| // Copyright (c) 2013, 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 simple_types_inferrer; |
| |
| import '../closure.dart' show ClosureClassMap, ClosureScope; |
| import '../dart_types.dart' |
| show DartType, InterfaceType, FunctionType, TypeKind; |
| import '../elements/elements.dart'; |
| import '../js_backend/js_backend.dart' as js; |
| import '../native_handler.dart' as native; |
| import '../tree/tree.dart' as ast; |
| import '../ir/ir_nodes.dart' as ir show Node; |
| import '../util/util.dart' show Link, Spannable, Setlet; |
| import '../types/types.dart' |
| show TypesInferrer, FlatTypeMask, TypeMask, ContainerTypeMask, |
| ElementTypeMask, ValueTypeMask, TypeSystem, MinimalInferrerEngine; |
| import 'inferrer_visitor.dart'; |
| |
| // BUG(8802): There's a bug in the analyzer that makes the re-export |
| // of Selector from dart2jslib.dart fail. For now, we work around that |
| // by importing universe.dart explicitly and disabling the re-export. |
| import '../dart2jslib.dart' hide Selector, TypedSelector; |
| import '../universe/universe.dart' show Selector, SideEffects, TypedSelector; |
| |
| /** |
| * An implementation of [TypeSystem] for [TypeMask]. |
| */ |
| class TypeMaskSystem implements TypeSystem<TypeMask> { |
| final Compiler compiler; |
| TypeMaskSystem(this.compiler); |
| |
| TypeMask narrowType(TypeMask type, |
| DartType annotation, |
| {bool isNullable: true}) { |
| if (annotation.treatAsDynamic) return type; |
| if (annotation.element == compiler.objectClass) return type; |
| TypeMask otherType; |
| if (annotation.isTypedef || annotation.isFunctionType) { |
| otherType = functionType; |
| } else if (annotation.isTypeVariable) { |
| // TODO(ngeoffray): Narrow to bound. |
| return type; |
| } else if (annotation.isVoid) { |
| otherType = nullType; |
| } else { |
| assert(annotation.isInterfaceType); |
| otherType = new TypeMask.nonNullSubtype(annotation.element); |
| } |
| if (isNullable) otherType = otherType.nullable(); |
| if (type == null) return otherType; |
| return type.intersection(otherType, compiler); |
| } |
| |
| TypeMask computeLUB(TypeMask firstType, TypeMask secondType) { |
| if (firstType == null) { |
| return secondType; |
| } else if (secondType == dynamicType || firstType == dynamicType) { |
| return dynamicType; |
| } else if (firstType == secondType) { |
| return firstType; |
| } else { |
| TypeMask union = firstType.union(secondType, compiler); |
| // TODO(kasperl): If the union isn't nullable it seems wasteful |
| // to use dynamic. Fix that. |
| return union.containsAll(compiler) ? dynamicType : union; |
| } |
| } |
| |
| TypeMask allocateDiamondPhi(TypeMask firstType, TypeMask secondType) { |
| return computeLUB(firstType, secondType); |
| } |
| |
| TypeMask get dynamicType => compiler.typesTask.dynamicType; |
| TypeMask get nullType => compiler.typesTask.nullType; |
| TypeMask get intType => compiler.typesTask.intType; |
| TypeMask get uint32Type => compiler.typesTask.uint32Type; |
| TypeMask get uint31Type => compiler.typesTask.uint31Type; |
| TypeMask get positiveIntType => compiler.typesTask.positiveIntType; |
| TypeMask get doubleType => compiler.typesTask.doubleType; |
| TypeMask get numType => compiler.typesTask.numType; |
| TypeMask get boolType => compiler.typesTask.boolType; |
| TypeMask get functionType => compiler.typesTask.functionType; |
| TypeMask get listType => compiler.typesTask.listType; |
| TypeMask get constListType => compiler.typesTask.constListType; |
| TypeMask get fixedListType => compiler.typesTask.fixedListType; |
| TypeMask get growableListType => compiler.typesTask.growableListType; |
| TypeMask get mapType => compiler.typesTask.mapType; |
| TypeMask get constMapType => compiler.typesTask.constMapType; |
| TypeMask get stringType => compiler.typesTask.stringType; |
| TypeMask get typeType => compiler.typesTask.typeType; |
| bool isNull(TypeMask mask) => mask.isEmpty && mask.isNullable; |
| |
| TypeMask stringLiteralType(ast.DartString value) => stringType; |
| |
| TypeMask nonNullSubtype(ClassElement type) |
| => new TypeMask.nonNullSubtype(type.declaration); |
| TypeMask nonNullSubclass(ClassElement type) |
| => new TypeMask.nonNullSubclass(type.declaration); |
| TypeMask nonNullExact(ClassElement type) |
| => new TypeMask.nonNullExact(type.declaration); |
| TypeMask nonNullEmpty() => new TypeMask.nonNullEmpty(); |
| |
| TypeMask allocateList(TypeMask type, |
| ast.Node node, |
| Element enclosing, |
| [TypeMask elementType, int length]) { |
| return new ContainerTypeMask(type, node, enclosing, elementType, length); |
| } |
| |
| TypeMask allocateMap(TypeMask type, ast.Node node, Element element, |
| [List<TypeMask> keys, List<TypeMask> values]) { |
| return type; |
| } |
| |
| TypeMask allocateClosure(ast.Node node, Element element) { |
| return functionType; |
| } |
| |
| Selector newTypedSelector(TypeMask receiver, Selector selector) { |
| return new TypedSelector(receiver, selector, compiler); |
| } |
| |
| TypeMask addPhiInput(Element element, TypeMask phiType, TypeMask newType) { |
| return computeLUB(phiType, newType); |
| } |
| |
| TypeMask allocatePhi(ast.Node node, Element element, TypeMask inputType) { |
| return inputType; |
| } |
| |
| TypeMask simplifyPhi(ast.Node node, Element element, TypeMask phiType) { |
| return phiType; |
| } |
| |
| TypeMask refineReceiver(Selector selector, TypeMask receiverType) { |
| TypeMask newType = compiler.world.allFunctions.receiverType(selector); |
| return receiverType.intersection(newType, compiler); |
| } |
| |
| TypeMask getConcreteTypeFor(TypeMask mask) => mask; |
| } |
| |
| /** |
| * Common super class used by [SimpleTypeInferrerVisitor] to propagate |
| * type information about visited nodes, as well as to request type |
| * information of elements. |
| */ |
| abstract class InferrerEngine<T, V extends TypeSystem> |
| implements MinimalInferrerEngine<T> { |
| final Compiler compiler; |
| final V types; |
| final Map<ast.Node, T> concreteTypes = new Map<ast.Node, T>(); |
| final Set<Element> generativeConstructorsExposingThis = new Set<Element>(); |
| |
| InferrerEngine(this.compiler, this.types); |
| |
| /** |
| * Records the default type of parameter [parameter]. |
| */ |
| void setDefaultTypeOfParameter(ParameterElement parameter, T type); |
| |
| /** |
| * Returns the type of [element]. |
| */ |
| T typeOfElement(Element element); |
| |
| /** |
| * Returns the return type of [element]. |
| */ |
| T returnTypeOfElement(Element element); |
| |
| /** |
| * Records that [node] sets final field [element] to be of type [type]. |
| * |
| * [nodeHolder] is the element holder of [node]. |
| */ |
| void recordTypeOfFinalField(ast.Node node, |
| Element nodeHolder, |
| Element field, |
| T type); |
| |
| /** |
| * Records that [node] sets non-final field [element] to be of type |
| * [type]. |
| */ |
| void recordTypeOfNonFinalField(Spannable node, Element field, T type); |
| |
| /** |
| * Records that [element] is of type [type]. |
| */ |
| void recordType(Element element, T type); |
| |
| /** |
| * Records that the return type [element] is of type [type]. |
| */ |
| void recordReturnType(Element element, T type); |
| |
| /** |
| * Registers that [caller] calls [callee] at location [node], with |
| * [selector], and [arguments]. Note that [selector] is null for |
| * forwarding constructors. |
| * |
| * [sideEffects] will be updated to incorporate [callee]'s side |
| * effects. |
| * |
| * [inLoop] tells whether the call happens in a loop. |
| */ |
| T registerCalledElement(Spannable node, |
| Selector selector, |
| Element caller, |
| Element callee, |
| ArgumentsTypes<T> arguments, |
| SideEffects sideEffects, |
| bool inLoop); |
| |
| /** |
| * Registers that [caller] calls [selector] with [receiverType] as |
| * receiver, and [arguments]. |
| * |
| * [sideEffects] will be updated to incorporate the potential |
| * callees' side effects. |
| * |
| * [inLoop] tells whether the call happens in a loop. |
| */ |
| T registerCalledSelector(ast.Node node, |
| Selector selector, |
| T receiverType, |
| Element caller, |
| ArgumentsTypes<T> arguments, |
| SideEffects sideEffects, |
| bool inLoop); |
| |
| /** |
| * Registers that [caller] calls [closure] with [arguments]. |
| * |
| * [sideEffects] will be updated to incorporate the potential |
| * callees' side effects. |
| * |
| * [inLoop] tells whether the call happens in a loop. |
| */ |
| T registerCalledClosure(ast.Node node, |
| Selector selector, |
| T closure, |
| Element caller, |
| ArgumentsTypes<T> arguments, |
| SideEffects sideEffects, |
| bool inLoop); |
| |
| /** |
| * Notifies to the inferrer that [analyzedElement] can have return |
| * type [newType]. [currentType] is the type the [InferrerVisitor] |
| * currently found. |
| * |
| * Returns the new type for [analyzedElement]. |
| */ |
| T addReturnTypeFor(Element analyzedElement, T currentType, T newType); |
| |
| /** |
| * Applies [f] to all elements in the universe that match |
| * [selector]. If [f] returns false, aborts the iteration. |
| */ |
| void forEachElementMatching(Selector selector, bool f(Element element)) { |
| Iterable<Element> elements = compiler.world.allFunctions.filter(selector); |
| for (Element e in elements) { |
| if (!f(e.implementation)) return; |
| } |
| } |
| |
| /** |
| * Update [sideEffects] with the side effects of [callee] being |
| * called with [selector]. |
| */ |
| void updateSideEffects(SideEffects sideEffects, |
| Selector selector, |
| Element callee) { |
| if (callee.isField) { |
| if (callee.isInstanceMember) { |
| if (selector.isSetter) { |
| sideEffects.setChangesInstanceProperty(); |
| } else if (selector.isGetter) { |
| sideEffects.setDependsOnInstancePropertyStore(); |
| } else { |
| sideEffects.setAllSideEffects(); |
| sideEffects.setDependsOnSomething(); |
| } |
| } else { |
| if (selector.isSetter) { |
| sideEffects.setChangesStaticProperty(); |
| } else if (selector.isGetter) { |
| sideEffects.setDependsOnStaticPropertyStore(); |
| } else { |
| sideEffects.setAllSideEffects(); |
| sideEffects.setDependsOnSomething(); |
| } |
| } |
| } else if (callee.isGetter && !selector.isGetter) { |
| sideEffects.setAllSideEffects(); |
| sideEffects.setDependsOnSomething(); |
| } else { |
| sideEffects.add(compiler.world.getSideEffectsOfElement(callee)); |
| } |
| } |
| |
| /** |
| * Returns the type for [nativeBehavior]. See documentation on |
| * [native.NativeBehavior]. |
| */ |
| T typeOfNativeBehavior(native.NativeBehavior nativeBehavior) { |
| if (nativeBehavior == null) return types.dynamicType; |
| List typesReturned = nativeBehavior.typesReturned; |
| if (typesReturned.isEmpty) return types.dynamicType; |
| T returnType; |
| for (var type in typesReturned) { |
| T mappedType; |
| if (type == native.SpecialType.JsObject) { |
| mappedType = types.nonNullExact(compiler.objectClass); |
| } else if (type.element == compiler.stringClass) { |
| mappedType = types.stringType; |
| } else if (type.element == compiler.intClass) { |
| mappedType = types.intType; |
| } else if (type.element == compiler.doubleClass) { |
| mappedType = types.doubleType; |
| } else if (type.element == compiler.numClass) { |
| mappedType = types.numType; |
| } else if (type.element == compiler.boolClass) { |
| mappedType = types.boolType; |
| } else if (type.element == compiler.nullClass) { |
| mappedType = types.nullType; |
| } else if (type.isVoid) { |
| mappedType = types.nullType; |
| } else if (type.isDynamic) { |
| return types.dynamicType; |
| } else if (!compiler.world.hasAnySubtype(type.element)) { |
| mappedType = types.nonNullExact(type.element); |
| } else { |
| ClassElement element = type.element; |
| Set<ClassElement> subtypes = compiler.world.subtypesOf(element); |
| Set<ClassElement> subclasses = compiler.world.subclassesOf(element); |
| if (subclasses != null && subtypes.length == subclasses.length) { |
| mappedType = types.nonNullSubclass(element); |
| } else { |
| mappedType = types.nonNullSubtype(element); |
| } |
| } |
| returnType = types.computeLUB(returnType, mappedType); |
| if (returnType == types.dynamicType) { |
| break; |
| } |
| } |
| return returnType; |
| } |
| |
| void updateSelectorInTree( |
| AstElement owner, Spannable node, Selector selector) { |
| if (node is ir.Node) { |
| // TODO(lry): update selector for IrInvokeDynamic. |
| throw "updateSelector for IR node $node"; |
| } |
| ast.Node astNode = node; |
| TreeElements elements = owner.resolvedAst.elements; |
| if (astNode.asSendSet() != null) { |
| if (selector.isSetter || selector.isIndexSet) { |
| elements.setSelector(node, selector); |
| } else if (selector.isGetter || selector.isIndex) { |
| elements.setGetterSelectorInComplexSendSet(node, selector); |
| } else { |
| assert(selector.isOperator); |
| elements.setOperatorSelectorInComplexSendSet(node, selector); |
| } |
| } else if (astNode.asSend() != null) { |
| elements.setSelector(node, selector); |
| } else { |
| assert(astNode.asForIn() != null); |
| if (selector.asUntyped == compiler.iteratorSelector) { |
| elements.setIteratorSelector(node, selector); |
| } else if (selector.asUntyped == compiler.currentSelector) { |
| elements.setCurrentSelector(node, selector); |
| } else { |
| assert(selector.asUntyped == compiler.moveNextSelector); |
| elements.setMoveNextSelector(node, selector); |
| } |
| } |
| } |
| |
| bool isNativeElement(Element element) { |
| if (element.isNative) return true; |
| return element.isMember |
| && element.enclosingClass.isNative |
| && element.isField; |
| } |
| |
| void analyze(Element element, ArgumentsTypes arguments); |
| |
| bool checkIfExposesThis(Element element) { |
| element = element.implementation; |
| return generativeConstructorsExposingThis.contains(element); |
| } |
| |
| void recordExposesThis(Element element, bool exposesThis) { |
| element = element.implementation; |
| if (exposesThis) { |
| generativeConstructorsExposingThis.add(element); |
| } |
| } |
| } |
| |
| class SimpleTypeInferrerVisitor<T> |
| extends InferrerVisitor<T, InferrerEngine<T, TypeSystem<T>>> { |
| T returnType; |
| bool visitingInitializers = false; |
| bool isConstructorRedirect = false; |
| bool seenSuperConstructorCall = false; |
| SideEffects sideEffects = new SideEffects.empty(); |
| final Element outermostElement; |
| final InferrerEngine<T, TypeSystem<T>> inferrer; |
| final Setlet<Element> capturedVariables = new Setlet<Element>(); |
| |
| SimpleTypeInferrerVisitor.internal(analyzedElement, |
| this.outermostElement, |
| inferrer, |
| compiler, |
| locals) |
| : super(analyzedElement, inferrer, inferrer.types, compiler, locals), |
| this.inferrer = inferrer { |
| assert(outermostElement != null); |
| } |
| |
| SimpleTypeInferrerVisitor(Element element, |
| Compiler compiler, |
| InferrerEngine<T, TypeSystem<T>> inferrer, |
| [LocalsHandler<T> handler]) |
| : this.internal(element, |
| element.outermostEnclosingMemberOrTopLevel.implementation, |
| inferrer, compiler, handler); |
| |
| void analyzeSuperConstructorCall(Element target, ArgumentsTypes arguments) { |
| inferrer.analyze(target, arguments); |
| isThisExposed = isThisExposed || inferrer.checkIfExposesThis(target); |
| } |
| |
| T run() { |
| var node = analyzedElement.node; |
| ast.Expression initializer; |
| if (analyzedElement.isField) { |
| VariableElement fieldElement = analyzedElement; |
| initializer = fieldElement.initializer; |
| if (initializer == null) { |
| // Eagerly bailout, because computing the closure data only |
| // works for functions and field assignments. |
| return types.nullType; |
| } |
| } |
| // Update the locals that are boxed in [locals]. These locals will |
| // be handled specially, in that we are computing their LUB at |
| // each update, and reading them yields the type that was found in a |
| // previous analysis of [outermostElement]. |
| ClosureClassMap closureData = |
| compiler.closureToClassMapper.computeClosureToClassMapping( |
| analyzedElement, node, elements); |
| closureData.forEachCapturedVariable((variable, field) { |
| locals.setCaptured(variable, field); |
| }); |
| closureData.forEachBoxedVariable((variable, field) { |
| locals.setCapturedAndBoxed(variable, field); |
| }); |
| if (analyzedElement.isField) { |
| return visit(initializer); |
| } |
| |
| FunctionElement function = analyzedElement; |
| FunctionSignature signature = function.functionSignature; |
| signature.forEachOptionalParameter((ParameterElement element) { |
| ast.Expression defaultValue = element.initializer; |
| T type = (defaultValue == null) ? types.nullType : visit(defaultValue); |
| inferrer.setDefaultTypeOfParameter(element, type); |
| }); |
| |
| if (analyzedElement.isNative) { |
| // Native methods do not have a body, and we currently just say |
| // they return dynamic. |
| return types.dynamicType; |
| } |
| |
| if (analyzedElement.isGenerativeConstructor) { |
| isThisExposed = false; |
| signature.forEachParameter((element) { |
| T parameterType = inferrer.typeOfElement(element); |
| if (element.kind == ElementKind.FIELD_PARAMETER) { |
| if (element.fieldElement.modifiers.isFinal) { |
| inferrer.recordTypeOfFinalField( |
| node, |
| analyzedElement, |
| element.fieldElement, |
| parameterType); |
| } else { |
| locals.updateField(element.fieldElement, parameterType); |
| inferrer.recordTypeOfNonFinalField( |
| element.parseNode(compiler), |
| element.fieldElement, |
| parameterType); |
| } |
| } |
| locals.update(element, parameterType, node); |
| }); |
| ClassElement cls = analyzedElement.enclosingClass; |
| if (analyzedElement.isSynthesized) { |
| node = analyzedElement; |
| ConstructorElement constructor = analyzedElement; |
| synthesizeForwardingCall(node, constructor.definingConstructor); |
| } else { |
| visitingInitializers = true; |
| visit(node.initializers); |
| visitingInitializers = false; |
| // For a generative constructor like: `Foo();`, we synthesize |
| // a call to the default super constructor (the one that takes |
| // no argument). Resolution ensures that such a constructor |
| // exists. |
| if (!isConstructorRedirect |
| && !seenSuperConstructorCall |
| && !cls.isObject(compiler)) { |
| Selector selector = |
| new Selector.callDefaultConstructor(analyzedElement.library); |
| FunctionElement target = cls.superclass.lookupConstructor(selector); |
| analyzeSuperConstructorCall(target, new ArgumentsTypes([], {})); |
| synthesizeForwardingCall(analyzedElement, target); |
| } |
| visit(node.body); |
| inferrer.recordExposesThis(analyzedElement, isThisExposed); |
| } |
| if (!isConstructorRedirect) { |
| // Iterate over all instance fields, and give a null type to |
| // fields that we haven't initialized for sure. |
| cls.forEachInstanceField((_, field) { |
| if (field.modifiers.isFinal) return; |
| T type = locals.fieldScope.readField(field); |
| if (type == null && field.initializer == null) { |
| inferrer.recordTypeOfNonFinalField(node, field, types.nullType); |
| } |
| }); |
| } |
| returnType = types.nonNullExact(cls); |
| } else { |
| signature.forEachParameter((element) { |
| locals.update(element, inferrer.typeOfElement(element), node); |
| }); |
| visit(node.body); |
| if (returnType == null) { |
| // No return in the body. |
| returnType = locals.seenReturnOrThrow |
| ? types.nonNullEmpty() // Body always throws. |
| : types.nullType; |
| } else if (!locals.seenReturnOrThrow) { |
| // We haven't seen returns on all branches. So the method may |
| // also return null. |
| returnType = inferrer.addReturnTypeFor( |
| analyzedElement, returnType, types.nullType); |
| } |
| } |
| |
| compiler.world.registerSideEffects(analyzedElement, sideEffects); |
| assert(breaksFor.isEmpty); |
| assert(continuesFor.isEmpty); |
| return returnType; |
| } |
| |
| T visitFunctionExpression(ast.FunctionExpression node) { |
| Element element = elements[node]; |
| // We don't put the closure in the work queue of the |
| // inferrer, because it will share information with its enclosing |
| // method, like for example the types of local variables. |
| LocalsHandler closureLocals = new LocalsHandler<T>.from( |
| locals, node, useOtherTryBlock: false); |
| SimpleTypeInferrerVisitor visitor = new SimpleTypeInferrerVisitor<T>( |
| element, compiler, inferrer, closureLocals); |
| visitor.run(); |
| inferrer.recordReturnType(element, visitor.returnType); |
| |
| // Record the types of captured non-boxed variables. Types of |
| // these variables may already be there, because of an analysis of |
| // a previous closure. |
| ClosureClassMap nestedClosureData = |
| compiler.closureToClassMapper.getMappingForNestedFunction(node); |
| nestedClosureData.forEachCapturedVariable((variable, field) { |
| if (!nestedClosureData.isVariableBoxed(variable)) { |
| if (variable == nestedClosureData.thisElement) { |
| inferrer.recordType(field, thisType); |
| } |
| // The type is null for type parameters. |
| if (locals.locals[variable] == null) return; |
| inferrer.recordType(field, locals.locals[variable]); |
| } |
| capturedVariables.add(variable); |
| }); |
| |
| return inferrer.concreteTypes.putIfAbsent(node, () { |
| return types.allocateClosure(node, element); |
| }); |
| } |
| |
| T visitFunctionDeclaration(ast.FunctionDeclaration node) { |
| Element element = elements[node]; |
| T type = inferrer.concreteTypes.putIfAbsent(node.function, () { |
| return types.allocateClosure(node.function, element); |
| }); |
| locals.update(element, type, node); |
| visit(node.function); |
| return type; |
| } |
| |
| T visitStringInterpolation(ast.StringInterpolation node) { |
| // Interpolation could have any effects since it could call any toString() |
| // method. |
| // TODO(sra): This could be modelled by a call to toString() but with a |
| // guaranteed String return type. Interpolation of known types would get |
| // specialized effects. This would not currently be effective since the JS |
| // code in the toString methods for intercepted primitive types is assumed |
| // to have all effects. Effect annotations on JS code would be needed to |
| // get the benefit. |
| sideEffects.setAllSideEffects(); |
| return super.visitStringInterpolation(node); |
| } |
| |
| T visitLiteralList(ast.LiteralList node) { |
| // We only set the type once. We don't need to re-visit the children |
| // when re-analyzing the node. |
| return inferrer.concreteTypes.putIfAbsent(node, () { |
| T elementType; |
| int length = 0; |
| for (ast.Node element in node.elements.nodes) { |
| T type = visit(element); |
| elementType = elementType == null |
| ? types.allocatePhi(null, null, type) |
| : types.addPhiInput(null, elementType, type); |
| length++; |
| } |
| elementType = elementType == null |
| ? types.nonNullEmpty() |
| : types.simplifyPhi(null, null, elementType); |
| T containerType = node.isConst |
| ? types.constListType |
| : types.growableListType; |
| return types.allocateList( |
| containerType, |
| node, |
| outermostElement, |
| elementType, |
| length); |
| }); |
| } |
| |
| T visitLiteralMap(ast.LiteralMap node) { |
| return inferrer.concreteTypes.putIfAbsent(node, () { |
| ast.NodeList entries = node.entries; |
| List<T> keyTypes = []; |
| List<T> valueTypes = []; |
| |
| for (ast.LiteralMapEntry entry in entries) { |
| keyTypes.add(visit(entry.key)); |
| valueTypes.add(visit(entry.value)); |
| } |
| |
| T type = node.isConst ? types.constMapType : types.mapType; |
| return types.allocateMap(type, |
| node, |
| outermostElement, |
| keyTypes, |
| valueTypes); |
| }); |
| } |
| |
| bool isThisOrSuper(ast.Node node) => node.isThis() || node.isSuper(); |
| |
| bool isInClassOrSubclass(Element element) { |
| ClassElement cls = outermostElement.enclosingClass; |
| ClassElement enclosing = element.enclosingClass; |
| return (enclosing == cls) || compiler.world.isSubclass(cls, enclosing); |
| } |
| |
| void checkIfExposesThis(Selector selector) { |
| if (isThisExposed) return; |
| inferrer.forEachElementMatching(selector, (element) { |
| if (element.isField) { |
| if (!selector.isSetter |
| && isInClassOrSubclass(element) |
| && !element.modifiers.isFinal |
| && locals.fieldScope.readField(element) == null |
| && element.initializer == null) { |
| // If the field is being used before this constructor |
| // actually had a chance to initialize it, say it can be |
| // null. |
| inferrer.recordTypeOfNonFinalField( |
| analyzedElement.node, element, |
| types.nullType); |
| } |
| // Accessing a field does not expose [:this:]. |
| return true; |
| } |
| // TODO(ngeoffray): We could do better here if we knew what we |
| // are calling does not expose this. |
| isThisExposed = true; |
| return false; |
| }); |
| } |
| |
| bool get inInstanceContext { |
| return (outermostElement.isInstanceMember && !outermostElement.isField) |
| || outermostElement.isGenerativeConstructor; |
| } |
| |
| bool treatAsInstanceMember(Element element) { |
| return (Elements.isUnresolved(element) && inInstanceContext) |
| || (element != null && element.isInstanceMember); |
| } |
| |
| T visitSendSet(ast.SendSet node) { |
| Element element = elements[node]; |
| if (!Elements.isUnresolved(element) && element.impliesType) { |
| node.visitChildren(this); |
| return types.dynamicType; |
| } |
| |
| Selector getterSelector = |
| elements.getGetterSelectorInComplexSendSet(node); |
| Selector operatorSelector = |
| elements.getOperatorSelectorInComplexSendSet(node); |
| Selector setterSelector = elements.getSelector(node); |
| |
| String op = node.assignmentOperator.source; |
| bool isIncrementOrDecrement = op == '++' || op == '--'; |
| |
| T receiverType; |
| bool isCallOnThis = false; |
| if (node.receiver == null) { |
| if (treatAsInstanceMember(element)) { |
| receiverType = thisType; |
| isCallOnThis = true; |
| } |
| } else { |
| receiverType = visit(node.receiver); |
| isCallOnThis = isThisOrSuper(node.receiver); |
| } |
| |
| T rhsType; |
| T indexType; |
| |
| if (isIncrementOrDecrement) { |
| rhsType = types.uint31Type; |
| if (node.isIndex) indexType = visit(node.arguments.head); |
| } else if (node.isIndex) { |
| indexType = visit(node.arguments.head); |
| rhsType = visit(node.arguments.tail.head); |
| } else { |
| rhsType = visit(node.arguments.head); |
| } |
| |
| if (!visitingInitializers && !isThisExposed) { |
| for (ast.Node node in node.arguments) { |
| if (isThisOrSuper(node)) { |
| isThisExposed = true; |
| break; |
| } |
| } |
| if (!isThisExposed && isCallOnThis) { |
| checkIfExposesThis( |
| types.newTypedSelector(receiverType, setterSelector)); |
| if (getterSelector != null) { |
| checkIfExposesThis( |
| types.newTypedSelector(receiverType, getterSelector)); |
| } |
| } |
| } |
| |
| if (node.isIndex) { |
| if (op == '=') { |
| // [: foo[0] = 42 :] |
| handleDynamicSend( |
| node, |
| setterSelector, |
| receiverType, |
| new ArgumentsTypes<T>([indexType, rhsType], null)); |
| return rhsType; |
| } else { |
| // [: foo[0] += 42 :] or [: foo[0]++ :]. |
| T getterType = handleDynamicSend( |
| node, |
| getterSelector, |
| receiverType, |
| new ArgumentsTypes<T>([indexType], null)); |
| T returnType = handleDynamicSend( |
| node, |
| operatorSelector, |
| getterType, |
| new ArgumentsTypes<T>([rhsType], null)); |
| handleDynamicSend( |
| node, |
| setterSelector, |
| receiverType, |
| new ArgumentsTypes<T>([indexType, returnType], null)); |
| |
| if (node.isPostfix) { |
| return getterType; |
| } else { |
| return returnType; |
| } |
| } |
| } else if (op == '=') { |
| return handlePlainAssignment( |
| node, element, setterSelector, receiverType, rhsType, |
| node.arguments.head); |
| } else { |
| // [: foo++ :] or [: foo += 1 :]. |
| ArgumentsTypes operatorArguments = new ArgumentsTypes<T>([rhsType], null); |
| T getterType; |
| T newType; |
| if (Elements.isErroneousElement(element)) { |
| getterType = types.dynamicType; |
| newType = types.dynamicType; |
| } else if (Elements.isStaticOrTopLevelField(element)) { |
| Element getterElement = elements[node.selector]; |
| getterType = |
| handleStaticSend(node, getterSelector, getterElement, null); |
| newType = handleDynamicSend( |
| node, operatorSelector, getterType, operatorArguments); |
| handleStaticSend( |
| node, setterSelector, element, |
| new ArgumentsTypes<T>([newType], null)); |
| } else if (Elements.isUnresolved(element) |
| || element.isSetter |
| || element.isField) { |
| getterType = handleDynamicSend( |
| node, getterSelector, receiverType, null); |
| newType = handleDynamicSend( |
| node, operatorSelector, getterType, operatorArguments); |
| handleDynamicSend(node, setterSelector, receiverType, |
| new ArgumentsTypes<T>([newType], null)); |
| } else if (Elements.isLocal(element)) { |
| getterType = locals.use(element); |
| newType = handleDynamicSend( |
| node, operatorSelector, getterType, operatorArguments); |
| locals.update(element, newType, node); |
| } else { |
| // Bogus SendSet, for example [: myMethod += 42 :]. |
| getterType = types.dynamicType; |
| newType = handleDynamicSend( |
| node, operatorSelector, getterType, operatorArguments); |
| } |
| |
| if (node.isPostfix) { |
| return getterType; |
| } else { |
| return newType; |
| } |
| } |
| } |
| |
| T handlePlainAssignment(ast.Node node, |
| Element element, |
| Selector setterSelector, |
| T receiverType, |
| T rhsType, |
| ast.Node rhs) { |
| ArgumentsTypes arguments = new ArgumentsTypes<T>([rhsType], null); |
| if (Elements.isErroneousElement(element)) { |
| // Code will always throw. |
| } else if (Elements.isStaticOrTopLevelField(element)) { |
| handleStaticSend(node, setterSelector, element, arguments); |
| } else if (Elements.isUnresolved(element) || element.isSetter) { |
| if (analyzedElement.isGenerativeConstructor |
| && (node.asSendSet() != null) |
| && (node.asSendSet().receiver != null) |
| && node.asSendSet().receiver.isThis()) { |
| Iterable<Element> targets = compiler.world.allFunctions.filter( |
| types.newTypedSelector(thisType, setterSelector)); |
| // We just recognized a field initialization of the form: |
| // `this.foo = 42`. If there is only one target, we can update |
| // its type. |
| if (targets.length == 1) { |
| Element single = targets.first; |
| if (single.isField) { |
| locals.updateField(single, rhsType); |
| } |
| } |
| } |
| handleDynamicSend( |
| node, setterSelector, receiverType, arguments); |
| } else if (element.isField) { |
| if (element.isFinal) { |
| inferrer.recordTypeOfFinalField( |
| node, outermostElement, element, rhsType); |
| } else { |
| if (analyzedElement.isGenerativeConstructor) { |
| locals.updateField(element, rhsType); |
| } |
| if (visitingInitializers) { |
| inferrer.recordTypeOfNonFinalField(node, element, rhsType); |
| } else { |
| handleDynamicSend( |
| node, setterSelector, receiverType, arguments); |
| } |
| } |
| } else if (Elements.isLocal(element)) { |
| locals.update(element, rhsType, node); |
| } |
| return rhsType; |
| } |
| |
| T visitSuperSend(ast.Send node) { |
| Element element = elements[node]; |
| ArgumentsTypes arguments = node.isPropertyAccess |
| ? null |
| : analyzeArguments(node.arguments); |
| if (visitingInitializers) { |
| seenSuperConstructorCall = true; |
| analyzeSuperConstructorCall(element, arguments); |
| } |
| Selector selector = elements.getSelector(node); |
| // TODO(ngeoffray): We could do better here if we knew what we |
| // are calling does not expose this. |
| isThisExposed = true; |
| if (Elements.isUnresolved(element) |
| || !selector.applies(element, compiler)) { |
| // Ensure we create a node, to make explicit the call to the |
| // `noSuchMethod` handler. |
| return handleDynamicSend(node, selector, superType, arguments); |
| } else if (node.isPropertyAccess |
| || element.isFunction |
| || element.isGenerativeConstructor) { |
| return handleStaticSend(node, selector, element, arguments); |
| } else { |
| return inferrer.registerCalledClosure( |
| node, selector, inferrer.typeOfElement(element), |
| outermostElement, arguments, sideEffects, inLoop); |
| } |
| } |
| |
| // Try to find the length given to a fixed array constructor call. |
| int findLength(ast.Send node) { |
| ast.Node firstArgument = node.arguments.head; |
| Element element = elements[firstArgument]; |
| ast.LiteralInt length = firstArgument.asLiteralInt(); |
| if (length != null) { |
| return length.value; |
| } else if (element != null |
| && element.isField |
| && Elements.isStaticOrTopLevelField(element) |
| && compiler.world.fieldNeverChanges(element)) { |
| var constant = |
| compiler.backend.constants.getConstantForVariable(element); |
| if (constant != null && constant.isInt) { |
| return constant.value; |
| } |
| } |
| return null; |
| } |
| |
| T visitStaticSend(ast.Send node) { |
| Element element = elements[node]; |
| if (elements.isAssert(node)) { |
| js.JavaScriptBackend backend = compiler.backend; |
| element = backend.assertMethod; |
| } |
| ArgumentsTypes arguments = analyzeArguments(node.arguments); |
| if (visitingInitializers) { |
| if (ast.Initializers.isConstructorRedirect(node)) { |
| isConstructorRedirect = true; |
| } else if (ast.Initializers.isSuperConstructorCall(node)) { |
| seenSuperConstructorCall = true; |
| analyzeSuperConstructorCall(element, arguments); |
| } |
| } |
| if (element.isForeign(compiler)) { |
| return handleForeignSend(node); |
| } |
| Selector selector = elements.getSelector(node); |
| // In erroneous code the number of arguments in the selector might not |
| // match the function element. |
| // TODO(polux): return nonNullEmpty and check it doesn't break anything |
| if (!selector.applies(element, compiler)) return types.dynamicType; |
| |
| T returnType = handleStaticSend(node, selector, element, arguments); |
| if (Elements.isGrowableListConstructorCall(element, node, compiler)) { |
| return inferrer.concreteTypes.putIfAbsent( |
| node, () => types.allocateList( |
| types.growableListType, node, outermostElement, |
| types.nonNullEmpty(), 0)); |
| } else if (Elements.isFixedListConstructorCall(element, node, compiler) |
| || Elements.isFilledListConstructorCall(element, node, compiler)) { |
| |
| int length = findLength(node); |
| T elementType = |
| Elements.isFixedListConstructorCall(element, node, compiler) |
| ? types.nullType |
| : arguments.positional[1]; |
| |
| return inferrer.concreteTypes.putIfAbsent( |
| node, () => types.allocateList( |
| types.fixedListType, node, outermostElement, |
| elementType, length)); |
| } else if (Elements.isConstructorOfTypedArraySubclass(element, compiler)) { |
| int length = findLength(node); |
| ConstructorElement constructor = element; |
| constructor = constructor.effectiveTarget; |
| T elementType = inferrer.returnTypeOfElement( |
| constructor.enclosingClass.lookupMember('[]')); |
| return inferrer.concreteTypes.putIfAbsent( |
| node, () => types.allocateList( |
| types.nonNullExact(constructor.enclosingClass), node, |
| outermostElement, elementType, length)); |
| } else if (element.isFunction || element.isConstructor) { |
| return returnType; |
| } else { |
| assert(element.isField || element.isGetter); |
| return inferrer.registerCalledClosure( |
| node, selector, inferrer.typeOfElement(element), |
| outermostElement, arguments, sideEffects, inLoop); |
| } |
| } |
| |
| T handleForeignSend(ast.Send node) { |
| ArgumentsTypes arguments = analyzeArguments(node.arguments); |
| Selector selector = elements.getSelector(node); |
| String name = selector.name; |
| handleStaticSend(node, selector, elements[node], arguments); |
| if (name == 'JS') { |
| native.NativeBehavior nativeBehavior = |
| compiler.enqueuer.resolution.nativeEnqueuer.getNativeBehaviorOf(node); |
| sideEffects.add(nativeBehavior.sideEffects); |
| return inferrer.typeOfNativeBehavior(nativeBehavior); |
| } else if (name == 'JS_GET_NAME' |
| || name == 'JS_NULL_CLASS_NAME' |
| || name == 'JS_OBJECT_CLASS_NAME' |
| || name == 'JS_OPERATOR_IS_PREFIX' |
| || name == 'JS_OPERATOR_AS_PREFIX' |
| || name == 'JS_STRING_CONCAT') { |
| return types.stringType; |
| } else { |
| sideEffects.setAllSideEffects(); |
| return types.dynamicType; |
| } |
| } |
| |
| ArgumentsTypes analyzeArguments(Link<ast.Node> arguments) { |
| List<T> positional = []; |
| Map<String, T> named; |
| for (var argument in arguments) { |
| ast.NamedArgument namedArgument = argument.asNamedArgument(); |
| if (namedArgument != null) { |
| argument = namedArgument.expression; |
| if (named == null) named = new Map<String, T>(); |
| named[namedArgument.name.source] = argument.accept(this); |
| } else { |
| positional.add(argument.accept(this)); |
| } |
| // TODO(ngeoffray): We could do better here if we knew what we |
| // are calling does not expose this. |
| isThisExposed = isThisExposed || argument.isThis(); |
| } |
| return new ArgumentsTypes<T>(positional, named); |
| } |
| |
| T visitGetterSend(ast.Send node) { |
| Element element = elements[node]; |
| Selector selector = elements.getSelector(node); |
| if (Elements.isStaticOrTopLevelField(element)) { |
| return handleStaticSend(node, selector, element, null); |
| } else if (Elements.isInstanceSend(node, elements)) { |
| return visitDynamicSend(node); |
| } else if (Elements.isStaticOrTopLevelFunction(element)) { |
| return handleStaticSend(node, selector, element, null); |
| } else if (Elements.isErroneousElement(element)) { |
| return types.dynamicType; |
| } else if (Elements.isLocal(element)) { |
| assert(locals.use(element) != null); |
| return locals.use(element); |
| } else { |
| assert(element is PrefixElement); |
| return null; |
| } |
| } |
| |
| T visitClosureSend(ast.Send node) { |
| assert(node.receiver == null); |
| T closure = node.selector.accept(this); |
| ArgumentsTypes arguments = analyzeArguments(node.arguments); |
| Element element = elements[node]; |
| Selector selector = elements.getSelector(node); |
| if (element != null && element.isFunction) { |
| assert(Elements.isLocal(element)); |
| // This only works for function statements. We need a |
| // more sophisticated type system with function types to support |
| // more. |
| return inferrer.registerCalledElement( |
| node, selector, outermostElement, element, arguments, |
| sideEffects, inLoop); |
| } else { |
| return inferrer.registerCalledClosure( |
| node, selector, closure, outermostElement, arguments, |
| sideEffects, inLoop); |
| } |
| } |
| |
| T handleStaticSend(ast.Node node, |
| Selector selector, |
| Element element, |
| ArgumentsTypes arguments) { |
| // Erroneous elements may be unresolved, for example missing getters. |
| if (Elements.isUnresolved(element)) return types.dynamicType; |
| return inferrer.registerCalledElement( |
| node, selector, outermostElement, element, arguments, |
| sideEffects, inLoop); |
| } |
| |
| T handleDynamicSend(ast.Node node, |
| Selector selector, |
| T receiverType, |
| ArgumentsTypes arguments) { |
| assert(receiverType != null); |
| if (selector.mask != receiverType) { |
| selector = (receiverType == types.dynamicType) |
| ? selector.asUntyped |
| : types.newTypedSelector(receiverType, selector); |
| inferrer.updateSelectorInTree(analyzedElement, node, selector); |
| } |
| |
| // If the receiver of the call is a local, we may know more about |
| // its type by refining it with the potential targets of the |
| // calls. |
| if (node.asSend() != null) { |
| ast.Node receiver = node.asSend().receiver; |
| if (receiver != null) { |
| Element element = elements[receiver]; |
| if (Elements.isLocal(element) && !capturedVariables.contains(element)) { |
| T refinedType = types.refineReceiver(selector, receiverType); |
| locals.update(element, refinedType, node); |
| } |
| } |
| } |
| |
| return inferrer.registerCalledSelector( |
| node, selector, receiverType, outermostElement, arguments, |
| sideEffects, inLoop); |
| } |
| |
| T visitDynamicSend(ast.Send node) { |
| Element element = elements[node]; |
| T receiverType; |
| bool isCallOnThis = false; |
| if (node.receiver == null) { |
| if (treatAsInstanceMember(element)) { |
| isCallOnThis = true; |
| receiverType = thisType; |
| } |
| } else { |
| ast.Node receiver = node.receiver; |
| isCallOnThis = isThisOrSuper(receiver); |
| receiverType = visit(receiver); |
| } |
| |
| Selector selector = elements.getSelector(node); |
| if (!isThisExposed && isCallOnThis) { |
| checkIfExposesThis(types.newTypedSelector(receiverType, selector)); |
| } |
| |
| ArgumentsTypes arguments = node.isPropertyAccess |
| ? null |
| : analyzeArguments(node.arguments); |
| if (selector.name == '==' |
| || selector.name == '!=') { |
| if (types.isNull(receiverType)) { |
| potentiallyAddNullCheck(node, node.arguments.head); |
| return types.boolType; |
| } else if (types.isNull(arguments.positional[0])) { |
| potentiallyAddNullCheck(node, node.receiver); |
| return types.boolType; |
| } |
| } |
| return handleDynamicSend(node, selector, receiverType, arguments); |
| } |
| |
| void recordReturnType(T type) { |
| returnType = inferrer.addReturnTypeFor(analyzedElement, returnType, type); |
| } |
| |
| T synthesizeForwardingCall(Spannable node, FunctionElement element) { |
| element = element.implementation; |
| FunctionElement function = analyzedElement; |
| FunctionSignature signature = function.functionSignature; |
| FunctionSignature calleeSignature = element.functionSignature; |
| if (!calleeSignature.isCompatibleWith(signature)) { |
| return types.nonNullEmpty(); |
| } |
| |
| List<T> unnamed = <T>[]; |
| signature.forEachRequiredParameter((Element element) { |
| assert(locals.use(element) != null); |
| unnamed.add(locals.use(element)); |
| }); |
| |
| Map<String, T> named; |
| if (signature.optionalParametersAreNamed) { |
| named = new Map<String, T>(); |
| signature.forEachOptionalParameter((Element element) { |
| named[element.name] = locals.use(element); |
| }); |
| } else { |
| signature.forEachOptionalParameter((Element element) { |
| unnamed.add(locals.use(element)); |
| }); |
| } |
| |
| ArgumentsTypes arguments = new ArgumentsTypes<T>(unnamed, named); |
| return inferrer.registerCalledElement(node, |
| null, |
| outermostElement, |
| element, |
| arguments, |
| sideEffects, |
| inLoop); |
| } |
| |
| T visitReturn(ast.Return node) { |
| if (node.isRedirectingFactoryBody) { |
| Element element = elements[node.expression]; |
| if (Elements.isErroneousElement(element)) { |
| recordReturnType(types.dynamicType); |
| } else { |
| // We don't create a selector for redirecting factories, and |
| // the send is just a property access. Therefore we must |
| // manually create the [ArgumentsTypes] of the call, and |
| // manually register [analyzedElement] as a caller of [element]. |
| T mask = synthesizeForwardingCall(node.expression, element); |
| recordReturnType(mask); |
| } |
| } else { |
| ast.Node expression = node.expression; |
| recordReturnType(expression == null |
| ? types.nullType |
| : expression.accept(this)); |
| } |
| locals.seenReturnOrThrow = true; |
| return null; |
| } |
| |
| T visitForIn(ast.ForIn node) { |
| T expressionType = visit(node.expression); |
| Selector iteratorSelector = elements.getIteratorSelector(node); |
| Selector currentSelector = elements.getCurrentSelector(node); |
| Selector moveNextSelector = elements.getMoveNextSelector(node); |
| |
| T iteratorType = |
| handleDynamicSend(node, iteratorSelector, expressionType, null); |
| handleDynamicSend(node, moveNextSelector, |
| iteratorType, new ArgumentsTypes<T>([], null)); |
| T currentType = |
| handleDynamicSend(node, currentSelector, iteratorType, null); |
| |
| if (node.expression.isThis()) { |
| // Any reasonable implementation of an iterator would expose |
| // this, so we play it safe and assume it will. |
| isThisExposed = true; |
| } |
| |
| ast.Node identifier = node.declaredIdentifier; |
| Element element = elements[identifier]; |
| Selector selector = elements.getSelector(identifier); |
| |
| T receiverType; |
| if (element != null && element.isInstanceMember) { |
| receiverType = thisType; |
| } else { |
| receiverType = types.dynamicType; |
| } |
| |
| handlePlainAssignment(identifier, element, selector, |
| receiverType, currentType, |
| node.expression); |
| return handleLoop(node, () { |
| visit(node.body); |
| }); |
| } |
| } |