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dart / sdk.git / 0ce2773914db8a48f3cf62a4dc093f1b9644c043 / . / pkg / analyzer / lib / src / dart / analysis / driver.dart
blob: 3aa510f210bfbcd7306cd5f1b27ff7c5e809417b [file] [log] [blame]
// Copyright (c) 2016, the Dart project authors. Please see the AUTHORS file
// for details. All rights reserved. Use of this source code is governed by a
// BSD-style license that can be found in the LICENSE file.
import 'dart:async';
import 'dart:typed_data';
import 'package:_fe_analyzer_shared/src/macros/executor/multi_executor.dart'
as macro;
import 'package:analyzer/dart/analysis/analysis_context.dart' as api;
import 'package:analyzer/dart/analysis/declared_variables.dart';
import 'package:analyzer/dart/analysis/results.dart';
import 'package:analyzer/dart/ast/ast.dart';
import 'package:analyzer/error/error.dart';
import 'package:analyzer/error/listener.dart';
import 'package:analyzer/exception/exception.dart';
import 'package:analyzer/file_system/file_system.dart';
import 'package:analyzer/src/context/packages.dart';
import 'package:analyzer/src/dart/analysis/byte_store.dart';
import 'package:analyzer/src/dart/analysis/feature_set_provider.dart';
import 'package:analyzer/src/dart/analysis/file_content_cache.dart';
import 'package:analyzer/src/dart/analysis/file_state.dart';
import 'package:analyzer/src/dart/analysis/file_tracker.dart';
import 'package:analyzer/src/dart/analysis/index.dart';
import 'package:analyzer/src/dart/analysis/library_analyzer.dart';
import 'package:analyzer/src/dart/analysis/library_context.dart';
import 'package:analyzer/src/dart/analysis/performance_logger.dart';
import 'package:analyzer/src/dart/analysis/results.dart';
import 'package:analyzer/src/dart/analysis/search.dart';
import 'package:analyzer/src/dart/analysis/session.dart';
import 'package:analyzer/src/dart/analysis/status.dart';
import 'package:analyzer/src/dart/analysis/testing_data.dart';
import 'package:analyzer/src/dart/element/element.dart';
import 'package:analyzer/src/diagnostic/diagnostic.dart';
import 'package:analyzer/src/error/codes.dart';
import 'package:analyzer/src/exception/exception.dart';
import 'package:analyzer/src/generated/engine.dart'
show AnalysisContext, AnalysisEngine, AnalysisOptions, AnalysisOptionsImpl;
import 'package:analyzer/src/generated/source.dart';
import 'package:analyzer/src/lint/registry.dart' as linter;
import 'package:analyzer/src/summary/api_signature.dart';
import 'package:analyzer/src/summary/format.dart';
import 'package:analyzer/src/summary/idl.dart';
import 'package:analyzer/src/summary/package_bundle_reader.dart';
import 'package:analyzer/src/summary2/ast_binary_flags.dart';
import 'package:analyzer/src/summary2/bundle_writer.dart';
import 'package:analyzer/src/summary2/macro.dart';
import 'package:analyzer/src/summary2/package_bundle_format.dart';
import 'package:analyzer/src/util/file_paths.dart' as file_paths;
import 'package:analyzer/src/util/performance/operation_performance.dart';
import 'package:meta/meta.dart';
/// This class computes [AnalysisResult]s for Dart files.
///
/// Let the set of "explicitly analyzed files" denote the set of paths that have
/// been passed to [addFile] but not subsequently passed to [removeFile]. Let
/// the "current analysis results" denote the map from the set of explicitly
/// analyzed files to the most recent [AnalysisResult] delivered to [results]
/// for each file. Let the "current file state" represent a map from file path
/// to the file contents most recently read from that file, or fetched from the
/// content cache (considering all possible possible file paths, regardless of
/// whether they're in the set of explicitly analyzed files). Let the
/// "analysis state" be either "analyzing" or "idle".
///
/// (These are theoretical constructs; they may not necessarily reflect data
/// structures maintained explicitly by the driver).
///
/// Then we make the following guarantees:
///
/// - Whenever the analysis state is idle, the current analysis results are
/// consistent with the current file state.
///
/// - A call to [addFile] or [changeFile] causes the analysis state to
/// transition to "analyzing", and schedules the contents of the given
/// files to be read into the current file state prior to the next time
/// the analysis state transitions back to "idle".
///
/// - If at any time the client stops making calls to [addFile], [changeFile],
/// and [removeFile], the analysis state will eventually transition back to
/// "idle" after a finite amount of processing.
///
/// As a result of these guarantees, a client may ensure that the analysis
/// results are "eventually consistent" with the file system by simply calling
/// [changeFile] any time the contents of a file on the file system have changed.
///
/// TODO(scheglov) Clean up the list of implicitly analyzed files.
class AnalysisDriver implements AnalysisDriverGeneric {
/// The version of data format, should be incremented on every format change.
static const int DATA_VERSION = 222;
/// The number of exception contexts allowed to write. Once this field is
/// zero, we stop writing any new exception contexts in this process.
static int allowedNumberOfContextsToWrite = 10;
/// The scheduler that schedules analysis work in this, and possibly other
/// analysis drivers.
final AnalysisDriverScheduler _scheduler;
/// The logger to write performed operations and performance to.
final PerformanceLog _logger;
/// The resource provider for working with files.
final ResourceProvider _resourceProvider;
/// The byte storage to get and put serialized data.
///
/// It can be shared with other [AnalysisDriver]s.
final ByteStore _byteStore;
/// The optional store with externally provided unlinked and corresponding
/// linked summaries. These summaries are always added to the store for any
/// file analysis.
final SummaryDataStore? _externalSummaries;
/// This [ContentCache] is consulted for a file content before reading
/// the content from the file.
final FileContentCache _fileContentCache;
/// The analysis options to analyze with.
AnalysisOptionsImpl _analysisOptions;
/// The [Packages] object with packages and their language versions.
Packages _packages;
/// The [SourceFactory] is used to resolve URIs to paths and restore URIs
/// from file paths.
SourceFactory _sourceFactory;
final MacroKernelBuilder? macroKernelBuilder;
/// The instance of macro executor that is used for all macros.
final macro.MultiMacroExecutor? macroExecutor;
/// The declared environment variables.
DeclaredVariables declaredVariables = DeclaredVariables();
/// The analysis context that created this driver / session.
api.AnalysisContext? analysisContext;
/// The salt to mix into all hashes used as keys for unlinked data.
Uint32List _saltForUnlinked = Uint32List(0);
/// The salt to mix into all hashes used as keys for elements.
Uint32List _saltForElements = Uint32List(0);
/// The salt to mix into all hashes used as keys for linked data.
Uint32List _saltForResolution = Uint32List(0);
/// The set of priority files, that should be analyzed sooner.
final _priorityFiles = <String>{};
/// The file changes that should be applied before processing requests.
final List<_FileChange> _pendingFileChanges = [];
/// When [_applyFileChangesSynchronously] is `true`, affected files are
/// accumulated here.
Set<String> _accumulatedAffected = {};
/// The completers to complete after [_pendingFileChanges] are applied.
final _pendingFileChangesCompleters = <Completer<List<String>>>[];
/// The mapping from the files for which analysis was requested using
/// [getResult] to the [Completer]s to report the result.
final _requestedFiles = <String, List<Completer<SomeResolvedUnitResult>>>{};
/// The mapping from the files for which analysis was requested using
/// [getResolvedLibrary] to the [Completer]s to report the result.
final _requestedLibraries =
<String, List<Completer<ResolvedLibraryResult>>>{};
/// The queue of requests for completion.
final List<_ResolveForCompletionRequest> _resolveForCompletionRequests = [];
/// The task that discovers available files. If this field is not `null`,
/// and the task is not completed, it should be performed and completed
/// before any name searching task.
_DiscoverAvailableFilesTask? _discoverAvailableFilesTask;
/// The list of tasks to compute files defining a class member name.
final _definingClassMemberNameTasks = <_FilesDefiningClassMemberNameTask>[];
/// The list of tasks to compute files referencing a name.
final _referencingNameTasks = <_FilesReferencingNameTask>[];
/// The mapping from the files for which errors were requested using
/// [getErrors] to the [Completer]s to report the result.
final _errorsRequestedFiles = <String, List<Completer<SomeErrorsResult>>>{};
/// The mapping from the files for which the index was requested using
/// [getIndex] to the [Completer]s to report the result.
final _indexRequestedFiles =
<String, List<Completer<AnalysisDriverUnitIndex?>>>{};
/// The mapping from the files for which the unit element was requested using
/// [getUnitElement] to the [Completer]s to report the result.
final _unitElementRequestedFiles =
<String, List<Completer<SomeUnitElementResult>>>{};
/// The controller for the [results] stream.
final _resultController = StreamController<Object>();
/// The stream that will be written to when analysis results are produced.
late final Stream<Object> _onResults;
/// Resolution signatures of the most recently produced results for files.
final Map<String, String> _lastProducedSignatures = {};
/// Cached results for [_priorityFiles].
final Map<String, ResolvedUnitResult> _priorityResults = {};
/// The controller for the [exceptions] stream.
final StreamController<ExceptionResult> _exceptionController =
StreamController<ExceptionResult>();
/// The instance of the [Search] helper.
late final Search _search;
late final AnalysisDriverTestView _testView;
late FeatureSetProvider featureSetProvider;
late FileSystemState _fsState;
/// The [FileTracker] used by this driver.
late FileTracker _fileTracker;
/// Whether resolved units should be indexed.
final bool enableIndex;
/// The context in which libraries should be analyzed.
LibraryContext? _libraryContext;
/// Whether `dart:core` has been transitively discovered.
bool _hasDartCoreDiscovered = false;
/// This flag is reset to `false` when a new file is added, because it
/// might be a library, so that some files that were disconnected parts
/// could be analyzed now.
bool _hasLibrariesDiscovered = false;
/// If testing data is being retained, a pointer to the object that is
/// retaining the testing data. Otherwise `null`.
final TestingData? testingData;
/// Create a new instance of [AnalysisDriver].
///
/// The given [SourceFactory] is cloned to ensure that it does not contain a
/// reference to a [AnalysisContext] in which it could have been used.
AnalysisDriver({
required AnalysisDriverScheduler scheduler,
required PerformanceLog logger,
required ResourceProvider resourceProvider,
required ByteStore byteStore,
required SourceFactory sourceFactory,
required AnalysisOptionsImpl analysisOptions,
required Packages packages,
this.macroKernelBuilder,
this.macroExecutor,
FileContentCache? fileContentCache,
this.enableIndex = false,
SummaryDataStore? externalSummaries,
bool retainDataForTesting = false,
}) : _scheduler = scheduler,
_resourceProvider = resourceProvider,
_byteStore = byteStore,
_fileContentCache =
fileContentCache ?? FileContentCache.ephemeral(resourceProvider),
_analysisOptions = analysisOptions,
_logger = logger,
_packages = packages,
_sourceFactory = sourceFactory,
_externalSummaries = externalSummaries,
testingData = retainDataForTesting ? TestingData() : null {
_onResults = _resultController.stream.asBroadcastStream();
_testView = AnalysisDriverTestView(this);
_createFileTracker();
_scheduler.add(this);
_search = Search(this);
}
/// Return the set of files explicitly added to analysis using [addFile].
Set<String> get addedFiles => _fileTracker.addedFiles;
/// Return the analysis options used to control analysis.
AnalysisOptions get analysisOptions => _analysisOptions;
/// Return the current analysis session.
AnalysisSessionImpl get currentSession {
return libraryContext.elementFactory.analysisSession;
}
/// Return the stream that produces [ExceptionResult]s.
Stream<ExceptionResult> get exceptions => _exceptionController.stream;
/// The current file system state.
FileSystemState get fsState => _fsState;
@override
bool get hasFilesToAnalyze {
return hasPendingFileChanges ||
_fileTracker.hasChangedFiles ||
_requestedFiles.isNotEmpty ||
_fileTracker.hasPendingFiles;
}
bool get hasPendingFileChanges => _pendingFileChanges.isNotEmpty;
/// Return the set of files that are known at this moment. This set does not
/// always include all added files or all implicitly used file. If a file has
/// not been processed yet, it might be missing.
Set<String> get knownFiles => _fsState.knownFilePaths;
/// Return the context in which libraries should be analyzed.
LibraryContext get libraryContext {
return _libraryContext ??= LibraryContext(
testView: _testView.libraryContextTestView,
analysisSession: AnalysisSessionImpl(this),
logger: _logger,
byteStore: _byteStore,
analysisOptions: _analysisOptions,
declaredVariables: declaredVariables,
sourceFactory: _sourceFactory,
macroKernelBuilder: macroKernelBuilder,
macroExecutor: macroExecutor,
externalSummaries: _externalSummaries,
fileSystemState: _fsState,
);
}
/// Return the path of the folder at the root of the context.
String get name => analysisContext?.contextRoot.root.path ?? '';
/// Return the number of files scheduled for analysis.
int get numberOfFilesToAnalyze => _fileTracker.numberOfPendingFiles;
/// Return the list of files that the driver should try to analyze sooner.
List<String> get priorityFiles => _priorityFiles.toList(growable: false);
@override
set priorityFiles(List<String> priorityPaths) {
_priorityResults.keys
.toSet()
.difference(priorityPaths.toSet())
.forEach(_priorityResults.remove);
_priorityFiles.clear();
_priorityFiles.addAll(priorityPaths);
_scheduler.notify(this);
}
/// Return the [ResourceProvider] that is used to access the file system.
ResourceProvider get resourceProvider => _resourceProvider;
/// Return the [Stream] that produces [AnalysisResult]s for added files.
///
/// Note that the stream supports only one single subscriber.
///
/// Analysis starts when the [AnalysisDriverScheduler] is started and the
/// driver is added to it. The analysis state transitions to "analyzing" and
/// an analysis result is produced for every added file prior to the next time
/// the analysis state transitions to "idle".
///
/// [ResolvedUnitResult]s are produced for:
/// 1. Files requested using [getResult].
/// 2. Files passed to [addFile] which are also in [priorityFiles].
///
/// [ErrorsResult]s are produced for:
/// 1. Files passed to [addFile] which are not in [priorityFiles].
///
/// At least one analysis result is produced for every file passed to
/// [addFile] or [changeFile] prior to the next time the analysis state
/// transitions to "idle", unless the file is later removed from analysis
/// using [removeFile]. Analysis results for other files are produced only if
/// the changes affect analysis results of other files.
///
/// More than one result might be produced for the same file, even if the
/// client does not change the state of the files.
///
/// Results might be produced even for files that have never been added
/// using [addFile], for example when [getResult] was called for a file.
Stream<Object> get results => _onResults;
/// Return the search support for the driver.
Search get search => _search;
/// Return the source factory used to resolve URIs to paths and restore URIs
/// from file paths.
SourceFactory get sourceFactory => _sourceFactory;
@visibleForTesting
AnalysisDriverTestView get test => _testView;
@override
AnalysisDriverPriority get workPriority {
if (_resolveForCompletionRequests.isNotEmpty) {
return AnalysisDriverPriority.completion;
}
if (_requestedFiles.isNotEmpty) {
return AnalysisDriverPriority.interactive;
}
if (_requestedLibraries.isNotEmpty) {
return AnalysisDriverPriority.interactive;
}
if (_discoverAvailableFilesTask != null &&
!_discoverAvailableFilesTask!.isCompleted) {
return AnalysisDriverPriority.interactive;
}
if (_definingClassMemberNameTasks.isNotEmpty ||
_referencingNameTasks.isNotEmpty) {
return AnalysisDriverPriority.interactive;
}
if (_errorsRequestedFiles.isNotEmpty) {
return AnalysisDriverPriority.interactive;
}
if (_indexRequestedFiles.isNotEmpty) {
return AnalysisDriverPriority.interactive;
}
if (_unitElementRequestedFiles.isNotEmpty) {
return AnalysisDriverPriority.interactive;
}
if (_priorityFiles.isNotEmpty) {
for (String path in _priorityFiles) {
if (_fileTracker.isFilePending(path)) {
return AnalysisDriverPriority.priority;
}
}
}
if (_pendingFileChanges.isNotEmpty) {
return AnalysisDriverPriority.general;
}
if (_fileTracker.hasChangedFiles) {
return AnalysisDriverPriority.changedFiles;
}
if (_fileTracker.hasPendingChangedFiles) {
return AnalysisDriverPriority.generalChanged;
}
if (_fileTracker.hasPendingImportFiles) {
return AnalysisDriverPriority.generalImportChanged;
}
if (_fileTracker.hasPendingErrorFiles) {
return AnalysisDriverPriority.generalWithErrors;
}
if (_fileTracker.hasPendingFiles) {
return AnalysisDriverPriority.general;
}
if (_pendingFileChangesCompleters.isNotEmpty) {
return AnalysisDriverPriority.general;
}
return AnalysisDriverPriority.nothing;
}
@override
void addFile(String path) {
_throwIfNotAbsolutePath(path);
if (!_fsState.hasUri(path)) {
return;
}
if (file_paths.isDart(resourceProvider.pathContext, path)) {
_priorityResults.clear();
_pendingFileChanges.add(
_FileChange(path, _FileChangeKind.add),
);
_scheduler.notify(this);
}
}
/// Return a [Future] that completes after pending file changes are applied,
/// so that [currentSession] can be used to compute results.
///
/// The value is the set of all files that are potentially affected by
/// the pending changes. This set can be both wider than the set of analyzed
/// files (because it may include files imported from other packages, and
/// which are on the import path from a changed file to an analyze file),
/// and narrower than the set of analyzed files (because only files that
/// were previously accessed are considered to be known and affected).
Future<List<String>> applyPendingFileChanges() {
if (_pendingFileChanges.isNotEmpty) {
var completer = Completer<List<String>>();
_pendingFileChangesCompleters.add(completer);
return completer.future;
} else {
var accumulatedAffected = _accumulatedAffected.toList();
_accumulatedAffected = {};
return Future.value(accumulatedAffected);
}
}
/// Builds elements for library files from [uriList], and packs them into
/// a bundle suitable for [PackageBundleReader].
///
/// Disconnected non-library files are ignored.
Future<Uint8List> buildPackageBundle({
required List<Uri> uriList,
PackageBundleSdk? packageBundleSdk,
}) async {
final elementFactory = libraryContext.elementFactory;
final bundleWriter = BundleWriter(
elementFactory.dynamicRef,
);
final packageBundleBuilder = PackageBundleBuilder();
for (final uri in uriList) {
final uriStr = uri.toString();
final libraryResult = await getLibraryByUri(uriStr);
if (libraryResult is LibraryElementResult) {
final libraryElement = libraryResult.element as LibraryElementImpl;
bundleWriter.writeLibraryElement(libraryElement);
packageBundleBuilder.addLibrary(
uriStr,
libraryElement.units.map((e) {
return e.source.uri.toString();
}).toList(),
);
}
}
final writeWriterResult = bundleWriter.finish();
return packageBundleBuilder.finish(
resolutionBytes: writeWriterResult.resolutionBytes,
sdk: packageBundleSdk,
);
}
/// The file with the given [path] might have changed - updated, added or
/// removed. Or not, we don't know. Or it might have, but then changed back.
///
/// The [path] must be absolute and normalized.
///
/// The [path] can be any file - explicitly or implicitly analyzed, or neither.
///
/// Causes the analysis state to transition to "analyzing" (if it is not in
/// that state already). Schedules the file contents for [path] to be read
/// into the current file state prior to the next time the analysis state
/// transitions to "idle".
///
/// Invocation of this method will not prevent a [Future] returned from
/// [getResult] from completing with a result, but the result is not
/// guaranteed to be consistent with the new current file state after this
/// [changeFile] invocation.
void changeFile(String path) {
_throwIfNotAbsolutePath(path);
if (!_fsState.hasUri(path)) {
return;
}
if (file_paths.isDart(resourceProvider.pathContext, path)) {
_priorityResults.clear();
_pendingFileChanges.add(
_FileChange(path, _FileChangeKind.change),
);
_scheduler.notify(this);
}
}
/// Clear the library context and any related data structures. Mostly we do
/// this to reduce memory consumption. The library context holds to every
/// library that was resynthesized, but after some initial analysis we might
/// not get again to many of these libraries. So, we should clear the context
/// periodically.
@visibleForTesting
void clearLibraryContext() {
_libraryContext?.dispose();
_libraryContext = null;
}
/// Some state on which analysis depends has changed, so the driver needs to be
/// re-configured with the new state.
///
/// At least one of the optional parameters should be provided, but only those
/// that represent state that has actually changed need be provided.
void configure({
api.AnalysisContext? analysisContext,
AnalysisOptionsImpl? analysisOptions,
Packages? packages,
SourceFactory? sourceFactory,
}) {
if (analysisContext != null) {
this.analysisContext = analysisContext;
_scheduler.driverWatcher?.addedDriver(this);
}
if (analysisOptions != null) {
_analysisOptions = analysisOptions;
}
if (packages != null) {
_packages = packages;
}
if (sourceFactory != null) {
_sourceFactory = sourceFactory;
}
_priorityResults.clear();
clearLibraryContext();
Iterable<String> addedFiles = _fileTracker.addedFiles;
_createFileTracker();
_fileTracker.addFiles(addedFiles);
_scheduler.notify(this);
}
/// Return a [Future] that completes when discovery of all files that are
/// potentially available is done, so that they are included in [knownFiles].
Future<void> discoverAvailableFiles() {
if (_discoverAvailableFilesTask != null &&
_discoverAvailableFilesTask!.isCompleted) {
return Future.value();
}
_discoverAvailableFiles();
_scheduler.notify(this);
return _discoverAvailableFilesTask!.completer.future;
}
@override
void dispose() {
_scheduler.remove(this);
clearLibraryContext();
}
/// Return the cached [ResolvedUnitResult] for the Dart file with the given
/// [path]. If there is no cached result, return `null`. Usually only results
/// of priority files are cached.
///
/// The [path] must be absolute and normalized.
///
/// The [path] can be any file - explicitly or implicitly analyzed, or neither.
ResolvedUnitResult? getCachedResult(String path) {
_throwIfNotAbsolutePath(path);
return _priorityResults[path];
}
/// Return a [Future] that completes with the [ErrorsResult] for the Dart
/// file with the given [path].
///
/// The [path] must be absolute and normalized.
///
/// This method does not use analysis priorities, and must not be used in
/// interactive analysis, such as Analysis Server or its plugins.
Future<SomeErrorsResult> getErrors(String path) async {
if (!_isAbsolutePath(path)) {
return Future.value(
InvalidPathResult(),
);
}
if (!_fsState.hasUri(path)) {
return Future.value(
NotPathOfUriResult(),
);
}
var completer = Completer<SomeErrorsResult>();
_errorsRequestedFiles
.putIfAbsent(path, () => <Completer<SomeErrorsResult>>[])
.add(completer);
_scheduler.notify(this);
return completer.future;
}
/// Return a [Future] that completes with the [ErrorsResult] for the Dart
/// file with the given [path].
///
/// The [path] must be absolute and normalized.
///
/// This method does not use analysis priorities, and must not be used in
/// interactive analysis, such as Analysis Server or its plugins.
@Deprecated('Use getErrors() instead')
Future<SomeErrorsResult> getErrors2(String path) async {
return getErrors(path);
}
/// Return a [Future] that completes with the list of added files that
/// define a class member with the given [name].
Future<List<String>> getFilesDefiningClassMemberName(String name) {
_discoverAvailableFiles();
var task = _FilesDefiningClassMemberNameTask(this, name);
_definingClassMemberNameTasks.add(task);
_scheduler.notify(this);
return task.completer.future;
}
/// Return a [Future] that completes with the list of known files that
/// reference the given external [name].
Future<List<String>> getFilesReferencingName(String name) {
_discoverAvailableFiles();
var task = _FilesReferencingNameTask(this, name);
_referencingNameTasks.add(task);
_scheduler.notify(this);
return task.completer.future;
}
/// Return the [FileResult] for the Dart file with the given [path].
///
/// The [path] must be absolute and normalized.
SomeFileResult getFileSync(String path) {
if (!_isAbsolutePath(path)) {
return InvalidPathResult();
}
FileState file = _fsState.getFileForPath(path);
return FileResultImpl(
currentSession, path, file.uri, file.lineInfo, file.isPart);
}
/// Return the [FileResult] for the Dart file with the given [path].
///
/// The [path] must be absolute and normalized.
@Deprecated('Use getFileSync() instead')
SomeFileResult getFileSync2(String path) {
return getFileSync(path);
}
/// Return a [Future] that completes with the [AnalysisDriverUnitIndex] for
/// the file with the given [path], or with `null` if the file cannot be
/// analyzed.
Future<AnalysisDriverUnitIndex?> getIndex(String path) {
_throwIfNotAbsolutePath(path);
if (!enableIndex) {
throw ArgumentError('Indexing is not enabled.');
}
if (!_fsState.hasUri(path)) {
return Future.value();
}
var completer = Completer<AnalysisDriverUnitIndex?>();
_indexRequestedFiles
.putIfAbsent(path, () => <Completer<AnalysisDriverUnitIndex?>>[])
.add(completer);
_scheduler.notify(this);
return completer.future;
}
/// Return a [Future] that completes with [LibraryElementResult] for the given
/// [uri], which is either resynthesized from the provided external summary
/// store, or built for a file to which the given [uri] is resolved.
Future<SomeLibraryElementResult> getLibraryByUri(String uri) async {
var uriObj = Uri.parse(uri);
var fileOr = _fsState.getFileForUri(uriObj);
return fileOr.map(
(file) async {
if (file == null) {
return CannotResolveUriResult();
}
if (file.isPart) {
return NotLibraryButPartResult();
}
var unitResult = await getUnitElement(file.path);
if (unitResult is UnitElementResult) {
return LibraryElementResultImpl(unitResult.element.library);
}
// Some invalid results are invalid results for this request.
// Note that up-down promotion does not work.
if (unitResult is InvalidResult &&
unitResult is SomeLibraryElementResult) {
return unitResult as SomeLibraryElementResult;
}
// Should not happen.
return UnspecifiedInvalidResult();
},
(externalLibrary) async {
final uri = externalLibrary.source.uri;
// TODO(scheglov) Check if the source is not for library.
var element = libraryContext.getLibraryElement(uri);
return LibraryElementResultImpl(element);
},
);
}
/// Return a [Future] that completes with [LibraryElementResult] for the given
/// [uri], which is either resynthesized from the provided external summary
/// store, or built for a file to which the given [uri] is resolved.
@Deprecated('Use getLibraryByUri() instead')
Future<SomeLibraryElementResult> getLibraryByUri2(String uri) async {
return getLibraryByUri(uri);
}
/// Return a [ParsedLibraryResult] for the library with the given [path].
///
/// The [path] must be absolute and normalized.
SomeParsedLibraryResult getParsedLibrary(String path) {
if (!_isAbsolutePath(path)) {
return InvalidPathResult();
}
if (!_fsState.hasUri(path)) {
return NotPathOfUriResult();
}
FileState file = _fsState.getFileForPath(path);
if (file.isPart) {
return NotLibraryButPartResult();
}
var units = <ParsedUnitResult>[];
for (var unitFile in file.libraryFiles) {
var unitPath = unitFile.path;
var unitResult = parseFileSync(unitPath);
if (unitResult is! ParsedUnitResult) {
return UnspecifiedInvalidResult();
}
units.add(unitResult);
}
return ParsedLibraryResultImpl(currentSession, units);
}
/// Return a [ParsedLibraryResult] for the library with the given [uri].
SomeParsedLibraryResult getParsedLibraryByUri(Uri uri) {
var fileOr = _fsState.getFileForUri(uri);
return fileOr.map(
(file) {
if (file == null) {
return CannotResolveUriResult();
}
if (file.isPart) {
return NotLibraryButPartResult();
}
return getParsedLibrary(file.path);
},
(externalLibrary) {
return UriOfExternalLibraryResult();
},
);
}
/// Return a [Future] that completes with a [ResolvedLibraryResult] for the
/// Dart library file with the given [path]. If the file cannot be analyzed,
/// the [Future] completes with an [InvalidResult].
///
/// The [path] must be absolute and normalized.
///
/// The [path] can be any file - explicitly or implicitly analyzed, or neither.
///
/// Invocation of this method causes the analysis state to transition to
/// "analyzing" (if it is not in that state already), the driver will produce
/// the resolution result for it, which is consistent with the current file
/// state (including new states of the files previously reported using
/// [changeFile]), prior to the next time the analysis state transitions
/// to "idle".
Future<SomeResolvedLibraryResult> getResolvedLibrary(String path) {
if (!_isAbsolutePath(path)) {
return Future.value(
InvalidPathResult(),
);
}
if (!_fsState.hasUri(path)) {
return Future.value(
NotPathOfUriResult(),
);
}
FileState file = _fsState.getFileForPath(path);
if (file.isPart) {
return Future.value(
NotLibraryButPartResult(),
);
}
// Schedule analysis.
var completer = Completer<ResolvedLibraryResult>();
_requestedLibraries
.putIfAbsent(path, () => <Completer<ResolvedLibraryResult>>[])
.add(completer);
_scheduler.notify(this);
return completer.future;
}
/// Return a [Future] that completes with a [ResolvedLibraryResult] for the
/// Dart library file with the given [uri]. If the file cannot be analyzed,
/// the [Future] completes with an [InvalidResult].
///
/// Invocation of this method causes the analysis state to transition to
/// "analyzing" (if it is not in that state already), the driver will produce
/// the resolution result for it, which is consistent with the current file
/// state (including new states of the files previously reported using
/// [changeFile]), prior to the next time the analysis state transitions
/// to "idle".
Future<SomeResolvedLibraryResult> getResolvedLibraryByUri(Uri uri) {
var fileOr = _fsState.getFileForUri(uri);
return fileOr.map(
(file) async {
if (file == null) {
return CannotResolveUriResult();
}
if (file.isPart) {
return NotLibraryButPartResult();
}
return getResolvedLibrary(file.path);
},
(externalLibrary) async {
return UriOfExternalLibraryResult();
},
);
}
/// Return a [Future] that completes with a [SomeResolvedUnitResult] for the
/// Dart file with the given [path]. If the file cannot be analyzed,
/// the [Future] completes with an [InvalidResult].
///
/// The [path] must be absolute and normalized.
///
/// The [path] can be any file - explicitly or implicitly analyzed, or neither.
///
/// If the driver has the cached analysis result for the file, it is returned.
/// If [sendCachedToStream] is `true`, then the result is also reported into
/// the [results] stream, just as if it were freshly computed.
///
/// Otherwise causes the analysis state to transition to "analyzing" (if it is
/// not in that state already), the driver will produce the analysis result for
/// it, which is consistent with the current file state (including new states
/// of the files previously reported using [changeFile]), prior to the next
/// time the analysis state transitions to "idle".
Future<SomeResolvedUnitResult> getResult(String path,
{bool sendCachedToStream = false}) {
if (!_isAbsolutePath(path)) {
return Future.value(
InvalidPathResult(),
);
}
if (!_fsState.hasUri(path)) {
return Future.value(
NotPathOfUriResult(),
);
}
// Return the cached result.
{
ResolvedUnitResult? result = getCachedResult(path);
if (result != null) {
if (sendCachedToStream) {
_resultController.add(result);
}
return Future.value(result);
}
}
// Schedule analysis.
var completer = Completer<SomeResolvedUnitResult>();
_requestedFiles
.putIfAbsent(path, () => <Completer<SomeResolvedUnitResult>>[])
.add(completer);
_scheduler.notify(this);
return completer.future;
}
/// Return a [Future] that completes with a [SomeResolvedUnitResult] for the
/// Dart file with the given [path]. If the file cannot be analyzed,
/// the [Future] completes with an [InvalidResult].
///
/// The [path] must be absolute and normalized.
///
/// The [path] can be any file - explicitly or implicitly analyzed, or neither.
///
/// If the driver has the cached analysis result for the file, it is returned.
/// If [sendCachedToStream] is `true`, then the result is also reported into
/// the [results] stream, just as if it were freshly computed.
///
/// Otherwise causes the analysis state to transition to "analyzing" (if it is
/// not in that state already), the driver will produce the analysis result for
/// it, which is consistent with the current file state (including new states
/// of the files previously reported using [changeFile]), prior to the next
/// time the analysis state transitions to "idle".
@Deprecated('Use getResult() instead')
Future<SomeResolvedUnitResult> getResult2(String path,
{bool sendCachedToStream = false}) {
return getResult(path);
}
/// Return a [Future] that completes with the [SomeUnitElementResult]
/// for the file with the given [path].
Future<SomeUnitElementResult> getUnitElement(String path) {
if (!_isAbsolutePath(path)) {
return Future.value(
InvalidPathResult(),
);
}
if (!_fsState.hasUri(path)) {
return Future.value(
NotPathOfUriResult(),
);
}
var completer = Completer<SomeUnitElementResult>();
_unitElementRequestedFiles
.putIfAbsent(path, () => <Completer<SomeUnitElementResult>>[])
.add(completer);
_scheduler.notify(this);
return completer.future;
}
/// Return `true` is the file with the given absolute [uri] is a library,
/// or `false` if it is a part. More specifically, return `true` if the file
/// is not known to be a part.
///
/// Correspondingly, return `true` if the [uri] does not correspond to a file,
/// for any reason, e.g. the file does not exist, or the [uri] cannot be
/// resolved to a file path, or the [uri] is invalid, e.g. a `package:` URI
/// without a package name. In these cases we cannot prove that the file is
/// not a part, so it must be a library.
bool isLibraryByUri(Uri uri) {
var fileOr = _fsState.getFileForUri(uri);
return fileOr.map(
(file) => file == null || !file.isPart,
(uri) => false,
);
}
/// Return a [Future] that completes with a [ParsedUnitResult] for the file
/// with the given [path].
///
/// The [path] must be absolute and normalized.
///
/// The [path] can be any file - explicitly or implicitly analyzed, or neither.
///
/// The parsing is performed in the method itself, and the result is not
/// produced through the [results] stream (just because it is not a fully
/// resolved unit).
@Deprecated('Use parseFileSync() instead')
Future<SomeParsedUnitResult> parseFile2(String path) async {
return parseFileSync2(path);
}
/// Return a [ParsedUnitResult] for the file with the given [path].
///
/// The [path] must be absolute and normalized.
///
/// The [path] can be any file - explicitly or implicitly analyzed, or neither.
///
/// The parsing is performed in the method itself, and the result is not
/// produced through the [results] stream (just because it is not a fully
/// resolved unit).
SomeParsedUnitResult parseFileSync(String path) {
if (!_isAbsolutePath(path)) {
return InvalidPathResult();
}
FileState file = _fsState.getFileForPath(path);
RecordingErrorListener listener = RecordingErrorListener();
CompilationUnit unit = file.parse(listener);
return ParsedUnitResultImpl(currentSession, file.path, file.uri,
file.content, file.lineInfo, file.isPart, unit, listener.errors);
}
/// Return a [ParsedUnitResult] for the file with the given [path].
///
/// The [path] must be absolute and normalized.
///
/// The [path] can be any file - explicitly or implicitly analyzed, or neither.
///
/// The parsing is performed in the method itself, and the result is not
/// produced through the [results] stream (just because it is not a fully
/// resolved unit).
@Deprecated('Use parseFile() instead')
SomeParsedUnitResult parseFileSync2(String path) {
return parseFileSync(path);
}
@override
Future<void> performWork() async {
_discoverDartCore();
_discoverLibraries();
if (_resolveForCompletionRequests.isNotEmpty) {
final request = _resolveForCompletionRequests.removeLast();
try {
final result = await _resolveForCompletion(request);
request.completer.complete(result);
} catch (exception, stackTrace) {
_reportException(request.path, exception, stackTrace);
request.completer.completeError(exception, stackTrace);
_clearLibraryContextAfterException();
}
return;
}
// Analyze a requested file.
if (_requestedFiles.isNotEmpty) {
final path = _requestedFiles.keys.first;
final completers = _requestedFiles.remove(path)!;
_fileTracker.fileWasAnalyzed(path);
try {
final result = await _computeAnalysisResult(path, withUnit: true);
final unitResult = result.unitResult!;
for (final completer in completers) {
completer.complete(unitResult);
}
_resultController.add(unitResult);
} catch (exception, stackTrace) {
_reportException(path, exception, stackTrace);
for (final completer in completers) {
completer.completeError(exception, stackTrace);
}
_clearLibraryContextAfterException();
}
return;
}
// Analyze a requested library.
if (_requestedLibraries.isNotEmpty) {
String path = _requestedLibraries.keys.first;
try {
var result = await _computeResolvedLibrary(path);
for (var completer in _requestedLibraries.remove(path)!) {
completer.complete(result);
}
} catch (exception, stackTrace) {
for (var completer in _requestedLibraries.remove(path)!) {
completer.completeError(exception, stackTrace);
}
_clearLibraryContextAfterException();
}
return;
}
// Process an error request.
if (_errorsRequestedFiles.isNotEmpty) {
var path = _errorsRequestedFiles.keys.first;
var completers = _errorsRequestedFiles.remove(path)!;
var result = await _computeErrors(
path: path,
);
for (var completer in completers) {
completer.complete(result);
}
return;
}
// Process an index request.
if (_indexRequestedFiles.isNotEmpty) {
String path = _indexRequestedFiles.keys.first;
final index = await _computeIndex(path);
for (var completer in _indexRequestedFiles.remove(path)!) {
completer.complete(index);
}
return;
}
// Process a unit element request.
if (_unitElementRequestedFiles.isNotEmpty) {
String path = _unitElementRequestedFiles.keys.first;
var completers = _unitElementRequestedFiles.remove(path)!;
final result = await _computeUnitElement(path);
for (var completer in completers) {
completer.complete(result);
}
return;
}
// Discover available files.
if (_discoverAvailableFilesTask != null &&
!_discoverAvailableFilesTask!.isCompleted) {
_discoverAvailableFilesTask!.perform();
return;
}
// Compute files defining a name.
if (_definingClassMemberNameTasks.isNotEmpty) {
_FilesDefiningClassMemberNameTask task =
_definingClassMemberNameTasks.first;
bool isDone = task.perform();
if (isDone) {
_definingClassMemberNameTasks.remove(task);
}
return;
}
// Compute files referencing a name.
if (_referencingNameTasks.isNotEmpty) {
_FilesReferencingNameTask task = _referencingNameTasks.first;
bool isDone = task.perform();
if (isDone) {
_referencingNameTasks.remove(task);
}
return;
}
// Analyze a priority file.
if (_priorityFiles.isNotEmpty) {
for (String path in _priorityFiles) {
if (_fileTracker.isFilePending(path)) {
try {
var result = await _computeAnalysisResult(path, withUnit: true);
_resultController.add(result.unitResult!);
} catch (exception, stackTrace) {
_reportException(path, exception, stackTrace);
_clearLibraryContextAfterException();
} finally {
_fileTracker.fileWasAnalyzed(path);
}
return;
}
}
}
// Analyze a general file.
if (_fileTracker.hasPendingFiles) {
String path = _fileTracker.anyPendingFile;
try {
var result = await _computeAnalysisResult(path,
withUnit: false, skipIfSameSignature: true);
if (result.isUnchangedErrors) {
// We found that the set of errors is the same as we produced the
// last time, so we don't need to produce it again now.
} else {
_resultController.add(result.errorsResult!);
_lastProducedSignatures[path] = result._signature;
}
} catch (exception, stackTrace) {
_reportException(path, exception, stackTrace);
_clearLibraryContextAfterException();
} finally {
_fileTracker.fileWasAnalyzed(path);
}
return;
}
}
/// Remove the file with the given [path] from the list of files to analyze.
///
/// The [path] must be absolute and normalized.
///
/// The results of analysis of the file might still be produced by the
/// [results] stream. The driver will try to stop producing these results,
/// but does not guarantee this.
void removeFile(String path) {
_throwIfNotAbsolutePath(path);
if (!_fsState.hasUri(path)) {
return;
}
if (file_paths.isDart(resourceProvider.pathContext, path)) {
_lastProducedSignatures.remove(path);
_priorityResults.clear();
_pendingFileChanges.add(
_FileChange(path, _FileChangeKind.remove),
);
_scheduler.notify(this);
}
}
Future<ResolvedForCompletionResultImpl?> resolveForCompletion({
required String path,
required int offset,
required OperationPerformanceImpl performance,
}) async {
final request = _ResolveForCompletionRequest(
path: path,
offset: offset,
performance: performance,
);
_resolveForCompletionRequests.add(request);
_scheduler.notify(this);
return request.completer.future;
}
void _addDeclaredVariablesToSignature(ApiSignature buffer) {
var variableNames = declaredVariables.variableNames;
buffer.addInt(variableNames.length);
for (var name in variableNames) {
var value = declaredVariables.get(name);
buffer.addString(name);
buffer.addString(value!);
}
}
void _applyPendingFileChanges() {
var accumulatedAffected = <String>{};
for (var fileChange in _pendingFileChanges) {
var path = fileChange.path;
_removePotentiallyAffectedLibraries(accumulatedAffected, path);
switch (fileChange.kind) {
case _FileChangeKind.add:
_fileTracker.addFile(path);
break;
case _FileChangeKind.change:
_fileTracker.changeFile(path);
break;
case _FileChangeKind.remove:
_fileTracker.removeFile(path);
break;
}
}
_pendingFileChanges.clear();
// Read files, so that synchronous methods also see new content.
while (_fileTracker.verifyChangedFilesIfNeeded()) {}
if (_pendingFileChangesCompleters.isNotEmpty) {
var completers = _pendingFileChangesCompleters.toList();
_pendingFileChangesCompleters.clear();
for (var completer in completers) {
completer.complete(
accumulatedAffected.toList(),
);
}
}
}
/// There was an exception during a file analysis, we don't know why.
/// But it might have been caused by an inconsistency of files state, and
/// the library context state. Reset the library context, and hope that
/// we will solve the inconsistency while loading / building summaries.
void _clearLibraryContextAfterException() {
clearLibraryContext();
}
/// Return the cached or newly computed analysis result of the file with the
/// given [path].
///
/// The [withUnit] flag control which result will be returned.
/// When `true`, [AnalysisResult.unitResult] will be set.
/// Otherwise [AnalysisResult.errorsResult] will be set.
///
/// Return [AnalysisResult._UNCHANGED] if [skipIfSameSignature] is `true` and
/// the resolved signature of the file in its library is the same as the one
/// that was the most recently produced to the client.
Future<AnalysisResult> _computeAnalysisResult(String path,
{required bool withUnit, bool skipIfSameSignature = false}) async {
FileState file = _fsState.getFileForPath(path);
// Prepare the library - the file itself, or the known library.
final FileState library;
final kind = file.kind;
if (kind is LibraryFileStateKind) {
library = kind.file;
} else if (kind is PartFileStateKind) {
library = kind.library ?? kind.asLibrary.file;
} else {
throw UnimplementedError('${kind.runtimeType}');
}
// Prepare the signature and key.
String signature = _getResolvedUnitSignature(library, file);
String key = _getResolvedUnitKey(signature);
// Skip reading if the signature, so errors, are the same as the last time.
if (skipIfSameSignature) {
assert(!withUnit);
if (_lastProducedSignatures[path] == signature) {
return AnalysisResult.unchangedErrors(signature);
}
}
// If we don't need the fully resolved unit, check for the cached result.
if (!withUnit) {
var bytes = _byteStore.get(key);
if (bytes != null) {
return _getAnalysisResultFromBytes(file, signature, bytes);
}
}
// We need the fully resolved unit, or the result is not cached.
return _logger.runAsync('Compute analysis result for $path', () async {
_logger.writeln('Work in $name');
try {
_testView.numOfAnalyzedLibraries++;
if (!_hasLibraryByUri('dart:core')) {
return _newMissingDartLibraryResult(file, 'dart:core');
}
if (!_hasLibraryByUri('dart:async')) {
return _newMissingDartLibraryResult(file, 'dart:async');
}
await libraryContext.load(library);
var results = LibraryAnalyzer(
analysisOptions as AnalysisOptionsImpl,
declaredVariables,
sourceFactory,
libraryContext.elementFactory.libraryOfUri2(library.uriStr),
libraryContext.elementFactory.analysisSession.inheritanceManager,
library,
testingData: testingData,
).analyze();
late Uint8List bytes;
late CompilationUnit resolvedUnit;
for (var unitResult in results) {
var unitBytes =
_serializeResolvedUnit(unitResult.unit, unitResult.errors);
String unitSignature =
_getResolvedUnitSignature(library, unitResult.file);
String unitKey = _getResolvedUnitKey(unitSignature);
_byteStore.put(unitKey, unitBytes);
if (unitResult.file == file) {
bytes = unitBytes;
resolvedUnit = unitResult.unit;
}
}
// Return the result, full or partial.
_logger.writeln('Computed new analysis result.');
var result = _getAnalysisResultFromBytes(file, signature, bytes,
content: withUnit ? file.content : null,
resolvedUnit: withUnit ? resolvedUnit : null);
if (withUnit && _priorityFiles.contains(path)) {
_priorityResults[path] = result.unitResult!;
}
return result;
} catch (exception, stackTrace) {
String? contextKey =
_storeExceptionContext(path, library, exception, stackTrace);
throw _ExceptionState(exception, stackTrace, contextKey);
}
});
}
Future<SomeErrorsResult> _computeErrors({
required String path,
}) async {
var analysisResult = await _computeAnalysisResult(path, withUnit: false);
return analysisResult.errorsResult!;
}
Future<AnalysisDriverUnitIndex> _computeIndex(String path) async {
var analysisResult = await _computeAnalysisResult(path, withUnit: false);
return analysisResult._index!;
}
/// Return the newly computed resolution result of the library with the
/// given [path].
Future<ResolvedLibraryResultImpl> _computeResolvedLibrary(String path) async {
FileState library = _fsState.getFileForPath(path);
return _logger.runAsync('Compute resolved library $path', () async {
_testView.numOfAnalyzedLibraries++;
await libraryContext.load(library);
var unitResults = LibraryAnalyzer(
analysisOptions as AnalysisOptionsImpl,
declaredVariables,
sourceFactory,
libraryContext.elementFactory.libraryOfUri2(library.uriStr),
libraryContext.elementFactory.analysisSession.inheritanceManager,
library,
testingData: testingData)
.analyze();
var resolvedUnits = <ResolvedUnitResult>[];
for (var unitResult in unitResults) {
var unitFile = unitResult.file;
resolvedUnits.add(
ResolvedUnitResultImpl(
currentSession,
unitFile.path,
unitFile.uri,
unitFile.exists,
unitFile.content,
unitFile.lineInfo,
unitFile.isPart,
unitResult.unit,
unitResult.errors,
),
);
}
return ResolvedLibraryResultImpl(
currentSession,
resolvedUnits.first.libraryElement,
resolvedUnits,
);
});
}
Future<UnitElementResult?> _computeUnitElement(String path) async {
FileState file = _fsState.getFileForPath(path);
// Prepare the library - the file itself, or the known library.
final FileState library;
final kind = file.kind;
if (kind is LibraryFileStateKind) {
library = kind.file;
} else if (kind is PartFileStateKind) {
library = kind.library ?? kind.asLibrary.file;
} else {
throw UnimplementedError('${kind.runtimeType}');
}
return _logger.runAsync('Compute unit element for $path', () async {
_logger.writeln('Work in $name');
await libraryContext.load(library);
var element = libraryContext.computeUnitElement(library, file);
return UnitElementResultImpl(
currentSession,
path,
file.uri,
file.lineInfo,
file.isPart,
element,
);
});
}
/// Creates new [FileSystemState] and [FileTracker] objects.
///
/// This is used both on initial construction and whenever the configuration
/// changes.
void _createFileTracker() {
_fillSalt();
featureSetProvider = FeatureSetProvider.build(
sourceFactory: sourceFactory,
resourceProvider: _resourceProvider,
packages: _packages,
packageDefaultFeatureSet: _analysisOptions.contextFeatures,
nonPackageDefaultLanguageVersion:
_analysisOptions.nonPackageLanguageVersion,
nonPackageDefaultFeatureSet: _analysisOptions.nonPackageFeatureSet,
);
_fsState = FileSystemState(
_logger,
_byteStore,
_resourceProvider,
name,
sourceFactory,
analysisContext?.contextRoot.workspace,
analysisOptions,
declaredVariables,
_saltForUnlinked,
_saltForElements,
featureSetProvider,
fileContentCache: _fileContentCache,
);
_fileTracker = FileTracker(_logger, _fsState);
}
/// If this has not been done yet, schedule discovery of all files that are
/// potentially available, so that they are included in [knownFiles].
void _discoverAvailableFiles() {
_discoverAvailableFilesTask ??= _DiscoverAvailableFilesTask(this);
}
/// When we look at a part that has a `part of name;` directive, we
/// usually don't know the library (in contrast to `part of uri;`).
/// So, we have no choice than to resolve this part as its own library.
/// TODO(scheglov) Maybe just return an error result instead?
///
/// But parts of `dart:xyz` libraries are special. The reason is that
/// `dart:core` is always implicitly imported. So, when we start building
/// the library cycle of such "part as a library", we discover `dart:core`,
/// and see that it contains our part. So, we don't add it as a library on
/// its own. But have already committed that it is a library. This causes
/// an exception in `LinkedElementFactory`.
///
/// The current workaround for this is to discover `dart:core` before any
/// analysis.
void _discoverDartCore() {
if (_hasDartCoreDiscovered) {
return;
}
_hasDartCoreDiscovered = true;
_fsState.getFileForUri(Uri.parse('dart:core')).map(
(file) {
file?.transitiveFiles;
},
(externalLibrary) {},
);
}
void _discoverLibraries() {
if (_hasLibrariesDiscovered) {
return;
}
_hasLibrariesDiscovered = true;
for (final path in _fileTracker.addedFiles) {
_fsState.getFileForPath(path);
}
}
void _fillSalt() {
_fillSaltForUnlinked();
_fillSaltForElements();
_fillSaltForResolution();
}
void _fillSaltForElements() {
var buffer = ApiSignature();
buffer.addInt(DATA_VERSION);
buffer.addUint32List(_analysisOptions.signatureForElements);
_addDeclaredVariablesToSignature(buffer);
_saltForElements = buffer.toUint32List();
}
void _fillSaltForResolution() {
var buffer = ApiSignature();
buffer.addInt(DATA_VERSION);
buffer.addBool(enableIndex);
buffer.addBool(enableDebugResolutionMarkers);
buffer.addUint32List(_analysisOptions.signature);
_addDeclaredVariablesToSignature(buffer);
var workspace = analysisContext?.contextRoot.workspace;
workspace?.contributeToResolutionSalt(buffer);
_saltForResolution = buffer.toUint32List();
}
void _fillSaltForUnlinked() {
var buffer = ApiSignature();
buffer.addInt(DATA_VERSION);
buffer.addBool(enableIndex);
buffer.addUint32List(_analysisOptions.unlinkedSignature);
_saltForUnlinked = buffer.toUint32List();
}
/// Load the [AnalysisResult] for the given [file] from the [bytes]. Set
/// optional [content] and [resolvedUnit].
AnalysisResult _getAnalysisResultFromBytes(
FileState file, String signature, Uint8List bytes,
{String? content, CompilationUnit? resolvedUnit}) {
var unit = AnalysisDriverResolvedUnit.fromBuffer(bytes);
List<AnalysisError> errors = _getErrorsFromSerialized(file, unit.errors);
_updateHasErrorOrWarningFlag(file, errors);
var index = unit.index!;
if (content != null && resolvedUnit != null) {
var resolvedUnitResult = ResolvedUnitResultImpl(
currentSession,
file.path,
file.uri,
file.exists,
content,
file.lineInfo,
file.isPart,
resolvedUnit,
errors,
);
return AnalysisResult.unit(signature, resolvedUnitResult, index);
} else {
var errorsResult = ErrorsResultImpl(
currentSession,
file.path,
file.uri,
file.lineInfo,
file.isPart,
errors,
);
return AnalysisResult.errors(signature, errorsResult, index);
}
}
/// Return [AnalysisError]s for the given [serialized] errors.
List<AnalysisError> _getErrorsFromSerialized(
FileState file, List<AnalysisDriverUnitError> serialized) {
List<AnalysisError> errors = <AnalysisError>[];
for (AnalysisDriverUnitError error in serialized) {
var analysisError = ErrorEncoding.decode(file.source, error);
if (analysisError != null) {
errors.add(analysisError);
}
}
return errors;
}
/// Return the key to store fully resolved results for the [signature].
String _getResolvedUnitKey(String signature) {
return '$signature.resolved';
}
/// Return the signature that identifies fully resolved results for the [file]
/// in the [library], e.g. element model, errors, index, etc.
String _getResolvedUnitSignature(FileState library, FileState file) {
ApiSignature signature = ApiSignature();
signature.addUint32List(_saltForResolution);
signature.addString(library.transitiveSignature);
signature.addString(file.contentHash);
return signature.toHex();
}
bool _hasLibraryByUri(String uriStr) {
var uri = Uri.parse(uriStr);
var fileOr = _fsState.getFileForUri(uri);
return fileOr.map(
(file) => file != null && file.exists,
(_) => true,
);
}
bool _isAbsolutePath(String path) {
return _resourceProvider.pathContext.isAbsolute(path);
}
/// We detected that one of the required `dart` libraries is missing.
/// Return the empty analysis result with the error.
AnalysisResult _newMissingDartLibraryResult(
FileState file, String missingUri) {
// TODO(scheglov) Find a better way to report this.
var errorsResult = ErrorsResultImpl(
currentSession,
file.path,
file.uri,
file.lineInfo,
file.isPart,
[
AnalysisError(file.source, 0, 0,
CompileTimeErrorCode.MISSING_DART_LIBRARY, [missingUri])
],
);
return AnalysisResult.errors(
'missing', errorsResult, AnalysisDriverUnitIndexBuilder());
}
void _removePotentiallyAffectedLibraries(
Set<String> accumulatedAffected,
String path,
) {
var affected = <FileState>{};
_fsState.collectAffected(path, affected);
for (var file in affected) {
file.invalidateLibraryCycle();
accumulatedAffected.add(file.path);
}
_libraryContext?.elementFactory.removeLibraries(
affected.map((e) => e.uriStr).toSet(),
);
_libraryContext?.elementFactory.replaceAnalysisSession(
AnalysisSessionImpl(this),
);
}
void _reportException(String path, Object exception, StackTrace stackTrace) {
String? contextKey;
if (exception is _ExceptionState) {
var state = exception;
exception = exception.exception;
stackTrace = state.stackTrace;
contextKey = state.contextKey;
}
CaughtException caught = CaughtException(exception, stackTrace);
var fileContentMap = <String, String>{};
var libraryFile = _fsState.getFileForPath(path);
try {
for (var file in libraryFile.libraryFiles) {
var path = file.path;
fileContentMap[path] = file.content;
}
} catch (_) {
// We might get an exception while parsing to access parts.
// Ignore, continue with the exception that we are reporting now.
}
if (exception is CaughtExceptionWithFiles) {
for (var nested in exception.fileContentMap.entries) {
fileContentMap['nested-${nested.key}'] = nested.value;
}
}
_exceptionController.add(
ExceptionResult(
filePath: path,
fileContentMap: fileContentMap,
fileContent: libraryFile.content,
exception: caught,
contextKey: contextKey,
),
);
}
Future<ResolvedForCompletionResultImpl?> _resolveForCompletion(
_ResolveForCompletionRequest request,
) async {
final path = request.path;
if (!_isAbsolutePath(path)) {
return null;
}
if (!_fsState.hasUri(path)) {
return null;
}
var file = _fsState.getFileForPath(path);
var library = file.isPart ? file.library : file;
if (library == null) {
return null;
}
await libraryContext.load(library);
var unitElement = libraryContext.computeUnitElement(library, file)
as CompilationUnitElementImpl;
var analysisResult = LibraryAnalyzer(
analysisOptions as AnalysisOptionsImpl,
declaredVariables,
sourceFactory,
libraryContext.elementFactory.libraryOfUri2(library.uriStr),
libraryContext.elementFactory.analysisSession.inheritanceManager,
library,
testingData: testingData,
).analyzeForCompletion(
file: file,
offset: request.offset,
unitElement: unitElement,
performance: request.performance,
);
return ResolvedForCompletionResultImpl(
analysisSession: currentSession,
path: path,
uri: file.uri,
exists: file.exists,
content: file.content,
lineInfo: file.lineInfo,
parsedUnit: analysisResult.parsedUnit,
unitElement: unitElement,
resolvedNodes: analysisResult.resolvedNodes,
);
}
/// Serialize the given [resolvedUnit] errors and index into bytes.
Uint8List _serializeResolvedUnit(
CompilationUnit resolvedUnit, List<AnalysisError> errors) {
AnalysisDriverUnitIndexBuilder index = enableIndex
? indexUnit(resolvedUnit)
: AnalysisDriverUnitIndexBuilder();
return AnalysisDriverResolvedUnitBuilder(
errors: errors.map((error) {
return ErrorEncoding.encode(error);
}).toList(),
index: index)
.toBuffer();
}
String? _storeExceptionContext(String path, FileState libraryFile,
Object exception, StackTrace stackTrace) {
if (allowedNumberOfContextsToWrite <= 0) {
return null;
} else {
allowedNumberOfContextsToWrite--;
}
try {
List<AnalysisDriverExceptionFileBuilder> contextFiles = libraryFile
.transitiveFiles
.map((file) => AnalysisDriverExceptionFileBuilder(
path: file.path, content: file.content))
.toList();
contextFiles.sort((a, b) => a.path.compareTo(b.path));
AnalysisDriverExceptionContextBuilder contextBuilder =
AnalysisDriverExceptionContextBuilder(
path: path,
exception: exception.toString(),
stackTrace: stackTrace.toString(),
files: contextFiles);
var bytes = contextBuilder.toBuffer();
String twoDigits(int n) {
if (n >= 10) return '$n';
return '0$n';
}
String threeDigits(int n) {
if (n >= 100) return '$n';
if (n >= 10) return '0$n';
return '00$n';
}
DateTime time = DateTime.now();
String m = twoDigits(time.month);
String d = twoDigits(time.day);
String h = twoDigits(time.hour);
String min = twoDigits(time.minute);
String sec = twoDigits(time.second);
String ms = threeDigits(time.millisecond);
String key = 'exception_${time.year}$m${d}_$h$min${sec}_$ms';
_byteStore.put(key, bytes);
return key;
} catch (_) {
return null;
}
}
/// The driver supports only absolute paths, this method is used to validate
/// any input paths to prevent errors later.
void _throwIfNotAbsolutePath(String path) {
if (!_isAbsolutePath(path)) {
throw ArgumentError('Only absolute paths are supported: $path');
}
}
/// Given the list of [errors] for the [file], update the [file]'s
/// [FileState.hasErrorOrWarning] flag.
void _updateHasErrorOrWarningFlag(
FileState file, List<AnalysisError> errors) {
for (AnalysisError error in errors) {
ErrorSeverity severity = error.errorCode.errorSeverity;
if (severity == ErrorSeverity.ERROR ||
severity == ErrorSeverity.WARNING) {
file.hasErrorOrWarning = true;
return;
}
}
file.hasErrorOrWarning = false;
}
}
/// A generic schedulable interface via the AnalysisDriverScheduler. Currently
/// only implemented by [AnalysisDriver] and the angular plugin, at least as
/// a temporary measure until the official plugin API is ready (and a different
/// scheduler is used)
abstract class AnalysisDriverGeneric {
/// Return `true` if the driver has a file to analyze.
bool get hasFilesToAnalyze;
/// Set the list of files that the driver should try to analyze sooner.
///
/// Every path in the list must be absolute and normalized.
///
/// The driver will produce the results through the [results] stream. The
/// exact order in which results are produced is not defined, neither
/// between priority files, nor between priority and non-priority files.
set priorityFiles(List<String> priorityPaths);
/// Return the priority of work that the driver needs to perform.
AnalysisDriverPriority get workPriority;
/// Add the file with the given [path] to the set of files that are explicitly
/// being analyzed.
///
/// The [path] must be absolute and normalized.
///
/// The results of analysis are eventually produced by the [results] stream.
void addFile(String path);
/// Notify the driver that the client is going to stop using it.
void dispose();
/// Perform a single chunk of work and produce [results].
Future<void> performWork();
}
/// Priorities of [AnalysisDriver] work. The farther a priority to the beginning
/// of the list, the earlier the corresponding [AnalysisDriver] should be asked
/// to perform work.
enum AnalysisDriverPriority {
nothing,
general,
generalWithErrors,
generalImportChanged,
generalChanged,
changedFiles,
priority,
interactive,
completion
}
/// Instances of this class schedule work in multiple [AnalysisDriver]s so that
/// work with the highest priority is performed first.
class AnalysisDriverScheduler {
/// Time interval in milliseconds before pumping the event queue.
///
/// Relinquishing execution flow and running the event loop after every task
/// has too much overhead. Instead we use a fixed length of time, so we can
/// spend less time overall and still respond quickly enough.
static const int _MS_BEFORE_PUMPING_EVENT_QUEUE = 2;
/// Event queue pumping is required to allow IO and other asynchronous data
/// processing while analysis is active. For example Analysis Server needs to
/// be able to process `updateContent` or `setPriorityFiles` requests while
/// background analysis is in progress.
///
/// The number of pumpings is arbitrary, might be changed if we see that
/// analysis or other data processing tasks are starving. Ideally we would
/// need to run all asynchronous operations using a single global scheduler.
static const int _NUMBER_OF_EVENT_QUEUE_PUMPINGS = 128;
final PerformanceLog _logger;
/// The object used to watch as analysis drivers are created and deleted.
final DriverWatcher? driverWatcher;
final List<AnalysisDriverGeneric> _drivers = [];
final Monitor _hasWork = Monitor();
final StatusSupport _statusSupport = StatusSupport();
bool _started = false;
/// The optional worker that is invoked when its work priority is higher
/// than work priorities in drivers.
///
/// Don't use outside of Analyzer and Analysis Server.
SchedulerWorker? outOfBandWorker;
AnalysisDriverScheduler(this._logger, {this.driverWatcher});
/// Return `true` if we are currently analyzing code.
bool get isAnalyzing => _hasFilesToAnalyze;
/// Return the stream that produces [AnalysisStatus] events.
Stream<AnalysisStatus> get status => _statusSupport.stream;
/// Return `true` if there is a driver with a file to analyze.
bool get _hasFilesToAnalyze {
for (AnalysisDriverGeneric driver in _drivers) {
if (driver.hasFilesToAnalyze) {
return true;
}
}
return false;
}
/// Add the given [driver] and schedule it to perform its work.
void add(AnalysisDriverGeneric driver) {
_drivers.add(driver);
_hasWork.notify();
if (driver is AnalysisDriver && driver.analysisContext != null) {
driverWatcher?.addedDriver(driver);
}
}
/// Notify that there is a change to the [driver], it it might need to
/// perform some work.
void notify(AnalysisDriverGeneric? driver) {
// TODO(brianwilkerson) Consider removing the parameter, given that it isn't
// referenced in the body.
_hasWork.notify();
_statusSupport.preTransitionToAnalyzing();
}
/// Remove the given [driver] from the scheduler, so that it will not be
/// asked to perform any new work.
void remove(AnalysisDriverGeneric driver) {
if (driver is AnalysisDriver) {
driverWatcher?.removedDriver(driver);
}
_drivers.remove(driver);
_hasWork.notify();
}
/// Start the scheduler, so that any [AnalysisDriver] created before or
/// after will be asked to perform work.
void start() {
if (_started) {
throw StateError('The scheduler has already been started.');
}
_started = true;
_run();
}
/// Usually we transition status to analyzing only if there are files to
/// analyze. However when used in the server, there are rare cases when
/// analysis roots don't have any Dart files, but for consistency we still
/// want to get status to transition to analysis, and back to idle.
void transitionToAnalyzingToIdleIfNoFilesToAnalyze() {
if (!_hasFilesToAnalyze) {
_statusSupport.transitionToAnalyzing();
_statusSupport.transitionToIdle();
}
}
/// Return a future that will be completed the next time the status is idle.
///
/// If the status is currently idle, the returned future will be signaled
/// immediately.
Future<void> waitForIdle() => _statusSupport.waitForIdle();
/// Run infinitely analysis cycle, selecting the drivers with the highest
/// priority first.
Future<void> _run() async {
// Give other microtasks the time to run before doing the analysis cycle.
await null;
Stopwatch timer = Stopwatch()..start();
PerformanceLogSection? analysisSection;
while (true) {
// Pump the event queue.
if (timer.elapsedMilliseconds > _MS_BEFORE_PUMPING_EVENT_QUEUE) {
await _pumpEventQueue(_NUMBER_OF_EVENT_QUEUE_PUMPINGS);
timer.reset();
}
await _hasWork.signal;
for (var driver in _drivers) {
if (driver is AnalysisDriver) {
driver._applyPendingFileChanges();
}
}
// Transition to analyzing if there are files to analyze.
if (_hasFilesToAnalyze) {
_statusSupport.transitionToAnalyzing();
analysisSection ??= _logger.enter('Analyzing');
}
// Find the driver with the highest priority.
late AnalysisDriverGeneric bestDriver;
AnalysisDriverPriority bestPriority = AnalysisDriverPriority.nothing;
for (AnalysisDriverGeneric driver in _drivers) {
AnalysisDriverPriority priority = driver.workPriority;
if (priority.index > bestPriority.index) {
bestDriver = driver;
bestPriority = priority;
}
}
if (outOfBandWorker != null) {
var workerPriority = outOfBandWorker!.workPriority;
if (workerPriority != AnalysisDriverPriority.nothing) {
if (workerPriority.index > bestPriority.index) {
await outOfBandWorker!.performWork();
_hasWork.notify();
continue;
}
}
}
// Transition to idle if no files to analyze.
if (!_hasFilesToAnalyze) {
_statusSupport.transitionToIdle();
analysisSection?.exit();
analysisSection = null;
}
// Continue to sleep if no work to do.
if (bestPriority == AnalysisDriverPriority.nothing) {
continue;
}
// Ask the driver to perform a chunk of work.
await bestDriver.performWork();
// Schedule one more cycle.
_hasWork.notify();
}
}
/// Returns a [Future] that completes after performing [times] pumpings of
/// the event queue.
static Future _pumpEventQueue(int times) {
if (times == 0) {
return Future.value();
}
return Future.delayed(Duration.zero, () => _pumpEventQueue(times - 1));
}
}
@visibleForTesting
class AnalysisDriverTestView {
final AnalysisDriver driver;
final LibraryContextTestView libraryContextTestView =
LibraryContextTestView();
int numOfAnalyzedLibraries = 0;
AnalysisDriverTestView(this.driver);
FileTracker get fileTracker => driver._fileTracker;
Set<String> get loadedLibraryUriSet {
var elementFactory = driver.libraryContext.elementFactory;
var libraryReferences = elementFactory.rootReference.children;
return libraryReferences.map((e) => e.name).toSet();
}
Map<String, ResolvedUnitResult> get priorityResults {
return driver._priorityResults;
}
}
/// The result of analyzing of a single file.
///
/// These results are self-consistent, i.e. the file content, line info, the
/// resolved unit correspond to each other. All referenced elements, even
/// external ones, are also self-consistent. But none of the results is
/// guaranteed to be consistent with the state of the files.
///
/// Every result is independent, and is not guaranteed to be consistent with
/// any previously returned result, even inside of the same library.
class AnalysisResult {
/// The signature of the result based on the content of the file, and the
/// transitive closure of files imported and exported by the library of
/// the requested file.
final String _signature;
final bool isUnchangedErrors;
/// Is not `null` if this result is a result with errors.
/// Otherwise is `null`, and usually [unitResult] is set.
final ErrorsResultImpl? errorsResult;
/// Is not `null` if this result is a result with a resolved unit.
/// Otherwise is `null`, and usually [errorsResult] is set.
final ResolvedUnitResultImpl? unitResult;
/// The index of the unit.
final AnalysisDriverUnitIndex? _index;
AnalysisResult.errors(
this._signature, this.errorsResult, AnalysisDriverUnitIndex index)
: isUnchangedErrors = false,
unitResult = null,
_index = index;
AnalysisResult.unchangedErrors(this._signature)
: isUnchangedErrors = true,
errorsResult = null,
unitResult = null,
_index = null;
AnalysisResult.unit(
this._signature, this.unitResult, AnalysisDriverUnitIndex index)
: isUnchangedErrors = false,
errorsResult = null,
_index = index;
}
/// An object that watches for the creation and removal of analysis drivers.
///
/// Clients may not extend, implement or mix-in this class.
abstract class DriverWatcher {
/// The context manager has just added the given analysis [driver]. This method
/// must be called before the driver has been allowed to perform any analysis.
void addedDriver(AnalysisDriver driver);
/// The context manager has just removed the given analysis [driver].
void removedDriver(AnalysisDriver driver);
}
class ErrorEncoding {
static AnalysisError? decode(
Source source,
AnalysisDriverUnitError error,
) {
String errorName = error.uniqueName;
ErrorCode? errorCode =
errorCodeByUniqueName(errorName) ?? _lintCodeByUniqueName(errorName);
if (errorCode == null) {
// This could fail because the error code is no longer defined, or, in
// the case of a lint rule, if the lint rule has been disabled since the
// errors were written.
AnalysisEngine.instance.instrumentationService
.logError('No error code for "$error" in "$source"');
return null;
}
var contextMessages = <DiagnosticMessageImpl>[];
for (var message in error.contextMessages) {
var url = message.url;
contextMessages.add(
DiagnosticMessageImpl(
filePath: message.filePath,
length: message.length,
message: message.message,
offset: message.offset,
url: url.isEmpty ? null : url,
),
);
}
return AnalysisError.forValues(
source,
error.offset,
error.length,
errorCode,
error.message,
error.correction.isEmpty ? null : error.correction,
contextMessages: contextMessages,
);
}
static AnalysisDriverUnitErrorBuilder encode(AnalysisError error) {
var contextMessages = <DiagnosticMessageBuilder>[];
for (var message in error.contextMessages) {
contextMessages.add(
DiagnosticMessageBuilder(
filePath: message.filePath,
length: message.length,
message: message.messageText(includeUrl: false),
offset: message.offset,
url: message.url,
),
);
}
return AnalysisDriverUnitErrorBuilder(
offset: error.offset,
length: error.length,
uniqueName: error.errorCode.uniqueName,
message: error.message,
correction: error.correction ?? '',
contextMessages: contextMessages,
);
}
/// Return the lint code with the given [errorName], or `null` if there is no
/// lint registered with that name.
static ErrorCode? _lintCodeByUniqueName(String errorName) {
return linter.Registry.ruleRegistry.codeForUniqueName(errorName);
}
}
/// Exception that happened during analysis.
class ExceptionResult {
/// The path of the library being analyzed when the [exception] happened.
///
/// Absolute and normalized.
final String filePath;
/// The content of the library and its parts.
final Map<String, String> fileContentMap;
/// The path of the file being analyzed when the [exception] happened.
@Deprecated('Use fileContentMap instead')
final String fileContent;
/// The exception during analysis of the file with the [filePath].
final CaughtException exception;
/// If the exception happened during a file analysis, and the context in which
/// the exception happened was stored, this field is the key of the context
/// in the byte store. May be `null` if the context is unknown, the maximum
/// number of context to store was reached, etc.
final String? contextKey;
ExceptionResult({
required this.filePath,
required this.fileContentMap,
required this.fileContent,
required this.exception,
required this.contextKey,
});
}
/// Worker in [AnalysisDriverScheduler].
abstract class SchedulerWorker {
/// Return the priority of work that this worker needs to perform.
AnalysisDriverPriority get workPriority;
/// Perform a single chunk of work.
Future<void> performWork();
}
/// Task that discovers all files that are available to the driver, and makes
/// them known.
class _DiscoverAvailableFilesTask {
static const int _MS_WORK_INTERVAL = 5;
final AnalysisDriver driver;
final Completer<void> completer = Completer<void>();
Iterator<Folder>? folderIterator;
final List<String> files = [];
int fileIndex = 0;
_DiscoverAvailableFilesTask(this.driver);
bool get isCompleted => completer.isCompleted;
/// Perform the next piece of work, and set [isCompleted] to `true` to
/// indicate that the task is done, or keeps it `false` to indicate that the
/// task should continue to be run.
void perform() {
if (folderIterator == null) {
files.addAll(driver.addedFiles);
// Discover SDK libraries.
var dartSdk = driver._sourceFactory.dartSdk;
if (dartSdk != null) {
for (var sdkLibrary in dartSdk.sdkLibraries) {
var file = dartSdk.mapDartUri(sdkLibrary.shortName)!.fullName;
files.add(file);
}
}
// Discover files in package/lib folders.
var packageMap = driver._sourceFactory.packageMap;
if (packageMap != null) {
folderIterator = packageMap.values.expand((f) => f).iterator;
} else {
folderIterator = <Folder>[].iterator;
}
}
// List each package/lib folder recursively.
Stopwatch timer = Stopwatch()..start();
while (folderIterator!.moveNext()) {
var folder = folderIterator!.current;
_appendFilesRecursively(folder);
// Note: must check if we are exiting before calling moveNext()
// otherwise we will skip one iteration of the loop when we come back.
if (timer.elapsedMilliseconds > _MS_WORK_INTERVAL) {
return;
}
}
// Get know files one by one.
while (fileIndex < files.length) {
if (timer.elapsedMilliseconds > _MS_WORK_INTERVAL) {
return;
}
var file = files[fileIndex++];
driver._fsState.getFileForPath(file);
}
// The task is done, clean up.
folderIterator = null;
files.clear();
completer.complete();
}
void _appendFilesRecursively(Folder folder) {
try {
var pathContext = driver.resourceProvider.pathContext;
for (var child in folder.getChildren()) {
if (child is File) {
var path = child.path;
if (file_paths.isDart(pathContext, path)) {
files.add(path);
}
} else if (child is Folder) {
_appendFilesRecursively(child);
}
}
} catch (_) {}
}
}
/// Information about an exception and its context.
class _ExceptionState {
final Object exception;
final StackTrace stackTrace;
/// The key under which the context of the exception was stored, or `null`
/// if unknown, the maximum number of context to store was reached, etc.
final String? contextKey;
_ExceptionState(this.exception, this.stackTrace, this.contextKey);
@override
String toString() => '$exception\n$stackTrace';
}
class _FileChange {
final String path;
final _FileChangeKind kind;
_FileChange(this.path, this.kind);
@override
String toString() {
return '[path: $path][kind: $kind]';
}
}
enum _FileChangeKind { add, change, remove }
/// Task that computes the list of files that were added to the driver and
/// declare a class member with the given [name].
class _FilesDefiningClassMemberNameTask {
static const int _MS_WORK_INTERVAL = 5;
final AnalysisDriver driver;
final String name;
final Completer<List<String>> completer = Completer<List<String>>();
final List<String> definingFiles = <String>[];
final Set<String> checkedFiles = <String>{};
final List<String> filesToCheck = <String>[];
_FilesDefiningClassMemberNameTask(this.driver, this.name);
/// Perform work for a fixed length of time, and complete the [completer] to
/// either return `true` to indicate that the task is done, or return `false`
/// to indicate that the task should continue to be run.
///
/// Each invocation of an asynchronous method has overhead, which looks as
/// `_SyncCompleter.complete` invocation, we see as much as 62% in some
/// scenarios. Instead we use a fixed length of time, so we can spend less time
/// overall and keep quick enough response time.
bool perform() {
Stopwatch timer = Stopwatch()..start();
while (timer.elapsedMilliseconds < _MS_WORK_INTERVAL) {
// Prepare files to check.
if (filesToCheck.isEmpty) {
Set<String> newFiles = driver.knownFiles.difference(checkedFiles);
filesToCheck.addAll(newFiles);
}
// If no more files to check, complete and done.
if (filesToCheck.isEmpty) {
completer.complete(definingFiles);
return true;
}
// Check the next file.
String path = filesToCheck.removeLast();
FileState file = driver._fsState.getFileForPath(path);
if (file.definedClassMemberNames.contains(name)) {
definingFiles.add(path);
}
checkedFiles.add(path);
}
// We're not done yet.
return false;
}
}
/// Task that computes the list of files that were added to the driver and
/// have at least one reference to an identifier [name] defined outside of the
/// file.
class _FilesReferencingNameTask {
static const int _WORK_FILES = 100;
static const int _MS_WORK_INTERVAL = 5;
final AnalysisDriver driver;
final String name;
final Completer<List<String>> completer = Completer<List<String>>();
int fileStamp = -1;
List<FileState>? filesToCheck;
int filesToCheckIndex = -1;
final List<String> referencingFiles = <String>[];
_FilesReferencingNameTask(this.driver, this.name);
/// Perform work for a fixed length of time, and complete the [completer] to
/// either return `true` to indicate that the task is done, or return `false`
/// to indicate that the task should continue to be run.
///
/// Each invocation of an asynchronous method has overhead, which looks as
/// `_SyncCompleter.complete` invocation, we see as much as 62% in some
/// scenarios. Instead we use a fixed length of time, so we can spend less time
/// overall and keep quick enough response time.
bool perform() {
if (driver._fsState.fileStamp != fileStamp) {
filesToCheck = null;
referencingFiles.clear();
}
// Prepare files to check.
if (filesToCheck == null) {
fileStamp = driver._fsState.fileStamp;
filesToCheck = driver._fsState.knownFiles;
filesToCheckIndex = 0;
}
Stopwatch timer = Stopwatch()..start();
while (filesToCheckIndex < filesToCheck!.length) {
if (filesToCheckIndex % _WORK_FILES == 0 &&
timer.elapsedMilliseconds > _MS_WORK_INTERVAL) {
return false;
}
FileState file = filesToCheck![filesToCheckIndex++];
if (file.referencedNames.contains(name)) {
referencingFiles.add(file.path);
}
}
// If no more files to check, complete and done.
completer.complete(referencingFiles);
return true;
}
}
class _ResolveForCompletionRequest {
final String path;
final int offset;
final OperationPerformanceImpl performance;
final Completer<ResolvedForCompletionResultImpl?> completer = Completer();
_ResolveForCompletionRequest({
required this.path,
required this.offset,
required this.performance,
});
}