//===- GCOVProfiling.cpp - Insert edge counters for gcov 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 implements GCOV-style profiling. When this pass is run it emits // "gcno" files next to the existing source, and instruments the code that runs // to records the edges between blocks that run and emit a complementary "gcda" // file on exit. // //===----------------------------------------------------------------------===// #include "CFGMST.h" #include "llvm/ADT/DenseMap.h" #include "llvm/ADT/Hashing.h" #include "llvm/ADT/MapVector.h" #include "llvm/ADT/STLExtras.h" #include "llvm/ADT/Sequence.h" #include "llvm/ADT/Statistic.h" #include "llvm/ADT/StringExtras.h" #include "llvm/ADT/StringMap.h" #include "llvm/Analysis/BlockFrequencyInfo.h" #include "llvm/Analysis/BranchProbabilityInfo.h" #include "llvm/Analysis/EHPersonalities.h" #include "llvm/Analysis/TargetLibraryInfo.h" #include "llvm/IR/CFG.h" #include "llvm/IR/DebugInfo.h" #include "llvm/IR/DebugLoc.h" #include "llvm/IR/IRBuilder.h" #include "llvm/IR/InstIterator.h" #include "llvm/IR/Instructions.h" #include "llvm/IR/IntrinsicInst.h" #include "llvm/IR/Module.h" #include "llvm/InitializePasses.h" #include "llvm/Pass.h" #include "llvm/Support/CRC.h" #include "llvm/Support/CommandLine.h" #include "llvm/Support/Debug.h" #include "llvm/Support/FileSystem.h" #include "llvm/Support/Path.h" #include "llvm/Support/Regex.h" #include "llvm/Support/raw_ostream.h" #include "llvm/Transforms/Instrumentation.h" #include "llvm/Transforms/Instrumentation/GCOVProfiler.h" #include "llvm/Transforms/Utils/ModuleUtils.h" #include #include #include #include using namespace llvm; namespace endian = llvm::support::endian; #define DEBUG_TYPE "insert-gcov-profiling" enum : uint32_t { GCOV_ARC_ON_TREE = 1 << 0, GCOV_TAG_FUNCTION = 0x01000000, GCOV_TAG_BLOCKS = 0x01410000, GCOV_TAG_ARCS = 0x01430000, GCOV_TAG_LINES = 0x01450000, }; static cl::opt DefaultGCOVVersion("default-gcov-version", cl::init("408*"), cl::Hidden, cl::ValueRequired); static cl::opt AtomicCounter("gcov-atomic-counter", cl::Hidden, cl::desc("Make counter updates atomic")); // Returns the number of words which will be used to represent this string. static unsigned wordsOfString(StringRef s) { // Length + NUL-terminated string + 0~3 padding NULs. return (s.size() / 4) + 2; } GCOVOptions GCOVOptions::getDefault() { GCOVOptions Options; Options.EmitNotes = true; Options.EmitData = true; Options.NoRedZone = false; Options.Atomic = AtomicCounter; if (DefaultGCOVVersion.size() != 4) { llvm::report_fatal_error(std::string("Invalid -default-gcov-version: ") + DefaultGCOVVersion); } memcpy(Options.Version, DefaultGCOVVersion.c_str(), 4); return Options; } namespace { class GCOVFunction; class GCOVProfiler { public: GCOVProfiler() : GCOVProfiler(GCOVOptions::getDefault()) {} GCOVProfiler(const GCOVOptions &Opts) : Options(Opts) {} bool runOnModule(Module &M, function_ref GetBFI, function_ref GetBPI, std::function GetTLI); void write(uint32_t i) { char Bytes[4]; endian::write32(Bytes, i, Endian); os->write(Bytes, 4); } void writeString(StringRef s) { write(wordsOfString(s) - 1); os->write(s.data(), s.size()); os->write_zeros(4 - s.size() % 4); } void writeBytes(const char *Bytes, int Size) { os->write(Bytes, Size); } private: // Create the .gcno files for the Module based on DebugInfo. bool emitProfileNotes(NamedMDNode *CUNode, bool HasExecOrFork, function_ref GetBFI, function_ref GetBPI, function_ref GetTLI); void emitGlobalConstructor( SmallVectorImpl> &CountersBySP); bool isFunctionInstrumented(const Function &F); std::vector createRegexesFromString(StringRef RegexesStr); static bool doesFilenameMatchARegex(StringRef Filename, std::vector &Regexes); // Get pointers to the functions in the runtime library. FunctionCallee getStartFileFunc(const TargetLibraryInfo *TLI); FunctionCallee getEmitFunctionFunc(const TargetLibraryInfo *TLI); FunctionCallee getEmitArcsFunc(const TargetLibraryInfo *TLI); FunctionCallee getSummaryInfoFunc(); FunctionCallee getEndFileFunc(); // Add the function to write out all our counters to the global destructor // list. Function * insertCounterWriteout(ArrayRef>); Function *insertReset(ArrayRef>); bool AddFlushBeforeForkAndExec(); enum class GCovFileType { GCNO, GCDA }; std::string mangleName(const DICompileUnit *CU, GCovFileType FileType); GCOVOptions Options; support::endianness Endian; raw_ostream *os; // Checksum, produced by hash of EdgeDestinations SmallVector FileChecksums; Module *M = nullptr; std::function GetTLI; LLVMContext *Ctx = nullptr; SmallVector, 16> Funcs; std::vector FilterRe; std::vector ExcludeRe; DenseSet ExecBlocks; StringMap InstrumentedFiles; }; class GCOVProfilerLegacyPass : public ModulePass { public: static char ID; GCOVProfilerLegacyPass() : GCOVProfilerLegacyPass(GCOVOptions::getDefault()) {} GCOVProfilerLegacyPass(const GCOVOptions &Opts) : ModulePass(ID), Profiler(Opts) { initializeGCOVProfilerLegacyPassPass(*PassRegistry::getPassRegistry()); } StringRef getPassName() const override { return "GCOV Profiler"; } bool runOnModule(Module &M) override { auto GetBFI = [this](Function &F) { return &this->getAnalysis(F).getBFI(); }; auto GetBPI = [this](Function &F) { return &this->getAnalysis(F).getBPI(); }; auto GetTLI = [this](Function &F) -> const TargetLibraryInfo & { return this->getAnalysis().getTLI(F); }; return Profiler.runOnModule(M, GetBFI, GetBPI, GetTLI); } void getAnalysisUsage(AnalysisUsage &AU) const override { AU.addRequired(); AU.addRequired(); } private: GCOVProfiler Profiler; }; struct BBInfo { BBInfo *Group; uint32_t Index; uint32_t Rank = 0; BBInfo(unsigned Index) : Group(this), Index(Index) {} const std::string infoString() const { return (Twine("Index=") + Twine(Index)).str(); } }; struct Edge { // This class implements the CFG edges. Note the CFG can be a multi-graph. // So there might be multiple edges with same SrcBB and DestBB. const BasicBlock *SrcBB; const BasicBlock *DestBB; uint64_t Weight; BasicBlock *Place = nullptr; uint32_t SrcNumber, DstNumber; bool InMST = false; bool Removed = false; bool IsCritical = false; Edge(const BasicBlock *Src, const BasicBlock *Dest, uint64_t W = 1) : SrcBB(Src), DestBB(Dest), Weight(W) {} // Return the information string of an edge. const std::string infoString() const { return (Twine(Removed ? "-" : " ") + (InMST ? " " : "*") + (IsCritical ? "c" : " ") + " W=" + Twine(Weight)) .str(); } }; } char GCOVProfilerLegacyPass::ID = 0; INITIALIZE_PASS_BEGIN( GCOVProfilerLegacyPass, "insert-gcov-profiling", "Insert instrumentation for GCOV profiling", false, false) INITIALIZE_PASS_DEPENDENCY(BlockFrequencyInfoWrapperPass) INITIALIZE_PASS_DEPENDENCY(BranchProbabilityInfoWrapperPass) INITIALIZE_PASS_DEPENDENCY(TargetLibraryInfoWrapperPass) INITIALIZE_PASS_END( GCOVProfilerLegacyPass, "insert-gcov-profiling", "Insert instrumentation for GCOV profiling", false, false) ModulePass *llvm::createGCOVProfilerPass(const GCOVOptions &Options) { return new GCOVProfilerLegacyPass(Options); } static StringRef getFunctionName(const DISubprogram *SP) { if (!SP->getLinkageName().empty()) return SP->getLinkageName(); return SP->getName(); } /// Extract a filename for a DISubprogram. /// /// Prefer relative paths in the coverage notes. Clang also may split /// up absolute paths into a directory and filename component. When /// the relative path doesn't exist, reconstruct the absolute path. static SmallString<128> getFilename(const DISubprogram *SP) { SmallString<128> Path; StringRef RelPath = SP->getFilename(); if (sys::fs::exists(RelPath)) Path = RelPath; else sys::path::append(Path, SP->getDirectory(), SP->getFilename()); return Path; } namespace { class GCOVRecord { protected: GCOVProfiler *P; GCOVRecord(GCOVProfiler *P) : P(P) {} void write(uint32_t i) { P->write(i); } void writeString(StringRef s) { P->writeString(s); } void writeBytes(const char *Bytes, int Size) { P->writeBytes(Bytes, Size); } }; class GCOVFunction; class GCOVBlock; // Constructed only by requesting it from a GCOVBlock, this object stores a // list of line numbers and a single filename, representing lines that belong // to the block. class GCOVLines : public GCOVRecord { public: void addLine(uint32_t Line) { assert(Line != 0 && "Line zero is not a valid real line number."); Lines.push_back(Line); } uint32_t length() const { return 1 + wordsOfString(Filename) + Lines.size(); } void writeOut() { write(0); writeString(Filename); for (int i = 0, e = Lines.size(); i != e; ++i) write(Lines[i]); } GCOVLines(GCOVProfiler *P, StringRef F) : GCOVRecord(P), Filename(std::string(F)) {} private: std::string Filename; SmallVector Lines; }; // Represent a basic block in GCOV. Each block has a unique number in the // function, number of lines belonging to each block, and a set of edges to // other blocks. class GCOVBlock : public GCOVRecord { public: GCOVLines &getFile(StringRef Filename) { return LinesByFile.try_emplace(Filename, P, Filename).first->second; } void addEdge(GCOVBlock &Successor, uint32_t Flags) { OutEdges.emplace_back(&Successor, Flags); } void writeOut() { uint32_t Len = 3; SmallVector *, 32> SortedLinesByFile; for (auto &I : LinesByFile) { Len += I.second.length(); SortedLinesByFile.push_back(&I); } write(GCOV_TAG_LINES); write(Len); write(Number); llvm::sort(SortedLinesByFile, [](StringMapEntry *LHS, StringMapEntry *RHS) { return LHS->getKey() < RHS->getKey(); }); for (auto &I : SortedLinesByFile) I->getValue().writeOut(); write(0); write(0); } GCOVBlock(const GCOVBlock &RHS) : GCOVRecord(RHS), Number(RHS.Number) { // Only allow copy before edges and lines have been added. After that, // there are inter-block pointers (eg: edges) that won't take kindly to // blocks being copied or moved around. assert(LinesByFile.empty()); assert(OutEdges.empty()); } uint32_t Number; SmallVector, 4> OutEdges; private: friend class GCOVFunction; GCOVBlock(GCOVProfiler *P, uint32_t Number) : GCOVRecord(P), Number(Number) {} StringMap LinesByFile; }; // A function has a unique identifier, a checksum (we leave as zero) and a // set of blocks and a map of edges between blocks. This is the only GCOV // object users can construct, the blocks and lines will be rooted here. class GCOVFunction : public GCOVRecord { public: GCOVFunction(GCOVProfiler *P, Function *F, const DISubprogram *SP, unsigned EndLine, uint32_t Ident, int Version) : GCOVRecord(P), SP(SP), EndLine(EndLine), Ident(Ident), Version(Version), EntryBlock(P, 0), ReturnBlock(P, 1) { LLVM_DEBUG(dbgs() << "Function: " << getFunctionName(SP) << "\n"); bool ExitBlockBeforeBody = Version >= 48; uint32_t i = ExitBlockBeforeBody ? 2 : 1; for (BasicBlock &BB : *F) Blocks.insert(std::make_pair(&BB, GCOVBlock(P, i++))); if (!ExitBlockBeforeBody) ReturnBlock.Number = i; std::string FunctionNameAndLine; raw_string_ostream FNLOS(FunctionNameAndLine); FNLOS << getFunctionName(SP) << SP->getLine(); FNLOS.flush(); FuncChecksum = hash_value(FunctionNameAndLine); } GCOVBlock &getBlock(const BasicBlock *BB) { return Blocks.find(const_cast(BB))->second; } GCOVBlock &getEntryBlock() { return EntryBlock; } GCOVBlock &getReturnBlock() { return ReturnBlock; } uint32_t getFuncChecksum() const { return FuncChecksum; } void writeOut(uint32_t CfgChecksum) { write(GCOV_TAG_FUNCTION); SmallString<128> Filename = getFilename(SP); uint32_t BlockLen = 2 + (Version >= 47) + wordsOfString(getFunctionName(SP)); if (Version < 80) BlockLen += wordsOfString(Filename) + 1; else BlockLen += 1 + wordsOfString(Filename) + 3 + (Version >= 90); write(BlockLen); write(Ident); write(FuncChecksum); if (Version >= 47) write(CfgChecksum); writeString(getFunctionName(SP)); if (Version < 80) { writeString(Filename); write(SP->getLine()); } else { write(SP->isArtificial()); // artificial writeString(Filename); write(SP->getLine()); // start_line write(0); // start_column // EndLine is the last line with !dbg. It is not the } line as in GCC, // but good enough. write(EndLine); if (Version >= 90) write(0); // end_column } // Emit count of blocks. write(GCOV_TAG_BLOCKS); if (Version < 80) { write(Blocks.size() + 2); for (int i = Blocks.size() + 2; i; --i) write(0); } else { write(1); write(Blocks.size() + 2); } LLVM_DEBUG(dbgs() << (Blocks.size() + 1) << " blocks\n"); // Emit edges between blocks. const uint32_t Outgoing = EntryBlock.OutEdges.size(); if (Outgoing) { write(GCOV_TAG_ARCS); write(Outgoing * 2 + 1); write(EntryBlock.Number); for (const auto &E : EntryBlock.OutEdges) { write(E.first->Number); write(E.second); } } for (auto &It : Blocks) { const GCOVBlock &Block = It.second; if (Block.OutEdges.empty()) continue; write(GCOV_TAG_ARCS); write(Block.OutEdges.size() * 2 + 1); write(Block.Number); for (const auto &E : Block.OutEdges) { write(E.first->Number); write(E.second); } } // Emit lines for each block. for (auto &It : Blocks) It.second.writeOut(); } public: const DISubprogram *SP; unsigned EndLine; uint32_t Ident; uint32_t FuncChecksum; int Version; MapVector Blocks; GCOVBlock EntryBlock; GCOVBlock ReturnBlock; }; } // RegexesStr is a string containing differents regex separated by a semi-colon. // For example "foo\..*$;bar\..*$". std::vector GCOVProfiler::createRegexesFromString(StringRef RegexesStr) { std::vector Regexes; while (!RegexesStr.empty()) { std::pair HeadTail = RegexesStr.split(';'); if (!HeadTail.first.empty()) { Regex Re(HeadTail.first); std::string Err; if (!Re.isValid(Err)) { Ctx->emitError(Twine("Regex ") + HeadTail.first + " is not valid: " + Err); } Regexes.emplace_back(std::move(Re)); } RegexesStr = HeadTail.second; } return Regexes; } bool GCOVProfiler::doesFilenameMatchARegex(StringRef Filename, std::vector &Regexes) { for (Regex &Re : Regexes) if (Re.match(Filename)) return true; return false; } bool GCOVProfiler::isFunctionInstrumented(const Function &F) { if (FilterRe.empty() && ExcludeRe.empty()) { return true; } SmallString<128> Filename = getFilename(F.getSubprogram()); auto It = InstrumentedFiles.find(Filename); if (It != InstrumentedFiles.end()) { return It->second; } SmallString<256> RealPath; StringRef RealFilename; // Path can be // /usr/lib/gcc/x86_64-linux-gnu/8/../../../../include/c++/8/bits/*.h so for // such a case we must get the real_path. if (sys::fs::real_path(Filename, RealPath)) { // real_path can fail with path like "foo.c". RealFilename = Filename; } else { RealFilename = RealPath; } bool ShouldInstrument; if (FilterRe.empty()) { ShouldInstrument = !doesFilenameMatchARegex(RealFilename, ExcludeRe); } else if (ExcludeRe.empty()) { ShouldInstrument = doesFilenameMatchARegex(RealFilename, FilterRe); } else { ShouldInstrument = doesFilenameMatchARegex(RealFilename, FilterRe) && !doesFilenameMatchARegex(RealFilename, ExcludeRe); } InstrumentedFiles[Filename] = ShouldInstrument; return ShouldInstrument; } std::string GCOVProfiler::mangleName(const DICompileUnit *CU, GCovFileType OutputType) { bool Notes = OutputType == GCovFileType::GCNO; if (NamedMDNode *GCov = M->getNamedMetadata("llvm.gcov")) { for (int i = 0, e = GCov->getNumOperands(); i != e; ++i) { MDNode *N = GCov->getOperand(i); bool ThreeElement = N->getNumOperands() == 3; if (!ThreeElement && N->getNumOperands() != 2) continue; if (dyn_cast(N->getOperand(ThreeElement ? 2 : 1)) != CU) continue; if (ThreeElement) { // These nodes have no mangling to apply, it's stored mangled in the // bitcode. MDString *NotesFile = dyn_cast(N->getOperand(0)); MDString *DataFile = dyn_cast(N->getOperand(1)); if (!NotesFile || !DataFile) continue; return std::string(Notes ? NotesFile->getString() : DataFile->getString()); } MDString *GCovFile = dyn_cast(N->getOperand(0)); if (!GCovFile) continue; SmallString<128> Filename = GCovFile->getString(); sys::path::replace_extension(Filename, Notes ? "gcno" : "gcda"); return std::string(Filename.str()); } } SmallString<128> Filename = CU->getFilename(); sys::path::replace_extension(Filename, Notes ? "gcno" : "gcda"); StringRef FName = sys::path::filename(Filename); SmallString<128> CurPath; if (sys::fs::current_path(CurPath)) return std::string(FName); sys::path::append(CurPath, FName); return std::string(CurPath.str()); } bool GCOVProfiler::runOnModule( Module &M, function_ref GetBFI, function_ref GetBPI, std::function GetTLI) { this->M = &M; this->GetTLI = std::move(GetTLI); Ctx = &M.getContext(); NamedMDNode *CUNode = M.getNamedMetadata("llvm.dbg.cu"); if (!CUNode || (!Options.EmitNotes && !Options.EmitData)) return false; bool HasExecOrFork = AddFlushBeforeForkAndExec(); FilterRe = createRegexesFromString(Options.Filter); ExcludeRe = createRegexesFromString(Options.Exclude); emitProfileNotes(CUNode, HasExecOrFork, GetBFI, GetBPI, this->GetTLI); return true; } PreservedAnalyses GCOVProfilerPass::run(Module &M, ModuleAnalysisManager &AM) { GCOVProfiler Profiler(GCOVOpts); FunctionAnalysisManager &FAM = AM.getResult(M).getManager(); auto GetBFI = [&FAM](Function &F) { return &FAM.getResult(F); }; auto GetBPI = [&FAM](Function &F) { return &FAM.getResult(F); }; auto GetTLI = [&FAM](Function &F) -> const TargetLibraryInfo & { return FAM.getResult(F); }; if (!Profiler.runOnModule(M, GetBFI, GetBPI, GetTLI)) return PreservedAnalyses::all(); return PreservedAnalyses::none(); } static bool functionHasLines(const Function &F, unsigned &EndLine) { // Check whether this function actually has any source lines. Not only // do these waste space, they also can crash gcov. EndLine = 0; for (auto &BB : F) { for (auto &I : BB) { // Debug intrinsic locations correspond to the location of the // declaration, not necessarily any statements or expressions. if (isa(&I)) continue; const DebugLoc &Loc = I.getDebugLoc(); if (!Loc) continue; // Artificial lines such as calls to the global constructors. if (Loc.getLine() == 0) continue; EndLine = std::max(EndLine, Loc.getLine()); return true; } } return false; } static bool isUsingScopeBasedEH(Function &F) { if (!F.hasPersonalityFn()) return false; EHPersonality Personality = classifyEHPersonality(F.getPersonalityFn()); return isScopedEHPersonality(Personality); } bool GCOVProfiler::AddFlushBeforeForkAndExec() { SmallVector Forks; SmallVector Execs; for (auto &F : M->functions()) { auto *TLI = &GetTLI(F); for (auto &I : instructions(F)) { if (CallInst *CI = dyn_cast(&I)) { if (Function *Callee = CI->getCalledFunction()) { LibFunc LF; if (TLI->getLibFunc(*Callee, LF)) { if (LF == LibFunc_fork) { #if !defined(_WIN32) Forks.push_back(CI); #endif } else if (LF == LibFunc_execl || LF == LibFunc_execle || LF == LibFunc_execlp || LF == LibFunc_execv || LF == LibFunc_execvp || LF == LibFunc_execve || LF == LibFunc_execvpe || LF == LibFunc_execvP) { Execs.push_back(CI); } } } } } } for (auto F : Forks) { IRBuilder<> Builder(F); BasicBlock *Parent = F->getParent(); auto NextInst = ++F->getIterator(); // We've a fork so just reset the counters in the child process FunctionType *FTy = FunctionType::get(Builder.getInt32Ty(), {}, false); FunctionCallee GCOVFork = M->getOrInsertFunction("__gcov_fork", FTy); F->setCalledFunction(GCOVFork); // We split just after the fork to have a counter for the lines after // Anyway there's a bug: // void foo() { fork(); } // void bar() { foo(); blah(); } // then "blah();" will be called 2 times but showed as 1 // because "blah()" belongs to the same block as "foo();" Parent->splitBasicBlock(NextInst); // back() is a br instruction with a debug location // equals to the one from NextAfterFork // So to avoid to have two debug locs on two blocks just change it DebugLoc Loc = F->getDebugLoc(); Parent->back().setDebugLoc(Loc); } for (auto E : Execs) { IRBuilder<> Builder(E); BasicBlock *Parent = E->getParent(); auto NextInst = ++E->getIterator(); // Since the process is replaced by a new one we need to write out gcdas // No need to reset the counters since they'll be lost after the exec** FunctionType *FTy = FunctionType::get(Builder.getVoidTy(), {}, false); FunctionCallee WriteoutF = M->getOrInsertFunction("llvm_writeout_files", FTy); Builder.CreateCall(WriteoutF); DebugLoc Loc = E->getDebugLoc(); Builder.SetInsertPoint(&*NextInst); // If the exec** fails we must reset the counters since they've been // dumped FunctionCallee ResetF = M->getOrInsertFunction("llvm_reset_counters", FTy); Builder.CreateCall(ResetF)->setDebugLoc(Loc); ExecBlocks.insert(Parent); Parent->splitBasicBlock(NextInst); Parent->back().setDebugLoc(Loc); } return !Forks.empty() || !Execs.empty(); } static BasicBlock *getInstrBB(CFGMST &MST, Edge &E, const DenseSet &ExecBlocks) { if (E.InMST || E.Removed) return nullptr; BasicBlock *SrcBB = const_cast(E.SrcBB); BasicBlock *DestBB = const_cast(E.DestBB); // For a fake edge, instrument the real BB. if (SrcBB == nullptr) return DestBB; if (DestBB == nullptr) return SrcBB; auto CanInstrument = [](BasicBlock *BB) -> BasicBlock * { // There are basic blocks (such as catchswitch) cannot be instrumented. // If the returned first insertion point is the end of BB, skip this BB. if (BB->getFirstInsertionPt() == BB->end()) return nullptr; return BB; }; // Instrument the SrcBB if it has a single successor, // otherwise, the DestBB if this is not a critical edge. Instruction *TI = SrcBB->getTerminator(); if (TI->getNumSuccessors() <= 1 && !ExecBlocks.count(SrcBB)) return CanInstrument(SrcBB); if (!E.IsCritical) return CanInstrument(DestBB); // Some IndirectBr critical edges cannot be split by the previous // SplitIndirectBrCriticalEdges call. Bail out. const unsigned SuccNum = GetSuccessorNumber(SrcBB, DestBB); BasicBlock *InstrBB = isa(TI) ? nullptr : SplitCriticalEdge(TI, SuccNum); if (!InstrBB) return nullptr; MST.addEdge(SrcBB, InstrBB, 0); MST.addEdge(InstrBB, DestBB, 0).InMST = true; E.Removed = true; return CanInstrument(InstrBB); } #ifndef NDEBUG static void dumpEdges(CFGMST &MST, GCOVFunction &GF) { size_t ID = 0; for (auto &E : make_pointee_range(MST.AllEdges)) { GCOVBlock &Src = E.SrcBB ? GF.getBlock(E.SrcBB) : GF.getEntryBlock(); GCOVBlock &Dst = E.DestBB ? GF.getBlock(E.DestBB) : GF.getReturnBlock(); dbgs() << " Edge " << ID++ << ": " << Src.Number << "->" << Dst.Number << E.infoString() << "\n"; } } #endif bool GCOVProfiler::emitProfileNotes( NamedMDNode *CUNode, bool HasExecOrFork, function_ref GetBFI, function_ref GetBPI, function_ref GetTLI) { int Version; { uint8_t c3 = Options.Version[0]; uint8_t c2 = Options.Version[1]; uint8_t c1 = Options.Version[2]; Version = c3 >= 'A' ? (c3 - 'A') * 100 + (c2 - '0') * 10 + c1 - '0' : (c3 - '0') * 10 + c1 - '0'; } bool EmitGCDA = Options.EmitData; for (unsigned i = 0, e = CUNode->getNumOperands(); i != e; ++i) { // Each compile unit gets its own .gcno file. This means that whether we run // this pass over the original .o's as they're produced, or run it after // LTO, we'll generate the same .gcno files. auto *CU = cast(CUNode->getOperand(i)); // Skip module skeleton (and module) CUs. if (CU->getDWOId()) continue; std::vector EdgeDestinations; SmallVector, 8> CountersBySP; Endian = M->getDataLayout().isLittleEndian() ? support::endianness::little : support::endianness::big; unsigned FunctionIdent = 0; for (auto &F : M->functions()) { DISubprogram *SP = F.getSubprogram(); unsigned EndLine; if (!SP) continue; if (!functionHasLines(F, EndLine) || !isFunctionInstrumented(F)) continue; // TODO: Functions using scope-based EH are currently not supported. if (isUsingScopeBasedEH(F)) continue; // Add the function line number to the lines of the entry block // to have a counter for the function definition. uint32_t Line = SP->getLine(); auto Filename = getFilename(SP); BranchProbabilityInfo *BPI = GetBPI(F); BlockFrequencyInfo *BFI = GetBFI(F); // Split indirectbr critical edges here before computing the MST rather // than later in getInstrBB() to avoid invalidating it. SplitIndirectBrCriticalEdges(F, BPI, BFI); CFGMST MST(F, /*InstrumentFuncEntry_=*/false, BPI, BFI); // getInstrBB can split basic blocks and push elements to AllEdges. for (size_t I : llvm::seq(0, MST.AllEdges.size())) { auto &E = *MST.AllEdges[I]; // For now, disable spanning tree optimization when fork or exec* is // used. if (HasExecOrFork) E.InMST = false; E.Place = getInstrBB(MST, E, ExecBlocks); } // Basic blocks in F are finalized at this point. BasicBlock &EntryBlock = F.getEntryBlock(); Funcs.push_back(std::make_unique(this, &F, SP, EndLine, FunctionIdent++, Version)); GCOVFunction &Func = *Funcs.back(); // Some non-tree edges are IndirectBr which cannot be split. Ignore them // as well. llvm::erase_if(MST.AllEdges, [](std::unique_ptr &E) { return E->Removed || (!E->InMST && !E->Place); }); const size_t Measured = std::stable_partition( MST.AllEdges.begin(), MST.AllEdges.end(), [](std::unique_ptr &E) { return E->Place; }) - MST.AllEdges.begin(); for (size_t I : llvm::seq(0, Measured)) { Edge &E = *MST.AllEdges[I]; GCOVBlock &Src = E.SrcBB ? Func.getBlock(E.SrcBB) : Func.getEntryBlock(); GCOVBlock &Dst = E.DestBB ? Func.getBlock(E.DestBB) : Func.getReturnBlock(); E.SrcNumber = Src.Number; E.DstNumber = Dst.Number; } std::stable_sort( MST.AllEdges.begin(), MST.AllEdges.begin() + Measured, [](const std::unique_ptr &L, const std::unique_ptr &R) { return L->SrcNumber != R->SrcNumber ? L->SrcNumber < R->SrcNumber : L->DstNumber < R->DstNumber; }); for (const Edge &E : make_pointee_range(MST.AllEdges)) { GCOVBlock &Src = E.SrcBB ? Func.getBlock(E.SrcBB) : Func.getEntryBlock(); GCOVBlock &Dst = E.DestBB ? Func.getBlock(E.DestBB) : Func.getReturnBlock(); Src.addEdge(Dst, E.Place ? 0 : uint32_t(GCOV_ARC_ON_TREE)); } // Artificial functions such as global initializers if (!SP->isArtificial()) Func.getBlock(&EntryBlock).getFile(Filename).addLine(Line); LLVM_DEBUG(dumpEdges(MST, Func)); for (auto &GB : Func.Blocks) { const BasicBlock &BB = *GB.first; auto &Block = GB.second; for (auto Succ : Block.OutEdges) { uint32_t Idx = Succ.first->Number; do EdgeDestinations.push_back(Idx & 255); while ((Idx >>= 8) > 0); } for (auto &I : BB) { // Debug intrinsic locations correspond to the location of the // declaration, not necessarily any statements or expressions. if (isa(&I)) continue; const DebugLoc &Loc = I.getDebugLoc(); if (!Loc) continue; // Artificial lines such as calls to the global constructors. if (Loc.getLine() == 0 || Loc.isImplicitCode()) continue; if (Line == Loc.getLine()) continue; Line = Loc.getLine(); if (SP != getDISubprogram(Loc.getScope())) continue; GCOVLines &Lines = Block.getFile(Filename); Lines.addLine(Loc.getLine()); } Line = 0; } if (EmitGCDA) { DISubprogram *SP = F.getSubprogram(); ArrayType *CounterTy = ArrayType::get(Type::getInt64Ty(*Ctx), Measured); GlobalVariable *Counters = new GlobalVariable( *M, CounterTy, false, GlobalValue::InternalLinkage, Constant::getNullValue(CounterTy), "__llvm_gcov_ctr"); CountersBySP.emplace_back(Counters, SP); for (size_t I : llvm::seq(0, Measured)) { const Edge &E = *MST.AllEdges[I]; IRBuilder<> Builder(E.Place, E.Place->getFirstInsertionPt()); Value *V = Builder.CreateConstInBoundsGEP2_64( Counters->getValueType(), Counters, 0, I); if (Options.Atomic) { Builder.CreateAtomicRMW(AtomicRMWInst::Add, V, Builder.getInt64(1), AtomicOrdering::Monotonic); } else { Value *Count = Builder.CreateLoad(Builder.getInt64Ty(), V, "gcov_ctr"); Count = Builder.CreateAdd(Count, Builder.getInt64(1)); Builder.CreateStore(Count, V); } } } } char Tmp[4]; JamCRC JC; JC.update(EdgeDestinations); uint32_t Stamp = JC.getCRC(); FileChecksums.push_back(Stamp); if (Options.EmitNotes) { std::error_code EC; raw_fd_ostream out(mangleName(CU, GCovFileType::GCNO), EC, sys::fs::OF_None); if (EC) { Ctx->emitError( Twine("failed to open coverage notes file for writing: ") + EC.message()); continue; } os = &out; if (Endian == support::endianness::big) { out.write("gcno", 4); out.write(Options.Version, 4); } else { out.write("oncg", 4); std::reverse_copy(Options.Version, Options.Version + 4, Tmp); out.write(Tmp, 4); } write(Stamp); if (Version >= 90) writeString(""); // unuseful current_working_directory if (Version >= 80) write(0); // unuseful has_unexecuted_blocks for (auto &Func : Funcs) Func->writeOut(Stamp); write(0); write(0); out.close(); } if (EmitGCDA) { emitGlobalConstructor(CountersBySP); EmitGCDA = false; } } return true; } void GCOVProfiler::emitGlobalConstructor( SmallVectorImpl> &CountersBySP) { Function *WriteoutF = insertCounterWriteout(CountersBySP); Function *ResetF = insertReset(CountersBySP); // Create a small bit of code that registers the "__llvm_gcov_writeout" to // be executed at exit and the "__llvm_gcov_flush" function to be executed // when "__gcov_flush" is called. FunctionType *FTy = FunctionType::get(Type::getVoidTy(*Ctx), false); Function *F = Function::Create(FTy, GlobalValue::InternalLinkage, "__llvm_gcov_init", M); F->setUnnamedAddr(GlobalValue::UnnamedAddr::Global); F->setLinkage(GlobalValue::InternalLinkage); F->addFnAttr(Attribute::NoInline); if (Options.NoRedZone) F->addFnAttr(Attribute::NoRedZone); BasicBlock *BB = BasicBlock::Create(*Ctx, "entry", F); IRBuilder<> Builder(BB); FTy = FunctionType::get(Type::getVoidTy(*Ctx), false); auto *PFTy = PointerType::get(FTy, 0); FTy = FunctionType::get(Builder.getVoidTy(), {PFTy, PFTy}, false); // Initialize the environment and register the local writeout, flush and // reset functions. FunctionCallee GCOVInit = M->getOrInsertFunction("llvm_gcov_init", FTy); Builder.CreateCall(GCOVInit, {WriteoutF, ResetF}); Builder.CreateRetVoid(); appendToGlobalCtors(*M, F, 0); } FunctionCallee GCOVProfiler::getStartFileFunc(const TargetLibraryInfo *TLI) { Type *Args[] = { Type::getInt8PtrTy(*Ctx), // const char *orig_filename Type::getInt32Ty(*Ctx), // uint32_t version Type::getInt32Ty(*Ctx), // uint32_t checksum }; FunctionType *FTy = FunctionType::get(Type::getVoidTy(*Ctx), Args, false); AttributeList AL; if (auto AK = TLI->getExtAttrForI32Param(false)) AL = AL.addParamAttribute(*Ctx, 2, AK); FunctionCallee Res = M->getOrInsertFunction("llvm_gcda_start_file", FTy, AL); return Res; } FunctionCallee GCOVProfiler::getEmitFunctionFunc(const TargetLibraryInfo *TLI) { Type *Args[] = { Type::getInt32Ty(*Ctx), // uint32_t ident Type::getInt32Ty(*Ctx), // uint32_t func_checksum Type::getInt32Ty(*Ctx), // uint32_t cfg_checksum }; FunctionType *FTy = FunctionType::get(Type::getVoidTy(*Ctx), Args, false); AttributeList AL; if (auto AK = TLI->getExtAttrForI32Param(false)) { AL = AL.addParamAttribute(*Ctx, 0, AK); AL = AL.addParamAttribute(*Ctx, 1, AK); AL = AL.addParamAttribute(*Ctx, 2, AK); } return M->getOrInsertFunction("llvm_gcda_emit_function", FTy); } FunctionCallee GCOVProfiler::getEmitArcsFunc(const TargetLibraryInfo *TLI) { Type *Args[] = { Type::getInt32Ty(*Ctx), // uint32_t num_counters Type::getInt64PtrTy(*Ctx), // uint64_t *counters }; FunctionType *FTy = FunctionType::get(Type::getVoidTy(*Ctx), Args, false); AttributeList AL; if (auto AK = TLI->getExtAttrForI32Param(false)) AL = AL.addParamAttribute(*Ctx, 0, AK); return M->getOrInsertFunction("llvm_gcda_emit_arcs", FTy, AL); } FunctionCallee GCOVProfiler::getSummaryInfoFunc() { FunctionType *FTy = FunctionType::get(Type::getVoidTy(*Ctx), false); return M->getOrInsertFunction("llvm_gcda_summary_info", FTy); } FunctionCallee GCOVProfiler::getEndFileFunc() { FunctionType *FTy = FunctionType::get(Type::getVoidTy(*Ctx), false); return M->getOrInsertFunction("llvm_gcda_end_file", FTy); } Function *GCOVProfiler::insertCounterWriteout( ArrayRef > CountersBySP) { FunctionType *WriteoutFTy = FunctionType::get(Type::getVoidTy(*Ctx), false); Function *WriteoutF = M->getFunction("__llvm_gcov_writeout"); if (!WriteoutF) WriteoutF = Function::Create(WriteoutFTy, GlobalValue::InternalLinkage, "__llvm_gcov_writeout", M); WriteoutF->setUnnamedAddr(GlobalValue::UnnamedAddr::Global); WriteoutF->addFnAttr(Attribute::NoInline); if (Options.NoRedZone) WriteoutF->addFnAttr(Attribute::NoRedZone); BasicBlock *BB = BasicBlock::Create(*Ctx, "entry", WriteoutF); IRBuilder<> Builder(BB); auto *TLI = &GetTLI(*WriteoutF); FunctionCallee StartFile = getStartFileFunc(TLI); FunctionCallee EmitFunction = getEmitFunctionFunc(TLI); FunctionCallee EmitArcs = getEmitArcsFunc(TLI); FunctionCallee SummaryInfo = getSummaryInfoFunc(); FunctionCallee EndFile = getEndFileFunc(); NamedMDNode *CUNodes = M->getNamedMetadata("llvm.dbg.cu"); if (!CUNodes) { Builder.CreateRetVoid(); return WriteoutF; } // Collect the relevant data into a large constant data structure that we can // walk to write out everything. StructType *StartFileCallArgsTy = StructType::create( {Builder.getInt8PtrTy(), Builder.getInt32Ty(), Builder.getInt32Ty()}, "start_file_args_ty"); StructType *EmitFunctionCallArgsTy = StructType::create( {Builder.getInt32Ty(), Builder.getInt32Ty(), Builder.getInt32Ty()}, "emit_function_args_ty"); StructType *EmitArcsCallArgsTy = StructType::create( {Builder.getInt32Ty(), Builder.getInt64Ty()->getPointerTo()}, "emit_arcs_args_ty"); StructType *FileInfoTy = StructType::create({StartFileCallArgsTy, Builder.getInt32Ty(), EmitFunctionCallArgsTy->getPointerTo(), EmitArcsCallArgsTy->getPointerTo()}, "file_info"); Constant *Zero32 = Builder.getInt32(0); // Build an explicit array of two zeros for use in ConstantExpr GEP building. Constant *TwoZero32s[] = {Zero32, Zero32}; SmallVector FileInfos; for (int i : llvm::seq(0, CUNodes->getNumOperands())) { auto *CU = cast(CUNodes->getOperand(i)); // Skip module skeleton (and module) CUs. if (CU->getDWOId()) continue; std::string FilenameGcda = mangleName(CU, GCovFileType::GCDA); uint32_t CfgChecksum = FileChecksums.empty() ? 0 : FileChecksums[i]; auto *StartFileCallArgs = ConstantStruct::get( StartFileCallArgsTy, {Builder.CreateGlobalStringPtr(FilenameGcda), Builder.getInt32(endian::read32be(Options.Version)), Builder.getInt32(CfgChecksum)}); SmallVector EmitFunctionCallArgsArray; SmallVector EmitArcsCallArgsArray; for (int j : llvm::seq(0, CountersBySP.size())) { uint32_t FuncChecksum = Funcs.empty() ? 0 : Funcs[j]->getFuncChecksum(); EmitFunctionCallArgsArray.push_back(ConstantStruct::get( EmitFunctionCallArgsTy, {Builder.getInt32(j), Builder.getInt32(FuncChecksum), Builder.getInt32(CfgChecksum)})); GlobalVariable *GV = CountersBySP[j].first; unsigned Arcs = cast(GV->getValueType())->getNumElements(); EmitArcsCallArgsArray.push_back(ConstantStruct::get( EmitArcsCallArgsTy, {Builder.getInt32(Arcs), ConstantExpr::getInBoundsGetElementPtr( GV->getValueType(), GV, TwoZero32s)})); } // Create global arrays for the two emit calls. int CountersSize = CountersBySP.size(); assert(CountersSize == (int)EmitFunctionCallArgsArray.size() && "Mismatched array size!"); assert(CountersSize == (int)EmitArcsCallArgsArray.size() && "Mismatched array size!"); auto *EmitFunctionCallArgsArrayTy = ArrayType::get(EmitFunctionCallArgsTy, CountersSize); auto *EmitFunctionCallArgsArrayGV = new GlobalVariable( *M, EmitFunctionCallArgsArrayTy, /*isConstant*/ true, GlobalValue::InternalLinkage, ConstantArray::get(EmitFunctionCallArgsArrayTy, EmitFunctionCallArgsArray), Twine("__llvm_internal_gcov_emit_function_args.") + Twine(i)); auto *EmitArcsCallArgsArrayTy = ArrayType::get(EmitArcsCallArgsTy, CountersSize); EmitFunctionCallArgsArrayGV->setUnnamedAddr( GlobalValue::UnnamedAddr::Global); auto *EmitArcsCallArgsArrayGV = new GlobalVariable( *M, EmitArcsCallArgsArrayTy, /*isConstant*/ true, GlobalValue::InternalLinkage, ConstantArray::get(EmitArcsCallArgsArrayTy, EmitArcsCallArgsArray), Twine("__llvm_internal_gcov_emit_arcs_args.") + Twine(i)); EmitArcsCallArgsArrayGV->setUnnamedAddr(GlobalValue::UnnamedAddr::Global); FileInfos.push_back(ConstantStruct::get( FileInfoTy, {StartFileCallArgs, Builder.getInt32(CountersSize), ConstantExpr::getInBoundsGetElementPtr(EmitFunctionCallArgsArrayTy, EmitFunctionCallArgsArrayGV, TwoZero32s), ConstantExpr::getInBoundsGetElementPtr( EmitArcsCallArgsArrayTy, EmitArcsCallArgsArrayGV, TwoZero32s)})); } // If we didn't find anything to actually emit, bail on out. if (FileInfos.empty()) { Builder.CreateRetVoid(); return WriteoutF; } // To simplify code, we cap the number of file infos we write out to fit // easily in a 32-bit signed integer. This gives consistent behavior between // 32-bit and 64-bit systems without requiring (potentially very slow) 64-bit // operations on 32-bit systems. It also seems unreasonable to try to handle // more than 2 billion files. if ((int64_t)FileInfos.size() > (int64_t)INT_MAX) FileInfos.resize(INT_MAX); // Create a global for the entire data structure so we can walk it more // easily. auto *FileInfoArrayTy = ArrayType::get(FileInfoTy, FileInfos.size()); auto *FileInfoArrayGV = new GlobalVariable( *M, FileInfoArrayTy, /*isConstant*/ true, GlobalValue::InternalLinkage, ConstantArray::get(FileInfoArrayTy, FileInfos), "__llvm_internal_gcov_emit_file_info"); FileInfoArrayGV->setUnnamedAddr(GlobalValue::UnnamedAddr::Global); // Create the CFG for walking this data structure. auto *FileLoopHeader = BasicBlock::Create(*Ctx, "file.loop.header", WriteoutF); auto *CounterLoopHeader = BasicBlock::Create(*Ctx, "counter.loop.header", WriteoutF); auto *FileLoopLatch = BasicBlock::Create(*Ctx, "file.loop.latch", WriteoutF); auto *ExitBB = BasicBlock::Create(*Ctx, "exit", WriteoutF); // We always have at least one file, so just branch to the header. Builder.CreateBr(FileLoopHeader); // The index into the files structure is our loop induction variable. Builder.SetInsertPoint(FileLoopHeader); PHINode *IV = Builder.CreatePHI(Builder.getInt32Ty(), /*NumReservedValues*/ 2, "file_idx"); IV->addIncoming(Builder.getInt32(0), BB); auto *FileInfoPtr = Builder.CreateInBoundsGEP( FileInfoArrayTy, FileInfoArrayGV, {Builder.getInt32(0), IV}); auto *StartFileCallArgsPtr = Builder.CreateStructGEP(FileInfoTy, FileInfoPtr, 0, "start_file_args"); auto *StartFileCall = Builder.CreateCall( StartFile, {Builder.CreateLoad(StartFileCallArgsTy->getElementType(0), Builder.CreateStructGEP(StartFileCallArgsTy, StartFileCallArgsPtr, 0), "filename"), Builder.CreateLoad(StartFileCallArgsTy->getElementType(1), Builder.CreateStructGEP(StartFileCallArgsTy, StartFileCallArgsPtr, 1), "version"), Builder.CreateLoad(StartFileCallArgsTy->getElementType(2), Builder.CreateStructGEP(StartFileCallArgsTy, StartFileCallArgsPtr, 2), "stamp")}); if (auto AK = TLI->getExtAttrForI32Param(false)) StartFileCall->addParamAttr(2, AK); auto *NumCounters = Builder.CreateLoad( FileInfoTy->getElementType(1), Builder.CreateStructGEP(FileInfoTy, FileInfoPtr, 1), "num_ctrs"); auto *EmitFunctionCallArgsArray = Builder.CreateLoad(FileInfoTy->getElementType(2), Builder.CreateStructGEP(FileInfoTy, FileInfoPtr, 2), "emit_function_args"); auto *EmitArcsCallArgsArray = Builder.CreateLoad( FileInfoTy->getElementType(3), Builder.CreateStructGEP(FileInfoTy, FileInfoPtr, 3), "emit_arcs_args"); auto *EnterCounterLoopCond = Builder.CreateICmpSLT(Builder.getInt32(0), NumCounters); Builder.CreateCondBr(EnterCounterLoopCond, CounterLoopHeader, FileLoopLatch); Builder.SetInsertPoint(CounterLoopHeader); auto *JV = Builder.CreatePHI(Builder.getInt32Ty(), /*NumReservedValues*/ 2, "ctr_idx"); JV->addIncoming(Builder.getInt32(0), FileLoopHeader); auto *EmitFunctionCallArgsPtr = Builder.CreateInBoundsGEP( EmitFunctionCallArgsTy, EmitFunctionCallArgsArray, JV); auto *EmitFunctionCall = Builder.CreateCall( EmitFunction, {Builder.CreateLoad(EmitFunctionCallArgsTy->getElementType(0), Builder.CreateStructGEP(EmitFunctionCallArgsTy, EmitFunctionCallArgsPtr, 0), "ident"), Builder.CreateLoad(EmitFunctionCallArgsTy->getElementType(1), Builder.CreateStructGEP(EmitFunctionCallArgsTy, EmitFunctionCallArgsPtr, 1), "func_checkssum"), Builder.CreateLoad(EmitFunctionCallArgsTy->getElementType(2), Builder.CreateStructGEP(EmitFunctionCallArgsTy, EmitFunctionCallArgsPtr, 2), "cfg_checksum")}); if (auto AK = TLI->getExtAttrForI32Param(false)) { EmitFunctionCall->addParamAttr(0, AK); EmitFunctionCall->addParamAttr(1, AK); EmitFunctionCall->addParamAttr(2, AK); } auto *EmitArcsCallArgsPtr = Builder.CreateInBoundsGEP(EmitArcsCallArgsTy, EmitArcsCallArgsArray, JV); auto *EmitArcsCall = Builder.CreateCall( EmitArcs, {Builder.CreateLoad( EmitArcsCallArgsTy->getElementType(0), Builder.CreateStructGEP(EmitArcsCallArgsTy, EmitArcsCallArgsPtr, 0), "num_counters"), Builder.CreateLoad( EmitArcsCallArgsTy->getElementType(1), Builder.CreateStructGEP(EmitArcsCallArgsTy, EmitArcsCallArgsPtr, 1), "counters")}); if (auto AK = TLI->getExtAttrForI32Param(false)) EmitArcsCall->addParamAttr(0, AK); auto *NextJV = Builder.CreateAdd(JV, Builder.getInt32(1)); auto *CounterLoopCond = Builder.CreateICmpSLT(NextJV, NumCounters); Builder.CreateCondBr(CounterLoopCond, CounterLoopHeader, FileLoopLatch); JV->addIncoming(NextJV, CounterLoopHeader); Builder.SetInsertPoint(FileLoopLatch); Builder.CreateCall(SummaryInfo, {}); Builder.CreateCall(EndFile, {}); auto *NextIV = Builder.CreateAdd(IV, Builder.getInt32(1), "next_file_idx"); auto *FileLoopCond = Builder.CreateICmpSLT(NextIV, Builder.getInt32(FileInfos.size())); Builder.CreateCondBr(FileLoopCond, FileLoopHeader, ExitBB); IV->addIncoming(NextIV, FileLoopLatch); Builder.SetInsertPoint(ExitBB); Builder.CreateRetVoid(); return WriteoutF; } Function *GCOVProfiler::insertReset( ArrayRef> CountersBySP) { FunctionType *FTy = FunctionType::get(Type::getVoidTy(*Ctx), false); Function *ResetF = M->getFunction("__llvm_gcov_reset"); if (!ResetF) ResetF = Function::Create(FTy, GlobalValue::InternalLinkage, "__llvm_gcov_reset", M); ResetF->setUnnamedAddr(GlobalValue::UnnamedAddr::Global); ResetF->addFnAttr(Attribute::NoInline); if (Options.NoRedZone) ResetF->addFnAttr(Attribute::NoRedZone); BasicBlock *Entry = BasicBlock::Create(*Ctx, "entry", ResetF); IRBuilder<> Builder(Entry); // Zero out the counters. for (const auto &I : CountersBySP) { GlobalVariable *GV = I.first; Constant *Null = Constant::getNullValue(GV->getValueType()); Builder.CreateStore(Null, GV); } Type *RetTy = ResetF->getReturnType(); if (RetTy->isVoidTy()) Builder.CreateRetVoid(); else if (RetTy->isIntegerTy()) // Used if __llvm_gcov_reset was implicitly declared. Builder.CreateRet(ConstantInt::get(RetTy, 0)); else report_fatal_error("invalid return type for __llvm_gcov_reset"); return ResetF; }