pkg/compiler/lib/src/universe/world_builder.dart - sdk.git - 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 world_builder;

 import 'dart:collection';

 import '../common.dart';
 import '../common/names.dart' show Identifiers, Names;
 import '../common_elements.dart';
 import '../constants/values.dart';
 import '../elements/entities.dart';
 import '../elements/types.dart';
 import '../js_backend/allocator_analysis.dart' show KAllocatorAnalysis;
 import '../js_backend/backend_usage.dart' show BackendUsageBuilder;
 import '../js_backend/interceptor_data.dart' show InterceptorDataBuilder;
 import '../js_backend/native_data.dart' show NativeBasicData, NativeDataBuilder;
 import '../js_backend/no_such_method_registry.dart';
 import '../js_backend/runtime_types.dart';
 import '../js_model/locals.dart';
 import '../js_model/elements.dart' show JSignatureMethod;
 import '../kernel/element_map_impl.dart';
 import '../kernel/kelements.dart';
 import '../native/enqueue.dart' show NativeResolutionEnqueuer;
 import '../options.dart';
 import '../universe/class_set.dart';
 import '../util/enumset.dart';
 import '../util/util.dart';
 import '../world.dart' show World, JClosedWorld, KClosedWorld, OpenWorld;
 import 'class_hierarchy_builder.dart' show ClassHierarchyBuilder, ClassQueries;
 import 'selector.dart' show Selector;
 import 'use.dart'
     show
         ConstantUse,
         ConstantUseKind,
         DynamicUse,
         DynamicUseKind,
         StaticUse,
         StaticUseKind;

 part 'codegen_world_builder.dart';
 part 'member_usage.dart';
 part 'resolution_world_builder.dart';

 /// The combined constraints on receivers all the dynamic call sites of the same
 /// selector.
 ///
 /// For instance for these calls
 ///
 ///     class A {
 ///        foo(a, b) {}
 ///     }
 ///     class B {
 ///        foo(a, b) {}
 ///     }
 ///     class C {
 ///        foo(a, b) {}
 ///     }
 ///     new A().foo(a, b);
 ///     new B().foo(0, 42);
 ///
 /// the selector constraints for dynamic calls to 'foo' with two positional
 /// arguments could be 'receiver of exact instance `A` or `B`'.
 abstract class SelectorConstraints {
   /// Returns `true` if [selector] applies to [element] under these constraints
   /// given the closed [world].
   ///
   /// Consider for instance in this world:
   ///
   ///     class A {
   ///        foo(a, b) {}
   ///     }
   ///     class B {
   ///        foo(a, b) {}
   ///     }
   ///     new A().foo(a, b);
   ///
   /// Ideally the selector constraints for calls `foo` with two positional
   /// arguments apply to `A.foo` but `B.foo`.
   bool applies(MemberEntity element, Selector selector, covariant World world);

   /// Returns `true` if at least one of the receivers matching these constraints
   /// in the closed [world] have no implementation matching [selector].
   ///
   /// For instance for this code snippet
   ///
   ///     class A {}
   ///     class B { foo() {} }
   ///     m(b) => (b ? new A() : new B()).foo();
   ///
   /// the potential receiver `new A()` has no implementation of `foo` and thus
   /// needs to handle the call through its `noSuchMethod` handler.
   bool needsNoSuchMethodHandling(Selector selector, covariant World world);
 }

 /// A mutable [SelectorConstraints] used in [WorldBuilder].
 abstract class UniverseSelectorConstraints extends SelectorConstraints {
   /// Adds [constraint] to these selector constraints. Return `true` if the set
   /// of potential receivers expanded due to the new constraint.
   bool addReceiverConstraint(covariant Object constraint);
 }

 /// Strategy for computing the constraints on potential receivers of dynamic
 /// call sites.
 abstract class SelectorConstraintsStrategy {
   /// Create a [UniverseSelectorConstraints] to represent the global receiver
   /// constraints for dynamic call sites with [selector].
   UniverseSelectorConstraints createSelectorConstraints(Selector selector);

   /// Returns `true`  if [member] is a potential target of [dynamicUse].
   bool appliedUnnamed(DynamicUse dynamicUse, MemberEntity member, World world);
 }

 class OpenWorldStrategy implements SelectorConstraintsStrategy {
   const OpenWorldStrategy();

   OpenWorldConstraints createSelectorConstraints(Selector selector) {
     return new OpenWorldConstraints();
   }

   @override
   bool appliedUnnamed(DynamicUse dynamicUse, MemberEntity member, World world) {
     Selector selector = dynamicUse.selector;
     return selector.appliesUnnamed(member);
   }
 }

 class OpenWorldConstraints extends UniverseSelectorConstraints {
   bool isAll = false;

   @override
   bool applies(MemberEntity element, Selector selector, World world) => isAll;

   @override
   bool needsNoSuchMethodHandling(Selector selector, World world) => isAll;

   @override
   bool addReceiverConstraint(Object constraint) {
     if (isAll) return false;
     isAll = true;
     return true;
   }

   String toString() {
     if (isAll) {
       return '<all>';
     } else {
       return '<none>';
     }
   }
 }

 bool useStrongModeWorldStrategy = false;

 /// Open world strategy that constrains instance member access to subtypes of
 /// the static type of the receiver.
 ///
 /// This strategy is used for Dart 2.
 class StrongModeWorldStrategy implements SelectorConstraintsStrategy {
   const StrongModeWorldStrategy();

   StrongModeWorldConstraints createSelectorConstraints(Selector selector) {
     return new StrongModeWorldConstraints();
   }

   @override
   bool appliedUnnamed(
       DynamicUse dynamicUse, MemberEntity member, covariant OpenWorld world) {
     Selector selector = dynamicUse.selector;
     StrongModeConstraint constraint = dynamicUse.receiverConstraint;
     return selector.appliesUnnamed(member) &&
         (constraint == null || constraint.canHit(member, selector, world));
   }
 }

 class StrongModeWorldConstraints extends UniverseSelectorConstraints {
   bool isAll = false;
   Set<StrongModeConstraint> _constraints;

   @override
   bool applies(MemberEntity element, Selector selector, World world) {
     if (isAll) return true;
     if (_constraints == null) return false;
     for (StrongModeConstraint constraint in _constraints) {
       if (constraint.canHit(element, selector, world)) {
         return true;
       }
     }
     return false;
   }

   @override
   bool needsNoSuchMethodHandling(Selector selector, World world) {
     if (isAll) {
       return true;
     }
     if (_constraints != null) {
       for (StrongModeConstraint constraint in _constraints) {
         if (constraint.needsNoSuchMethodHandling(selector, world)) {
           return true;
         }
       }
     }
     return false;
   }

   @override
   bool addReceiverConstraint(StrongModeConstraint constraint) {
     if (isAll) return false;
     if (constraint?.cls == null) {
       isAll = true;
       _constraints = null;
       return true;
     }
     _constraints ??= new Set<StrongModeConstraint>();
     return _constraints.add(constraint);
   }

   String toString() {
     if (isAll) {
       return '<all>';
     } else if (_constraints != null) {
       return '<${_constraints.map((c) => c.cls).join(',')}>';
     } else {
       return '<none>';
     }
   }
 }

 class StrongModeConstraint {
   final ClassEntity cls;

   const StrongModeConstraint(this.cls);

   bool needsNoSuchMethodHandling(Selector selector, World world) => true;

   bool canHit(MemberEntity element, Selector selector, OpenWorld world) {
     return world.isInheritedInSubtypeOf(element, cls);
   }

   bool operator ==(other) {
     if (identical(this, other)) return true;
     if (other is! StrongModeConstraint) return false;
     return cls == other.cls;
   }

   int get hashCode => cls.hashCode * 13;

   String toString() => 'StrongModeConstraint($cls)';
 }

 /// The [WorldBuilder] is an auxiliary class used in the process of computing
 /// the [JClosedWorld].
 // TODO(johnniwinther): Move common implementation to a [WorldBuilderBase] when
 // universes and worlds have been unified.
 abstract class WorldBuilder {
   /// All directly instantiated classes, that is, classes with a generative
   /// constructor that has been called directly and not only through a
   /// super-call.
   // TODO(johnniwinther): Improve semantic precision.
   Iterable<ClassEntity> get directlyInstantiatedClasses;

   /// All types that are checked either through is, as or checked mode checks.
   Iterable<DartType> get isChecks;

   /// All directly instantiated types, that is, the types of the directly
   /// instantiated classes.
   // TODO(johnniwinther): Improve semantic precision.
   Iterable<InterfaceType> get instantiatedTypes;

   // TODO(johnniwinther): Clean up these getters.
   /// Methods in instantiated classes that are potentially closurized.
   Iterable<FunctionEntity> get closurizedMembers;

   /// Static or top level methods that are closurized.
   Iterable<FunctionEntity> get closurizedStatics;

   /// Live generic instance methods.
   Iterable<FunctionEntity> get genericInstanceMethods;

   /// Live generic local functions.
   Iterable<Local> get genericLocalFunctions;

   /// Live generic methods.
   Iterable<FunctionEntity> get genericMethods;

   /// Live user-defined 'noSuchMethod' implementations.
   Iterable<FunctionEntity> get userNoSuchMethods;

   /// Type variables used as type literals.
   Iterable<TypeVariableType> get typeVariableTypeLiterals;

   /// Call [f] for each generic [function] with the type arguments passed
   /// through static calls to [function].
   void forEachStaticTypeArgument(
       void f(Entity function, Set<DartType> typeArguments));

   /// Call [f] for each generic [selector] with the type arguments passed
   /// through dynamic calls to [selector].
   void forEachDynamicTypeArgument(
       void f(Selector selector, Set<DartType> typeArguments));
 }

 abstract class WorldBuilderBase {
   final Map<Entity, Set<DartType>> _staticTypeArgumentDependencies =
       <Entity, Set<DartType>>{};

   final Map<Selector, Set<DartType>> _dynamicTypeArgumentDependencies =
       <Selector, Set<DartType>>{};

   /// Set of methods in instantiated classes that are potentially closurized.
   final Set<FunctionEntity> closurizedMembers = new Set<FunctionEntity>();

   /// Set of static or top level methods that are closurized.
   final Set<FunctionEntity> closurizedStatics = new Set<FunctionEntity>();

   final Set<TypeVariableType> typeVariableTypeLiterals =
       new Set<TypeVariableType>();

   void _registerStaticTypeArgumentDependency(
       Entity element, List<DartType> typeArguments) {
     _staticTypeArgumentDependencies.putIfAbsent(
         element, () => new Set<DartType>())
       ..addAll(typeArguments);
   }

   void _registerDynamicTypeArgumentDependency(
       Selector selector, List<DartType> typeArguments) {
     _dynamicTypeArgumentDependencies.putIfAbsent(
         selector, () => new Set<DartType>())
       ..addAll(typeArguments);
   }

   void registerStaticInvocation(StaticUse staticUse) {
     if (staticUse.typeArguments == null || staticUse.typeArguments.isEmpty) {
       return;
     }
     _registerStaticTypeArgumentDependency(
         staticUse.element, staticUse.typeArguments);
   }

   void registerDynamicInvocation(
       Selector selector, List<DartType> typeArguments) {
     if (typeArguments.isEmpty) return;
     _registerDynamicTypeArgumentDependency(selector, typeArguments);
   }

   void forEachStaticTypeArgument(
       void f(Entity function, Set<DartType> typeArguments)) {
     _staticTypeArgumentDependencies.forEach(f);
   }

   void forEachDynamicTypeArgument(
       void f(Selector selector, Set<DartType> typeArguments)) {
     _dynamicTypeArgumentDependencies.forEach(f);
   }

   void registerTypeVariableTypeLiteral(TypeVariableType typeVariable) {
     typeVariableTypeLiterals.add(typeVariable);
   }
 }
	// 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 world_builder;

	import 'dart:collection';

	import '../common.dart';
	import '../common/names.dart' show Identifiers, Names;
	import '../common_elements.dart';
	import '../constants/values.dart';
	import '../elements/entities.dart';
	import '../elements/types.dart';
	import '../js_backend/allocator_analysis.dart' show KAllocatorAnalysis;
	import '../js_backend/backend_usage.dart' show BackendUsageBuilder;
	import '../js_backend/interceptor_data.dart' show InterceptorDataBuilder;
	import '../js_backend/native_data.dart' show NativeBasicData, NativeDataBuilder;
	import '../js_backend/no_such_method_registry.dart';
	import '../js_backend/runtime_types.dart';
	import '../js_model/locals.dart';
	import '../js_model/elements.dart' show JSignatureMethod;
	import '../kernel/element_map_impl.dart';
	import '../kernel/kelements.dart';
	import '../native/enqueue.dart' show NativeResolutionEnqueuer;
	import '../options.dart';
	import '../universe/class_set.dart';
	import '../util/enumset.dart';
	import '../util/util.dart';
	import '../world.dart' show World, JClosedWorld, KClosedWorld, OpenWorld;
	import 'class_hierarchy_builder.dart' show ClassHierarchyBuilder, ClassQueries;
	import 'selector.dart' show Selector;
	import 'use.dart'
	show
	ConstantUse,
	ConstantUseKind,
	DynamicUse,
	DynamicUseKind,
	StaticUse,
	StaticUseKind;

	part 'codegen_world_builder.dart';
	part 'member_usage.dart';
	part 'resolution_world_builder.dart';

	/// The combined constraints on receivers all the dynamic call sites of the same
	/// selector.
	///
	/// For instance for these calls
	///
	/// class A {
	/// foo(a, b) {}
	/// }
	/// class B {
	/// foo(a, b) {}
	/// }
	/// class C {
	/// foo(a, b) {}
	/// }
	/// new A().foo(a, b);
	/// new B().foo(0, 42);
	///
	/// the selector constraints for dynamic calls to 'foo' with two positional
	/// arguments could be 'receiver of exact instance `A` or `B`'.
	abstract class SelectorConstraints {
	/// Returns `true` if [selector] applies to [element] under these constraints
	/// given the closed [world].
	///
	/// Consider for instance in this world:
	///
	/// class A {
	/// foo(a, b) {}
	/// }
	/// class B {
	/// foo(a, b) {}
	/// }
	/// new A().foo(a, b);
	///
	/// Ideally the selector constraints for calls `foo` with two positional
	/// arguments apply to `A.foo` but `B.foo`.
	bool applies(MemberEntity element, Selector selector, covariant World world);

	/// Returns `true` if at least one of the receivers matching these constraints
	/// in the closed [world] have no implementation matching [selector].
	///
	/// For instance for this code snippet
	///
	/// class A {}
	/// class B { foo() {} }
	/// m(b) => (b ? new A() : new B()).foo();
	///
	/// the potential receiver `new A()` has no implementation of `foo` and thus
	/// needs to handle the call through its `noSuchMethod` handler.
	bool needsNoSuchMethodHandling(Selector selector, covariant World world);
	}

	/// A mutable [SelectorConstraints] used in [WorldBuilder].
	abstract class UniverseSelectorConstraints extends SelectorConstraints {
	/// Adds [constraint] to these selector constraints. Return `true` if the set
	/// of potential receivers expanded due to the new constraint.
	bool addReceiverConstraint(covariant Object constraint);
	}

	/// Strategy for computing the constraints on potential receivers of dynamic
	/// call sites.
	abstract class SelectorConstraintsStrategy {
	/// Create a [UniverseSelectorConstraints] to represent the global receiver
	/// constraints for dynamic call sites with [selector].
	UniverseSelectorConstraints createSelectorConstraints(Selector selector);

	/// Returns `true` if [member] is a potential target of [dynamicUse].
	bool appliedUnnamed(DynamicUse dynamicUse, MemberEntity member, World world);
	}

	class OpenWorldStrategy implements SelectorConstraintsStrategy {
	const OpenWorldStrategy();

	OpenWorldConstraints createSelectorConstraints(Selector selector) {
	return new OpenWorldConstraints();
	}

	@override
	bool appliedUnnamed(DynamicUse dynamicUse, MemberEntity member, World world) {
	Selector selector = dynamicUse.selector;
	return selector.appliesUnnamed(member);
	}
	}

	class OpenWorldConstraints extends UniverseSelectorConstraints {
	bool isAll = false;

	@override
	bool applies(MemberEntity element, Selector selector, World world) => isAll;

	@override
	bool needsNoSuchMethodHandling(Selector selector, World world) => isAll;

	@override
	bool addReceiverConstraint(Object constraint) {
	if (isAll) return false;
	isAll = true;
	return true;
	}

	String toString() {
	if (isAll) {
	return '<all>';
	} else {
	return '<none>';
	}
	}
	}

	bool useStrongModeWorldStrategy = false;

	/// Open world strategy that constrains instance member access to subtypes of
	/// the static type of the receiver.
	///
	/// This strategy is used for Dart 2.
	class StrongModeWorldStrategy implements SelectorConstraintsStrategy {
	const StrongModeWorldStrategy();

	StrongModeWorldConstraints createSelectorConstraints(Selector selector) {
	return new StrongModeWorldConstraints();
	}

	@override
	bool appliedUnnamed(
	DynamicUse dynamicUse, MemberEntity member, covariant OpenWorld world) {
	Selector selector = dynamicUse.selector;
	StrongModeConstraint constraint = dynamicUse.receiverConstraint;
	return selector.appliesUnnamed(member) &&
	(constraint == null \|\| constraint.canHit(member, selector, world));
	}
	}

	class StrongModeWorldConstraints extends UniverseSelectorConstraints {
	bool isAll = false;
	Set<StrongModeConstraint> _constraints;

	@override
	bool applies(MemberEntity element, Selector selector, World world) {
	if (isAll) return true;
	if (_constraints == null) return false;
	for (StrongModeConstraint constraint in _constraints) {
	if (constraint.canHit(element, selector, world)) {
	return true;
	}
	}
	return false;
	}

	@override
	bool needsNoSuchMethodHandling(Selector selector, World world) {
	if (isAll) {
	return true;
	}
	if (_constraints != null) {
	for (StrongModeConstraint constraint in _constraints) {
	if (constraint.needsNoSuchMethodHandling(selector, world)) {
	return true;
	}
	}
	}
	return false;
	}

	@override
	bool addReceiverConstraint(StrongModeConstraint constraint) {
	if (isAll) return false;
	if (constraint?.cls == null) {
	isAll = true;
	_constraints = null;
	return true;
	}
	_constraints ??= new Set<StrongModeConstraint>();
	return _constraints.add(constraint);
	}

	String toString() {
	if (isAll) {
	return '<all>';
	} else if (_constraints != null) {
	return '<${_constraints.map((c) => c.cls).join(',')}>';
	} else {
	return '<none>';
	}
	}
	}

	class StrongModeConstraint {
	final ClassEntity cls;

	const StrongModeConstraint(this.cls);

	bool needsNoSuchMethodHandling(Selector selector, World world) => true;

	bool canHit(MemberEntity element, Selector selector, OpenWorld world) {
	return world.isInheritedInSubtypeOf(element, cls);
	}

	bool operator ==(other) {
	if (identical(this, other)) return true;
	if (other is! StrongModeConstraint) return false;
	return cls == other.cls;
	}

	int get hashCode => cls.hashCode * 13;

	String toString() => 'StrongModeConstraint($cls)';
	}

	/// The [WorldBuilder] is an auxiliary class used in the process of computing
	/// the [JClosedWorld].
	// TODO(johnniwinther): Move common implementation to a [WorldBuilderBase] when
	// universes and worlds have been unified.
	abstract class WorldBuilder {
	/// All directly instantiated classes, that is, classes with a generative
	/// constructor that has been called directly and not only through a
	/// super-call.
	// TODO(johnniwinther): Improve semantic precision.
	Iterable<ClassEntity> get directlyInstantiatedClasses;

	/// All types that are checked either through is, as or checked mode checks.
	Iterable<DartType> get isChecks;

	/// All directly instantiated types, that is, the types of the directly
	/// instantiated classes.
	// TODO(johnniwinther): Improve semantic precision.
	Iterable<InterfaceType> get instantiatedTypes;

	// TODO(johnniwinther): Clean up these getters.
	/// Methods in instantiated classes that are potentially closurized.
	Iterable<FunctionEntity> get closurizedMembers;

	/// Static or top level methods that are closurized.
	Iterable<FunctionEntity> get closurizedStatics;

	/// Live generic instance methods.
	Iterable<FunctionEntity> get genericInstanceMethods;

	/// Live generic local functions.
	Iterable<Local> get genericLocalFunctions;

	/// Live generic methods.
	Iterable<FunctionEntity> get genericMethods;

	/// Live user-defined 'noSuchMethod' implementations.
	Iterable<FunctionEntity> get userNoSuchMethods;

	/// Type variables used as type literals.
	Iterable<TypeVariableType> get typeVariableTypeLiterals;

	/// Call [f] for each generic [function] with the type arguments passed
	/// through static calls to [function].
	void forEachStaticTypeArgument(
	void f(Entity function, Set<DartType> typeArguments));

	/// Call [f] for each generic [selector] with the type arguments passed
	/// through dynamic calls to [selector].
	void forEachDynamicTypeArgument(
	void f(Selector selector, Set<DartType> typeArguments));
	}

	abstract class WorldBuilderBase {
	final Map<Entity, Set<DartType>> _staticTypeArgumentDependencies =
	<Entity, Set<DartType>>{};

	final Map<Selector, Set<DartType>> _dynamicTypeArgumentDependencies =
	<Selector, Set<DartType>>{};

	/// Set of methods in instantiated classes that are potentially closurized.
	final Set<FunctionEntity> closurizedMembers = new Set<FunctionEntity>();

	/// Set of static or top level methods that are closurized.
	final Set<FunctionEntity> closurizedStatics = new Set<FunctionEntity>();

	final Set<TypeVariableType> typeVariableTypeLiterals =
	new Set<TypeVariableType>();

	void _registerStaticTypeArgumentDependency(
	Entity element, List<DartType> typeArguments) {
	_staticTypeArgumentDependencies.putIfAbsent(
	element, () => new Set<DartType>())
	..addAll(typeArguments);
	}

	void _registerDynamicTypeArgumentDependency(
	Selector selector, List<DartType> typeArguments) {
	_dynamicTypeArgumentDependencies.putIfAbsent(
	selector, () => new Set<DartType>())
	..addAll(typeArguments);
	}

	void registerStaticInvocation(StaticUse staticUse) {
	if (staticUse.typeArguments == null \|\| staticUse.typeArguments.isEmpty) {
	return;
	}
	_registerStaticTypeArgumentDependency(
	staticUse.element, staticUse.typeArguments);
	}

	void registerDynamicInvocation(
	Selector selector, List<DartType> typeArguments) {
	if (typeArguments.isEmpty) return;
	_registerDynamicTypeArgumentDependency(selector, typeArguments);
	}

	void forEachStaticTypeArgument(
	void f(Entity function, Set<DartType> typeArguments)) {
	_staticTypeArgumentDependencies.forEach(f);
	}

	void forEachDynamicTypeArgument(
	void f(Selector selector, Set<DartType> typeArguments)) {
	_dynamicTypeArgumentDependencies.forEach(f);
	}

	void registerTypeVariableTypeLiteral(TypeVariableType typeVariable) {
	typeVariableTypeLiterals.add(typeVariable);
	}
	}