| // Copyright (c) 2017, 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 'package:kernel/ast.dart' as ir; |
| |
| import '../common.dart'; |
| import '../common/names.dart'; |
| import '../compiler.dart'; |
| import '../constants/expressions.dart'; |
| import '../constants/values.dart'; |
| import '../common_elements.dart'; |
| import '../elements/elements.dart'; |
| import '../elements/entities.dart'; |
| import '../js_backend/annotations.dart'; |
| import '../js_backend/js_backend.dart'; |
| import '../native/behavior.dart' as native; |
| import '../resolution/tree_elements.dart'; |
| import '../tree/nodes.dart' as ast; |
| import '../types/constants.dart'; |
| import '../types/types.dart'; |
| import '../universe/call_structure.dart'; |
| import '../universe/selector.dart'; |
| import '../universe/side_effects.dart'; |
| import '../util/util.dart'; |
| import '../world.dart'; |
| import 'closure_tracer.dart'; |
| import 'debug.dart' as debug; |
| import 'locals_handler.dart'; |
| import 'list_tracer.dart'; |
| import 'map_tracer.dart'; |
| import 'builder.dart'; |
| import 'builder_kernel.dart'; |
| import 'type_graph_dump.dart'; |
| import 'type_graph_inferrer.dart'; |
| import 'type_graph_nodes.dart'; |
| import 'type_system.dart'; |
| |
| /** |
| * An inferencing engine that computes a call graph of |
| * [TypeInformation] nodes by visiting the AST of the application, and |
| * then does the inferencing on the graph. |
| */ |
| class InferrerEngine { |
| final Map<Element, TypeInformation> defaultTypeOfParameter = |
| new Map<Element, TypeInformation>(); |
| final WorkQueue workQueue = new WorkQueue(); |
| final Element mainElement; |
| final Set<Element> analyzedElements = new Set<Element>(); |
| |
| /// The maximum number of times we allow a node in the graph to |
| /// change types. If a node reaches that limit, we give up |
| /// inferencing on it and give it the dynamic type. |
| final int MAX_CHANGE_COUNT = 6; |
| |
| int overallRefineCount = 0; |
| int addedInGraph = 0; |
| |
| final Compiler compiler; |
| |
| /// The [ClosedWorld] on which inference reasoning is based. |
| final ClosedWorld closedWorld; |
| |
| final ClosedWorldRefiner closedWorldRefiner; |
| final TypeSystem types; |
| final Map<ast.Node, TypeInformation> concreteTypes = |
| new Map<ast.Node, TypeInformation>(); |
| |
| /// Parallel structure for concreteTypes. |
| // TODO(efortuna): Remove concreteTypes and/or parameterize InferrerEngine by |
| // ir.Node or ast.Node type. Then remove this in favor of `concreteTypes`. |
| final Map<ir.Node, TypeInformation> concreteKernelTypes = |
| new Map<ir.Node, TypeInformation>(); |
| final Set<Element> generativeConstructorsExposingThis = new Set<Element>(); |
| |
| /// Data computed internally within elements, like the type-mask of a send a |
| /// list allocation, or a for-in loop. |
| final Map<Element, GlobalTypeInferenceElementData> inTreeData = |
| new Map<Element, GlobalTypeInferenceElementData>(); |
| |
| InferrerEngine(this.compiler, ClosedWorld closedWorld, |
| this.closedWorldRefiner, this.mainElement) |
| : this.types = new TypeSystem(closedWorld), |
| this.closedWorld = closedWorld; |
| |
| CommonElements get commonElements => closedWorld.commonElements; |
| |
| /** |
| * Applies [f] to all elements in the universe that match |
| * [selector] and [mask]. If [f] returns false, aborts the iteration. |
| */ |
| void forEachElementMatching( |
| Selector selector, TypeMask mask, bool f(Element element)) { |
| Iterable<MemberEntity> elements = |
| closedWorld.allFunctions.filter(selector, mask); |
| for (MemberElement e in elements) { |
| if (!f(e.implementation)) return; |
| } |
| } |
| |
| // TODO(johnniwinther): Make this private again. |
| GlobalTypeInferenceElementData dataOf(AstElement element) => inTreeData |
| .putIfAbsent(element, () => new GlobalTypeInferenceElementData()); |
| |
| /** |
| * 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( |
| closedWorldRefiner.getCurrentlyKnownSideEffects(callee.declaration)); |
| } |
| } |
| |
| /** |
| * Returns the type for [nativeBehavior]. See documentation on |
| * [native.NativeBehavior]. |
| */ |
| TypeInformation typeOfNativeBehavior(native.NativeBehavior nativeBehavior) { |
| if (nativeBehavior == null) return types.dynamicType; |
| List typesReturned = nativeBehavior.typesReturned; |
| if (typesReturned.isEmpty) return types.dynamicType; |
| TypeInformation returnType; |
| for (var type in typesReturned) { |
| TypeInformation mappedType; |
| if (type == native.SpecialType.JsObject) { |
| mappedType = types.nonNullExact(commonElements.objectClass); |
| } else if (type == commonElements.stringType) { |
| mappedType = types.stringType; |
| } else if (type == commonElements.intType) { |
| mappedType = types.intType; |
| } else if (type == commonElements.numType || |
| type == commonElements.doubleType) { |
| // Note: the backend double class is specifically for non-integer |
| // doubles, and a native behavior returning 'double' does not guarantee |
| // a non-integer return type, so we return the number type for those. |
| mappedType = types.numType; |
| } else if (type == commonElements.boolType) { |
| mappedType = types.boolType; |
| } else if (type == commonElements.nullType) { |
| mappedType = types.nullType; |
| } else if (type.isVoid) { |
| mappedType = types.nullType; |
| } else if (type.isDynamic) { |
| return types.dynamicType; |
| } else { |
| mappedType = types.nonNullSubtype(type.element); |
| } |
| returnType = types.computeLUB(returnType, mappedType); |
| if (returnType == types.dynamicType) { |
| break; |
| } |
| } |
| return returnType; |
| } |
| |
| // TODO(johnniwinther): Pass the [ResolvedAst] instead of [owner]. |
| void updateSelectorInTree( |
| AstElement owner, Spannable node, Selector selector, TypeMask mask) { |
| ast.Node astNode = node; |
| GlobalTypeInferenceElementData data = dataOf(owner); |
| if (astNode.asSendSet() != null) { |
| if (selector.isSetter || selector.isIndexSet) { |
| data.setTypeMask(node, mask); |
| } else if (selector.isGetter || selector.isIndex) { |
| data.setGetterTypeMaskInComplexSendSet(node, mask); |
| } else { |
| assert(selector.isOperator); |
| data.setOperatorTypeMaskInComplexSendSet(node, mask); |
| } |
| } else if (astNode.asSend() != null) { |
| data.setTypeMask(node, mask); |
| } else { |
| assert(astNode.asForIn() != null); |
| if (selector == Selectors.iterator) { |
| data.setIteratorTypeMask(node, mask); |
| } else if (selector == Selectors.current) { |
| data.setCurrentTypeMask(node, mask); |
| } else { |
| assert(selector == Selectors.moveNext); |
| data.setMoveNextTypeMask(node, mask); |
| } |
| } |
| } |
| |
| bool isNativeMember(Element element) { |
| return element is MemberElement && |
| compiler.backend.nativeData.isNativeMember(element); |
| } |
| |
| 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); |
| } |
| } |
| |
| JavaScriptBackend get backend => compiler.backend; |
| OptimizerHintsForTests get annotations => backend.annotations; |
| DiagnosticReporter get reporter => compiler.reporter; |
| CommonMasks get commonMasks => closedWorld.commonMasks; |
| |
| /** |
| * A set of selector names that [List] implements, that we know return |
| * their element type. |
| */ |
| final Set<Selector> returnsListElementTypeSet = |
| new Set<Selector>.from(<Selector>[ |
| new Selector.getter(const PublicName('first')), |
| new Selector.getter(const PublicName('last')), |
| new Selector.getter(const PublicName('single')), |
| new Selector.call(const PublicName('singleWhere'), CallStructure.ONE_ARG), |
| new Selector.call(const PublicName('elementAt'), CallStructure.ONE_ARG), |
| new Selector.index(), |
| new Selector.call(const PublicName('removeAt'), CallStructure.ONE_ARG), |
| new Selector.call(const PublicName('removeLast'), CallStructure.NO_ARGS) |
| ]); |
| |
| bool returnsListElementType(Selector selector, TypeMask mask) { |
| return mask != null && |
| mask.isContainer && |
| returnsListElementTypeSet.contains(selector); |
| } |
| |
| bool returnsMapValueType(Selector selector, TypeMask mask) { |
| return mask != null && mask.isMap && selector.isIndex; |
| } |
| |
| void analyzeListAndEnqueue(ListTypeInformation info) { |
| if (info.analyzed) return; |
| info.analyzed = true; |
| |
| ListTracerVisitor tracer = new ListTracerVisitor(info, this); |
| bool succeeded = tracer.run(); |
| if (!succeeded) return; |
| |
| info.bailedOut = false; |
| info.elementType.inferred = true; |
| TypeMask fixedListType = commonMasks.fixedListType; |
| if (info.originalType.forwardTo == fixedListType) { |
| info.checksGrowable = tracer.callsGrowableMethod; |
| } |
| tracer.assignments.forEach(info.elementType.addAssignment); |
| // Enqueue the list for later refinement |
| workQueue.add(info); |
| workQueue.add(info.elementType); |
| } |
| |
| void analyzeMapAndEnqueue(MapTypeInformation info) { |
| if (info.analyzed) return; |
| info.analyzed = true; |
| MapTracerVisitor tracer = new MapTracerVisitor(info, this); |
| |
| bool succeeded = tracer.run(); |
| if (!succeeded) return; |
| |
| info.bailedOut = false; |
| for (int i = 0; i < tracer.keyAssignments.length; ++i) { |
| TypeInformation newType = info.addEntryAssignment( |
| tracer.keyAssignments[i], tracer.valueAssignments[i]); |
| if (newType != null) workQueue.add(newType); |
| } |
| for (TypeInformation map in tracer.mapAssignments) { |
| workQueue.addAll(info.addMapAssignment(map)); |
| } |
| |
| info.markAsInferred(); |
| workQueue.add(info.keyType); |
| workQueue.add(info.valueType); |
| workQueue.addAll(info.typeInfoMap.values); |
| workQueue.add(info); |
| } |
| |
| void runOverAllElements() { |
| if (compiler.disableTypeInference) return; |
| if (compiler.options.verbose) { |
| compiler.progress.reset(); |
| } |
| sortResolvedAsts().forEach((ResolvedAst resolvedAst) { |
| if (compiler.shouldPrintProgress) { |
| reporter.log('Added $addedInGraph elements in inferencing graph.'); |
| compiler.progress.reset(); |
| } |
| // This also forces the creation of the [ElementTypeInformation] to ensure |
| // it is in the graph. |
| types.withMember( |
| resolvedAst.element.implementation, () => analyze(resolvedAst, null)); |
| }); |
| reporter.log('Added $addedInGraph elements in inferencing graph.'); |
| |
| TypeGraphDump dump = debug.PRINT_GRAPH ? new TypeGraphDump(this) : null; |
| |
| dump?.beforeAnalysis(); |
| buildWorkQueue(); |
| refine(); |
| |
| // Try to infer element types of lists and compute their escape information. |
| types.allocatedLists.values.forEach((ListTypeInformation info) { |
| analyzeListAndEnqueue(info); |
| }); |
| |
| // Try to infer the key and value types for maps and compute the values' |
| // escape information. |
| types.allocatedMaps.values.forEach((MapTypeInformation info) { |
| analyzeMapAndEnqueue(info); |
| }); |
| |
| Set<FunctionElement> bailedOutOn = new Set<FunctionElement>(); |
| |
| // Trace closures to potentially infer argument types. |
| types.allocatedClosures.forEach((info) { |
| void trace( |
| Iterable<FunctionElement> elements, ClosureTracerVisitor tracer) { |
| tracer.run(); |
| if (!tracer.continueAnalyzing) { |
| elements.forEach((FunctionElement e) { |
| closedWorldRefiner.registerMightBePassedToApply(e); |
| if (debug.VERBOSE) print("traced closure $e as ${true} (bail)"); |
| e.functionSignature.forEachParameter((parameter) { |
| types |
| .getInferredTypeOf(parameter) |
| .giveUp(this, clearAssignments: false); |
| }); |
| }); |
| bailedOutOn.addAll(elements); |
| return; |
| } |
| elements |
| .where((e) => !bailedOutOn.contains(e)) |
| .forEach((FunctionElement e) { |
| e.functionSignature.forEachParameter((parameter) { |
| var info = types.getInferredTypeOf(parameter); |
| info.maybeResume(); |
| workQueue.add(info); |
| }); |
| if (tracer.tracedType.mightBePassedToFunctionApply) { |
| closedWorldRefiner.registerMightBePassedToApply(e); |
| } |
| if (debug.VERBOSE) { |
| print("traced closure $e as " |
| "${closedWorldRefiner |
| .getCurrentlyKnownMightBePassedToApply(e)}"); |
| } |
| }); |
| } |
| |
| if (info is ClosureTypeInformation) { |
| Iterable<FunctionElement> elements = [info.element]; |
| trace(elements, new ClosureTracerVisitor(elements, info, this)); |
| } else if (info is CallSiteTypeInformation) { |
| if (info is StaticCallSiteTypeInformation && |
| info.selector != null && |
| info.selector.isCall) { |
| // This is a constructor call to a class with a call method. So we |
| // need to trace the call method here. |
| assert(info.calledElement.isGenerativeConstructor); |
| ClassElement cls = info.calledElement.enclosingClass; |
| FunctionElement callMethod = cls.lookupMember(Identifiers.call); |
| assert(invariant(cls, callMethod != null)); |
| Iterable<FunctionElement> elements = [callMethod]; |
| trace(elements, new ClosureTracerVisitor(elements, info, this)); |
| } else { |
| // We only are interested in functions here, as other targets |
| // of this closure call are not a root to trace but an intermediate |
| // for some other function. |
| Iterable<FunctionElement> elements = new List<FunctionElement>.from( |
| info.callees.where((e) => e.isFunction)); |
| trace(elements, new ClosureTracerVisitor(elements, info, this)); |
| } |
| } else { |
| assert(info is ElementTypeInformation); |
| trace([info.element], |
| new StaticTearOffClosureTracerVisitor(info.element, info, this)); |
| } |
| }); |
| |
| dump?.beforeTracing(); |
| |
| // Reset all nodes that use lists/maps that have been inferred, as well |
| // as nodes that use elements fetched from these lists/maps. The |
| // workset for a new run of the analysis will be these nodes. |
| Set<TypeInformation> seenTypes = new Set<TypeInformation>(); |
| while (!workQueue.isEmpty) { |
| TypeInformation info = workQueue.remove(); |
| if (seenTypes.contains(info)) continue; |
| // If the node cannot be reset, we do not need to update its users either. |
| if (!info.reset(this)) continue; |
| seenTypes.add(info); |
| workQueue.addAll(info.users); |
| } |
| |
| workQueue.addAll(seenTypes); |
| refine(); |
| |
| if (debug.PRINT_SUMMARY) { |
| types.allocatedLists.values.forEach((ListTypeInformation info) { |
| print('${info.type} ' |
| 'for ${info.originalType.allocationNode} ' |
| 'at ${info.originalType.allocationElement} ' |
| 'after ${info.refineCount}'); |
| }); |
| types.allocatedMaps.values.forEach((MapTypeInformation info) { |
| print('${info.type} ' |
| 'for ${info.originalType.allocationNode} ' |
| 'at ${info.originalType.allocationElement} ' |
| 'after ${info.refineCount}'); |
| }); |
| types.allocatedClosures.forEach((TypeInformation info) { |
| if (info is ElementTypeInformation) { |
| print('${types.getInferredSignatureOf(info.element)} for ' |
| '${info.element}'); |
| } else if (info is ClosureTypeInformation) { |
| print('${types.getInferredSignatureOf(info.element)} for ' |
| '${info.element}'); |
| } else if (info is DynamicCallSiteTypeInformation) { |
| for (MemberElement target in info.targets) { |
| if (target is MethodElement) { |
| print('${types.getInferredSignatureOf(target)} for ${target}'); |
| } else { |
| print('${types.getInferredTypeOf(target).type} for ${target}'); |
| } |
| } |
| } else if (info is StaticCallSiteTypeInformation) { |
| ClassElement cls = info.calledElement.enclosingClass; |
| FunctionElement callMethod = cls.lookupMember(Identifiers.call); |
| print('${types.getInferredSignatureOf(callMethod)} for ${cls}'); |
| } else { |
| print('${info.type} for some unknown kind of closure'); |
| } |
| }); |
| analyzedElements.forEach((Element elem) { |
| TypeInformation type = types.getInferredTypeOf(elem); |
| print('${elem} :: ${type} from ${type.assignments} '); |
| }); |
| } |
| dump?.afterAnalysis(); |
| |
| reporter.log('Inferred $overallRefineCount types.'); |
| |
| processLoopInformation(); |
| } |
| |
| void analyze(ResolvedAst resolvedAst, ArgumentsTypes arguments) { |
| AstElement element = resolvedAst.element.implementation; |
| if (analyzedElements.contains(element)) return; |
| analyzedElements.add(element); |
| |
| dynamic visitor = compiler.options.kernelGlobalInference |
| ? new KernelTypeGraphBuilder(element, resolvedAst, compiler, this) |
| : new ElementGraphBuilder(element, resolvedAst, compiler, this); |
| TypeInformation type; |
| reporter.withCurrentElement(element, () { |
| // ignore: UNDEFINED_METHOD |
| type = visitor.run(); |
| }); |
| addedInGraph++; |
| |
| if (element.isField) { |
| VariableElement fieldElement = element; |
| ast.Node node = resolvedAst.node; |
| ast.Node initializer = resolvedAst.body; |
| if (element.isFinal || element.isConst) { |
| // If [element] is final and has an initializer, we record |
| // the inferred type. |
| if (resolvedAst.body != null) { |
| if (type is! ListTypeInformation && type is! MapTypeInformation) { |
| // For non-container types, the constant handler does |
| // constant folding that could give more precise results. |
| ConstantExpression constant = fieldElement.constant; |
| if (constant != null) { |
| ConstantValue value = |
| compiler.backend.constants.getConstantValue(constant); |
| if (value != null) { |
| if (value.isFunction) { |
| FunctionConstantValue functionConstant = value; |
| MethodElement function = functionConstant.element; |
| type = types.allocateClosure(node, function); |
| } else { |
| // Although we might find a better type, we have to keep |
| // the old type around to ensure that we get a complete view |
| // of the type graph and do not drop any flow edges. |
| TypeMask refinedType = computeTypeMask(closedWorld, value); |
| assert(TypeMask.assertIsNormalized(refinedType, closedWorld)); |
| type = new NarrowTypeInformation(type, refinedType); |
| types.allocatedTypes.add(type); |
| } |
| } else { |
| assert(invariant( |
| fieldElement, |
| fieldElement.isInstanceMember || |
| constant.isImplicit || |
| constant.isPotential, |
| message: "Constant expression without value: " |
| "${constant.toStructuredText()}.")); |
| } |
| } |
| } |
| recordType(element, type); |
| } else if (!element.isInstanceMember) { |
| recordType(element, types.nullType); |
| } |
| } else if (initializer == null) { |
| // Only update types of static fields if there is no |
| // assignment. Instance fields are dealt with in the constructor. |
| if (Elements.isStaticOrTopLevelField(element)) { |
| recordTypeOfNonFinalField(node, element, type); |
| } |
| } else { |
| recordTypeOfNonFinalField(node, element, type); |
| } |
| if (Elements.isStaticOrTopLevelField(element) && |
| resolvedAst.body != null && |
| !element.isConst) { |
| var argument = resolvedAst.body; |
| // TODO(13429): We could do better here by using the |
| // constant handler to figure out if it's a lazy field or not. |
| if (argument.asSend() != null || |
| (argument.asNewExpression() != null && !argument.isConst)) { |
| recordType(element, types.nullType); |
| } |
| } |
| } else { |
| recordReturnType(element, type); |
| } |
| } |
| |
| void processLoopInformation() { |
| types.allocatedCalls.forEach((info) { |
| if (!info.inLoop) return; |
| if (info is StaticCallSiteTypeInformation) { |
| closedWorldRefiner |
| .addFunctionCalledInLoop(info.calledElement.declaration); |
| } else if (info.mask != null && !info.mask.containsAll(closedWorld)) { |
| // For instance methods, we only register a selector called in a |
| // loop if it is a typed selector, to avoid marking too many |
| // methods as being called from within a loop. This cuts down |
| // on the code bloat. |
| info.targets.forEach((MemberElement element) { |
| closedWorldRefiner.addFunctionCalledInLoop(element); |
| }); |
| } |
| }); |
| } |
| |
| void refine() { |
| while (!workQueue.isEmpty) { |
| if (compiler.shouldPrintProgress) { |
| reporter.log('Inferred $overallRefineCount types.'); |
| compiler.progress.reset(); |
| } |
| TypeInformation info = workQueue.remove(); |
| TypeMask oldType = info.type; |
| TypeMask newType = info.refine(this); |
| // Check that refinement has not accidentally changed the type. |
| assert(oldType == info.type); |
| if (info.abandonInferencing) info.doNotEnqueue = true; |
| if ((info.type = newType) != oldType) { |
| overallRefineCount++; |
| info.refineCount++; |
| if (info.refineCount > MAX_CHANGE_COUNT) { |
| if (debug.ANOMALY_WARN) { |
| print("ANOMALY WARNING: max refinement reached for $info"); |
| } |
| info.giveUp(this); |
| info.type = info.refine(this); |
| info.doNotEnqueue = true; |
| } |
| workQueue.addAll(info.users); |
| if (info.hasStableType(this)) { |
| info.stabilize(this); |
| } |
| } |
| } |
| } |
| |
| void buildWorkQueue() { |
| workQueue.addAll(types.typeInformations.values); |
| workQueue.addAll(types.allocatedTypes); |
| workQueue.addAll(types.allocatedClosures); |
| workQueue.addAll(types.allocatedCalls); |
| } |
| |
| /** |
| * Update the assignments to parameters in the graph. [remove] tells |
| * wheter assignments must be added or removed. If [init] is false, |
| * parameters are added to the work queue. |
| */ |
| void updateParameterAssignments(TypeInformation caller, Element callee, |
| ArgumentsTypes arguments, Selector selector, TypeMask mask, |
| {bool remove, bool addToQueue: true}) { |
| if (callee.name == Identifiers.noSuchMethod_) return; |
| if (callee.isField) { |
| if (selector.isSetter) { |
| ElementTypeInformation info = types.getInferredTypeOf(callee); |
| if (remove) { |
| info.removeAssignment(arguments.positional[0]); |
| } else { |
| info.addAssignment(arguments.positional[0]); |
| } |
| if (addToQueue) workQueue.add(info); |
| } |
| } else if (callee.isGetter) { |
| return; |
| } else if (selector != null && selector.isGetter) { |
| // We are tearing a function off and thus create a closure. |
| assert(callee.isFunction); |
| MemberTypeInformation info = types.getInferredTypeOf(callee); |
| if (remove) { |
| info.closurizedCount--; |
| } else { |
| info.closurizedCount++; |
| if (Elements.isStaticOrTopLevel(callee)) { |
| types.allocatedClosures.add(info); |
| } else { |
| // We add the call-site type information here so that we |
| // can benefit from further refinement of the selector. |
| types.allocatedClosures.add(caller); |
| } |
| FunctionElement function = callee.implementation; |
| FunctionSignature signature = function.functionSignature; |
| signature.forEachParameter((Element parameter) { |
| ParameterTypeInformation info = types.getInferredTypeOf(parameter); |
| info.tagAsTearOffClosureParameter(this); |
| if (addToQueue) workQueue.add(info); |
| }); |
| } |
| } else { |
| FunctionElement function = callee.implementation; |
| FunctionSignature signature = function.functionSignature; |
| int parameterIndex = 0; |
| bool visitingRequiredParameter = true; |
| signature.forEachParameter((Element parameter) { |
| if (signature.hasOptionalParameters && |
| parameter == signature.optionalParameters.first) { |
| visitingRequiredParameter = false; |
| } |
| TypeInformation type = visitingRequiredParameter |
| ? arguments.positional[parameterIndex] |
| : signature.optionalParametersAreNamed |
| ? arguments.named[parameter.name] |
| : parameterIndex < arguments.positional.length |
| ? arguments.positional[parameterIndex] |
| : null; |
| if (type == null) type = getDefaultTypeOfParameter(parameter); |
| TypeInformation info = types.getInferredTypeOf(parameter); |
| if (remove) { |
| info.removeAssignment(type); |
| } else { |
| info.addAssignment(type); |
| } |
| parameterIndex++; |
| if (addToQueue) workQueue.add(info); |
| }); |
| } |
| } |
| |
| /** |
| * Sets the type of a parameter's default value to [type]. If the global |
| * mapping in [defaultTypeOfParameter] already contains a type, it must be |
| * a [PlaceholderTypeInformation], which will be replaced. All its uses are |
| * updated. |
| */ |
| void setDefaultTypeOfParameter( |
| ParameterElement parameter, TypeInformation type) { |
| assert(parameter.functionDeclaration.isImplementation); |
| TypeInformation existing = defaultTypeOfParameter[parameter]; |
| defaultTypeOfParameter[parameter] = type; |
| TypeInformation info = types.getInferredTypeOf(parameter); |
| if (existing != null && existing is PlaceholderTypeInformation) { |
| // Replace references to [existing] to use [type] instead. |
| if (parameter.functionDeclaration.isInstanceMember) { |
| ParameterAssignments assignments = info.assignments; |
| assignments.replace(existing, type); |
| } else { |
| List<TypeInformation> assignments = info.assignments; |
| for (int i = 0; i < assignments.length; i++) { |
| if (assignments[i] == existing) { |
| assignments[i] = type; |
| } |
| } |
| } |
| // Also forward all users. |
| type.addUsersOf(existing); |
| } else { |
| assert(existing == null); |
| } |
| } |
| |
| /** |
| * Returns the [TypeInformation] node for the default value of a parameter. |
| * If this is queried before it is set by [setDefaultTypeOfParameter], a |
| * [PlaceholderTypeInformation] is returned, which will later be replaced |
| * by the actual node when [setDefaultTypeOfParameter] is called. |
| * |
| * Invariant: After graph construction, no [PlaceholderTypeInformation] nodes |
| * should be present and a default type for each parameter should |
| * exist. |
| */ |
| TypeInformation getDefaultTypeOfParameter(Element parameter) { |
| return defaultTypeOfParameter.putIfAbsent(parameter, () { |
| return new PlaceholderTypeInformation(types.currentMember); |
| }); |
| } |
| |
| /** |
| * This helper breaks abstractions but is currently required to work around |
| * the wrong modeling of default values of optional parameters of |
| * synthetic constructors. |
| * |
| * TODO(johnniwinther): Remove once default values of synthetic parameters |
| * are fixed. |
| */ |
| bool hasAlreadyComputedTypeOfParameterDefault(Element parameter) { |
| TypeInformation seen = defaultTypeOfParameter[parameter]; |
| return (seen != null && seen is! PlaceholderTypeInformation); |
| } |
| |
| /** |
| * Returns the type of [element]. |
| */ |
| TypeInformation typeOfElement(Element element) { |
| if (element is FunctionElement) return types.functionType; |
| return types.getInferredTypeOf(element); |
| } |
| |
| /** |
| * Returns the return type of [element]. |
| */ |
| TypeInformation returnTypeOfElement(Element element) { |
| if (element is! FunctionElement) return types.dynamicType; |
| return types.getInferredTypeOf(element); |
| } |
| |
| /** |
| * Records that [node] sets final field [element] to be of type [type]. |
| * |
| * [nodeHolder] is the element holder of [node]. |
| */ |
| void recordTypeOfFinalField( |
| Spannable node, Element analyzed, Element element, TypeInformation type) { |
| types.getInferredTypeOf(element).addAssignment(type); |
| } |
| |
| /** |
| * Records that [node] sets non-final field [element] to be of type |
| * [type]. |
| */ |
| void recordTypeOfNonFinalField( |
| Spannable node, Element element, TypeInformation type) { |
| types.getInferredTypeOf(element).addAssignment(type); |
| } |
| |
| /** |
| * Records that [element] is of type [type]. |
| */ |
| void recordType(Element element, TypeInformation type) { |
| types.getInferredTypeOf(element).addAssignment(type); |
| } |
| |
| /** |
| * Records that the return type [element] is of type [type]. |
| */ |
| void recordReturnType(Element element, TypeInformation type) { |
| TypeInformation info = types.getInferredTypeOf(element); |
| if (element.name == '==') { |
| // Even if x.== doesn't return a bool, 'x == null' evaluates to 'false'. |
| info.addAssignment(types.boolType); |
| } |
| // TODO(ngeoffray): Clean up. We do these checks because |
| // [SimpleTypesInferrer] deals with two different inferrers. |
| if (type == null) return; |
| if (info.assignments.isEmpty) info.addAssignment(type); |
| } |
| |
| /** |
| * Notifies to the inferrer that [analyzedElement] can have return |
| * type [newType]. [currentType] is the type the [ElementGraphBuilder] |
| * currently found. |
| * |
| * Returns the new type for [analyzedElement]. |
| */ |
| TypeInformation addReturnTypeFor( |
| Element element, TypeInformation unused, TypeInformation newType) { |
| TypeInformation type = types.getInferredTypeOf(element); |
| // TODO(ngeoffray): Clean up. We do this check because |
| // [SimpleTypesInferrer] deals with two different inferrers. |
| if (element.isGenerativeConstructor) return type; |
| type.addAssignment(newType); |
| return 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. |
| */ |
| TypeInformation registerCalledElement( |
| Spannable node, |
| Selector selector, |
| TypeMask mask, |
| Element caller, |
| Element callee, |
| ArgumentsTypes arguments, |
| SideEffects sideEffects, |
| bool inLoop) { |
| CallSiteTypeInformation info = new StaticCallSiteTypeInformation( |
| types.currentMember, |
| node, |
| caller, |
| callee, |
| selector, |
| mask, |
| arguments, |
| inLoop); |
| // If this class has a 'call' method then we have essentially created a |
| // closure here. Register it as such so that it is traced. |
| // Note: we exclude factory constructors because they don't always create an |
| // instance of the type. They are static methods that delegate to some other |
| // generative constructor to do the actual creation of the object. |
| if (selector != null && selector.isCall && callee.isGenerativeConstructor) { |
| ClassElement cls = callee.enclosingClass; |
| if (cls.callType != null) { |
| types.allocatedClosures.add(info); |
| } |
| } |
| info.addToGraph(this); |
| types.allocatedCalls.add(info); |
| updateSideEffects(sideEffects, selector, callee); |
| return info; |
| } |
| |
| /** |
| * 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. |
| */ |
| TypeInformation registerCalledSelector( |
| ast.Node node, |
| Selector selector, |
| TypeMask mask, |
| TypeInformation receiverType, |
| Element caller, |
| ArgumentsTypes arguments, |
| SideEffects sideEffects, |
| bool inLoop) { |
| if (selector.isClosureCall) { |
| return registerCalledClosure(node, selector, mask, receiverType, caller, |
| arguments, sideEffects, inLoop); |
| } |
| |
| closedWorld.allFunctions |
| .filter(selector, mask) |
| .forEach((MemberElement callee) { |
| updateSideEffects(sideEffects, selector, callee); |
| }); |
| |
| CallSiteTypeInformation info = new DynamicCallSiteTypeInformation( |
| types.currentMember, |
| node, |
| caller, |
| selector, |
| mask, |
| receiverType, |
| arguments, |
| inLoop); |
| |
| info.addToGraph(this); |
| types.allocatedCalls.add(info); |
| return info; |
| } |
| |
| /** |
| * Registers a call to await with an expression of type [argumentType] as |
| * argument. |
| */ |
| TypeInformation registerAwait(ast.Node node, TypeInformation argument) { |
| AwaitTypeInformation info = |
| new AwaitTypeInformation(types.currentMember, node); |
| info.addAssignment(argument); |
| types.allocatedTypes.add(info); |
| return info; |
| } |
| |
| /** |
| * Registers a call to yield with an expression of type [argumentType] as |
| * argument. |
| */ |
| TypeInformation registerYield(ast.Node node, TypeInformation argument) { |
| YieldTypeInformation info = |
| new YieldTypeInformation(types.currentMember, node); |
| info.addAssignment(argument); |
| types.allocatedTypes.add(info); |
| return info; |
| } |
| |
| /** |
| * 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. |
| */ |
| TypeInformation registerCalledClosure( |
| ast.Node node, |
| Selector selector, |
| TypeMask mask, |
| TypeInformation closure, |
| Element caller, |
| ArgumentsTypes arguments, |
| SideEffects sideEffects, |
| bool inLoop) { |
| sideEffects.setDependsOnSomething(); |
| sideEffects.setAllSideEffects(); |
| CallSiteTypeInformation info = new ClosureCallSiteTypeInformation( |
| types.currentMember, |
| node, |
| caller, |
| selector, |
| mask, |
| closure, |
| arguments, |
| inLoop); |
| info.addToGraph(this); |
| types.allocatedCalls.add(info); |
| return info; |
| } |
| |
| // Sorts the resolved elements by size. We do this for this inferrer |
| // to get the same results for [ListTracer] compared to the |
| // [SimpleTypesInferrer]. |
| Iterable<ResolvedAst> sortResolvedAsts() { |
| int max = 0; |
| Map<int, Setlet<ResolvedAst>> methodSizes = <int, Setlet<ResolvedAst>>{}; |
| compiler.enqueuer.resolution.processedEntities |
| .forEach((MemberElement element) { |
| ResolvedAst resolvedAst = element.resolvedAst; |
| element = element.implementation; |
| if (element.impliesType) return; |
| assert(invariant( |
| element, |
| element.isField || |
| element.isFunction || |
| element.isConstructor || |
| element.isGetter || |
| element.isSetter, |
| message: 'Unexpected element kind: ${element.kind}')); |
| if (element.isAbstract) return; |
| // Put the other operators in buckets by length, later to be added in |
| // length order. |
| int length = 0; |
| if (resolvedAst.kind == ResolvedAstKind.PARSED) { |
| TreeElementMapping mapping = resolvedAst.elements; |
| length = mapping.getSelectorCount(); |
| } |
| max = length > max ? length : max; |
| Setlet<ResolvedAst> set = |
| methodSizes.putIfAbsent(length, () => new Setlet<ResolvedAst>()); |
| set.add(resolvedAst); |
| }); |
| |
| List<ResolvedAst> result = <ResolvedAst>[]; |
| for (int i = 0; i <= max; i++) { |
| Setlet<ResolvedAst> set = methodSizes[i]; |
| if (set != null) result.addAll(set); |
| } |
| return result; |
| } |
| |
| void clear() { |
| void cleanup(TypeInformation info) => info.cleanup(); |
| |
| types.allocatedCalls.forEach(cleanup); |
| types.allocatedCalls.clear(); |
| |
| defaultTypeOfParameter.clear(); |
| |
| types.typeInformations.values.forEach(cleanup); |
| |
| types.allocatedTypes.forEach(cleanup); |
| types.allocatedTypes.clear(); |
| |
| types.concreteTypes.clear(); |
| |
| types.allocatedClosures.forEach(cleanup); |
| types.allocatedClosures.clear(); |
| |
| analyzedElements.clear(); |
| generativeConstructorsExposingThis.clear(); |
| |
| types.allocatedMaps.values.forEach(cleanup); |
| types.allocatedLists.values.forEach(cleanup); |
| } |
| |
| Iterable<Element> getCallersOf(Element element) { |
| if (compiler.disableTypeInference) { |
| throw new UnsupportedError( |
| "Cannot query the type inferrer when type inference is disabled."); |
| } |
| MemberTypeInformation info = types.getInferredTypeOf(element); |
| return info.callers; |
| } |
| |
| /** |
| * Returns the type of [element] when being called with [selector]. |
| */ |
| TypeInformation typeOfElementWithSelector( |
| Element element, Selector selector) { |
| if (element.name == Identifiers.noSuchMethod_ && |
| selector.name != element.name) { |
| // An invocation can resolve to a [noSuchMethod], in which case |
| // we get the return type of [noSuchMethod]. |
| return returnTypeOfElement(element); |
| } else if (selector.isGetter) { |
| if (element.isFunction) { |
| // [functionType] is null if the inferrer did not run. |
| return types.functionType == null |
| ? types.dynamicType |
| : types.functionType; |
| } else if (element.isField) { |
| return typeOfElement(element); |
| } else if (Elements.isUnresolved(element)) { |
| return types.dynamicType; |
| } else { |
| assert(element.isGetter); |
| return returnTypeOfElement(element); |
| } |
| } else if (element.isGetter || element.isField) { |
| assert(selector.isCall || selector.isSetter); |
| return types.dynamicType; |
| } else { |
| return returnTypeOfElement(element); |
| } |
| } |
| |
| /** |
| * Records that the captured variable [local] is read. |
| */ |
| void recordCapturedLocalRead(Local local) {} |
| |
| /** |
| * Records that the variable [local] is being updated. |
| */ |
| void recordLocalUpdate(Local local, TypeInformation type) {} |
| } |