//===-- InstrProfiling.cpp - Frontend instrumentation based profiling -----===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// // // This pass lowers instrprof_* intrinsics emitted by an instrumentor. // It also builds the data structures and initialization code needed for // updating execution counts and emitting the profile at runtime. // //===----------------------------------------------------------------------===// #include "llvm/Transforms/Instrumentation/InstrProfiling.h" #include "llvm/ADT/ArrayRef.h" #include "llvm/ADT/STLExtras.h" #include "llvm/ADT/SmallVector.h" #include "llvm/ADT/StringRef.h" #include "llvm/ADT/Twine.h" #include "llvm/Analysis/BlockFrequencyInfo.h" #include "llvm/Analysis/BranchProbabilityInfo.h" #include "llvm/Analysis/CFG.h" #include "llvm/Analysis/LoopInfo.h" #include "llvm/Analysis/TargetLibraryInfo.h" #include "llvm/IR/Attributes.h" #include "llvm/IR/BasicBlock.h" #include "llvm/IR/CFG.h" #include "llvm/IR/Constant.h" #include "llvm/IR/Constants.h" #include "llvm/IR/DIBuilder.h" #include "llvm/IR/DerivedTypes.h" #include "llvm/IR/DiagnosticInfo.h" #include "llvm/IR/Dominators.h" #include "llvm/IR/Function.h" #include "llvm/IR/GlobalValue.h" #include "llvm/IR/GlobalVariable.h" #include "llvm/IR/IRBuilder.h" #include "llvm/IR/Instruction.h" #include "llvm/IR/Instructions.h" #include "llvm/IR/IntrinsicInst.h" #include "llvm/IR/MDBuilder.h" #include "llvm/IR/Module.h" #include "llvm/IR/Type.h" #include "llvm/Pass.h" #include "llvm/ProfileData/InstrProf.h" #include "llvm/ProfileData/InstrProfCorrelator.h" #include "llvm/Support/Casting.h" #include "llvm/Support/CommandLine.h" #include "llvm/Support/Compiler.h" #include "llvm/Support/Error.h" #include "llvm/Support/ErrorHandling.h" #include "llvm/TargetParser/Triple.h" #include "llvm/Transforms/Instrumentation/PGOInstrumentation.h" #include "llvm/Transforms/Utils/BasicBlockUtils.h" #include "llvm/Transforms/Utils/Instrumentation.h" #include "llvm/Transforms/Utils/ModuleUtils.h" #include "llvm/Transforms/Utils/SSAUpdater.h" #include #include #include #include using namespace llvm; #define DEBUG_TYPE "instrprof" namespace llvm { // Command line option to enable vtable value profiling. Defined in // ProfileData/InstrProf.cpp: -enable-vtable-value-profiling= extern cl::opt EnableVTableValueProfiling; // TODO: Remove -debug-info-correlate in next LLVM release, in favor of // -profile-correlate=debug-info. cl::opt DebugInfoCorrelate( "debug-info-correlate", cl::desc("Use debug info to correlate profiles. (Deprecated, use " "-profile-correlate=debug-info)"), cl::init(false)); LLVM_ABI cl::opt ProfileCorrelate( "profile-correlate", cl::desc("Use debug info or binary file to correlate profiles."), cl::init(InstrProfCorrelator::NONE), cl::values(clEnumValN(InstrProfCorrelator::NONE, "", "No profile correlation"), clEnumValN(InstrProfCorrelator::DEBUG_INFO, "debug-info", "Use debug info to correlate"), clEnumValN(InstrProfCorrelator::BINARY, "binary", "Use binary to correlate"))); } // namespace llvm namespace { cl::opt DoHashBasedCounterSplit( "hash-based-counter-split", cl::desc("Rename counter variable of a comdat function based on cfg hash"), cl::init(true)); cl::opt RuntimeCounterRelocation("runtime-counter-relocation", cl::desc("Enable relocating counters at runtime."), cl::init(false)); cl::opt ValueProfileStaticAlloc( "vp-static-alloc", cl::desc("Do static counter allocation for value profiler"), cl::init(true)); cl::opt NumCountersPerValueSite( "vp-counters-per-site", cl::desc("The average number of profile counters allocated " "per value profiling site."), // This is set to a very small value because in real programs, only // a very small percentage of value sites have non-zero targets, e.g, 1/30. // For those sites with non-zero profile, the average number of targets // is usually smaller than 2. cl::init(1.0)); cl::opt AtomicCounterUpdateAll( "instrprof-atomic-counter-update-all", cl::desc("Make all profile counter updates atomic (for testing only)"), cl::init(false)); cl::opt AtomicCounterUpdatePromoted( "atomic-counter-update-promoted", cl::desc("Do counter update using atomic fetch add " " for promoted counters only"), cl::init(false)); cl::opt AtomicFirstCounter( "atomic-first-counter", cl::desc("Use atomic fetch add for first counter in a function (usually " "the entry counter)"), cl::init(false)); cl::opt ConditionalCounterUpdate( "conditional-counter-update", cl::desc("Do conditional counter updates in single byte counters mode)"), cl::init(false)); // If the option is not specified, the default behavior about whether // counter promotion is done depends on how instrumentaiton lowering // pipeline is setup, i.e., the default value of true of this option // does not mean the promotion will be done by default. Explicitly // setting this option can override the default behavior. cl::opt DoCounterPromotion("do-counter-promotion", cl::desc("Do counter register promotion"), cl::init(false)); cl::opt MaxNumOfPromotionsPerLoop( "max-counter-promotions-per-loop", cl::init(20), cl::desc("Max number counter promotions per loop to avoid" " increasing register pressure too much")); // A debug option cl::opt MaxNumOfPromotions("max-counter-promotions", cl::init(-1), cl::desc("Max number of allowed counter promotions")); cl::opt SpeculativeCounterPromotionMaxExiting( "speculative-counter-promotion-max-exiting", cl::init(3), cl::desc("The max number of exiting blocks of a loop to allow " " speculative counter promotion")); cl::opt SpeculativeCounterPromotionToLoop( "speculative-counter-promotion-to-loop", cl::desc("When the option is false, if the target block is in a loop, " "the promotion will be disallowed unless the promoted counter " " update can be further/iteratively promoted into an acyclic " " region.")); cl::opt IterativeCounterPromotion( "iterative-counter-promotion", cl::init(true), cl::desc("Allow counter promotion across the whole loop nest.")); cl::opt SkipRetExitBlock( "skip-ret-exit-block", cl::init(true), cl::desc("Suppress counter promotion if exit blocks contain ret.")); static cl::opt SampledInstr("sampled-instrumentation", cl::ZeroOrMore, cl::init(false), cl::desc("Do PGO instrumentation sampling")); static cl::opt SampledInstrPeriod( "sampled-instr-period", cl::desc("Set the profile instrumentation sample period. A sample period " "of 0 is invalid. For each sample period, a fixed number of " "consecutive samples will be recorded. The number is controlled " "by 'sampled-instr-burst-duration' flag. The default sample " "period of 65536 is optimized for generating efficient code that " "leverages unsigned short integer wrapping in overflow, but this " "is disabled under simple sampling (burst duration = 1)."), cl::init(USHRT_MAX + 1)); static cl::opt SampledInstrBurstDuration( "sampled-instr-burst-duration", cl::desc("Set the profile instrumentation burst duration, which can range " "from 1 to the value of 'sampled-instr-period' (0 is invalid). " "This number of samples will be recorded for each " "'sampled-instr-period' count update. Setting to 1 enables simple " "sampling, in which case it is recommended to set " "'sampled-instr-period' to a prime number."), cl::init(200)); struct SampledInstrumentationConfig { unsigned BurstDuration; unsigned Period; bool UseShort; bool IsSimpleSampling; bool IsFastSampling; }; static SampledInstrumentationConfig getSampledInstrumentationConfig() { SampledInstrumentationConfig config; config.BurstDuration = SampledInstrBurstDuration.getValue(); config.Period = SampledInstrPeriod.getValue(); if (config.BurstDuration > config.Period) report_fatal_error( "SampledBurstDuration must be less than or equal to SampledPeriod"); if (config.Period == 0 || config.BurstDuration == 0) report_fatal_error( "SampledPeriod and SampledBurstDuration must be greater than 0"); config.IsSimpleSampling = (config.BurstDuration == 1); // If (BurstDuration == 1 && Period == 65536), generate the simple sampling // style code. config.IsFastSampling = (!config.IsSimpleSampling && config.Period == USHRT_MAX + 1); config.UseShort = (config.Period <= USHRT_MAX) || config.IsFastSampling; return config; } using LoadStorePair = std::pair; static uint64_t getIntModuleFlagOrZero(const Module &M, StringRef Flag) { auto *MD = dyn_cast_or_null(M.getModuleFlag(Flag)); if (!MD) return 0; // If the flag is a ConstantAsMetadata, it should be an integer representable // in 64-bits. return cast(MD->getValue())->getZExtValue(); } static bool enablesValueProfiling(const Module &M) { return isIRPGOFlagSet(&M) || getIntModuleFlagOrZero(M, "EnableValueProfiling") != 0; } // Conservatively returns true if value profiling is enabled. static bool profDataReferencedByCode(const Module &M) { return enablesValueProfiling(M); } class InstrLowerer final { public: InstrLowerer(Module &M, const InstrProfOptions &Options, std::function GetTLI, bool IsCS) : M(M), Options(Options), TT(M.getTargetTriple()), IsCS(IsCS), GetTLI(GetTLI), DataReferencedByCode(profDataReferencedByCode(M)) {} bool lower(); private: Module &M; const InstrProfOptions Options; const Triple TT; // Is this lowering for the context-sensitive instrumentation. const bool IsCS; std::function GetTLI; const bool DataReferencedByCode; struct PerFunctionProfileData { uint32_t NumValueSites[IPVK_Last + 1] = {}; GlobalVariable *RegionCounters = nullptr; GlobalVariable *DataVar = nullptr; GlobalVariable *RegionBitmaps = nullptr; uint32_t NumBitmapBytes = 0; PerFunctionProfileData() = default; }; DenseMap ProfileDataMap; // Key is virtual table variable, value is 'VTableProfData' in the form of // GlobalVariable. DenseMap VTableDataMap; /// If runtime relocation is enabled, this maps functions to the load /// instruction that produces the profile relocation bias. DenseMap FunctionToProfileBiasMap; std::vector CompilerUsedVars; std::vector UsedVars; std::vector ReferencedNames; // The list of virtual table variables of which the VTableProfData is // collected. std::vector ReferencedVTables; GlobalVariable *NamesVar = nullptr; size_t NamesSize = 0; // vector of counter load/store pairs to be register promoted. std::vector PromotionCandidates; int64_t TotalCountersPromoted = 0; /// Lower instrumentation intrinsics in the function. Returns true if there /// any lowering. bool lowerIntrinsics(Function *F); /// Register-promote counter loads and stores in loops. void promoteCounterLoadStores(Function *F); /// Returns true if relocating counters at runtime is enabled. bool isRuntimeCounterRelocationEnabled() const; /// Returns true if profile counter update register promotion is enabled. bool isCounterPromotionEnabled() const; /// Return true if profile sampling is enabled. bool isSamplingEnabled() const; /// Count the number of instrumented value sites for the function. void computeNumValueSiteCounts(InstrProfValueProfileInst *Ins); /// Replace instrprof.value.profile with a call to runtime library. void lowerValueProfileInst(InstrProfValueProfileInst *Ins); /// Replace instrprof.cover with a store instruction to the coverage byte. void lowerCover(InstrProfCoverInst *Inc); /// Replace instrprof.timestamp with a call to /// INSTR_PROF_PROFILE_SET_TIMESTAMP. void lowerTimestamp(InstrProfTimestampInst *TimestampInstruction); /// Replace instrprof.increment with an increment of the appropriate value. void lowerIncrement(InstrProfIncrementInst *Inc); /// Force emitting of name vars for unused functions. void lowerCoverageData(GlobalVariable *CoverageNamesVar); /// Replace instrprof.mcdc.tvbitmask.update with a shift and or instruction /// using the index represented by the a temp value into a bitmap. void lowerMCDCTestVectorBitmapUpdate(InstrProfMCDCTVBitmapUpdate *Ins); /// Get the Bias value for data to access mmap-ed area. /// Create it if it hasn't been seen. GlobalVariable *getOrCreateBiasVar(StringRef VarName); /// Compute the address of the counter value that this profiling instruction /// acts on. Value *getCounterAddress(InstrProfCntrInstBase *I); /// Lower the incremental instructions under profile sampling predicates. void doSampling(Instruction *I); /// Get the region counters for an increment, creating them if necessary. /// /// If the counter array doesn't yet exist, the profile data variables /// referring to them will also be created. GlobalVariable *getOrCreateRegionCounters(InstrProfCntrInstBase *Inc); /// Create the region counters. GlobalVariable *createRegionCounters(InstrProfCntrInstBase *Inc, StringRef Name, GlobalValue::LinkageTypes Linkage); /// Compute the address of the test vector bitmap that this profiling /// instruction acts on. Value *getBitmapAddress(InstrProfMCDCTVBitmapUpdate *I); /// Get the region bitmaps for an increment, creating them if necessary. /// /// If the bitmap array doesn't yet exist, the profile data variables /// referring to them will also be created. GlobalVariable *getOrCreateRegionBitmaps(InstrProfMCDCBitmapInstBase *Inc); /// Create the MC/DC bitmap as a byte-aligned array of bytes associated with /// an MC/DC Decision region. The number of bytes required is indicated by /// the intrinsic used (type InstrProfMCDCBitmapInstBase). This is called /// as part of setupProfileSection() and is conceptually very similar to /// what is done for profile data counters in createRegionCounters(). GlobalVariable *createRegionBitmaps(InstrProfMCDCBitmapInstBase *Inc, StringRef Name, GlobalValue::LinkageTypes Linkage); /// Set Comdat property of GV, if required. void maybeSetComdat(GlobalVariable *GV, GlobalObject *GO, StringRef VarName); /// Setup the sections into which counters and bitmaps are allocated. GlobalVariable *setupProfileSection(InstrProfInstBase *Inc, InstrProfSectKind IPSK); /// Create INSTR_PROF_DATA variable for counters and bitmaps. void createDataVariable(InstrProfCntrInstBase *Inc); /// Get the counters for virtual table values, creating them if necessary. void getOrCreateVTableProfData(GlobalVariable *GV); /// Emit the section with compressed function names. void emitNameData(); /// Emit the section with compressed vtable names. void emitVTableNames(); /// Emit value nodes section for value profiling. void emitVNodes(); /// Emit runtime registration functions for each profile data variable. void emitRegistration(); /// Emit the necessary plumbing to pull in the runtime initialization. /// Returns true if a change was made. bool emitRuntimeHook(); /// Add uses of our data variables and runtime hook. void emitUses(); /// Create a static initializer for our data, on platforms that need it, /// and for any profile output file that was specified. void emitInitialization(); }; /// /// A helper class to promote one counter RMW operation in the loop /// into register update. /// /// RWM update for the counter will be sinked out of the loop after /// the transformation. /// class PGOCounterPromoterHelper : public LoadAndStorePromoter { public: PGOCounterPromoterHelper( Instruction *L, Instruction *S, SSAUpdater &SSA, Value *Init, BasicBlock *PH, ArrayRef ExitBlocks, ArrayRef InsertPts, DenseMap> &LoopToCands, LoopInfo &LI) : LoadAndStorePromoter({L, S}, SSA), Store(S), ExitBlocks(ExitBlocks), InsertPts(InsertPts), LoopToCandidates(LoopToCands), LI(LI) { assert(isa(L)); assert(isa(S)); SSA.AddAvailableValue(PH, Init); } void doExtraRewritesBeforeFinalDeletion() override { for (unsigned i = 0, e = ExitBlocks.size(); i != e; ++i) { BasicBlock *ExitBlock = ExitBlocks[i]; Instruction *InsertPos = InsertPts[i]; // Get LiveIn value into the ExitBlock. If there are multiple // predecessors, the value is defined by a PHI node in this // block. Value *LiveInValue = SSA.GetValueInMiddleOfBlock(ExitBlock); Value *Addr = cast(Store)->getPointerOperand(); Type *Ty = LiveInValue->getType(); IRBuilder<> Builder(InsertPos); if (auto *AddrInst = dyn_cast_or_null(Addr)) { // If isRuntimeCounterRelocationEnabled() is true then the address of // the store instruction is computed with two instructions in // InstrProfiling::getCounterAddress(). We need to copy those // instructions to this block to compute Addr correctly. // %BiasAdd = add i64 ptrtoint <__profc_>, <__llvm_profile_counter_bias> // %Addr = inttoptr i64 %BiasAdd to i64* auto *OrigBiasInst = dyn_cast(AddrInst->getOperand(0)); assert(OrigBiasInst->getOpcode() == Instruction::BinaryOps::Add); Value *BiasInst = Builder.Insert(OrigBiasInst->clone()); Addr = Builder.CreateIntToPtr(BiasInst, PointerType::getUnqual(Ty->getContext())); } if (AtomicCounterUpdatePromoted) // automic update currently can only be promoted across the current // loop, not the whole loop nest. Builder.CreateAtomicRMW(AtomicRMWInst::Add, Addr, LiveInValue, MaybeAlign(), AtomicOrdering::SequentiallyConsistent); else { LoadInst *OldVal = Builder.CreateLoad(Ty, Addr, "pgocount.promoted"); auto *NewVal = Builder.CreateAdd(OldVal, LiveInValue); auto *NewStore = Builder.CreateStore(NewVal, Addr); // Now update the parent loop's candidate list: if (IterativeCounterPromotion) { auto *TargetLoop = LI.getLoopFor(ExitBlock); if (TargetLoop) LoopToCandidates[TargetLoop].emplace_back(OldVal, NewStore); } } } } private: Instruction *Store; ArrayRef ExitBlocks; ArrayRef InsertPts; DenseMap> &LoopToCandidates; LoopInfo &LI; }; /// A helper class to do register promotion for all profile counter /// updates in a loop. /// class PGOCounterPromoter { public: PGOCounterPromoter( DenseMap> &LoopToCands, Loop &CurLoop, LoopInfo &LI, BlockFrequencyInfo *BFI) : LoopToCandidates(LoopToCands), L(CurLoop), LI(LI), BFI(BFI) { // Skip collection of ExitBlocks and InsertPts for loops that will not be // able to have counters promoted. SmallVector LoopExitBlocks; SmallPtrSet BlockSet; L.getExitBlocks(LoopExitBlocks); if (!isPromotionPossible(&L, LoopExitBlocks)) return; for (BasicBlock *ExitBlock : LoopExitBlocks) { if (BlockSet.insert(ExitBlock).second && llvm::none_of(predecessors(ExitBlock), [&](const BasicBlock *Pred) { return llvm::isPresplitCoroSuspendExitEdge(*Pred, *ExitBlock); })) { ExitBlocks.push_back(ExitBlock); InsertPts.push_back(&*ExitBlock->getFirstInsertionPt()); } } } bool run(int64_t *NumPromoted) { // Skip 'infinite' loops: if (ExitBlocks.size() == 0) return false; // Skip if any of the ExitBlocks contains a ret instruction. // This is to prevent dumping of incomplete profile -- if the // the loop is a long running loop and dump is called in the middle // of the loop, the result profile is incomplete. // FIXME: add other heuristics to detect long running loops. if (SkipRetExitBlock) { for (auto *BB : ExitBlocks) if (isa(BB->getTerminator())) return false; } unsigned MaxProm = getMaxNumOfPromotionsInLoop(&L); if (MaxProm == 0) return false; unsigned Promoted = 0; for (auto &Cand : LoopToCandidates[&L]) { SmallVector NewPHIs; SSAUpdater SSA(&NewPHIs); Value *InitVal = ConstantInt::get(Cand.first->getType(), 0); // If BFI is set, we will use it to guide the promotions. if (BFI) { auto *BB = Cand.first->getParent(); auto InstrCount = BFI->getBlockProfileCount(BB); if (!InstrCount) continue; auto PreheaderCount = BFI->getBlockProfileCount(L.getLoopPreheader()); // If the average loop trip count is not greater than 1.5, we skip // promotion. if (PreheaderCount && (*PreheaderCount * 3) >= (*InstrCount * 2)) continue; } PGOCounterPromoterHelper Promoter(Cand.first, Cand.second, SSA, InitVal, L.getLoopPreheader(), ExitBlocks, InsertPts, LoopToCandidates, LI); Promoter.run(SmallVector({Cand.first, Cand.second})); Promoted++; if (Promoted >= MaxProm) break; (*NumPromoted)++; if (MaxNumOfPromotions != -1 && *NumPromoted >= MaxNumOfPromotions) break; } LLVM_DEBUG(dbgs() << Promoted << " counters promoted for loop (depth=" << L.getLoopDepth() << ")\n"); return Promoted != 0; } private: bool allowSpeculativeCounterPromotion(Loop *LP) { SmallVector ExitingBlocks; L.getExitingBlocks(ExitingBlocks); // Not considierered speculative. if (ExitingBlocks.size() == 1) return true; if (ExitingBlocks.size() > SpeculativeCounterPromotionMaxExiting) return false; return true; } // Check whether the loop satisfies the basic conditions needed to perform // Counter Promotions. bool isPromotionPossible(Loop *LP, const SmallVectorImpl &LoopExitBlocks) { // We can't insert into a catchswitch. if (llvm::any_of(LoopExitBlocks, [](BasicBlock *Exit) { return isa(Exit->getTerminator()); })) return false; if (!LP->hasDedicatedExits()) return false; BasicBlock *PH = LP->getLoopPreheader(); if (!PH) return false; return true; } // Returns the max number of Counter Promotions for LP. unsigned getMaxNumOfPromotionsInLoop(Loop *LP) { SmallVector LoopExitBlocks; LP->getExitBlocks(LoopExitBlocks); if (!isPromotionPossible(LP, LoopExitBlocks)) return 0; SmallVector ExitingBlocks; LP->getExitingBlocks(ExitingBlocks); // If BFI is set, we do more aggressive promotions based on BFI. if (BFI) return (unsigned)-1; // Not considierered speculative. if (ExitingBlocks.size() == 1) return MaxNumOfPromotionsPerLoop; if (ExitingBlocks.size() > SpeculativeCounterPromotionMaxExiting) return 0; // Whether the target block is in a loop does not matter: if (SpeculativeCounterPromotionToLoop) return MaxNumOfPromotionsPerLoop; // Now check the target block: unsigned MaxProm = MaxNumOfPromotionsPerLoop; for (auto *TargetBlock : LoopExitBlocks) { auto *TargetLoop = LI.getLoopFor(TargetBlock); if (!TargetLoop) continue; unsigned MaxPromForTarget = getMaxNumOfPromotionsInLoop(TargetLoop); unsigned PendingCandsInTarget = LoopToCandidates[TargetLoop].size(); MaxProm = std::min(MaxProm, std::max(MaxPromForTarget, PendingCandsInTarget) - PendingCandsInTarget); } return MaxProm; } DenseMap> &LoopToCandidates; SmallVector ExitBlocks; SmallVector InsertPts; Loop &L; LoopInfo &LI; BlockFrequencyInfo *BFI; }; enum class ValueProfilingCallType { // Individual values are tracked. Currently used for indiret call target // profiling. Default, // MemOp: the memop size value profiling. MemOp }; } // end anonymous namespace PreservedAnalyses InstrProfilingLoweringPass::run(Module &M, ModuleAnalysisManager &AM) { FunctionAnalysisManager &FAM = AM.getResult(M).getManager(); auto GetTLI = [&FAM](Function &F) -> TargetLibraryInfo & { return FAM.getResult(F); }; InstrLowerer Lowerer(M, Options, GetTLI, IsCS); if (!Lowerer.lower()) return PreservedAnalyses::all(); return PreservedAnalyses::none(); } // // Perform instrumentation sampling. // // There are 3 favors of sampling: // (1) Full burst sampling: We transform: // Increment_Instruction; // to: // if (__llvm_profile_sampling__ <= SampledInstrBurstDuration - 1) { // Increment_Instruction; // } // __llvm_profile_sampling__ += 1; // if (__llvm_profile_sampling__ >= SampledInstrPeriod) { // __llvm_profile_sampling__ = 0; // } // // "__llvm_profile_sampling__" is a thread-local global shared by all PGO // counters (value-instrumentation and edge instrumentation). // // (2) Fast burst sampling: // "__llvm_profile_sampling__" variable is an unsigned type, meaning it will // wrap around to zero when overflows. In this case, the second check is // unnecessary, so we won't generate check2 when the SampledInstrPeriod is // set to 65536 (64K). The code after: // if (__llvm_profile_sampling__ <= SampledInstrBurstDuration - 1) { // Increment_Instruction; // } // __llvm_profile_sampling__ += 1; // // (3) Simple sampling: // When SampledInstrBurstDuration is set to 1, we do a simple sampling: // __llvm_profile_sampling__ += 1; // if (__llvm_profile_sampling__ >= SampledInstrPeriod) { // __llvm_profile_sampling__ = 0; // Increment_Instruction; // } // // Note that, the code snippet after the transformation can still be counter // promoted. However, with sampling enabled, counter updates are expected to // be infrequent, making the benefits of counter promotion negligible. // Moreover, counter promotion can potentially cause issues in server // applications, particularly when the counters are dumped without a clean // exit. To mitigate this risk, counter promotion is disabled by default when // sampling is enabled. This behavior can be overridden using the internal // option. void InstrLowerer::doSampling(Instruction *I) { if (!isSamplingEnabled()) return; SampledInstrumentationConfig config = getSampledInstrumentationConfig(); auto GetConstant = [&config](IRBuilder<> &Builder, uint32_t C) { if (config.UseShort) return Builder.getInt16(C); else return Builder.getInt32(C); }; IntegerType *SamplingVarTy; if (config.UseShort) SamplingVarTy = Type::getInt16Ty(M.getContext()); else SamplingVarTy = Type::getInt32Ty(M.getContext()); auto *SamplingVar = M.getGlobalVariable(INSTR_PROF_QUOTE(INSTR_PROF_PROFILE_SAMPLING_VAR)); assert(SamplingVar && "SamplingVar not set properly"); // Create the condition for checking the burst duration. Instruction *SamplingVarIncr; Value *NewSamplingVarVal; MDBuilder MDB(I->getContext()); MDNode *BranchWeight; IRBuilder<> CondBuilder(I); auto *LoadSamplingVar = CondBuilder.CreateLoad(SamplingVarTy, SamplingVar); if (config.IsSimpleSampling) { // For the simple sampling, just create the load and increments. IRBuilder<> IncBuilder(I); NewSamplingVarVal = IncBuilder.CreateAdd(LoadSamplingVar, GetConstant(IncBuilder, 1)); SamplingVarIncr = IncBuilder.CreateStore(NewSamplingVarVal, SamplingVar); } else { // For the burst-sampling, create the conditional update. auto *DurationCond = CondBuilder.CreateICmpULE( LoadSamplingVar, GetConstant(CondBuilder, config.BurstDuration - 1)); BranchWeight = MDB.createBranchWeights( config.BurstDuration, config.Period - config.BurstDuration); Instruction *ThenTerm = SplitBlockAndInsertIfThen( DurationCond, I, /* Unreachable */ false, BranchWeight); IRBuilder<> IncBuilder(I); NewSamplingVarVal = IncBuilder.CreateAdd(LoadSamplingVar, GetConstant(IncBuilder, 1)); SamplingVarIncr = IncBuilder.CreateStore(NewSamplingVarVal, SamplingVar); I->moveBefore(ThenTerm->getIterator()); } if (config.IsFastSampling) return; // Create the condition for checking the period. Instruction *ThenTerm, *ElseTerm; IRBuilder<> PeriodCondBuilder(SamplingVarIncr); auto *PeriodCond = PeriodCondBuilder.CreateICmpUGE( NewSamplingVarVal, GetConstant(PeriodCondBuilder, config.Period)); BranchWeight = MDB.createBranchWeights(1, config.Period - 1); SplitBlockAndInsertIfThenElse(PeriodCond, SamplingVarIncr, &ThenTerm, &ElseTerm, BranchWeight); // For the simple sampling, the counter update happens in sampling var reset. if (config.IsSimpleSampling) I->moveBefore(ThenTerm->getIterator()); IRBuilder<> ResetBuilder(ThenTerm); ResetBuilder.CreateStore(GetConstant(ResetBuilder, 0), SamplingVar); SamplingVarIncr->moveBefore(ElseTerm->getIterator()); } bool InstrLowerer::lowerIntrinsics(Function *F) { bool MadeChange = false; PromotionCandidates.clear(); SmallVector InstrProfInsts; // To ensure compatibility with sampling, we save the intrinsics into // a buffer to prevent potential breakage of the iterator (as the // intrinsics will be moved to a different BB). for (BasicBlock &BB : *F) { for (Instruction &Instr : llvm::make_early_inc_range(BB)) { if (auto *IP = dyn_cast(&Instr)) InstrProfInsts.push_back(IP); } } for (auto *Instr : InstrProfInsts) { doSampling(Instr); if (auto *IPIS = dyn_cast(Instr)) { lowerIncrement(IPIS); MadeChange = true; } else if (auto *IPI = dyn_cast(Instr)) { lowerIncrement(IPI); MadeChange = true; } else if (auto *IPC = dyn_cast(Instr)) { lowerTimestamp(IPC); MadeChange = true; } else if (auto *IPC = dyn_cast(Instr)) { lowerCover(IPC); MadeChange = true; } else if (auto *IPVP = dyn_cast(Instr)) { lowerValueProfileInst(IPVP); MadeChange = true; } else if (auto *IPMP = dyn_cast(Instr)) { IPMP->eraseFromParent(); MadeChange = true; } else if (auto *IPBU = dyn_cast(Instr)) { lowerMCDCTestVectorBitmapUpdate(IPBU); MadeChange = true; } } if (!MadeChange) return false; promoteCounterLoadStores(F); return true; } bool InstrLowerer::isRuntimeCounterRelocationEnabled() const { // Mach-O don't support weak external references. if (TT.isOSBinFormatMachO()) return false; if (RuntimeCounterRelocation.getNumOccurrences() > 0) return RuntimeCounterRelocation; // Fuchsia uses runtime counter relocation by default. return TT.isOSFuchsia(); } bool InstrLowerer::isSamplingEnabled() const { if (SampledInstr.getNumOccurrences() > 0) return SampledInstr; return Options.Sampling; } bool InstrLowerer::isCounterPromotionEnabled() const { if (DoCounterPromotion.getNumOccurrences() > 0) return DoCounterPromotion; return Options.DoCounterPromotion; } void InstrLowerer::promoteCounterLoadStores(Function *F) { if (!isCounterPromotionEnabled()) return; DominatorTree DT(*F); LoopInfo LI(DT); DenseMap> LoopPromotionCandidates; std::unique_ptr BFI; if (Options.UseBFIInPromotion) { std::unique_ptr BPI; BPI.reset(new BranchProbabilityInfo(*F, LI, &GetTLI(*F))); BFI.reset(new BlockFrequencyInfo(*F, *BPI, LI)); } for (const auto &LoadStore : PromotionCandidates) { auto *CounterLoad = LoadStore.first; auto *CounterStore = LoadStore.second; BasicBlock *BB = CounterLoad->getParent(); Loop *ParentLoop = LI.getLoopFor(BB); if (!ParentLoop) continue; LoopPromotionCandidates[ParentLoop].emplace_back(CounterLoad, CounterStore); } SmallVector Loops = LI.getLoopsInPreorder(); // Do a post-order traversal of the loops so that counter updates can be // iteratively hoisted outside the loop nest. for (auto *Loop : llvm::reverse(Loops)) { PGOCounterPromoter Promoter(LoopPromotionCandidates, *Loop, LI, BFI.get()); Promoter.run(&TotalCountersPromoted); } } static bool needsRuntimeHookUnconditionally(const Triple &TT) { // On Fuchsia, we only need runtime hook if any counters are present. if (TT.isOSFuchsia()) return false; return true; } /// Check if the module contains uses of any profiling intrinsics. static bool containsProfilingIntrinsics(Module &M) { auto containsIntrinsic = [&](int ID) { if (auto *F = Intrinsic::getDeclarationIfExists(&M, ID)) return !F->use_empty(); return false; }; return containsIntrinsic(Intrinsic::instrprof_cover) || containsIntrinsic(Intrinsic::instrprof_increment) || containsIntrinsic(Intrinsic::instrprof_increment_step) || containsIntrinsic(Intrinsic::instrprof_timestamp) || containsIntrinsic(Intrinsic::instrprof_value_profile); } bool InstrLowerer::lower() { bool MadeChange = false; bool NeedsRuntimeHook = needsRuntimeHookUnconditionally(TT); if (NeedsRuntimeHook) MadeChange = emitRuntimeHook(); if (!IsCS && isSamplingEnabled()) createProfileSamplingVar(M); bool ContainsProfiling = containsProfilingIntrinsics(M); GlobalVariable *CoverageNamesVar = M.getNamedGlobal(getCoverageUnusedNamesVarName()); // Improve compile time by avoiding linear scans when there is no work. if (!ContainsProfiling && !CoverageNamesVar) return MadeChange; // We did not know how many value sites there would be inside // the instrumented function. This is counting the number of instrumented // target value sites to enter it as field in the profile data variable. for (Function &F : M) { InstrProfCntrInstBase *FirstProfInst = nullptr; for (BasicBlock &BB : F) { for (auto I = BB.begin(), E = BB.end(); I != E; I++) { if (auto *Ind = dyn_cast(I)) computeNumValueSiteCounts(Ind); else { if (FirstProfInst == nullptr && (isa(I) || isa(I))) FirstProfInst = dyn_cast(I); // If the MCDCBitmapParameters intrinsic seen, create the bitmaps. if (const auto &Params = dyn_cast(I)) static_cast(getOrCreateRegionBitmaps(Params)); } } } // Use a profile intrinsic to create the region counters and data variable. // Also create the data variable based on the MCDCParams. if (FirstProfInst != nullptr) { static_cast(getOrCreateRegionCounters(FirstProfInst)); } } if (EnableVTableValueProfiling) for (GlobalVariable &GV : M.globals()) // Global variables with type metadata are virtual table variables. if (GV.hasMetadata(LLVMContext::MD_type)) getOrCreateVTableProfData(&GV); for (Function &F : M) MadeChange |= lowerIntrinsics(&F); if (CoverageNamesVar) { lowerCoverageData(CoverageNamesVar); MadeChange = true; } if (!MadeChange) return false; emitVNodes(); emitNameData(); emitVTableNames(); // Emit runtime hook for the cases where the target does not unconditionally // require pulling in profile runtime, and coverage is enabled on code that is // not eliminated by the front-end, e.g. unused functions with internal // linkage. if (!NeedsRuntimeHook && ContainsProfiling) emitRuntimeHook(); emitRegistration(); emitUses(); emitInitialization(); return true; } static FunctionCallee getOrInsertValueProfilingCall( Module &M, const TargetLibraryInfo &TLI, ValueProfilingCallType CallType = ValueProfilingCallType::Default) { LLVMContext &Ctx = M.getContext(); auto *ReturnTy = Type::getVoidTy(M.getContext()); AttributeList AL; if (auto AK = TLI.getExtAttrForI32Param(false)) AL = AL.addParamAttribute(M.getContext(), 2, AK); assert((CallType == ValueProfilingCallType::Default || CallType == ValueProfilingCallType::MemOp) && "Must be Default or MemOp"); Type *ParamTypes[] = { #define VALUE_PROF_FUNC_PARAM(ParamType, ParamName, ParamLLVMType) ParamLLVMType #include "llvm/ProfileData/InstrProfData.inc" }; auto *ValueProfilingCallTy = FunctionType::get(ReturnTy, ArrayRef(ParamTypes), false); StringRef FuncName = CallType == ValueProfilingCallType::Default ? getInstrProfValueProfFuncName() : getInstrProfValueProfMemOpFuncName(); return M.getOrInsertFunction(FuncName, ValueProfilingCallTy, AL); } void InstrLowerer::computeNumValueSiteCounts(InstrProfValueProfileInst *Ind) { GlobalVariable *Name = Ind->getName(); uint64_t ValueKind = Ind->getValueKind()->getZExtValue(); uint64_t Index = Ind->getIndex()->getZExtValue(); auto &PD = ProfileDataMap[Name]; PD.NumValueSites[ValueKind] = std::max(PD.NumValueSites[ValueKind], (uint32_t)(Index + 1)); } void InstrLowerer::lowerValueProfileInst(InstrProfValueProfileInst *Ind) { // TODO: Value profiling heavily depends on the data section which is omitted // in lightweight mode. We need to move the value profile pointer to the // Counter struct to get this working. assert( !DebugInfoCorrelate && ProfileCorrelate == InstrProfCorrelator::NONE && "Value profiling is not yet supported with lightweight instrumentation"); GlobalVariable *Name = Ind->getName(); auto It = ProfileDataMap.find(Name); assert(It != ProfileDataMap.end() && It->second.DataVar && "value profiling detected in function with no counter incerement"); GlobalVariable *DataVar = It->second.DataVar; uint64_t ValueKind = Ind->getValueKind()->getZExtValue(); uint64_t Index = Ind->getIndex()->getZExtValue(); for (uint32_t Kind = IPVK_First; Kind < ValueKind; ++Kind) Index += It->second.NumValueSites[Kind]; IRBuilder<> Builder(Ind); bool IsMemOpSize = (Ind->getValueKind()->getZExtValue() == llvm::InstrProfValueKind::IPVK_MemOPSize); CallInst *Call = nullptr; auto *TLI = &GetTLI(*Ind->getFunction()); auto *NormalizedDataVarPtr = ConstantExpr::getPointerBitCastOrAddrSpaceCast( DataVar, PointerType::get(M.getContext(), 0)); // To support value profiling calls within Windows exception handlers, funclet // information contained within operand bundles needs to be copied over to // the library call. This is required for the IR to be processed by the // WinEHPrepare pass. SmallVector OpBundles; Ind->getOperandBundlesAsDefs(OpBundles); if (!IsMemOpSize) { Value *Args[3] = {Ind->getTargetValue(), NormalizedDataVarPtr, Builder.getInt32(Index)}; Call = Builder.CreateCall(getOrInsertValueProfilingCall(M, *TLI), Args, OpBundles); } else { Value *Args[3] = {Ind->getTargetValue(), NormalizedDataVarPtr, Builder.getInt32(Index)}; Call = Builder.CreateCall( getOrInsertValueProfilingCall(M, *TLI, ValueProfilingCallType::MemOp), Args, OpBundles); } if (auto AK = TLI->getExtAttrForI32Param(false)) Call->addParamAttr(2, AK); Ind->replaceAllUsesWith(Call); Ind->eraseFromParent(); } GlobalVariable *InstrLowerer::getOrCreateBiasVar(StringRef VarName) { GlobalVariable *Bias = M.getGlobalVariable(VarName); if (Bias) return Bias; Type *Int64Ty = Type::getInt64Ty(M.getContext()); // Compiler must define this variable when runtime counter relocation // is being used. Runtime has a weak external reference that is used // to check whether that's the case or not. Bias = new GlobalVariable(M, Int64Ty, false, GlobalValue::LinkOnceODRLinkage, Constant::getNullValue(Int64Ty), VarName); Bias->setVisibility(GlobalVariable::HiddenVisibility); // A definition that's weak (linkonce_odr) without being in a COMDAT // section wouldn't lead to link errors, but it would lead to a dead // data word from every TU but one. Putting it in COMDAT ensures there // will be exactly one data slot in the link. if (TT.supportsCOMDAT()) Bias->setComdat(M.getOrInsertComdat(VarName)); return Bias; } Value *InstrLowerer::getCounterAddress(InstrProfCntrInstBase *I) { auto *Counters = getOrCreateRegionCounters(I); IRBuilder<> Builder(I); if (isa(I)) Counters->setAlignment(Align(8)); auto *Addr = Builder.CreateConstInBoundsGEP2_32( Counters->getValueType(), Counters, 0, I->getIndex()->getZExtValue()); if (!isRuntimeCounterRelocationEnabled()) return Addr; Type *Int64Ty = Type::getInt64Ty(M.getContext()); Function *Fn = I->getParent()->getParent(); LoadInst *&BiasLI = FunctionToProfileBiasMap[Fn]; if (!BiasLI) { IRBuilder<> EntryBuilder(&Fn->getEntryBlock().front()); auto *Bias = getOrCreateBiasVar(getInstrProfCounterBiasVarName()); BiasLI = EntryBuilder.CreateLoad(Int64Ty, Bias, "profc_bias"); // Bias doesn't change after startup. BiasLI->setMetadata(LLVMContext::MD_invariant_load, MDNode::get(M.getContext(), {})); } auto *Add = Builder.CreateAdd(Builder.CreatePtrToInt(Addr, Int64Ty), BiasLI); return Builder.CreateIntToPtr(Add, Addr->getType()); } Value *InstrLowerer::getBitmapAddress(InstrProfMCDCTVBitmapUpdate *I) { auto *Bitmaps = getOrCreateRegionBitmaps(I); if (!isRuntimeCounterRelocationEnabled()) return Bitmaps; // Put BiasLI onto the entry block. Type *Int64Ty = Type::getInt64Ty(M.getContext()); Function *Fn = I->getFunction(); IRBuilder<> EntryBuilder(&Fn->getEntryBlock().front()); auto *Bias = getOrCreateBiasVar(getInstrProfBitmapBiasVarName()); auto *BiasLI = EntryBuilder.CreateLoad(Int64Ty, Bias, "profbm_bias"); // Assume BiasLI invariant (in the function at least) BiasLI->setMetadata(LLVMContext::MD_invariant_load, MDNode::get(M.getContext(), {})); // Add Bias to Bitmaps and put it before the intrinsic. IRBuilder<> Builder(I); return Builder.CreatePtrAdd(Bitmaps, BiasLI, "profbm_addr"); } void InstrLowerer::lowerCover(InstrProfCoverInst *CoverInstruction) { auto *Addr = getCounterAddress(CoverInstruction); IRBuilder<> Builder(CoverInstruction); if (ConditionalCounterUpdate) { Instruction *SplitBefore = CoverInstruction->getNextNode(); auto &Ctx = CoverInstruction->getParent()->getContext(); auto *Int8Ty = llvm::Type::getInt8Ty(Ctx); Value *Load = Builder.CreateLoad(Int8Ty, Addr, "pgocount"); Value *Cmp = Builder.CreateIsNotNull(Load, "pgocount.ifnonzero"); Instruction *ThenBranch = SplitBlockAndInsertIfThen(Cmp, SplitBefore, false); Builder.SetInsertPoint(ThenBranch); } // We store zero to represent that this block is covered. Builder.CreateStore(Builder.getInt8(0), Addr); CoverInstruction->eraseFromParent(); } void InstrLowerer::lowerTimestamp( InstrProfTimestampInst *TimestampInstruction) { assert(TimestampInstruction->getIndex()->isZeroValue() && "timestamp probes are always the first probe for a function"); auto &Ctx = M.getContext(); auto *TimestampAddr = getCounterAddress(TimestampInstruction); IRBuilder<> Builder(TimestampInstruction); auto *CalleeTy = FunctionType::get(Type::getVoidTy(Ctx), TimestampAddr->getType(), false); auto Callee = M.getOrInsertFunction( INSTR_PROF_QUOTE(INSTR_PROF_PROFILE_SET_TIMESTAMP), CalleeTy); Builder.CreateCall(Callee, {TimestampAddr}); TimestampInstruction->eraseFromParent(); } void InstrLowerer::lowerIncrement(InstrProfIncrementInst *Inc) { auto *Addr = getCounterAddress(Inc); IRBuilder<> Builder(Inc); if (Options.Atomic || AtomicCounterUpdateAll || (Inc->getIndex()->isZeroValue() && AtomicFirstCounter)) { Builder.CreateAtomicRMW(AtomicRMWInst::Add, Addr, Inc->getStep(), MaybeAlign(), AtomicOrdering::Monotonic); } else { Value *IncStep = Inc->getStep(); Value *Load = Builder.CreateLoad(IncStep->getType(), Addr, "pgocount"); auto *Count = Builder.CreateAdd(Load, Inc->getStep()); auto *Store = Builder.CreateStore(Count, Addr); if (isCounterPromotionEnabled()) PromotionCandidates.emplace_back(cast(Load), Store); } Inc->eraseFromParent(); } void InstrLowerer::lowerCoverageData(GlobalVariable *CoverageNamesVar) { ConstantArray *Names = cast(CoverageNamesVar->getInitializer()); for (unsigned I = 0, E = Names->getNumOperands(); I < E; ++I) { Constant *NC = Names->getOperand(I); Value *V = NC->stripPointerCasts(); assert(isa(V) && "Missing reference to function name"); GlobalVariable *Name = cast(V); Name->setLinkage(GlobalValue::PrivateLinkage); ReferencedNames.push_back(Name); if (isa(NC)) NC->dropAllReferences(); } CoverageNamesVar->eraseFromParent(); } void InstrLowerer::lowerMCDCTestVectorBitmapUpdate( InstrProfMCDCTVBitmapUpdate *Update) { auto &Ctx = M.getContext(); IRBuilder<> Builder(Update); auto *Int8Ty = Type::getInt8Ty(Ctx); auto *Int32Ty = Type::getInt32Ty(Ctx); auto *MCDCCondBitmapAddr = Update->getMCDCCondBitmapAddr(); auto *BitmapAddr = getBitmapAddress(Update); // Load Temp Val + BitmapIdx. // %mcdc.temp = load i32, ptr %mcdc.addr, align 4 auto *Temp = Builder.CreateAdd( Builder.CreateLoad(Int32Ty, MCDCCondBitmapAddr, "mcdc.temp"), Update->getBitmapIndex()); // Calculate byte offset using div8. // %1 = lshr i32 %mcdc.temp, 3 auto *BitmapByteOffset = Builder.CreateLShr(Temp, 0x3); // Add byte offset to section base byte address. // %4 = getelementptr inbounds i8, ptr @__profbm_test, i32 %1 auto *BitmapByteAddr = Builder.CreateInBoundsPtrAdd(BitmapAddr, BitmapByteOffset); // Calculate bit offset into bitmap byte by using div8 remainder (AND ~8) // %5 = and i32 %mcdc.temp, 7 // %6 = trunc i32 %5 to i8 auto *BitToSet = Builder.CreateTrunc(Builder.CreateAnd(Temp, 0x7), Int8Ty); // Shift bit offset left to form a bitmap. // %7 = shl i8 1, %6 auto *ShiftedVal = Builder.CreateShl(Builder.getInt8(0x1), BitToSet); // Load profile bitmap byte. // %mcdc.bits = load i8, ptr %4, align 1 auto *Bitmap = Builder.CreateLoad(Int8Ty, BitmapByteAddr, "mcdc.bits"); if (Options.Atomic || AtomicCounterUpdateAll) { // If ((Bitmap & Val) != Val), then execute atomic (Bitmap |= Val). // Note, just-loaded Bitmap might not be up-to-date. Use it just for // early testing. auto *Masked = Builder.CreateAnd(Bitmap, ShiftedVal); auto *ShouldStore = Builder.CreateICmpNE(Masked, ShiftedVal); // Assume updating will be rare. auto *Unlikely = MDBuilder(Ctx).createUnlikelyBranchWeights(); Instruction *ThenBranch = SplitBlockAndInsertIfThen(ShouldStore, Update, false, Unlikely); // Execute if (unlikely(ShouldStore)). Builder.SetInsertPoint(ThenBranch); Builder.CreateAtomicRMW(AtomicRMWInst::Or, BitmapByteAddr, ShiftedVal, MaybeAlign(), AtomicOrdering::Monotonic); } else { // Perform logical OR of profile bitmap byte and shifted bit offset. // %8 = or i8 %mcdc.bits, %7 auto *Result = Builder.CreateOr(Bitmap, ShiftedVal); // Store the updated profile bitmap byte. // store i8 %8, ptr %3, align 1 Builder.CreateStore(Result, BitmapByteAddr); } Update->eraseFromParent(); } /// Get the name of a profiling variable for a particular function. static std::string getVarName(InstrProfInstBase *Inc, StringRef Prefix, bool &Renamed) { StringRef NamePrefix = getInstrProfNameVarPrefix(); StringRef Name = Inc->getName()->getName().substr(NamePrefix.size()); Function *F = Inc->getParent()->getParent(); Module *M = F->getParent(); if (!DoHashBasedCounterSplit || !isIRPGOFlagSet(M) || !canRenameComdatFunc(*F)) { Renamed = false; return (Prefix + Name).str(); } Renamed = true; uint64_t FuncHash = Inc->getHash()->getZExtValue(); SmallVector HashPostfix; if (Name.ends_with((Twine(".") + Twine(FuncHash)).toStringRef(HashPostfix))) return (Prefix + Name).str(); return (Prefix + Name + "." + Twine(FuncHash)).str(); } static inline bool shouldRecordFunctionAddr(Function *F) { // Only record function addresses if IR PGO is enabled or if clang value // profiling is enabled. Recording function addresses greatly increases object // file size, because it prevents the inliner from deleting functions that // have been inlined everywhere. if (!profDataReferencedByCode(*F->getParent())) return false; // Check the linkage bool HasAvailableExternallyLinkage = F->hasAvailableExternallyLinkage(); if (!F->hasLinkOnceLinkage() && !F->hasLocalLinkage() && !HasAvailableExternallyLinkage) return true; // A function marked 'alwaysinline' with available_externally linkage can't // have its address taken. Doing so would create an undefined external ref to // the function, which would fail to link. if (HasAvailableExternallyLinkage && F->hasFnAttribute(Attribute::AlwaysInline)) return false; // Prohibit function address recording if the function is both internal and // COMDAT. This avoids the profile data variable referencing internal symbols // in COMDAT. if (F->hasLocalLinkage() && F->hasComdat()) return false; // Check uses of this function for other than direct calls or invokes to it. // Inline virtual functions have linkeOnceODR linkage. When a key method // exists, the vtable will only be emitted in the TU where the key method // is defined. In a TU where vtable is not available, the function won't // be 'addresstaken'. If its address is not recorded here, the profile data // with missing address may be picked by the linker leading to missing // indirect call target info. return F->hasAddressTaken() || F->hasLinkOnceLinkage(); } static inline bool shouldUsePublicSymbol(Function *Fn) { // It isn't legal to make an alias of this function at all if (Fn->isDeclarationForLinker()) return true; // Symbols with local linkage can just use the symbol directly without // introducing relocations if (Fn->hasLocalLinkage()) return true; // PGO + ThinLTO + CFI cause duplicate symbols to be introduced due to some // unfavorable interaction between the new alias and the alias renaming done // in LowerTypeTests under ThinLTO. For comdat functions that would normally // be deduplicated, but the renaming scheme ends up preventing renaming, since // it creates unique names for each alias, resulting in duplicated symbols. In // the future, we should update the CFI related passes to migrate these // aliases to the same module as the jump-table they refer to will be defined. if (Fn->hasMetadata(LLVMContext::MD_type)) return true; // For comdat functions, an alias would need the same linkage as the original // function and hidden visibility. There is no point in adding an alias with // identical linkage an visibility to avoid introducing symbolic relocations. if (Fn->hasComdat() && (Fn->getVisibility() == GlobalValue::VisibilityTypes::HiddenVisibility)) return true; // its OK to use an alias return false; } static inline Constant *getFuncAddrForProfData(Function *Fn) { auto *Int8PtrTy = PointerType::getUnqual(Fn->getContext()); // Store a nullptr in __llvm_profd, if we shouldn't use a real address if (!shouldRecordFunctionAddr(Fn)) return ConstantPointerNull::get(Int8PtrTy); // If we can't use an alias, we must use the public symbol, even though this // may require a symbolic relocation. if (shouldUsePublicSymbol(Fn)) return Fn; // When possible use a private alias to avoid symbolic relocations. auto *GA = GlobalAlias::create(GlobalValue::LinkageTypes::PrivateLinkage, Fn->getName() + ".local", Fn); // When the instrumented function is a COMDAT function, we cannot use a // private alias. If we did, we would create reference to a local label in // this function's section. If this version of the function isn't selected by // the linker, then the metadata would introduce a reference to a discarded // section. So, for COMDAT functions, we need to adjust the linkage of the // alias. Using hidden visibility avoids a dynamic relocation and an entry in // the dynamic symbol table. // // Note that this handles COMDAT functions with visibility other than Hidden, // since that case is covered in shouldUsePublicSymbol() if (Fn->hasComdat()) { GA->setLinkage(Fn->getLinkage()); GA->setVisibility(GlobalValue::VisibilityTypes::HiddenVisibility); } // appendToCompilerUsed(*Fn->getParent(), {GA}); return GA; } static bool needsRuntimeRegistrationOfSectionRange(const Triple &TT) { // compiler-rt uses linker support to get data/counters/name start/end for // ELF, COFF, Mach-O, XCOFF, and Wasm. if (TT.isOSBinFormatELF() || TT.isOSBinFormatCOFF() || TT.isOSBinFormatMachO() || TT.isOSBinFormatXCOFF() || TT.isOSBinFormatWasm()) return false; return true; } void InstrLowerer::maybeSetComdat(GlobalVariable *GV, GlobalObject *GO, StringRef CounterGroupName) { // Place lowered global variables in a comdat group if the associated function // or global variable is a COMDAT. This will make sure that only one copy of // global variable (e.g. function counters) of the COMDAT function will be // emitted after linking. bool NeedComdat = needsComdatForCounter(*GO, M); bool UseComdat = (NeedComdat || TT.isOSBinFormatELF()); if (!UseComdat) return; // Keep in mind that this pass may run before the inliner, so we need to // create a new comdat group (for counters, profiling data, etc). If we use // the comdat of the parent function, that will result in relocations against // discarded sections. // // If the data variable is referenced by code, non-counter variables (notably // profiling data) and counters have to be in different comdats for COFF // because the Visual C++ linker will report duplicate symbol errors if there // are multiple external symbols with the same name marked // IMAGE_COMDAT_SELECT_ASSOCIATIVE. StringRef GroupName = TT.isOSBinFormatCOFF() && DataReferencedByCode ? GV->getName() : CounterGroupName; Comdat *C = M.getOrInsertComdat(GroupName); if (!NeedComdat) { // Object file format must be ELF since `UseComdat && !NeedComdat` is true. // // For ELF, when not using COMDAT, put counters, data and values into a // nodeduplicate COMDAT which is lowered to a zero-flag section group. This // allows -z start-stop-gc to discard the entire group when the function is // discarded. C->setSelectionKind(Comdat::NoDeduplicate); } GV->setComdat(C); // COFF doesn't allow the comdat group leader to have private linkage, so // upgrade private linkage to internal linkage to produce a symbol table // entry. if (TT.isOSBinFormatCOFF() && GV->hasPrivateLinkage()) GV->setLinkage(GlobalValue::InternalLinkage); } static inline bool shouldRecordVTableAddr(GlobalVariable *GV) { if (!profDataReferencedByCode(*GV->getParent())) return false; if (!GV->hasLinkOnceLinkage() && !GV->hasLocalLinkage() && !GV->hasAvailableExternallyLinkage()) return true; // This avoids the profile data from referencing internal symbols in // COMDAT. if (GV->hasLocalLinkage() && GV->hasComdat()) return false; return true; } // FIXME: Introduce an internal alias like what's done for functions to reduce // the number of relocation entries. static inline Constant *getVTableAddrForProfData(GlobalVariable *GV) { // Store a nullptr in __profvt_ if a real address shouldn't be used. if (!shouldRecordVTableAddr(GV)) return ConstantPointerNull::get(PointerType::getUnqual(GV->getContext())); return GV; } void InstrLowerer::getOrCreateVTableProfData(GlobalVariable *GV) { assert(!DebugInfoCorrelate && "Value profiling is not supported with lightweight instrumentation"); if (GV->isDeclaration() || GV->hasAvailableExternallyLinkage()) return; // Skip llvm internal global variable or __prof variables. if (GV->getName().starts_with("llvm.") || GV->getName().starts_with("__llvm") || GV->getName().starts_with("__prof")) return; // VTableProfData already created auto It = VTableDataMap.find(GV); if (It != VTableDataMap.end() && It->second) return; GlobalValue::LinkageTypes Linkage = GV->getLinkage(); GlobalValue::VisibilityTypes Visibility = GV->getVisibility(); // This is to keep consistent with per-function profile data // for correctness. if (TT.isOSBinFormatXCOFF()) { Linkage = GlobalValue::InternalLinkage; Visibility = GlobalValue::DefaultVisibility; } LLVMContext &Ctx = M.getContext(); Type *DataTypes[] = { #define INSTR_PROF_VTABLE_DATA(Type, LLVMType, Name, Init) LLVMType, #include "llvm/ProfileData/InstrProfData.inc" #undef INSTR_PROF_VTABLE_DATA }; auto *DataTy = StructType::get(Ctx, ArrayRef(DataTypes)); // Used by INSTR_PROF_VTABLE_DATA MACRO Constant *VTableAddr = getVTableAddrForProfData(GV); const std::string PGOVTableName = getPGOName(*GV); // Record the length of the vtable. This is needed since vtable pointers // loaded from C++ objects might be from the middle of a vtable definition. uint32_t VTableSizeVal = M.getDataLayout().getTypeAllocSize(GV->getValueType()); Constant *DataVals[] = { #define INSTR_PROF_VTABLE_DATA(Type, LLVMType, Name, Init) Init, #include "llvm/ProfileData/InstrProfData.inc" #undef INSTR_PROF_VTABLE_DATA }; auto *Data = new GlobalVariable(M, DataTy, /*constant=*/false, Linkage, ConstantStruct::get(DataTy, DataVals), getInstrProfVTableVarPrefix() + PGOVTableName); Data->setVisibility(Visibility); Data->setSection(getInstrProfSectionName(IPSK_vtab, TT.getObjectFormat())); Data->setAlignment(Align(8)); maybeSetComdat(Data, GV, Data->getName()); VTableDataMap[GV] = Data; ReferencedVTables.push_back(GV); // VTable is used by runtime but not referenced by other // sections. Conservatively mark it linker retained. UsedVars.push_back(Data); } GlobalVariable *InstrLowerer::setupProfileSection(InstrProfInstBase *Inc, InstrProfSectKind IPSK) { GlobalVariable *NamePtr = Inc->getName(); // Match the linkage and visibility of the name global. Function *Fn = Inc->getParent()->getParent(); GlobalValue::LinkageTypes Linkage = NamePtr->getLinkage(); GlobalValue::VisibilityTypes Visibility = NamePtr->getVisibility(); // Use internal rather than private linkage so the counter variable shows up // in the symbol table when using debug info for correlation. if ((DebugInfoCorrelate || ProfileCorrelate == InstrProfCorrelator::DEBUG_INFO) && TT.isOSBinFormatMachO() && Linkage == GlobalValue::PrivateLinkage) Linkage = GlobalValue::InternalLinkage; // Due to the limitation of binder as of 2021/09/28, the duplicate weak // symbols in the same csect won't be discarded. When there are duplicate weak // symbols, we can NOT guarantee that the relocations get resolved to the // intended weak symbol, so we can not ensure the correctness of the relative // CounterPtr, so we have to use private linkage for counter and data symbols. if (TT.isOSBinFormatXCOFF()) { Linkage = GlobalValue::PrivateLinkage; Visibility = GlobalValue::DefaultVisibility; } // Move the name variable to the right section. bool Renamed; GlobalVariable *Ptr; StringRef VarPrefix; std::string VarName; if (IPSK == IPSK_cnts) { VarPrefix = getInstrProfCountersVarPrefix(); VarName = getVarName(Inc, VarPrefix, Renamed); InstrProfCntrInstBase *CntrIncrement = dyn_cast(Inc); Ptr = createRegionCounters(CntrIncrement, VarName, Linkage); } else if (IPSK == IPSK_bitmap) { VarPrefix = getInstrProfBitmapVarPrefix(); VarName = getVarName(Inc, VarPrefix, Renamed); InstrProfMCDCBitmapInstBase *BitmapUpdate = dyn_cast(Inc); Ptr = createRegionBitmaps(BitmapUpdate, VarName, Linkage); } else { llvm_unreachable("Profile Section must be for Counters or Bitmaps"); } Ptr->setVisibility(Visibility); // Put the counters and bitmaps in their own sections so linkers can // remove unneeded sections. Ptr->setSection(getInstrProfSectionName(IPSK, TT.getObjectFormat())); Ptr->setLinkage(Linkage); maybeSetComdat(Ptr, Fn, VarName); return Ptr; } GlobalVariable * InstrLowerer::createRegionBitmaps(InstrProfMCDCBitmapInstBase *Inc, StringRef Name, GlobalValue::LinkageTypes Linkage) { uint64_t NumBytes = Inc->getNumBitmapBytes(); auto *BitmapTy = ArrayType::get(Type::getInt8Ty(M.getContext()), NumBytes); auto GV = new GlobalVariable(M, BitmapTy, false, Linkage, Constant::getNullValue(BitmapTy), Name); GV->setAlignment(Align(1)); return GV; } GlobalVariable * InstrLowerer::getOrCreateRegionBitmaps(InstrProfMCDCBitmapInstBase *Inc) { GlobalVariable *NamePtr = Inc->getName(); auto &PD = ProfileDataMap[NamePtr]; if (PD.RegionBitmaps) return PD.RegionBitmaps; // If RegionBitmaps doesn't already exist, create it by first setting up // the corresponding profile section. auto *BitmapPtr = setupProfileSection(Inc, IPSK_bitmap); PD.RegionBitmaps = BitmapPtr; PD.NumBitmapBytes = Inc->getNumBitmapBytes(); return PD.RegionBitmaps; } GlobalVariable * InstrLowerer::createRegionCounters(InstrProfCntrInstBase *Inc, StringRef Name, GlobalValue::LinkageTypes Linkage) { uint64_t NumCounters = Inc->getNumCounters()->getZExtValue(); auto &Ctx = M.getContext(); GlobalVariable *GV; if (isa(Inc)) { auto *CounterTy = Type::getInt8Ty(Ctx); auto *CounterArrTy = ArrayType::get(CounterTy, NumCounters); // TODO: `Constant::getAllOnesValue()` does not yet accept an array type. std::vector InitialValues(NumCounters, Constant::getAllOnesValue(CounterTy)); GV = new GlobalVariable(M, CounterArrTy, false, Linkage, ConstantArray::get(CounterArrTy, InitialValues), Name); GV->setAlignment(Align(1)); } else { auto *CounterTy = ArrayType::get(Type::getInt64Ty(Ctx), NumCounters); GV = new GlobalVariable(M, CounterTy, false, Linkage, Constant::getNullValue(CounterTy), Name); GV->setAlignment(Align(8)); } return GV; } GlobalVariable * InstrLowerer::getOrCreateRegionCounters(InstrProfCntrInstBase *Inc) { GlobalVariable *NamePtr = Inc->getName(); auto &PD = ProfileDataMap[NamePtr]; if (PD.RegionCounters) return PD.RegionCounters; // If RegionCounters doesn't already exist, create it by first setting up // the corresponding profile section. auto *CounterPtr = setupProfileSection(Inc, IPSK_cnts); PD.RegionCounters = CounterPtr; if (DebugInfoCorrelate || ProfileCorrelate == InstrProfCorrelator::DEBUG_INFO) { LLVMContext &Ctx = M.getContext(); Function *Fn = Inc->getParent()->getParent(); if (auto *SP = Fn->getSubprogram()) { DIBuilder DB(M, true, SP->getUnit()); Metadata *FunctionNameAnnotation[] = { MDString::get(Ctx, InstrProfCorrelator::FunctionNameAttributeName), MDString::get(Ctx, getPGOFuncNameVarInitializer(NamePtr)), }; Metadata *CFGHashAnnotation[] = { MDString::get(Ctx, InstrProfCorrelator::CFGHashAttributeName), ConstantAsMetadata::get(Inc->getHash()), }; Metadata *NumCountersAnnotation[] = { MDString::get(Ctx, InstrProfCorrelator::NumCountersAttributeName), ConstantAsMetadata::get(Inc->getNumCounters()), }; auto Annotations = DB.getOrCreateArray({ MDNode::get(Ctx, FunctionNameAnnotation), MDNode::get(Ctx, CFGHashAnnotation), MDNode::get(Ctx, NumCountersAnnotation), }); auto *DICounter = DB.createGlobalVariableExpression( SP, CounterPtr->getName(), /*LinkageName=*/StringRef(), SP->getFile(), /*LineNo=*/0, DB.createUnspecifiedType("Profile Data Type"), CounterPtr->hasLocalLinkage(), /*IsDefined=*/true, /*Expr=*/nullptr, /*Decl=*/nullptr, /*TemplateParams=*/nullptr, /*AlignInBits=*/0, Annotations); CounterPtr->addDebugInfo(DICounter); DB.finalize(); } // Mark the counter variable as used so that it isn't optimized out. CompilerUsedVars.push_back(PD.RegionCounters); } // Create the data variable (if it doesn't already exist). createDataVariable(Inc); return PD.RegionCounters; } void InstrLowerer::createDataVariable(InstrProfCntrInstBase *Inc) { // When debug information is correlated to profile data, a data variable // is not needed. if (DebugInfoCorrelate || ProfileCorrelate == InstrProfCorrelator::DEBUG_INFO) return; GlobalVariable *NamePtr = Inc->getName(); auto &PD = ProfileDataMap[NamePtr]; // Return if data variable was already created. if (PD.DataVar) return; LLVMContext &Ctx = M.getContext(); Function *Fn = Inc->getParent()->getParent(); GlobalValue::LinkageTypes Linkage = NamePtr->getLinkage(); GlobalValue::VisibilityTypes Visibility = NamePtr->getVisibility(); // Due to the limitation of binder as of 2021/09/28, the duplicate weak // symbols in the same csect won't be discarded. When there are duplicate weak // symbols, we can NOT guarantee that the relocations get resolved to the // intended weak symbol, so we can not ensure the correctness of the relative // CounterPtr, so we have to use private linkage for counter and data symbols. if (TT.isOSBinFormatXCOFF()) { Linkage = GlobalValue::PrivateLinkage; Visibility = GlobalValue::DefaultVisibility; } bool NeedComdat = needsComdatForCounter(*Fn, M); bool Renamed; // The Data Variable section is anchored to profile counters. std::string CntsVarName = getVarName(Inc, getInstrProfCountersVarPrefix(), Renamed); std::string DataVarName = getVarName(Inc, getInstrProfDataVarPrefix(), Renamed); auto *Int8PtrTy = PointerType::getUnqual(Ctx); // Allocate statically the array of pointers to value profile nodes for // the current function. Constant *ValuesPtrExpr = ConstantPointerNull::get(Int8PtrTy); uint64_t NS = 0; for (uint32_t Kind = IPVK_First; Kind <= IPVK_Last; ++Kind) NS += PD.NumValueSites[Kind]; if (NS > 0 && ValueProfileStaticAlloc && !needsRuntimeRegistrationOfSectionRange(TT)) { ArrayType *ValuesTy = ArrayType::get(Type::getInt64Ty(Ctx), NS); auto *ValuesVar = new GlobalVariable( M, ValuesTy, false, Linkage, Constant::getNullValue(ValuesTy), getVarName(Inc, getInstrProfValuesVarPrefix(), Renamed)); ValuesVar->setVisibility(Visibility); setGlobalVariableLargeSection(TT, *ValuesVar); ValuesVar->setSection( getInstrProfSectionName(IPSK_vals, TT.getObjectFormat())); ValuesVar->setAlignment(Align(8)); maybeSetComdat(ValuesVar, Fn, CntsVarName); ValuesPtrExpr = ConstantExpr::getPointerBitCastOrAddrSpaceCast( ValuesVar, PointerType::get(Fn->getContext(), 0)); } uint64_t NumCounters = Inc->getNumCounters()->getZExtValue(); auto *CounterPtr = PD.RegionCounters; uint64_t NumBitmapBytes = PD.NumBitmapBytes; // Create data variable. auto *IntPtrTy = M.getDataLayout().getIntPtrType(M.getContext()); auto *Int16Ty = Type::getInt16Ty(Ctx); auto *Int16ArrayTy = ArrayType::get(Int16Ty, IPVK_Last + 1); Type *DataTypes[] = { #define INSTR_PROF_DATA(Type, LLVMType, Name, Init) LLVMType, #include "llvm/ProfileData/InstrProfData.inc" }; auto *DataTy = StructType::get(Ctx, ArrayRef(DataTypes)); Constant *FunctionAddr = getFuncAddrForProfData(Fn); Constant *Int16ArrayVals[IPVK_Last + 1]; for (uint32_t Kind = IPVK_First; Kind <= IPVK_Last; ++Kind) Int16ArrayVals[Kind] = ConstantInt::get(Int16Ty, PD.NumValueSites[Kind]); if (isGPUProfTarget(M)) { Linkage = GlobalValue::ExternalLinkage; Visibility = GlobalValue::ProtectedVisibility; } // If the data variable is not referenced by code (if we don't emit // @llvm.instrprof.value.profile, NS will be 0), and the counter keeps the // data variable live under linker GC, the data variable can be private. This // optimization applies to ELF. // // On COFF, a comdat leader cannot be local so we require DataReferencedByCode // to be false. // // If profd is in a deduplicate comdat, NS==0 with a hash suffix guarantees // that other copies must have the same CFG and cannot have value profiling. // If no hash suffix, other profd copies may be referenced by code. else if (NS == 0 && !(DataReferencedByCode && NeedComdat && !Renamed) && (TT.isOSBinFormatELF() || (!DataReferencedByCode && TT.isOSBinFormatCOFF()))) { Linkage = GlobalValue::PrivateLinkage; Visibility = GlobalValue::DefaultVisibility; } auto *Data = new GlobalVariable(M, DataTy, false, Linkage, nullptr, DataVarName); Constant *RelativeCounterPtr; GlobalVariable *BitmapPtr = PD.RegionBitmaps; Constant *RelativeBitmapPtr = ConstantInt::get(IntPtrTy, 0); InstrProfSectKind DataSectionKind; // With binary profile correlation, profile data is not loaded into memory. // profile data must reference profile counter with an absolute relocation. if (ProfileCorrelate == InstrProfCorrelator::BINARY) { DataSectionKind = IPSK_covdata; RelativeCounterPtr = ConstantExpr::getPtrToInt(CounterPtr, IntPtrTy); if (BitmapPtr != nullptr) RelativeBitmapPtr = ConstantExpr::getPtrToInt(BitmapPtr, IntPtrTy); } else { // Reference the counter variable with a label difference (link-time // constant). DataSectionKind = IPSK_data; RelativeCounterPtr = ConstantExpr::getSub(ConstantExpr::getPtrToInt(CounterPtr, IntPtrTy), ConstantExpr::getPtrToInt(Data, IntPtrTy)); if (BitmapPtr != nullptr) RelativeBitmapPtr = ConstantExpr::getSub(ConstantExpr::getPtrToInt(BitmapPtr, IntPtrTy), ConstantExpr::getPtrToInt(Data, IntPtrTy)); } Constant *DataVals[] = { #define INSTR_PROF_DATA(Type, LLVMType, Name, Init) Init, #include "llvm/ProfileData/InstrProfData.inc" }; Data->setInitializer(ConstantStruct::get(DataTy, DataVals)); Data->setVisibility(Visibility); Data->setSection( getInstrProfSectionName(DataSectionKind, TT.getObjectFormat())); Data->setAlignment(Align(INSTR_PROF_DATA_ALIGNMENT)); maybeSetComdat(Data, Fn, CntsVarName); PD.DataVar = Data; // Mark the data variable as used so that it isn't stripped out. CompilerUsedVars.push_back(Data); // Now that the linkage set by the FE has been passed to the data and counter // variables, reset Name variable's linkage and visibility to private so that // it can be removed later by the compiler. NamePtr->setLinkage(GlobalValue::PrivateLinkage); // Collect the referenced names to be used by emitNameData. ReferencedNames.push_back(NamePtr); } void InstrLowerer::emitVNodes() { if (!ValueProfileStaticAlloc) return; // For now only support this on platforms that do // not require runtime registration to discover // named section start/end. if (needsRuntimeRegistrationOfSectionRange(TT)) return; size_t TotalNS = 0; for (auto &PD : ProfileDataMap) { for (uint32_t Kind = IPVK_First; Kind <= IPVK_Last; ++Kind) TotalNS += PD.second.NumValueSites[Kind]; } if (!TotalNS) return; uint64_t NumCounters = TotalNS * NumCountersPerValueSite; // Heuristic for small programs with very few total value sites. // The default value of vp-counters-per-site is chosen based on // the observation that large apps usually have a low percentage // of value sites that actually have any profile data, and thus // the average number of counters per site is low. For small // apps with very few sites, this may not be true. Bump up the // number of counters in this case. #define INSTR_PROF_MIN_VAL_COUNTS 10 if (NumCounters < INSTR_PROF_MIN_VAL_COUNTS) NumCounters = std::max(INSTR_PROF_MIN_VAL_COUNTS, (int)NumCounters * 2); auto &Ctx = M.getContext(); Type *VNodeTypes[] = { #define INSTR_PROF_VALUE_NODE(Type, LLVMType, Name, Init) LLVMType, #include "llvm/ProfileData/InstrProfData.inc" }; auto *VNodeTy = StructType::get(Ctx, ArrayRef(VNodeTypes)); ArrayType *VNodesTy = ArrayType::get(VNodeTy, NumCounters); auto *VNodesVar = new GlobalVariable( M, VNodesTy, false, GlobalValue::PrivateLinkage, Constant::getNullValue(VNodesTy), getInstrProfVNodesVarName()); setGlobalVariableLargeSection(TT, *VNodesVar); VNodesVar->setSection( getInstrProfSectionName(IPSK_vnodes, TT.getObjectFormat())); VNodesVar->setAlignment(M.getDataLayout().getABITypeAlign(VNodesTy)); // VNodesVar is used by runtime but not referenced via relocation by other // sections. Conservatively make it linker retained. UsedVars.push_back(VNodesVar); } void InstrLowerer::emitNameData() { if (ReferencedNames.empty()) return; std::string CompressedNameStr; if (Error E = collectPGOFuncNameStrings(ReferencedNames, CompressedNameStr, DoInstrProfNameCompression)) { report_fatal_error(Twine(toString(std::move(E))), false); } auto &Ctx = M.getContext(); auto *NamesVal = ConstantDataArray::getString(Ctx, StringRef(CompressedNameStr), false); NamesVar = new GlobalVariable(M, NamesVal->getType(), true, GlobalValue::PrivateLinkage, NamesVal, getInstrProfNamesVarName()); NamesSize = CompressedNameStr.size(); setGlobalVariableLargeSection(TT, *NamesVar); NamesVar->setSection( ProfileCorrelate == InstrProfCorrelator::BINARY ? getInstrProfSectionName(IPSK_covname, TT.getObjectFormat()) : getInstrProfSectionName(IPSK_name, TT.getObjectFormat())); // On COFF, it's important to reduce the alignment down to 1 to prevent the // linker from inserting padding before the start of the names section or // between names entries. NamesVar->setAlignment(Align(1)); // NamesVar is used by runtime but not referenced via relocation by other // sections. Conservatively make it linker retained. UsedVars.push_back(NamesVar); for (auto *NamePtr : ReferencedNames) NamePtr->eraseFromParent(); } void InstrLowerer::emitVTableNames() { if (!EnableVTableValueProfiling || ReferencedVTables.empty()) return; // Collect the PGO names of referenced vtables and compress them. std::string CompressedVTableNames; if (Error E = collectVTableStrings(ReferencedVTables, CompressedVTableNames, DoInstrProfNameCompression)) { report_fatal_error(Twine(toString(std::move(E))), false); } auto &Ctx = M.getContext(); auto *VTableNamesVal = ConstantDataArray::getString( Ctx, StringRef(CompressedVTableNames), false /* AddNull */); GlobalVariable *VTableNamesVar = new GlobalVariable(M, VTableNamesVal->getType(), true /* constant */, GlobalValue::PrivateLinkage, VTableNamesVal, getInstrProfVTableNamesVarName()); VTableNamesVar->setSection( getInstrProfSectionName(IPSK_vname, TT.getObjectFormat())); VTableNamesVar->setAlignment(Align(1)); // Make VTableNames linker retained. UsedVars.push_back(VTableNamesVar); } void InstrLowerer::emitRegistration() { if (!needsRuntimeRegistrationOfSectionRange(TT)) return; // Construct the function. auto *VoidTy = Type::getVoidTy(M.getContext()); auto *VoidPtrTy = PointerType::getUnqual(M.getContext()); auto *Int64Ty = Type::getInt64Ty(M.getContext()); auto *RegisterFTy = FunctionType::get(VoidTy, false); auto *RegisterF = Function::Create(RegisterFTy, GlobalValue::InternalLinkage, getInstrProfRegFuncsName(), M); RegisterF->setUnnamedAddr(GlobalValue::UnnamedAddr::Global); if (Options.NoRedZone) RegisterF->addFnAttr(Attribute::NoRedZone); auto *RuntimeRegisterTy = FunctionType::get(VoidTy, VoidPtrTy, false); auto *RuntimeRegisterF = Function::Create(RuntimeRegisterTy, GlobalVariable::ExternalLinkage, getInstrProfRegFuncName(), M); IRBuilder<> IRB(BasicBlock::Create(M.getContext(), "", RegisterF)); for (Value *Data : CompilerUsedVars) if (!isa(Data)) // Check for addrspace cast when profiling GPU IRB.CreateCall(RuntimeRegisterF, IRB.CreatePointerBitCastOrAddrSpaceCast(Data, VoidPtrTy)); for (Value *Data : UsedVars) if (Data != NamesVar && !isa(Data)) IRB.CreateCall(RuntimeRegisterF, IRB.CreatePointerBitCastOrAddrSpaceCast(Data, VoidPtrTy)); if (NamesVar) { Type *ParamTypes[] = {VoidPtrTy, Int64Ty}; auto *NamesRegisterTy = FunctionType::get(VoidTy, ArrayRef(ParamTypes), false); auto *NamesRegisterF = Function::Create(NamesRegisterTy, GlobalVariable::ExternalLinkage, getInstrProfNamesRegFuncName(), M); IRB.CreateCall(NamesRegisterF, {IRB.CreatePointerBitCastOrAddrSpaceCast( NamesVar, VoidPtrTy), IRB.getInt64(NamesSize)}); } IRB.CreateRetVoid(); } bool InstrLowerer::emitRuntimeHook() { // We expect the linker to be invoked with -u flag for Linux // in which case there is no need to emit the external variable. if (TT.isOSLinux() || TT.isOSAIX()) return false; // If the module's provided its own runtime, we don't need to do anything. if (M.getGlobalVariable(getInstrProfRuntimeHookVarName())) return false; // Declare an external variable that will pull in the runtime initialization. auto *Int32Ty = Type::getInt32Ty(M.getContext()); auto *Var = new GlobalVariable(M, Int32Ty, false, GlobalValue::ExternalLinkage, nullptr, getInstrProfRuntimeHookVarName()); if (isGPUProfTarget(M)) Var->setVisibility(GlobalValue::ProtectedVisibility); else Var->setVisibility(GlobalValue::HiddenVisibility); if (TT.isOSBinFormatELF() && !TT.isPS()) { // Mark the user variable as used so that it isn't stripped out. CompilerUsedVars.push_back(Var); } else { // Make a function that uses it. auto *User = Function::Create(FunctionType::get(Int32Ty, false), GlobalValue::LinkOnceODRLinkage, getInstrProfRuntimeHookVarUseFuncName(), M); User->addFnAttr(Attribute::NoInline); if (Options.NoRedZone) User->addFnAttr(Attribute::NoRedZone); User->setVisibility(GlobalValue::HiddenVisibility); if (TT.supportsCOMDAT()) User->setComdat(M.getOrInsertComdat(User->getName())); IRBuilder<> IRB(BasicBlock::Create(M.getContext(), "", User)); auto *Load = IRB.CreateLoad(Int32Ty, Var); IRB.CreateRet(Load); // Mark the function as used so that it isn't stripped out. CompilerUsedVars.push_back(User); } return true; } void InstrLowerer::emitUses() { // The metadata sections are parallel arrays. Optimizers (e.g. // GlobalOpt/ConstantMerge) may not discard associated sections as a unit, so // we conservatively retain all unconditionally in the compiler. // // On ELF and Mach-O, the linker can guarantee the associated sections will be // retained or discarded as a unit, so llvm.compiler.used is sufficient. // Similarly on COFF, if prof data is not referenced by code we use one comdat // and ensure this GC property as well. Otherwise, we have to conservatively // make all of the sections retained by the linker. if (TT.isOSBinFormatELF() || TT.isOSBinFormatMachO() || (TT.isOSBinFormatCOFF() && !DataReferencedByCode)) appendToCompilerUsed(M, CompilerUsedVars); else appendToUsed(M, CompilerUsedVars); // We do not add proper references from used metadata sections to NamesVar and // VNodesVar, so we have to be conservative and place them in llvm.used // regardless of the target, appendToUsed(M, UsedVars); } void InstrLowerer::emitInitialization() { // Create ProfileFileName variable. Don't don't this for the // context-sensitive instrumentation lowering: This lowering is after // LTO/ThinLTO linking. Pass PGOInstrumentationGenCreateVar should // have already create the variable before LTO/ThinLTO linking. if (!IsCS) createProfileFileNameVar(M, Options.InstrProfileOutput); Function *RegisterF = M.getFunction(getInstrProfRegFuncsName()); if (!RegisterF) return; // Create the initialization function. auto *VoidTy = Type::getVoidTy(M.getContext()); auto *F = Function::Create(FunctionType::get(VoidTy, false), GlobalValue::InternalLinkage, getInstrProfInitFuncName(), M); F->setUnnamedAddr(GlobalValue::UnnamedAddr::Global); F->addFnAttr(Attribute::NoInline); if (Options.NoRedZone) F->addFnAttr(Attribute::NoRedZone); // Add the basic block and the necessary calls. IRBuilder<> IRB(BasicBlock::Create(M.getContext(), "", F)); IRB.CreateCall(RegisterF, {}); IRB.CreateRetVoid(); appendToGlobalCtors(M, F, 0); } namespace llvm { // Create the variable for profile sampling. void createProfileSamplingVar(Module &M) { const StringRef VarName(INSTR_PROF_QUOTE(INSTR_PROF_PROFILE_SAMPLING_VAR)); IntegerType *SamplingVarTy; Constant *ValueZero; if (getSampledInstrumentationConfig().UseShort) { SamplingVarTy = Type::getInt16Ty(M.getContext()); ValueZero = Constant::getIntegerValue(SamplingVarTy, APInt(16, 0)); } else { SamplingVarTy = Type::getInt32Ty(M.getContext()); ValueZero = Constant::getIntegerValue(SamplingVarTy, APInt(32, 0)); } auto SamplingVar = new GlobalVariable( M, SamplingVarTy, false, GlobalValue::WeakAnyLinkage, ValueZero, VarName); SamplingVar->setVisibility(GlobalValue::DefaultVisibility); SamplingVar->setThreadLocal(true); Triple TT(M.getTargetTriple()); if (TT.supportsCOMDAT()) { SamplingVar->setLinkage(GlobalValue::ExternalLinkage); SamplingVar->setComdat(M.getOrInsertComdat(VarName)); } appendToCompilerUsed(M, SamplingVar); } } // namespace llvm