//===-- ClangModulesDeclVendor.cpp ----------------------------------------===// // // 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 "clang/Basic/TargetInfo.h" #include "clang/Frontend/CompilerInstance.h" #include "clang/Frontend/FrontendActions.h" #include "clang/Frontend/TextDiagnosticPrinter.h" #include "clang/Lex/Preprocessor.h" #include "clang/Lex/PreprocessorOptions.h" #include "clang/Parse/Parser.h" #include "clang/Sema/Lookup.h" #include "clang/Serialization/ASTReader.h" #include "llvm/Support/FileSystem.h" #include "llvm/Support/Path.h" #include "llvm/Support/Threading.h" #include "ClangHost.h" #include "ClangModulesDeclVendor.h" #include "ModuleDependencyCollector.h" #include "Plugins/TypeSystem/Clang/TypeSystemClang.h" #include "lldb/Core/ModuleList.h" #include "lldb/Host/Host.h" #include "lldb/Host/HostInfo.h" #include "lldb/Symbol/CompileUnit.h" #include "lldb/Symbol/SourceModule.h" #include "lldb/Target/Target.h" #include "lldb/Utility/FileSpec.h" #include "lldb/Utility/LLDBAssert.h" #include "lldb/Utility/Log.h" #include "lldb/Utility/ReproducerProvider.h" #include "lldb/Utility/StreamString.h" #include #include using namespace lldb_private; namespace { /// Any Clang compiler requires a consumer for diagnostics. This one stores /// them as strings so we can provide them to the user in case a module failed /// to load. class StoringDiagnosticConsumer : public clang::DiagnosticConsumer { public: StoringDiagnosticConsumer(); void HandleDiagnostic(clang::DiagnosticsEngine::Level DiagLevel, const clang::Diagnostic &info) override; void ClearDiagnostics(); void DumpDiagnostics(Stream &error_stream); void BeginSourceFile(const clang::LangOptions &LangOpts, const clang::Preprocessor *PP = nullptr) override; void EndSourceFile() override; private: typedef std::pair IDAndDiagnostic; std::vector m_diagnostics; /// The DiagnosticPrinter used for creating the full diagnostic messages /// that are stored in m_diagnostics. std::shared_ptr m_diag_printer; /// Output stream of m_diag_printer. std::shared_ptr m_os; /// Output string filled by m_os. Will be reused for different diagnostics. std::string m_output; Log *m_log; }; /// The private implementation of our ClangModulesDeclVendor. Contains all the /// Clang state required to load modules. class ClangModulesDeclVendorImpl : public ClangModulesDeclVendor { public: ClangModulesDeclVendorImpl( llvm::IntrusiveRefCntPtr diagnostics_engine, std::shared_ptr compiler_invocation, std::unique_ptr compiler_instance, std::unique_ptr parser); ~ClangModulesDeclVendorImpl() override = default; bool AddModule(const SourceModule &module, ModuleVector *exported_modules, Stream &error_stream) override; bool AddModulesForCompileUnit(CompileUnit &cu, ModuleVector &exported_modules, Stream &error_stream) override; uint32_t FindDecls(ConstString name, bool append, uint32_t max_matches, std::vector &decls) override; void ForEachMacro( const ModuleVector &modules, std::function handler) override; private: typedef llvm::DenseSet ExportedModuleSet; void ReportModuleExportsHelper(ExportedModuleSet &exports, clang::Module *module); void ReportModuleExports(ModuleVector &exports, clang::Module *module); clang::ModuleLoadResult DoGetModule(clang::ModuleIdPath path, bool make_visible); bool m_enabled = false; llvm::IntrusiveRefCntPtr m_diagnostics_engine; std::shared_ptr m_compiler_invocation; std::unique_ptr m_compiler_instance; std::unique_ptr m_parser; size_t m_source_location_index = 0; // used to give name components fake SourceLocations typedef std::vector ImportedModule; typedef std::map ImportedModuleMap; typedef llvm::DenseSet ImportedModuleSet; ImportedModuleMap m_imported_modules; ImportedModuleSet m_user_imported_modules; // We assume that every ASTContext has an TypeSystemClang, so we also store // a custom TypeSystemClang for our internal ASTContext. std::unique_ptr m_ast_context; }; } // anonymous namespace StoringDiagnosticConsumer::StoringDiagnosticConsumer() { m_log = lldb_private::GetLogIfAllCategoriesSet(LIBLLDB_LOG_EXPRESSIONS); clang::DiagnosticOptions *m_options = new clang::DiagnosticOptions(); m_os = std::make_shared(m_output); m_diag_printer = std::make_shared(*m_os, m_options); } void StoringDiagnosticConsumer::HandleDiagnostic( clang::DiagnosticsEngine::Level DiagLevel, const clang::Diagnostic &info) { // Print the diagnostic to m_output. m_output.clear(); m_diag_printer->HandleDiagnostic(DiagLevel, info); m_os->flush(); // Store the diagnostic for later. m_diagnostics.push_back(IDAndDiagnostic(DiagLevel, m_output)); } void StoringDiagnosticConsumer::ClearDiagnostics() { m_diagnostics.clear(); } void StoringDiagnosticConsumer::DumpDiagnostics(Stream &error_stream) { for (IDAndDiagnostic &diag : m_diagnostics) { switch (diag.first) { default: error_stream.PutCString(diag.second); error_stream.PutChar('\n'); break; case clang::DiagnosticsEngine::Level::Ignored: break; } } } void StoringDiagnosticConsumer::BeginSourceFile( const clang::LangOptions &LangOpts, const clang::Preprocessor *PP) { m_diag_printer->BeginSourceFile(LangOpts, PP); } void StoringDiagnosticConsumer::EndSourceFile() { m_diag_printer->EndSourceFile(); } ClangModulesDeclVendor::ClangModulesDeclVendor() : ClangDeclVendor(eClangModuleDeclVendor) {} ClangModulesDeclVendor::~ClangModulesDeclVendor() {} ClangModulesDeclVendorImpl::ClangModulesDeclVendorImpl( llvm::IntrusiveRefCntPtr diagnostics_engine, std::shared_ptr compiler_invocation, std::unique_ptr compiler_instance, std::unique_ptr parser) : m_diagnostics_engine(std::move(diagnostics_engine)), m_compiler_invocation(std::move(compiler_invocation)), m_compiler_instance(std::move(compiler_instance)), m_parser(std::move(parser)) { // Initialize our TypeSystemClang. m_ast_context = std::make_unique("ClangModulesDeclVendor ASTContext", m_compiler_instance->getASTContext()); } void ClangModulesDeclVendorImpl::ReportModuleExportsHelper( ExportedModuleSet &exports, clang::Module *module) { if (exports.count(reinterpret_cast(module))) return; exports.insert(reinterpret_cast(module)); llvm::SmallVector sub_exports; module->getExportedModules(sub_exports); for (clang::Module *module : sub_exports) ReportModuleExportsHelper(exports, module); } void ClangModulesDeclVendorImpl::ReportModuleExports( ClangModulesDeclVendor::ModuleVector &exports, clang::Module *module) { ExportedModuleSet exports_set; ReportModuleExportsHelper(exports_set, module); for (ModuleID module : exports_set) exports.push_back(module); } bool ClangModulesDeclVendorImpl::AddModule(const SourceModule &module, ModuleVector *exported_modules, Stream &error_stream) { // Fail early. if (m_compiler_instance->hadModuleLoaderFatalFailure()) { error_stream.PutCString("error: Couldn't load a module because the module " "loader is in a fatal state.\n"); return false; } // Check if we've already imported this module. std::vector imported_module; for (ConstString path_component : module.path) imported_module.push_back(path_component); { ImportedModuleMap::iterator mi = m_imported_modules.find(imported_module); if (mi != m_imported_modules.end()) { if (exported_modules) ReportModuleExports(*exported_modules, mi->second); return true; } } clang::HeaderSearch &HS = m_compiler_instance->getPreprocessor().getHeaderSearchInfo(); if (module.search_path) { auto path_begin = llvm::sys::path::begin(module.search_path.GetStringRef()); auto path_end = llvm::sys::path::end(module.search_path.GetStringRef()); auto sysroot_begin = llvm::sys::path::begin(module.sysroot.GetStringRef()); auto sysroot_end = llvm::sys::path::end(module.sysroot.GetStringRef()); // FIXME: Use C++14 std::equal(it, it, it, it) variant once it's available. bool is_system_module = (std::distance(path_begin, path_end) >= std::distance(sysroot_begin, sysroot_end)) && std::equal(sysroot_begin, sysroot_end, path_begin); // No need to inject search paths to modules in the sysroot. if (!is_system_module) { auto error = [&]() { error_stream.Printf("error: No module map file in %s\n", module.search_path.AsCString()); return false; }; bool is_system = true; bool is_framework = false; auto dir = HS.getFileMgr().getDirectory(module.search_path.GetStringRef()); if (!dir) return error(); auto *file = HS.lookupModuleMapFile(*dir, is_framework); if (!file) return error(); if (!HS.loadModuleMapFile(file, is_system)) return error(); } } if (!HS.lookupModule(module.path.front().GetStringRef())) { error_stream.Printf("error: Header search couldn't locate module %s\n", module.path.front().AsCString()); return false; } llvm::SmallVector, 4> clang_path; { clang::SourceManager &source_manager = m_compiler_instance->getASTContext().getSourceManager(); for (ConstString path_component : module.path) { clang_path.push_back(std::make_pair( &m_compiler_instance->getASTContext().Idents.get( path_component.GetStringRef()), source_manager.getLocForStartOfFile(source_manager.getMainFileID()) .getLocWithOffset(m_source_location_index++))); } } StoringDiagnosticConsumer *diagnostic_consumer = static_cast( m_compiler_instance->getDiagnostics().getClient()); diagnostic_consumer->ClearDiagnostics(); clang::Module *top_level_module = DoGetModule(clang_path.front(), false); if (!top_level_module) { diagnostic_consumer->DumpDiagnostics(error_stream); error_stream.Printf("error: Couldn't load top-level module %s\n", module.path.front().AsCString()); return false; } clang::Module *submodule = top_level_module; for (auto &component : llvm::ArrayRef(module.path).drop_front()) { submodule = submodule->findSubmodule(component.GetStringRef()); if (!submodule) { diagnostic_consumer->DumpDiagnostics(error_stream); error_stream.Printf("error: Couldn't load submodule %s\n", component.GetCString()); return false; } } clang::Module *requested_module = DoGetModule(clang_path, true); if (requested_module != nullptr) { if (exported_modules) ReportModuleExports(*exported_modules, requested_module); m_imported_modules[imported_module] = requested_module; m_enabled = true; return true; } return false; } bool ClangModulesDeclVendor::LanguageSupportsClangModules( lldb::LanguageType language) { switch (language) { default: return false; case lldb::LanguageType::eLanguageTypeC: case lldb::LanguageType::eLanguageTypeC11: case lldb::LanguageType::eLanguageTypeC89: case lldb::LanguageType::eLanguageTypeC99: case lldb::LanguageType::eLanguageTypeC_plus_plus: case lldb::LanguageType::eLanguageTypeC_plus_plus_03: case lldb::LanguageType::eLanguageTypeC_plus_plus_11: case lldb::LanguageType::eLanguageTypeC_plus_plus_14: case lldb::LanguageType::eLanguageTypeObjC: case lldb::LanguageType::eLanguageTypeObjC_plus_plus: return true; } } bool ClangModulesDeclVendorImpl::AddModulesForCompileUnit( CompileUnit &cu, ClangModulesDeclVendor::ModuleVector &exported_modules, Stream &error_stream) { if (LanguageSupportsClangModules(cu.GetLanguage())) { for (auto &imported_module : cu.GetImportedModules()) if (!AddModule(imported_module, &exported_modules, error_stream)) return false; } return true; } // ClangImporter::lookupValue uint32_t ClangModulesDeclVendorImpl::FindDecls(ConstString name, bool append, uint32_t max_matches, std::vector &decls) { if (!m_enabled) return 0; if (!append) decls.clear(); clang::IdentifierInfo &ident = m_compiler_instance->getASTContext().Idents.get(name.GetStringRef()); clang::LookupResult lookup_result( m_compiler_instance->getSema(), clang::DeclarationName(&ident), clang::SourceLocation(), clang::Sema::LookupOrdinaryName); m_compiler_instance->getSema().LookupName( lookup_result, m_compiler_instance->getSema().getScopeForContext( m_compiler_instance->getASTContext().getTranslationUnitDecl())); uint32_t num_matches = 0; for (clang::NamedDecl *named_decl : lookup_result) { if (num_matches >= max_matches) return num_matches; decls.push_back(m_ast_context->GetCompilerDecl(named_decl)); ++num_matches; } return num_matches; } void ClangModulesDeclVendorImpl::ForEachMacro( const ClangModulesDeclVendor::ModuleVector &modules, std::function handler) { if (!m_enabled) return; typedef std::map ModulePriorityMap; ModulePriorityMap module_priorities; ssize_t priority = 0; for (ModuleID module : modules) module_priorities[module] = priority++; if (m_compiler_instance->getPreprocessor().getExternalSource()) { m_compiler_instance->getPreprocessor() .getExternalSource() ->ReadDefinedMacros(); } for (clang::Preprocessor::macro_iterator mi = m_compiler_instance->getPreprocessor().macro_begin(), me = m_compiler_instance->getPreprocessor().macro_end(); mi != me; ++mi) { const clang::IdentifierInfo *ii = nullptr; { if (clang::IdentifierInfoLookup *lookup = m_compiler_instance->getPreprocessor() .getIdentifierTable() .getExternalIdentifierLookup()) { lookup->get(mi->first->getName()); } if (!ii) ii = mi->first; } ssize_t found_priority = -1; clang::MacroInfo *macro_info = nullptr; for (clang::ModuleMacro *module_macro : m_compiler_instance->getPreprocessor().getLeafModuleMacros(ii)) { clang::Module *module = module_macro->getOwningModule(); { ModulePriorityMap::iterator pi = module_priorities.find(reinterpret_cast(module)); if (pi != module_priorities.end() && pi->second > found_priority) { macro_info = module_macro->getMacroInfo(); found_priority = pi->second; } } clang::Module *top_level_module = module->getTopLevelModule(); if (top_level_module != module) { ModulePriorityMap::iterator pi = module_priorities.find( reinterpret_cast(top_level_module)); if ((pi != module_priorities.end()) && pi->second > found_priority) { macro_info = module_macro->getMacroInfo(); found_priority = pi->second; } } } if (macro_info) { std::string macro_expansion = "#define "; llvm::StringRef macro_identifier = mi->first->getName(); macro_expansion.append(macro_identifier.str()); { if (macro_info->isFunctionLike()) { macro_expansion.append("("); bool first_arg = true; for (auto pi = macro_info->param_begin(), pe = macro_info->param_end(); pi != pe; ++pi) { if (!first_arg) macro_expansion.append(", "); else first_arg = false; macro_expansion.append((*pi)->getName().str()); } if (macro_info->isC99Varargs()) { if (first_arg) macro_expansion.append("..."); else macro_expansion.append(", ..."); } else if (macro_info->isGNUVarargs()) macro_expansion.append("..."); macro_expansion.append(")"); } macro_expansion.append(" "); bool first_token = true; for (clang::MacroInfo::tokens_iterator ti = macro_info->tokens_begin(), te = macro_info->tokens_end(); ti != te; ++ti) { if (!first_token) macro_expansion.append(" "); else first_token = false; if (ti->isLiteral()) { if (const char *literal_data = ti->getLiteralData()) { std::string token_str(literal_data, ti->getLength()); macro_expansion.append(token_str); } else { bool invalid = false; const char *literal_source = m_compiler_instance->getSourceManager().getCharacterData( ti->getLocation(), &invalid); if (invalid) { lldbassert(0 && "Unhandled token kind"); macro_expansion.append(""); } else { macro_expansion.append( std::string(literal_source, ti->getLength())); } } } else if (const char *punctuator_spelling = clang::tok::getPunctuatorSpelling(ti->getKind())) { macro_expansion.append(punctuator_spelling); } else if (const char *keyword_spelling = clang::tok::getKeywordSpelling(ti->getKind())) { macro_expansion.append(keyword_spelling); } else { switch (ti->getKind()) { case clang::tok::TokenKind::identifier: macro_expansion.append(ti->getIdentifierInfo()->getName().str()); break; case clang::tok::TokenKind::raw_identifier: macro_expansion.append(ti->getRawIdentifier().str()); break; default: macro_expansion.append(ti->getName()); break; } } } if (handler(macro_identifier, macro_expansion)) { return; } } } } } clang::ModuleLoadResult ClangModulesDeclVendorImpl::DoGetModule(clang::ModuleIdPath path, bool make_visible) { clang::Module::NameVisibilityKind visibility = make_visible ? clang::Module::AllVisible : clang::Module::Hidden; const bool is_inclusion_directive = false; return m_compiler_instance->loadModule(path.front().second, path, visibility, is_inclusion_directive); } static const char *ModuleImportBufferName = "LLDBModulesMemoryBuffer"; lldb_private::ClangModulesDeclVendor * ClangModulesDeclVendor::Create(Target &target) { // FIXME we should insure programmatically that the expression parser's // compiler and the modules runtime's // compiler are both initialized in the same way – preferably by the same // code. if (!target.GetPlatform()->SupportsModules()) return nullptr; const ArchSpec &arch = target.GetArchitecture(); std::vector compiler_invocation_arguments = { "clang", "-fmodules", "-fimplicit-module-maps", "-fcxx-modules", "-fsyntax-only", "-femit-all-decls", "-target", arch.GetTriple().str(), "-fmodules-validate-system-headers", "-Werror=non-modular-include-in-framework-module"}; target.GetPlatform()->AddClangModuleCompilationOptions( &target, compiler_invocation_arguments); compiler_invocation_arguments.push_back(ModuleImportBufferName); // Add additional search paths with { "-I", path } or { "-F", path } here. { llvm::SmallString<128> path; const auto &props = ModuleList::GetGlobalModuleListProperties(); props.GetClangModulesCachePath().GetPath(path); std::string module_cache_argument("-fmodules-cache-path="); module_cache_argument.append(std::string(path.str())); compiler_invocation_arguments.push_back(module_cache_argument); } FileSpecList module_search_paths = target.GetClangModuleSearchPaths(); for (size_t spi = 0, spe = module_search_paths.GetSize(); spi < spe; ++spi) { const FileSpec &search_path = module_search_paths.GetFileSpecAtIndex(spi); std::string search_path_argument = "-I"; search_path_argument.append(search_path.GetPath()); compiler_invocation_arguments.push_back(search_path_argument); } { FileSpec clang_resource_dir = GetClangResourceDir(); if (FileSystem::Instance().IsDirectory(clang_resource_dir.GetPath())) { compiler_invocation_arguments.push_back("-resource-dir"); compiler_invocation_arguments.push_back(clang_resource_dir.GetPath()); } } llvm::IntrusiveRefCntPtr diagnostics_engine = clang::CompilerInstance::createDiagnostics(new clang::DiagnosticOptions, new StoringDiagnosticConsumer); std::vector compiler_invocation_argument_cstrs; compiler_invocation_argument_cstrs.reserve( compiler_invocation_arguments.size()); for (const std::string &arg : compiler_invocation_arguments) compiler_invocation_argument_cstrs.push_back(arg.c_str()); Log *log(lldb_private::GetLogIfAllCategoriesSet(LIBLLDB_LOG_EXPRESSIONS)); LLDB_LOG(log, "ClangModulesDeclVendor's compiler flags {0:$[ ]}", llvm::make_range(compiler_invocation_arguments.begin(), compiler_invocation_arguments.end())); std::shared_ptr invocation = clang::createInvocationFromCommandLine(compiler_invocation_argument_cstrs, diagnostics_engine); if (!invocation) return nullptr; std::unique_ptr source_buffer = llvm::MemoryBuffer::getMemBuffer( "extern int __lldb __attribute__((unavailable));", ModuleImportBufferName); invocation->getPreprocessorOpts().addRemappedFile(ModuleImportBufferName, source_buffer.release()); std::unique_ptr instance( new clang::CompilerInstance); // When capturing a reproducer, hook up the file collector with clang to // collector modules and headers. if (repro::Generator *g = repro::Reproducer::Instance().GetGenerator()) { repro::FileProvider &fp = g->GetOrCreate(); instance->setModuleDepCollector( std::make_shared( fp.GetFileCollector())); clang::DependencyOutputOptions &opts = instance->getDependencyOutputOpts(); opts.IncludeSystemHeaders = true; opts.IncludeModuleFiles = true; } // Make sure clang uses the same VFS as LLDB. instance->createFileManager(FileSystem::Instance().GetVirtualFileSystem()); instance->setDiagnostics(diagnostics_engine.get()); instance->setInvocation(invocation); std::unique_ptr action(new clang::SyntaxOnlyAction); instance->setTarget(clang::TargetInfo::CreateTargetInfo( *diagnostics_engine, instance->getInvocation().TargetOpts)); if (!instance->hasTarget()) return nullptr; instance->getTarget().adjust(*diagnostics_engine, instance->getLangOpts()); if (!action->BeginSourceFile(*instance, instance->getFrontendOpts().Inputs[0])) return nullptr; instance->getPreprocessor().enableIncrementalProcessing(); instance->createASTReader(); instance->createSema(action->getTranslationUnitKind(), nullptr); const bool skipFunctionBodies = false; std::unique_ptr parser(new clang::Parser( instance->getPreprocessor(), instance->getSema(), skipFunctionBodies)); instance->getPreprocessor().EnterMainSourceFile(); parser->Initialize(); clang::Parser::DeclGroupPtrTy parsed; while (!parser->ParseTopLevelDecl(parsed)) ; return new ClangModulesDeclVendorImpl(std::move(diagnostics_engine), std::move(invocation), std::move(instance), std::move(parser)); }