// TODO: cleanup includes #include "cache.h" #include "clang_complete.h" #include "file_consumer.h" #include "include_complete.h" #include "indexer.h" #include "ipc_manager.h" #include "language_server_api.h" #include "lex_utils.h" #include "match.h" #include "options.h" #include "platform.h" #include "project.h" #include "query.h" #include "query_utils.h" #include "serializer.h" #include "standard_includes.h" #include "test.h" #include "threaded_queue.h" #include "timer.h" #include "work_thread.h" #include "working_files.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include // TODO: provide a feature like 'https://github.com/goldsborough/clang-expand', // ie, a fully linear view of a function with inline function calls expanded. // We can probably use vscode decorators to achieve it. // TODO: implement ThreadPool type which monitors CPU usage / number of work // items per second completed and scales up/down number of running threads. namespace { std::vector kEmptyArgs; // Expected client version. We show an error if this doesn't match. const int kExpectedClientVersion = 3; // Cached completion information, so we can give fast completion results when // the user erases a character. vscode will resend the completion request if // that happens. struct CodeCompleteCache { // NOTE: Make sure to access these variables under |WithLock|. optional cached_path_; optional cached_completion_position_; NonElidedVector cached_results_; std::mutex mutex_; void WithLock(std::function action) { std::lock_guard lock(mutex_); action(); } bool IsCacheValid(lsTextDocumentPositionParams position) { std::lock_guard lock(mutex_); return cached_path_ == position.textDocument.uri.GetPath() && cached_completion_position_ == position.position; } }; // This function returns true if e2e timing should be displayed for the given // IpcId. bool ShouldDisplayIpcTiming(IpcId id) { switch (id) { case IpcId::TextDocumentPublishDiagnostics: case IpcId::CqueryPublishInactiveRegions: case IpcId::Cout: return false; default: return true; } } void PushBack(NonElidedVector* result, optional location) { if (location) result->push_back(*location); } bool FindFileOrFail(QueryDatabase* db, optional id, const std::string& absolute_path, QueryFile** out_query_file, QueryFileId* out_file_id = nullptr) { *out_query_file = nullptr; auto it = db->usr_to_file.find(LowerPathIfCaseInsensitive(absolute_path)); if (it != db->usr_to_file.end()) { QueryFile& file = db->files[it->second.id]; if (file.def) { *out_query_file = &file; if (out_file_id) *out_file_id = QueryFileId(it->second.id); return true; } } if (out_file_id) *out_file_id = QueryFileId((size_t)-1); LOG_S(INFO) << "Unable to find file \"" << absolute_path << "\""; if (id) { Out_Error out; out.id = *id; out.error.code = lsErrorCodes::InternalError; out.error.message = "Unable to find file " + absolute_path; IpcManager::instance()->SendOutMessageToClient(IpcId::Cout, out); } return false; } void EmitInactiveLines(WorkingFile* working_file, const std::vector& inactive_regions) { Out_CquerySetInactiveRegion out; out.params.uri = lsDocumentUri::FromPath(working_file->filename); for (Range skipped : inactive_regions) { optional ls_skipped = GetLsRange(working_file, skipped); if (ls_skipped) out.params.inactiveRegions.push_back(*ls_skipped); } IpcManager::instance()->SendOutMessageToClient( IpcId::CqueryPublishInactiveRegions, out); } void EmitSemanticHighlighting(QueryDatabase* db, WorkingFile* working_file, QueryFile* file) { auto map_symbol_kind_to_symbol_type = [](SymbolKind kind) { switch (kind) { case SymbolKind::Type: return Out_CqueryPublishSemanticHighlighting::SymbolType::Type; case SymbolKind::Func: return Out_CqueryPublishSemanticHighlighting::SymbolType::Function; case SymbolKind::Var: return Out_CqueryPublishSemanticHighlighting::SymbolType::Variable; default: assert(false); return Out_CqueryPublishSemanticHighlighting::SymbolType::Variable; } }; // Group symbols together. std::unordered_map grouped_symbols; for (SymbolRef sym : file->def->all_symbols) { bool is_type_member = false; switch (sym.idx.kind) { case SymbolKind::Func: { QueryFunc* func = &db->funcs[sym.idx.idx]; if (!func->def) continue; // applies to for loop is_type_member = func->def->declaring_type.has_value(); break; } case SymbolKind::Var: { QueryVar* var = &db->vars[sym.idx.idx]; if (!var->def) continue; // applies to for loop if (!var->def->is_local && !var->def->declaring_type) continue; // applies to for loop is_type_member = var->def->declaring_type.has_value(); break; } default: continue; // applies to for loop } optional loc = GetLsRange(working_file, sym.loc.range); if (loc) { auto it = grouped_symbols.find(sym.idx); if (it != grouped_symbols.end()) { it->second.ranges.push_back(*loc); } else { Out_CqueryPublishSemanticHighlighting::Symbol symbol; symbol.type = map_symbol_kind_to_symbol_type(sym.idx.kind); symbol.is_type_member = is_type_member; symbol.ranges.push_back(*loc); grouped_symbols[sym.idx] = symbol; } } } // Publish. Out_CqueryPublishSemanticHighlighting out; out.params.uri = lsDocumentUri::FromPath(working_file->filename); for (auto& entry : grouped_symbols) out.params.symbols.push_back(entry.second); IpcManager::instance()->SendOutMessageToClient( IpcId::CqueryPublishSemanticHighlighting, out); } optional FindIncludeLine(const std::vector& lines, const std::string& full_include_line) { // // This returns an include line. For example, // // #include // 0 // #include // 1 // // Given #include , this will return '1', which means that the // #include text should be inserted at the start of line 1. Inserting // at the start of a line allows insertion at both the top and bottom of the // document. // // If the include line is already in the document this returns nullopt. // optional last_include_line; optional best_include_line; // 1 => include line is gt content (ie, it should go after) // -1 => include line is lt content (ie, it should go before) int last_line_compare = 1; for (int line = 0; line < (int)lines.size(); ++line) { if (!StartsWith(lines[line], "#include")) { last_line_compare = 1; continue; } last_include_line = line; int current_line_compare = full_include_line.compare(lines[line]); if (current_line_compare == 0) return nullopt; if (last_line_compare == 1 && current_line_compare == -1) best_include_line = line; last_line_compare = current_line_compare; } if (best_include_line) return *best_include_line; // If |best_include_line| didn't match that means we likely didn't find an // include which was lt the new one, so put it at the end of the last include // list. if (last_include_line) return *last_include_line + 1; // No includes, use top of document. return 0; } optional GetImplementationFile(QueryDatabase* db, QueryFileId file_id, QueryFile* file) { for (SymbolRef sym : file->def->outline) { switch (sym.idx.kind) { case SymbolKind::Func: { QueryFunc& func = db->funcs[sym.idx.idx]; // Note: we ignore the definition if it is in the same file (ie, // possibly a header). if (func.def && func.def->definition_extent && func.def->definition_extent->path != file_id) { return func.def->definition_extent->path; } break; } case SymbolKind::Var: { QueryVar& var = db->vars[sym.idx.idx]; // Note: we ignore the definition if it is in the same file (ie, // possibly a header). if (var.def && var.def->definition_extent && var.def->definition_extent->path != file_id) { return db->vars[sym.idx.idx].def->definition_extent->path; } break; } default: break; } } // No associated definition, scan the project for a file in the same // directory with the same base-name. std::string original_path = LowerPathIfCaseInsensitive(file->def->path); std::string target_path = original_path; size_t last = target_path.find_last_of('.'); if (last != std::string::npos) { target_path = target_path.substr(0, last); } LOG_S(INFO) << "!! Looking for impl file that starts with " << target_path; for (auto& entry : db->usr_to_file) { Usr path = entry.first; // Do not consider header files for implementation files. // TODO: make file extensions configurable. if (EndsWith(path, ".h") || EndsWith(path, ".hpp")) continue; if (StartsWith(path, target_path) && path != original_path) { return entry.second; } } return nullopt; } void EnsureImplFile(QueryDatabase* db, QueryFileId file_id, optional& impl_uri, optional& impl_file_id) { if (!impl_uri.has_value()) { QueryFile& file = db->files[file_id.id]; assert(file.def); impl_file_id = GetImplementationFile(db, file_id, &file); if (!impl_file_id.has_value()) impl_file_id = file_id; QueryFile& impl_file = db->files[impl_file_id->id]; if (impl_file.def) impl_uri = lsDocumentUri::FromPath(impl_file.def->path); else impl_uri = lsDocumentUri::FromPath(file.def->path); } } optional BuildAutoImplementForFunction(QueryDatabase* db, WorkingFiles* working_files, WorkingFile* working_file, int default_line, QueryFileId decl_file_id, QueryFileId impl_file_id, QueryFunc& func) { assert(func.def); for (const QueryLocation& decl : func.declarations) { if (decl.path != decl_file_id) continue; optional ls_decl = GetLsRange(working_file, decl.range); if (!ls_decl) continue; optional type_name; optional same_file_insert_end; if (func.def->declaring_type) { QueryType& declaring_type = db->types[func.def->declaring_type->id]; if (declaring_type.def) { type_name = declaring_type.def->short_name; optional ls_type_def_extent = GetLsRange( working_file, declaring_type.def->definition_extent->range); if (ls_type_def_extent) { same_file_insert_end = ls_type_def_extent->end; same_file_insert_end->character += 1; // move past semicolon. } } } std::string insert_text; int newlines_after_name = 0; LexFunctionDeclaration(working_file->buffer_content, ls_decl->start, type_name, &insert_text, &newlines_after_name); if (!same_file_insert_end) { same_file_insert_end = ls_decl->end; same_file_insert_end->line += newlines_after_name; same_file_insert_end->character = 1000; } lsTextEdit edit; if (decl_file_id == impl_file_id) { edit.range.start = *same_file_insert_end; edit.range.end = *same_file_insert_end; edit.newText = "\n\n" + insert_text; } else { lsPosition best_pos; best_pos.line = default_line; int best_dist = INT_MAX; QueryFile& file = db->files[impl_file_id.id]; assert(file.def); for (SymbolRef sym : file.def->outline) { switch (sym.idx.kind) { case SymbolKind::Func: { QueryFunc& sym_func = db->funcs[sym.idx.idx]; if (!sym_func.def || !sym_func.def->definition_extent) break; for (QueryLocation& func_decl : sym_func.declarations) { if (func_decl.path == decl_file_id) { int dist = func_decl.range.start.line - decl.range.start.line; if (abs(dist) < abs(best_dist)) { optional def_loc = GetLsLocation( db, working_files, *sym_func.def->definition_extent); if (!def_loc) continue; best_dist = dist; if (dist > 0) best_pos = def_loc->range.start; else best_pos = def_loc->range.end; } } } break; } case SymbolKind::Var: { // TODO: handle vars. break; } case SymbolKind::Invalid: case SymbolKind::File: case SymbolKind::Type: LOG_S(WARNING) << "Unexpected SymbolKind " << static_cast(sym.idx.kind); break; } } edit.range.start = best_pos; edit.range.end = best_pos; if (best_dist < 0) edit.newText = "\n\n" + insert_text; else edit.newText = insert_text + "\n\n"; } return edit; } return nullopt; } void EmitDiagnostics(WorkingFiles* working_files, std::string path, NonElidedVector diagnostics) { // Emit diagnostics. Out_TextDocumentPublishDiagnostics diagnostic_response; diagnostic_response.params.uri = lsDocumentUri::FromPath(path); diagnostic_response.params.diagnostics = diagnostics; IpcManager::instance()->SendOutMessageToClient( IpcId::TextDocumentPublishDiagnostics, diagnostic_response); // Cache diagnostics so we can show fixits. working_files->DoActionOnFile(path, [&](WorkingFile* working_file) { if (working_file) working_file->diagnostics_ = diagnostics; }); } // Pre-filters completion responses before sending to vscode. This results in a // significantly snappier completion experience as vscode is easily overloaded // when given 1000+ completion items. void FilterCompletionResponse(Out_TextDocumentComplete* complete_response, const std::string& complete_text) { // Used to inject more completions. #if false const size_t kNumIterations = 250; size_t size = complete_response->result.items.size(); complete_response->result.items.reserve(size * (kNumIterations + 1)); for (size_t iteration = 0; iteration < kNumIterations; ++iteration) { for (size_t i = 0; i < size; ++i) { auto item = complete_response->result.items[i]; item.label += "#" + std::to_string(iteration); complete_response->result.items.push_back(item); } } #endif const size_t kMaxResultSize = 100u; if (complete_response->result.items.size() > kMaxResultSize) { if (complete_text.empty()) { complete_response->result.items.resize(kMaxResultSize); } else { NonElidedVector filtered_result; filtered_result.reserve(kMaxResultSize); std::unordered_set inserted; inserted.reserve(kMaxResultSize); // Find literal matches first. for (const lsCompletionItem& item : complete_response->result.items) { if (item.label.find(complete_text) != std::string::npos) { // Don't insert the same completion entry. if (!inserted.insert(item.InsertedContent()).second) continue; filtered_result.push_back(item); if (filtered_result.size() >= kMaxResultSize) break; } } // Find fuzzy matches if we haven't found all of the literal matches. if (filtered_result.size() < kMaxResultSize) { for (const lsCompletionItem& item : complete_response->result.items) { if (SubstringMatch(complete_text, item.label)) { // Don't insert the same completion entry. if (!inserted.insert(item.InsertedContent()).second) continue; filtered_result.push_back(item); if (filtered_result.size() >= kMaxResultSize) break; } } } complete_response->result.items = filtered_result; } // Assuming the client does not support out-of-order completion (ie, ao // matches against oa), our filtering is guaranteed to contain any // potential matches, so the completion is only incomplete if we have the // max number of emitted matches. if (complete_response->result.items.size() >= kMaxResultSize) { LOG_S(INFO) << "Marking completion results as incomplete"; complete_response->result.isIncomplete = true; } } } struct Index_Request { std::string path; // TODO: make |args| a string that is parsed lazily. std::vector args; bool is_interactive; optional contents; // Preloaded contents. Useful for tests. Index_Request(const std::string& path, const std::vector& args, bool is_interactive, optional contents) : path(path), args(args), is_interactive(is_interactive), contents(contents) {} }; struct Index_DoIdMap { std::unique_ptr current; std::unique_ptr previous; PerformanceImportFile perf; bool is_interactive = false; bool write_to_disk = false; bool load_previous = false; Index_DoIdMap(std::unique_ptr current, PerformanceImportFile perf, bool is_interactive, bool write_to_disk) : current(std::move(current)), perf(perf), is_interactive(is_interactive), write_to_disk(write_to_disk) { assert(this->current); } }; struct Index_OnIdMapped { struct File { std::unique_ptr file; std::unique_ptr ids; File(std::unique_ptr file, std::unique_ptr ids) : file(std::move(file)), ids(std::move(ids)) {} }; std::unique_ptr previous; std::unique_ptr current; PerformanceImportFile perf; bool is_interactive; bool write_to_disk; Index_OnIdMapped(PerformanceImportFile perf, bool is_interactive, bool write_to_disk) : perf(perf), is_interactive(is_interactive), write_to_disk(write_to_disk) {} }; struct Index_OnIndexed { IndexUpdate update; PerformanceImportFile perf; Index_OnIndexed(IndexUpdate& update, PerformanceImportFile perf) : update(update), perf(perf) {} }; struct QueueManager { using Index_RequestQueue = ThreadedQueue; using Index_DoIdMapQueue = ThreadedQueue; using Index_OnIdMappedQueue = ThreadedQueue; using Index_OnIndexedQueue = ThreadedQueue; Index_RequestQueue index_request; Index_DoIdMapQueue do_id_map; Index_DoIdMapQueue load_previous_index; Index_OnIdMappedQueue on_id_mapped; Index_OnIndexedQueue on_indexed; QueueManager(MultiQueueWaiter* waiter) : index_request(waiter), do_id_map(waiter), load_previous_index(waiter), on_id_mapped(waiter), on_indexed(waiter) {} bool HasWork() { return !index_request.IsEmpty() || !do_id_map.IsEmpty() || !load_previous_index.IsEmpty() || !on_id_mapped.IsEmpty() || !on_indexed.IsEmpty(); } }; void RegisterMessageTypes() { MessageRegistry::instance()->Register(); MessageRegistry::instance()->Register(); MessageRegistry::instance()->Register(); MessageRegistry::instance()->Register(); MessageRegistry::instance()->Register(); MessageRegistry::instance()->Register(); MessageRegistry::instance()->Register(); MessageRegistry::instance()->Register(); MessageRegistry::instance()->Register(); MessageRegistry::instance()->Register(); MessageRegistry::instance()->Register(); MessageRegistry::instance()->Register(); MessageRegistry::instance()->Register(); MessageRegistry::instance()->Register(); MessageRegistry::instance()->Register(); MessageRegistry::instance()->Register(); MessageRegistry::instance()->Register(); MessageRegistry::instance()->Register(); MessageRegistry::instance()->Register(); MessageRegistry::instance()->Register(); MessageRegistry::instance()->Register(); MessageRegistry::instance()->Register(); MessageRegistry::instance()->Register(); MessageRegistry::instance()->Register(); MessageRegistry::instance()->Register(); MessageRegistry::instance()->Register(); MessageRegistry::instance()->Register(); MessageRegistry::instance()->Register(); MessageRegistry::instance()->Register(); MessageRegistry::instance()->Register(); MessageRegistry::instance()->Register(); MessageRegistry::instance()->Register(); } // Manages files inside of the indexing pipeline so we don't have the same file // being imported multiple times. // // NOTE: This is not thread safe and should only be used on the querydb thread. struct ImportManager { // Try to mark the given dependency as imported. A dependency can only ever be // imported once. bool TryMarkDependencyImported(const std::string& path) { std::lock_guard lock(depdency_mutex_); return depdency_imported_.insert(path).second; } // Try to import the given file into querydb. We should only ever be // importing a file into querydb once per file. Returns true if the file // can be imported. bool StartQueryDbImport(const std::string& path) { return querydb_processing_.insert(path).second; } // The file has been fully imported and can be imported again later on. void DoneQueryDbImport(const std::string& path) { querydb_processing_.erase(path); } // Returns true if there any any files currently being imported. bool HasActiveQuerydbImports() { return !querydb_processing_.empty(); } std::unordered_set querydb_processing_; // TODO: use std::shared_mutex so we can have multiple readers. std::mutex depdency_mutex_; std::unordered_set depdency_imported_; }; // Manages loading caches from file paths for the indexer process. struct CacheLoader { explicit CacheLoader(Config* config) : config_(config) {} IndexFile* TryLoad(const std::string& path) { auto it = caches.find(path); if (it != caches.end()) return it->second.get(); std::unique_ptr cache = LoadCachedIndex(config_, path); if (!cache) return nullptr; caches[path] = std::move(cache); return caches[path].get(); } // Takes the existing cache or loads the cache at |path|. May return nullptr // if the cache does not exist. std::unique_ptr TryTakeOrLoad(const std::string& path) { auto it = caches.find(path); if (it != caches.end()) { auto result = std::move(it->second); caches.erase(it); return result; } return LoadCachedIndex(config_, path); } // Takes the existing cache or loads the cache at |path|. Asserts the cache // exists. std::unique_ptr TakeOrLoad(const std::string& path) { auto result = TryTakeOrLoad(path); assert(result); return result; } std::unordered_map> caches; Config* config_; }; // Caches timestamps of cc files so we can avoid a filesystem reads. This is // important for import perf, as during dependency checking the same files are // checked over and over again if they are common headers. struct TimestampManager { optional GetLastCachedModificationTime(CacheLoader* cache_loader, const std::string& path) { { std::lock_guard guard(mutex_); auto it = timestamps_.find(path); if (it != timestamps_.end()) return it->second; } IndexFile* file = cache_loader->TryLoad(path); if (!file) return nullopt; UpdateCachedModificationTime(path, file->last_modification_time); return file->last_modification_time; } void UpdateCachedModificationTime(const std::string& path, int64_t timestamp) { std::lock_guard guard(mutex_); timestamps_[path] = timestamp; } // TODO: use std::shared_mutex so we can have multiple readers. std::mutex mutex_; std::unordered_map timestamps_; }; struct IndexManager { std::unordered_set files_being_indexed_; std::mutex mutex_; // Marks a file as being indexed. Returns true if the file is not already // being indexed. bool MarkIndex(const std::string& path) { std::lock_guard lock(mutex_); return files_being_indexed_.insert(path).second; } // Unmarks a file as being indexed, so it can get indexed again in the // future. void ClearIndex(const std::string& path) { std::lock_guard lock(mutex_); auto it = files_being_indexed_.find(path); assert(it != files_being_indexed_.end()); files_being_indexed_.erase(it); } }; // Sends indexing progress to client. void EmitProgress(QueueManager* queue) { Out_Progress out; out.params.indexRequestCount = queue->index_request.Size(); out.params.doIdMapCount = queue->do_id_map.Size(); out.params.loadPreviousIndexCount = queue->load_previous_index.Size(); out.params.onIdMappedCount = queue->on_id_mapped.Size(); out.params.onIndexedCount = queue->on_indexed.Size(); IpcManager::instance()->SendOutMessageToClient(IpcId::Cout, out); } } // namespace //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// // IMPORT PIPELINE ///////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// enum class FileParseQuery { NeedsParse, DoesNotNeedParse, NoSuchFile }; std::vector DoParseFile( Config* config, WorkingFiles* working_files, ClangIndex* index, FileConsumer::SharedState* file_consumer_shared, TimestampManager* timestamp_manager, ImportManager* import_manager, CacheLoader* cache_loader, bool is_interactive, const std::string& path, const std::vector& args, const optional& contents) { std::vector result; // Always run this block, even if we are interactive, so we can check // dependencies and reset files in |file_consumer_shared|. IndexFile* previous_index = cache_loader->TryLoad(path); if (previous_index) { // If none of the dependencies have changed and the index is not // interactive (ie, requested by a file save), skip parsing and just load // from cache. // Checks if |path| needs to be reparsed. This will modify cached state // such that calling this function twice with the same path may return true // the first time but will return false the second. auto file_needs_parse = [&](const std::string& path, bool is_dependency) { // If the file is a dependency but another file as already imported it, // don't bother. if (!is_interactive && is_dependency && !import_manager->TryMarkDependencyImported(path)) { return FileParseQuery::DoesNotNeedParse; } optional modification_timestamp = GetLastModificationTime(path); // Cannot find file. if (!modification_timestamp) return FileParseQuery::NoSuchFile; optional last_cached_modification = timestamp_manager->GetLastCachedModificationTime(cache_loader, path); // File has been changed. if (!last_cached_modification || modification_timestamp != *last_cached_modification) { file_consumer_shared->Reset(path); timestamp_manager->UpdateCachedModificationTime( path, *modification_timestamp); return FileParseQuery::NeedsParse; } // File has not changed, do not parse it. return FileParseQuery::DoesNotNeedParse; }; // Check timestamps and update |file_consumer_shared|. FileParseQuery path_state = file_needs_parse(path, false /*is_dependency*/); // Target file does not exist on disk, do not emit any indexes. // TODO: Dependencies should be reassigned to other files. We can do this by // updating the "primary_file" if it doesn't exist. Might not actually be a // problem in practice. if (path_state == FileParseQuery::NoSuchFile) return result; bool needs_reparse = is_interactive || path_state == FileParseQuery::NeedsParse; for (const std::string& dependency : previous_index->dependencies) { assert(!dependency.empty()); // note: Use != as there are multiple failure results for FileParseQuery. if (file_needs_parse(dependency, true /*is_dependency*/) != FileParseQuery::DoesNotNeedParse) { LOG_S(INFO) << "Timestamp has changed for " << dependency << " (via " << previous_index->path << ")"; needs_reparse = true; // SUBTLE: Do not break here, as |file_consumer_shared| is updated // inside of |file_needs_parse|. } } // No timestamps changed - load directly from cache. if (!needs_reparse) { LOG_S(INFO) << "Skipping parse; no timestamp change for " << path; // TODO/FIXME: real perf PerformanceImportFile perf; result.push_back(Index_DoIdMap(cache_loader->TakeOrLoad(path), perf, is_interactive, false /*write_to_disk*/)); for (const std::string& dependency : previous_index->dependencies) { // Only load a dependency if it is not already loaded. // // This is important for perf in large projects where there are lots of // dependencies shared between many files. if (!file_consumer_shared->Mark(dependency)) continue; LOG_S(INFO) << "Emitting index result for " << dependency << " (via " << previous_index->path << ")"; std::unique_ptr dependency_index = cache_loader->TryTakeOrLoad(dependency); // |dependency_index| may be null if there is no cache for it but // another file has already started importing it. if (!dependency_index) continue; result.push_back(Index_DoIdMap(std::move(dependency_index), perf, is_interactive, false /*write_to_disk*/)); } return result; } } LOG_S(INFO) << "Parsing " << path; // Load file contents for all dependencies into memory. If the dependencies // for the file changed we may not end up using all of the files we // preloaded. If a new dependency was added the indexer will grab the file // contents as soon as possible. // // We do this to minimize the race between indexing a file and capturing the // file contents. // // TODO: We might be able to optimize perf by only copying for files in // working_files. We can pass that same set of files to the indexer as // well. We then default to a fast file-copy if not in working set. bool loaded_primary = false; std::vector file_contents; if (contents) { loaded_primary = loaded_primary || contents->path == path; file_contents.push_back(*contents); } for (const auto& it : cache_loader->caches) { const std::unique_ptr& index = it.second; assert(index); optional index_content = ReadContent(index->path); if (!index_content) { LOG_S(ERROR) << "Failed to preload index content for " << index->path; continue; } file_contents.push_back(FileContents(index->path, *index_content)); loaded_primary = loaded_primary || index->path == path; } if (!loaded_primary) { optional content = ReadContent(path); if (!content) { LOG_S(ERROR) << "Skipping index (file cannot be found): " << path; return result; } file_contents.push_back(FileContents(path, *content)); } PerformanceImportFile perf; std::vector> indexes = Parse( config, file_consumer_shared, path, args, file_contents, &perf, index); for (std::unique_ptr& new_index : indexes) { Timer time; // Only emit diagnostics for non-interactive sessions, which makes it easier // to identify indexing problems. For interactive sessions, diagnostics are // handled by code completion. if (!is_interactive) EmitDiagnostics(working_files, new_index->path, new_index->diagnostics_); // When main thread does IdMap request it will request the previous index if // needed. LOG_S(INFO) << "Emitting index result for " << new_index->path; result.push_back(Index_DoIdMap(std::move(new_index), perf, is_interactive, true /*write_to_disk*/)); } return result; } // Index a file using an already-parsed translation unit from code completion. // Since most of the time for indexing a file comes from parsing, we can do // real-time indexing. // TODO: add option to disable this. void IndexWithTuFromCodeCompletion( QueueManager* queue, FileConsumer::SharedState* file_consumer_shared, ClangTranslationUnit* tu, const std::vector& file_contents, const std::string& path, const std::vector& args) { file_consumer_shared->Reset(path); PerformanceImportFile perf; ClangIndex index; std::vector> indexes = ParseWithTu( file_consumer_shared, &perf, tu, &index, path, args, file_contents); std::vector result; for (std::unique_ptr& new_index : indexes) { Timer time; // When main thread does IdMap request it will request the previous index if // needed. LOG_S(INFO) << "Emitting index result for " << new_index->path; result.push_back(Index_DoIdMap(std::move(new_index), perf, true /*is_interactive*/, true /*write_to_disk*/)); } LOG_IF_S(WARNING, result.size() > 1) << "Code completion index update generated more than one index"; queue->do_id_map.EnqueueAll(std::move(result)); } std::vector ParseFile( Config* config, WorkingFiles* working_files, ClangIndex* index, FileConsumer::SharedState* file_consumer_shared, TimestampManager* timestamp_manager, ImportManager* import_manager, bool is_interactive, const Project::Entry& entry, const optional& contents) { optional file_contents; if (contents) file_contents = FileContents(entry.filename, *contents); CacheLoader cache_loader(config); // Try to determine the original import file by loading the file from cache. // This lets the user request an index on a header file, which clang will // complain about if indexed by itself. IndexFile* entry_cache = cache_loader.TryLoad(entry.filename); std::string tu_path = entry_cache ? entry_cache->import_file : entry.filename; return DoParseFile(config, working_files, index, file_consumer_shared, timestamp_manager, import_manager, &cache_loader, is_interactive, tu_path, entry.args, file_contents); } bool IndexMain_DoParse(Config* config, WorkingFiles* working_files, QueueManager* queue, FileConsumer::SharedState* file_consumer_shared, TimestampManager* timestamp_manager, ImportManager* import_manager, ClangIndex* index) { optional request = queue->index_request.TryDequeue(); if (!request) return false; Project::Entry entry; entry.filename = request->path; entry.args = request->args; std::vector responses = ParseFile( config, working_files, index, file_consumer_shared, timestamp_manager, import_manager, request->is_interactive, entry, request->contents); // Don't bother sending an IdMap request if there are no responses. if (responses.empty()) return false; // EnqueueAll will clear |responses|. queue->do_id_map.EnqueueAll(std::move(responses)); return true; } bool IndexMain_DoCreateIndexUpdate(Config* config, QueueManager* queue, TimestampManager* timestamp_manager) { optional response = queue->on_id_mapped.TryDequeue(); if (!response) return false; Timer time; IdMap* previous_id_map = nullptr; IndexFile* previous_index = nullptr; if (response->previous) { previous_id_map = response->previous->ids.get(); previous_index = response->previous->file.get(); } // Build delta update. IndexUpdate update = IndexUpdate::CreateDelta(previous_id_map, response->current->ids.get(), previous_index, response->current->file.get()); response->perf.index_make_delta = time.ElapsedMicrosecondsAndReset(); LOG_S(INFO) << "Built index update for " << response->current->file->path << " (is_delta=" << !!response->previous << ")"; // Write current index to disk if requested. if (response->write_to_disk) { LOG_S(INFO) << "Writing cached index to disk for " << response->current->file->path; time.Reset(); WriteToCache(config, *response->current->file); response->perf.index_save_to_disk = time.ElapsedMicrosecondsAndReset(); timestamp_manager->UpdateCachedModificationTime( response->current->file->path, response->current->file->last_modification_time); } #if false #define PRINT_SECTION(name) \ if (response->perf.name) { \ total += response->perf.name; \ output << " " << #name << ": " << FormatMicroseconds(response->perf.name); \ } std::stringstream output; long long total = 0; output << "[perf]"; PRINT_SECTION(index_parse); PRINT_SECTION(index_build); PRINT_SECTION(index_save_to_disk); PRINT_SECTION(index_load_cached); PRINT_SECTION(querydb_id_map); PRINT_SECTION(index_make_delta); output << "\n total: " << FormatMicroseconds(total); output << " path: " << response->current_index->path; output << std::endl; std::cerr << output.rdbuf(); #undef PRINT_SECTION if (response->is_interactive) std::cerr << "Applying IndexUpdate" << std::endl << update.ToString() << std::endl; #endif Index_OnIndexed reply(update, response->perf); queue->on_indexed.Enqueue(std::move(reply)); return true; } bool IndexMain_LoadPreviousIndex(Config* config, QueueManager* queue) { optional response = queue->load_previous_index.TryDequeue(); if (!response) return false; response->previous = LoadCachedIndex(config, response->current->path); LOG_IF_S(ERROR, !response->previous) << "Unable to load previous index for already imported index " << response->current->path; queue->do_id_map.Enqueue(std::move(*response)); return true; } bool IndexMergeIndexUpdates(QueueManager* queue) { optional root = queue->on_indexed.TryDequeue(); if (!root) return false; bool did_merge = false; while (true) { optional to_join = queue->on_indexed.TryDequeue(); if (!to_join) { queue->on_indexed.Enqueue(std::move(*root)); return did_merge; } did_merge = true; Timer time; root->update.Merge(to_join->update); // time.ResetAndPrint("Joined querydb updates for files: " + // StringJoinMap(root->update.files_def_update, //[](const QueryFile::DefUpdate& update) { // return update.path; //})); } } WorkThread::Result IndexMain(Config* config, FileConsumer::SharedState* file_consumer_shared, TimestampManager* timestamp_manager, ImportManager* import_manager, Project* project, WorkingFiles* working_files, MultiQueueWaiter* waiter, QueueManager* queue) { EmitProgress(queue); // TODO: dispose of index after it is not used for a while. ClangIndex index; // TODO: process all off IndexMain_DoIndex before calling // IndexMain_DoCreateIndexUpdate for // better icache behavior. We need to have some threads spinning on // both though // otherwise memory usage will get bad. // We need to make sure to run both IndexMain_DoParse and // IndexMain_DoCreateIndexUpdate so we don't starve querydb from doing any // work. Running both also lets the user query the partially constructed // index. bool did_parse = IndexMain_DoParse(config, working_files, queue, file_consumer_shared, timestamp_manager, import_manager, &index); bool did_create_update = IndexMain_DoCreateIndexUpdate(config, queue, timestamp_manager); bool did_load_previous = IndexMain_LoadPreviousIndex(config, queue); // Nothing to index and no index updates to create, so join some already // created index updates to reduce work on querydb thread. bool did_merge = false; if (!did_parse && !did_create_update && !did_load_previous) did_merge = IndexMergeIndexUpdates(queue); // We didn't do any work, so wait for a notification. if (!did_parse && !did_create_update && !did_merge && !did_load_previous) { waiter->Wait({&queue->index_request, &queue->on_id_mapped, &queue->load_previous_index, &queue->on_indexed}); } return queue->HasWork() ? WorkThread::Result::MoreWork : WorkThread::Result::NoWork; } bool QueryDb_ImportMain(Config* config, QueryDatabase* db, ImportManager* import_manager, QueueManager* queue, WorkingFiles* working_files) { EmitProgress(queue); bool did_work = false; while (true) { optional request = queue->do_id_map.TryDequeue(); if (!request) break; did_work = true; assert(request->current); // If the request does not have previous state and we have already imported // it, load the previous state from disk and rerun IdMap logic later. Do not // do this if we have already attempted in the past. if (!request->load_previous && !request->previous && db->usr_to_file.find(LowerPathIfCaseInsensitive( request->current->path)) != db->usr_to_file.end()) { assert(!request->load_previous); request->load_previous = true; queue->load_previous_index.Enqueue(std::move(*request)); continue; } // Check if the file is already being imported into querydb. If it is, drop // the request. // // Note, we must do this *after* we have checked for the previous index, // otherwise we will never actually generate the IdMap. if (!import_manager->StartQueryDbImport(request->current->path)) { LOG_S(INFO) << "Dropping index as it is already being imported for " << request->current->path; continue; } Index_OnIdMapped response(request->perf, request->is_interactive, request->write_to_disk); Timer time; auto make_map = [db](std::unique_ptr file) -> std::unique_ptr { if (!file) return nullptr; auto id_map = MakeUnique(db, file->id_cache); return MakeUnique(std::move(file), std::move(id_map)); }; response.current = make_map(std::move(request->current)); response.previous = make_map(std::move(request->previous)); response.perf.querydb_id_map = time.ElapsedMicrosecondsAndReset(); queue->on_id_mapped.Enqueue(std::move(response)); } while (true) { optional response = queue->on_indexed.TryDequeue(); if (!response) break; did_work = true; Timer time; for (auto& updated_file : response->update.files_def_update) { // TODO: We're reading a file on querydb thread. This is slow!! If this // a real problem in practice we can load the file in a previous stage. // It should be fine though because we only do it if the user has the // file open. WorkingFile* working_file = working_files->GetFileByFilename(updated_file.path); if (working_file) { optional cached_file_contents = LoadCachedFileContents(config, updated_file.path); if (cached_file_contents) working_file->SetIndexContent(*cached_file_contents); else working_file->SetIndexContent(working_file->buffer_content); time.ResetAndPrint( "Update WorkingFile index contents (via disk load) for " + updated_file.path); // Update inactive region. EmitInactiveLines(working_file, updated_file.inactive_regions); } } time.Reset(); db->ApplyIndexUpdate(&response->update); time.ResetAndPrint("Applying index update for " + StringJoinMap(response->update.files_def_update, [](const QueryFile::DefUpdate& value) { return value.path; })); // Update semantic highlighting. for (auto& updated_file : response->update.files_def_update) { WorkingFile* working_file = working_files->GetFileByFilename(updated_file.path); if (working_file) { QueryFileId file_id = db->usr_to_file[LowerPathIfCaseInsensitive(working_file->filename)]; QueryFile* file = &db->files[file_id.id]; EmitSemanticHighlighting(db, working_file, file); } } // Mark the files as being done in querydb stage after we apply the index // update. for (auto& updated_file : response->update.files_def_update) import_manager->DoneQueryDbImport(updated_file.path); } return did_work; } //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// // QUERYDB MAIN //////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// bool QueryDbMainLoop(Config* config, QueryDatabase* db, bool* exit_when_idle, MultiQueueWaiter* waiter, QueueManager* queue, Project* project, FileConsumer::SharedState* file_consumer_shared, ImportManager* import_manager, TimestampManager* timestamp_manager, WorkingFiles* working_files, ClangCompleteManager* clang_complete, IncludeComplete* include_complete, CodeCompleteCache* global_code_complete_cache, CodeCompleteCache* non_global_code_complete_cache, CodeCompleteCache* signature_cache) { IpcManager* ipc = IpcManager::instance(); bool did_work = false; std::vector> messages = ipc->GetMessages(IpcManager::Destination::Server); for (auto& message : messages) { did_work = true; switch (message->method_id) { case IpcId::Initialize: { auto request = message->As(); // Log initialization parameters. rapidjson::StringBuffer output; Writer writer(output); Reflect(writer, request->params.initializationOptions); std::cerr << output.GetString() << std::endl; if (request->params.rootUri) { std::string project_path = request->params.rootUri->GetPath(); LOG_S(INFO) << "[querydb] Initialize in directory " << project_path << " with uri " << request->params.rootUri->raw_uri; if (!request->params.initializationOptions) { LOG_S(FATAL) << "Initialization parameters (particularily " "cacheDirectory) are required"; exit(1); } *config = *request->params.initializationOptions; // Check client version. if (config->clientVersion != kExpectedClientVersion && config->clientVersion != -1 /*disable check*/) { Out_ShowLogMessage out; out.display_type = Out_ShowLogMessage::DisplayType::Show; out.params.type = lsMessageType::Error; out.params.message = "cquery client (v" + std::to_string(config->clientVersion) + ") and server (v" + std::to_string(kExpectedClientVersion) + ") version mismatch. Please update "; if (config->clientVersion > kExpectedClientVersion) out.params.message += "the cquery binary."; else out.params.message += "your extension client (VSIX file). Make sure to uninstall " "the cquery extension and restart vscode before " "reinstalling."; out.Write(std::cout); } // Make sure cache directory is valid. if (config->cacheDirectory.empty()) { LOG_S(FATAL) << "Exiting; no cache directory"; exit(1); } // Make sure compile commands directory is valid. if (config->compileCommandsDirectory.empty()) { LOG_S(ERROR) << "No compile commands directory"; exit(1); } config->cacheDirectory = NormalizePath(config->cacheDirectory); EnsureEndsInSlash(config->cacheDirectory); MakeDirectoryRecursive(config->cacheDirectory); // Ensure there is a resource directory. if (config->resourceDirectory.empty()) { config->resourceDirectory = GetWorkingDirectory(); #if defined(_WIN32) config->resourceDirectory += std::string("../../clang_resource_dir/"); #else config->resourceDirectory += std::string("../clang_resource_dir/"); #endif } config->resourceDirectory = NormalizePath(config->resourceDirectory); LOG_S(INFO) << "Using -resource-dir=" << config->resourceDirectory; // Send initialization before starting indexers, so we don't send a // status update too early. // TODO: query request->params.capabilities.textDocument and support // only things the client supports. auto response = Out_InitializeResponse(); response.id = request->id; // response.result.capabilities.textDocumentSync = // lsTextDocumentSyncOptions(); // response.result.capabilities.textDocumentSync->openClose = true; // response.result.capabilities.textDocumentSync->change = // lsTextDocumentSyncKind::Full; // response.result.capabilities.textDocumentSync->willSave = true; // response.result.capabilities.textDocumentSync->willSaveWaitUntil = // true; response.result.capabilities.textDocumentSync = lsTextDocumentSyncKind::Incremental; response.result.capabilities.renameProvider = true; response.result.capabilities.completionProvider = lsCompletionOptions(); response.result.capabilities.completionProvider->resolveProvider = false; // vscode doesn't support trigger character sequences, so we use ':' // for // '::' and '>' for '->'. See // https://github.com/Microsoft/language-server-protocol/issues/138. response.result.capabilities.completionProvider->triggerCharacters = { ".", ":", ">", "#"}; response.result.capabilities.signatureHelpProvider = lsSignatureHelpOptions(); // NOTE: If updating signature help tokens make sure to also update // WorkingFile::FindClosestCallNameInBuffer. response.result.capabilities.signatureHelpProvider ->triggerCharacters = {"(", ","}; response.result.capabilities.codeLensProvider = lsCodeLensOptions(); response.result.capabilities.codeLensProvider->resolveProvider = false; response.result.capabilities.definitionProvider = true; response.result.capabilities.documentHighlightProvider = true; response.result.capabilities.hoverProvider = true; response.result.capabilities.referencesProvider = true; response.result.capabilities.codeActionProvider = true; response.result.capabilities.documentSymbolProvider = true; response.result.capabilities.workspaceSymbolProvider = true; response.result.capabilities.documentLinkProvider = lsDocumentLinkOptions(); response.result.capabilities.documentLinkProvider->resolveProvider = false; ipc->SendOutMessageToClient(IpcId::Initialize, response); // Set project root. config->projectRoot = NormalizePath(request->params.rootUri->GetPath()); EnsureEndsInSlash(config->projectRoot); // Start indexer threads. if (config->indexerCount == 0) { // If the user has not specified how many indexers to run, try to // guess an appropriate value. Default to 80% utilization. const float kDefaultTargetUtilization = 0.8; config->indexerCount = std::thread::hardware_concurrency() * kDefaultTargetUtilization; if (config->indexerCount <= 0) config->indexerCount = 1; } LOG_S(INFO) << "Starting " << config->indexerCount << " indexers"; for (int i = 0; i < config->indexerCount; ++i) { WorkThread::StartThread("indexer" + std::to_string(i), [=]() { return IndexMain(config, file_consumer_shared, timestamp_manager, import_manager, project, working_files, waiter, queue); }); } Timer time; // Open up / load the project. project->Load(config->extraClangArguments, config->compileCommandsDirectory, config->resourceDirectory); time.ResetAndPrint("[perf] Loaded compilation entries (" + std::to_string(project->entries.size()) + " files)"); // Start scanning include directories before dispatching project // files, because that takes a long time. include_complete->Rescan(); time.Reset(); project->ForAllFilteredFiles( config, [&](int i, const Project::Entry& entry) { // std::cerr << "[" << i << "/" << (project->entries.size() - 1) // << "] Dispatching index request for file " << entry.filename // << std::endl; bool is_interactive = working_files->GetFileByFilename(entry.filename) != nullptr; queue->index_request.Enqueue(Index_Request( entry.filename, entry.args, is_interactive, nullopt)); }); // We need to support multiple concurrent index processes. time.ResetAndPrint("[perf] Dispatched initial index requests"); } break; } case IpcId::Exit: { LOG_S(INFO) << "Exiting; got IpcId::Exit"; exit(0); break; } case IpcId::CqueryFreshenIndex: { LOG_S(INFO) << "Freshening " << project->entries.size() << " files"; // TODO: think about this flow and test it more. // Unmark all files whose timestamp has changed. CacheLoader cache_loader(config); for (const auto& file : db->files) { if (!file.def) continue; optional modification_timestamp = GetLastModificationTime(file.def->path); if (!modification_timestamp) continue; optional cached_modification = timestamp_manager->GetLastCachedModificationTime(&cache_loader, file.def->path); if (modification_timestamp != cached_modification) file_consumer_shared->Reset(file.def->path); } // Send index requests for every file. project->ForAllFilteredFiles( config, [&](int i, const Project::Entry& entry) { LOG_S(INFO) << "[" << i << "/" << (project->entries.size() - 1) << "] Dispatching index request for file " << entry.filename; bool is_interactive = working_files->GetFileByFilename(entry.filename) != nullptr; queue->index_request.Enqueue(Index_Request( entry.filename, entry.args, is_interactive, nullopt)); }); break; } case IpcId::CqueryTypeHierarchyTree: { auto msg = message->As(); QueryFile* file; if (!FindFileOrFail(db, msg->id, msg->params.textDocument.uri.GetPath(), &file)) break; WorkingFile* working_file = working_files->GetFileByFilename(file->def->path); Out_CqueryTypeHierarchyTree response; response.id = msg->id; for (const SymbolRef& ref : FindSymbolsAtLocation(working_file, file, msg->params.position)) { if (ref.idx.kind == SymbolKind::Type) { response.result = BuildInheritanceHierarchyForType( db, working_files, QueryTypeId(ref.idx.idx)); break; } if (ref.idx.kind == SymbolKind::Func) { response.result = BuildInheritanceHierarchyForFunc( db, working_files, QueryFuncId(ref.idx.idx)); break; } } ipc->SendOutMessageToClient(IpcId::CqueryTypeHierarchyTree, response); break; } case IpcId::CqueryCallTreeInitial: { auto msg = message->As(); QueryFile* file; if (!FindFileOrFail(db, msg->id, msg->params.textDocument.uri.GetPath(), &file)) break; WorkingFile* working_file = working_files->GetFileByFilename(file->def->path); Out_CqueryCallTree response; response.id = msg->id; for (const SymbolRef& ref : FindSymbolsAtLocation(working_file, file, msg->params.position)) { if (ref.idx.kind == SymbolKind::Func) { response.result = BuildInitialCallTree(db, working_files, QueryFuncId(ref.idx.idx)); break; } } ipc->SendOutMessageToClient(IpcId::CqueryCallTreeInitial, response); break; } case IpcId::CqueryCallTreeExpand: { auto msg = message->As(); Out_CqueryCallTree response; response.id = msg->id; auto func_id = db->usr_to_func.find(msg->params.usr); if (func_id != db->usr_to_func.end()) response.result = BuildExpandCallTree(db, working_files, func_id->second); ipc->SendOutMessageToClient(IpcId::CqueryCallTreeExpand, response); break; } case IpcId::CqueryVars: { auto msg = message->As(); QueryFile* file; if (!FindFileOrFail(db, msg->id, msg->params.textDocument.uri.GetPath(), &file)) break; WorkingFile* working_file = working_files->GetFileByFilename(file->def->path); Out_LocationList response; response.id = msg->id; for (const SymbolRef& ref : FindSymbolsAtLocation(working_file, file, msg->params.position)) { if (ref.idx.kind == SymbolKind::Type) { QueryType& type = db->types[ref.idx.idx]; std::vector locations = ToQueryLocation(db, type.instances); response.result = GetLsLocations(db, working_files, locations); } } ipc->SendOutMessageToClient(IpcId::CqueryVars, response); break; } case IpcId::CqueryCallers: { auto msg = message->As(); QueryFile* file; if (!FindFileOrFail(db, msg->id, msg->params.textDocument.uri.GetPath(), &file)) break; WorkingFile* working_file = working_files->GetFileByFilename(file->def->path); Out_LocationList response; response.id = msg->id; for (const SymbolRef& ref : FindSymbolsAtLocation(working_file, file, msg->params.position)) { if (ref.idx.kind == SymbolKind::Func) { QueryFunc& func = db->funcs[ref.idx.idx]; std::vector locations = ToQueryLocation(db, func.callers); for (QueryFuncRef func_ref : GetCallersForAllBaseFunctions(db, func)) locations.push_back(func_ref.loc); for (QueryFuncRef func_ref : GetCallersForAllDerivedFunctions(db, func)) locations.push_back(func_ref.loc); response.result = GetLsLocations(db, working_files, locations); } } ipc->SendOutMessageToClient(IpcId::CqueryCallers, response); break; } case IpcId::CqueryBase: { auto msg = message->As(); QueryFile* file; if (!FindFileOrFail(db, msg->id, msg->params.textDocument.uri.GetPath(), &file)) break; WorkingFile* working_file = working_files->GetFileByFilename(file->def->path); Out_LocationList response; response.id = msg->id; for (const SymbolRef& ref : FindSymbolsAtLocation(working_file, file, msg->params.position)) { if (ref.idx.kind == SymbolKind::Type) { QueryType& type = db->types[ref.idx.idx]; if (!type.def) continue; std::vector locations = ToQueryLocation(db, type.def->parents); response.result = GetLsLocations(db, working_files, locations); } else if (ref.idx.kind == SymbolKind::Func) { QueryFunc& func = db->funcs[ref.idx.idx]; optional location = GetBaseDefinitionOrDeclarationSpelling(db, func); if (!location) continue; optional ls_loc = GetLsLocation(db, working_files, *location); if (!ls_loc) continue; response.result.push_back(*ls_loc); } } ipc->SendOutMessageToClient(IpcId::CqueryBase, response); break; } case IpcId::CqueryDerived: { auto msg = message->As(); QueryFile* file; if (!FindFileOrFail(db, msg->id, msg->params.textDocument.uri.GetPath(), &file)) break; WorkingFile* working_file = working_files->GetFileByFilename(file->def->path); Out_LocationList response; response.id = msg->id; for (const SymbolRef& ref : FindSymbolsAtLocation(working_file, file, msg->params.position)) { if (ref.idx.kind == SymbolKind::Type) { QueryType& type = db->types[ref.idx.idx]; std::vector locations = ToQueryLocation(db, type.derived); response.result = GetLsLocations(db, working_files, locations); } else if (ref.idx.kind == SymbolKind::Func) { QueryFunc& func = db->funcs[ref.idx.idx]; std::vector locations = ToQueryLocation(db, func.derived); response.result = GetLsLocations(db, working_files, locations); } } ipc->SendOutMessageToClient(IpcId::CqueryDerived, response); break; } case IpcId::TextDocumentDidOpen: { // NOTE: This function blocks code lens. If it starts taking a long time // we will need to find a way to unblock the code lens request. Timer time; auto msg = message->As(); std::string path = msg->params.textDocument.uri.GetPath(); WorkingFile* working_file = working_files->OnOpen(msg->params); optional cached_file_contents = LoadCachedFileContents(config, path); if (cached_file_contents) working_file->SetIndexContent(*cached_file_contents); else working_file->SetIndexContent(working_file->buffer_content); QueryFile* file = nullptr; FindFileOrFail(db, nullopt, path, &file); if (file && file->def) { EmitInactiveLines(working_file, file->def->inactive_regions); EmitSemanticHighlighting(db, working_file, file); } time.ResetAndPrint( "[querydb] Loading cached index file for DidOpen (blocks " "CodeLens)"); include_complete->AddFile(working_file->filename); clang_complete->NotifyView(path); // Submit new index request. const Project::Entry& entry = project->FindCompilationEntryForFile(path); queue->index_request.PriorityEnqueue(Index_Request( entry.filename, entry.args, true /*is_interactive*/, nullopt)); break; } case IpcId::TextDocumentDidChange: { auto msg = message->As(); std::string path = msg->params.textDocument.uri.GetPath(); working_files->OnChange(msg->params); clang_complete->NotifyEdit(path); clang_complete->DiagnosticsUpdate( msg->params.textDocument.AsTextDocumentIdentifier()); break; } case IpcId::TextDocumentDidClose: { auto msg = message->As(); std::string path = msg->params.textDocument.uri.GetPath(); // Clear any diagnostics for the file. Out_TextDocumentPublishDiagnostics diag; diag.params.uri = msg->params.textDocument.uri; IpcManager::instance()->SendOutMessageToClient( IpcId::TextDocumentPublishDiagnostics, diag); // Remove internal state. working_files->OnClose(msg->params); clang_complete->NotifyClose(path); break; } case IpcId::TextDocumentDidSave: { auto msg = message->As(); std::string path = msg->params.textDocument.uri.GetPath(); // Send out an index request, and copy the current buffer state so we // can update the cached index contents when the index is done. // // We also do not index if there is already an index request. // // TODO: Cancel outgoing index request. Might be tricky to make // efficient since we have to cancel. // - we could have an |atomic active_cancellations| variable // that all of the indexers check before accepting an index. if // zero we don't slow down fast-path. if non-zero we acquire // mutex and check to see if we should skip the current request. // if so, ignore that index response. // TODO: send as priority request Project::Entry entry = project->FindCompilationEntryForFile(path); queue->index_request.Enqueue(Index_Request( entry.filename, entry.args, true /*is_interactive*/, nullopt)); clang_complete->NotifySave(path); break; } case IpcId::TextDocumentRename: { auto msg = message->As(); QueryFileId file_id; QueryFile* file; if (!FindFileOrFail(db, msg->id, msg->params.textDocument.uri.GetPath(), &file, &file_id)) break; WorkingFile* working_file = working_files->GetFileByFilename(file->def->path); Out_TextDocumentRename response; response.id = msg->id; for (const SymbolRef& ref : FindSymbolsAtLocation(working_file, file, msg->params.position)) { // Found symbol. Return references to rename. std::vector uses = GetUsesOfSymbol(db, ref.idx); response.result = BuildWorkspaceEdit(db, working_files, uses, msg->params.newName); break; } ipc->SendOutMessageToClient(IpcId::TextDocumentRename, response); break; } case IpcId::TextDocumentCompletion: { auto msg = std::shared_ptr( static_cast(message.release())); std::string path = msg->params.textDocument.uri.GetPath(); WorkingFile* file = working_files->GetFileByFilename(path); // It shouldn't be possible, but sometimes vscode will send queries out // of order, ie, we get completion request before buffer content update. std::string buffer_line; if (msg->params.position.line >= 0 && msg->params.position.line < file->all_buffer_lines.size()) buffer_line = file->all_buffer_lines[msg->params.position.line]; if (ShouldRunIncludeCompletion(buffer_line)) { Out_TextDocumentComplete complete_response; complete_response.id = msg->id; { std::unique_lock lock( include_complete->completion_items_mutex, std::defer_lock); if (include_complete->is_scanning) lock.lock(); complete_response.result.items.assign( include_complete->completion_items.begin(), include_complete->completion_items.end()); if (lock) lock.unlock(); // Update textEdit params. for (lsCompletionItem& item : complete_response.result.items) { item.textEdit->range.start.line = msg->params.position.line; item.textEdit->range.start.character = 0; item.textEdit->range.end.line = msg->params.position.line; item.textEdit->range.end.character = (int)buffer_line.size(); } } FilterCompletionResponse(&complete_response, buffer_line); ipc->SendOutMessageToClient(IpcId::TextDocumentCompletion, complete_response); } else { bool is_global_completion = false; std::string existing_completion; if (file) { msg->params.position = file->FindStableCompletionSource( msg->params.position, &is_global_completion, &existing_completion); } ClangCompleteManager::OnComplete callback = std::bind( [global_code_complete_cache, non_global_code_complete_cache, is_global_completion, existing_completion, msg](const NonElidedVector& results, bool is_cached_result) { Out_TextDocumentComplete complete_response; complete_response.id = msg->id; complete_response.result.items = results; // Emit completion results. FilterCompletionResponse(&complete_response, existing_completion); IpcManager::instance()->SendOutMessageToClient( IpcId::TextDocumentCompletion, complete_response); // Cache completion results. if (!is_cached_result) { std::string path = msg->params.textDocument.uri.GetPath(); if (is_global_completion) { global_code_complete_cache->WithLock([&]() { global_code_complete_cache->cached_path_ = path; global_code_complete_cache->cached_results_ = results; }); } else { non_global_code_complete_cache->WithLock([&]() { non_global_code_complete_cache->cached_path_ = path; non_global_code_complete_cache ->cached_completion_position_ = msg->params.position; non_global_code_complete_cache->cached_results_ = results; }); } } }, std::placeholders::_1, std::placeholders::_2); bool is_cache_match = false; global_code_complete_cache->WithLock([&]() { is_cache_match = is_global_completion && global_code_complete_cache->cached_path_ == path && !global_code_complete_cache->cached_results_.empty(); }); if (is_cache_match) { ClangCompleteManager::OnComplete freshen_global = [global_code_complete_cache]( NonElidedVector results, bool is_cached_result) { assert(!is_cached_result); // note: path is updated in the normal completion handler. global_code_complete_cache->WithLock([&]() { global_code_complete_cache->cached_results_ = results; }); }; global_code_complete_cache->WithLock([&]() { callback(global_code_complete_cache->cached_results_, true /*is_cached_result*/); }); clang_complete->CodeComplete(msg->params, freshen_global); } else if (non_global_code_complete_cache->IsCacheValid( msg->params)) { non_global_code_complete_cache->WithLock([&]() { callback(non_global_code_complete_cache->cached_results_, true /*is_cached_result*/); }); } else { clang_complete->CodeComplete(msg->params, callback); } } break; } case IpcId::TextDocumentSignatureHelp: { auto msg = message->As(); lsTextDocumentPositionParams& params = msg->params; WorkingFile* file = working_files->GetFileByFilename(params.textDocument.uri.GetPath()); std::string search; int active_param = 0; if (file) { lsPosition completion_position; search = file->FindClosestCallNameInBuffer( params.position, &active_param, &completion_position); params.position = completion_position; } if (search.empty()) break; ClangCompleteManager::OnComplete callback = std::bind( [signature_cache](BaseIpcMessage* message, std::string search, int active_param, const NonElidedVector& results, bool is_cached_result) { auto msg = message->As(); auto ipc = IpcManager::instance(); Out_TextDocumentSignatureHelp response; response.id = msg->id; for (auto& result : results) { if (result.label != search) continue; lsSignatureInformation signature; signature.label = result.detail; for (auto& parameter : result.parameters_) { lsParameterInformation ls_param; ls_param.label = parameter; signature.parameters.push_back(ls_param); } response.result.signatures.push_back(signature); } // Guess the signature the user wants based on available parameter // count. response.result.activeSignature = 0; for (size_t i = 0; i < response.result.signatures.size(); ++i) { if (active_param < response.result.signatures.size()) { response.result.activeSignature = (int)i; break; } } // Set signature to what we parsed from the working file. response.result.activeParameter = active_param; Timer timer; ipc->SendOutMessageToClient(IpcId::TextDocumentSignatureHelp, response); if (!is_cached_result) { signature_cache->WithLock([&]() { signature_cache->cached_path_ = msg->params.textDocument.uri.GetPath(); signature_cache->cached_completion_position_ = msg->params.position; signature_cache->cached_results_ = results; }); } delete message; }, message.release(), search, active_param, std::placeholders::_1, std::placeholders::_2); if (signature_cache->IsCacheValid(params)) { signature_cache->WithLock([&]() { callback(signature_cache->cached_results_, true /*is_cached_result*/); }); } else { clang_complete->CodeComplete(params, std::move(callback)); } break; } case IpcId::TextDocumentDefinition: { auto msg = message->As(); QueryFileId file_id; QueryFile* file; if (!FindFileOrFail(db, msg->id, msg->params.textDocument.uri.GetPath(), &file, &file_id)) break; WorkingFile* working_file = working_files->GetFileByFilename(file->def->path); Out_TextDocumentDefinition response; response.id = msg->id; int target_line = msg->params.position.line + 1; int target_column = msg->params.position.character + 1; for (const SymbolRef& ref : FindSymbolsAtLocation(working_file, file, msg->params.position)) { // Found symbol. Return definition. // Special cases which are handled: // - symbol has declaration but no definition (ie, pure virtual) // - start at spelling but end at extent for better mouse tooltip // - goto declaration while in definition of recursive type optional def_loc = GetDefinitionSpellingOfSymbol(db, ref.idx); // We use spelling start and extent end because this causes vscode to // highlight the entire definition when previewing / hoving with the // mouse. optional def_extent = GetDefinitionExtentOfSymbol(db, ref.idx); if (def_loc && def_extent) def_loc->range.end = def_extent->range.end; // If the cursor is currently at or in the definition we should goto // the declaration if possible. We also want to use declarations if // we're pointing to, ie, a pure virtual function which has no // definition. if (!def_loc || (def_loc->path == file_id && def_loc->range.Contains(target_line, target_column))) { // Goto declaration. std::vector declarations = GetDeclarationsOfSymbolForGotoDefinition(db, ref.idx); for (auto declaration : declarations) { optional ls_declaration = GetLsLocation(db, working_files, declaration); if (ls_declaration) response.result.push_back(*ls_declaration); } // We found some declarations. Break so we don't add the definition // location. if (!response.result.empty()) break; } if (def_loc) { PushBack(&response.result, GetLsLocation(db, working_files, *def_loc)); } if (!response.result.empty()) break; } // No symbols - check for includes. if (response.result.empty()) { for (const IndexInclude& include : file->def->includes) { if (include.line == target_line) { lsLocation result; result.uri = lsDocumentUri::FromPath(include.resolved_path); response.result.push_back(result); break; } } } ipc->SendOutMessageToClient(IpcId::TextDocumentDefinition, response); break; } case IpcId::TextDocumentDocumentHighlight: { auto msg = message->As(); QueryFileId file_id; QueryFile* file; if (!FindFileOrFail(db, msg->id, msg->params.textDocument.uri.GetPath(), &file, &file_id)) break; WorkingFile* working_file = working_files->GetFileByFilename(file->def->path); Out_TextDocumentDocumentHighlight response; response.id = msg->id; for (const SymbolRef& ref : FindSymbolsAtLocation(working_file, file, msg->params.position)) { // Found symbol. Return references to highlight. std::vector uses = GetUsesOfSymbol(db, ref.idx); response.result.reserve(uses.size()); for (const QueryLocation& use : uses) { if (use.path != file_id) continue; optional ls_location = GetLsLocation(db, working_files, use); if (!ls_location) continue; lsDocumentHighlight highlight; highlight.kind = lsDocumentHighlightKind::Text; highlight.range = ls_location->range; response.result.push_back(highlight); } break; } ipc->SendOutMessageToClient(IpcId::TextDocumentDocumentHighlight, response); break; } case IpcId::TextDocumentHover: { auto msg = message->As(); QueryFile* file; if (!FindFileOrFail(db, msg->id, msg->params.textDocument.uri.GetPath(), &file)) break; WorkingFile* working_file = working_files->GetFileByFilename(file->def->path); Out_TextDocumentHover response; response.id = msg->id; for (const SymbolRef& ref : FindSymbolsAtLocation(working_file, file, msg->params.position)) { // Found symbol. Return hover. optional ls_range = GetLsRange( working_files->GetFileByFilename(file->def->path), ref.loc.range); if (!ls_range) continue; response.result.contents = GetHoverForSymbol(db, ref.idx); response.result.range = *ls_range; break; } ipc->SendOutMessageToClient(IpcId::TextDocumentHover, response); break; } case IpcId::TextDocumentReferences: { auto msg = message->As(); QueryFile* file; if (!FindFileOrFail(db, msg->id, msg->params.textDocument.uri.GetPath(), &file)) break; WorkingFile* working_file = working_files->GetFileByFilename(file->def->path); Out_TextDocumentReferences response; response.id = msg->id; for (const SymbolRef& ref : FindSymbolsAtLocation(working_file, file, msg->params.position)) { optional excluded_declaration; if (!msg->params.context.includeDeclaration) { LOG_S(INFO) << "Excluding declaration in references"; excluded_declaration = GetDefinitionSpellingOfSymbol(db, ref.idx); } // Found symbol. Return references. std::vector uses = GetUsesOfSymbol(db, ref.idx); response.result.reserve(uses.size()); for (const QueryLocation& use : uses) { if (excluded_declaration.has_value() && use == *excluded_declaration) continue; optional ls_location = GetLsLocation(db, working_files, use); if (ls_location) response.result.push_back(*ls_location); } break; } ipc->SendOutMessageToClient(IpcId::TextDocumentReferences, response); break; } case IpcId::TextDocumentDocumentSymbol: { auto msg = message->As(); Out_TextDocumentDocumentSymbol response; response.id = msg->id; QueryFile* file; if (!FindFileOrFail(db, msg->id, msg->params.textDocument.uri.GetPath(), &file)) break; for (SymbolRef ref : file->def->outline) { optional info = GetSymbolInfo(db, working_files, ref.idx); if (!info) continue; optional location = GetLsLocation(db, working_files, ref.loc); if (!location) continue; info->location = *location; response.result.push_back(*info); } ipc->SendOutMessageToClient(IpcId::TextDocumentDocumentSymbol, response); break; } case IpcId::TextDocumentDocumentLink: { auto msg = message->As(); Out_TextDocumentDocumentLink response; response.id = msg->id; if (config->showDocumentLinksOnIncludes) { QueryFile* file; if (!FindFileOrFail(db, msg->id, msg->params.textDocument.uri.GetPath(), &file)) break; WorkingFile* working_file = working_files->GetFileByFilename( msg->params.textDocument.uri.GetPath()); if (!working_file) { LOG_S(INFO) << "Unable to find working file " << msg->params.textDocument.uri.GetPath(); break; } for (const IndexInclude& include : file->def->includes) { optional buffer_line; optional buffer_line_content = working_file->GetBufferLineContentFromIndexLine(include.line, &buffer_line); if (!buffer_line || !buffer_line_content) continue; // Subtract 1 from line because querydb stores 1-based lines but // vscode expects 0-based lines. optional between_quotes = ExtractQuotedRange(*buffer_line - 1, *buffer_line_content); if (!between_quotes) continue; lsDocumentLink link; link.target = lsDocumentUri::FromPath(include.resolved_path); link.range = *between_quotes; response.result.push_back(link); } } ipc->SendOutMessageToClient(IpcId::TextDocumentDocumentLink, response); break; } case IpcId::TextDocumentCodeAction: { // NOTE: This code snippet will generate some FixIts for testing: // // struct origin { int x, int y }; // void foo() { // point origin = { // x: 0.0, // y: 0.0 // }; // } // auto msg = message->As(); QueryFileId file_id; QueryFile* file; if (!FindFileOrFail(db, msg->id, msg->params.textDocument.uri.GetPath(), &file, &file_id)) break; WorkingFile* working_file = working_files->GetFileByFilename( msg->params.textDocument.uri.GetPath()); if (!working_file) { // TODO: send error response. LOG_S(INFO) << "[error] textDocument/codeAction could not find working file"; break; } Out_TextDocumentCodeAction response; response.id = msg->id; // TODO: auto-insert namespace? int default_line = (int)working_file->all_buffer_lines.size(); // Make sure to call EnsureImplFile before using these. We lazy load // them because computing the values could involve an entire project // scan. optional impl_uri; optional impl_file_id; std::vector syms = FindSymbolsAtLocation(working_file, file, msg->params.range.start); for (SymbolRef sym : syms) { switch (sym.idx.kind) { case SymbolKind::Type: { QueryType& type = db->types[sym.idx.idx]; if (!type.def) break; int num_edits = 0; // Get implementation file. Out_TextDocumentCodeAction::Command command; for (QueryFuncId func_id : type.def->funcs) { QueryFunc& func_def = db->funcs[func_id.id]; if (!func_def.def || func_def.def->definition_extent) continue; EnsureImplFile(db, file_id, impl_uri /*out*/, impl_file_id /*out*/); optional edit = BuildAutoImplementForFunction( db, working_files, working_file, default_line, file_id, *impl_file_id, func_def); if (!edit) continue; ++num_edits; // Merge edits together if they are on the same line. // TODO: be smarter about newline merging? ie, don't end up // with foo()\n\n\n\nfoo(), we want foo()\n\nfoo()\n\n // if (!command.arguments.edits.empty() && command.arguments.edits[command.arguments.edits.size() - 1] .range.end.line == edit->range.start.line) { command.arguments.edits[command.arguments.edits.size() - 1] .newText += edit->newText; } else { command.arguments.edits.push_back(*edit); } } if (command.arguments.edits.empty()) break; // If we're inserting at the end of the document, put a newline // before the insertion. if (command.arguments.edits[0].range.start.line >= default_line) command.arguments.edits[0].newText.insert(0, "\n"); command.arguments.textDocumentUri = *impl_uri; command.title = "Auto-Implement " + std::to_string(num_edits) + " methods on " + type.def->short_name; command.command = "cquery._autoImplement"; response.result.push_back(command); break; } case SymbolKind::Func: { QueryFunc& func = db->funcs[sym.idx.idx]; if (!func.def || func.def->definition_extent) break; EnsureImplFile(db, file_id, impl_uri /*out*/, impl_file_id /*out*/); // Get implementation file. Out_TextDocumentCodeAction::Command command; command.title = "Auto-Implement " + func.def->short_name; command.command = "cquery._autoImplement"; command.arguments.textDocumentUri = *impl_uri; optional edit = BuildAutoImplementForFunction( db, working_files, working_file, default_line, file_id, *impl_file_id, func); if (!edit) break; // If we're inserting at the end of the document, put a newline // before the insertion. if (edit->range.start.line >= default_line) edit->newText.insert(0, "\n"); command.arguments.edits.push_back(*edit); response.result.push_back(command); break; } default: break; } // Only show one auto-impl section. if (!response.result.empty()) break; } std::vector diagnostics; working_files->DoAction( [&]() { diagnostics = working_file->diagnostics_; }); for (lsDiagnostic& diag : diagnostics) { if (diag.range.start.line != msg->params.range.start.line) continue; // For error diagnostics, provide an action to resolve an include. // TODO: find a way to index diagnostic contents so line numbers // don't get mismatched when actively editing a file. std::string include_query = LexWordAroundPos(diag.range.start, working_file->buffer_content); if (diag.severity == lsDiagnosticSeverity::Error && !include_query.empty()) { const size_t kMaxResults = 20; std::unordered_set include_absolute_paths; // Find include candidate strings. for (int i = 0; i < db->detailed_names.size(); ++i) { if (include_absolute_paths.size() > kMaxResults) break; if (db->detailed_names[i].find(include_query) == std::string::npos) continue; optional decl_file_id = GetDeclarationFileForSymbol(db, db->symbols[i]); if (!decl_file_id) continue; QueryFile& decl_file = db->files[decl_file_id->id]; if (!decl_file.def) continue; include_absolute_paths.insert(decl_file.def->path); } // Build include strings. std::unordered_set include_insert_strings; include_insert_strings.reserve(include_absolute_paths.size()); for (const std::string& path : include_absolute_paths) { optional item = include_complete->FindCompletionItemForAbsolutePath(path); if (!item) continue; if (item->textEdit) include_insert_strings.insert(item->textEdit->newText); else if (!item->insertText.empty()) include_insert_strings.insert(item->insertText); else assert(false && "unable to determine insert string for include " "completion item"); } // Build code action. if (!include_insert_strings.empty()) { Out_TextDocumentCodeAction::Command command; // Build edits. for (const std::string& include_insert_string : include_insert_strings) { lsTextEdit edit; optional include_line = FindIncludeLine( working_file->all_buffer_lines, include_insert_string); if (!include_line) continue; edit.range.start.line = *include_line; edit.range.end.line = *include_line; edit.newText = include_insert_string + "\n"; command.arguments.edits.push_back(edit); } // Setup metadata and send to client. if (include_insert_strings.size() == 1) command.title = "Insert " + *include_insert_strings.begin(); else command.title = "Pick one of " + std::to_string(command.arguments.edits.size()) + " includes to insert"; command.command = "cquery._insertInclude"; command.arguments.textDocumentUri = msg->params.textDocument.uri; response.result.push_back(command); } } // clang does not provide accurate enough column reporting for // diagnostics to do good column filtering, so report all // diagnostics on the line. if (!diag.fixits_.empty()) { Out_TextDocumentCodeAction::Command command; command.title = "FixIt: " + diag.message; command.command = "cquery._applyFixIt"; command.arguments.textDocumentUri = msg->params.textDocument.uri; command.arguments.edits = diag.fixits_; response.result.push_back(command); } } ipc->SendOutMessageToClient(IpcId::TextDocumentCodeAction, response); break; } case IpcId::TextDocumentCodeLens: { auto msg = message->As(); Out_TextDocumentCodeLens response; response.id = msg->id; lsDocumentUri file_as_uri = msg->params.textDocument.uri; std::string path = file_as_uri.GetPath(); clang_complete->NotifyView(path); QueryFile* file; if (!FindFileOrFail(db, msg->id, msg->params.textDocument.uri.GetPath(), &file)) break; CommonCodeLensParams common; common.result = &response.result; common.db = db; common.working_files = working_files; common.working_file = working_files->GetFileByFilename(file->def->path); for (SymbolRef ref : file->def->outline) { // NOTE: We OffsetColumn so that the code lens always show up in a // predictable order. Otherwise, the client may randomize it. SymbolIdx symbol = ref.idx; switch (symbol.kind) { case SymbolKind::Type: { QueryType& type = db->types[symbol.idx]; if (!type.def) continue; AddCodeLens("ref", "refs", &common, ref.loc.OffsetStartColumn(0), type.uses, type.def->definition_spelling, true /*force_display*/); AddCodeLens("derived", "derived", &common, ref.loc.OffsetStartColumn(1), ToQueryLocation(db, type.derived), nullopt, false /*force_display*/); AddCodeLens("var", "vars", &common, ref.loc.OffsetStartColumn(2), ToQueryLocation(db, type.instances), nullopt, false /*force_display*/); break; } case SymbolKind::Func: { QueryFunc& func = db->funcs[symbol.idx]; if (!func.def) continue; int16_t offset = 0; std::vector base_callers = GetCallersForAllBaseFunctions(db, func); std::vector derived_callers = GetCallersForAllDerivedFunctions(db, func); if (base_callers.empty() && derived_callers.empty()) { AddCodeLens("call", "calls", &common, ref.loc.OffsetStartColumn(offset++), ToQueryLocation(db, func.callers), nullopt, true /*force_display*/); } else { AddCodeLens("direct call", "direct calls", &common, ref.loc.OffsetStartColumn(offset++), ToQueryLocation(db, func.callers), nullopt, false /*force_display*/); if (!base_callers.empty()) AddCodeLens("base call", "base calls", &common, ref.loc.OffsetStartColumn(offset++), ToQueryLocation(db, base_callers), nullopt, false /*force_display*/); if (!derived_callers.empty()) AddCodeLens("derived call", "derived calls", &common, ref.loc.OffsetStartColumn(offset++), ToQueryLocation(db, derived_callers), nullopt, false /*force_display*/); } AddCodeLens("derived", "derived", &common, ref.loc.OffsetStartColumn(offset++), ToQueryLocation(db, func.derived), nullopt, false /*force_display*/); // "Base" optional base_loc = GetBaseDefinitionOrDeclarationSpelling(db, func); if (base_loc) { optional ls_base = GetLsLocation(db, working_files, *base_loc); if (ls_base) { optional range = GetLsRange(common.working_file, ref.loc.range); if (range) { TCodeLens code_lens; code_lens.range = *range; code_lens.range.start.character += offset++; code_lens.command = lsCommand(); code_lens.command->title = "Base"; code_lens.command->command = "cquery.goto"; code_lens.command->arguments.uri = ls_base->uri; code_lens.command->arguments.position = ls_base->range.start; response.result.push_back(code_lens); } } } break; } case SymbolKind::Var: { QueryVar& var = db->vars[symbol.idx]; if (!var.def) continue; if (var.def->is_local && !config->codeLensOnLocalVariables) continue; bool force_display = true; // Do not show 0 refs on macro with no uses, as it is most likely // a header guard. if (var.def->is_macro) force_display = false; AddCodeLens("ref", "refs", &common, ref.loc.OffsetStartColumn(0), var.uses, var.def->definition_spelling, force_display); break; } case SymbolKind::File: case SymbolKind::Invalid: { assert(false && "unexpected"); break; } }; } ipc->SendOutMessageToClient(IpcId::TextDocumentCodeLens, response); // TODO: We need to move this to a separate request, as the user may // have turned code lens off (ie, a custom DidView notification). if (file && file->def) { WorkingFile* working_file = working_files->GetFileByFilename(file->def->path); EmitInactiveLines(working_file, file->def->inactive_regions); // Do not emit semantic highlighting information here, as it has not // been updated. } break; } case IpcId::WorkspaceSymbol: { // TODO: implement fuzzy search, see // https://github.com/junegunn/fzf/blob/master/src/matcher.go for // inspiration auto msg = message->As(); Out_WorkspaceSymbol response; response.id = msg->id; LOG_S(INFO) << "[querydb] Considering " << db->detailed_names.size() << " candidates for query " << msg->params.query; std::string query = msg->params.query; std::unordered_set inserted_results; inserted_results.reserve(config->maxWorkspaceSearchResults); for (int i = 0; i < db->detailed_names.size(); ++i) { if (db->detailed_names[i].find(query) != std::string::npos) { // Do not show the same entry twice. if (!inserted_results.insert(db->detailed_names[i]).second) continue; InsertSymbolIntoResult(db, working_files, db->symbols[i], &response.result); if (response.result.size() >= config->maxWorkspaceSearchResults) break; } } if (response.result.size() < config->maxWorkspaceSearchResults) { for (int i = 0; i < db->detailed_names.size(); ++i) { if (SubstringMatch(query, db->detailed_names[i])) { // Do not show the same entry twice. if (!inserted_results.insert(db->detailed_names[i]).second) continue; InsertSymbolIntoResult(db, working_files, db->symbols[i], &response.result); if (response.result.size() >= config->maxWorkspaceSearchResults) break; } } } LOG_S(INFO) << "[querydb] Found " << response.result.size() << " results for query " << query; ipc->SendOutMessageToClient(IpcId::WorkspaceSymbol, response); break; } case IpcId::CqueryIndexFile: { auto msg = message->As(); queue->index_request.Enqueue( Index_Request(NormalizePath(msg->params.path), msg->params.args, msg->params.is_interactive, msg->params.contents)); break; } case IpcId::CqueryQueryDbWaitForIdleIndexer: { LOG_S(INFO) << "Waiting for idle"; int idle_count = 0; while (true) { bool has_work = false; has_work |= import_manager->HasActiveQuerydbImports(); has_work |= queue->HasWork(); has_work |= QueryDb_ImportMain(config, db, import_manager, queue, working_files); if (!has_work) ++idle_count; else idle_count = 0; // There are race conditions between each of the three checks above, // so we retry a bunch of times to try to avoid any. if (idle_count > 10) break; } LOG_S(INFO) << "Done waiting for idle"; break; } case IpcId::CqueryExitWhenIdle: { *exit_when_idle = true; WorkThread::request_exit_on_idle = true; break; } default: { LOG_S(FATAL) << "Exiting; unhandled IPC message " << IpcIdToString(message->method_id); exit(1); } } } // TODO: consider rate-limiting and checking for IPC messages so we don't // block requests / we can serve partial requests. if (QueryDb_ImportMain(config, db, import_manager, queue, working_files)) did_work = true; return did_work; } void RunQueryDbThread(const std::string& bin_name, Config* config, MultiQueueWaiter* waiter, QueueManager* queue) { bool exit_when_idle = false; Project project; WorkingFiles working_files; FileConsumer::SharedState file_consumer_shared; ClangCompleteManager clang_complete( config, &project, &working_files, std::bind(&EmitDiagnostics, &working_files, std::placeholders::_1, std::placeholders::_2), std::bind(&IndexWithTuFromCodeCompletion, queue, &file_consumer_shared, std::placeholders::_1, std::placeholders::_2, std::placeholders::_3, std::placeholders::_4)); IncludeComplete include_complete(config, &project); auto global_code_complete_cache = MakeUnique(); auto non_global_code_complete_cache = MakeUnique(); auto signature_cache = MakeUnique(); ImportManager import_manager; TimestampManager timestamp_manager; // Run query db main loop. SetCurrentThreadName("querydb"); QueryDatabase db; while (true) { bool did_work = QueryDbMainLoop( config, &db, &exit_when_idle, waiter, queue, &project, &file_consumer_shared, &import_manager, ×tamp_manager, &working_files, &clang_complete, &include_complete, global_code_complete_cache.get(), non_global_code_complete_cache.get(), signature_cache.get()); // No more work left and exit request. Exit. if (!did_work && exit_when_idle && WorkThread::num_active_threads == 0) { LOG_S(INFO) << "Exiting; exit_when_idle is set and there is no more work"; exit(0); } // Cleanup and free any unused memory. FreeUnusedMemory(); if (!did_work) { waiter->Wait({IpcManager::instance()->threaded_queue_for_server_.get(), &queue->do_id_map, &queue->on_indexed}); } } } //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// // STDIN MAIN ////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// // Separate thread whose only job is to read from stdin and // dispatch read commands to the actual indexer program. This // cannot be done on the main thread because reading from std::cin // blocks. // // |ipc| is connected to a server. void LaunchStdinLoop(Config* config, std::unordered_map* request_times) { WorkThread::StartThread("stdin", [request_times]() { IpcManager* ipc = IpcManager::instance(); std::unique_ptr message = MessageRegistry::instance()->ReadMessageFromStdin(); // Message parsing can fail if we don't recognize the method. if (!message) return WorkThread::Result::MoreWork; (*request_times)[message->method_id] = Timer(); // std::cerr << "[stdin] Got message " << IpcIdToString(message->method_id) // << std::endl; switch (message->method_id) { case IpcId::Initialized: { // TODO: don't send output until we get this notification break; } case IpcId::CancelRequest: { // TODO: support cancellation break; } case IpcId::Exit: { LOG_S(INFO) << "Exiting"; exit(0); break; } case IpcId::CqueryExitWhenIdle: { // querydb needs to know to exit when idle. We return out of the stdin // loop to exit the thread. If we keep parsing input stdin is likely // closed so cquery will exit. LOG_S(INFO) << "cquery will exit when all threads are idle"; ipc->SendMessage(IpcManager::Destination::Server, std::move(message)); return WorkThread::Result::ExitThread; } case IpcId::Initialize: case IpcId::TextDocumentDidOpen: case IpcId::TextDocumentDidChange: case IpcId::TextDocumentDidClose: case IpcId::TextDocumentDidSave: case IpcId::TextDocumentRename: case IpcId::TextDocumentCompletion: case IpcId::TextDocumentSignatureHelp: case IpcId::TextDocumentDefinition: case IpcId::TextDocumentDocumentHighlight: case IpcId::TextDocumentHover: case IpcId::TextDocumentReferences: case IpcId::TextDocumentDocumentSymbol: case IpcId::TextDocumentDocumentLink: case IpcId::TextDocumentCodeAction: case IpcId::TextDocumentCodeLens: case IpcId::WorkspaceSymbol: case IpcId::CqueryFreshenIndex: case IpcId::CqueryTypeHierarchyTree: case IpcId::CqueryCallTreeInitial: case IpcId::CqueryCallTreeExpand: case IpcId::CqueryVars: case IpcId::CqueryCallers: case IpcId::CqueryBase: case IpcId::CqueryDerived: case IpcId::CqueryIndexFile: case IpcId::CqueryQueryDbWaitForIdleIndexer: { ipc->SendMessage(IpcManager::Destination::Server, std::move(message)); break; } default: { LOG_S(ERROR) << "Unhandled IPC message " << IpcIdToString(message->method_id); exit(1); } } return WorkThread::Result::MoreWork; }); } void LaunchStdoutThread(std::unordered_map* request_times, MultiQueueWaiter* waiter, QueueManager* queue) { WorkThread::StartThread("stdout", [=]() { IpcManager* ipc = IpcManager::instance(); std::vector> messages = ipc->GetMessages(IpcManager::Destination::Client); if (messages.empty()) { waiter->Wait({ipc->threaded_queue_for_client_.get()}); return queue->HasWork() ? WorkThread::Result::MoreWork : WorkThread::Result::NoWork; } for (auto& message : messages) { // std::cerr << "[stdout] Processing message " << // IpcIdToString(message->method_id) << std::endl; switch (message->method_id) { case IpcId::Cout: { auto msg = message->As(); if (ShouldDisplayIpcTiming(msg->original_ipc_id)) { Timer time = (*request_times)[msg->original_ipc_id]; time.ResetAndPrint("[e2e] Running " + std::string(IpcIdToString( msg->original_ipc_id))); } std::cout << msg->content; std::cout.flush(); break; } default: { LOG_S(FATAL) << "Exiting; unhandled IPC message " << IpcIdToString(message->method_id); exit(1); } } } return WorkThread::Result::MoreWork; }); } void LanguageServerMain(const std::string& bin_name, Config* config, MultiQueueWaiter* waiter) { QueueManager queue(waiter); std::unordered_map request_times; LaunchStdinLoop(config, &request_times); // We run a dedicated thread for writing to stdout because there can be an // unknown number of delays when output information. LaunchStdoutThread(&request_times, waiter, &queue); // Start querydb which takes over this thread. The querydb will launch // indexer threads as needed. RunQueryDbThread(bin_name, config, waiter, &queue); } //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// // MAIN //////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// int main(int argc, char** argv) { loguru::init(argc, argv); loguru::add_file("cquery_diagnostics.log", loguru::Truncate, loguru::Verbosity_MAX); loguru::g_flush_interval_ms = 0; loguru::g_stderr_verbosity = 1; MultiQueueWaiter waiter; IpcManager::CreateInstance(&waiter); // bool loop = true; // while (loop) // std::this_thread::sleep_for(std::chrono::milliseconds(10)); // std::this_thread::sleep_for(std::chrono::seconds(10)); PlatformInit(); IndexInit(); RegisterMessageTypes(); std::unordered_map options = ParseOptions(argc, argv); bool print_help = true; if (HasOption(options, "--test-unit")) { print_help = false; doctest::Context context; context.applyCommandLine(argc, argv); int res = context.run(); if (context.shouldExit()) return res; } if (HasOption(options, "--test-index")) { print_help = false; RunIndexTests(); std::cerr << std::endl << "[Enter] to exit" << std::endl; std::cin.get(); } if (HasOption(options, "--language-server")) { print_help = false; // std::cerr << "Running language server" << std::endl; auto config = MakeUnique(); LanguageServerMain(argv[0], config.get(), &waiter); return 0; } if (print_help) { std::cout << R"help(cquery help: cquery is a low-latency C++ language server. General: --help Print this help information. --language-server Run as a language server. This implements the language server spec over STDIN and STDOUT. --test-unit Run unit tests. --test-index Run index tests. Configuration: When opening up a directory, cquery will look for a compile_commands.json file emitted by your preferred build system. If not present, cquery will use a recursive directory listing instead. Command line flags can be provided by adding a "clang_args" file in the top-level directory. Each line in that file is a separate argument. There are also a number of configuration options available when initializing the language server - your editor should have tooling to describe those options. See |Config| in this source code for a detailed list of all currently supported options. )help"; } return 0; } TEST_SUITE("LexFunctionDeclaration") { TEST_CASE("simple") { std::string buffer_content = " void Foo(); "; lsPosition declaration = CharPos(buffer_content, 'F'); std::string insert_text; int newlines_after_name = 0; LexFunctionDeclaration(buffer_content, declaration, nullopt, &insert_text, &newlines_after_name); REQUIRE(insert_text == "void Foo() {\n}"); REQUIRE(newlines_after_name == 0); LexFunctionDeclaration(buffer_content, declaration, std::string("Type"), &insert_text, &newlines_after_name); REQUIRE(insert_text == "void Type::Foo() {\n}"); REQUIRE(newlines_after_name == 0); } TEST_CASE("ctor") { std::string buffer_content = " Foo(); "; lsPosition declaration = CharPos(buffer_content, 'F'); std::string insert_text; int newlines_after_name = 0; LexFunctionDeclaration(buffer_content, declaration, std::string("Foo"), &insert_text, &newlines_after_name); REQUIRE(insert_text == "Foo::Foo() {\n}"); REQUIRE(newlines_after_name == 0); } TEST_CASE("dtor") { std::string buffer_content = " ~Foo(); "; lsPosition declaration = CharPos(buffer_content, '~'); std::string insert_text; int newlines_after_name = 0; LexFunctionDeclaration(buffer_content, declaration, std::string("Foo"), &insert_text, &newlines_after_name); REQUIRE(insert_text == "Foo::~Foo() {\n}"); REQUIRE(newlines_after_name == 0); } TEST_CASE("complex return type") { std::string buffer_content = " std::vector Foo(); "; lsPosition declaration = CharPos(buffer_content, 'F'); std::string insert_text; int newlines_after_name = 0; LexFunctionDeclaration(buffer_content, declaration, nullopt, &insert_text, &newlines_after_name); REQUIRE(insert_text == "std::vector Foo() {\n}"); REQUIRE(newlines_after_name == 0); LexFunctionDeclaration(buffer_content, declaration, std::string("Type"), &insert_text, &newlines_after_name); REQUIRE(insert_text == "std::vector Type::Foo() {\n}"); REQUIRE(newlines_after_name == 0); } TEST_CASE("extra complex return type") { std::string buffer_content = " std::function < int() > \n Foo(); "; lsPosition declaration = CharPos(buffer_content, 'F'); std::string insert_text; int newlines_after_name = 0; LexFunctionDeclaration(buffer_content, declaration, nullopt, &insert_text, &newlines_after_name); REQUIRE(insert_text == "std::function < int() > \n Foo() {\n}"); REQUIRE(newlines_after_name == 0); LexFunctionDeclaration(buffer_content, declaration, std::string("Type"), &insert_text, &newlines_after_name); REQUIRE(insert_text == "std::function < int() > \n Type::Foo() {\n}"); REQUIRE(newlines_after_name == 0); } TEST_CASE("parameters") { std::string buffer_content = "void Foo(int a,\n\n int b); "; lsPosition declaration = CharPos(buffer_content, 'F'); std::string insert_text; int newlines_after_name = 0; LexFunctionDeclaration(buffer_content, declaration, nullopt, &insert_text, &newlines_after_name); REQUIRE(insert_text == "void Foo(int a,\n\n int b) {\n}"); REQUIRE(newlines_after_name == 2); LexFunctionDeclaration(buffer_content, declaration, std::string("Type"), &insert_text, &newlines_after_name); REQUIRE(insert_text == "void Type::Foo(int a,\n\n int b) {\n}"); REQUIRE(newlines_after_name == 2); } } TEST_SUITE("LexWordAroundPos") { TEST_CASE("edges") { std::string content = "Foobar"; REQUIRE(LexWordAroundPos(CharPos(content, 'F'), content) == "Foobar"); REQUIRE(LexWordAroundPos(CharPos(content, 'o'), content) == "Foobar"); REQUIRE(LexWordAroundPos(CharPos(content, 'b'), content) == "Foobar"); REQUIRE(LexWordAroundPos(CharPos(content, 'a'), content) == "Foobar"); REQUIRE(LexWordAroundPos(CharPos(content, 'r'), content) == "Foobar"); } TEST_CASE("simple") { std::string content = " Foobar "; REQUIRE(LexWordAroundPos(CharPos(content, 'F'), content) == "Foobar"); REQUIRE(LexWordAroundPos(CharPos(content, 'o'), content) == "Foobar"); REQUIRE(LexWordAroundPos(CharPos(content, 'b'), content) == "Foobar"); REQUIRE(LexWordAroundPos(CharPos(content, 'a'), content) == "Foobar"); REQUIRE(LexWordAroundPos(CharPos(content, 'r'), content) == "Foobar"); } TEST_CASE("underscores and numbers") { std::string content = " _my_t5ype7 "; REQUIRE(LexWordAroundPos(CharPos(content, '_'), content) == "_my_t5ype7"); REQUIRE(LexWordAroundPos(CharPos(content, '5'), content) == "_my_t5ype7"); REQUIRE(LexWordAroundPos(CharPos(content, 'e'), content) == "_my_t5ype7"); REQUIRE(LexWordAroundPos(CharPos(content, '7'), content) == "_my_t5ype7"); } TEST_CASE("dot, dash, colon are skipped") { std::string content = "1. 2- 3:"; REQUIRE(LexWordAroundPos(CharPos(content, '1'), content) == "1"); REQUIRE(LexWordAroundPos(CharPos(content, '2'), content) == "2"); REQUIRE(LexWordAroundPos(CharPos(content, '3'), content) == "3"); } } TEST_SUITE("FindIncludeLine") { TEST_CASE("in document") { std::vector lines = { "#include ", // 0 "#include " // 1 }; REQUIRE(FindIncludeLine(lines, "#include ") == nullopt); } TEST_CASE("insert before") { std::vector lines = { "#include ", // 0 "#include " // 1 }; REQUIRE(FindIncludeLine(lines, "#include ") == 0); } TEST_CASE("insert middle") { std::vector lines = { "#include ", // 0 "#include " // 1 }; REQUIRE(FindIncludeLine(lines, "#include ") == 1); } TEST_CASE("insert after") { std::vector lines = { "#include ", // 0 "#include ", // 1 "", // 2 }; REQUIRE(FindIncludeLine(lines, "#include ") == 2); } TEST_CASE("ignore header") { std::vector lines = { "// FOOBAR", // 0 "// FOOBAR", // 1 "// FOOBAR", // 2 "// FOOBAR", // 3 "", // 4 "#include ", // 5 "#include ", // 6 "", // 7 }; REQUIRE(FindIncludeLine(lines, "#include ") == 5); REQUIRE(FindIncludeLine(lines, "#include ") == 6); REQUIRE(FindIncludeLine(lines, "#include ") == 7); } }