevel() > 1) { FunctionPassManager EarlyFPM; EarlyFPM.addPass(CallSiteSplittingPass()); MPM.addPass(createModuleToFunctionPassAdaptor(std::move(EarlyFPM))); // Indirect call promotion. This should promote all the targets that are // left by the earlier promotion pass that promotes intra-module targets. // This two-step promotion is to save the compile time. For LTO, it should // produce the same result as if we only do promotion here. MPM.addPass(PGOIndirectCallPromotion( true /* InLTO */, PGOOpt && PGOOpt->Action == PGOOptions::SampleUse)); // Propagate constants at call sites into the functions they call. This // opens opportunities for globalopt (and inlining) by substituting function // pointers passed as arguments to direct uses of functions. MPM.addPass(IPSCCPPass()); // Attach metadata to indirect call sites indicating the set of functions // they may target at run-time. This should follow IPSCCP. MPM.addPass(CalledValuePropagationPass()); } // Now deduce any function attributes based in the current code. MPM.addPass(createModuleToPostOrderCGSCCPassAdaptor( PostOrderFunctionAttrsPass())); // Do RPO function attribute inference across the module to forward-propagate // attributes where applicable. // FIXME: Is this really an optimization rather than a canonicalization? MPM.addPass(ReversePostOrderFunctionAttrsPass()); // Use in-range annotations on GEP indices to split globals where beneficial. MPM.addPass(GlobalSplitPass()); // Run whole program optimization of virtual call when the list of callees // is fixed. MPM.addPass(WholeProgramDevirtPass(ExportSummary, nullptr)); // Stop here at -O1. if (Level == OptimizationLevel::O1) { // The LowerTypeTestsPass needs to run to lower type metadata and the // type.test intrinsics. The pass does nothing if CFI is disabled. MPM.addPass(LowerTypeTestsPass(ExportSummary, nullptr)); // Run a second time to clean up any type tests left behind by WPD for use // in ICP (which is performed earlier than this in the regular LTO // pipeline). MPM.addPass(LowerTypeTestsPass(nullptr, nullptr, true)); // Emit annotation remarks. addAnnotationRemarksPass(MPM); return MPM; } // Optimize globals to try and fold them into constants. MPM.addPass(GlobalOptPass()); // Promote any localized globals to SSA registers. MPM.addPass(createModuleToFunctionPassAdaptor(PromotePass())); // Linking modules together can lead to duplicate global constant, only // keep one copy of each constant. MPM.addPass(ConstantMergePass()); // Remove unused arguments from functions. MPM.addPass(DeadArgumentEliminationPass()); // Reduce the code after globalopt and ipsccp. Both can open up significant // simplification opportunities, and both can propagate functions through // function pointers. When this happens, we often have to resolve varargs // calls, etc, so let instcombine do this. FunctionPassManager PeepholeFPM; if (Level == OptimizationLevel::O3) PeepholeFPM.addPass(AggressiveInstCombinePass()); PeepholeFPM.addPass(InstCombinePass()); invokePeepholeEPCallbacks(PeepholeFPM, Level); MPM.addPass(createModuleToFunctionPassAdaptor(std::move(PeepholeFPM))); // Note: historically, the PruneEH pass was run first to deduce nounwind and // generally clean up exception handling overhead. It isn't clear this is // valuable as the inliner doesn't currently care whether it is inlining an // invoke or a call. // Run the inliner now. MPM.addPass(ModuleInlinerWrapperPass(getInlineParamsFromOptLevel(Level))); // Optimize globals again after we ran the inliner. MPM.addPass(GlobalOptPass()); // Garbage collect dead functions. // FIXME: Add ArgumentPromotion pass after once it's ported. MPM.addPass(GlobalDCEPass()); FunctionPassManager FPM; // The IPO Passes may leave cruft around. Clean up after them. FPM.addPass(InstCombinePass()); invokePeepholeEPCallbacks(FPM, Level); FPM.addPass(JumpThreadingPass(/*InsertFreezeWhenUnfoldingSelect*/ true)); // Do a post inline PGO instrumentation and use pass. This is a context // sensitive PGO pass. if (PGOOpt) { if (PGOOpt->CSAction == PGOOptions::CSIRInstr) addPGOInstrPasses(MPM, Level, /* RunProfileGen */ true, /* IsCS */ true, PGOOpt->CSProfileGenFile, PGOOpt->ProfileRemappingFile); else if (PGOOpt->CSAction == PGOOptions::CSIRUse) addPGOInstrPasses(MPM, Level, /* RunProfileGen */ false, /* IsCS */ true, PGOOpt->ProfileFile, PGOOpt->ProfileRemappingFile); } // Break up allocas FPM.addPass(SROA()); // LTO provides additional opportunities for tailcall elimination due to // link-time inlining, and visibility of nocapture attribute. FPM.addPass(TailCallElimPass()); // Run a few AA driver optimizations here and now to cleanup the code. MPM.addPass(createModuleToFunctionPassAdaptor(std::move(FPM))); MPM.addPass( createModuleToPostOrderCGSCCPassAdaptor(PostOrderFunctionAttrsPass())); // Require the GlobalsAA analysis for the module so we can query it within // MainFPM. MPM.addPass(RequireAnalysisPass()); // Invalidate AAManager so it can be recreated and pick up the newly available // GlobalsAA. MPM.addPass( createModuleToFunctionPassAdaptor(InvalidateAnalysisPass())); FunctionPassManager MainFPM; MainFPM.addPass(createFunctionToLoopPassAdaptor( LICMPass(PTO.LicmMssaOptCap, PTO.LicmMssaNoAccForPromotionCap), EnableMSSALoopDependency, /*UseBlockFrequencyInfo=*/true)); if (RunNewGVN) MainFPM.addPass(NewGVNPass()); else MainFPM.addPass(GVN()); // Remove dead memcpy()'s. MainFPM.addPass(MemCpyOptPass()); // Nuke dead stores. MainFPM.addPass(DSEPass()); MainFPM.addPass(MergedLoadStoreMotionPass()); // More loops are countable; try to optimize them. if (EnableLoopFlatten && Level.getSpeedupLevel() > 1) MainFPM.addPass(LoopFlattenPass()); if (EnableConstraintElimination) MainFPM.addPass(ConstraintEliminationPass()); LoopPassManager LPM; LPM.addPass(IndVarSimplifyPass()); LPM.addPass(LoopDeletionPass()); // FIXME: Add loop interchange. // Unroll small loops and perform peeling. LPM.addPass(LoopFullUnrollPass(Level.getSpeedupLevel(), /* OnlyWhenForced= */ !PTO.LoopUnrolling, PTO.ForgetAllSCEVInLoopUnroll)); // The loop passes in LPM (LoopFullUnrollPass) do not preserve MemorySSA. // *All* loop passes must preserve it, in order to be able to use it. MainFPM.addPass(createFunctionToLoopPassAdaptor( std::move(LPM), /*UseMemorySSA=*/false, /*UseBlockFrequencyInfo=*/true)); MainFPM.addPass(LoopDistributePass()); addVectorPasses(Level, MainFPM, /* IsLTO */ true); invokePeepholeEPCallbacks(MainFPM, Level); MainFPM.addPass(JumpThreadingPass(/*InsertFreezeWhenUnfoldingSelect*/ true)); MPM.addPass(createModuleToFunctionPassAdaptor(std::move(MainFPM))); // Create a function that performs CFI checks for cross-DSO calls with // targets in the current module. MPM.addPass(CrossDSOCFIPass()); // Lower type metadata and the type.test intrinsic. This pass supports // clang's control flow integrity mechanisms (-fsanitize=cfi*) and needs // to be run at link time if CFI is enabled. This pass does nothing if // CFI is disabled. MPM.addPass(LowerTypeTestsPass(ExportSummary, nullptr)); // Run a second time to clean up any type tests left behind by WPD for use // in ICP (which is performed earlier than this in the regular LTO pipeline). MPM.addPass(LowerTypeTestsPass(nullptr, nullptr, true)); // Enable splitting late in the FullLTO post-link pipeline. This is done in // the same stage in the old pass manager (\ref addLateLTOOptimizationPasses). if (EnableHotColdSplit) MPM.addPass(HotColdSplittingPass()); // Add late LTO optimization passes. // Delete basic blocks, which optimization passes may have killed. MPM.addPass(createModuleToFunctionPassAdaptor( SimplifyCFGPass(SimplifyCFGOptions().hoistCommonInsts(true)))); // Drop bodies of available eternally objects to improve GlobalDCE. MPM.addPass(EliminateAvailableExternallyPass()); // Now that we have optimized the program, discard unreachable functions. MPM.addPass(GlobalDCEPass()); if (PTO.MergeFunctions) MPM.addPass(MergeFunctionsPass()); // Emit annotation remarks. addAnnotationRemarksPass(MPM); return MPM; } ModulePassManager PassBuilder::buildO0DefaultPipeline(OptimizationLevel Level, bool LTOPreLink) { assert(Level == OptimizationLevel::O0 && "buildO0DefaultPipeline should only be used with O0"); ModulePassManager MPM; if (PGOOpt && (PGOOpt->Action == PGOOptions::IRInstr || PGOOpt->Action == PGOOptions::IRUse)) addPGOInstrPassesForO0( MPM, /* RunProfileGen */ (PGOOpt->Action == PGOOptions::IRInstr), /* IsCS */ false, PGOOpt->ProfileFile, PGOOpt->ProfileRemappingFile); for (auto &C : PipelineStartEPCallbacks) C(MPM, Level); for (auto &C : PipelineEarlySimplificationEPCallbacks) C(MPM, Level); // Build a minimal pipeline based on the semantics required by LLVM, // which is just that always inlining occurs. Further, disable generating // lifetime intrinsics to avoid enabling further optimizations during // code generation. // However, we need to insert lifetime intrinsics to avoid invalid access // caused by multithreaded coroutines. MPM.addPass(AlwaysInlinerPass( /*InsertLifetimeIntrinsics=*/PTO.Coroutines)); if (PTO.MergeFunctions) MPM.addPass(MergeFunctionsPass()); if (EnableMatrix) MPM.addPass( createModuleToFunctionPassAdaptor(LowerMatrixIntrinsicsPass(true))); if (!CGSCCOptimizerLateEPCallbacks.empty()) { CGSCCPassManager CGPM; for (auto &C : CGSCCOptimizerLateEPCallbacks) C(CGPM, Level); if (!CGPM.isEmpty()) MPM.addPass(createModuleToPostOrderCGSCCPassAdaptor(std::move(CGPM))); } if (!LateLoopOptimizationsEPCallbacks.empty()) { LoopPassManager LPM; for (auto &C : LateLoopOptimizationsEPCallbacks) C(LPM, Level); if (!LPM.isEmpty()) { MPM.addPass(createModuleToFunctionPassAdaptor( createFunctionToLoopPassAdaptor(std::move(LPM)))); } } if (!LoopOptimizerEndEPCallbacks.empty()) { LoopPassManager LPM; for (auto &C : LoopOptimizerEndEPCallbacks) C(LPM, Level); if (!LPM.isEmpty()) { MPM.addPass(createModuleToFunctionPassAdaptor( createFunctionToLoopPassAdaptor(std::move(LPM)))); } } if (!ScalarOptimizerLateEPCallbacks.empty()) { FunctionPassManager FPM; for (auto &C : ScalarOptimizerLateEPCallbacks) C(FPM, Level); if (!FPM.isEmpty()) MPM.addPass(createModuleToFunctionPassAdaptor(std::move(FPM))); } if (!VectorizerStartEPCallbacks.empty()) { FunctionPassManager FPM; for (auto &C : VectorizerStartEPCallbacks) C(FPM, Level); if (!FPM.isEmpty()) MPM.addPass(createModuleToFunctionPassAdaptor(std::move(FPM))); } if (PTO.Coroutines) { MPM.addPass(createModuleToFunctionPassAdaptor(CoroEarlyPass())); CGSCCPassManager CGPM; CGPM.addPass(CoroSplitPass()); CGPM.addPass(createCGSCCToFunctionPassAdaptor(CoroElidePass())); MPM.addPass(createModuleToPostOrderCGSCCPassAdaptor(std::move(CGPM))); MPM.addPass(createModuleToFunctionPassAdaptor(CoroCleanupPass())); } for (auto &C : OptimizerLastEPCallbacks) C(MPM, Level); if (LTOPreLink) addRequiredLTOPreLinkPasses(MPM); return MPM; } AAManager PassBuilder::buildDefaultAAPipeline() { AAManager AA; // The order in which these are registered determines their priority when // being queried. // First we register the basic alias analysis that provides the majority of // per-function local AA logic. This is a stateless, on-demand local set of // AA techniques. AA.registerFunctionAnalysis(); // Next we query fast, specialized alias analyses that wrap IR-embedded // information about aliasing. AA.registerFunctionAnalysis(); AA.registerFunctionAnalysis(); // Add support for querying global aliasing information when available. // Because the `AAManager` is a function analysis and `GlobalsAA` is a module // analysis, all that the `AAManager` can do is query for any *cached* // results from `GlobalsAA` through a readonly proxy. AA.registerModuleAnalysis(); // Add target-specific alias analyses. if (TM) TM->registerDefaultAliasAnalyses(AA); return AA; } static Optional parseRepeatPassName(StringRef Name) { if (!Name.consume_front("repeat<") || !Name.consume_back(">")) return None; int Count; if (Name.getAsInteger(0, Count) || Count <= 0) return None; return Count; } static Optional parseDevirtPassName(StringRef Name) { if (!Name.consume_front("devirt<") || !Name.consume_back(">")) return None; int Count; if (Name.getAsInteger(0, Count) || Count < 0) return None; return Count; } static bool checkParametrizedPassName(StringRef Name, StringRef PassName) { if (!Name.consume_front(PassName)) return false; // normal pass name w/o parameters == default parameters if (Name.empty()) return true; return Name.startswith("<") && Name.endswith(">"); } namespace { /// This performs customized parsing of pass name with parameters. /// /// We do not need parametrization of passes in textual pipeline very often, /// yet on a rare occasion ability to specify parameters right there can be /// useful. /// /// \p Name - parameterized specification of a pass from a textual pipeline /// is a string in a form of : /// PassName '<' parameter-list '>' /// /// Parameter list is being parsed by the parser callable argument, \p Parser, /// It takes a string-ref of parameters and returns either StringError or a /// parameter list in a form of a custom parameters type, all wrapped into /// Expected<> template class. /// template auto parsePassParameters(ParametersParseCallableT &&Parser, StringRef Name, StringRef PassName) -> decltype(Parser(StringRef{})) { using ParametersT = typename decltype(Parser(StringRef{}))::value_type; StringRef Params = Name; if (!Params.consume_front(PassName)) { assert(false && "unable to strip pass name from parametrized pass specification"); } if (Params.empty()) return ParametersT{}; if (!Params.consume_front("<") || !Params.consume_back(">")) { assert(false && "invalid format for parametrized pass name"); } Expected Result = Parser(Params); assert((Result || Result.template errorIsA()) && "Pass parameter parser can only return StringErrors."); return Result; } /// Parser of parameters for LoopUnroll pass. Expected parseLoopUnrollOptions(StringRef Params) { LoopUnrollOptions UnrollOpts; while (!Params.empty()) { StringRef ParamName; std::tie(ParamName, Params) = Params.split(';'); int OptLevel = StringSwitch(ParamName) .Case("O0", 0) .Case("O1", 1) .Case("O2", 2) .Case("O3", 3) .Default(-1); if (OptLevel >= 0) { UnrollOpts.setOptLevel(OptLevel); continue; } if (ParamName.consume_front("full-unroll-max=")) { int Count; if (ParamName.getAsInteger(0, Count)) return make_error( formatv("invalid LoopUnrollPass parameter '{0}' ", ParamName).str(), inconvertibleErrorCode()); UnrollOpts.setFullUnrollMaxCount(Count); continue; } bool Enable = !ParamName.consume_front("no-"); if (ParamName == "partial") { UnrollOpts.setPartial(Enable); } else if (ParamName == "peeling") { UnrollOpts.setPeeling(Enable); } else if (ParamName == "profile-peeling") { UnrollOpts.setProfileBasedPeeling(Enable); } else if (ParamName == "runtime") { UnrollOpts.setRuntime(Enable); } else if (ParamName == "upperbound") { UnrollOpts.setUpperBound(Enable); } else { return make_error( formatv("invalid LoopUnrollPass parameter '{0}' ", ParamName).str(), inconvertibleErrorCode()); } } return UnrollOpts; } Expected parseMSanPassOptions(StringRef Params) { MemorySanitizerOptions Result; while (!Params.empty()) { StringRef ParamName; std::tie(ParamName, Params) = Params.split(';'); if (ParamName == "recover") { Result.Recover = true; } else if (ParamName == "kernel") { Result.Kernel = true; } else if (ParamName.consume_front("track-origins=")) { if (ParamName.getAsInteger(0, Result.TrackOrigins)) return make_error( formatv("invalid argument to MemorySanitizer pass track-origins " "parameter: '{0}' ", ParamName) .str(), inconvertibleErrorCode()); } else { return make_error( formatv("invalid MemorySanitizer pass parameter '{0}' ", ParamName) .str(), inconvertibleErrorCode()); } } return Result; } /// Parser of parameters for SimplifyCFG pass. Expected parseSimplifyCFGOptions(StringRef Params) { SimplifyCFGOptions Result; while (!Params.empty()) { StringRef ParamName; std::tie(ParamName, Params) = Params.split(';'); bool Enable = !ParamName.consume_front("no-"); if (ParamName == "forward-switch-cond") { Result.forwardSwitchCondToPhi(Enable); } else if (ParamName == "switch-to-lookup") { Result.convertSwitchToLookupTable(Enable); } else if (ParamName == "keep-loops") { Result.needCanonicalLoops(Enable); } else if (ParamName == "hoist-common-insts") { Result.hoistCommonInsts(Enable); } else if (ParamName == "sink-common-insts") { Result.sinkCommonInsts(Enable); } else if (Enable && ParamName.consume_front("bonus-inst-threshold=")) { APInt BonusInstThreshold; if (ParamName.getAsInteger(0, BonusInstThreshold)) return make_error( formatv("invalid argument to SimplifyCFG pass bonus-threshold " "parameter: '{0}' ", ParamName).str(), inconvertibleErrorCode()); Result.bonusInstThreshold(BonusInstThreshold.getSExtValue()); } else { return make_error( formatv("invalid SimplifyCFG pass parameter '{0}' ", ParamName).str(), inconvertibleErrorCode()); } } return Result; } /// Parser of parameters for LoopVectorize pass. Expected parseLoopVectorizeOptions(StringRef Params) { LoopVectorizeOptions Opts; while (!Params.empty()) { StringRef ParamName; std::tie(ParamName, Params) = Params.split(';'); bool Enable = !ParamName.consume_front("no-"); if (ParamName == "interleave-forced-only") { Opts.setInterleaveOnlyWhenForced(Enable); } else if (ParamName == "vectorize-forced-only") { Opts.setVectorizeOnlyWhenForced(Enable); } else { return make_error( formatv("invalid LoopVectorize parameter '{0}' ", ParamName).str(), inconvertibleErrorCode()); } } return Opts; } Expected parseLoopUnswitchOptions(StringRef Params) { bool Result = false; while (!Params.empty()) { StringRef ParamName; std::tie(ParamName, Params) = Params.split(';'); bool Enable = !ParamName.consume_front("no-"); if (ParamName == "nontrivial") { Result = Enable; } else { return make_error( formatv("invalid LoopUnswitch pass parameter '{0}' ", ParamName) .str(), inconvertibleErrorCode()); } } return Result; } Expected parseMergedLoadStoreMotionOptions(StringRef Params) { bool Result = false; while (!Params.empty()) { StringRef ParamName; std::tie(ParamName, Params) = Params.split(';'); bool Enable = !ParamName.consume_front("no-"); if (ParamName == "split-footer-bb") { Result = Enable; } else { return make_error( formatv("invalid MergedLoadStoreMotion pass parameter '{0}' ", ParamName) .str(), inconvertibleErrorCode()); } } return Result; } Expected parseGVNOptions(StringRef Params) { GVNOptions Result; while (!Params.empty()) { StringRef ParamName; std::tie(ParamName, Params) = Params.split(';'); bool Enable = !ParamName.consume_front("no-"); if (ParamName == "pre") { Result.setPRE(Enable); } else if (ParamName == "load-pre") { Result.setLoadPRE(Enable); } else if (ParamName == "split-backedge-load-pre") { Result.setLoadPRESplitBackedge(Enable); } else if (ParamName == "memdep") { Result.setMemDep(Enable); } else { return make_error( formatv("invalid GVN pass parameter '{0}' ", ParamName).str(), inconvertibleErrorCode()); } } return Result; } Expected parseStackLifetimeOptions(StringRef Params) { StackLifetime::LivenessType Result = StackLifetime::LivenessType::May; while (!Params.empty()) { StringRef ParamName; std::tie(ParamName, Params) = Params.split(';'); if (ParamName == "may") { Result = StackLifetime::LivenessType::May; } else if (ParamName == "must") { Result = StackLifetime::LivenessType::Must; } else { return make_error( formatv("invalid StackLifetime parameter '{0}' ", ParamName).str(), inconvertibleErrorCode()); } } return Result; } } // namespace /// Tests whether a pass name starts with a valid prefix for a default pipeline /// alias. static bool startsWithDefaultPipelineAliasPrefix(StringRef Name) { return Name.startswith("default") || Name.startswith("thinlto") || Name.startswith("lto"); } /// Tests whether registered callbacks will accept a given pass name. /// /// When parsing a pipeline text, the type of the outermost pipeline may be /// omitted, in which case the type is automatically determined from the first /// pass name in the text. This may be a name that is handled through one of the /// callbacks. We check this through the oridinary parsing callbacks by setting /// up a dummy PassManager in order to not force the client to also handle this /// type of query. template static bool callbacksAcceptPassName(StringRef Name, CallbacksT &Callbacks) { if (!Callbacks.empty()) { PassManagerT DummyPM; for (auto &CB : Callbacks) if (CB(Name, DummyPM, {})) return true; } return false; } template static bool isModulePassName(StringRef Name, CallbacksT &Callbacks) { // Manually handle aliases for pre-configured pipeline fragments. if (startsWithDefaultPipelineAliasPrefix(Name)) return DefaultAliasRegex.match(Name); // Explicitly handle pass manager names. if (Name == "module") return true; if (Name == "cgscc") return true; if (Name == "function") return true; // Explicitly handle custom-parsed pass names. if (parseRepeatPassName(Name)) return true; #define MODULE_PASS(NAME, CREATE_PASS) \ if (Name == NAME) \ return true; #define MODULE_ANALYSIS(NAME, CREATE_PASS) \ if (Name == "require<" NAME ">" || Name == "invalidate<" NAME ">") \ return true; #include "PassRegistry.def" return callbacksAcceptPassName(Name, Callbacks); } template static bool isCGSCCPassName(StringRef Name, CallbacksT &Callbacks) { // Explicitly handle pass manager names. if (Name == "cgscc") return true; if (Name == "function") return true; // Explicitly handle custom-parsed pass names. if (parseRepeatPassName(Name)) return true; if (parseDevirtPassName(Name)) return true; #define CGSCC_PASS(NAME, CREATE_PASS) \ if (Name == NAME) \ return true; #define CGSCC_ANALYSIS(NAME, CREATE_PASS) \ if (Name == "require<" NAME ">" || Name == "invalidate<" NAME ">") \ return true; #include "PassRegistry.def" return callbacksAcceptPassName(Name, Callbacks); } template static bool isFunctionPassName(StringRef Name, CallbacksT &Callbacks) { // Explicitly handle pass manager names. if (Name == "function") return true; if (Name == "loop" || Name == "loop-mssa") return true; // Explicitly handle custom-parsed pass names. if (parseRepeatPassName(Name)) return true; #define FUNCTION_PASS(NAME, CREATE_PASS) \ if (Name == NAME) \ return true; #define FUNCTION_PASS_WITH_PARAMS(NAME, CREATE_PASS, PARSER) \ if (checkParametrizedPassName(Name, NAME)) \ return true; #define FUNCTION_ANALYSIS(NAME, CREATE_PASS) \ if (Name == "require<" NAME ">" || Name == "invalidate<" NAME ">") \ return true; #include "PassRegistry.def" return callbacksAcceptPassName(Name, Callbacks); } template static bool isLoopPassName(StringRef Name, CallbacksT &Callbacks) { // Explicitly handle pass manager names. if (Name == "loop" || Name == "loop-mssa") return true; // Explicitly handle custom-parsed pass names. if (parseRepeatPassName(Name)) return true; #define LOOP_PASS(NAME, CREATE_PASS) \ if (Name == NAME) \ return true; #define LOOP_PASS_WITH_PARAMS(NAME, CREATE_PASS, PARSER) \ if (checkParametrizedPassName(Name, NAME)) \ return true; #define LOOP_ANALYSIS(NAME, CREATE_PASS) \ if (Name == "require<" NAME ">" || Name == "invalidate<" NAME ">") \ return true; #include "PassRegistry.def" return callbacksAcceptPassName(Name, Callbacks); } Optional> PassBuilder::parsePipelineText(StringRef Text) { std::vector ResultPipeline; SmallVector *, 4> PipelineStack = { &ResultPipeline}; for (;;) { std::vector &Pipeline = *PipelineStack.back(); size_t Pos = Text.find_first_of(",()"); Pipeline.push_back({Text.substr(0, Pos), {}}); // If we have a single terminating name, we're done. if (Pos == Text.npos) break; char Sep = Text[Pos]; Text = Text.substr(Pos + 1); if (Sep == ',') // Just a name ending in a comma, continue. continue; if (Sep == '(') { // Push the inner pipeline onto the stack to continue processing. PipelineStack.push_back(&Pipeline.back().InnerPipeline); continue; } assert(Sep == ')' && "Bogus separator!"); // When handling the close parenthesis, we greedily consume them to avoid // empty strings in the pipeline. do { // If we try to pop the outer pipeline we have unbalanced parentheses. if (PipelineStack.size() == 1) return None; PipelineStack.pop_back(); } while (Text.consume_front(")")); // Check if we've finished parsing. if (Text.empty()) break; // Otherwise, the end of an inner pipeline always has to be followed by // a comma, and then we can continue. if (!Text.consume_front(",")) return None; } if (PipelineStack.size() > 1) // Unbalanced paretheses. return None; assert(PipelineStack.back() == &ResultPipeline && "Wrong pipeline at the bottom of the stack!"); return {std::move(ResultPipeline)}; } Error PassBuilder::parseModulePass(ModulePassManager &MPM, const PipelineElement &E) { auto &Name = E.Name; auto &InnerPipeline = E.InnerPipeline; // First handle complex passes like the pass managers which carry pipelines. if (!InnerPipeline.empty()) { if (Name == "module") { ModulePassManager NestedMPM; if (auto Err = parseModulePassPipeline(NestedMPM, InnerPipeline)) return Err; MPM.addPass(std::move(NestedMPM)); return Error::success(); } if (Name == "cgscc") { CGSCCPassManager CGPM; if (auto Err = parseCGSCCPassPipeline(CGPM, InnerPipeline)) return Err; MPM.addPass(createModuleToPostOrderCGSCCPassAdaptor(std::move(CGPM))); return Error::success(); } if (Name == "function") { FunctionPassManager FPM; if (auto Err = parseFunctionPassPipeline(FPM, InnerPipeline)) return Err; MPM.addPass(createModuleToFunctionPassAdaptor(std::move(FPM))); return Error::success(); } if (auto Count = parseRepeatPassName(Name)) { ModulePassManager NestedMPM; if (auto Err = parseModulePassPipeline(NestedMPM, InnerPipeline)) return Err; MPM.addPass(createRepeatedPass(*Count, std::move(NestedMPM))); return Error::success(); } for (auto &C : ModulePipelineParsingCallbacks) if (C(Name, MPM, InnerPipeline)) return Error::success(); // Normal passes can't have pipelines. return make_error( formatv("invalid use of '{0}' pass as module pipeline", Name).str(), inconvertibleErrorCode()); ; } // Manually handle aliases for pre-configured pipeline fragments. if (startsWithDefaultPipelineAliasPrefix(Name)) { SmallVector Matches; if (!DefaultAliasRegex.match(Name, &Matches)) return make_error( formatv("unknown default pipeline alias '{0}'", Name).str(), inconvertibleErrorCode()); assert(Matches.size() == 3 && "Must capture two matched strings!"); OptimizationLevel L = StringSwitch(Matches[2]) .Case("O0", OptimizationLevel::O0) .Case("O1", OptimizationLevel::O1) .Case("O2", OptimizationLevel::O2) .Case("O3", OptimizationLevel::O3) .Case("Os", OptimizationLevel::Os) .Case("Oz", OptimizationLevel::Oz); if (L == OptimizationLevel::O0 && Matches[1] != "thinlto" && Matches[1] != "lto") { MPM.addPass(buildO0DefaultPipeline(L, Matches[1] == "thinlto-pre-link" || Matches[1] == "lto-pre-link")); return Error::success(); } // This is consistent with old pass manager invoked via opt, but // inconsistent with clang. Clang doesn't enable loop vectorization // but does enable slp vectorization at Oz. PTO.LoopVectorization = L.getSpeedupLevel() > 1 && L != OptimizationLevel::Oz; PTO.SLPVectorization = L.getSpeedupLevel() > 1 && L != OptimizationLevel::Oz; if (Matches[1] == "default") { MPM.addPass(buildPerModuleDefaultPipeline(L)); } else if (Matches[1] == "thinlto-pre-link") { MPM.addPass(buildThinLTOPreLinkDefaultPipeline(L)); } else if (Matches[1] == "thinlto") { MPM.addPass(buildThinLTODefaultPipeline(L, nullptr)); } else if (Matches[1] == "lto-pre-link") { MPM.addPass(buildLTOPreLinkDefaultPipeline(L)); } else { assert(Matches[1] == "lto" && "Not one of the matched options!"); MPM.addPass(buildLTODefaultPipeline(L, nullptr)); } return Error::success(); } // Finally expand the basic registered passes from the .inc file. #define MODULE_PASS(NAME, CREATE_PASS) \ if (Name == NAME) { \ MPM.addPass(CREATE_PASS); \ return Error::success(); \ } #define MODULE_ANALYSIS(NAME, CREATE_PASS) \ if (Name == "require<" NAME ">") { \ MPM.addPass( \ RequireAnalysisPass< \ std::remove_reference::type, Module>()); \ return Error::success(); \ } \ if (Name == "invalidate<" NAME ">") { \ MPM.addPass(InvalidateAnalysisPass< \ std::remove_reference::type>()); \ return Error::success(); \ } #define CGSCC_PASS(NAME, CREATE_PASS) \ if (Name == NAME) { \ MPM.addPass(createModuleToPostOrderCGSCCPassAdaptor(CREATE_PASS)); \ return Error::success(); \ } #define FUNCTION_PASS(NAME, CREATE_PASS) \ if (Name == NAME) { \ MPM.addPass(createModuleToFunctionPassAdaptor(CREATE_PASS)); \ return Error::success(); \ } #define FUNCTION_PASS_WITH_PARAMS(NAME, CREATE_PASS, PARSER) \ if (checkParametrizedPassName(Name, NAME)) { \ auto Params = parsePassParameters(PARSER, Name, NAME); \ if (!Params) \ return Params.takeError(); \ MPM.addPass(createModuleToFunctionPassAdaptor(CREATE_PASS(Params.get()))); \ return Error::success(); \ } #define LOOP_PASS(NAME, CREATE_PASS) \ if (Name == NAME) { \ MPM.addPass(createModuleToFunctionPassAdaptor( \ createFunctionToLoopPassAdaptor(CREATE_PASS, false, false))); \ return Error::success(); \ } #define LOOP_PASS_WITH_PARAMS(NAME, CREATE_PASS, PARSER) \ if (checkParametrizedPassName(Name, NAME)) { \ auto Params = parsePassParameters(PARSER, Name, NAME); \ if (!Params) \ return Params.takeError(); \ MPM.addPass( \ createModuleToFunctionPassAdaptor(createFunctionToLoopPassAdaptor( \ CREATE_PASS(Params.get()), false, false))); \ return Error::success(); \ } #include "PassRegistry.def" for (auto &C : ModulePipelineParsingCallbacks) if (C(Name, MPM, InnerPipeline)) return Error::success(); return make_error( formatv("unknown module pass '{0}'", Name).str(), inconvertibleErrorCode()); } Error PassBuilder::parseCGSCCPass(CGSCCPassManager &CGPM, const PipelineElement &E) { auto &Name = E.Name; auto &InnerPipeline = E.InnerPipeline; // First handle complex passes like the pass managers which carry pipelines. if (!InnerPipeline.empty()) { if (Name == "cgscc") { CGSCCPassManager NestedCGPM; if (auto Err = parseCGSCCPassPipeline(NestedCGPM, InnerPipeline)) return Err; // Add the nested pass manager with the appropriate adaptor. CGPM.addPass(std::move(NestedCGPM)); return Error::success(); } if (Name == "function") { FunctionPassManager FPM; if (auto Err = parseFunctionPassPipeline(FPM, InnerPipeline)) return Err; // Add the nested pass manager with the appropriate adaptor. CGPM.addPass(createCGSCCToFunctionPassAdaptor(std::move(FPM))); return Error::success(); } if (auto Count = parseRepeatPassName(Name)) { CGSCCPassManager NestedCGPM; if (auto Err = parseCGSCCPassPipeline(NestedCGPM, InnerPipeline)) return Err; CGPM.addPass(createRepeatedPass(*Count, std::move(NestedCGPM))); return Error::success(); } if (auto MaxRepetitions = parseDevirtPassName(Name)) { CGSCCPassManager NestedCGPM; if (auto Err = parseCGSCCPassPipeline(NestedCGPM, InnerPipeline)) return Err; CGPM.addPass( createDevirtSCCRepeatedPass(std::move(NestedCGPM), *MaxRepetitions)); return Error::success(); } for (auto &C : CGSCCPipelineParsingCallbacks) if (C(Name, CGPM, InnerPipeline)) return Error::success(); // Normal passes can't have pipelines. return make_error( formatv("invalid use of '{0}' pass as cgscc pipeline", Name).str(), inconvertibleErrorCode()); } // Now expand the basic registered passes from the .inc file. #define CGSCC_PASS(NAME, CREATE_PASS) \ if (Name == NAME) { \ CGPM.addPass(CREATE_PASS); \ return Error::success(); \ } #define CGSCC_ANALYSIS(NAME, CREATE_PASS) \ if (Name == "require<" NAME ">") { \ CGPM.addPass(RequireAnalysisPass< \ std::remove_reference::type, \ LazyCallGraph::SCC, CGSCCAnalysisManager, LazyCallGraph &, \ CGSCCUpdateResult &>()); \ return Error::success(); \ } \ if (Name == "invalidate<" NAME ">") { \ CGPM.addPass(InvalidateAnalysisPass< \ std::remove_reference::type>()); \ return Error::success(); \ } #define FUNCTION_PASS(NAME, CREATE_PASS) \ if (Name == NAME) { \ CGPM.addPass(createCGSCCToFunctionPassAdaptor(CREATE_PASS)); \ return Error::success(); \ } #define FUNCTION_PASS_WITH_PARAMS(NAME, CREATE_PASS, PARSER) \ if (checkParametrizedPassName(Name, NAME)) { \ auto Params = parsePassParameters(PARSER, Name, NAME); \ if (!Params) \ return Params.takeError(); \ CGPM.addPass(createCGSCCToFunctionPassAdaptor(CREATE_PASS(Params.get()))); \ return Error::success(); \ } #define LOOP_PASS(NAME, CREATE_PASS) \ if (Name == NAME) { \ CGPM.addPass(createCGSCCToFunctionPassAdaptor( \ createFunctionToLoopPassAdaptor(CREATE_PASS, false, false))); \ return Error::success(); \ } #define LOOP_PASS_WITH_PARAMS(NAME, CREATE_PASS, PARSER) \ if (checkParametrizedPassName(Name, NAME)) { \ auto Params = parsePassParameters(PARSER, Name, NAME); \ if (!Params) \ return Params.takeError(); \ CGPM.addPass( \ createCGSCCToFunctionPassAdaptor(createFunctionToLoopPassAdaptor( \ CREATE_PASS(Params.get()), false, false))); \ return Error::success(); \ } #include "PassRegistry.def" for (auto &C : CGSCCPipelineParsingCallbacks) if (C(Name, CGPM, InnerPipeline)) return Error::success(); return make_error( formatv("unknown cgscc pass '{0}'", Name).str(), inconvertibleErrorCode()); } Error PassBuilder::parseFunctionPass(FunctionPassManager &FPM, const PipelineElement &E) { auto &Name = E.Name; auto &InnerPipeline = E.InnerPipeline; // First handle complex passes like the pass managers which carry pipelines. if (!InnerPipeline.empty()) { if (Name == "function") { FunctionPassManager NestedFPM; if (auto Err = parseFunctionPassPipeline(NestedFPM, InnerPipeline)) return Err; // Add the nested pass manager with the appropriate adaptor. FPM.addPass(std::move(NestedFPM)); return Error::success(); } if (Name == "loop" || Name == "loop-mssa") { LoopPassManager LPM; if (auto Err = parseLoopPassPipeline(LPM, InnerPipeline)) return Err; // Add the nested pass manager with the appropriate adaptor. bool UseMemorySSA = (Name == "loop-mssa"); bool UseBFI = llvm::any_of( InnerPipeline, [](auto Pipeline) { return Pipeline.Name == "licm"; }); FPM.addPass(createFunctionToLoopPassAdaptor(std::move(LPM), UseMemorySSA, UseBFI)); return Error::success(); } if (auto Count = parseRepeatPassName(Name)) { FunctionPassManager NestedFPM; if (auto Err = parseFunctionPassPipeline(NestedFPM, InnerPipeline)) return Err; FPM.addPass(createRepeatedPass(*Count, std::move(NestedFPM))); return Error::success(); } for (auto &C : FunctionPipelineParsingCallbacks) if (C(Name, FPM, InnerPipeline)) return Error::success(); // Normal passes can't have pipelines. return make_error( formatv("invalid use of '{0}' pass as function pipeline", Name).str(), inconvertibleErrorCode()); } // Now expand the basic registered passes from the .inc file. #define FUNCTION_PASS(NAME, CREATE_PASS) \ if (Name == NAME) { \ FPM.addPass(CREATE_PASS); \ return Error::success(); \ } #define FUNCTION_PASS_WITH_PARAMS(NAME, CREATE_PASS, PARSER) \ if (checkParametrizedPassName(Name, NAME)) { \ auto Params = parsePassParameters(PARSER, Name, NAME); \ if (!Params) \ return Params.takeError(); \ FPM.addPass(CREATE_PASS(Params.get())); \ return Error::success(); \ } #define FUNCTION_ANALYSIS(NAME, CREATE_PASS) \ if (Name == "require<" NAME ">") { \ FPM.addPass( \ RequireAnalysisPass< \ std::remove_reference::type, Function>()); \ return Error::success(); \ } \ if (Name == "invalidate<" NAME ">") { \ FPM.addPass(InvalidateAnalysisPass< \ std::remove_reference::type>()); \ return Error::success(); \ } // FIXME: UseMemorySSA is set to false. Maybe we could do things like: // bool UseMemorySSA = !("canon-freeze" || "loop-predication" || // "guard-widening"); // The risk is that it may become obsolete if we're not careful. #define LOOP_PASS(NAME, CREATE_PASS) \ if (Name == NAME) { \ FPM.addPass(createFunctionToLoopPassAdaptor(CREATE_PASS, false, false)); \ return Error::success(); \ } #define LOOP_PASS_WITH_PARAMS(NAME, CREATE_PASS, PARSER) \ if (checkParametrizedPassName(Name, NAME)) { \ auto Params = parsePassParameters(PARSER, Name, NAME); \ if (!Params) \ return Params.takeError(); \ FPM.addPass(createFunctionToLoopPassAdaptor(CREATE_PASS(Params.get()), \ false, false)); \ return Error::success(); \ } #include "PassRegistry.def" for (auto &C : FunctionPipelineParsingCallbacks) if (C(Name, FPM, InnerPipeline)) return Error::success(); return make_error( formatv("unknown function pass '{0}'", Name).str(), inconvertibleErrorCode()); } Error PassBuilder::parseLoopPass(LoopPassManager &LPM, const PipelineElement &E) { StringRef Name = E.Name; auto &InnerPipeline = E.InnerPipeline; // First handle complex passes like the pass managers which carry pipelines. if (!InnerPipeline.empty()) { if (Name == "loop") { LoopPassManager NestedLPM; if (auto Err = parseLoopPassPipeline(NestedLPM, InnerPipeline)) return Err; // Add the nested pass manager with the appropriate adaptor. LPM.addPass(std::move(NestedLPM)); return Error::success(); } if (auto Count = parseRepeatPassName(Name)) { LoopPassManager NestedLPM; if (auto Err = parseLoopPassPipeline(NestedLPM, InnerPipeline)) return Err; LPM.addPass(createRepeatedPass(*Count, std::move(NestedLPM))); return Error::success(); } for (auto &C : LoopPipelineParsingCallbacks) if (C(Name, LPM, InnerPipeline)) return Error::success(); // Normal passes can't have pipelines. return make_error( formatv("invalid use of '{0}' pass as loop pipeline", Name).str(), inconvertibleErrorCode()); } // Now expand the basic registered passes from the .inc file. #define LOOP_PASS(NAME, CREATE_PASS) \ if (Name == NAME) { \ LPM.addPass(CREATE_PASS); \ return Error::success(); \ } #define LOOP_PASS_WITH_PARAMS(NAME, CREATE_PASS, PARSER) \ if (checkParametrizedPassName(Name, NAME)) { \ auto Params = parsePassParameters(PARSER, Name, NAME); \ if (!Params) \ return Params.takeError(); \ LPM.addPass(CREATE_PASS(Params.get())); \ return Error::success(); \ } #define LOOP_ANALYSIS(NAME, CREATE_PASS) \ if (Name == "require<" NAME ">") { \ LPM.addPass(RequireAnalysisPass< \ std::remove_reference::type, Loop, \ LoopAnalysisManager, LoopStandardAnalysisResults &, \ LPMUpdater &>()); \ return Error::success(); \ } \ if (Name == "invalidate<" NAME ">") { \ LPM.addPass(InvalidateAnalysisPass< \ std::remove_reference::type>()); \ return Error::success(); \ } #include "PassRegistry.def" for (auto &C : LoopPipelineParsingCallbacks) if (C(Name, LPM, InnerPipeline)) return Error::success(); return make_error(formatv("unknown loop pass '{0}'", Name).str(), inconvertibleErrorCode()); } bool PassBuilder::parseAAPassName(AAManager &AA, StringRef Name) { #define MODULE_ALIAS_ANALYSIS(NAME, CREATE_PASS) \ if (Name == NAME) { \ AA.registerModuleAnalysis< \ std::remove_reference::type>(); \ return true; \ } #define FUNCTION_ALIAS_ANALYSIS(NAME, CREATE_PASS) \ if (Name == NAME) { \ AA.registerFunctionAnalysis< \ std::remove_reference::type>(); \ return true; \ } #include "PassRegistry.def" for (auto &C : AAParsingCallbacks) if (C(Name, AA)) return true; return false; } Error PassBuilder::parseLoopPassPipeline(LoopPassManager &LPM, ArrayRef Pipeline) { for (const auto &Element : Pipeline) { if (auto Err = parseLoopPass(LPM, Element)) return Err; } return Error::success(); } Error PassBuilder::parseFunctionPassPipeline( FunctionPassManager &FPM, ArrayRef Pipeline) { for (const auto &Element : Pipeline) { if (auto Err = parseFunctionPass(FPM, Element)) return Err; } return Error::success(); } Error PassBuilder::parseCGSCCPassPipeline(CGSCCPassManager &CGPM, ArrayRef Pipeline) { for (const auto &Element : Pipeline) { if (auto Err = parseCGSCCPass(CGPM, Element)) return Err; } return Error::success(); } void PassBuilder::crossRegisterProxies(LoopAnalysisManager &LAM, FunctionAnalysisManager &FAM, CGSCCAnalysisManager &CGAM, ModuleAnalysisManager &MAM) { MAM.registerPass([&] { return FunctionAnalysisManagerModuleProxy(FAM); }); MAM.registerPass([&] { return CGSCCAnalysisManagerModuleProxy(CGAM); }); CGAM.registerPass([&] { return ModuleAnalysisManagerCGSCCProxy(MAM); }); FAM.registerPass([&] { return CGSCCAnalysisManagerFunctionProxy(CGAM); }); FAM.registerPass([&] { return ModuleAnalysisManagerFunctionProxy(MAM); }); FAM.registerPass([&] { return LoopAnalysisManagerFunctionProxy(LAM); }); LAM.registerPass([&] { return FunctionAnalysisManagerLoopProxy(FAM); }); } Error PassBuilder::parseModulePassPipeline(ModulePassManager &MPM, ArrayRef Pipeline) { for (const auto &Element : Pipeline) { if (auto Err = parseModulePass(MPM, Element)) return Err; } return Error::success(); } // Primary pass pipeline description parsing routine for a \c ModulePassManager // FIXME: Should this routine accept a TargetMachine or require the caller to // pre-populate the analysis managers with target-specific stuff? Error PassBuilder::parsePassPipeline(ModulePassManager &MPM, StringRef PipelineText) { auto Pipeline = parsePipelineText(PipelineText); if (!Pipeline || Pipeline->empty()) return make_error( formatv("invalid pipeline '{0}'", PipelineText).str(), inconvertibleErrorCode()); // If the first name isn't at the module layer, wrap the pipeline up // automatically. StringRef FirstName = Pipeline->front().Name; if (!isModulePassName(FirstName, ModulePipelineParsingCallbacks)) { if (isCGSCCPassName(FirstName, CGSCCPipelineParsingCallbacks)) { Pipeline = {{"cgscc", std::move(*Pipeline)}}; } else if (isFunctionPassName(FirstName, FunctionPipelineParsingCallbacks)) { Pipeline = {{"function", std::move(*Pipeline)}}; } else if (isLoopPassName(FirstName, LoopPipelineParsingCallbacks)) { Pipeline = {{"function", {{"loop", std::move(*Pipeline)}}}}; } else { for (auto &C : TopLevelPipelineParsingCallbacks) if (C(MPM, *Pipeline)) return Error::success(); // Unknown pass or pipeline name! auto &InnerPipeline = Pipeline->front().InnerPipeline; return make_error( formatv("unknown {0} name '{1}'", (InnerPipeline.empty() ? "pass" : "pipeline"), FirstName) .str(), inconvertibleErrorCode()); } } if (auto Err = parseModulePassPipeline(MPM, *Pipeline)) return Err; return Error::success(); } // Primary pass pipeline description parsing routine for a \c CGSCCPassManager Error PassBuilder::parsePassPipeline(CGSCCPassManager &CGPM, StringRef PipelineText) { auto Pipeline = parsePipelineText(PipelineText); if (!Pipeline || Pipeline->empty()) return make_error( formatv("invalid pipeline '{0}'", PipelineText).str(), inconvertibleErrorCode()); StringRef FirstName = Pipeline->front().Name; if (!isCGSCCPassName(FirstName, CGSCCPipelineParsingCallbacks)) return make_error( formatv("unknown cgscc pass '{0}' in pipeline '{1}'", FirstName, PipelineText) .str(), inconvertibleErrorCode()); if (auto Err = parseCGSCCPassPipeline(CGPM, *Pipeline)) return Err; return Error::success(); } // Primary pass pipeline description parsing routine for a \c // FunctionPassManager Error PassBuilder::parsePassPipeline(FunctionPassManager &FPM, StringRef PipelineText) { auto Pipeline = parsePipelineText(PipelineText); if (!Pipeline || Pipeline->empty()) return make_error( formatv("invalid pipeline '{0}'", PipelineText).str(), inconvertibleErrorCode()); StringRef FirstName = Pipeline->front().Name; if (!isFunctionPassName(FirstName, FunctionPipelineParsingCallbacks)) return make_error( formatv("unknown function pass '{0}' in pipeline '{1}'", FirstName, PipelineText) .str(), inconvertibleErrorCode()); if (auto Err = parseFunctionPassPipeline(FPM, *Pipeline)) return Err; return Error::success(); } // Primary pass pipeline description parsing routine for a \c LoopPassManager Error PassBuilder::parsePassPipeline(LoopPassManager &CGPM, StringRef PipelineText) { auto Pipeline = parsePipelineText(PipelineText); if (!Pipeline || Pipeline->empty()) return make_error( formatv("invalid pipeline '{0}'", PipelineText).str(), inconvertibleErrorCode()); if (auto Err = parseLoopPassPipeline(CGPM, *Pipeline)) return Err; return Error::success(); } Error PassBuilder::parseAAPipeline(AAManager &AA, StringRef PipelineText) { // If the pipeline just consists of the word 'default' just replace the AA // manager with our default one. if (PipelineText == "default") { AA = buildDefaultAAPipeline(); return Error::success(); } while (!PipelineText.empty()) { StringRef Name; std::tie(Name, PipelineText) = PipelineText.split(','); if (!parseAAPassName(AA, Name)) return make_error( formatv("unknown alias analysis name '{0}'", Name).str(), inconvertibleErrorCode()); } return Error::success(); } bool PassBuilder::isAAPassName(StringRef PassName) { #define MODULE_ALIAS_ANALYSIS(NAME, CREATE_PASS) \ if (PassName == NAME) \ return true; #define FUNCTION_ALIAS_ANALYSIS(NAME, CREATE_PASS) \ if (PassName == NAME) \ return true; #include "PassRegistry.def" return false; } bool PassBuilder::isAnalysisPassName(StringRef PassName) { #define MODULE_ANALYSIS(NAME, CREATE_PASS) \ if (PassName == NAME) \ return true; #define FUNCTION_ANALYSIS(NAME, CREATE_PASS) \ if (PassName == NAME) \ return true; #define LOOP_ANALYSIS(NAME, CREATE_PASS) \ if (PassName == NAME) \ return true; #define CGSCC_ANALYSIS(NAME, CREATE_PASS) \ if (PassName == NAME) \ return true; #define MODULE_ALIAS_ANALYSIS(NAME, CREATE_PASS) \ if (PassName == NAME) \ return true; #define FUNCTION_ALIAS_ANALYSIS(NAME, CREATE_PASS) \ if (PassName == NAME) \ return true; #include "PassRegistry.def" return false; } static void printPassName(StringRef PassName, raw_ostream &OS) { OS << " " << PassName << "\n"; } void PassBuilder::printPassNames(raw_ostream &OS) { // TODO: print pass descriptions when they are available OS << "Module passes:\n"; #define MODULE_PASS(NAME, CREATE_PASS) printPassName(NAME, OS); #include "PassRegistry.def" OS << "Module analyses:\n"; #define MODULE_ANALYSIS(NAME, CREATE_PASS) printPassName(NAME, OS); #include "PassRegistry.def" OS << "Module alias analyses:\n"; #define MODULE_ALIAS_ANALYSIS(NAME, CREATE_PASS) printPassName(NAME, OS); #include "PassRegistry.def" OS << "CGSCC passes:\n"; #define CGSCC_PASS(NAME, CREATE_PASS) printPassName(NAME, OS); #include "PassRegistry.def" OS << "CGSCC analyses:\n"; #define CGSCC_ANALYSIS(NAME, CREATE_PASS) printPassName(NAME, OS); #include "PassRegistry.def" OS << "Function passes:\n"; #define FUNCTION_PASS(NAME, CREATE_PASS) printPassName(NAME, OS); #include "PassRegistry.def" OS << "Function analyses:\n"; #define FUNCTION_ANALYSIS(NAME, CREATE_PASS) printPassName(NAME, OS); #include "PassRegistry.def" OS << "Function alias analyses:\n"; #define FUNCTION_ALIAS_ANALYSIS(NAME, CREATE_PASS) printPassName(NAME, OS); #include "PassRegistry.def" OS << "Loop passes:\n"; #define LOOP_PASS(NAME, CREATE_PASS) printPassName(NAME, OS); #include "PassRegistry.def" OS << "Loop analyses:\n"; #define LOOP_ANALYSIS(NAME, CREATE_PASS) printPassName(NAME, OS); #include "PassRegistry.def" } void PassBuilder::registerParseTopLevelPipelineCallback( const std::function)> &C) { TopLevelPipelineParsingCallbacks.push_back(C); }