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Closure Compiler is a JavaScript optimizing compiler. It parses your JavaScript, analyzes it, removes dead code and rewrites and minimizes what's left. It also checks syntax, variable references, and types, and warns about common JavaScript pitfalls. It is used in many of Google's JavaScript apps, including Gmail, Google Web Search, Google Maps, and Google Docs. This binary checks for style issues such as incorrect or missing JSDoc usage, and missing goog.require() statements. It does not do more advanced checks such as typechecking.

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/*
 * Copyright 2018 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.checkArgument;
import static com.google.common.base.Preconditions.checkNotNull;
import static com.google.common.base.Preconditions.checkState;

import com.google.common.base.Splitter;
import com.google.common.base.Supplier;
import com.google.common.base.Suppliers;
import com.google.common.collect.ImmutableList;
import com.google.common.collect.Iterables;
import com.google.javascript.rhino.IR;
import com.google.javascript.rhino.Node;
import com.google.javascript.rhino.jstype.BooleanLiteralSet;
import com.google.javascript.rhino.jstype.FunctionType;
import com.google.javascript.rhino.jstype.JSType;
import com.google.javascript.rhino.jstype.JSTypeNative;
import com.google.javascript.rhino.jstype.JSTypeRegistry;
import com.google.javascript.rhino.jstype.ObjectType;
import com.google.javascript.rhino.jstype.TemplateTypeMap;
import com.google.javascript.rhino.jstype.TemplateTypeReplacer;
import javax.annotation.Nullable;

/**
 * Creates AST nodes and subtrees.
 *
 * 

This class supports creating nodes either with or without type information. * *

The idea is that client code can create the trees of nodes it needs without having to contain * logic for deciding whether type information should be added or not, and only minimal logic for * determining which types to add when they are necessary. Most methods in this class are able to * determine the correct type information from already existing AST nodes and the current scope. */ final class AstFactory { @Nullable private final JSTypeRegistry registry; // We need the unknown type so frequently, it's worth caching it. private final JSType unknownType; // We might not need Arguments type, but if we do, we should avoid redundant lookups private final Supplier argumentsTypeSupplier; private AstFactory() { this.registry = null; unknownType = null; argumentsTypeSupplier = () -> null; } private AstFactory(JSTypeRegistry registry) { this.registry = registry; this.unknownType = getNativeType(JSTypeNative.UNKNOWN_TYPE); this.argumentsTypeSupplier = Suppliers.memoize( () -> { JSType globalType = registry.getGlobalType("Arguments"); if (globalType != null) { return globalType; } else { return unknownType; } }); ; } static AstFactory createFactoryWithoutTypes() { return new AstFactory(); } static AstFactory createFactoryWithTypes(JSTypeRegistry registry) { return new AstFactory(registry); } /** Does this class instance add types to the nodes it creates? */ boolean isAddingTypes() { return registry != null; } /** * Returns a new EXPR_RESULT node. * *

Statements have no type information, so this is functionally the same as calling {@code * IR.exprResult(expr)}. It exists so that a pass can be consistent about always using {@code * AstFactory} to create new nodes. */ Node exprResult(Node expr) { return IR.exprResult(expr); } /** * Returns a new EMPTY node. * *

EMPTY Nodes have no type information, so this is functionally the same as calling {@code * IR.empty()}. It exists so that a pass can be consistent about always using {@code AstFactory} * to create new nodes. */ Node createEmpty() { return IR.empty(); } /** * Returns a new BLOCK node. * *

Blocks have no type information, so this is functionally the same as calling {@code * IR.block(statements)}. It exists so that a pass can be consistent about always using {@code * AstFactory} to create new nodes. */ Node createBlock(Node... statements) { return IR.block(statements); } /** * Returns a new IF node. * *

Blocks have no type information, so this is functionally the same as calling {@code * IR.ifNode(cond, then)}. It exists so that a pass can be consistent about always using {@code * AstFactory} to create new nodes. */ Node createIf(Node cond, Node then) { return IR.ifNode(cond, then); } /** * Returns a new IF node. * *

Blocks have no type information, so this is functionally the same as calling {@code * IR.ifNode(cond, then, elseNode)}. It exists so that a pass can be consistent about always using * {@code AstFactory} to create new nodes. */ Node createIf(Node cond, Node then, Node elseNode) { return IR.ifNode(cond, then, elseNode); } /** * Returns a new FOR node. * *

Blocks have no type information, so this is functionally the same as calling {@code * IR.forNode(init, cond, incr, body)}. It exists so that a pass can be consistent about always * using {@code AstFactory} to create new nodes. */ Node createFor(Node init, Node cond, Node incr, Node body) { return IR.forNode(init, cond, incr, body); } /** * Returns a new BREAK node. * *

Breaks have no type information, so this is functionally the same as calling {@code * IR.breakNode()}. It exists so that a pass can be consistent about always using {@code * AstFactory} to create new nodes. */ Node createBreak() { return IR.breakNode(); } /** * Returns a new {@code return} statement. * *

Return statements have no type information, so this is functionally the same as calling * {@code IR.return(value)}. It exists so that a pass can be consistent about always using {@code * AstFactory} to create new nodes. */ Node createReturn(Node value) { return IR.returnNode(value); } /** * Returns a new {@code yield} expression. * * @param jsType Type we expect to get back after the yield * @param value value to yield */ Node createYield(JSType jsType, Node value) { Node result = IR.yield(value); if (isAddingTypes()) { result.setJSType(checkNotNull(jsType)); } return result; } /** * Returns a new {@code await} expression. * * @param jsType Type we expect to get back after the await * @param value value to await */ Node createAwait(JSType jsType, Node value) { Node result = IR.await(value); if (isAddingTypes()) { result.setJSType(checkNotNull(jsType)); } return result; } Node createString(String value) { Node result = IR.string(value); if (isAddingTypes()) { result.setJSType(getNativeType(JSTypeNative.STRING_TYPE)); } return result; } Node createNumber(double value) { Node result = IR.number(value); if (isAddingTypes()) { result.setJSType(getNativeType(JSTypeNative.NUMBER_TYPE)); } return result; } Node createBoolean(boolean value) { Node result = value ? IR.trueNode() : IR.falseNode(); if (isAddingTypes()) { result.setJSType(getNativeType(JSTypeNative.BOOLEAN_TYPE)); } return result; } Node createNull() { Node result = IR.nullNode(); if (isAddingTypes()) { result.setJSType(getNativeType(JSTypeNative.NULL_TYPE)); } return result; } Node createVoid(Node child) { Node result = IR.voidNode(child); if (isAddingTypes()) { result.setJSType(getNativeType(JSTypeNative.VOID_TYPE)); } return result; } Node createNot(Node child) { Node result = IR.not(child); if (isAddingTypes()) { result.setJSType(getNativeType(JSTypeNative.BOOLEAN_TYPE)); } return result; } Node createThis(JSType thisType) { Node result = IR.thisNode(); if (isAddingTypes()) { result.setJSType(checkNotNull(thisType)); } return result; } Node createSuper(JSType superType) { Node result = IR.superNode(); if (isAddingTypes()) { result.setJSType(checkNotNull(superType)); } return result; } /** Creates a THIS node with the correct type for the given function node. */ Node createThisForFunction(Node functionNode) { final Node result = IR.thisNode(); if (isAddingTypes()) { result.setJSType(getTypeOfThisForFunctionNode(functionNode)); } return result; } /** Creates a SUPER node with the correct type for the given function node. */ Node createSuperForFunction(Node functionNode) { final Node result = IR.superNode(); if (isAddingTypes()) { result.setJSType(getTypeOfSuperForFunctionNode(functionNode)); } return result; } @Nullable private JSType getTypeOfThisForFunctionNode(Node functionNode) { if (isAddingTypes()) { FunctionType functionType = getFunctionType(functionNode); return checkNotNull(functionType.getTypeOfThis(), functionType); } else { return null; // not adding type information } } @Nullable private JSType getTypeOfSuperForFunctionNode(Node functionNode) { if (isAddingTypes()) { ObjectType thisType = getTypeOfThisForFunctionNode(functionNode).assertObjectType(); return checkNotNull(thisType.getSuperClassConstructor().getInstanceType(), thisType); } else { return null; // not adding type information } } private FunctionType getFunctionType(Node functionNode) { checkState(functionNode.isFunction(), "not a function: %s", functionNode); // If the function declaration was cast to a different type, we want the original type // from before the cast. final JSType typeBeforeCast = functionNode.getJSTypeBeforeCast(); final FunctionType functionType; if (typeBeforeCast != null) { functionType = typeBeforeCast.assertFunctionType(); } else { functionType = functionNode.getJSTypeRequired().assertFunctionType(); } return functionType; } /** Creates a NAME node having the type of "this" appropriate for the given function node. */ Node createThisAliasReferenceForFunction(String aliasName, Node functionNode) { final Node result = IR.name(aliasName); if (isAddingTypes()) { result.setJSType(getTypeOfThisForFunctionNode(functionNode)); } return result; } /** * Creates a statement declaring a const alias for "this" to be used in the given function node. * *

e.g. `const aliasName = this;` */ Node createThisAliasDeclarationForFunction(String aliasName, Node functionNode) { return createSingleConstNameDeclaration( aliasName, createThis(getTypeOfThisForFunctionNode(functionNode))); } /** * Creates a new `const` declaration statement for a single variable name. * *

Takes the type for the variable name from the value node. * *

e.g. `const variableName = value;` */ Node createSingleConstNameDeclaration(String variableName, Node value) { return IR.constNode(createName(variableName, value.getJSType()), value); } /** * Creates a reference to "arguments" with the type specified in externs, or unknown if the * externs for it weren't included. */ Node createArgumentsReference() { Node result = IR.name("arguments"); if (isAddingTypes()) { result.setJSType(argumentsTypeSupplier.get()); } return result; } /** * Creates a statement declaring a const alias for "arguments". * *

e.g. `const argsAlias = arguments;` */ Node createArgumentsAliasDeclaration(String aliasName) { return createSingleConstNameDeclaration(aliasName, createArgumentsReference()); } Node createName(String name, JSType type) { Node result = IR.name(name); if (isAddingTypes()) { result.setJSType(checkNotNull(type)); } return result; } Node createName(String name, JSTypeNative nativeType) { Node result = IR.name(name); if (isAddingTypes()) { result.setJSType(getNativeType(nativeType)); } return result; } Node createNameWithUnknownType(String name) { return createName(name, unknownType); } Node createName(Scope scope, String name) { Node result = IR.name(name); if (isAddingTypes()) { result.setJSType(getVarNameType(scope, name)); } return result; } Node createQName(Scope scope, String qname) { return createQName(scope, Splitter.on(".").split(qname)); } private Node createQName(Scope scope, Iterable names) { String baseName = checkNotNull(Iterables.getFirst(names, null)); Iterable propertyNames = Iterables.skip(names, 1); Node baseNameNode = createName(scope, baseName); return createGetProps(baseNameNode, propertyNames); } Node createGetProp(Node receiver, String propertyName) { Node result = IR.getprop(receiver, IR.string(propertyName)); if (isAddingTypes()) { result.setJSType(getJsTypeForProperty(receiver, propertyName)); } return result; } /** Creates a tree of nodes representing `receiver.name1.name2.etc`. */ private Node createGetProps(Node receiver, Iterable propertyNames) { Node result = receiver; for (String propertyName : propertyNames) { result = createGetProp(result, propertyName); } return result; } /** Creates a tree of nodes representing `receiver.name1.name2.etc`. */ Node createGetProps(Node receiver, String firstPropName, String... otherPropNames) { Node result = createGetProp(receiver, firstPropName); for (String propertyName : otherPropNames) { result = createGetProp(result, propertyName); } return result; } Node createGetElem(Node receiver, Node key) { Node result = IR.getelem(receiver, key); if (isAddingTypes()) { // In general we cannot assume we know the type we get from a GETELEM. // TODO(bradfordcsmith): When receiver is an Array or an Object, use the template // type here. result.setJSType(unknownType); } return result; } Node createDelProp(Node target) { Node result = IR.delprop(target); if (isAddingTypes()) { result.setJSType(getNativeType(JSTypeNative.BOOLEAN_TYPE)); } return result; } Node createStringKey(String key, Node value) { Node result = IR.stringKey(key, value); if (isAddingTypes()) { result.setJSType(value.getJSType()); } return result; } Node createComputedProperty(Node key, Node value) { Node result = IR.computedProp(key, value); if (isAddingTypes()) { result.setJSType(value.getJSType()); } return result; } Node createIn(Node left, Node right) { Node result = IR.in(left, right); if (isAddingTypes()) { result.setJSType(getNativeType(JSTypeNative.BOOLEAN_TYPE)); } return result; } Node createComma(Node left, Node right) { Node result = IR.comma(left, right); if (isAddingTypes()) { result.setJSType(right.getJSType()); } return result; } Node createCommas(Node first, Node second, Node... rest) { Node result = createComma(first, second); for (Node next : rest) { result = createComma(result, next); } return result; } Node createAnd(Node left, Node right) { Node result = IR.and(left, right); if (isAddingTypes()) { JSType leftType = checkNotNull(left.getJSType(), left); JSType rightType = checkNotNull(right.getJSType(), right); BooleanLiteralSet possibleLhsBooleanValues = leftType.getPossibleToBooleanOutcomes(); switch (possibleLhsBooleanValues) { case TRUE: // left cannot be false, so rhs will always be evaluated result.setJSType(rightType); break; case FALSE: // left cannot be true, so rhs will never be evaluated result.setJSType(leftType); break; case BOTH: // result could be the type of either the lhs or the rhs result.setJSType(leftType.getLeastSupertype(rightType)); break; default: checkState( possibleLhsBooleanValues == BooleanLiteralSet.EMPTY, "unexpected enum value: %s", possibleLhsBooleanValues); // TODO(bradfordcsmith): Should we be trying to determine whether we actually need // NO_OBJECT_TYPE or similar here? It probably doesn't matter since this code is // expected to execute only after all static type analysis has been done. result.setJSType(getNativeType(JSTypeNative.NO_TYPE)); break; } } return result; } Node createOr(Node left, Node right) { Node result = IR.or(left, right); if (isAddingTypes()) { JSType leftType = checkNotNull(left.getJSType(), left); JSType rightType = checkNotNull(right.getJSType(), right); BooleanLiteralSet possibleLhsBooleanValues = leftType.getPossibleToBooleanOutcomes(); switch (possibleLhsBooleanValues) { case TRUE: // left cannot be false, so rhs will never be evaluated result.setJSType(leftType); break; case FALSE: // left cannot be true, so rhs will always be evaluated result.setJSType(rightType); break; case BOTH: // result could be the type of either the lhs or the rhs result.setJSType(leftType.getLeastSupertype(rightType)); break; default: checkState( possibleLhsBooleanValues == BooleanLiteralSet.EMPTY, "unexpected enum value: %s", possibleLhsBooleanValues); // TODO(bradfordcsmith): Should we be trying to determine whether we actually need // NO_OBJECT_TYPE or similar here? It probably doesn't matter since this code is // expected to execute only after all static type analysis has been done. result.setJSType(getNativeType(JSTypeNative.NO_TYPE)); break; } } return result; } Node createCall(Node callee, Node... args) { Node result = NodeUtil.newCallNode(callee, args); if (isAddingTypes()) { FunctionType calleeType = JSType.toMaybeFunctionType(callee.getJSType()); // TODO(sdh): this does not handle generic functions - we'd need to unify the argument types. // checkState(calleeType == null || !calleeType.hasAnyTemplateTypes(), calleeType); // TODO(bradfordcsmith): Consider throwing an exception if calleeType is null. JSType returnType = calleeType != null ? calleeType.getReturnType() : unknownType; result.setJSType(returnType); } return result; } /** * Creates a call to Object.assign that returns the specified type. * *

Object.assign returns !Object in the externs, which can lose type information if the actual * type is known. */ Node createObjectDotAssignCall(Scope scope, JSType returnType, Node... args) { Node objAssign = createQName(scope, "Object.assign"); Node result = createCall(objAssign, args); if (isAddingTypes()) { // Make a unique function type that returns the exact type we've inferred it to be. // Object.assign in the externs just returns !Object, which loses type information. JSType objAssignType = registry.createFunctionTypeWithVarArgs( returnType, registry.getNativeType(JSTypeNative.OBJECT_TYPE), registry.createUnionType(JSTypeNative.OBJECT_TYPE, JSTypeNative.NULL_TYPE)); objAssign.setJSType(objAssignType); result.setJSType(returnType); } return result; } Node createNewNode(Node target, Node... args) { Node result = IR.newNode(target, args); if (isAddingTypes()) { JSType instanceType = target.getJSType(); if (instanceType.isFunctionType()) { instanceType = instanceType.toMaybeFunctionType().getInstanceType(); } else { instanceType = getNativeType(JSTypeNative.UNKNOWN_TYPE); } result.setJSType(instanceType); } return result; } Node createObjectGetPrototypeOfCall(Node argObjectNode) { Node objectName = createName("Object", JSTypeNative.OBJECT_FUNCTION_TYPE); Node objectGetPrototypeOf = createGetProp(objectName, "getPrototypeOf"); Node result = createCall(objectGetPrototypeOf, argObjectNode); if (isAddingTypes()) { ObjectType typeOfArgObject = argObjectNode.getJSTypeRequired().assertObjectType(); JSType returnedType = getPrototypeObjectType(typeOfArgObject); result.setJSType(returnedType); // Return type of the function needs to match that of the entire expression. getPrototypeOf // normally returns !Object. objectGetPrototypeOf.setJSType( registry.createFunctionType(returnedType, getNativeType(JSTypeNative.OBJECT_TYPE))); } return result; } ObjectType getPrototypeObjectType(ObjectType objectType) { checkNotNull(objectType); if (objectType.isUnknownType()) { // Calling getImplicitPrototype() on the unknown type returns `null`, but we want // the prototype of an unknown type to also be unknown. // TODO(bradfordcsmith): Can we fix this behavior of the unknown type? return objectType; } else { return checkNotNull(objectType.getImplicitPrototype(), "null prototype: %s", objectType); } } /** * Create a call that returns an instance of the given class type. * *

This method is intended for use in special cases, such as calling `super()` in a * constructor. */ Node createConstructorCall(@Nullable JSType classType, Node callee, Node... args) { Node result = NodeUtil.newCallNode(callee, args); if (isAddingTypes()) { checkNotNull(classType); FunctionType constructorType = checkNotNull(classType.toMaybeFunctionType()); ObjectType instanceType = checkNotNull(constructorType.getInstanceType()); result.setJSType(instanceType); } return result; } /** Creates a statement `lhs = rhs;`. */ Node createAssignStatement(Node lhs, Node rhs) { return exprResult(createAssign(lhs, rhs)); } /** Creates an assignment expression `lhs = rhs` */ Node createAssign(Node lhs, Node rhs) { Node result = IR.assign(lhs, rhs); if (isAddingTypes()) { result.setJSType(rhs.getJSType()); } return result; } /** * Creates an object-literal with zero or more elements, `{}`. * *

The type of the literal, if assigned, may be a supertype of the known properties. */ Node createObjectLit(Node... elements) { Node result = IR.objectlit(elements); if (isAddingTypes()) { result.setJSType(registry.createAnonymousObjectType(null)); } return result; } /** Creates an empty function `function() {}` */ Node createEmptyFunction(JSType type) { Node result = NodeUtil.emptyFunction(); if (isAddingTypes()) { checkNotNull(type); checkArgument(type.isFunctionType(), type); result.setJSType(checkNotNull(type)); } return result; } /** Creates an empty function `function*() {}` */ Node createEmptyGeneratorFunction(JSType type) { Node result = NodeUtil.emptyFunction(); result.setIsGeneratorFunction(true); if (isAddingTypes()) { checkNotNull(type); checkArgument(type.isFunctionType(), type); result.setJSType(checkNotNull(type)); } return result; } /** * Creates a function `function name(paramList) { body }` * * @param name STRING node - empty string if no name * @param paramList PARAM_LIST node * @param body BLOCK node * @param type type to apply to the function itself */ Node createFunction(String name, Node paramList, Node body, JSType type) { Node nameNode = createName(name, type); Node result = IR.function(nameNode, paramList, body); if (isAddingTypes()) { checkArgument(type.isFunctionType(), type); result.setJSType(type); } return result; } Node createZeroArgFunction(String name, Node body, @Nullable JSType returnType) { FunctionType functionType = isAddingTypes() ? registry.createFunctionType(returnType) : null; return createFunction(name, IR.paramList(), body, functionType); } Node createZeroArgGeneratorFunction(String name, Node body, @Nullable JSType returnType) { Node result = createZeroArgFunction(name, body, returnType); result.setIsGeneratorFunction(true); return result; } Node createZeroArgArrowFunctionForExpression(Node expression) { Node result = IR.arrowFunction(IR.name(""), IR.paramList(), expression); if (isAddingTypes()) { // It feels like we should be adding type-of-this here, but it should remain unknown, // because you're allowed to supply any kind of value of `this` when calling an arrow // function. It will just be ignored in favor of the `this` in the scope where the // arrow was defined. FunctionType functionType = FunctionType.builder(registry) .withReturnType(expression.getJSTypeRequired()) .withParamsNode(IR.paramList()) .build(); result.setJSType(functionType); } return result; } Node createMemberFunctionDef(String name, Node function) { // A function used for a member function definition must have an empty name, // because the name string goes on the MEMBER_FUNCTION_DEF node. checkArgument(function.getFirstChild().getString().isEmpty(), function); Node result = IR.memberFunctionDef(name, function); if (isAddingTypes()) { // member function definition must share the type of the function that implements it result.setJSType(function.getJSType()); } return result; } Node createSheq(Node expr1, Node expr2) { Node result = IR.sheq(expr1, expr2); if (isAddingTypes()) { result.setJSType(getNativeType(JSTypeNative.BOOLEAN_TYPE)); } return result; } Node createHook(Node condition, Node expr1, Node expr2) { Node result = IR.hook(condition, expr1, expr2); if (isAddingTypes()) { result.setJSType(registry.createUnionType(expr1.getJSType(), expr2.getJSType())); } return result; } Node createArraylit(Node... elements) { Node result = IR.arraylit(elements); if (isAddingTypes()) { result.setJSType( registry.createTemplatizedType( registry.getNativeObjectType(JSTypeNative.ARRAY_TYPE), // TODO(nickreid): Use a reasonable template type. Remeber to consider SPREAD. getNativeType(JSTypeNative.UNKNOWN_TYPE))); } return result; } Node createJSCompMakeIteratorCall(Node iterable, Scope scope) { String function = "makeIterator"; Node makeIteratorName = createQName(scope, "$jscomp." + function); // Since createCall (currently) doesn't handle templated functions, fill in the template types // of makeIteratorName manually. if (isAddingTypes() && !makeIteratorName.getJSType().isUnknownType()) { // if makeIteratorName has the unknown type, we must have not injected the required runtime // libraries - hopefully because this is in a test using NonInjectingCompiler. // e.g get `number` from `Iterable` JSType iterableType = iterable .getJSType() .getTemplateTypeMap() .getResolvedTemplateType(registry.getIterableTemplate()); JSType makeIteratorType = makeIteratorName.getJSType(); // e.g. replace // function(Iterable): Iterator // with // function(Iterable): Iterator makeIteratorName.setJSType(replaceTemplate(makeIteratorType, ImmutableList.of(iterableType))); } return createCall(makeIteratorName, iterable); } Node createJscompArrayFromIteratorCall(Node iterator, Scope scope) { String function = "arrayFromIterator"; Node makeIteratorName = createQName(scope, "$jscomp." + function); // Since createCall (currently) doesn't handle templated functions, fill in the template types // of makeIteratorName manually. if (isAddingTypes() && !makeIteratorName.getJSType().isUnknownType()) { // if makeIteratorName has the unknown type, we must have not injected the required runtime // libraries - hopefully because this is in a test using NonInjectingCompiler. JSType iterableType = iterator .getJSType() .getTemplateTypeMap() .getResolvedTemplateType(registry.getIteratorValueTemplate()); JSType makeIteratorType = makeIteratorName.getJSType(); // e.g. replace // function(Iterator): Array // with // function(Iterator): Array makeIteratorName.setJSType(replaceTemplate(makeIteratorType, ImmutableList.of(iterableType))); } return createCall(makeIteratorName, iterator); } /** * Given an iterable like {@code rhs} in * *

{@code
   * for await (lhs of rhs) { block(); }
   * }
* *

returns a call node for the {@code rhs} wrapped in a {@code $jscomp.makeAsyncIterator} call. * *

{@code
   * $jscomp.makeAsyncIterator(rhs)
   * }
*/ Node createJSCompMakeAsyncIteratorCall(Node iterable, Scope scope) { Node makeIteratorAsyncName = createQName(scope, "$jscomp.makeAsyncIterator"); // Since createCall (currently) doesn't handle templated functions, fill in the template types // of makeIteratorName manually. if (isAddingTypes() && !makeIteratorAsyncName.getJSType().isUnknownType()) { // if makeIteratorName has the unknown type, we must have not injected the required runtime // libraries - hopefully because this is in a test using NonInjectingCompiler. // e.g get `number` from `AsyncIterable` JSType asyncIterableType = JsIterables.maybeBoxIterableOrAsyncIterable(iterable.getJSType(), registry) .orElse(unknownType); JSType makeAsyncIteratorType = makeIteratorAsyncName.getJSType(); // e.g. replace // function(AsyncIterable): AsyncIterator // with // function(AsyncIterable): AsyncIterator makeIteratorAsyncName.setJSType( replaceTemplate(makeAsyncIteratorType, ImmutableList.of(asyncIterableType))); } return createCall(makeIteratorAsyncName, iterable); } private JSType replaceTemplate(JSType templatedType, ImmutableList templateTypes) { TemplateTypeMap typeMap = registry .getEmptyTemplateTypeMap() .copyWithExtension(templatedType.getTemplateTypeMap().getTemplateKeys(), templateTypes); TemplateTypeReplacer replacer = TemplateTypeReplacer.forPartialReplacement(registry, typeMap); return templatedType.visit(replacer); } /** * Creates a reference to $jscomp.AsyncGeneratorWrapper with the template filled in to match the * original function. * * @param originalFunctionType the type of the async generator function that needs transpilation */ Node createAsyncGeneratorWrapperReference(JSType originalFunctionType, Scope scope) { Node ctor = createQName(scope, "$jscomp.AsyncGeneratorWrapper"); if (isAddingTypes() && !ctor.getJSType().isUnknownType()) { // if ctor has the unknown type, we must have not injected the required runtime // libraries - hopefully because this is in a test using NonInjectingCompiler. // e.g get `number` from `AsyncIterable` JSType yieldedType = originalFunctionType .toMaybeFunctionType() .getReturnType() .getTemplateTypeMap() .getResolvedTemplateType(registry.getAsyncIterableTemplate()); // e.g. replace // AsyncGeneratorWrapper // with // AsyncGeneratorWrapper ctor.setJSType(replaceTemplate(ctor.getJSType(), ImmutableList.of(yieldedType))); } return ctor; } /** * Creates an empty generator function with the correct return type to be an argument to * $jscomp.AsyncGeneratorWrapper. * * @param asyncGeneratorWrapperType the specific type of the $jscomp.AsyncGeneratorWrapper with * its template filled in. Should be the type on the node returned from * createAsyncGeneratorWrapperReference. */ Node createEmptyAsyncGeneratorWrapperArgument(JSType asyncGeneratorWrapperType) { JSType generatorType = null; if (isAddingTypes()) { if (asyncGeneratorWrapperType.isUnknownType()) { // Not injecting libraries? generatorType = registry.createFunctionType( replaceTemplate( getNativeType(JSTypeNative.GENERATOR_TYPE), ImmutableList.of(unknownType))); } else { // Generator<$jscomp.AsyncGeneratorWrapper$ActionRecord> JSType innerFunctionReturnType = Iterables.getOnlyElement( asyncGeneratorWrapperType.toMaybeFunctionType().getParameterTypes()); generatorType = registry.createFunctionType(innerFunctionReturnType); } } return createEmptyGeneratorFunction(generatorType); } Node createJscompAsyncExecutePromiseGeneratorFunctionCall(Scope scope, Node generatorFunction) { String function = "asyncExecutePromiseGeneratorFunction"; Node jscompDotAsyncExecutePromiseGeneratorFunction = createQName(scope, "$jscomp." + function); // TODO(bradfordcsmith): Maybe update the type to be more specific // Currently this method expects `function(): !Generator` and returns `Promise`. // Since we propagate type information only if type checking has already run, // these unknowns probably don't matter, but we should be able to be more specific with the // return type at least. return createCall(jscompDotAsyncExecutePromiseGeneratorFunction, generatorFunction); } private JSType getNativeType(JSTypeNative nativeType) { checkNotNull(registry, "registry is null"); return checkNotNull( registry.getNativeType(nativeType), "native type not found: %s", nativeType); } /** * Look up the correct type for the given name in the given scope. * *

Returns the unknown type if no type can be found */ private JSType getVarNameType(Scope scope, String name) { Var var = scope.getVar(name); JSType type = null; if (var != null) { Node nameDefinitionNode = var.getNode(); if (nameDefinitionNode != null) { type = nameDefinitionNode.getJSType(); } } if (type == null) { // TODO(bradfordcsmith): Consider throwing an error if the type cannot be found. type = unknownType; } return type; } private JSType getJsTypeForProperty(Node receiver, String propertyName) { // NOTE: we use both findPropertyType and getPropertyType because they are subtly // different: findPropertyType works on JSType, autoboxing scalars and joining unions, // but it returns null if the type is not found and does not handle dynamic types of // Function.prototype.call and .apply; whereas getPropertyType does not autobox nor // iterate over unions, but it does synthesize the function properties correctly, and // it returns unknown instead of null if the property is missing. JSType getpropType = null; JSType receiverJSType = receiver.getJSType(); if (receiverJSType != null) { getpropType = receiverJSType.findPropertyType(propertyName); if (getpropType == null) { ObjectType receiverObjectType = ObjectType.cast(receiverJSType.autobox()); getpropType = receiverObjectType == null ? unknownType : receiverObjectType.getPropertyType(propertyName); } } if (getpropType == null) { getpropType = unknownType; } // TODO(bradfordcsmith): Special case $jscomp.global until we annotate its type correctly. if (getpropType.isUnknownType() && propertyName.equals("global") && receiver.matchesName("$jscomp")) { getpropType = getNativeType(JSTypeNative.GLOBAL_THIS); } return getpropType; } }





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