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

import com.google.common.annotations.GwtIncompatible;
import com.google.common.annotations.VisibleForTesting;
import com.google.common.base.Joiner;
import com.google.common.base.Preconditions;
import com.google.common.collect.ImmutableList;
import com.google.common.collect.Iterables;
import com.google.common.collect.LinkedListMultimap;
import com.google.common.collect.ListMultimap;
import com.google.common.collect.Ordering;
import com.google.gson.JsonArray;
import com.google.gson.JsonObject;
import com.google.gson.JsonPrimitive;
import com.google.javascript.jscomp.deps.Es6SortedDependencies;
import com.google.javascript.jscomp.deps.SortedDependencies;
import com.google.javascript.jscomp.deps.SortedDependencies.MissingProvideException;
import com.google.javascript.jscomp.graph.LinkedDirectedGraph;
import com.google.javascript.jscomp.parsing.parser.util.format.SimpleFormat;
import com.google.javascript.rhino.StaticSourceFile.SourceKind;
import java.io.Serializable;
import java.util.ArrayList;
import java.util.Arrays;
import java.util.BitSet;
import java.util.Collection;
import java.util.HashMap;
import java.util.HashSet;
import java.util.IdentityHashMap;
import java.util.Iterator;
import java.util.LinkedHashSet;
import java.util.List;
import java.util.Map;
import java.util.Set;
import javax.annotation.Nullable;

/**
 * A {@link JSModule} dependency graph that assigns a depth to each module and can answer
 * depth-related queries about them. For the purposes of this class, a module's depth is defined as
 * the number of hops in the longest (non cyclic) path from the module to a module with no
 * dependencies.
 */
public final class JSModuleGraph implements Serializable {

  static final DiagnosticType WEAK_FILE_REACHABLE_FROM_ENTRY_POINT_ERROR =
      DiagnosticType.error(
          "JSC_WEAK_FILE_REACHABLE_FROM_ENTRY_POINT_ERROR",
          "File strongly reachable from an entry point must not be weak: {0}");

  static final DiagnosticType EXPLICIT_WEAK_ENTRY_POINT_ERROR =
      DiagnosticType.error(
          "JSC_EXPLICIT_WEAK_ENTRY_POINT_ERROR",
          "Explicit entry point input must not be weak: {0}");

  static final DiagnosticType IMPLICIT_WEAK_ENTRY_POINT_ERROR =
      DiagnosticType.warning(
          "JSC_IMPLICIT_WEAK_ENTRY_POINT_ERROR",
          "Implicit entry point input should not be weak: {0}");

  private final JSModule[] modules;

  /**
   * selfPlusTransitiveDeps[i] = indices of all modules that modules[i] depends on, including
   * itself.
   */
  private final BitSet[] selfPlusTransitiveDeps;

  /**
   * subtreeSize[i] = Number of modules that transitively depend on modules[i], including itself.
   */
  private final int[] subtreeSize;

  /**
   * Lists of modules at each depth. modulesByDepth.get(3) is a list of the modules at
   * depth 3, for example.
   */
  private final List> modulesByDepth;

  /**
   * dependencyMap is a cache of dependencies that makes the dependsOn function faster. Each map
   * entry associates a starting JSModule with the set of JSModules that are transitively dependent
   * on the starting module.
   *
   * 

If the cache returns null, then the entry hasn't been filled in for that module. * *

NOTE: JSModule has identity semantics so this map implementation is safe */ private final Map> dependencyMap = new IdentityHashMap<>(); /** Creates a module graph from a list of modules in dependency order. */ public JSModuleGraph(JSModule[] modulesInDepOrder) { this(Arrays.asList(modulesInDepOrder)); } /** Creates a module graph from a list of modules in dependency order. */ public JSModuleGraph(List modulesInDepOrder) { Preconditions.checkState(!modulesInDepOrder.isEmpty()); modulesInDepOrder = makeWeakModule(modulesInDepOrder); modules = new JSModule[modulesInDepOrder.size()]; // n = number of modules // Populate modules O(n) for (int moduleIndex = 0; moduleIndex < modules.length; ++moduleIndex) { final JSModule module = modulesInDepOrder.get(moduleIndex); checkState(module.getIndex() == -1, "Module index already set: %s", module); module.setIndex(moduleIndex); modules[moduleIndex] = module; } // Determine depth for all modules. // m = number of edges in the graph // O(n*m) modulesByDepth = initModulesByDepth(); // Determine transitive deps for all modules. // O(n*m * log(n)) (probably a bit better than that) selfPlusTransitiveDeps = initTransitiveDepsBitSets(); // O(n*m) subtreeSize = initSubtreeSize(); // Move all sources marked as weak by outside sources (e.g. flags) into the weak module. moveMarkedWeakSources(getModuleByName(JSModule.WEAK_MODULE_NAME), getAllInputs()); } private List> initModulesByDepth() { final List> tmpModulesByDepth = new ArrayList<>(); for (int moduleIndex = 0; moduleIndex < modules.length; ++moduleIndex) { final JSModule module = modules[moduleIndex]; checkState(module.getDepth() == -1, "Module depth already set: %s", module); int depth = 0; for (JSModule dep : module.getDependencies()) { int depDepth = dep.getDepth(); if (depDepth < 0) { throw new ModuleDependenceException(SimpleFormat.format( "Modules not in dependency order: %s preceded %s", module.getName(), dep.getName()), module, dep); } depth = Math.max(depth, depDepth + 1); } module.setDepth(depth); if (depth == tmpModulesByDepth.size()) { tmpModulesByDepth.add(new ArrayList()); } tmpModulesByDepth.get(depth).add(module); } return tmpModulesByDepth; } /** * If a weak module doesn't already exist, creates a weak module depending on every other module. * *

Does not move any sources into the weak module. * * @return a new list of modules that includes the weak module, if it was newly created, or the * same list if the weak module already existed * @throws IllegalStateException if a weak module already exists but doesn't fulfill the above * conditions */ private List makeWeakModule(List modulesInDepOrder) { boolean hasWeakModule = false; for (JSModule module : modulesInDepOrder) { if (module.getName().equals(JSModule.WEAK_MODULE_NAME)) { hasWeakModule = true; Set allOtherModules = new HashSet<>(modulesInDepOrder); allOtherModules.remove(module); checkState( module.getAllDependencies().containsAll(allOtherModules), "A weak module already exists but it does not depend on every other module."); checkState( module.getAllDependencies().size() == allOtherModules.size(), "The weak module cannot have extra dependencies."); break; } } if (hasWeakModule) { // All weak files (and only weak files) should be in the weak module. List misplacedWeakFiles = new ArrayList<>(); List misplacedStrongFiles = new ArrayList<>(); for (JSModule module : modulesInDepOrder) { boolean isWeakModule = module.getName().equals(JSModule.WEAK_MODULE_NAME); for (CompilerInput input : module.getInputs()) { if (isWeakModule && !input.getSourceFile().isWeak()) { misplacedStrongFiles.add(input.getSourceFile().getName()); } else if (!isWeakModule && input.getSourceFile().isWeak()) { misplacedWeakFiles.add( input.getSourceFile().getName() + " (in module " + module.getName() + ")"); } } } if (!(misplacedStrongFiles.isEmpty() && misplacedWeakFiles.isEmpty())) { StringBuilder sb = new StringBuilder("A weak module exists but some sources are misplaced."); if (!misplacedStrongFiles.isEmpty()) { sb.append("\nFound these strong sources in the weak module:\n ") .append(Joiner.on("\n ").join(misplacedStrongFiles)); } if (!misplacedWeakFiles.isEmpty()) { sb.append("\nFound these weak sources in other modules:\n ") .append(Joiner.on("\n ").join(misplacedWeakFiles)); } throw new IllegalStateException(sb.toString()); } } else { JSModule weakModule = new JSModule(JSModule.WEAK_MODULE_NAME); for (JSModule module : modulesInDepOrder) { weakModule.addDependency(module); } modulesInDepOrder = new ArrayList<>(modulesInDepOrder); modulesInDepOrder.add(weakModule); } return modulesInDepOrder; } private BitSet[] initTransitiveDepsBitSets() { BitSet[] array = new BitSet[modules.length]; for (int moduleIndex = 0; moduleIndex < modules.length; ++moduleIndex) { final JSModule module = modules[moduleIndex]; BitSet selfPlusTransitiveDeps = new BitSet(moduleIndex + 1); array[moduleIndex] = selfPlusTransitiveDeps; selfPlusTransitiveDeps.set(moduleIndex); // O(moduleIndex * log64(moduleIndex)) for (JSModule dep : module.getDependencies()) { // Add this dependency and all of its dependencies to the current module. // O(log64(moduleIndex)) selfPlusTransitiveDeps.or(array[dep.getIndex()]); } } return array; } private int[] initSubtreeSize() { int[] subtreeSize = new int[modules.length]; for (int dependentIndex = 0; dependentIndex < modules.length; ++dependentIndex) { BitSet dependencies = selfPlusTransitiveDeps[dependentIndex]; // Iterating backward through the bitset is slightly more efficient, since it avoids // considering later modules, which this one cannot depend on. for (int requiredIndex = dependentIndex; requiredIndex >= 0; requiredIndex = dependencies.previousSetBit(requiredIndex - 1)) { subtreeSize[requiredIndex] += 1; // Count dependent in required module's subtree. } } return subtreeSize; } /** Gets an iterable over all input source files in dependency order. */ Iterable getAllInputs() { return Iterables.concat(Iterables.transform(Arrays.asList(modules), JSModule::getInputs)); } /** Gets the total number of input source files. */ int getInputCount() { int count = 0; for (JSModule module : modules) { count += module.getInputCount(); } return count; } /** * Gets an iterable over all modules in dependency order. */ Iterable getAllModules() { return Arrays.asList(modules); } /** * Gets a single module by name. * * @return The module, or null if no such module exists. */ @Nullable JSModule getModuleByName(String name) { for (JSModule m : modules) { if (m.getName().equals(name)) { return m; } } return null; } /** * Gets all modules indexed by name. */ Map getModulesByName() { Map result = new HashMap<>(); for (JSModule m : modules) { result.put(m.getName(), m); } return result; } /** * Gets the total number of modules. */ int getModuleCount() { return modules.length; } /** * Gets the root module. */ JSModule getRootModule() { return Iterables.getOnlyElement(modulesByDepth.get(0)); } /** * Returns a JSON representation of the JSModuleGraph. Specifically a * JsonArray of "Modules" where each module has a * - "name" * - "dependencies" (list of module names) * - "transitive-dependencies" (list of module names, deepest first) * - "inputs" (list of file names) * @return List of module JSONObjects. */ @GwtIncompatible("com.google.gson") JsonArray toJson() { JsonArray modules = new JsonArray(); for (JSModule module : getAllModules()) { JsonObject node = new JsonObject(); node.add("name", new JsonPrimitive(module.getName())); JsonArray deps = new JsonArray(); node.add("dependencies", deps); for (JSModule m : module.getDependencies()) { deps.add(new JsonPrimitive(m.getName())); } JsonArray transitiveDeps = new JsonArray(); node.add("transitive-dependencies", transitiveDeps); for (JSModule m : getTransitiveDepsDeepestFirst(module)) { transitiveDeps.add(new JsonPrimitive(m.getName())); } JsonArray inputs = new JsonArray(); node.add("inputs", inputs); for (CompilerInput input : module.getInputs()) { inputs.add(new JsonPrimitive( input.getSourceFile().getOriginalPath())); } modules.add(node); } return modules; } /** * Determines whether this module depends on a given module. Note that a * module never depends on itself, as that dependency would be cyclic. */ public boolean dependsOn(JSModule src, JSModule m) { return src != m && selfPlusTransitiveDeps[src.getIndex()].get(m.getIndex()); } /** * Finds the module with the fewest transitive dependents on which all of the given modules depend * and that is a subtree of the given parent module tree. * *

If no such subtree can be found, the parent module is returned. * *

If multiple candidates have the same number of dependents, the module farthest down in the * total ordering of modules will be chosen. * * @param parentTree module on which the result must depend * @param dependentModules indices of modules to consider * @return A module on which all of the argument modules depend */ public JSModule getSmallestCoveringSubtree(JSModule parentTree, BitSet dependentModules) { checkState(!dependentModules.isEmpty()); // Candidate modules are those that all of the given dependent modules depend on, including // themselves. The dependent module with the smallest index might be our answer, if all // the other modules depend on it. int minDependentModuleIndex = modules.length; final BitSet candidates = new BitSet(modules.length); candidates.set(0, modules.length, true); for (int dependentIndex = dependentModules.nextSetBit(0); dependentIndex >= 0; dependentIndex = dependentModules.nextSetBit(dependentIndex + 1)) { minDependentModuleIndex = Math.min(minDependentModuleIndex, dependentIndex); candidates.and(selfPlusTransitiveDeps[dependentIndex]); } checkState( !candidates.isEmpty(), "No common dependency found for %s", dependentModules); // All candidates must have an index <= the smallest dependent module index. // Work backwards through the candidates starting with the dependent module with the smallest // index. For each candidate, we'll remove all of the modules it depends on from consideration, // since they must all have larger subtrees than the one we're considering. int parentTreeIndex = parentTree.getIndex(); // default to parent tree if we don't find anything better int bestCandidateIndex = parentTreeIndex; for (int candidateIndex = candidates.previousSetBit(minDependentModuleIndex); candidateIndex >= 0; candidateIndex = candidates.previousSetBit(candidateIndex - 1)) { BitSet candidatePlusTransitiveDeps = selfPlusTransitiveDeps[candidateIndex]; if (candidatePlusTransitiveDeps.get(parentTreeIndex)) { // candidate is a subtree of parentTree candidates.andNot(candidatePlusTransitiveDeps); if (subtreeSize[candidateIndex] < subtreeSize[bestCandidateIndex]) { bestCandidateIndex = candidateIndex; } } // eliminate candidates that are not a subtree of parentTree } return modules[bestCandidateIndex]; } /** * Finds the deepest common dependency of two modules, not including the two * modules themselves. * * @param m1 A module in this graph * @param m2 A module in this graph * @return The deepest common dep of {@code m1} and {@code m2}, or null if * they have no common dependencies */ JSModule getDeepestCommonDependency(JSModule m1, JSModule m2) { int m1Depth = m1.getDepth(); int m2Depth = m2.getDepth(); // According our definition of depth, the result must have a strictly // smaller depth than either m1 or m2. for (int depth = Math.min(m1Depth, m2Depth) - 1; depth >= 0; depth--) { List modulesAtDepth = modulesByDepth.get(depth); // Look at the modules at this depth in reverse order, so that we use the // original ordering of the modules to break ties (later meaning deeper). for (int i = modulesAtDepth.size() - 1; i >= 0; i--) { JSModule m = modulesAtDepth.get(i); if (dependsOn(m1, m) && dependsOn(m2, m)) { return m; } } } return null; } /** * Finds the deepest common dependency of two modules, including the * modules themselves. * * @param m1 A module in this graph * @param m2 A module in this graph * @return The deepest common dep of {@code m1} and {@code m2}, or null if * they have no common dependencies */ public JSModule getDeepestCommonDependencyInclusive( JSModule m1, JSModule m2) { if (m2 == m1 || dependsOn(m2, m1)) { return m1; } else if (dependsOn(m1, m2)) { return m2; } return getDeepestCommonDependency(m1, m2); } /** Returns the deepest common dependency of the given modules. */ public JSModule getDeepestCommonDependencyInclusive( Collection modules) { Iterator iter = modules.iterator(); JSModule dep = iter.next(); while (iter.hasNext()) { dep = getDeepestCommonDependencyInclusive(dep, iter.next()); } return dep; } /** * Creates an iterable over the transitive dependencies of module {@code m} * in a non-increasing depth ordering. The result does not include the module * {@code m}. * * @param m A module in this graph * @return The transitive dependencies of module {@code m} */ @VisibleForTesting List getTransitiveDepsDeepestFirst(JSModule m) { return InverseDepthComparator.INSTANCE.sortedCopy(getTransitiveDeps(m)); } /** Returns the transitive dependencies of the module. */ private Set getTransitiveDeps(JSModule m) { Set deps = dependencyMap.computeIfAbsent(m, JSModule::getAllDependencies); return deps; } /** * Moves all sources that have {@link SourceKind#WEAK} into the weak module so that they may be * pruned later. */ private static void moveMarkedWeakSources(JSModule weakModule, Iterable inputs) { checkNotNull(weakModule); ImmutableList allInputs = ImmutableList.copyOf(inputs); for (CompilerInput i : allInputs) { if (i.getSourceFile().isWeak()) { JSModule existingModule = i.getModule(); if (existingModule == weakModule) { continue; } if (existingModule != null) { existingModule.remove(i); } weakModule.add(i); } } } /** * Apply the dependency options to the list of sources, returning a new source list re-ordering * and dropping files as necessary. This module graph will be updated to reflect the new list. * *

See {@link DependencyOptions} for more information on how this works. * * @throws MissingProvideException if an entry point was not provided by any of the inputs. */ public ImmutableList manageDependencies( AbstractCompiler compiler, DependencyOptions dependencyOptions) throws MissingProvideException, MissingModuleException { // Make a copy since we're going to mutate the graph below. List originalInputs = ImmutableList.copyOf(getAllInputs()); SortedDependencies sorter = new Es6SortedDependencies<>(originalInputs); Set entryPointInputs = createEntryPointInputs(compiler, dependencyOptions, getAllInputs(), sorter); HashMap inputsByProvide = new HashMap<>(); for (CompilerInput input : originalInputs) { for (String provide : input.getKnownProvides()) { inputsByProvide.put(provide, input); } String moduleName = input.getPath().toModuleName(); inputsByProvide.putIfAbsent(moduleName, input); } // Dynamically imported files must be added to the module graph, but // they should not be ordered ahead of the files that import them. // We add them as entry points to ensure they get included. for (CompilerInput input : originalInputs) { for (String require : input.getDynamicRequires()) { if (inputsByProvide.containsKey(require)) { entryPointInputs.add(inputsByProvide.get(require)); } } } // The order of inputs, sorted independently of modules. List absoluteOrder = sorter.getStrongDependenciesOf(originalInputs, dependencyOptions.shouldSort()); // Figure out which sources *must* be in each module. ListMultimap entryPointInputsPerModule = LinkedListMultimap.create(); for (CompilerInput input : entryPointInputs) { JSModule module = input.getModule(); checkNotNull(module); entryPointInputsPerModule.put(module, input); } // Clear the modules of their inputs. This also nulls out the input's reference to its module. for (JSModule module : getAllModules()) { module.removeAll(); } // Figure out which sources *must* be in each module, or in one // of that module's dependencies. List orderedInputs = new ArrayList<>(); Set reachedInputs = new HashSet<>(); for (JSModule module : entryPointInputsPerModule.keySet()) { List transitiveClosure; // Prefer a depth first ordering of dependencies from entry points. // Always orders in a deterministic fashion regardless of the order of provided inputs // given the same entry points in the same order. if (dependencyOptions.shouldSort() && dependencyOptions.shouldPrune()) { transitiveClosure = new ArrayList<>(); // We need the ful set of dependencies for each module, so start with the full input set Set inputsNotYetReached = new HashSet<>(originalInputs); for (CompilerInput entryPoint : entryPointInputsPerModule.get(module)) { transitiveClosure.addAll( getDepthFirstDependenciesOf(entryPoint, inputsNotYetReached, inputsByProvide)); } // For any input we have not yet reached, add them to the ordered list for (CompilerInput orderedInput : transitiveClosure) { if (reachedInputs.add(orderedInput)) { orderedInputs.add(orderedInput); } } } else { // Simply order inputs so that any required namespace comes before it's usage. // Ordered result varies based on the original order of inputs. transitiveClosure = sorter.getStrongDependenciesOf( entryPointInputsPerModule.get(module), dependencyOptions.shouldSort()); } for (CompilerInput input : transitiveClosure) { if (dependencyOptions.shouldPrune() && input.getSourceFile().isWeak() && !entryPointInputs.contains(input)) { compiler.report( JSError.make( WEAK_FILE_REACHABLE_FROM_ENTRY_POINT_ERROR, input.getSourceFile().getName())); } JSModule oldModule = input.getModule(); if (oldModule == null) { input.setModule(module); } else { input.setModule(null); input.setModule( getDeepestCommonDependencyInclusive(oldModule, module)); } } } if (!(dependencyOptions.shouldSort() && dependencyOptions.shouldPrune()) || entryPointInputsPerModule.isEmpty()) { orderedInputs = absoluteOrder; } JSModule weakModule = getModuleByName(JSModule.WEAK_MODULE_NAME); checkNotNull(weakModule); // Mark all sources that are detected as weak. if (dependencyOptions.shouldPrune()) { List weakInputs = sorter.getSortedWeakDependenciesOf(orderedInputs); for (CompilerInput i : weakInputs) { // Add weak inputs to the weak module in dependency order. moveMarkedWeakSources will move // in command line flag order. checkState(i.getModule() == null); i.getSourceFile().setKind(SourceKind.WEAK); i.setModule(weakModule); weakModule.add(i); } } else { // Only move sourced marked as weak if the compiler isn't doing its own detection. moveMarkedWeakSources(weakModule, originalInputs); } // All the inputs are pointing to the modules that own them. Yeah! // Update the modules to reflect this. for (CompilerInput input : orderedInputs) { JSModule module = input.getModule(); if (module != null && !module.getInputs().contains(input)) { module.add(input); } } // Now, generate the sorted result. ImmutableList.Builder result = ImmutableList.builder(); for (JSModule module : getAllModules()) { result.addAll(module.getInputs()); } return result.build(); } /** * Given an input and set of unprocessed inputs, return the input and it's strong dependencies by * performing a recursive, depth-first traversal. */ private List getDepthFirstDependenciesOf( CompilerInput rootInput, Set unreachedInputs, Map inputsByProvide) { List orderedInputs = new ArrayList<>(); if (!unreachedInputs.remove(rootInput)) { return orderedInputs; } for (String importedNamespace : rootInput.getRequiredSymbols()) { CompilerInput dependency = null; if (inputsByProvide.containsKey(importedNamespace) && unreachedInputs.contains(inputsByProvide.get(importedNamespace))) { dependency = inputsByProvide.get(importedNamespace); } if (dependency != null) { orderedInputs.addAll( getDepthFirstDependenciesOf(dependency, unreachedInputs, inputsByProvide)); } } orderedInputs.add(rootInput); return orderedInputs; } private Set createEntryPointInputs( AbstractCompiler compiler, DependencyOptions dependencyOptions, Iterable inputs, SortedDependencies sorter) throws MissingModuleException, MissingProvideException { Set entryPointInputs = new LinkedHashSet<>(); Map modulesByName = getModulesByName(); if (dependencyOptions.shouldPrune()) { // Some files implicitly depend on base.js without actually requiring anything. // So we always treat it as the first entry point to ensure it's ordered correctly. CompilerInput baseJs = sorter.maybeGetInputProviding("goog"); if (baseJs != null) { entryPointInputs.add(baseJs); } if (!dependencyOptions.shouldDropMoochers()) { for (CompilerInput entryPointInput : sorter.getInputsWithoutProvides()) { if (entryPointInput.getSourceFile().isWeak()) { compiler.report( JSError.make( IMPLICIT_WEAK_ENTRY_POINT_ERROR, entryPointInput.getSourceFile().getName())); } else { entryPointInputs.add(entryPointInput); } } } for (ModuleIdentifier entryPoint : dependencyOptions.getEntryPoints()) { CompilerInput entryPointInput = null; try { if (entryPoint.getClosureNamespace().equals(entryPoint.getModuleName())) { entryPointInput = sorter.maybeGetInputProviding(entryPoint.getClosureNamespace()); // Check to see if we can find the entry point as an ES6 and CommonJS module // ES6 and CommonJS entry points may not provide any symbols if (entryPointInput == null) { entryPointInput = sorter.getInputProviding(entryPoint.getName()); } } else { JSModule module = modulesByName.get(entryPoint.getModuleName()); if (module == null) { throw new MissingModuleException(entryPoint.getModuleName()); } else { entryPointInput = sorter.getInputProviding(entryPoint.getClosureNamespace()); entryPointInput.overrideModule(module); } } } catch (MissingProvideException e) { throw new MissingProvideException(entryPoint.getName(), e); } if (entryPointInput.getSourceFile().isWeak()) { compiler.report( JSError.make( EXPLICIT_WEAK_ENTRY_POINT_ERROR, entryPointInput.getSourceFile().getName())); } else { entryPointInputs.add(entryPointInput); } } } else { Iterables.addAll(entryPointInputs, inputs); } return entryPointInputs; } @SuppressWarnings("unused") LinkedDirectedGraph toGraphvizGraph() { LinkedDirectedGraph graphViz = LinkedDirectedGraph.create(); for (JSModule module : getAllModules()) { graphViz.createNode(module); for (JSModule dep : module.getDependencies()) { graphViz.createNode(dep); graphViz.connect(module, "->", dep); } } return graphViz; } /** * A module depth comparator that considers a deeper module to be "less than" * a shallower module. Uses module names to consistently break ties. */ private static final class InverseDepthComparator extends Ordering { static final InverseDepthComparator INSTANCE = new InverseDepthComparator(); @Override public int compare(JSModule m1, JSModule m2) { return depthCompare(m2, m1); } } private static int depthCompare(JSModule m1, JSModule m2) { if (m1 == m2) { return 0; } int d1 = m1.getDepth(); int d2 = m2.getDepth(); return d1 < d2 ? -1 : d2 == d1 ? m1.getName().compareTo(m2.getName()) : 1; } /** * Exception class for declaring when the modules being fed into a * JSModuleGraph as input aren't in dependence order, and so can't be * processed for caching of various dependency-related queries. */ protected static class ModuleDependenceException extends IllegalArgumentException { private static final long serialVersionUID = 1; private final JSModule module; private final JSModule dependentModule; protected ModuleDependenceException(String message, JSModule module, JSModule dependentModule) { super(message); this.module = module; this.dependentModule = dependentModule; } public JSModule getModule() { return module; } public JSModule getDependentModule() { return dependentModule; } } /** Another exception class */ public static class MissingModuleException extends Exception { MissingModuleException(String moduleName) { super(moduleName); } } }





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