Mercurial > hg > CbC > CbC_llvm
view clang-tools-extra/clangd/Preamble.cpp @ 266:00f31e85ec16 default tip
Added tag current for changeset 31d058e83c98
| author | Shinji KONO <kono@ie.u-ryukyu.ac.jp> |
|---|---|
| date | Sat, 14 Oct 2023 10:13:55 +0900 |
| parents | 1f2b6ac9f198 |
| children |
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//===--- Preamble.cpp - Reusing expensive parts of the AST ----------------===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// #include "Preamble.h" #include "CollectMacros.h" #include "Compiler.h" #include "Config.h" #include "Diagnostics.h" #include "FS.h" #include "FeatureModule.h" #include "Headers.h" #include "Protocol.h" #include "SourceCode.h" #include "clang-include-cleaner/Record.h" #include "support/Logger.h" #include "support/Path.h" #include "support/ThreadsafeFS.h" #include "support/Trace.h" #include "clang/AST/DeclTemplate.h" #include "clang/AST/Type.h" #include "clang/Basic/Diagnostic.h" #include "clang/Basic/DiagnosticLex.h" #include "clang/Basic/DiagnosticOptions.h" #include "clang/Basic/LangOptions.h" #include "clang/Basic/SourceLocation.h" #include "clang/Basic/SourceManager.h" #include "clang/Basic/TargetInfo.h" #include "clang/Basic/TokenKinds.h" #include "clang/Frontend/CompilerInstance.h" #include "clang/Frontend/CompilerInvocation.h" #include "clang/Frontend/FrontendActions.h" #include "clang/Frontend/PrecompiledPreamble.h" #include "clang/Lex/HeaderSearch.h" #include "clang/Lex/Lexer.h" #include "clang/Lex/PPCallbacks.h" #include "clang/Lex/Preprocessor.h" #include "clang/Lex/PreprocessorOptions.h" #include "clang/Serialization/ASTReader.h" #include "clang/Tooling/CompilationDatabase.h" #include "llvm/ADT/ArrayRef.h" #include "llvm/ADT/DenseMap.h" #include "llvm/ADT/IntrusiveRefCntPtr.h" #include "llvm/ADT/STLExtras.h" #include "llvm/ADT/SmallString.h" #include "llvm/ADT/SmallVector.h" #include "llvm/ADT/StringExtras.h" #include "llvm/ADT/StringMap.h" #include "llvm/ADT/StringRef.h" #include "llvm/Support/Casting.h" #include "llvm/Support/Error.h" #include "llvm/Support/ErrorHandling.h" #include "llvm/Support/ErrorOr.h" #include "llvm/Support/FormatVariadic.h" #include "llvm/Support/MemoryBuffer.h" #include "llvm/Support/Path.h" #include "llvm/Support/VirtualFileSystem.h" #include "llvm/Support/raw_ostream.h" #include <cassert> #include <chrono> #include <cstddef> #include <cstdint> #include <cstdlib> #include <functional> #include <memory> #include <optional> #include <string> #include <system_error> #include <tuple> #include <utility> #include <vector> namespace clang { namespace clangd { namespace { bool compileCommandsAreEqual(const tooling::CompileCommand &LHS, const tooling::CompileCommand &RHS) { // We don't check for Output, it should not matter to clangd. return LHS.Directory == RHS.Directory && LHS.Filename == RHS.Filename && llvm::ArrayRef(LHS.CommandLine).equals(RHS.CommandLine); } class CppFilePreambleCallbacks : public PreambleCallbacks { public: CppFilePreambleCallbacks( PathRef File, PreambleBuildStats *Stats, bool ParseForwardingFunctions, std::function<void(CompilerInstance &)> BeforeExecuteCallback) : File(File), Stats(Stats), ParseForwardingFunctions(ParseForwardingFunctions), BeforeExecuteCallback(std::move(BeforeExecuteCallback)) {} IncludeStructure takeIncludes() { return std::move(Includes); } MainFileMacros takeMacros() { return std::move(Macros); } std::vector<PragmaMark> takeMarks() { return std::move(Marks); } include_cleaner::PragmaIncludes takePragmaIncludes() { return std::move(Pragmas); } std::optional<CapturedASTCtx> takeLife() { return std::move(CapturedCtx); } bool isMainFileIncludeGuarded() const { return IsMainFileIncludeGuarded; } void AfterExecute(CompilerInstance &CI) override { // As part of the Preamble compilation, ASTConsumer // PrecompilePreambleConsumer/PCHGenerator is setup. This would be called // when Preamble consists of modules. Therefore while capturing AST context, // we have to reset ast consumer and ASTMutationListener. if (CI.getASTReader()) { CI.getASTReader()->setDeserializationListener(nullptr); // This just sets consumer to null when DeserializationListener is null. CI.getASTReader()->StartTranslationUnit(nullptr); } CI.getASTContext().setASTMutationListener(nullptr); CapturedCtx.emplace(CI); const SourceManager &SM = CI.getSourceManager(); const FileEntry *MainFE = SM.getFileEntryForID(SM.getMainFileID()); IsMainFileIncludeGuarded = CI.getPreprocessor().getHeaderSearchInfo().isFileMultipleIncludeGuarded( MainFE); if (Stats) { const ASTContext &AST = CI.getASTContext(); Stats->BuildSize = AST.getASTAllocatedMemory(); Stats->BuildSize += AST.getSideTableAllocatedMemory(); Stats->BuildSize += AST.Idents.getAllocator().getTotalMemory(); Stats->BuildSize += AST.Selectors.getTotalMemory(); Stats->BuildSize += AST.getSourceManager().getContentCacheSize(); Stats->BuildSize += AST.getSourceManager().getDataStructureSizes(); Stats->BuildSize += AST.getSourceManager().getMemoryBufferSizes().malloc_bytes; const Preprocessor &PP = CI.getPreprocessor(); Stats->BuildSize += PP.getTotalMemory(); if (PreprocessingRecord *PRec = PP.getPreprocessingRecord()) Stats->BuildSize += PRec->getTotalMemory(); Stats->BuildSize += PP.getHeaderSearchInfo().getTotalMemory(); } } void BeforeExecute(CompilerInstance &CI) override { LangOpts = &CI.getLangOpts(); SourceMgr = &CI.getSourceManager(); PP = &CI.getPreprocessor(); Includes.collect(CI); Pragmas.record(CI); if (BeforeExecuteCallback) BeforeExecuteCallback(CI); } std::unique_ptr<PPCallbacks> createPPCallbacks() override { assert(SourceMgr && LangOpts && PP && "SourceMgr, LangOpts and PP must be set at this point"); return std::make_unique<PPChainedCallbacks>( std::make_unique<CollectMainFileMacros>(*PP, Macros), collectPragmaMarksCallback(*SourceMgr, Marks)); } static bool isLikelyForwardingFunction(FunctionTemplateDecl *FT) { const auto *FD = FT->getTemplatedDecl(); const auto NumParams = FD->getNumParams(); // Check whether its last parameter is a parameter pack... if (NumParams > 0) { const auto *LastParam = FD->getParamDecl(NumParams - 1); if (const auto *PET = dyn_cast<PackExpansionType>(LastParam->getType())) { // ... of the type T&&... or T... const auto BaseType = PET->getPattern().getNonReferenceType(); if (const auto *TTPT = dyn_cast<TemplateTypeParmType>(BaseType.getTypePtr())) { // ... whose template parameter comes from the function directly if (FT->getTemplateParameters()->getDepth() == TTPT->getDepth()) { return true; } } } } return false; } bool shouldSkipFunctionBody(Decl *D) override { // Usually we don't need to look inside the bodies of header functions // to understand the program. However when forwarding function like // emplace() forward their arguments to some other function, the // interesting overload resolution happens inside the forwarding // function's body. To provide more meaningful diagnostics, // code completion, and parameter hints we should parse (and later // instantiate) the bodies. if (auto *FT = llvm::dyn_cast<clang::FunctionTemplateDecl>(D)) { if (ParseForwardingFunctions) { // Don't skip parsing the body if it looks like a forwarding function if (isLikelyForwardingFunction(FT)) return false; } else { // By default, only take care of make_unique // std::make_unique is trivial, and we diagnose bad constructor calls. if (const auto *II = FT->getDeclName().getAsIdentifierInfo()) { if (II->isStr("make_unique") && FT->isInStdNamespace()) return false; } } } return true; } private: PathRef File; IncludeStructure Includes; include_cleaner::PragmaIncludes Pragmas; MainFileMacros Macros; std::vector<PragmaMark> Marks; bool IsMainFileIncludeGuarded = false; const clang::LangOptions *LangOpts = nullptr; const SourceManager *SourceMgr = nullptr; const Preprocessor *PP = nullptr; PreambleBuildStats *Stats; bool ParseForwardingFunctions; std::function<void(CompilerInstance &)> BeforeExecuteCallback; std::optional<CapturedASTCtx> CapturedCtx; }; // Represents directives other than includes, where basic textual information is // enough. struct TextualPPDirective { unsigned DirectiveLine; // Full text that's representing the directive, including the `#`. std::string Text; unsigned Offset; tok::PPKeywordKind Directive = tok::PPKeywordKind::pp_not_keyword; // Name of the macro being defined in the case of a #define directive. std::string MacroName; bool operator==(const TextualPPDirective &RHS) const { return std::tie(DirectiveLine, Offset, Text) == std::tie(RHS.DirectiveLine, RHS.Offset, RHS.Text); } }; // Formats a PP directive consisting of Prefix (e.g. "#define ") and Body ("X // 10"). The formatting is copied so that the tokens in Body have PresumedLocs // with correct columns and lines. std::string spellDirective(llvm::StringRef Prefix, CharSourceRange DirectiveRange, const LangOptions &LangOpts, const SourceManager &SM, unsigned &DirectiveLine, unsigned &Offset) { std::string SpelledDirective; llvm::raw_string_ostream OS(SpelledDirective); OS << Prefix; // Make sure DirectiveRange is a char range and doesn't contain macro ids. DirectiveRange = SM.getExpansionRange(DirectiveRange); if (DirectiveRange.isTokenRange()) { DirectiveRange.setEnd( Lexer::getLocForEndOfToken(DirectiveRange.getEnd(), 0, SM, LangOpts)); } auto DecompLoc = SM.getDecomposedLoc(DirectiveRange.getBegin()); DirectiveLine = SM.getLineNumber(DecompLoc.first, DecompLoc.second); Offset = DecompLoc.second; auto TargetColumn = SM.getColumnNumber(DecompLoc.first, DecompLoc.second) - 1; // Pad with spaces before DirectiveRange to make sure it will be on right // column when patched. if (Prefix.size() <= TargetColumn) { // There is enough space for Prefix and space before directive, use it. // We try to squeeze the Prefix into the same line whenever we can, as // putting onto a separate line won't work at the beginning of the file. OS << std::string(TargetColumn - Prefix.size(), ' '); } else { // Prefix was longer than the space we had. We produce e.g.: // #line N-1 // #define \ // X 10 OS << "\\\n" << std::string(TargetColumn, ' '); // Decrement because we put an additional line break before // DirectiveRange.begin(). --DirectiveLine; } OS << toSourceCode(SM, DirectiveRange.getAsRange()); return OS.str(); } // Collects #define directives inside the main file. struct DirectiveCollector : public PPCallbacks { DirectiveCollector(const Preprocessor &PP, std::vector<TextualPPDirective> &TextualDirectives) : LangOpts(PP.getLangOpts()), SM(PP.getSourceManager()), TextualDirectives(TextualDirectives) {} void FileChanged(SourceLocation Loc, FileChangeReason Reason, SrcMgr::CharacteristicKind FileType, FileID PrevFID) override { InMainFile = SM.isWrittenInMainFile(Loc); } void MacroDefined(const Token &MacroNameTok, const MacroDirective *MD) override { if (!InMainFile) return; TextualDirectives.emplace_back(); TextualPPDirective &TD = TextualDirectives.back(); TD.Directive = tok::pp_define; TD.MacroName = MacroNameTok.getIdentifierInfo()->getName().str(); const auto *MI = MD->getMacroInfo(); TD.Text = spellDirective("#define ", CharSourceRange::getTokenRange( MI->getDefinitionLoc(), MI->getDefinitionEndLoc()), LangOpts, SM, TD.DirectiveLine, TD.Offset); } private: bool InMainFile = true; const LangOptions &LangOpts; const SourceManager &SM; std::vector<TextualPPDirective> &TextualDirectives; }; struct ScannedPreamble { std::vector<Inclusion> Includes; std::vector<TextualPPDirective> TextualDirectives; // Literal lines of the preamble contents. std::vector<llvm::StringRef> Lines; PreambleBounds Bounds = {0, false}; std::vector<PragmaMark> Marks; MainFileMacros Macros; }; /// Scans the preprocessor directives in the preamble section of the file by /// running preprocessor over \p Contents. Returned includes do not contain /// resolved paths. \p Cmd is used to build the compiler invocation, which might /// stat/read files. llvm::Expected<ScannedPreamble> scanPreamble(llvm::StringRef Contents, const tooling::CompileCommand &Cmd) { class EmptyFS : public ThreadsafeFS { private: llvm::IntrusiveRefCntPtr<llvm::vfs::FileSystem> viewImpl() const override { return new llvm::vfs::InMemoryFileSystem; } }; EmptyFS FS; // Build and run Preprocessor over the preamble. ParseInputs PI; // Memory buffers below expect null-terminated && non-null strings. So make // sure to always use PI.Contents! PI.Contents = Contents.str(); PI.TFS = &FS; PI.CompileCommand = Cmd; IgnoringDiagConsumer IgnoreDiags; auto CI = buildCompilerInvocation(PI, IgnoreDiags); if (!CI) return error("failed to create compiler invocation"); CI->getDiagnosticOpts().IgnoreWarnings = true; auto ContentsBuffer = llvm::MemoryBuffer::getMemBuffer(PI.Contents); // This means we're scanning (though not preprocessing) the preamble section // twice. However, it's important to precisely follow the preamble bounds used // elsewhere. auto Bounds = ComputePreambleBounds(*CI->getLangOpts(), *ContentsBuffer, 0); auto PreambleContents = llvm::MemoryBuffer::getMemBufferCopy( llvm::StringRef(PI.Contents).take_front(Bounds.Size)); auto Clang = prepareCompilerInstance( std::move(CI), nullptr, std::move(PreambleContents), // Provide an empty FS to prevent preprocessor from performing IO. This // also implies missing resolved paths for includes. FS.view(std::nullopt), IgnoreDiags); if (Clang->getFrontendOpts().Inputs.empty()) return error("compiler instance had no inputs"); // We are only interested in main file includes. Clang->getPreprocessorOpts().SingleFileParseMode = true; Clang->getPreprocessorOpts().UsePredefines = false; PreprocessOnlyAction Action; if (!Action.BeginSourceFile(*Clang, Clang->getFrontendOpts().Inputs[0])) return error("failed BeginSourceFile"); Preprocessor &PP = Clang->getPreprocessor(); const auto &SM = PP.getSourceManager(); IncludeStructure Includes; Includes.collect(*Clang); ScannedPreamble SP; SP.Bounds = Bounds; PP.addPPCallbacks( std::make_unique<DirectiveCollector>(PP, SP.TextualDirectives)); PP.addPPCallbacks(collectPragmaMarksCallback(SM, SP.Marks)); PP.addPPCallbacks(std::make_unique<CollectMainFileMacros>(PP, SP.Macros)); if (llvm::Error Err = Action.Execute()) return std::move(Err); Action.EndSourceFile(); SP.Includes = std::move(Includes.MainFileIncludes); llvm::append_range(SP.Lines, llvm::split(Contents, "\n")); return SP; } const char *spellingForIncDirective(tok::PPKeywordKind IncludeDirective) { switch (IncludeDirective) { case tok::pp_include: return "include"; case tok::pp_import: return "import"; case tok::pp_include_next: return "include_next"; default: break; } llvm_unreachable("not an include directive"); } // Accumulating wall time timer. Similar to llvm::Timer, but much cheaper, // it only tracks wall time. // Since this is a generic timer, We may want to move this to support/ if we // find a use case outside of FS time tracking. class WallTimer { public: WallTimer() : TotalTime(std::chrono::steady_clock::duration::zero()) {} // [Re-]Start the timer. void startTimer() { StartTime = std::chrono::steady_clock::now(); } // Stop the timer and update total time. void stopTimer() { TotalTime += std::chrono::steady_clock::now() - StartTime; } // Return total time, in seconds. double getTime() { return std::chrono::duration<double>(TotalTime).count(); } private: std::chrono::steady_clock::duration TotalTime; std::chrono::steady_clock::time_point StartTime; }; class WallTimerRegion { public: WallTimerRegion(WallTimer &T) : T(T) { T.startTimer(); } ~WallTimerRegion() { T.stopTimer(); } private: WallTimer &T; }; // Used by TimerFS, tracks time spent in status() and getBuffer() calls while // proxying to underlying File implementation. class TimerFile : public llvm::vfs::File { public: TimerFile(WallTimer &Timer, std::unique_ptr<File> InnerFile) : Timer(Timer), InnerFile(std::move(InnerFile)) {} llvm::ErrorOr<llvm::vfs::Status> status() override { WallTimerRegion T(Timer); return InnerFile->status(); } llvm::ErrorOr<std::unique_ptr<llvm::MemoryBuffer>> getBuffer(const Twine &Name, int64_t FileSize, bool RequiresNullTerminator, bool IsVolatile) override { WallTimerRegion T(Timer); return InnerFile->getBuffer(Name, FileSize, RequiresNullTerminator, IsVolatile); } std::error_code close() override { WallTimerRegion T(Timer); return InnerFile->close(); } private: WallTimer &Timer; std::unique_ptr<llvm::vfs::File> InnerFile; }; // A wrapper for FileSystems that tracks the amount of time spent in status() // and openFileForRead() calls. class TimerFS : public llvm::vfs::ProxyFileSystem { public: TimerFS(llvm::IntrusiveRefCntPtr<llvm::vfs::FileSystem> FS) : ProxyFileSystem(std::move(FS)) {} llvm::ErrorOr<std::unique_ptr<llvm::vfs::File>> openFileForRead(const llvm::Twine &Path) override { WallTimerRegion T(Timer); auto FileOr = getUnderlyingFS().openFileForRead(Path); if (!FileOr) return FileOr; return std::make_unique<TimerFile>(Timer, std::move(FileOr.get())); } llvm::ErrorOr<llvm::vfs::Status> status(const llvm::Twine &Path) override { WallTimerRegion T(Timer); return getUnderlyingFS().status(Path); } double getTime() { return Timer.getTime(); } private: WallTimer Timer; }; // Helpers for patching diagnostics between two versions of file contents. class DiagPatcher { llvm::ArrayRef<llvm::StringRef> OldLines; llvm::ArrayRef<llvm::StringRef> CurrentLines; llvm::StringMap<llvm::SmallVector<int>> CurrentContentsToLine; // Translates a range from old lines to current lines. // Finds the consecutive set of lines that corresponds to the same contents in // old and current, and applies the same translation to the range. // Returns true if translation succeeded. bool translateRange(Range &R) { int OldStart = R.start.line; int OldEnd = R.end.line; assert(OldStart <= OldEnd); size_t RangeLen = OldEnd - OldStart + 1; auto RangeContents = OldLines.slice(OldStart).take_front(RangeLen); // Make sure the whole range is covered in old contents. if (RangeContents.size() < RangeLen) return false; std::optional<int> Closest; for (int AlternateLine : CurrentContentsToLine.lookup(RangeContents[0])) { // Check if AlternateLine matches all lines in the range. if (RangeContents != CurrentLines.slice(AlternateLine).take_front(RangeLen)) continue; int Delta = AlternateLine - OldStart; if (!Closest.has_value() || abs(Delta) < abs(*Closest)) Closest = Delta; } // Couldn't find any viable matches in the current contents. if (!Closest.has_value()) return false; R.start.line += *Closest; R.end.line += *Closest; return true; } // Translates a Note by patching its range when inside main file. Returns true // on success. bool translateNote(Note &N) { if (!N.InsideMainFile) return true; if (translateRange(N.Range)) return true; return false; } // Tries to translate all the edit ranges inside the fix. Returns true on // success. On failure fixes might be in an invalid state. bool translateFix(Fix &F) { return llvm::all_of( F.Edits, [this](TextEdit &E) { return translateRange(E.range); }); } public: DiagPatcher(llvm::ArrayRef<llvm::StringRef> OldLines, llvm::ArrayRef<llvm::StringRef> CurrentLines) { this->OldLines = OldLines; this->CurrentLines = CurrentLines; for (int Line = 0, E = CurrentLines.size(); Line != E; ++Line) { llvm::StringRef Contents = CurrentLines[Line]; CurrentContentsToLine[Contents].push_back(Line); } } // Translate diagnostic by moving its main range to new location (if inside // the main file). Preserve all the notes and fixes that can be translated to // new contents. // Drops the whole diagnostic if main range can't be patched. std::optional<Diag> translateDiag(const Diag &D) { Range NewRange = D.Range; // Patch range if it's inside main file. if (D.InsideMainFile && !translateRange(NewRange)) { // Drop the diagnostic if we couldn't patch the range. return std::nullopt; } Diag NewD = D; NewD.Range = NewRange; // Translate ranges inside notes and fixes too, dropping the ones that are // no longer relevant. llvm::erase_if(NewD.Notes, [this](Note &N) { return !translateNote(N); }); llvm::erase_if(NewD.Fixes, [this](Fix &F) { return !translateFix(F); }); return NewD; } }; } // namespace std::shared_ptr<const PreambleData> buildPreamble(PathRef FileName, CompilerInvocation CI, const ParseInputs &Inputs, bool StoreInMemory, PreambleParsedCallback PreambleCallback, PreambleBuildStats *Stats) { // Note that we don't need to copy the input contents, preamble can live // without those. auto ContentsBuffer = llvm::MemoryBuffer::getMemBuffer(Inputs.Contents, FileName); auto Bounds = ComputePreambleBounds(*CI.getLangOpts(), *ContentsBuffer, 0); trace::Span Tracer("BuildPreamble"); SPAN_ATTACH(Tracer, "File", FileName); std::vector<std::unique_ptr<FeatureModule::ASTListener>> ASTListeners; if (Inputs.FeatureModules) { for (auto &M : *Inputs.FeatureModules) { if (auto Listener = M.astListeners()) ASTListeners.emplace_back(std::move(Listener)); } } StoreDiags PreambleDiagnostics; PreambleDiagnostics.setDiagCallback( [&ASTListeners](const clang::Diagnostic &D, clangd::Diag &Diag) { llvm::for_each(ASTListeners, [&](const auto &L) { L->sawDiagnostic(D, Diag); }); }); llvm::IntrusiveRefCntPtr<DiagnosticsEngine> PreambleDiagsEngine = CompilerInstance::createDiagnostics(&CI.getDiagnosticOpts(), &PreambleDiagnostics, /*ShouldOwnClient=*/false); const Config &Cfg = Config::current(); PreambleDiagnostics.setLevelAdjuster([&](DiagnosticsEngine::Level DiagLevel, const clang::Diagnostic &Info) { if (Cfg.Diagnostics.SuppressAll || isBuiltinDiagnosticSuppressed(Info.getID(), Cfg.Diagnostics.Suppress, *CI.getLangOpts())) return DiagnosticsEngine::Ignored; switch (Info.getID()) { case diag::warn_no_newline_eof: case diag::warn_cxx98_compat_no_newline_eof: case diag::ext_no_newline_eof: // If the preamble doesn't span the whole file, drop the no newline at // eof warnings. return Bounds.Size != ContentsBuffer->getBufferSize() ? DiagnosticsEngine::Level::Ignored : DiagLevel; } return DiagLevel; }); // Skip function bodies when building the preamble to speed up building // the preamble and make it smaller. assert(!CI.getFrontendOpts().SkipFunctionBodies); CI.getFrontendOpts().SkipFunctionBodies = true; // We don't want to write comment locations into PCH. They are racy and slow // to read back. We rely on dynamic index for the comments instead. CI.getPreprocessorOpts().WriteCommentListToPCH = false; CppFilePreambleCallbacks CapturedInfo( FileName, Stats, Inputs.Opts.PreambleParseForwardingFunctions, [&ASTListeners](CompilerInstance &CI) { for (const auto &L : ASTListeners) L->beforeExecute(CI); }); auto VFS = Inputs.TFS->view(Inputs.CompileCommand.Directory); llvm::SmallString<32> AbsFileName(FileName); VFS->makeAbsolute(AbsFileName); auto StatCache = std::make_shared<PreambleFileStatusCache>(AbsFileName); auto StatCacheFS = StatCache->getProducingFS(VFS); llvm::IntrusiveRefCntPtr<TimerFS> TimedFS(new TimerFS(StatCacheFS)); WallTimer PreambleTimer; PreambleTimer.startTimer(); auto BuiltPreamble = PrecompiledPreamble::Build( CI, ContentsBuffer.get(), Bounds, *PreambleDiagsEngine, Stats ? TimedFS : StatCacheFS, std::make_shared<PCHContainerOperations>(), StoreInMemory, /*StoragePath=*/"", CapturedInfo); PreambleTimer.stopTimer(); // Reset references to ref-counted-ptrs before executing the callbacks, to // prevent resetting them concurrently. PreambleDiagsEngine.reset(); CI.DiagnosticOpts.reset(); // When building the AST for the main file, we do want the function // bodies. CI.getFrontendOpts().SkipFunctionBodies = false; if (Stats != nullptr) { Stats->TotalBuildTime = PreambleTimer.getTime(); Stats->FileSystemTime = TimedFS->getTime(); Stats->SerializedSize = BuiltPreamble ? BuiltPreamble->getSize() : 0; } if (BuiltPreamble) { log("Built preamble of size {0} for file {1} version {2} in {3} seconds", BuiltPreamble->getSize(), FileName, Inputs.Version, PreambleTimer.getTime()); std::vector<Diag> Diags = PreambleDiagnostics.take(); auto Result = std::make_shared<PreambleData>(std::move(*BuiltPreamble)); Result->Version = Inputs.Version; Result->CompileCommand = Inputs.CompileCommand; Result->Diags = std::move(Diags); Result->Includes = CapturedInfo.takeIncludes(); Result->Pragmas = std::make_shared<const include_cleaner::PragmaIncludes>( CapturedInfo.takePragmaIncludes()); Result->Macros = CapturedInfo.takeMacros(); Result->Marks = CapturedInfo.takeMarks(); Result->StatCache = StatCache; Result->MainIsIncludeGuarded = CapturedInfo.isMainFileIncludeGuarded(); if (PreambleCallback) { trace::Span Tracer("Running PreambleCallback"); auto Ctx = CapturedInfo.takeLife(); // Stat cache is thread safe only when there are no producers. Hence // change the VFS underneath to a consuming fs. Ctx->getFileManager().setVirtualFileSystem( Result->StatCache->getConsumingFS(VFS)); // While extending the life of FileMgr and VFS, StatCache should also be // extended. Ctx->setStatCache(Result->StatCache); PreambleCallback(std::move(*Ctx), Result->Pragmas); } return Result; } elog("Could not build a preamble for file {0} version {1}: {2}", FileName, Inputs.Version, BuiltPreamble.getError().message()); for (const Diag &D : PreambleDiagnostics.take()) { if (D.Severity < DiagnosticsEngine::Error) continue; // Not an ideal way to show errors, but better than nothing! elog(" error: {0}", D.Message); } return nullptr; } bool isPreambleCompatible(const PreambleData &Preamble, const ParseInputs &Inputs, PathRef FileName, const CompilerInvocation &CI) { auto ContentsBuffer = llvm::MemoryBuffer::getMemBuffer(Inputs.Contents, FileName); auto Bounds = ComputePreambleBounds(*CI.getLangOpts(), *ContentsBuffer, 0); auto VFS = Inputs.TFS->view(Inputs.CompileCommand.Directory); return compileCommandsAreEqual(Inputs.CompileCommand, Preamble.CompileCommand) && Preamble.Preamble.CanReuse(CI, *ContentsBuffer, Bounds, *VFS); } void escapeBackslashAndQuotes(llvm::StringRef Text, llvm::raw_ostream &OS) { for (char C : Text) { switch (C) { case '\\': case '"': OS << '\\'; break; default: break; } OS << C; } } // Translate diagnostics from baseline into modified for the lines that have the // same spelling. static std::vector<Diag> patchDiags(llvm::ArrayRef<Diag> BaselineDiags, const ScannedPreamble &BaselineScan, const ScannedPreamble &ModifiedScan) { std::vector<Diag> PatchedDiags; if (BaselineDiags.empty()) return PatchedDiags; DiagPatcher Patcher(BaselineScan.Lines, ModifiedScan.Lines); for (auto &D : BaselineDiags) { if (auto NewD = Patcher.translateDiag(D)) PatchedDiags.emplace_back(std::move(*NewD)); } return PatchedDiags; } static std::string getPatchName(llvm::StringRef FileName) { // This shouldn't coincide with any real file name. llvm::SmallString<128> PatchName; llvm::sys::path::append(PatchName, llvm::sys::path::parent_path(FileName), PreamblePatch::HeaderName); return PatchName.str().str(); } PreamblePatch PreamblePatch::create(llvm::StringRef FileName, const ParseInputs &Modified, const PreambleData &Baseline, PatchType PatchType) { trace::Span Tracer("CreatePreamblePatch"); SPAN_ATTACH(Tracer, "File", FileName); assert(llvm::sys::path::is_absolute(FileName) && "relative FileName!"); // First scan preprocessor directives in Baseline and Modified. These will be // used to figure out newly added directives in Modified. Scanning can fail, // the code just bails out and creates an empty patch in such cases, as: // - If scanning for Baseline fails, no knowledge of existing includes hence // patch will contain all the includes in Modified. Leading to rebuild of // whole preamble, which is terribly slow. // - If scanning for Modified fails, cannot figure out newly added ones so // there's nothing to do but generate an empty patch. auto BaselineScan = scanPreamble(Baseline.Preamble.getContents(), Modified.CompileCommand); if (!BaselineScan) { elog("Failed to scan baseline of {0}: {1}", FileName, BaselineScan.takeError()); return PreamblePatch::unmodified(Baseline); } auto ModifiedScan = scanPreamble(Modified.Contents, Modified.CompileCommand); if (!ModifiedScan) { elog("Failed to scan modified contents of {0}: {1}", FileName, ModifiedScan.takeError()); return PreamblePatch::unmodified(Baseline); } bool IncludesChanged = BaselineScan->Includes != ModifiedScan->Includes; bool DirectivesChanged = BaselineScan->TextualDirectives != ModifiedScan->TextualDirectives; if ((PatchType == PatchType::MacroDirectives || !IncludesChanged) && !DirectivesChanged) return PreamblePatch::unmodified(Baseline); PreamblePatch PP; PP.Baseline = &Baseline; PP.PatchFileName = getPatchName(FileName); PP.ModifiedBounds = ModifiedScan->Bounds; llvm::raw_string_ostream Patch(PP.PatchContents); // Set default filename for subsequent #line directives Patch << "#line 0 \""; // FileName part of a line directive is subject to backslash escaping, which // might lead to problems on windows especially. escapeBackslashAndQuotes(FileName, Patch); Patch << "\"\n"; if (IncludesChanged && PatchType == PatchType::All) { // We are only interested in newly added includes, record the ones in // Baseline for exclusion. llvm::DenseMap<std::pair<tok::PPKeywordKind, llvm::StringRef>, const Inclusion *> ExistingIncludes; for (const auto &Inc : Baseline.Includes.MainFileIncludes) ExistingIncludes[{Inc.Directive, Inc.Written}] = &Inc; // There might be includes coming from disabled regions, record these for // exclusion too. note that we don't have resolved paths for those. for (const auto &Inc : BaselineScan->Includes) ExistingIncludes.try_emplace({Inc.Directive, Inc.Written}); // Calculate extra includes that needs to be inserted. for (auto &Inc : ModifiedScan->Includes) { auto It = ExistingIncludes.find({Inc.Directive, Inc.Written}); // Include already present in the baseline preamble. Set resolved path and // put into preamble includes. if (It != ExistingIncludes.end()) { if (It->second) { // If this header is included in an active region of the baseline // preamble, preserve it. auto &PatchedInc = PP.PreambleIncludes.emplace_back(); // Copy everything from existing include, apart from the location, // when it's coming from baseline preamble. PatchedInc = *It->second; PatchedInc.HashLine = Inc.HashLine; PatchedInc.HashOffset = Inc.HashOffset; } continue; } // Include is new in the modified preamble. Inject it into the patch and // use #line to set the presumed location to where it is spelled. auto LineCol = offsetToClangLineColumn(Modified.Contents, Inc.HashOffset); Patch << llvm::formatv("#line {0}\n", LineCol.first); Patch << llvm::formatv( "#{0} {1}\n", spellingForIncDirective(Inc.Directive), Inc.Written); } } else { // Make sure we have the full set of includes available even when we're not // patching. As these are used by features we provide afterwards like hover, // go-to-def or include-cleaner when preamble is stale. PP.PreambleIncludes = Baseline.Includes.MainFileIncludes; } if (DirectivesChanged) { // We need to patch all the directives, since they are order dependent. e.g: // #define BAR(X) NEW(X) // Newly introduced in Modified // #define BAR(X) OLD(X) // Exists in the Baseline // // If we've patched only the first directive, the macro definition would've // been wrong for the rest of the file, since patch is applied after the // baseline preamble. // // Note that we deliberately ignore conditional directives and undefs to // reduce complexity. The former might cause problems because scanning is // imprecise and might pick directives from disabled regions. for (const auto &TD : ModifiedScan->TextualDirectives) { // Introduce an #undef directive before #defines to suppress any // re-definition warnings. if (TD.Directive == tok::pp_define) Patch << "#undef " << TD.MacroName << '\n'; Patch << "#line " << TD.DirectiveLine << '\n'; Patch << TD.Text << '\n'; } } PP.PatchedDiags = patchDiags(Baseline.Diags, *BaselineScan, *ModifiedScan); PP.PatchedMarks = std::move(ModifiedScan->Marks); PP.PatchedMacros = std::move(ModifiedScan->Macros); dlog("Created preamble patch: {0}", Patch.str()); Patch.flush(); return PP; } PreamblePatch PreamblePatch::createFullPatch(llvm::StringRef FileName, const ParseInputs &Modified, const PreambleData &Baseline) { return create(FileName, Modified, Baseline, PatchType::All); } PreamblePatch PreamblePatch::createMacroPatch(llvm::StringRef FileName, const ParseInputs &Modified, const PreambleData &Baseline) { return create(FileName, Modified, Baseline, PatchType::MacroDirectives); } void PreamblePatch::apply(CompilerInvocation &CI) const { // No need to map an empty file. if (PatchContents.empty()) return; auto &PPOpts = CI.getPreprocessorOpts(); auto PatchBuffer = // we copy here to ensure contents are still valid if CI outlives the // PreamblePatch. llvm::MemoryBuffer::getMemBufferCopy(PatchContents, PatchFileName); // CI will take care of the lifetime of the buffer. PPOpts.addRemappedFile(PatchFileName, PatchBuffer.release()); // The patch will be parsed after loading the preamble ast and before parsing // the main file. PPOpts.Includes.push_back(PatchFileName); } std::vector<Inclusion> PreamblePatch::preambleIncludes() const { return PreambleIncludes; } PreamblePatch PreamblePatch::unmodified(const PreambleData &Preamble) { PreamblePatch PP; PP.Baseline = &Preamble; PP.PreambleIncludes = Preamble.Includes.MainFileIncludes; PP.ModifiedBounds = Preamble.Preamble.getBounds(); PP.PatchedDiags = Preamble.Diags; return PP; } llvm::ArrayRef<PragmaMark> PreamblePatch::marks() const { if (PatchContents.empty()) return Baseline->Marks; return PatchedMarks; } const MainFileMacros &PreamblePatch::mainFileMacros() const { if (PatchContents.empty()) return Baseline->Macros; return PatchedMacros; } const FileEntry *PreamblePatch::getPatchEntry(llvm::StringRef MainFilePath, const SourceManager &SM) { auto PatchFilePath = getPatchName(MainFilePath); if (auto File = SM.getFileManager().getFile(PatchFilePath)) return *File; return nullptr; } } // namespace clangd } // namespace clang