pkg/dev_compiler/lib/src/kernel/property_model.dart - sdk - Git at Google

 // 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:collection' show HashMap, HashSet, Queue;

 import 'package:kernel/core_types.dart';
 import 'package:kernel/kernel.dart';
 import 'package:kernel/type_environment.dart';
 import '../compiler/js_names.dart' as JS;
 import '../js_ast/js_ast.dart' as JS;
 import 'kernel_helpers.dart';
 import 'native_types.dart';

 /// Dart allows all fields to be overridden.
 ///
 /// To prevent a performance/code size penalty for allowing this, we analyze
 /// private classes within each library that is being compiled to determine
 /// if those fields should be virtual or not. In effect, we devirtualize fields
 /// when possible by analyzing the class hierarchy and using knowledge of
 /// which members are private and thus, could not be overridden outside of the
 /// current library.
 class VirtualFieldModel {
   final _modelForLibrary = HashMap<Library, _LibraryVirtualFieldModel>();

   _LibraryVirtualFieldModel _getModel(Library library) => _modelForLibrary
       .putIfAbsent(library, () => _LibraryVirtualFieldModel.build(library));

   /// Returns true if a field is virtual.
   bool isVirtual(Field field) =>
       _getModel(field.enclosingLibrary).isVirtual(field);
 }

 /// This is a building block of [VirtualFieldModel], used to track information
 /// about a single library that has been analyzed.
 class _LibraryVirtualFieldModel {
   /// Fields that are private (or public fields of a private class) and
   /// overridden in this library.
   ///
   /// This means we must generate them as virtual fields using a property pair
   /// in JavaScript.
   final _overriddenPrivateFields = HashSet<Field>();

   /// Private classes that can be extended outside of this library.
   ///
   /// Normally private classes cannot be accessed outside this library, however,
   /// this can happen if they are extended by a public class, for example:
   ///
   ///     class _A { int x = 42; }
   ///     class _B { int x = 42; }
   ///
   ///     // _A is now effectively public for the purpose of overrides.
   ///     class C extends _A {}
   ///
   /// The class _A must treat is "x" as virtual, however _B does not.
   final _extensiblePrivateClasses = HashSet<Class>();

   _LibraryVirtualFieldModel.build(Library library) {
     var allClasses = library.classes;

     // The set of public types is our initial extensible type set.
     // From there, visit all immediate private types in this library, and so on
     // from those private types, marking them as extensible.
     var classesToVisit =
         Queue<Class>.from(allClasses.where((c) => !c.name.startsWith('_')));
     while (classesToVisit.isNotEmpty) {
       var c = classesToVisit.removeFirst();

       // For each supertype of a public type in this library,
       // if we encounter a private class, we mark it as being extended, and
       // add it to our work set if this is the first time we've visited it.
       for (var superclass in getImmediateSuperclasses(c)) {
         if (superclass.name.startsWith('_') &&
             superclass.enclosingLibrary == library) {
           if (_extensiblePrivateClasses.add(superclass)) {
             classesToVisit.add(superclass);
           }
         }
       }
     }

     // Class can only look up inherited members with an O(N) scan through
     // the class, so we build up a mapping of all fields in the library ahead of
     // time.
     Map<String, Field> getInstanceFieldMap(Class c) {
       var instanceFields = c.fields.where((f) => !f.isStatic);
       return HashMap.fromIterables(
           instanceFields.map((f) => f.name.name), instanceFields);
     }

     var allFields =
         HashMap.fromIterables(allClasses, allClasses.map(getInstanceFieldMap));

     for (var class_ in allClasses) {
       Set<Class> superclasses;

       // Visit accessors in the current class, and see if they override an
       // otherwise private field.
       for (var member in class_.members) {
         // Ignore abstract/static accessors, methods, constructors.
         if (member.isAbstract ||
             member is Procedure && (!member.isAccessor || member.isStatic) ||
             member is Constructor) {
           continue;
         }
         assert(member is Field || member is Procedure && member.isAccessor);

         // Ignore public accessors in extensible classes.
         if (!member.name.isPrivate &&
             (!class_.name.startsWith('_') ||
                 _extensiblePrivateClasses.contains(class_))) {
           continue;
         }

         if (superclasses == null) {
           superclasses = Set();
           void collectSupertypes(Class c) {
             if (!superclasses.add(c)) return;
             var s = c.superclass;
             if (s != null) collectSupertypes(s);
             var m = c.mixedInClass;
             if (m != null) collectSupertypes(m);
           }

           collectSupertypes(class_);
           superclasses.remove(class_);
           superclasses.removeWhere((s) => s.enclosingLibrary != library);
         }

         // Look in all super classes to see if we're overriding a field in our
         // library, if so mark that field as overridden.
         var name = member.name.name;
         _overriddenPrivateFields.addAll(superclasses
             .map((c) => allFields[c][name])
             .where((f) => f != null));
       }
     }
   }

   /// Returns true if a field inside this library is virtual.
   bool isVirtual(Field field) {
     // If the field was marked non-virtual, we know for sure.
     if (field.isStatic) return false;

     var class_ = field.enclosingClass;
     if (class_.isEnum) {
       // Enums are not extensible.
       return false;
     }
     var libraryUri = class_.enclosingLibrary.importUri;
     if (libraryUri.scheme == 'dart' && libraryUri.path.startsWith('_')) {
       // There should be no extensible fields in private SDK libraries.
       return false;
     }

     if (!field.name.isPrivate) {
       // Public fields in public classes (or extensible private classes)
       // are always virtual.
       // They could be overridden by someone using our library.
       if (!class_.name.startsWith('_')) return true;
       if (_extensiblePrivateClasses.contains(class_)) return true;
     }

     // Otherwise, the field is effectively private and we only need to make it
     // virtual if it's overridden.
     return _overriddenPrivateFields.contains(field);
   }
 }

 /// Tracks how fields, getters and setters are represented when emitting JS.
 ///
 /// Dart classes have implicit features that must be made explicit:
 ///
 /// - virtual fields induce a getter and setter pair.
 /// - getters and setters are independent.
 /// - getters and setters can be overridden.
 ///
 class ClassPropertyModel {
   final NativeTypeSet extensionTypes;
   final TypeEnvironment types;

   /// Fields that are virtual, that is, they must be generated as a property
   /// pair in JavaScript.
   ///
   /// The value property stores the symbol used for the field's storage slot.
   final virtualFields = <Field, JS.TemporaryId>{};

   /// The set of inherited getters, used because JS getters/setters are paired,
   /// so if we're generating a setter we may need to emit a getter that calls
   /// super.
   final inheritedGetters = HashSet<String>();

   /// The set of inherited setters, used because JS getters/setters are paired,
   /// so if we're generating a getter we may need to emit a setter that calls
   /// super.
   final inheritedSetters = HashSet<String>();

   final extensionMethods = Set<String>();

   final extensionAccessors = Set<String>();

   ClassPropertyModel.build(this.types, this.extensionTypes,
       VirtualFieldModel fieldModel, Class class_) {
     // Visit superclasses to collect information about their fields/accessors.
     // This is expensive so we try to collect everything in one pass.
     for (var base in getSuperclasses(class_)) {
       for (var member in base.members) {
         if (member is Constructor ||
             member is Procedure && (!member.isAccessor || member.isStatic)) {
           continue;
         }

         // Ignore private names from other libraries.
         if (member.name.isPrivate &&
             member.enclosingLibrary != class_.enclosingLibrary) {
           continue;
         }

         var name = member.name.name;
         if (member is Field) {
           inheritedGetters.add(name);
           if (!member.isFinal) inheritedSetters.add(name);
         } else {
           var accessor = member as Procedure;
           assert(accessor.isAccessor);
           (accessor.isGetter ? inheritedGetters : inheritedSetters).add(name);
         }
       }
     }

     _collectExtensionMembers(class_);

     var virtualAccessorNames = HashSet<String>()
       ..addAll(inheritedGetters)
       ..addAll(inheritedSetters)
       ..addAll(extensionAccessors);

     // Visit accessors in the current class, and see if they need to be
     // generated differently based on the inherited fields/accessors.
     for (var field in class_.fields) {
       // Also ignore abstract fields.
       if (field.isAbstract || field.isStatic) continue;

       var name = field.name.name;
       if (virtualAccessorNames.contains(name) ||
           fieldModel.isVirtual(field) ||
           field.isCovariant ||
           field.isGenericCovariantImpl) {
         virtualFields[field] = JS.TemporaryId(name);
       }
     }
   }

   CoreTypes get coreTypes => extensionTypes.coreTypes;

   void _collectExtensionMembers(Class class_) {
     if (extensionTypes.isNativeClass(class_)) return;

     // Find all generic interfaces that could be used to call into members of
     // this class. This will help us identify which parameters need checks
     // for soundness.
     var allNatives = HashSet<String>();
     _collectNativeMembers(class_, allNatives);
     if (allNatives.isEmpty) return;

     // For members on this class, check them against all generic interfaces.
     var seenConcreteMembers = HashSet<String>();
     _findExtensionMembers(class_, seenConcreteMembers, allNatives);

     // For members of the superclass, we may need to add checks because this
     // class adds a new unsafe interface. Collect those checks.
     var visited = HashSet<Class>()..add(class_);
     var existingMembers = HashSet<String>();

     void visitImmediateSuper(Class c) {
       // For members of mixins/supertypes, check them against new interfaces,
       // and also record any existing checks they already had.
       var oldCovariant = HashSet<String>();
       _collectNativeMembers(c, oldCovariant);
       var newCovariant = allNatives.difference(oldCovariant);
       if (newCovariant.isEmpty) return;

       existingMembers.addAll(oldCovariant);

       void visitSuper(Class c) {
         if (visited.add(c)) {
           _findExtensionMembers(c, seenConcreteMembers, newCovariant);
           var m = c.mixedInClass;
           if (m != null) visitSuper(m);
           var s = c.superclass;
           if (s != null) visitSuper(s);
         }
       }

       visitSuper(c);
     }

     if (class_.superclass != null) {
       var mixins = <Class>[];
       var superclass = getSuperclassAndMixins(class_, mixins);
       mixins.forEach(visitImmediateSuper);
       visitImmediateSuper(superclass);
     }
   }

   /// Searches all concrete instance members declared on this type, skipping
   /// already [seenConcreteMembers], and adds them to [extensionMembers] if
   /// needed.
   ///
   /// By tracking the set of seen members, we can visit superclasses and mixins
   /// and ultimately collect every most-derived member exposed by a given type.
   void _findExtensionMembers(
       Class c, HashSet<String> seenConcreteMembers, Set<String> allNatives) {
     // We only visit each most derived concrete member.
     // To avoid visiting an overridden superclass member, we skip members
     // we've seen, and visit starting from the class, then mixins in
     // reverse order, then superclasses.
     for (var m in c.members) {
       var name = m.name.name;
       if (m.isAbstract || m is Constructor) continue;
       if (m is Procedure) {
         if (m.isStatic) continue;
         if (seenConcreteMembers.add(name) && allNatives.contains(name)) {
           (m.isAccessor ? extensionAccessors : extensionMethods).add(name);
         }
       } else if (m is Field) {
         if (m.isStatic) continue;
         if (seenConcreteMembers.add(name) && allNatives.contains(name)) {
           extensionAccessors.add(name);
         }
       }
     }
   }

   /// Collects all supertypes that may themselves contain native subtypes,
   /// excluding [Object], for example `List` is implemented by several native
   /// types.
   void _collectNativeMembers(Class c, Set<String> members) {
     if (extensionTypes.hasNativeSubtype(c)) {
       for (var m in c.members) {
         if (!m.name.isPrivate &&
             (m is Procedure && !m.isStatic || m is Field && !m.isStatic)) {
           members.add(m.name.name);
         }
       }
     }
     var m = c.mixedInClass;
     if (m != null) _collectNativeMembers(m, members);
     for (var i in c.implementedTypes) {
       _collectNativeMembers(i.classNode, members);
     }
     var s = c.superclass;
     if (s != null) _collectNativeMembers(s, members);
   }
 }
	// 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:collection' show HashMap, HashSet, Queue;

	import 'package:kernel/core_types.dart';
	import 'package:kernel/kernel.dart';
	import 'package:kernel/type_environment.dart';
	import '../compiler/js_names.dart' as JS;
	import '../js_ast/js_ast.dart' as JS;
	import 'kernel_helpers.dart';
	import 'native_types.dart';

	/// Dart allows all fields to be overridden.
	///
	/// To prevent a performance/code size penalty for allowing this, we analyze
	/// private classes within each library that is being compiled to determine
	/// if those fields should be virtual or not. In effect, we devirtualize fields
	/// when possible by analyzing the class hierarchy and using knowledge of
	/// which members are private and thus, could not be overridden outside of the
	/// current library.
	class VirtualFieldModel {
	final _modelForLibrary = HashMap<Library, _LibraryVirtualFieldModel>();

	_LibraryVirtualFieldModel _getModel(Library library) => _modelForLibrary
	.putIfAbsent(library, () => _LibraryVirtualFieldModel.build(library));

	/// Returns true if a field is virtual.
	bool isVirtual(Field field) =>
	_getModel(field.enclosingLibrary).isVirtual(field);
	}

	/// This is a building block of [VirtualFieldModel], used to track information
	/// about a single library that has been analyzed.
	class _LibraryVirtualFieldModel {
	/// Fields that are private (or public fields of a private class) and
	/// overridden in this library.
	///
	/// This means we must generate them as virtual fields using a property pair
	/// in JavaScript.
	final _overriddenPrivateFields = HashSet<Field>();

	/// Private classes that can be extended outside of this library.
	///
	/// Normally private classes cannot be accessed outside this library, however,
	/// this can happen if they are extended by a public class, for example:
	///
	/// class _A { int x = 42; }
	/// class _B { int x = 42; }
	///
	/// // _A is now effectively public for the purpose of overrides.
	/// class C extends _A {}
	///
	/// The class _A must treat is "x" as virtual, however _B does not.
	final _extensiblePrivateClasses = HashSet<Class>();

	_LibraryVirtualFieldModel.build(Library library) {
	var allClasses = library.classes;

	// The set of public types is our initial extensible type set.
	// From there, visit all immediate private types in this library, and so on
	// from those private types, marking them as extensible.
	var classesToVisit =
	Queue<Class>.from(allClasses.where((c) => !c.name.startsWith('_')));
	while (classesToVisit.isNotEmpty) {
	var c = classesToVisit.removeFirst();

	// For each supertype of a public type in this library,
	// if we encounter a private class, we mark it as being extended, and
	// add it to our work set if this is the first time we've visited it.
	for (var superclass in getImmediateSuperclasses(c)) {
	if (superclass.name.startsWith('_') &&
	superclass.enclosingLibrary == library) {
	if (_extensiblePrivateClasses.add(superclass)) {
	classesToVisit.add(superclass);
	}
	}
	}
	}

	// Class can only look up inherited members with an O(N) scan through
	// the class, so we build up a mapping of all fields in the library ahead of
	// time.
	Map<String, Field> getInstanceFieldMap(Class c) {
	var instanceFields = c.fields.where((f) => !f.isStatic);
	return HashMap.fromIterables(
	instanceFields.map((f) => f.name.name), instanceFields);
	}

	var allFields =
	HashMap.fromIterables(allClasses, allClasses.map(getInstanceFieldMap));

	for (var class_ in allClasses) {
	Set<Class> superclasses;

	// Visit accessors in the current class, and see if they override an
	// otherwise private field.
	for (var member in class_.members) {
	// Ignore abstract/static accessors, methods, constructors.
	if (member.isAbstract \|\|
	member is Procedure && (!member.isAccessor \|\| member.isStatic) \|\|
	member is Constructor) {
	continue;
	}
	assert(member is Field \|\| member is Procedure && member.isAccessor);

	// Ignore public accessors in extensible classes.
	if (!member.name.isPrivate &&
	(!class_.name.startsWith('_') \|\|
	_extensiblePrivateClasses.contains(class_))) {
	continue;
	}

	if (superclasses == null) {
	superclasses = Set();
	void collectSupertypes(Class c) {
	if (!superclasses.add(c)) return;
	var s = c.superclass;
	if (s != null) collectSupertypes(s);
	var m = c.mixedInClass;
	if (m != null) collectSupertypes(m);
	}

	collectSupertypes(class_);
	superclasses.remove(class_);
	superclasses.removeWhere((s) => s.enclosingLibrary != library);
	}

	// Look in all super classes to see if we're overriding a field in our
	// library, if so mark that field as overridden.
	var name = member.name.name;
	_overriddenPrivateFields.addAll(superclasses
	.map((c) => allFields[c][name])
	.where((f) => f != null));
	}
	}
	}

	/// Returns true if a field inside this library is virtual.
	bool isVirtual(Field field) {
	// If the field was marked non-virtual, we know for sure.
	if (field.isStatic) return false;

	var class_ = field.enclosingClass;
	if (class_.isEnum) {
	// Enums are not extensible.
	return false;
	}
	var libraryUri = class_.enclosingLibrary.importUri;
	if (libraryUri.scheme == 'dart' && libraryUri.path.startsWith('_')) {
	// There should be no extensible fields in private SDK libraries.
	return false;
	}

	if (!field.name.isPrivate) {
	// Public fields in public classes (or extensible private classes)
	// are always virtual.
	// They could be overridden by someone using our library.
	if (!class_.name.startsWith('_')) return true;
	if (_extensiblePrivateClasses.contains(class_)) return true;
	}

	// Otherwise, the field is effectively private and we only need to make it
	// virtual if it's overridden.
	return _overriddenPrivateFields.contains(field);
	}
	}

	/// Tracks how fields, getters and setters are represented when emitting JS.
	///
	/// Dart classes have implicit features that must be made explicit:
	///
	/// - virtual fields induce a getter and setter pair.
	/// - getters and setters are independent.
	/// - getters and setters can be overridden.
	///
	class ClassPropertyModel {
	final NativeTypeSet extensionTypes;
	final TypeEnvironment types;

	/// Fields that are virtual, that is, they must be generated as a property
	/// pair in JavaScript.
	///
	/// The value property stores the symbol used for the field's storage slot.
	final virtualFields = <Field, JS.TemporaryId>{};

	/// The set of inherited getters, used because JS getters/setters are paired,
	/// so if we're generating a setter we may need to emit a getter that calls
	/// super.
	final inheritedGetters = HashSet<String>();

	/// The set of inherited setters, used because JS getters/setters are paired,
	/// so if we're generating a getter we may need to emit a setter that calls
	/// super.
	final inheritedSetters = HashSet<String>();

	final extensionMethods = Set<String>();

	final extensionAccessors = Set<String>();

	ClassPropertyModel.build(this.types, this.extensionTypes,
	VirtualFieldModel fieldModel, Class class_) {
	// Visit superclasses to collect information about their fields/accessors.
	// This is expensive so we try to collect everything in one pass.
	for (var base in getSuperclasses(class_)) {
	for (var member in base.members) {
	if (member is Constructor \|\|
	member is Procedure && (!member.isAccessor \|\| member.isStatic)) {
	continue;
	}

	// Ignore private names from other libraries.
	if (member.name.isPrivate &&
	member.enclosingLibrary != class_.enclosingLibrary) {
	continue;
	}

	var name = member.name.name;
	if (member is Field) {
	inheritedGetters.add(name);
	if (!member.isFinal) inheritedSetters.add(name);
	} else {
	var accessor = member as Procedure;
	assert(accessor.isAccessor);
	(accessor.isGetter ? inheritedGetters : inheritedSetters).add(name);
	}
	}
	}

	_collectExtensionMembers(class_);

	var virtualAccessorNames = HashSet<String>()
	..addAll(inheritedGetters)
	..addAll(inheritedSetters)
	..addAll(extensionAccessors);

	// Visit accessors in the current class, and see if they need to be
	// generated differently based on the inherited fields/accessors.
	for (var field in class_.fields) {
	// Also ignore abstract fields.
	if (field.isAbstract \|\| field.isStatic) continue;

	var name = field.name.name;
	if (virtualAccessorNames.contains(name) \|\|
	fieldModel.isVirtual(field) \|\|
	field.isCovariant \|\|
	field.isGenericCovariantImpl) {
	virtualFields[field] = JS.TemporaryId(name);
	}
	}
	}

	CoreTypes get coreTypes => extensionTypes.coreTypes;

	void _collectExtensionMembers(Class class_) {
	if (extensionTypes.isNativeClass(class_)) return;

	// Find all generic interfaces that could be used to call into members of
	// this class. This will help us identify which parameters need checks
	// for soundness.
	var allNatives = HashSet<String>();
	_collectNativeMembers(class_, allNatives);
	if (allNatives.isEmpty) return;

	// For members on this class, check them against all generic interfaces.
	var seenConcreteMembers = HashSet<String>();
	_findExtensionMembers(class_, seenConcreteMembers, allNatives);

	// For members of the superclass, we may need to add checks because this
	// class adds a new unsafe interface. Collect those checks.
	var visited = HashSet<Class>()..add(class_);
	var existingMembers = HashSet<String>();

	void visitImmediateSuper(Class c) {
	// For members of mixins/supertypes, check them against new interfaces,
	// and also record any existing checks they already had.
	var oldCovariant = HashSet<String>();
	_collectNativeMembers(c, oldCovariant);
	var newCovariant = allNatives.difference(oldCovariant);
	if (newCovariant.isEmpty) return;

	existingMembers.addAll(oldCovariant);

	void visitSuper(Class c) {
	if (visited.add(c)) {
	_findExtensionMembers(c, seenConcreteMembers, newCovariant);
	var m = c.mixedInClass;
	if (m != null) visitSuper(m);
	var s = c.superclass;
	if (s != null) visitSuper(s);
	}
	}

	visitSuper(c);
	}

	if (class_.superclass != null) {
	var mixins = <Class>[];
	var superclass = getSuperclassAndMixins(class_, mixins);
	mixins.forEach(visitImmediateSuper);
	visitImmediateSuper(superclass);
	}
	}

	/// Searches all concrete instance members declared on this type, skipping
	/// already [seenConcreteMembers], and adds them to [extensionMembers] if
	/// needed.
	///
	/// By tracking the set of seen members, we can visit superclasses and mixins
	/// and ultimately collect every most-derived member exposed by a given type.
	void _findExtensionMembers(
	Class c, HashSet<String> seenConcreteMembers, Set<String> allNatives) {
	// We only visit each most derived concrete member.
	// To avoid visiting an overridden superclass member, we skip members
	// we've seen, and visit starting from the class, then mixins in
	// reverse order, then superclasses.
	for (var m in c.members) {
	var name = m.name.name;
	if (m.isAbstract \|\| m is Constructor) continue;
	if (m is Procedure) {
	if (m.isStatic) continue;
	if (seenConcreteMembers.add(name) && allNatives.contains(name)) {
	(m.isAccessor ? extensionAccessors : extensionMethods).add(name);
	}
	} else if (m is Field) {
	if (m.isStatic) continue;
	if (seenConcreteMembers.add(name) && allNatives.contains(name)) {
	extensionAccessors.add(name);
	}
	}
	}
	}

	/// Collects all supertypes that may themselves contain native subtypes,
	/// excluding [Object], for example `List` is implemented by several native
	/// types.
	void _collectNativeMembers(Class c, Set<String> members) {
	if (extensionTypes.hasNativeSubtype(c)) {
	for (var m in c.members) {
	if (!m.name.isPrivate &&
	(m is Procedure && !m.isStatic \|\| m is Field && !m.isStatic)) {
	members.add(m.name.name);
	}
	}
	}
	var m = c.mixedInClass;
	if (m != null) _collectNativeMembers(m, members);
	for (var i in c.implementedTypes) {
	_collectNativeMembers(i.classNode, members);
	}
	var s = c.superclass;
	if (s != null) _collectNativeMembers(s, members);
	}
	}