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/*
 * Copyright 2008 The Closure Compiler Authors.
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
 * You may obtain a copy of the License at
 *
 *     http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */
package com.google.javascript.jscomp;

import static com.google.common.base.Preconditions.checkState;

import com.google.common.annotations.VisibleForTesting;
import com.google.common.base.Joiner;
import com.google.common.base.Supplier;
import com.google.common.base.Suppliers;
import com.google.common.collect.FluentIterable;
import com.google.common.collect.HashMultimap;
import com.google.common.collect.ImmutableSet;
import com.google.common.collect.LinkedHashMultimap;
import com.google.common.collect.Multimap;
import com.google.javascript.jscomp.AbstractCompiler.LifeCycleStage;
import com.google.javascript.jscomp.NodeTraversal.AbstractScopedCallback;
import com.google.javascript.jscomp.graph.StandardUnionFind;
import com.google.javascript.jscomp.graph.UnionFind;
import com.google.javascript.rhino.FunctionTypeI;
import com.google.javascript.rhino.Node;
import com.google.javascript.rhino.ObjectTypeI;
import com.google.javascript.rhino.TypeI;
import com.google.javascript.rhino.TypeIRegistry;
import com.google.javascript.rhino.jstype.JSTypeNative;
import java.util.ArrayList;
import java.util.Collection;
import java.util.HashMap;
import java.util.HashSet;
import java.util.IdentityHashMap;
import java.util.LinkedHashMap;
import java.util.List;
import java.util.Map;
import java.util.Objects;
import java.util.Set;
import java.util.logging.Level;
import java.util.logging.Logger;
import java.util.regex.Pattern;

/**
 * DisambiguateProperties renames properties to disambiguate between unrelated
 * fields with the same name. Two properties are considered related if they
 * share a definition on their prototype chains, or if they are potentially
 * referenced together via union types.
 *
 * 

Renamimg only occurs if there are two or more distinct properties with * the same name. * *

This pass allows other passes, such as inlining and code removal to take * advantage of type information implicitly. * *

 *   Foo.a;
 *   Bar.a;
 * 
* *

will become * *

 *   Foo.Foo$a;
 *   Bar.Bar$a;
 * 
* * NOTE(dimvar): For every property, this pass groups together the types that * can't be disambiguated. If a type inherits from another type, their common * properties can never be disambiguated, yet we have to compute this info once * per property rather than just once in the pass. This is where the bulk of the * time is spent. * We have added many caches that help a lot, but it is probably worth it to * revisit this pass and rewrite it in a way that does not compute the same * thing over and over. * */ class DisambiguateProperties implements CompilerPass { // To prevent the logs from filling up, we cap the number of warnings // that we tell the user to fix per-property. private static final int MAX_INVALIDATION_WARNINGS_PER_PROPERTY = 10; private static final Logger logger = Logger.getLogger( DisambiguateProperties.class.getName()); private static final Pattern NONWORD_PATTERN = Pattern.compile("[^\\w$]"); static class Warnings { // TODO(user): {1} and {2} are not exactly useful for most people. static final DiagnosticType INVALIDATION = DiagnosticType.disabled( "JSC_INVALIDATION", "Property disambiguator skipping all instances of property {0} " + "because of type {1} node {2}. {3}"); static final DiagnosticType INVALIDATION_ON_TYPE = DiagnosticType.disabled( "JSC_INVALIDATION_TYPE", "Property disambiguator skipping instances of property {0} on type {1}. {2}"); // TODO(tbreisacher): Check this in a separate pass, so that users get the error even if // optimizations are not running. static final DiagnosticType INVALID_RENAME_FUNCTION = DiagnosticType.error("JSC_INVALID_RENAME_FUNCTION", "{0} call is invalid: {1}"); } private final AbstractCompiler compiler; private final InvalidatingTypes invalidatingTypes; private final TypeIRegistry registry; // Used as a substitute for null in gtwpCache. The method gtwpCacheGet returns // null to indicate that an element wasn't present. private final ObjectTypeI BOTTOM_OBJECT; /** * Map of a type to all the related errors that invalidated the type * for disambiguation. */ private final Multimap> invalidationMap; /** * In practice any large code base will have thousands and thousands of * type invalidations, which makes reporting all of the errors useless. * However, certain properties are worth specifically guarding because of the * large amount of code that can be removed as dead code. This list contains * the properties (eg: "toString") that we care about; if any of these * properties is invalidated it causes an error. */ private final Map propertiesToErrorFor; // Use this cache to call FunctionTypeI#getImplementedInterfaces // or FunctionTypeI#getExtendedInterfaces only once per constructor. private Map> ancestorInterfaces; // Cache calls to getTypeWithProperty. private Map> gtwpCache; private ObjectTypeI gtwpCacheGet(String field, TypeI type) { IdentityHashMap m = gtwpCache.get(field); return m == null ? null : m.get(type); } private void gtwpCachePut(String field, TypeI type, ObjectTypeI top) { IdentityHashMap m = gtwpCache.get(field); if (m == null) { m = new IdentityHashMap<>(); gtwpCache.put(field, m); } checkState(null == m.put(type, top)); } private class Property { /** The name of the property. */ final String name; /** * All top types on which the field exists, grouped together if related. * See getTypeWithProperty. If a property exists on a parent class and a * subclass, only the parent class is recorded here. */ private UnionFind types; /** * A set of types for which renaming this field should be skipped. This * list is first filled by fields defined in the externs file. */ Set typesToSkip = new HashSet<>(); /** * If true, do not rename any instance of this field, as it has been * referenced from an unknown type. */ boolean skipRenaming; /** * A map from nodes that need renaming to the highest type in the prototype * chain containing the field for each node. In the case of a union, the * type is the highest type of one of the types in the union. */ Map rootTypesByNode = new HashMap<>(); /** * For every property p and type t, we only need to run recordInterfaces * once. Use this cache to avoid needless calls. */ private final Set recordInterfacesCache = new HashSet<>(); Property(String name) { this.name = name; } /** Returns the types on which this field is referenced. */ UnionFind getTypes() { if (types == null) { types = new StandardUnionFind<>(); } return types; } /** * Record that this property is referenced from this type. */ void addType(TypeI type, TypeI relatedType) { checkState(!skipRenaming, "Attempt to record skipped property: %s", name); TypeI top = getTypeWithProperty(this.name, type); if (invalidatingTypes.isInvalidating(top)) { invalidate(); return; } if (isTypeToSkip(top)) { addTypeToSkip(top); } if (relatedType == null) { getTypes().add(top); } else { getTypes().union(top, relatedType); } FunctionTypeI constructor = getConstructor(type); if (constructor != null && recordInterfacesCache.add(type)) { recordInterfaces(constructor, top, this); } } /** Records the given type as one to skip for this property. */ void addTypeToSkip(TypeI type) { for (TypeI skipType : getTypesToSkipForType(type)) { typesToSkip.add(skipType); getTypes().union(skipType, type); } } /** Invalidates any types related to invalid types. */ void expandTypesToSkip() { // If we are not going to rename any properties, then we do not need to // update the list of invalid types, as they are all invalid. if (shouldRename()) { int count = 0; while (true) { // It should usually only take one time through this do-while. checkState(++count < 10, "Stuck in loop expanding types to skip."); // Make sure that the representative type for each type to skip is // marked as being skipped. Set rootTypesToSkip = new HashSet<>(); for (TypeI subType : typesToSkip) { rootTypesToSkip.add(types.find(subType)); } typesToSkip.addAll(rootTypesToSkip); Set newTypesToSkip = new HashSet<>(); Set allTypes = types.elements(); int originalTypesSize = allTypes.size(); for (TypeI subType : allTypes) { if (!typesToSkip.contains(subType) && typesToSkip.contains(types.find(subType))) { newTypesToSkip.add(subType); } } for (TypeI newType : newTypesToSkip) { addTypeToSkip(newType); } // If there were not any new types added, we are done here. if (types.elements().size() == originalTypesSize) { break; } } } } /** Returns true if any instance of this property should be renamed. */ boolean shouldRename() { return !skipRenaming && types != null && types.allEquivalenceClasses().size() > 1; } /** * Returns true if this property should be renamed on this type. * expandTypesToSkip() should be called before this, if anything has been * added to the typesToSkip list. */ boolean shouldRename(TypeI type) { return !skipRenaming && !typesToSkip.contains(type); } /** * Invalidates a field from renaming. Used for field references on an * object with unknown type. */ boolean invalidate() { boolean changed = !skipRenaming; skipRenaming = true; types = null; typesToSkip = null; rootTypesByNode = null; return changed; } /** * Schedule the node to potentially be renamed. * @param node the node to rename * @param type the highest type in the prototype chain for which the * property is defined * @return True if type was accepted without invalidation or if the property * was already invalidated. False if this property was invalidated this * time. */ boolean scheduleRenaming(Node node, TypeI type) { if (!skipRenaming) { if (invalidatingTypes.isInvalidating(type)) { invalidate(); return false; } rootTypesByNode.put(node, type); } return true; } } private final Map properties = new LinkedHashMap<>(); DisambiguateProperties( AbstractCompiler compiler, Map propertiesToErrorFor) { this.compiler = compiler; this.registry = compiler.getTypeIRegistry(); this.BOTTOM_OBJECT = this.registry.getNativeType(JSTypeNative.NO_OBJECT_TYPE).toMaybeObjectType(); this.propertiesToErrorFor = propertiesToErrorFor; this.invalidationMap = propertiesToErrorFor.isEmpty() ? null : LinkedHashMultimap.>create(); this.invalidatingTypes = new InvalidatingTypes.Builder(registry) .recordInvalidations(this.invalidationMap) .addTypesInvalidForPropertyRenaming() .addAllTypeMismatches(compiler.getTypeMismatches()) .addAllTypeMismatches(compiler.getImplicitInterfaceUses()) .allowEnumsAndScalars() .build(); } @Override public void process(Node externs, Node root) { checkState(compiler.getLifeCycleStage() == LifeCycleStage.NORMALIZED); this.ancestorInterfaces = new HashMap<>(); this.gtwpCache = new HashMap<>(); // Gather names of properties in externs; these properties can't be renamed. NodeTraversal.traverseEs6(compiler, externs, new FindExternProperties()); // Look at each unquoted property access and decide if that property will // be renamed. NodeTraversal.traverseEs6(compiler, root, new FindRenameableProperties()); // Do the actual renaming. renameProperties(); } /** Returns the property for the given name, creating it if necessary. */ protected Property getProperty(String name) { if (!properties.containsKey(name)) { properties.put(name, new Property(name)); } return properties.get(name); } /** * Finds all properties defined in the externs file and sets them as * ineligible for renaming from the type on which they are defined. */ private class FindExternProperties extends AbstractScopedCallback { @Override public void visit(NodeTraversal t, Node n, Node parent) { // TODO(johnlenz): Support object-literal property definitions. if (n.isGetProp()) { Node recv = n.getFirstChild(); TypeI recvType = getType(recv); Property prop = getProperty(n.getLastChild().getString()); // TODO(dimvar): invalidating here when isStructuralInterfacePrototype is true is // kind of arbitrary. We should only do it when the @record is implicitly implemented. if (invalidatingTypes.isInvalidating(recvType) || isStructuralInterfacePrototype(recv)) { prop.invalidate(); } else if (!prop.skipRenaming) { prop.addTypeToSkip(recvType); // If this is a prototype property, then we want to skip assignments // to the instance type as well. These assignments are not usually // seen in the extern code itself, so we must handle them here. if ((recvType = getInstanceFromPrototype(recv)) != null) { prop.getTypes().add(recvType); prop.typesToSkip.add(recvType); } } } } private boolean isStructuralInterfacePrototype(Node n) { return n.isGetProp() && n.getLastChild().getString().equals("prototype") && n.getFirstChild().getTypeI().isStructuralInterface(); } } /** * Traverses the tree, building a map from field names to Nodes for all * fields that can be renamed. */ private class FindRenameableProperties extends AbstractScopedCallback { @Override public void visit(NodeTraversal t, Node n, Node parent) { if (n.isGetProp()) { handleGetProp(t, n); } else if (n.isObjectLit()) { handleObjectLit(t, n); } else if (n.isCall()) { handleCall(t, n); } } private void handleGetProp(NodeTraversal t, Node n) { String name = n.getLastChild().getString(); TypeI type = getType(n.getFirstChild()); Property prop = getProperty(name); if (!prop.scheduleRenaming(n.getLastChild(), processProperty(t, prop, type, null)) && propertiesToErrorFor.containsKey(name)) { String suggestion = ""; if (type.isTop() || type.isUnknownType()) { if (n.getFirstChild().isThis()) { suggestion = "The \"this\" object is unknown in the function, consider using @this"; } else { String qName = n.getFirstChild().getQualifiedName(); suggestion = "Consider casting " + qName + " if you know its type."; } } else { List errors = new ArrayList<>(); printErrorLocations(errors, type); if (!errors.isEmpty()) { suggestion = "Consider fixing errors for the following types:\n"; suggestion += Joiner.on("\n").join(errors); } } compiler.report(JSError.make(n, propertiesToErrorFor.get(name), Warnings.INVALIDATION, name, String.valueOf(type), n.toString(), suggestion)); } } private void handleObjectLit(NodeTraversal t, Node n) { // Object.defineProperties literals are handled at the CALL node. if (n.getParent().isCall() && NodeUtil.isObjectDefinePropertiesDefinition(n.getParent())) { return; } for (Node child = n.getFirstChild(); child != null; child = child.getNext()) { // Maybe STRING, GET, SET if (child.isQuotedString()) { continue; } // We should never see a mix of numbers and strings. String name = child.getString(); TypeI objlitType = getType(n); Property prop = getProperty(name); if (!prop.scheduleRenaming(child, processProperty(t, prop, objlitType, null))) { // TODO(user): It doesn't look like the user can do much in this // case right now. if (propertiesToErrorFor.containsKey(name)) { compiler.report(JSError.make(child, propertiesToErrorFor.get(name), Warnings.INVALIDATION, name, String.valueOf(objlitType), n.toString(), "")); } } } } private void handleCall(NodeTraversal t, Node call) { Node target = call.getFirstChild(); if (!target.isQualifiedName()) { return; } String functionName = target.getOriginalQualifiedName(); if (functionName != null && compiler.getCodingConvention().isPropertyRenameFunction(functionName)) { handlePropertyRenameFunctionCall(t, call, functionName); } else if (NodeUtil.isObjectDefinePropertiesDefinition(call)) { handleObjectDefineProperties(t, call); } } private void handlePropertyRenameFunctionCall( NodeTraversal t, Node call, String renameFunctionName) { int childCount = call.getChildCount(); if (childCount != 2 && childCount != 3) { compiler.report( JSError.make( call, Warnings.INVALID_RENAME_FUNCTION, renameFunctionName, " Must be called with 1 or 2 arguments")); return; } if (!call.getSecondChild().isString()) { compiler.report( JSError.make( call, Warnings.INVALID_RENAME_FUNCTION, renameFunctionName, " The first argument must be a string literal.")); return; } String propName = call.getSecondChild().getString(); if (propName.contains(".")) { compiler.report( JSError.make( call, Warnings.INVALID_RENAME_FUNCTION, renameFunctionName, " The first argument must not be a property path.")); return; } Node obj = call.getChildAtIndex(2); TypeI type = getType(obj); Property prop = getProperty(propName); if (!prop.scheduleRenaming(call.getSecondChild(), processProperty(t, prop, type, null)) && propertiesToErrorFor.containsKey(propName)) { String suggestion = ""; if (type.isTop() || type.isUnknownType()) { if (obj.isThis()) { suggestion = "The \"this\" object is unknown in the function, consider using @this"; } else { String qName = obj.getQualifiedName(); suggestion = "Consider casting " + qName + " if you know its type."; } } else { List errors = new ArrayList<>(); printErrorLocations(errors, type); if (!errors.isEmpty()) { suggestion = "Consider fixing errors for the following types:\n"; suggestion += Joiner.on("\n").join(errors); } } compiler.report( JSError.make( call, propertiesToErrorFor.get(propName), Warnings.INVALIDATION, propName, String.valueOf(type), renameFunctionName, suggestion)); } } private void handleObjectDefineProperties(NodeTraversal t, Node call) { Node typeObj = call.getSecondChild(); TypeI type = getType(typeObj); Node objectLiteral = typeObj.getNext(); if (!objectLiteral.isObjectLit()) { return; } for (Node key : objectLiteral.children()) { if (key.isQuotedString()) { continue; } String propName = key.getString(); Property prop = getProperty(propName); prop.scheduleRenaming(key, processProperty(t, prop, type, null)); } } private void printErrorLocations(List errors, TypeI t) { if (!t.isObjectType() || t.isTop()) { return; } if (t.isUnionType()) { for (TypeI alt : t.getUnionMembers()) { printErrorLocations(errors, alt); } return; } Iterable invalidations = FluentIterable.from(invalidationMap.get(t)) .transform(Suppliers.supplierFunction()) .limit(MAX_INVALIDATION_WARNINGS_PER_PROPERTY); for (JSError error : invalidations) { errors.add(t + " at " + error.sourceName + ":" + error.lineNumber); } } /** * Processes a property, adding it to the list of properties to rename. * @return a representative type for the property reference, which will be * the highest type on the prototype chain of the provided type. In the * case of a union type, it will be the highest type on the prototype * chain of one of the members of the union. */ private TypeI processProperty(NodeTraversal t, Property prop, TypeI type, TypeI relatedType) { type = type.restrictByNotNullOrUndefined(); if (prop.skipRenaming || invalidatingTypes.isInvalidating(type)) { return null; } ObjectTypeI maybeObj = type.toMaybeObjectType(); if (maybeObj != null) { type = maybeObj.withoutStrayProperties(); } Iterable alternatives = getTypeAlternatives(type); if (alternatives != null) { TypeI firstType = relatedType; for (TypeI subType : alternatives) { TypeI lastType = processProperty(t, prop, subType, firstType); if (lastType != null) { firstType = firstType == null ? lastType : firstType; } } return firstType; } else { TypeI topType = getTypeWithProperty(prop.name, type); if (invalidatingTypes.isInvalidating(topType)) { return null; } prop.addType(type, relatedType); return topType; } } } /** Renames all properties with references on more than one type. */ void renameProperties() { int propsRenamed = 0; int propsSkipped = 0; int instancesRenamed = 0; int instancesSkipped = 0; int singleTypeProps = 0; Set reported = new HashSet<>(); for (Property prop : properties.values()) { if (prop.shouldRename()) { UnionFind pTypes = prop.getTypes(); Map propNames = buildPropNames(prop); ++propsRenamed; prop.expandTypesToSkip(); // This loop has poor locality, because instead of walking the AST, // we iterate over all accesses of a property, which can be in very // different places in the code. for (Map.Entry entry : prop.rootTypesByNode.entrySet()) { Node node = entry.getKey(); TypeI rootType = entry.getValue(); if (prop.shouldRename(rootType)) { String newName = propNames.get(pTypes.find(rootType)); node.setString(newName); compiler.reportChangeToEnclosingScope(node); ++instancesRenamed; } else { ++instancesSkipped; CheckLevel checkLevelForProp = propertiesToErrorFor.get(prop.name); if (checkLevelForProp != null && checkLevelForProp != CheckLevel.OFF && !reported.contains(prop.name)) { reported.add(prop.name); compiler.report(JSError.make( node, checkLevelForProp, Warnings.INVALIDATION_ON_TYPE, prop.name, rootType.toString(), "")); } } } } else { if (prop.skipRenaming) { ++propsSkipped; } else { ++singleTypeProps; } } } if (logger.isLoggable(Level.FINE)) { logger.fine("Renamed " + instancesRenamed + " instances of " + propsRenamed + " properties."); logger.fine("Skipped renaming " + instancesSkipped + " invalidated " + "properties, " + propsSkipped + " instances of properties " + "that were skipped for specific types and " + singleTypeProps + " properties that were referenced from only one type."); } } /** * Chooses a name to use for renaming in each equivalence class and maps * the representative type of that class to that name. */ private Map buildPropNames(Property prop) { UnionFind pTypes = prop.getTypes(); String pname = prop.name; Map names = new HashMap<>(); for (Set set : pTypes.allEquivalenceClasses()) { checkState(!set.isEmpty()); TypeI representative = pTypes.find(set.iterator().next()); String typeName = null; for (TypeI type : set) { String typeString = type.toString(); if (typeName == null || typeString.compareTo(typeName) < 0) { typeName = typeString; } } String newName; if ("{...}".equals(typeName)) { newName = pname; } else { newName = NONWORD_PATTERN.matcher(typeName).replaceAll("_") + '$' + pname; } names.put(representative, newName); } return names; } /** Returns a map from field name to types for which it will be renamed. */ @VisibleForTesting Multimap> getRenamedTypesForTesting() { Multimap> ret = HashMultimap.create(); for (Map.Entry entry : properties.entrySet()) { Property prop = entry.getValue(); if (!prop.skipRenaming) { for (Collection c : prop.getTypes().allEquivalenceClasses()) { if (!c.isEmpty() && !prop.typesToSkip.contains(c.iterator().next())) { ret.put(entry.getKey(), c); } } } } return ret; } private TypeI getType(Node node) { if (node == null || node.getTypeI() == null) { return registry.getNativeType(JSTypeNative.UNKNOWN_TYPE); } return node.getTypeI(); } /** * Returns a set of types that should be skipped given the given type. This is * necessary for interfaces, as all super interfaces must also be skipped. */ private ImmutableSet getTypesToSkipForType(TypeI type) { type = type.restrictByNotNullOrUndefined(); if (type.isUnionType()) { ImmutableSet.Builder types = ImmutableSet.builder(); types.add(type); for (TypeI alt : type.getUnionMembers()) { types.addAll(getTypesToSkipForTypeNonUnion(alt)); } return types.build(); } else if (type.isEnumElement()) { return getTypesToSkipForType(type.getEnumeratedTypeOfEnumElement()); } return ImmutableSet.copyOf(getTypesToSkipForTypeNonUnion(type)); } private Set getTypesToSkipForTypeNonUnion(TypeI type) { Set types = new HashSet<>(); TypeI skipType = type; while (skipType != null) { types.add(skipType); ObjectTypeI objSkipType = skipType.toMaybeObjectType(); if (objSkipType != null) { skipType = objSkipType.getPrototypeObject(); } else { break; } } return types; } /** * Determines whether the given type is one whose properties should not be * considered for renaming. */ private boolean isTypeToSkip(TypeI type) { return type.isEnumObject() || type.isBoxableScalar(); } /** * Returns the alternatives if this is a type that represents multiple * types, and null if not. Union and interface types can correspond to * multiple other types. */ private Iterable getTypeAlternatives(TypeI type) { if (type.isUnionType()) { return type.getUnionMembers(); } else { ObjectTypeI objType = type.toMaybeObjectType(); FunctionTypeI constructor = objType != null ? objType.getConstructor() : null; if (constructor != null && constructor.isInterface()) { List list = new ArrayList<>(); for (FunctionTypeI impl : constructor.getDirectSubTypes()) { list.add(impl.getInstanceType()); } return list.isEmpty() ? null : list; } else { return null; } } } /** * Returns the type in the chain from the given type that contains the given * field or null if it is not found anywhere. * Can return a subtype of the input type. */ private ObjectTypeI getTypeWithProperty(String field, TypeI type) { if (type == null) { return null; } ObjectTypeI foundType = gtwpCacheGet(field, type); if (foundType != null) { return foundType.equals(BOTTOM_OBJECT) ? null : foundType; } if (type.isEnumElement()) { foundType = getTypeWithProperty(field, type.getEnumeratedTypeOfEnumElement()); gtwpCachePut(field, type, foundType == null ? BOTTOM_OBJECT : foundType); return foundType; } if (!type.isObjectType()) { if (type.isBoxableScalar()) { foundType = getTypeWithProperty(field, type.autobox()); gtwpCachePut(field, type, foundType == null ? BOTTOM_OBJECT : foundType); return foundType; } else { gtwpCachePut(field, type, BOTTOM_OBJECT); return null; } } // Ignore the prototype itself at all times. if ("prototype".equals(field)) { gtwpCachePut(field, type, BOTTOM_OBJECT); return null; } // We look up the prototype chain to find the highest place (if any) that // this appears. This will make references to overridden properties look // like references to the initial property, so they are renamed alike. ObjectTypeI objType = type.toMaybeObjectType(); if (objType != null && objType.getConstructor() != null && objType.getConstructor().isInterface()) { ObjectTypeI topInterface = objType.getTopDefiningInterface(field); if (topInterface != null && topInterface.getConstructor() != null) { foundType = topInterface.getPrototypeObject(); } } else { while (objType != null && !Objects.equals(objType.getPrototypeObject(), objType)) { if (objType.hasOwnProperty(field)) { foundType = objType; } objType = objType.getPrototypeObject(); } } // If the property does not exist on the referenced type but the original // type is an object type, see if any subtype has the property. if (foundType == null) { TypeI subtypeWithProp = type.getGreatestSubtypeWithProperty(field); ObjectTypeI maybeType = subtypeWithProp == null ? null : subtypeWithProp.toMaybeObjectType(); // getGreatestSubtypeWithProperty does not guarantee that the property // is defined on the returned type, it just indicates that it might be, // so we have to double check. if (maybeType != null && maybeType.hasOwnProperty(field)) { foundType = maybeType; } } // Unwrap templatized types, they are not unique at runtime. if (foundType != null && foundType.isGenericObjectType()) { foundType = foundType.getRawType(); } // Since disambiguation just looks at names, we must return a uniquely named type rather // than an "equivalent" type. In particular, we must manually unwrap named types // so that the returned type has the correct name. if (foundType != null && foundType.isLegacyNamedType()) { foundType = foundType.getLegacyResolvedType().toMaybeObjectType(); } gtwpCachePut(field, type, foundType == null ? BOTTOM_OBJECT : foundType); return foundType; } private TypeI getInstanceFromPrototype(Node n) { if (n.isGetProp() && n.getLastChild().getString().equals("prototype")) { FunctionTypeI f = n.getFirstChild().getTypeI().toMaybeFunctionType(); if (f != null && f.hasInstanceType()) { return f.getInstanceType(); } } return null; } /** * Records that this property could be referenced from any interface that * this type inherits from. * * If the property p is defined only on a subtype of constructor, then this * method has no effect. But we tried modifying getTypeWithProperty to tell us * when the returned type is a subtype, and then skip those calls to * recordInterface, and there was no speed-up. * And it made the code harder to understand, so we don't do it. */ private void recordInterfaces(FunctionTypeI constructor, TypeI relatedType, Property p) { Iterable interfaces = ancestorInterfaces.get(constructor); if (interfaces == null) { interfaces = constructor.getAncestorInterfaces(); ancestorInterfaces.put(constructor, interfaces); } for (ObjectTypeI itype : interfaces) { TypeI top = getTypeWithProperty(p.name, itype); if (top != null) { p.addType(itype, relatedType); } // If this interface invalidated this property, return now. if (p.skipRenaming) { return; } } } private FunctionTypeI getConstructor(TypeI type) { ObjectTypeI objType = type.toMaybeObjectType(); if (objType == null) { return null; } FunctionTypeI constructor = null; if (objType.isFunctionType()) { constructor = objType.toMaybeFunctionType(); } else if (objType.isPrototypeObject()) { constructor = objType.getOwnerFunction(); } else { constructor = objType.getConstructor(); } return constructor; } }




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