//===--- PrecompiledPreamble.cpp - Build precompiled preambles --*- C++ -*-===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// // // Helper class to build precompiled preamble. // //===----------------------------------------------------------------------===// #include "clang/Frontend/PrecompiledPreamble.h" #include "clang/Basic/FileManager.h" #include "clang/Basic/LangStandard.h" #include "clang/Frontend/CompilerInstance.h" #include "clang/Frontend/CompilerInvocation.h" #include "clang/Frontend/FrontendActions.h" #include "clang/Frontend/FrontendOptions.h" #include "clang/Lex/HeaderSearch.h" #include "clang/Lex/Lexer.h" #include "clang/Lex/Preprocessor.h" #include "clang/Lex/PreprocessorOptions.h" #include "clang/Serialization/ASTWriter.h" #include "llvm/ADT/SmallString.h" #include "llvm/ADT/StringSet.h" #include "llvm/ADT/iterator_range.h" #include "llvm/Config/llvm-config.h" #include "llvm/Support/CrashRecoveryContext.h" #include "llvm/Support/FileSystem.h" #include "llvm/Support/Path.h" #include "llvm/Support/Process.h" #include "llvm/Support/VirtualFileSystem.h" #include #include #include using namespace clang; namespace { StringRef getInMemoryPreamblePath() { #if defined(LLVM_ON_UNIX) return "/__clang_tmp/___clang_inmemory_preamble___"; #elif defined(_WIN32) return "C:\\__clang_tmp\\___clang_inmemory_preamble___"; #else #warning "Unknown platform. Defaulting to UNIX-style paths for in-memory PCHs" return "/__clang_tmp/___clang_inmemory_preamble___"; #endif } IntrusiveRefCntPtr createVFSOverlayForPreamblePCH(StringRef PCHFilename, std::unique_ptr PCHBuffer, IntrusiveRefCntPtr VFS) { // We want only the PCH file from the real filesystem to be available, // so we create an in-memory VFS with just that and overlay it on top. IntrusiveRefCntPtr PCHFS( new llvm::vfs::InMemoryFileSystem()); PCHFS->addFile(PCHFilename, 0, std::move(PCHBuffer)); IntrusiveRefCntPtr Overlay( new llvm::vfs::OverlayFileSystem(VFS)); Overlay->pushOverlay(PCHFS); return Overlay; } class PreambleDependencyCollector : public DependencyCollector { public: // We want to collect all dependencies for correctness. Avoiding the real // system dependencies (e.g. stl from /usr/lib) would probably be a good idea, // but there is no way to distinguish between those and the ones that can be // spuriously added by '-isystem' (e.g. to suppress warnings from those // headers). bool needSystemDependencies() override { return true; } }; // Collects files whose existence would invalidate the preamble. // Collecting *all* of these would make validating it too slow though, so we // just find all the candidates for 'file not found' diagnostics. // // A caveat that may be significant for generated files: we'll omit files under // search path entries whose roots don't exist when the preamble is built. // These are pruned by InitHeaderSearch and so we don't see the search path. // It would be nice to include them but we don't want to duplicate all the rest // of the InitHeaderSearch logic to reconstruct them. class MissingFileCollector : public PPCallbacks { llvm::StringSet<> &Out; const HeaderSearch &Search; const SourceManager &SM; public: MissingFileCollector(llvm::StringSet<> &Out, const HeaderSearch &Search, const SourceManager &SM) : Out(Out), Search(Search), SM(SM) {} void InclusionDirective(SourceLocation HashLoc, const Token &IncludeTok, StringRef FileName, bool IsAngled, CharSourceRange FilenameRange, OptionalFileEntryRef File, StringRef SearchPath, StringRef RelativePath, const Module *Imported, SrcMgr::CharacteristicKind FileType) override { // File is std::nullopt if it wasn't found. // (We have some false negatives if PP recovered e.g. -> "foo") if (File) return; // If it's a rare absolute include, we know the full path already. if (llvm::sys::path::is_absolute(FileName)) { Out.insert(FileName); return; } // Reconstruct the filenames that would satisfy this directive... llvm::SmallString<256> Buf; auto NotFoundRelativeTo = [&](DirectoryEntryRef DE) { Buf = DE.getName(); llvm::sys::path::append(Buf, FileName); llvm::sys::path::remove_dots(Buf, /*remove_dot_dot=*/true); Out.insert(Buf); }; // ...relative to the including file. if (!IsAngled) { if (OptionalFileEntryRef IncludingFile = SM.getFileEntryRefForID(SM.getFileID(IncludeTok.getLocation()))) if (IncludingFile->getDir()) NotFoundRelativeTo(IncludingFile->getDir()); } // ...relative to the search paths. for (const auto &Dir : llvm::make_range( IsAngled ? Search.angled_dir_begin() : Search.search_dir_begin(), Search.search_dir_end())) { // No support for frameworks or header maps yet. if (Dir.isNormalDir()) NotFoundRelativeTo(*Dir.getDirRef()); } } }; /// Keeps a track of files to be deleted in destructor. class TemporaryFiles { public: // A static instance to be used by all clients. static TemporaryFiles &getInstance(); private: // Disallow constructing the class directly. TemporaryFiles() = default; // Disallow copy. TemporaryFiles(const TemporaryFiles &) = delete; public: ~TemporaryFiles(); /// Adds \p File to a set of tracked files. void addFile(StringRef File); /// Remove \p File from disk and from the set of tracked files. void removeFile(StringRef File); private: std::mutex Mutex; llvm::StringSet<> Files; }; TemporaryFiles &TemporaryFiles::getInstance() { static TemporaryFiles Instance; return Instance; } TemporaryFiles::~TemporaryFiles() { std::lock_guard Guard(Mutex); for (const auto &File : Files) llvm::sys::fs::remove(File.getKey()); } void TemporaryFiles::addFile(StringRef File) { std::lock_guard Guard(Mutex); auto IsInserted = Files.insert(File).second; (void)IsInserted; assert(IsInserted && "File has already been added"); } void TemporaryFiles::removeFile(StringRef File) { std::lock_guard Guard(Mutex); auto WasPresent = Files.erase(File); (void)WasPresent; assert(WasPresent && "File was not tracked"); llvm::sys::fs::remove(File); } // A temp file that would be deleted on destructor call. If destructor is not // called for any reason, the file will be deleted at static objects' // destruction. // An assertion will fire if two TempPCHFiles are created with the same name, // so it's not intended to be used outside preamble-handling. class TempPCHFile { public: // A main method used to construct TempPCHFile. static std::unique_ptr create(StringRef StoragePath) { // FIXME: This is a hack so that we can override the preamble file during // crash-recovery testing, which is the only case where the preamble files // are not necessarily cleaned up. if (const char *TmpFile = ::getenv("CINDEXTEST_PREAMBLE_FILE")) return std::unique_ptr(new TempPCHFile(TmpFile)); llvm::SmallString<128> File; // Using the versions of createTemporaryFile() and // createUniqueFile() with a file descriptor guarantees // that we would never get a race condition in a multi-threaded setting // (i.e., multiple threads getting the same temporary path). int FD; std::error_code EC; if (StoragePath.empty()) EC = llvm::sys::fs::createTemporaryFile("preamble", "pch", FD, File); else { llvm::SmallString<128> TempPath = StoragePath; // Use the same filename model as fs::createTemporaryFile(). llvm::sys::path::append(TempPath, "preamble-%%%%%%.pch"); namespace fs = llvm::sys::fs; // Use the same owner-only file permissions as fs::createTemporaryFile(). EC = fs::createUniqueFile(TempPath, FD, File, fs::OF_None, fs::owner_read | fs::owner_write); } if (EC) return nullptr; // We only needed to make sure the file exists, close the file right away. llvm::sys::Process::SafelyCloseFileDescriptor(FD); return std::unique_ptr(new TempPCHFile(File.str().str())); } TempPCHFile &operator=(const TempPCHFile &) = delete; TempPCHFile(const TempPCHFile &) = delete; ~TempPCHFile() { TemporaryFiles::getInstance().removeFile(FilePath); }; /// A path where temporary file is stored. llvm::StringRef getFilePath() const { return FilePath; }; private: TempPCHFile(std::string FilePath) : FilePath(std::move(FilePath)) { TemporaryFiles::getInstance().addFile(this->FilePath); } std::string FilePath; }; class PrecompilePreambleAction : public ASTFrontendAction { public: PrecompilePreambleAction(std::shared_ptr Buffer, bool WritePCHFile, PreambleCallbacks &Callbacks) : Buffer(std::move(Buffer)), WritePCHFile(WritePCHFile), Callbacks(Callbacks) {} std::unique_ptr CreateASTConsumer(CompilerInstance &CI, StringRef InFile) override; bool hasEmittedPreamblePCH() const { return HasEmittedPreamblePCH; } void setEmittedPreamblePCH(ASTWriter &Writer) { if (FileOS) { *FileOS << Buffer->Data; // Make sure it hits disk now. FileOS.reset(); } this->HasEmittedPreamblePCH = true; Callbacks.AfterPCHEmitted(Writer); } bool BeginSourceFileAction(CompilerInstance &CI) override { assert(CI.getLangOpts().CompilingPCH); return ASTFrontendAction::BeginSourceFileAction(CI); } bool shouldEraseOutputFiles() override { return !hasEmittedPreamblePCH(); } bool hasCodeCompletionSupport() const override { return false; } bool hasASTFileSupport() const override { return false; } TranslationUnitKind getTranslationUnitKind() override { return TU_Prefix; } private: friend class PrecompilePreambleConsumer; bool HasEmittedPreamblePCH = false; std::shared_ptr Buffer; bool WritePCHFile; // otherwise the PCH is written into the PCHBuffer only. std::unique_ptr FileOS; // null if in-memory PreambleCallbacks &Callbacks; }; class PrecompilePreambleConsumer : public PCHGenerator { public: PrecompilePreambleConsumer(PrecompilePreambleAction &Action, const Preprocessor &PP, InMemoryModuleCache &ModuleCache, StringRef isysroot, std::shared_ptr Buffer) : PCHGenerator(PP, ModuleCache, "", isysroot, std::move(Buffer), ArrayRef>(), /*AllowASTWithErrors=*/true), Action(Action) {} bool HandleTopLevelDecl(DeclGroupRef DG) override { Action.Callbacks.HandleTopLevelDecl(DG); return true; } void HandleTranslationUnit(ASTContext &Ctx) override { PCHGenerator::HandleTranslationUnit(Ctx); if (!hasEmittedPCH()) return; Action.setEmittedPreamblePCH(getWriter()); } bool shouldSkipFunctionBody(Decl *D) override { return Action.Callbacks.shouldSkipFunctionBody(D); } private: PrecompilePreambleAction &Action; }; std::unique_ptr PrecompilePreambleAction::CreateASTConsumer(CompilerInstance &CI, StringRef InFile) { std::string Sysroot; if (!GeneratePCHAction::ComputeASTConsumerArguments(CI, Sysroot)) return nullptr; if (WritePCHFile) { std::string OutputFile; // unused FileOS = GeneratePCHAction::CreateOutputFile(CI, InFile, OutputFile); if (!FileOS) return nullptr; } if (!CI.getFrontendOpts().RelocatablePCH) Sysroot.clear(); return std::make_unique( *this, CI.getPreprocessor(), CI.getModuleCache(), Sysroot, Buffer); } template bool moveOnNoError(llvm::ErrorOr Val, T &Output) { if (!Val) return false; Output = std::move(*Val); return true; } } // namespace PreambleBounds clang::ComputePreambleBounds(const LangOptions &LangOpts, const llvm::MemoryBufferRef &Buffer, unsigned MaxLines) { return Lexer::ComputePreamble(Buffer.getBuffer(), LangOpts, MaxLines); } class PrecompiledPreamble::PCHStorage { public: static std::unique_ptr file(std::unique_ptr File) { assert(File); std::unique_ptr S(new PCHStorage()); S->File = std::move(File); return S; } static std::unique_ptr inMemory(std::shared_ptr Buf) { std::unique_ptr S(new PCHStorage()); S->Memory = std::move(Buf); return S; } enum class Kind { InMemory, TempFile }; Kind getKind() const { if (Memory) return Kind::InMemory; if (File) return Kind::TempFile; llvm_unreachable("Neither Memory nor File?"); } llvm::StringRef filePath() const { assert(getKind() == Kind::TempFile); return File->getFilePath(); } llvm::StringRef memoryContents() const { assert(getKind() == Kind::InMemory); return StringRef(Memory->Data.data(), Memory->Data.size()); } // Shrink in-memory buffers to fit. // This incurs a copy, but preambles tend to be long-lived. // Only safe to call once nothing can alias the buffer. void shrink() { if (!Memory) return; Memory->Data = decltype(Memory->Data)(Memory->Data); } private: PCHStorage() = default; PCHStorage(const PCHStorage &) = delete; PCHStorage &operator=(const PCHStorage &) = delete; std::shared_ptr Memory; std::unique_ptr File; }; PrecompiledPreamble::~PrecompiledPreamble() = default; PrecompiledPreamble::PrecompiledPreamble(PrecompiledPreamble &&) = default; PrecompiledPreamble & PrecompiledPreamble::operator=(PrecompiledPreamble &&) = default; llvm::ErrorOr PrecompiledPreamble::Build( const CompilerInvocation &Invocation, const llvm::MemoryBuffer *MainFileBuffer, PreambleBounds Bounds, DiagnosticsEngine &Diagnostics, IntrusiveRefCntPtr VFS, std::shared_ptr PCHContainerOps, bool StoreInMemory, StringRef StoragePath, PreambleCallbacks &Callbacks) { assert(VFS && "VFS is null"); auto PreambleInvocation = std::make_shared(Invocation); FrontendOptions &FrontendOpts = PreambleInvocation->getFrontendOpts(); PreprocessorOptions &PreprocessorOpts = PreambleInvocation->getPreprocessorOpts(); std::shared_ptr Buffer = std::make_shared(); std::unique_ptr Storage; if (StoreInMemory) { Storage = PCHStorage::inMemory(Buffer); } else { // Create a temporary file for the precompiled preamble. In rare // circumstances, this can fail. std::unique_ptr PreamblePCHFile = TempPCHFile::create(StoragePath); if (!PreamblePCHFile) return BuildPreambleError::CouldntCreateTempFile; Storage = PCHStorage::file(std::move(PreamblePCHFile)); } // Save the preamble text for later; we'll need to compare against it for // subsequent reparses. std::vector PreambleBytes(MainFileBuffer->getBufferStart(), MainFileBuffer->getBufferStart() + Bounds.Size); bool PreambleEndsAtStartOfLine = Bounds.PreambleEndsAtStartOfLine; // Tell the compiler invocation to generate a temporary precompiled header. FrontendOpts.ProgramAction = frontend::GeneratePCH; FrontendOpts.OutputFile = std::string( StoreInMemory ? getInMemoryPreamblePath() : Storage->filePath()); PreprocessorOpts.PrecompiledPreambleBytes.first = 0; PreprocessorOpts.PrecompiledPreambleBytes.second = false; // Inform preprocessor to record conditional stack when building the preamble. PreprocessorOpts.GeneratePreamble = true; // Create the compiler instance to use for building the precompiled preamble. std::unique_ptr Clang( new CompilerInstance(std::move(PCHContainerOps))); // Recover resources if we crash before exiting this method. llvm::CrashRecoveryContextCleanupRegistrar CICleanup( Clang.get()); Clang->setInvocation(std::move(PreambleInvocation)); Clang->setDiagnostics(&Diagnostics); // Create the target instance. if (!Clang->createTarget()) return BuildPreambleError::CouldntCreateTargetInfo; if (Clang->getFrontendOpts().Inputs.size() != 1 || Clang->getFrontendOpts().Inputs[0].getKind().getFormat() != InputKind::Source || Clang->getFrontendOpts().Inputs[0].getKind().getLanguage() == Language::LLVM_IR) { return BuildPreambleError::BadInputs; } // Clear out old caches and data. Diagnostics.Reset(); ProcessWarningOptions(Diagnostics, Clang->getDiagnosticOpts()); VFS = createVFSFromCompilerInvocation(Clang->getInvocation(), Diagnostics, VFS); // Create a file manager object to provide access to and cache the filesystem. Clang->setFileManager(new FileManager(Clang->getFileSystemOpts(), VFS)); // Create the source manager. Clang->setSourceManager( new SourceManager(Diagnostics, Clang->getFileManager())); auto PreambleDepCollector = std::make_shared(); Clang->addDependencyCollector(PreambleDepCollector); Clang->getLangOpts().CompilingPCH = true; // Remap the main source file to the preamble buffer. StringRef MainFilePath = FrontendOpts.Inputs[0].getFile(); auto PreambleInputBuffer = llvm::MemoryBuffer::getMemBufferCopy( MainFileBuffer->getBuffer().slice(0, Bounds.Size), MainFilePath); if (PreprocessorOpts.RetainRemappedFileBuffers) { // MainFileBuffer will be deleted by unique_ptr after leaving the method. PreprocessorOpts.addRemappedFile(MainFilePath, PreambleInputBuffer.get()); } else { // In that case, remapped buffer will be deleted by CompilerInstance on // BeginSourceFile, so we call release() to avoid double deletion. PreprocessorOpts.addRemappedFile(MainFilePath, PreambleInputBuffer.release()); } auto Act = std::make_unique( std::move(Buffer), /*WritePCHFile=*/Storage->getKind() == PCHStorage::Kind::TempFile, Callbacks); if (!Act->BeginSourceFile(*Clang.get(), Clang->getFrontendOpts().Inputs[0])) return BuildPreambleError::BeginSourceFileFailed; // Performed after BeginSourceFile to ensure Clang->Preprocessor can be // referenced in the callback. Callbacks.BeforeExecute(*Clang); std::unique_ptr DelegatedPPCallbacks = Callbacks.createPPCallbacks(); if (DelegatedPPCallbacks) Clang->getPreprocessor().addPPCallbacks(std::move(DelegatedPPCallbacks)); if (auto CommentHandler = Callbacks.getCommentHandler()) Clang->getPreprocessor().addCommentHandler(CommentHandler); llvm::StringSet<> MissingFiles; Clang->getPreprocessor().addPPCallbacks( std::make_unique( MissingFiles, Clang->getPreprocessor().getHeaderSearchInfo(), Clang->getSourceManager())); if (llvm::Error Err = Act->Execute()) return errorToErrorCode(std::move(Err)); // Run the callbacks. Callbacks.AfterExecute(*Clang); Act->EndSourceFile(); if (!Act->hasEmittedPreamblePCH()) return BuildPreambleError::CouldntEmitPCH; Act.reset(); // Frees the PCH buffer, unless Storage keeps it in memory. // Keep track of all of the files that the source manager knows about, // so we can verify whether they have changed or not. llvm::StringMap FilesInPreamble; SourceManager &SourceMgr = Clang->getSourceManager(); for (auto &Filename : PreambleDepCollector->getDependencies()) { auto MaybeFile = Clang->getFileManager().getOptionalFileRef(Filename); if (!MaybeFile || MaybeFile == SourceMgr.getFileEntryRefForID(SourceMgr.getMainFileID())) continue; auto File = *MaybeFile; if (time_t ModTime = File.getModificationTime()) { FilesInPreamble[File.getName()] = PrecompiledPreamble::PreambleFileHash::createForFile(File.getSize(), ModTime); } else { llvm::MemoryBufferRef Buffer = SourceMgr.getMemoryBufferForFileOrFake(File); FilesInPreamble[File.getName()] = PrecompiledPreamble::PreambleFileHash::createForMemoryBuffer(Buffer); } } // Shrinking the storage requires extra temporary memory. // Destroying clang first reduces peak memory usage. CICleanup.unregister(); Clang.reset(); Storage->shrink(); return PrecompiledPreamble( std::move(Storage), std::move(PreambleBytes), PreambleEndsAtStartOfLine, std::move(FilesInPreamble), std::move(MissingFiles)); } PreambleBounds PrecompiledPreamble::getBounds() const { return PreambleBounds(PreambleBytes.size(), PreambleEndsAtStartOfLine); } std::size_t PrecompiledPreamble::getSize() const { switch (Storage->getKind()) { case PCHStorage::Kind::InMemory: return Storage->memoryContents().size(); case PCHStorage::Kind::TempFile: { uint64_t Result; if (llvm::sys::fs::file_size(Storage->filePath(), Result)) return 0; assert(Result <= std::numeric_limits::max() && "file size did not fit into size_t"); return Result; } } llvm_unreachable("Unhandled storage kind"); } bool PrecompiledPreamble::CanReuse(const CompilerInvocation &Invocation, const llvm::MemoryBufferRef &MainFileBuffer, PreambleBounds Bounds, llvm::vfs::FileSystem &VFS) const { assert( Bounds.Size <= MainFileBuffer.getBufferSize() && "Buffer is too large. Bounds were calculated from a different buffer?"); auto PreambleInvocation = std::make_shared(Invocation); PreprocessorOptions &PreprocessorOpts = PreambleInvocation->getPreprocessorOpts(); // We've previously computed a preamble. Check whether we have the same // preamble now that we did before, and that there's enough space in // the main-file buffer within the precompiled preamble to fit the // new main file. if (PreambleBytes.size() != Bounds.Size || PreambleEndsAtStartOfLine != Bounds.PreambleEndsAtStartOfLine || !std::equal(PreambleBytes.begin(), PreambleBytes.end(), MainFileBuffer.getBuffer().begin())) return false; // The preamble has not changed. We may be able to re-use the precompiled // preamble. // Check that none of the files used by the preamble have changed. // First, make a record of those files that have been overridden via // remapping or unsaved_files. std::map OverriddenFiles; llvm::StringSet<> OverriddenAbsPaths; // Either by buffers or files. for (const auto &R : PreprocessorOpts.RemappedFiles) { llvm::vfs::Status Status; if (!moveOnNoError(VFS.status(R.second), Status)) { // If we can't stat the file we're remapping to, assume that something // horrible happened. return false; } // If a mapped file was previously missing, then it has changed. llvm::SmallString<128> MappedPath(R.first); if (!VFS.makeAbsolute(MappedPath)) OverriddenAbsPaths.insert(MappedPath); OverriddenFiles[Status.getUniqueID()] = PreambleFileHash::createForFile( Status.getSize(), llvm::sys::toTimeT(Status.getLastModificationTime())); } // OverridenFileBuffers tracks only the files not found in VFS. llvm::StringMap OverridenFileBuffers; for (const auto &RB : PreprocessorOpts.RemappedFileBuffers) { const PrecompiledPreamble::PreambleFileHash PreambleHash = PreambleFileHash::createForMemoryBuffer(RB.second->getMemBufferRef()); llvm::vfs::Status Status; if (moveOnNoError(VFS.status(RB.first), Status)) OverriddenFiles[Status.getUniqueID()] = PreambleHash; else OverridenFileBuffers[RB.first] = PreambleHash; llvm::SmallString<128> MappedPath(RB.first); if (!VFS.makeAbsolute(MappedPath)) OverriddenAbsPaths.insert(MappedPath); } // Check whether anything has changed. for (const auto &F : FilesInPreamble) { auto OverridenFileBuffer = OverridenFileBuffers.find(F.first()); if (OverridenFileBuffer != OverridenFileBuffers.end()) { // The file's buffer was remapped and the file was not found in VFS. // Check whether it matches up with the previous mapping. if (OverridenFileBuffer->second != F.second) return false; continue; } llvm::vfs::Status Status; if (!moveOnNoError(VFS.status(F.first()), Status)) { // If the file's buffer is not remapped and we can't stat it, // assume that something horrible happened. return false; } std::map::iterator Overridden = OverriddenFiles.find(Status.getUniqueID()); if (Overridden != OverriddenFiles.end()) { // This file was remapped; check whether the newly-mapped file // matches up with the previous mapping. if (Overridden->second != F.second) return false; continue; } // Neither the file's buffer nor the file itself was remapped; // check whether it has changed on disk. if (Status.getSize() != uint64_t(F.second.Size) || llvm::sys::toTimeT(Status.getLastModificationTime()) != F.second.ModTime) return false; } for (const auto &F : MissingFiles) { // A missing file may be "provided" by an override buffer or file. if (OverriddenAbsPaths.count(F.getKey())) return false; // If a file previously recorded as missing exists as a regular file, then // consider the preamble out-of-date. if (auto Status = VFS.status(F.getKey())) { if (Status->isRegularFile()) return false; } } return true; } void PrecompiledPreamble::AddImplicitPreamble( CompilerInvocation &CI, IntrusiveRefCntPtr &VFS, llvm::MemoryBuffer *MainFileBuffer) const { PreambleBounds Bounds(PreambleBytes.size(), PreambleEndsAtStartOfLine); configurePreamble(Bounds, CI, VFS, MainFileBuffer); } void PrecompiledPreamble::OverridePreamble( CompilerInvocation &CI, IntrusiveRefCntPtr &VFS, llvm::MemoryBuffer *MainFileBuffer) const { auto Bounds = ComputePreambleBounds(CI.getLangOpts(), *MainFileBuffer, 0); configurePreamble(Bounds, CI, VFS, MainFileBuffer); } PrecompiledPreamble::PrecompiledPreamble( std::unique_ptr Storage, std::vector PreambleBytes, bool PreambleEndsAtStartOfLine, llvm::StringMap FilesInPreamble, llvm::StringSet<> MissingFiles) : Storage(std::move(Storage)), FilesInPreamble(std::move(FilesInPreamble)), MissingFiles(std::move(MissingFiles)), PreambleBytes(std::move(PreambleBytes)), PreambleEndsAtStartOfLine(PreambleEndsAtStartOfLine) { assert(this->Storage != nullptr); } PrecompiledPreamble::PreambleFileHash PrecompiledPreamble::PreambleFileHash::createForFile(off_t Size, time_t ModTime) { PreambleFileHash Result; Result.Size = Size; Result.ModTime = ModTime; Result.MD5 = {}; return Result; } PrecompiledPreamble::PreambleFileHash PrecompiledPreamble::PreambleFileHash::createForMemoryBuffer( const llvm::MemoryBufferRef &Buffer) { PreambleFileHash Result; Result.Size = Buffer.getBufferSize(); Result.ModTime = 0; llvm::MD5 MD5Ctx; MD5Ctx.update(Buffer.getBuffer().data()); MD5Ctx.final(Result.MD5); return Result; } void PrecompiledPreamble::configurePreamble( PreambleBounds Bounds, CompilerInvocation &CI, IntrusiveRefCntPtr &VFS, llvm::MemoryBuffer *MainFileBuffer) const { assert(VFS); auto &PreprocessorOpts = CI.getPreprocessorOpts(); // Remap main file to point to MainFileBuffer. auto MainFilePath = CI.getFrontendOpts().Inputs[0].getFile(); PreprocessorOpts.addRemappedFile(MainFilePath, MainFileBuffer); // Configure ImpicitPCHInclude. PreprocessorOpts.PrecompiledPreambleBytes.first = Bounds.Size; PreprocessorOpts.PrecompiledPreambleBytes.second = Bounds.PreambleEndsAtStartOfLine; PreprocessorOpts.DisablePCHOrModuleValidation = DisableValidationForModuleKind::PCH; // Don't bother generating the long version of the predefines buffer. // The preamble is going to overwrite it anyway. PreprocessorOpts.UsePredefines = false; setupPreambleStorage(*Storage, PreprocessorOpts, VFS); } void PrecompiledPreamble::setupPreambleStorage( const PCHStorage &Storage, PreprocessorOptions &PreprocessorOpts, IntrusiveRefCntPtr &VFS) { if (Storage.getKind() == PCHStorage::Kind::TempFile) { llvm::StringRef PCHPath = Storage.filePath(); PreprocessorOpts.ImplicitPCHInclude = PCHPath.str(); // Make sure we can access the PCH file even if we're using a VFS IntrusiveRefCntPtr RealFS = llvm::vfs::getRealFileSystem(); if (VFS == RealFS || VFS->exists(PCHPath)) return; auto Buf = RealFS->getBufferForFile(PCHPath); if (!Buf) { // We can't read the file even from RealFS, this is clearly an error, // but we'll just leave the current VFS as is and let clang's code // figure out what to do with missing PCH. return; } // We have a slight inconsistency here -- we're using the VFS to // read files, but the PCH was generated in the real file system. VFS = createVFSOverlayForPreamblePCH(PCHPath, std::move(*Buf), VFS); } else { assert(Storage.getKind() == PCHStorage::Kind::InMemory); // For in-memory preamble, we have to provide a VFS overlay that makes it // accessible. StringRef PCHPath = getInMemoryPreamblePath(); PreprocessorOpts.ImplicitPCHInclude = std::string(PCHPath); auto Buf = llvm::MemoryBuffer::getMemBuffer( Storage.memoryContents(), PCHPath, /*RequiresNullTerminator=*/false); VFS = createVFSOverlayForPreamblePCH(PCHPath, std::move(Buf), VFS); } } void PreambleCallbacks::BeforeExecute(CompilerInstance &CI) {} void PreambleCallbacks::AfterExecute(CompilerInstance &CI) {} void PreambleCallbacks::AfterPCHEmitted(ASTWriter &Writer) {} void PreambleCallbacks::HandleTopLevelDecl(DeclGroupRef DG) {} std::unique_ptr PreambleCallbacks::createPPCallbacks() { return nullptr; } CommentHandler *PreambleCallbacks::getCommentHandler() { return nullptr; } static llvm::ManagedStatic BuildPreambleErrCategory; std::error_code clang::make_error_code(BuildPreambleError Error) { return std::error_code(static_cast(Error), *BuildPreambleErrCategory); } const char *BuildPreambleErrorCategory::name() const noexcept { return "build-preamble.error"; } std::string BuildPreambleErrorCategory::message(int condition) const { switch (static_cast(condition)) { case BuildPreambleError::CouldntCreateTempFile: return "Could not create temporary file for PCH"; case BuildPreambleError::CouldntCreateTargetInfo: return "CreateTargetInfo() return null"; case BuildPreambleError::BeginSourceFileFailed: return "BeginSourceFile() return an error"; case BuildPreambleError::CouldntEmitPCH: return "Could not emit PCH"; case BuildPreambleError::BadInputs: return "Command line arguments must contain exactly one source file"; } llvm_unreachable("unexpected BuildPreambleError"); }