pkg/compiler/lib/src/common/tasks.dart - sdk - Git at Google

 // Copyright (c) 2012, 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.

 library dart2js.common.tasks;

 import 'dart:async'
     show Future, Zone, ZoneDelegate, ZoneSpecification, runZoned;

 /// Used to measure where time is spent in the compiler.
 ///
 /// This exposes [measure] and [measureIo], which wrap an action and associate
 /// the time spent during that action with this task. Nested measurementsccan be
 /// introduced by using [measureSubtask].
 // TODO(sigmund): rename to MeasurableTask
 abstract class CompilerTask {
   final Measurer _measurer;
   final Stopwatch _watch;
   final Map<String, GenericTask> _subtasks = <String, GenericTask>{};

   int _asyncCount = 0;

   // Each task has a fixed, lazily computed, ZoneSpecification and zoneValues
   // for [_measureZoned].
   ZoneSpecification _zoneSpecification;
   Map _zoneValues;

   CompilerTask(this._measurer)
       : _watch = _measurer.enableTaskMeasurements ? new Stopwatch() : null;

   /// Whether measurement is disabled. The functions [measure] and [measureIo]
   /// only measure time if measurements are enabled.
   bool get _isDisabled => _watch == null;

   /// Name to use for reporting timing information. Subclasses should override
   /// this with a proper name, otherwise we use the runtime type of the task.
   String get name => "Unknown task '${this.runtimeType}'";

   bool get isRunning => _watch?.isRunning == true;

   int get timing {
     if (_isDisabled) return 0;
     int total = _watch.elapsedMilliseconds;
     for (GenericTask subtask in _subtasks.values) {
       total += subtask.timing;
     }
     return total;
   }

   Duration get duration {
     if (_isDisabled) return Duration.zero;
     Duration total = _watch.elapsed;
     for (GenericTask subtask in _subtasks.values) {
       total += subtask.duration;
     }
     return total;
   }

   /// Perform [action] and measure its runtime (including any asynchronous
   /// callbacks, such as, [Future.then], but excluding code measured by other
   /// tasks).
   T measure<T>(T action()) => _isDisabled ? action() : _measureZoned(action);

   /// Helper method that starts measuring with this [CompilerTask], that is,
   /// make this task the currently measured task.
   CompilerTask _start() {
     if (_isDisabled) return null;
     CompilerTask previous = _measurer._currentTask;
     _measurer._currentTask = this;
     if (previous != null) previous._watch.stop();
     // Regardless of whether [previous] is `null` we've returned from the
     // eventloop.
     _measurer.stopAsyncWallClock();
     _watch.start();
     return previous;
   }

   /// Helper method that stops measuring with this [CompilerTask], that is,
   /// make [previous] the currently measured task.
   void _stop(CompilerTask previous) {
     if (_isDisabled) return;
     _watch.stop();
     if (previous != null) {
       previous._watch.start();
     } else {
       // If there's no previous task, we're about to return control to the
       // event loop. Start counting that as waiting asynchronous I/O.
       _measurer.startAsyncWallClock();
     }
     _measurer._currentTask = previous;
   }

   T _measureZoned<T>(T action()) {
     // Using zones, we're able to track asynchronous operations correctly, as
     // our zone will be asked to invoke `then` blocks. Then blocks (the closure
     // passed to runZoned, and other closures) are run via the `run` functions
     // below.

     assert(_watch != null);

     // The current zone is already measuring `this` task.
     if (Zone.current[_measurer] == this) return action();

     return runZoned(action,
         zoneValues: _zoneValues ??= {_measurer: this},
         zoneSpecification: _zoneSpecification ??= new ZoneSpecification(
             run: _run, runUnary: _runUnary, runBinary: _runBinary));
   }

   /// Run [f] in [zone]. Running must be delegated to [parent] to ensure that
   /// various state is set up correctly (in particular that `Zone.current`
   /// has the right value). Since [_measureZoned] can be called recursively
   /// (synchronously), some of the measuring zones we create will be parents
   /// of other measuring zones, but we still need to call through the parent
   /// chain. Consequently, we use a zone value keyed by [_measurer] to see if
   /// we should measure or not when delegating.
   R _run<R>(Zone self, ZoneDelegate parent, Zone zone, R f()) {
     if (zone[_measurer] != this) return parent.run(zone, f);
     CompilerTask previous = _start();
     try {
       return parent.run(zone, f);
     } finally {
       _stop(previous);
     }
   }

   /// Same as [run] except that [f] takes one argument, [arg].
   R _runUnary<R, T>(
       Zone self, ZoneDelegate parent, Zone zone, R f(T arg), T arg) {
     if (zone[_measurer] != this) return parent.runUnary(zone, f, arg);
     CompilerTask previous = _start();
     try {
       return parent.runUnary(zone, f, arg);
     } finally {
       _stop(previous);
     }
   }

   /// Same as [run] except that [f] takes two arguments ([a1] and [a2]).
   R _runBinary<R, T1, T2>(Zone self, ZoneDelegate parent, Zone zone,
       R f(T1 a1, T2 a2), T1 a1, T2 a2) {
     if (zone[_measurer] != this) return parent.runBinary(zone, f, a1, a2);
     CompilerTask previous = _start();
     try {
       return parent.runBinary(zone, f, a1, a2);
     } finally {
       _stop(previous);
     }
   }

   /// Asynchronous version of [measure]. Use this when action returns a future
   /// that's truly asynchronous, such I/O. Only one task can use this method
   /// concurrently.
   ///
   /// Note: we assume that this method is used only by the compiler input
   /// provider, but it could be used by other tasks as long as the input
   /// provider will not be called by those tasks.
   Future<T> measureIo<T>(Future<T> action()) {
     if (_isDisabled) return action();

     if (_measurer._currentAsyncTask == null) {
       _measurer._currentAsyncTask = this;
     } else if (_measurer._currentAsyncTask != this) {
       throw "Can't track async task '$name' because"
           " '${_measurer._currentAsyncTask.name}' is already being tracked.";
     }
     _asyncCount++;
     return measure(action).whenComplete(() {
       _asyncCount--;
       if (_asyncCount == 0) _measurer._currentAsyncTask = null;
     });
   }

   /// Measure the time spent in [action] (if in verbose mode) and accumulate it
   /// under a subtask with the given name.
   T measureSubtask<T>(String name, T action()) {
     if (_isDisabled) return action();

     // Use a nested CompilerTask for the measurement to ensure nested [measure]
     // calls work correctly. The subtasks will never themselves have nested
     // subtasks because they are not accessible outside.
     GenericTask subtask = _subtasks[name] ??= new GenericTask(name, _measurer);
     return subtask.measure(action);
   }

   /// Asynchronous version of [measureSubtask]. Use this when action returns a
   /// future that's truly asynchronous, such I/O. Only one task can use this
   /// concurrently.
   ///
   /// Note: we assume that this method is used only by the compiler input
   /// provider, but it could be used by other tasks as long as the input
   /// provider will not be called by those tasks.
   Future<T> measureIoSubtask<T>(String name, Future<T> action()) {
     if (_isDisabled) return action();

     // Use a nested CompilerTask for the measurement to ensure nested [measure]
     // calls work correctly. The subtasks will never themselves have nested
     // subtasks because they are not accessible outside.
     GenericTask subtask = _subtasks[name] ??= new GenericTask(name, _measurer);
     return subtask.measureIo(action);
   }

   Iterable<String> get subtasks => _subtasks.keys;

   int getSubtaskTime(String subtask) => _subtasks[subtask].timing;

   bool getSubtaskIsRunning(String subtask) => _subtasks[subtask].isRunning;
 }

 class GenericTask extends CompilerTask {
   @override
   final String name;
   GenericTask(this.name, Measurer measurer) : super(measurer);
 }

 class Measurer {
   /// Measures the total runtime from this object was constructed.
   ///
   /// Note: MUST be the first field of this class to ensure [wallclock] is
   /// started before other computations.
   final Stopwatch _wallClock = new Stopwatch()..start();

   Duration get elapsedWallClock => _wallClock.elapsed;

   /// Measures gaps between zoned closures due to asynchronicity.
   final Stopwatch _asyncWallClock = new Stopwatch();

   Duration get elapsedAsyncWallClock => _asyncWallClock.elapsed;

   /// Whether measurement of tasks is enabled.
   final bool enableTaskMeasurements;

   static int _hashCodeGenerator = 197;
   @override
   final int hashCode = _hashCodeGenerator++;

   Measurer({this.enableTaskMeasurements: false});

   /// The currently running task, that is, the task whose [Stopwatch] is
   /// currently running.
   CompilerTask _currentTask;

   /// The current task which should be charged for asynchronous gaps.
   CompilerTask _currentAsyncTask;

   /// Start counting the total elapsed time since the compiler started.
   void startWallClock() {
     _wallClock.start();
   }

   /// Start counting the total elapsed time since the compiler started.
   void stopWallClock() {
     _wallClock.stop();
   }

   /// Call this before returning to the eventloop.
   void startAsyncWallClock() {
     if (_currentAsyncTask != null) {
       _currentAsyncTask._watch.start();
     } else {
       _asyncWallClock.start();
     }
   }

   /// Call this when the eventloop returns control to us.
   void stopAsyncWallClock() {
     if (_currentAsyncTask != null) {
       _currentAsyncTask._watch.stop();
     }
     _asyncWallClock.stop();
   }
 }
	// Copyright (c) 2012, 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.

	library dart2js.common.tasks;

	import 'dart:async'
	show Future, Zone, ZoneDelegate, ZoneSpecification, runZoned;

	/// Used to measure where time is spent in the compiler.
	///
	/// This exposes [measure] and [measureIo], which wrap an action and associate
	/// the time spent during that action with this task. Nested measurementsccan be
	/// introduced by using [measureSubtask].
	// TODO(sigmund): rename to MeasurableTask
	abstract class CompilerTask {
	final Measurer _measurer;
	final Stopwatch _watch;
	final Map<String, GenericTask> _subtasks = <String, GenericTask>{};

	int _asyncCount = 0;

	// Each task has a fixed, lazily computed, ZoneSpecification and zoneValues
	// for [_measureZoned].
	ZoneSpecification _zoneSpecification;
	Map _zoneValues;

	CompilerTask(this._measurer)
	: _watch = _measurer.enableTaskMeasurements ? new Stopwatch() : null;

	/// Whether measurement is disabled. The functions [measure] and [measureIo]
	/// only measure time if measurements are enabled.
	bool get _isDisabled => _watch == null;

	/// Name to use for reporting timing information. Subclasses should override
	/// this with a proper name, otherwise we use the runtime type of the task.
	String get name => "Unknown task '${this.runtimeType}'";

	bool get isRunning => _watch?.isRunning == true;

	int get timing {
	if (_isDisabled) return 0;
	int total = _watch.elapsedMilliseconds;
	for (GenericTask subtask in _subtasks.values) {
	total += subtask.timing;
	}
	return total;
	}

	Duration get duration {
	if (_isDisabled) return Duration.zero;
	Duration total = _watch.elapsed;
	for (GenericTask subtask in _subtasks.values) {
	total += subtask.duration;
	}
	return total;
	}

	/// Perform [action] and measure its runtime (including any asynchronous
	/// callbacks, such as, [Future.then], but excluding code measured by other
	/// tasks).
	T measure<T>(T action()) => _isDisabled ? action() : _measureZoned(action);

	/// Helper method that starts measuring with this [CompilerTask], that is,
	/// make this task the currently measured task.
	CompilerTask _start() {
	if (_isDisabled) return null;
	CompilerTask previous = _measurer._currentTask;
	_measurer._currentTask = this;
	if (previous != null) previous._watch.stop();
	// Regardless of whether [previous] is `null` we've returned from the
	// eventloop.
	_measurer.stopAsyncWallClock();
	_watch.start();
	return previous;
	}

	/// Helper method that stops measuring with this [CompilerTask], that is,
	/// make [previous] the currently measured task.
	void _stop(CompilerTask previous) {
	if (_isDisabled) return;
	_watch.stop();
	if (previous != null) {
	previous._watch.start();
	} else {
	// If there's no previous task, we're about to return control to the
	// event loop. Start counting that as waiting asynchronous I/O.
	_measurer.startAsyncWallClock();
	}
	_measurer._currentTask = previous;
	}

	T _measureZoned<T>(T action()) {
	// Using zones, we're able to track asynchronous operations correctly, as
	// our zone will be asked to invoke `then` blocks. Then blocks (the closure
	// passed to runZoned, and other closures) are run via the `run` functions
	// below.

	assert(_watch != null);

	// The current zone is already measuring `this` task.
	if (Zone.current[_measurer] == this) return action();

	return runZoned(action,
	zoneValues: _zoneValues ??= {_measurer: this},
	zoneSpecification: _zoneSpecification ??= new ZoneSpecification(
	run: _run, runUnary: _runUnary, runBinary: _runBinary));
	}

	/// Run [f] in [zone]. Running must be delegated to [parent] to ensure that
	/// various state is set up correctly (in particular that `Zone.current`
	/// has the right value). Since [_measureZoned] can be called recursively
	/// (synchronously), some of the measuring zones we create will be parents
	/// of other measuring zones, but we still need to call through the parent
	/// chain. Consequently, we use a zone value keyed by [_measurer] to see if
	/// we should measure or not when delegating.
	R _run<R>(Zone self, ZoneDelegate parent, Zone zone, R f()) {
	if (zone[_measurer] != this) return parent.run(zone, f);
	CompilerTask previous = _start();
	try {
	return parent.run(zone, f);
	} finally {
	_stop(previous);
	}
	}

	/// Same as [run] except that [f] takes one argument, [arg].
	R _runUnary<R, T>(
	Zone self, ZoneDelegate parent, Zone zone, R f(T arg), T arg) {
	if (zone[_measurer] != this) return parent.runUnary(zone, f, arg);
	CompilerTask previous = _start();
	try {
	return parent.runUnary(zone, f, arg);
	} finally {
	_stop(previous);
	}
	}

	/// Same as [run] except that [f] takes two arguments ([a1] and [a2]).
	R _runBinary<R, T1, T2>(Zone self, ZoneDelegate parent, Zone zone,
	R f(T1 a1, T2 a2), T1 a1, T2 a2) {
	if (zone[_measurer] != this) return parent.runBinary(zone, f, a1, a2);
	CompilerTask previous = _start();
	try {
	return parent.runBinary(zone, f, a1, a2);
	} finally {
	_stop(previous);
	}
	}

	/// Asynchronous version of [measure]. Use this when action returns a future
	/// that's truly asynchronous, such I/O. Only one task can use this method
	/// concurrently.
	///
	/// Note: we assume that this method is used only by the compiler input
	/// provider, but it could be used by other tasks as long as the input
	/// provider will not be called by those tasks.
	Future<T> measureIo<T>(Future<T> action()) {
	if (_isDisabled) return action();

	if (_measurer._currentAsyncTask == null) {
	_measurer._currentAsyncTask = this;
	} else if (_measurer._currentAsyncTask != this) {
	throw "Can't track async task '$name' because"
	" '${_measurer._currentAsyncTask.name}' is already being tracked.";
	}
	_asyncCount++;
	return measure(action).whenComplete(() {
	_asyncCount--;
	if (_asyncCount == 0) _measurer._currentAsyncTask = null;
	});
	}

	/// Measure the time spent in [action] (if in verbose mode) and accumulate it
	/// under a subtask with the given name.
	T measureSubtask<T>(String name, T action()) {
	if (_isDisabled) return action();

	// Use a nested CompilerTask for the measurement to ensure nested [measure]
	// calls work correctly. The subtasks will never themselves have nested
	// subtasks because they are not accessible outside.
	GenericTask subtask = _subtasks[name] ??= new GenericTask(name, _measurer);
	return subtask.measure(action);
	}

	/// Asynchronous version of [measureSubtask]. Use this when action returns a
	/// future that's truly asynchronous, such I/O. Only one task can use this
	/// concurrently.
	///
	/// Note: we assume that this method is used only by the compiler input
	/// provider, but it could be used by other tasks as long as the input
	/// provider will not be called by those tasks.
	Future<T> measureIoSubtask<T>(String name, Future<T> action()) {
	if (_isDisabled) return action();

	// Use a nested CompilerTask for the measurement to ensure nested [measure]
	// calls work correctly. The subtasks will never themselves have nested
	// subtasks because they are not accessible outside.
	GenericTask subtask = _subtasks[name] ??= new GenericTask(name, _measurer);
	return subtask.measureIo(action);
	}

	Iterable<String> get subtasks => _subtasks.keys;

	int getSubtaskTime(String subtask) => _subtasks[subtask].timing;

	bool getSubtaskIsRunning(String subtask) => _subtasks[subtask].isRunning;
	}

	class GenericTask extends CompilerTask {
	@override
	final String name;
	GenericTask(this.name, Measurer measurer) : super(measurer);
	}

	class Measurer {
	/// Measures the total runtime from this object was constructed.
	///
	/// Note: MUST be the first field of this class to ensure [wallclock] is
	/// started before other computations.
	final Stopwatch _wallClock = new Stopwatch()..start();

	Duration get elapsedWallClock => _wallClock.elapsed;

	/// Measures gaps between zoned closures due to asynchronicity.
	final Stopwatch _asyncWallClock = new Stopwatch();

	Duration get elapsedAsyncWallClock => _asyncWallClock.elapsed;

	/// Whether measurement of tasks is enabled.
	final bool enableTaskMeasurements;

	static int _hashCodeGenerator = 197;
	@override
	final int hashCode = _hashCodeGenerator++;

	Measurer({this.enableTaskMeasurements: false});

	/// The currently running task, that is, the task whose [Stopwatch] is
	/// currently running.
	CompilerTask _currentTask;

	/// The current task which should be charged for asynchronous gaps.
	CompilerTask _currentAsyncTask;

	/// Start counting the total elapsed time since the compiler started.
	void startWallClock() {
	_wallClock.start();
	}

	/// Start counting the total elapsed time since the compiler started.
	void stopWallClock() {
	_wallClock.stop();
	}

	/// Call this before returning to the eventloop.
	void startAsyncWallClock() {
	if (_currentAsyncTask != null) {
	_currentAsyncTask._watch.start();
	} else {
	_asyncWallClock.start();
	}
	}

	/// Call this when the eventloop returns control to us.
	void stopAsyncWallClock() {
	if (_currentAsyncTask != null) {
	_currentAsyncTask._watch.stop();
	}
	_asyncWallClock.stop();
	}
	}