//===--- SerializedModuleLoader.cpp - Import Swift modules ----------------===// // // This source file is part of the Swift.org open source project // // Copyright (c) 2014 - 2017 Apple Inc. and the Swift project authors // Licensed under Apache License v2.0 with Runtime Library Exception // // See https://swift.org/LICENSE.txt for license information // See https://swift.org/CONTRIBUTORS.txt for the list of Swift project authors // //===----------------------------------------------------------------------===// #include "swift/Serialization/SerializedModuleLoader.h" #include "swift/Serialization/ModuleFile.h" #include "swift/AST/ASTContext.h" #include "swift/AST/DiagnosticsSema.h" #include "swift/Basic/Defer.h" #include "swift/Basic/FileTypes.h" #include "swift/Basic/STLExtras.h" #include "swift/Basic/SourceManager.h" #include "swift/Basic/Version.h" #include "llvm/ADT/SmallString.h" #include "llvm/ADT/StringSet.h" #include "llvm/Support/FileSystem.h" #include "llvm/Support/MemoryBuffer.h" #include "llvm/Support/Path.h" #include "llvm/Support/Debug.h" #include using namespace swift; using swift::version::Version; namespace { } // end unnamed namespace // Defined out-of-line so that we can see ~ModuleFile. SerializedModuleLoaderBase::SerializedModuleLoaderBase(ASTContext &ctx, DependencyTracker *tracker, ModuleLoadingMode loadMode) : ModuleLoader(tracker), Ctx(ctx), LoadMode(loadMode) {} SerializedModuleLoaderBase::~SerializedModuleLoaderBase() = default; SerializedModuleLoader::~SerializedModuleLoader() = default; std::error_code SerializedModuleLoaderBase::openModuleFiles( AccessPathElem ModuleID, StringRef ModulePath, StringRef ModuleDocPath, std::unique_ptr *ModuleBuffer, std::unique_ptr *ModuleDocBuffer) { assert(((ModuleBuffer && ModuleDocBuffer) || (!ModuleBuffer && !ModuleDocBuffer)) && "Module and Module Doc buffer must both be initialized or NULL"); llvm::vfs::FileSystem &FS = *Ctx.SourceMgr.getFileSystem(); // Try to open the module file first. If we fail, don't even look for the // module documentation file. // If there are no buffers to load into, simply check for the existence of // the module file. if (!(ModuleBuffer || ModuleDocBuffer)) { llvm::ErrorOr statResult = FS.status(ModulePath); if (!statResult) return statResult.getError(); if (!statResult->exists()) return std::make_error_code(std::errc::no_such_file_or_directory); // FIXME: clang::vfs::FileSystem doesn't give us information on whether or // not we can /read/ the file without actually trying to do so. return std::error_code(); } llvm::ErrorOr> ModuleOrErr = FS.getBufferForFile(ModulePath); if (!ModuleOrErr) return ModuleOrErr.getError(); // Try to open the module documentation file. If it does not exist, ignore // the error. However, pass though all other errors. llvm::ErrorOr> ModuleDocOrErr = FS.getBufferForFile(ModuleDocPath); if (!ModuleDocOrErr && ModuleDocOrErr.getError() != std::errc::no_such_file_or_directory) { return ModuleDocOrErr.getError(); } *ModuleBuffer = std::move(ModuleOrErr.get()); if (ModuleDocOrErr) *ModuleDocBuffer = std::move(ModuleDocOrErr.get()); return std::error_code(); } std::error_code SerializedModuleLoader::findModuleFilesInDirectory( AccessPathElem ModuleID, StringRef DirPath, StringRef ModuleFilename, StringRef ModuleDocFilename, std::unique_ptr *ModuleBuffer, std::unique_ptr *ModuleDocBuffer) { if (LoadMode == ModuleLoadingMode::OnlyParseable) return std::make_error_code(std::errc::not_supported); llvm::SmallString<256> ModulePath{DirPath}; llvm::sys::path::append(ModulePath, ModuleFilename); llvm::SmallString<256> ModuleDocPath{DirPath}; llvm::sys::path::append(ModuleDocPath, ModuleDocFilename); return SerializedModuleLoaderBase::openModuleFiles(ModuleID, ModulePath, ModuleDocPath, ModuleBuffer, ModuleDocBuffer); } bool SerializedModuleLoader::maybeDiagnoseArchitectureMismatch( SourceLoc sourceLocation, StringRef moduleName, StringRef archName, StringRef directoryPath) { clang::vfs::FileSystem &fs = *Ctx.SourceMgr.getFileSystem(); std::error_code errorCode; std::string foundArchs; for (clang::vfs::directory_iterator directoryIterator = fs.dir_begin(directoryPath, errorCode), endIterator; directoryIterator != endIterator; directoryIterator.increment(errorCode)) { if (errorCode) return false; StringRef filePath = directoryIterator->getName(); StringRef extension = llvm::sys::path::extension(filePath); if (file_types::lookupTypeForExtension(extension) == file_types::TY_SwiftModuleFile) { if (!foundArchs.empty()) foundArchs += ", "; foundArchs += llvm::sys::path::stem(filePath).str(); } } if (foundArchs.empty()) { // Maybe this swiftmodule directory only contains swiftinterfaces, or // maybe something else is going on. Regardless, we shouldn't emit a // possibly incorrect diagnostic. return false; } Ctx.Diags.diagnose(sourceLocation, diag::sema_no_import_arch, moduleName, archName, foundArchs); return true; } static std::pair, llvm::SmallString<16>> getArchSpecificModuleFileNames(StringRef archName) { llvm::SmallString<16> archFile, archDocFile; if (!archName.empty()) { archFile += archName; archFile += '.'; archFile += file_types::getExtension(file_types::TY_SwiftModuleFile); archDocFile += archName; archDocFile += '.'; archDocFile += file_types::getExtension(file_types::TY_SwiftModuleDocFile); } return {archFile, archDocFile}; } bool SerializedModuleLoaderBase::findModule(AccessPathElem moduleID, std::unique_ptr *moduleBuffer, std::unique_ptr *moduleDocBuffer, bool &isFramework) { llvm::SmallString<64> moduleName(moduleID.first.str()); llvm::SmallString<64> moduleFilename(moduleName); moduleFilename += '.'; moduleFilename += file_types::getExtension(file_types::TY_SwiftModuleFile); llvm::SmallString<64> moduleDocFilename(moduleID.first.str()); moduleDocFilename += '.'; moduleDocFilename += file_types::getExtension(file_types::TY_SwiftModuleDocFile); StringRef archName = Ctx.LangOpts.Target.getArchName(); auto archFileNames = getArchSpecificModuleFileNames(archName); // FIXME: We used to use "major architecture" names for these files---the // names checked in "#if arch(...)". Fall back to that name in the one case // where it's different from what Swift 4.2 supported: 32-bit ARM platforms. // We should be able to drop this once there's an Xcode that supports the // new names. StringRef alternateArchName; if (Ctx.LangOpts.Target.getArch() == llvm::Triple::ArchType::arm) alternateArchName = "arm"; auto alternateArchFileNames = getArchSpecificModuleFileNames(alternateArchName); auto &fs = *Ctx.SourceMgr.getFileSystem(); isFramework = false; llvm::SmallString<256> currPath; for (auto path : Ctx.SearchPathOpts.ImportSearchPaths) { std::error_code result; currPath = path; llvm::sys::path::append(currPath, moduleFilename.str()); llvm::ErrorOr statResult = fs.status(currPath); if (statResult && statResult->isDirectory()) { // A .swiftmodule directory contains architecture-specific files. result = findModuleFilesInDirectory(moduleID, currPath, archFileNames.first, archFileNames.second, moduleBuffer, moduleDocBuffer); if (result == std::errc::no_such_file_or_directory && !alternateArchName.empty()) { result = findModuleFilesInDirectory(moduleID, currPath, alternateArchFileNames.first, alternateArchFileNames.second, moduleBuffer, moduleDocBuffer); } if (result == std::errc::no_such_file_or_directory) { if (maybeDiagnoseArchitectureMismatch(moduleID.second, moduleName, archName, currPath)) { return false; } } } else { // We can't just return the error; the path we're looking for might not // be "Foo.swiftmodule". result = findModuleFilesInDirectory(moduleID, path, moduleFilename.str(), moduleDocFilename.str(), moduleBuffer, moduleDocBuffer); } if (!result) return true; } { llvm::SmallString<64> moduleFramework(moduleID.first.str()); moduleFramework += ".framework"; isFramework = true; auto tryFrameworkImport = [&](StringRef frameworkPath) -> bool { currPath = frameworkPath; llvm::sys::path::append(currPath, moduleFramework.str()); // Check if the framework directory exists if (!fs.exists(currPath)) { return false; } // Frameworks always use architecture-specific files within a .swiftmodule // directory. llvm::sys::path::append(currPath, "Modules", moduleFilename.str()); auto err = findModuleFilesInDirectory(moduleID, currPath, archFileNames.first, archFileNames.second, moduleBuffer, moduleDocBuffer); if (err == std::errc::no_such_file_or_directory && !alternateArchName.empty()) { err = findModuleFilesInDirectory(moduleID, currPath, alternateArchFileNames.first, alternateArchFileNames.second, moduleBuffer, moduleDocBuffer); } if (err == std::errc::no_such_file_or_directory) { if (maybeDiagnoseArchitectureMismatch(moduleID.second, moduleName, archName, currPath)) { return false; } } return !err; }; for (const auto &framepath : Ctx.SearchPathOpts.FrameworkSearchPaths) { if (tryFrameworkImport(framepath.Path)) return true; } if (Ctx.LangOpts.Target.isOSDarwin()) { // Apple platforms have extra implicit framework search paths: // $SDKROOT/System/Library/Frameworks/ and $SDKROOT/Library/Frameworks/ SmallString<256> scratch; scratch = Ctx.SearchPathOpts.SDKPath; llvm::sys::path::append(scratch, "System", "Library", "Frameworks"); if (tryFrameworkImport(scratch)) return true; scratch = Ctx.SearchPathOpts.SDKPath; llvm::sys::path::append(scratch, "Library", "Frameworks"); if (tryFrameworkImport(scratch)) return true; } } // If we're not allowed to look in the runtime library import path, stop. if (Ctx.SearchPathOpts.SkipRuntimeLibraryImportPath) return false; // Search the runtime import path. isFramework = false; return !findModuleFilesInDirectory( moduleID, Ctx.SearchPathOpts.RuntimeLibraryImportPath, moduleFilename.str(), moduleDocFilename.str(), moduleBuffer, moduleDocBuffer); } static std::pair getOSAndVersionForDiagnostics(const llvm::Triple &triple) { StringRef osName; unsigned major, minor, micro; if (triple.isMacOSX()) { // macOS triples represent their versions differently, so we have to use the // special accessor. triple.getMacOSXVersion(major, minor, micro); osName = swift::prettyPlatformString(PlatformKind::OSX); } else { triple.getOSVersion(major, minor, micro); if (triple.isWatchOS()) { osName = swift::prettyPlatformString(PlatformKind::watchOS); } else if (triple.isTvOS()) { assert(triple.isiOS() && "LLVM treats tvOS as a kind of iOS, so tvOS is checked first"); osName = swift::prettyPlatformString(PlatformKind::tvOS); } else if (triple.isiOS()) { osName = swift::prettyPlatformString(PlatformKind::iOS); } else { assert(!triple.isOSDarwin() && "unknown Apple OS"); // Fallback to the LLVM triple name. This isn't great (it won't be // capitalized or anything), but it's better than nothing. osName = triple.getOSName(); } } assert(!osName.empty()); clang::VersionTuple version; if (micro != 0) version = clang::VersionTuple(major, minor, micro); else version = clang::VersionTuple(major, minor); return {osName, version}; } FileUnit *SerializedModuleLoaderBase::loadAST( ModuleDecl &M, Optional diagLoc, std::unique_ptr moduleInputBuffer, std::unique_ptr moduleDocInputBuffer, bool isFramework) { assert(moduleInputBuffer); StringRef moduleBufferID = moduleInputBuffer->getBufferIdentifier(); StringRef moduleDocBufferID; if (moduleDocInputBuffer) moduleDocBufferID = moduleDocInputBuffer->getBufferIdentifier(); if (moduleInputBuffer->getBufferSize() % 4 != 0) { if (diagLoc) Ctx.Diags.diagnose(*diagLoc, diag::serialization_malformed_module, moduleBufferID); return nullptr; } serialization::ExtendedValidationInfo extendedInfo; std::unique_ptr loadedModuleFile; serialization::ValidationInfo loadInfo = ModuleFile::load(std::move(moduleInputBuffer), std::move(moduleDocInputBuffer), isFramework, loadedModuleFile, &extendedInfo); if (loadInfo.status == serialization::Status::Valid) { M.setResilienceStrategy(extendedInfo.getResilienceStrategy()); // We've loaded the file. Now try to bring it into the AST. auto fileUnit = new (Ctx) SerializedASTFile(M, *loadedModuleFile, extendedInfo.isSIB()); M.addFile(*fileUnit); if (extendedInfo.isTestable()) M.setTestingEnabled(); if (extendedInfo.arePrivateImportsEnabled()) M.setPrivateImportsEnabled(); auto diagLocOrInvalid = diagLoc.getValueOr(SourceLoc()); loadInfo.status = loadedModuleFile->associateWithFileContext(fileUnit, diagLocOrInvalid); if (loadInfo.status == serialization::Status::Valid) { Ctx.bumpGeneration(); LoadedModuleFiles.emplace_back(std::move(loadedModuleFile), Ctx.getCurrentGeneration()); return fileUnit; } M.removeFile(*fileUnit); } // From here on is the failure path. // Even though the module failed to load, it's possible its contents include // a source buffer that need to survive because it's already been used for // diagnostics. if (auto orphanedBuffer = loadedModuleFile->takeBufferForDiagnostics()) OrphanedMemoryBuffers.push_back(std::move(orphanedBuffer)); if (diagLoc) serialization::diagnoseSerializedASTLoadFailure( Ctx, *diagLoc, loadInfo, extendedInfo, moduleBufferID, moduleDocBufferID, loadedModuleFile.get(), M.getName()); return nullptr; } void swift::serialization::diagnoseSerializedASTLoadFailure( ASTContext &Ctx, SourceLoc diagLoc, const serialization::ValidationInfo &loadInfo, const serialization::ExtendedValidationInfo &extendedInfo, StringRef moduleBufferID, StringRef moduleDocBufferID, ModuleFile *loadedModuleFile, Identifier ModuleName) { auto diagnoseDifferentLanguageVersion = [&](StringRef shortVersion) -> bool { if (shortVersion.empty()) return false; SmallString<32> versionBuf; llvm::raw_svector_ostream versionString(versionBuf); versionString << Version::getCurrentLanguageVersion(); if (versionString.str() == shortVersion) return false; Ctx.Diags.diagnose( diagLoc, diag::serialization_module_language_version_mismatch, loadInfo.shortVersion, versionString.str(), moduleBufferID); return true; }; switch (loadInfo.status) { case serialization::Status::Valid: llvm_unreachable("At this point we know loading has failed"); case serialization::Status::FormatTooNew: if (diagnoseDifferentLanguageVersion(loadInfo.shortVersion)) break; Ctx.Diags.diagnose(diagLoc, diag::serialization_module_too_new, moduleBufferID); break; case serialization::Status::FormatTooOld: if (diagnoseDifferentLanguageVersion(loadInfo.shortVersion)) break; Ctx.Diags.diagnose(diagLoc, diag::serialization_module_too_old, ModuleName, moduleBufferID); break; case serialization::Status::Malformed: Ctx.Diags.diagnose(diagLoc, diag::serialization_malformed_module, moduleBufferID); break; case serialization::Status::MalformedDocumentation: assert(!moduleDocBufferID.empty()); Ctx.Diags.diagnose(diagLoc, diag::serialization_malformed_module, moduleDocBufferID); break; case serialization::Status::MissingDependency: { // Figure out /which/ dependencies are missing. // FIXME: Dependencies should be de-duplicated at serialization time, // not now. llvm::StringSet<> duplicates; llvm::SmallVector missing; std::copy_if( loadedModuleFile->getDependencies().begin(), loadedModuleFile->getDependencies().end(), std::back_inserter(missing), [&duplicates](const ModuleFile::Dependency &dependency) -> bool { if (dependency.isLoaded() || dependency.isHeader()) return false; return duplicates.insert(dependency.RawPath).second; }); // FIXME: only show module part of RawAccessPath assert(!missing.empty() && "unknown missing dependency?"); if (missing.size() == 1) { Ctx.Diags.diagnose(diagLoc, diag::serialization_missing_single_dependency, missing.front().getPrettyPrintedPath()); } else { llvm::SmallString<64> missingNames; missingNames += '\''; interleave(missing, [&](const ModuleFile::Dependency &next) { missingNames += next.getPrettyPrintedPath(); }, [&] { missingNames += "', '"; }); missingNames += '\''; Ctx.Diags.diagnose(diagLoc, diag::serialization_missing_dependencies, missingNames); } if (Ctx.SearchPathOpts.SDKPath.empty() && llvm::Triple(llvm::sys::getProcessTriple()).isMacOSX()) { Ctx.Diags.diagnose(SourceLoc(), diag::sema_no_import_no_sdk); Ctx.Diags.diagnose(SourceLoc(), diag::sema_no_import_no_sdk_xcrun); } break; } case serialization::Status::CircularDependency: { auto circularDependencyIter = llvm::find_if(loadedModuleFile->getDependencies(), [](const ModuleFile::Dependency &next) { return !next.Import.second->hasResolvedImports(); }); assert(circularDependencyIter != loadedModuleFile->getDependencies().end() && "circular dependency reported, but no module with unresolved " "imports found"); // FIXME: We should include the path of the circularity as well, but that's // hard because we're discovering this /while/ resolving imports, which // means the problematic modules haven't been recorded yet. Ctx.Diags.diagnose(diagLoc, diag::serialization_circular_dependency, circularDependencyIter->getPrettyPrintedPath(), ModuleName); break; } case serialization::Status::MissingShadowedModule: { Ctx.Diags.diagnose(diagLoc, diag::serialization_missing_shadowed_module, ModuleName); if (Ctx.SearchPathOpts.SDKPath.empty() && llvm::Triple(llvm::sys::getProcessTriple()).isMacOSX()) { Ctx.Diags.diagnose(SourceLoc(), diag::sema_no_import_no_sdk); Ctx.Diags.diagnose(SourceLoc(), diag::sema_no_import_no_sdk_xcrun); } break; } case serialization::Status::FailedToLoadBridgingHeader: // We already emitted a diagnostic about the bridging header. Just emit // a generic message here. Ctx.Diags.diagnose(diagLoc, diag::serialization_load_failed, ModuleName); break; case serialization::Status::NameMismatch: { // FIXME: This doesn't handle a non-debugger REPL, which should also treat // this as a non-fatal error. auto diagKind = diag::serialization_name_mismatch; if (Ctx.LangOpts.DebuggerSupport) diagKind = diag::serialization_name_mismatch_repl; Ctx.Diags.diagnose(diagLoc, diagKind, loadInfo.name, ModuleName.str()); break; } case serialization::Status::TargetIncompatible: { // FIXME: This doesn't handle a non-debugger REPL, which should also treat // this as a non-fatal error. auto diagKind = diag::serialization_target_incompatible; if (Ctx.LangOpts.DebuggerSupport) diagKind = diag::serialization_target_incompatible_repl; Ctx.Diags.diagnose(diagLoc, diagKind, ModuleName, loadInfo.targetTriple, moduleBufferID); break; } case serialization::Status::TargetTooNew: { llvm::Triple moduleTarget(llvm::Triple::normalize(loadInfo.targetTriple)); std::pair moduleOSInfo = getOSAndVersionForDiagnostics(moduleTarget); std::pair compilationOSInfo = getOSAndVersionForDiagnostics(Ctx.LangOpts.Target); // FIXME: This doesn't handle a non-debugger REPL, which should also treat // this as a non-fatal error. auto diagKind = diag::serialization_target_too_new; if (Ctx.LangOpts.DebuggerSupport) diagKind = diag::serialization_target_too_new_repl; Ctx.Diags.diagnose(diagLoc, diagKind, compilationOSInfo.first, compilationOSInfo.second, ModuleName, moduleOSInfo.second, moduleBufferID); break; } } } bool SerializedModuleLoaderBase::canImportModule(std::pair mID) { // First see if we find it in the registered memory buffers. if (!MemoryBuffers.empty()) { auto bufIter = MemoryBuffers.find(mID.first.str()); if (bufIter != MemoryBuffers.end()) { return true; } } // Otherwise look on disk. bool isFramework = false; return findModule(mID, nullptr, nullptr, isFramework); } ModuleDecl *SerializedModuleLoaderBase::loadModule(SourceLoc importLoc, ModuleDecl::AccessPathTy path) { // FIXME: Swift submodules? if (path.size() > 1) return nullptr; auto moduleID = path[0]; bool isFramework = false; std::unique_ptr moduleInputBuffer; std::unique_ptr moduleDocInputBuffer; // First see if we find it in the registered memory buffers. if (!MemoryBuffers.empty()) { // FIXME: Right now this works only with access paths of length 1. // Once submodules are designed, this needs to support suffix // matching and a search path. auto bufIter = MemoryBuffers.find(moduleID.first.str()); if (bufIter != MemoryBuffers.end()) { moduleInputBuffer = std::move(bufIter->second); MemoryBuffers.erase(bufIter); } } // Otherwise look on disk. if (!moduleInputBuffer) { if (!findModule(moduleID, &moduleInputBuffer, &moduleDocInputBuffer, isFramework)) { return nullptr; } if (dependencyTracker) dependencyTracker->addDependency(moduleInputBuffer->getBufferIdentifier(), /*isSystem=*/false); } assert(moduleInputBuffer); auto M = ModuleDecl::create(moduleID.first, Ctx); Ctx.LoadedModules[moduleID.first] = M; SWIFT_DEFER { M->setHasResolvedImports(); }; if (!loadAST(*M, moduleID.second, std::move(moduleInputBuffer), std::move(moduleDocInputBuffer), isFramework)) { M->setFailedToLoad(); } return M; } void SerializedModuleLoaderBase::loadExtensions(NominalTypeDecl *nominal, unsigned previousGeneration) { for (auto &modulePair : LoadedModuleFiles) { if (modulePair.second <= previousGeneration) continue; modulePair.first->loadExtensions(nominal); } } void SerializedModuleLoaderBase::loadObjCMethods( ClassDecl *classDecl, ObjCSelector selector, bool isInstanceMethod, unsigned previousGeneration, llvm::TinyPtrVector &methods) { for (auto &modulePair : LoadedModuleFiles) { if (modulePair.second <= previousGeneration) continue; modulePair.first->loadObjCMethods(classDecl, selector, isInstanceMethod, methods); } } void SerializedModuleLoaderBase::verifyAllModules() { #ifndef NDEBUG for (const LoadedModulePair &loaded : LoadedModuleFiles) loaded.first->verify(); #endif } //----------------------------------------------------------------------------- // SerializedASTFile implementation //----------------------------------------------------------------------------- void SerializedASTFile::getImportedModules( SmallVectorImpl &imports, ModuleDecl::ImportFilter filter) const { File.getImportedModules(imports, filter); } void SerializedASTFile::collectLinkLibrariesFromImports( ModuleDecl::LinkLibraryCallback callback) const { llvm::SmallVector Imports; File.getImportedModules(Imports, ModuleDecl::ImportFilter::All); for (auto Import : Imports) Import.second->collectLinkLibraries(callback); } void SerializedASTFile::collectLinkLibraries( ModuleDecl::LinkLibraryCallback callback) const { if (isSIB()) { collectLinkLibrariesFromImports(callback); } else { File.collectLinkLibraries(callback); } } bool SerializedASTFile::isSystemModule() const { if (auto Mod = File.getShadowedModule()) { return Mod->isSystemModule(); } return false; } void SerializedASTFile::lookupValue(ModuleDecl::AccessPathTy accessPath, DeclName name, NLKind lookupKind, SmallVectorImpl &results) const{ if (!ModuleDecl::matchesAccessPath(accessPath, name)) return; File.lookupValue(name, results); } TypeDecl *SerializedASTFile::lookupLocalType(llvm::StringRef MangledName) const{ return File.lookupLocalType(MangledName); } TypeDecl * SerializedASTFile::lookupNestedType(Identifier name, const NominalTypeDecl *parent) const { return File.lookupNestedType(name, parent); } OperatorDecl *SerializedASTFile::lookupOperator(Identifier name, DeclKind fixity) const { return File.lookupOperator(name, fixity); } PrecedenceGroupDecl * SerializedASTFile::lookupPrecedenceGroup(Identifier name) const { return File.lookupPrecedenceGroup(name); } void SerializedASTFile::lookupVisibleDecls(ModuleDecl::AccessPathTy accessPath, VisibleDeclConsumer &consumer, NLKind lookupKind) const { File.lookupVisibleDecls(accessPath, consumer, lookupKind); } void SerializedASTFile::lookupClassMembers(ModuleDecl::AccessPathTy accessPath, VisibleDeclConsumer &consumer) const{ File.lookupClassMembers(accessPath, consumer); } void SerializedASTFile::lookupClassMember(ModuleDecl::AccessPathTy accessPath, DeclName name, SmallVectorImpl &decls) const { File.lookupClassMember(accessPath, name, decls); } void SerializedASTFile::lookupObjCMethods( ObjCSelector selector, SmallVectorImpl &results) const { File.lookupObjCMethods(selector, results); } Optional SerializedASTFile::getCommentForDecl(const Decl *D) const { return File.getCommentForDecl(D); } Optional SerializedASTFile::getGroupNameForDecl(const Decl *D) const { return File.getGroupNameForDecl(D); } Optional SerializedASTFile::getSourceFileNameForDecl(const Decl *D) const { return File.getSourceFileNameForDecl(D); } Optional SerializedASTFile::getSourceOrderForDecl(const Decl *D) const { return File.getSourceOrderForDecl(D); } void SerializedASTFile::collectAllGroups(std::vector &Names) const { File.collectAllGroups(Names); }; Optional SerializedASTFile::getGroupNameByUSR(StringRef USR) const { return File.getGroupNameByUSR(USR); } void SerializedASTFile::getTopLevelDecls(SmallVectorImpl &results) const { File.getTopLevelDecls(results); } void SerializedASTFile::getPrecedenceGroups( SmallVectorImpl &results) const { File.getPrecedenceGroups(results); } void SerializedASTFile::getLocalTypeDecls(SmallVectorImpl &results) const{ File.getLocalTypeDecls(results); } void SerializedASTFile::getDisplayDecls(SmallVectorImpl &results) const { File.getDisplayDecls(results); } StringRef SerializedASTFile::getFilename() const { return File.getModuleFilename(); } const clang::Module *SerializedASTFile::getUnderlyingClangModule() const { if (auto *ShadowedModule = File.getShadowedModule()) return ShadowedModule->findUnderlyingClangModule(); return nullptr; } Identifier SerializedASTFile::getDiscriminatorForPrivateValue(const ValueDecl *D) const { Identifier discriminator = File.getDiscriminatorForPrivateValue(D); assert(!discriminator.empty() && "no discriminator found for value"); return discriminator; }