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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 2009 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 com.google.common.annotations.VisibleForTesting;
import com.google.common.base.Preconditions;
import com.google.common.base.Supplier;
import com.google.common.collect.ImmutableList;
import com.google.common.collect.ImmutableMap;
import com.google.errorprone.annotations.MustBeClosed;
import com.google.javascript.jscomp.deps.ModuleLoader;
import com.google.javascript.jscomp.diagnostic.LogFile;
import com.google.javascript.jscomp.modules.ModuleMap;
import com.google.javascript.jscomp.modules.ModuleMetadataMap;
import com.google.javascript.jscomp.parsing.Config;
import com.google.javascript.jscomp.parsing.parser.FeatureSet;
import com.google.javascript.jscomp.parsing.parser.trees.Comment;
import com.google.javascript.jscomp.type.ReverseAbstractInterpreter;
import com.google.javascript.rhino.ErrorReporter;
import com.google.javascript.rhino.InputId;
import com.google.javascript.rhino.Node;
import com.google.javascript.rhino.jstype.JSTypeRegistry;
import java.io.Serializable;
import java.nio.file.Path;
import java.nio.file.Paths;
import java.util.HashMap;
import java.util.List;
import java.util.Map;
import java.util.Set;
import javax.annotation.Nullable;

/**
 * An abstract compiler, to help remove the circular dependency of passes on JSCompiler.
 *
 * 

This is an abstract class, so that we can make the methods package-private. */ public abstract class AbstractCompiler implements SourceExcerptProvider, CompilerInputProvider { static final DiagnosticType READ_ERROR = DiagnosticType.error( "JSC_READ_ERROR", "Cannot read file {0}: {1}"); protected Map annotationMap = new HashMap<>(); /** Will be called before each pass runs. */ abstract void beforePass(String passName); /** * Will be called after each pass finishes. */ abstract void afterPass(String passName); private LifeCycleStage stage = LifeCycleStage.RAW; // TODO(nicksantos): Decide if all of these are really necessary. // Many of them are just accessors that should be passed to the // CompilerPass's constructor. /** * Looks up an input (possibly an externs input) by input id. * May return null. */ public abstract CompilerInput getInput(InputId inputId); /** Looks up a source file by name. May return null. */ @Nullable abstract SourceFile getSourceFileByName(String sourceName); @Nullable abstract Node getScriptNode(String filename); /** Gets the module graph. */ @Nullable abstract JSModuleGraph getModuleGraph(); /** * Gets the inputs in the order in which they are being processed. Only for use by {@code * AbstractCompilerRunner}. */ abstract Iterable getInputsInOrder(); /** * Gets the total number of inputs. * *

This can be useful as a guide for the initial allocated size for data structures. */ abstract int getNumberOfInputs(); // // Intermediate state and results produced and needed by particular passes. // TODO(rluble): move these into the general structure for keeping state between pass runs. // /** Adds exported names to keep track. */ public abstract void addExportedNames(Set exportedVariableNames); /** Gets the names that have been exported. */ public abstract Set getExportedNames(); /** Sets the variable renaming map */ public abstract void setVariableMap(VariableMap variableMap); /** Sets the property renaming map */ public abstract void setPropertyMap(VariableMap propertyMap); /** Sets the string replacement map */ public abstract void setStringMap(VariableMap stringMap); /** Sets the css names found during compilation. */ public abstract void setCssNames(Map newCssNames); /** Sets the id generator for cross-module motion. */ public abstract void setIdGeneratorMap(String serializedIdMappings); /** Gets the id generator for cross-module motion. */ public abstract IdGenerator getCrossModuleIdGenerator(); /** Sets the naming map for anonymous functions */ public abstract void setAnonymousFunctionNameMap(VariableMap functionMap); // // End of intermediate state needed by passes. // /** * Sets the type-checking pass that ran most recently. */ abstract void setTypeCheckingHasRun(boolean hasRun); /** Gets the type-checking pass that ran most recently. */ abstract boolean hasTypeCheckingRun(); /** * Gets a central registry of type information from the compiled JS. */ public abstract JSTypeRegistry getTypeRegistry(); public abstract void clearJSTypeRegistry(); abstract void forwardDeclareType(String typeName); /** * Gets a memoized scope creator with type information. Only used by jsdev. */ abstract ScopeCreator getTypedScopeCreator(); /** * Gets the top scope. */ public abstract TypedScope getTopScope(); /** * Gets a memoized scope creator without type information, used by the checks and optimization * passes to avoid continuously recreating the entire scope. */ abstract IncrementalScopeCreator getScopeCreator(); /** * Stores a memoized scope creator without type information, used by the checks and optimization * passes to avoid continuously recreating the entire scope. */ abstract void putScopeCreator(IncrementalScopeCreator creator); /** * Report an error or warning. */ public abstract void report(JSError error); /** * Report an internal error. */ abstract void throwInternalError(String msg, Throwable cause); /** * Gets the current coding convention. */ public abstract CodingConvention getCodingConvention(); /** * Passes that make modifications in a scope that is different than the Compiler.currentScope use * this (eg, InlineVariables and many others) */ public abstract void reportChangeToEnclosingScope(Node n); /** * Mark modifications in a scope that is different than the Compiler.currentScope use this (eg, * InlineVariables and many others) */ public abstract void reportChangeToChangeScope(Node changeScopeRoot); /** * Mark a specific function node as known to be deleted. Is part of having accurate change * tracking which is necessary to streamline optimizations. */ abstract void reportFunctionDeleted(Node node); /** * Sets the CssRenamingMap. */ abstract void setCssRenamingMap(CssRenamingMap map); /** * Gets the CssRenamingMap. */ abstract CssRenamingMap getCssRenamingMap(); /** * Gets a suitable SCRIPT node to serve as a parent for code insertion. If * {@code module} contains any inputs, the returned node will be the SCRIPT * node corresponding to its first input. If {@code module} is empty, on the * other hand, then the returned node will be the first SCRIPT node in a * non-empty module that {@code module} depends on (the deepest one possible). * * @param module A module. If null, will return the first SCRIPT node of all * modules. * @return A SCRIPT node (never null). */ abstract Node getNodeForCodeInsertion(@Nullable JSModule module); /** * Only used by passes in the old type checker. */ abstract TypeValidator getTypeValidator(); /** Gets the central registry of type violations. */ public abstract Iterable getTypeMismatches(); /** * Gets all types that are used implicitly as a matching interface type. These are recorded as * TypeMismatchs only for convenience */ public abstract Iterable getImplicitInterfaceUses(); abstract void setExternExports(String externExports); /** * Parses code for injecting. */ abstract Node parseSyntheticCode(String code); /** * Parses code for injecting, and associate it with a given source file. */ abstract Node parseSyntheticCode(String filename, String code); /** * Parses code for testing. */ @VisibleForTesting abstract Node parseTestCode(String code); /** Parses code for testing. */ @VisibleForTesting abstract Node parseTestCode(ImmutableList code); /** * Prints a node to source code. */ public abstract String toSource(); /** * Prints a node to source code. */ public abstract String toSource(Node root); /** * Gets a default error reporter for injecting into Rhino. */ abstract ErrorReporter getDefaultErrorReporter(); /** * Get an interpreter for type analysis. */ public abstract ReverseAbstractInterpreter getReverseAbstractInterpreter(); /** * @return The current life-cycle stage of the AST we're working on. */ LifeCycleStage getLifeCycleStage() { return stage; } private static final String FILL_FILE_SUFFIX = "$fillFile"; /** Empty modules get an empty "fill" file, so that we can move code into an empty module. */ static String createFillFileName(String moduleName) { return moduleName + FILL_FILE_SUFFIX; } /** Returns whether a file name was created by {@link createFillFileName}. */ public static boolean isFillFileName(String fileName) { return fileName.endsWith(FILL_FILE_SUFFIX); } /** * Generates unique String Ids when requested via a compiler instance. * *

This supplier provides Ids that are deterministic and unique across all input files given to * the compiler. The generated ID format is: uniqueId = "fileHashCode$counterForThisFile" */ abstract UniqueIdSupplier getUniqueIdSupplier(); /** * Generates unique ids. * * @deprecated because the generated names during transpilation are not unique across all input * files. Use the new supplier by calling {@code getUniqueIdSupplier()}. */ @Deprecated abstract Supplier getUniqueNameIdSupplier(); /** * @return Whether any errors have been encountered that * should stop the compilation process. */ abstract boolean hasHaltingErrors(); /** * Register a listener for code change events. */ abstract void addChangeHandler(CodeChangeHandler handler); /** * Remove a listener for code change events. */ abstract void removeChangeHandler(CodeChangeHandler handler); /** Register a provider for some type of index. */ abstract void addIndexProvider(IndexProvider indexProvider); /** * Returns, from a provider, the desired index of type T, otherwise null if no provider is * registered for the given type. */ abstract T getIndex(Class type); /** A monotonically increasing value to identify a change */ abstract int getChangeStamp(); /** * An accumulation of changed scope nodes since the last time the given pass was run. A returned * empty list means no scope nodes have changed since the last run and a returned null means this * is the first time the pass has run. */ abstract List getChangedScopeNodesForPass(String passName); /** * An accumulation of deleted scope nodes since the last time the given pass was run. A returned * null or empty list means no scope nodes have been deleted since the last run or this is the * first time the pass has run. */ abstract List getDeletedScopeNodesForPass(String passName); /** Called to indicate that the current change stamp has been used */ abstract void incrementChangeStamp(); /** Returns the root of the source tree, ignoring externs */ abstract Node getJsRoot(); /** True iff a function changed since the last time a pass was run */ abstract boolean hasScopeChanged(Node n); /** * Represents the different contexts for which the compiler could have * distinct configurations. */ static enum ConfigContext { /** * Normal JavaScript. */ DEFAULT, /** * Externs files. */ EXTERNS } /** * Returns the parser configuration for the specified context. */ abstract Config getParserConfig(ConfigContext context); /** * Normalizes the types of AST nodes in the given tree, and * annotates any nodes to which the coding convention applies so that passes * can read the annotations instead of using the coding convention. */ abstract void prepareAst(Node root); /** * Gets the error manager. */ public abstract ErrorManager getErrorManager(); /** * Set the current life-cycle state. */ void setLifeCycleStage(LifeCycleStage stage) { this.stage = stage; } /** * Are the nodes equal for the purpose of inlining? * If type aware optimizations are on, type equality is checked. */ abstract boolean areNodesEqualForInlining(Node n1, Node n2); /** * Set if RegExp global properties are used. * @param references Whether there are references to the RegExp global object * properties. */ abstract void setHasRegExpGlobalReferences(boolean references); /** * @return Whether the AST contains references to the RegExp global object * properties. */ abstract boolean hasRegExpGlobalReferences(); /** * @return The error level the given error object will be reported at. */ abstract CheckLevel getErrorLevel(JSError error); static enum LifeCycleStage implements Serializable { RAW, // See constraints put on the tree by Normalize.java NORMALIZED, // The normalize pass has put constraints on the tree, // but variables and properties have been renamed so // coding conventions no longer apply. NORMALIZED_OBFUSCATED; boolean isNormalized() { return this == NORMALIZED || this == NORMALIZED_OBFUSCATED; } boolean isNormalizedUnobfuscated() { return this == NORMALIZED; } boolean isNormalizedObfuscated() { return this == NORMALIZED_OBFUSCATED; } } /** * Runs a given compiler-pass by calling its {@code process()} method. * @param pass The pass to be run. */ abstract void process(CompilerPass pass); /** * Returns the root node of the AST, which includes both externs and source. */ public abstract Node getRoot(); abstract CompilerOptions getOptions(); /** * The set of features defined by the input language mode that have not (yet) been transpiled * away. * *

This is **not** the exact set of all features currently in the AST, but rather an improper * super set. This set starts out as the set of features from the language input mode specified by * the options, which is verified to be a super set of what appears in the input code (if the * input code contains a feature outside the language input mode it is an error). As the compiler * transpiles code any features that are transpiled away from the AST are removed from this set. * *

The feature set is computed this way, rather than using the detected features in the AST, so * that the set of passes that run is determined purely by input flags. Otherwise, introducing a * previously unused feature in any of the transitive deps of compilation target could effect the * build behaviour. */ abstract FeatureSet getFeatureSet(); abstract void setFeatureSet(FeatureSet fs); // TODO(bashir) It would be good to extract a single dumb data object with // only getters and setters that keeps all global information we keep for a // compiler instance. Then move some of the functions of this class there. /** * Updates the list of references for variables in global scope. * * @param refMapPatch Maps each variable to all of its references; may contain * references collected from the whole AST or only a SCRIPT sub-tree. * @param collectionRoot The root of sub-tree in which reference collection * has been done. This should either be a SCRIPT node (if collection is * done on a single file) or it is assumed that collection is on full AST. */ abstract void updateGlobalVarReferences(Map refMapPatch, Node collectionRoot); /** * This can be used to get the list of all references to all global variables * based on all previous calls to {@code updateGlobalVarReferences}. * * @return The reference collection map associated to global scope variable. */ abstract GlobalVarReferenceMap getGlobalVarReferences(); /** * @return a CompilerInput that can be modified to add additional extern * definitions to the beginning of the externs AST */ abstract CompilerInput getSynthesizedExternsInput(); /** * @return a CompilerInput that can be modified to add additional extern * definitions to the end of the externs AST */ abstract CompilerInput getSynthesizedExternsInputAtEnd(); /** * @return a number in [0,1] range indicating an approximate progress of the * last compile. Note this should only be used as a hint and no assumptions * should be made on accuracy, even a completed compile may choose not to set * this to 1.0 at the end. */ public abstract double getProgress(); /** * Gets the last pass name set by setProgress. */ abstract String getLastPassName(); /** * Sets the progress percentage as well as the name of the last pass that * ran (if available). * @param progress A percentage expressed as a double in the range [0, 1]. * Use -1 if you just want to set the last pass name. */ abstract void setProgress(double progress, @Nullable String lastPassName); /** * The subdir js/ contains libraries of code that we inject * at compile-time only if requested by this function. * * Notice that these libraries will almost always create global symbols. * * @param resourceName The name of the library. For example, if "base" is * is specified, then we load js/base.js * @param force Inject the library even if compiler options say not to. * @return The last node of the most-recently-injected runtime library. * If new code was injected, this will be the last expression node of the * library. If the caller needs to add additional code, they should add * it as the next sibling of this node. If no runtime libraries have been * injected, then null is returned. */ abstract Node ensureLibraryInjected(String resourceName, boolean force); /** * Sets the names of the properties defined in externs. * @param externProperties The set of property names defined in externs. */ abstract void setExternProperties(Set externProperties); /** * Gets the names of the properties defined in externs or null if * GatherExternProperties pass was not run yet. */ abstract Set getExternProperties(); /** * Adds a {@link SourceMapInput} for the given {@code sourceFileName}, to be used for error * reporting and source map combining. */ public abstract void addInputSourceMap(String name, SourceMapInput sourceMap); abstract void addComments(String filename, List comments); /** * Returns a summary an entry for every property name found in the AST with a getter and / or * setter defined. * *

Property names for which there are no getters or setters will not be in the map. */ abstract AccessorSummary getAccessorSummary(); /** Sets the summary of properties with getters and setters. */ abstract void setAccessorSummary(AccessorSummary summary); /** * Returns all the comments from the given file. */ abstract List getComments(String filename); /** * Stores a map of default @define values. These values * can be overridden by values specifically set in the CompilerOptions. */ abstract void setDefaultDefineValues(ImmutableMap values); /** * Gets a map of default @define values. These values * can be overridden by values specifically set in the CompilerOptions. */ abstract ImmutableMap getDefaultDefineValues(); /** * Gets the module loader. */ abstract ModuleLoader getModuleLoader(); /** Lookup the type of a module from its name. */ abstract CompilerInput.ModuleType getModuleTypeByName(String moduleName); /** * Sets an annotation for the given key. * * @param key the annotation key * @param object the object to store as the annotation */ void setAnnotation(String key, Object object) { checkArgument(object != null, "The stored annotation value cannot be null."); Preconditions.checkArgument( !annotationMap.containsKey(key), "Cannot overwrite the existing annotation '%s'.", key); annotationMap.put(key, object); } /** * Gets the annotation for the given key. * * @param key the annotation key * @return the annotation object for the given key if it has been set, or null */ @Nullable Object getAnnotation(String key) { return annotationMap.get(key); } /** * Returns a new AstFactory that will add type information to the nodes it creates if and only if * type type checking has already happened. */ public AstFactory createAstFactory() { return hasTypeCheckingRun() ? AstFactory.createFactoryWithTypes(getTypeRegistry()) : AstFactory.createFactoryWithoutTypes(); } /** * Returns a new AstAnalyzer configured correctly to answer questions about Nodes in the AST * currently being compiled. */ public AstAnalyzer getAstAnalyzer() { return new AstAnalyzer(this, getOptions().getAssumeGettersArePure()); } public abstract ModuleMetadataMap getModuleMetadataMap(); public abstract void setModuleMetadataMap(ModuleMetadataMap moduleMetadataMap); public abstract ModuleMap getModuleMap(); public abstract void setModuleMap(ModuleMap moduleMap); @MustBeClosed public LogFile createOrReopenLog(Class owner, String name) { @Nullable Path dir = getOptions().getDebugLogDirectory(); if (dir == null) { return LogFile.createNoOp(); } Path file = Paths.get(dir.toString(), owner.getSimpleName(), name); return LogFile.createOrReopen(file); } /** Returns the InputId of the synthetic code input (even if it is not initialized yet). */ abstract InputId getSyntheticCodeInputId(); /** * Adds a synthetic script to the front of the AST * *

Useful to allow inserting code into the global scope, earlier than any of the user-provided * code, in the case that the first user-provided input is a module. */ abstract void initializeSyntheticCodeInput(); /** Removes the script added by {@link #initializeSyntheticCodeInput} */ abstract void removeSyntheticCodeInput(); }





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