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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.MoreObjects.firstNonNull;
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.collect.HashMultimap;
import com.google.common.collect.ImmutableSet;
import com.google.common.collect.Multimap;
import com.google.javascript.jscomp.AccessorSummary.PropertyAccessKind;
import com.google.javascript.jscomp.CodingConvention.SubclassRelationship;
import com.google.javascript.rhino.IR;
import com.google.javascript.rhino.Node;
import com.google.javascript.rhino.Token;
import com.google.javascript.rhino.jstype.JSType;
import com.google.javascript.rhino.jstype.JSTypeNative;
import com.google.javascript.rhino.jstype.ObjectType;
import java.util.ArrayDeque;
import java.util.ArrayList;
import java.util.Deque;
import java.util.HashMap;
import java.util.HashSet;
import java.util.Iterator;
import java.util.List;
import java.util.Map;
import java.util.Map.Entry;
import java.util.Set;
import javax.annotation.Nullable;

/**
 * Garbage collection for variable and function definitions. Basically performs
 * a mark-and-sweep type algorithm over the JavaScript parse tree.
 *
 * For each scope:
 * (1) Scan the variable/function declarations at that scope.
 * (2) Traverse the scope for references, marking all referenced variables.
 *     Unlike other compiler passes, this is a pre-order traversal, not a
 *     post-order traversal.
 * (3) If the traversal encounters an assign without other side-effects,
 *     create a continuation. Continue the continuation iff the assigned
 *     variable is referenced.
 * (4) When the traversal completes, remove all unreferenced variables.
 *
 * If it makes it easier, you can think of the continuations of the traversal
 * as a reference graph. Each continuation represents a set of edges, where the
 * source node is a known variable, and the destination nodes are lazily
 * evaluated when the continuation is executed.
 *
 * This algorithm is similar to the algorithm used by {@code SmartNameRemoval}.
 * {@code SmartNameRemoval} maintains an explicit graph of dependencies
 * between global symbols. However, {@code SmartNameRemoval} cannot handle
 * non-trivial edges in the reference graph ("A is referenced iff both B and C
 * are referenced"), or local variables. {@code SmartNameRemoval} is also
 * substantially more complicated because it tries to handle namespaces
 * (which is largely unnecessary in the presence of {@code CollapseProperties}.
 *
 * This pass also uses a more complex analysis of assignments, where
 * an assignment to a variable or a property of that variable does not
 * necessarily count as a reference to that variable, unless we can prove
 * that it modifies external state. This is similar to
 * {@code FlowSensitiveInlineVariables}, except that it works for variables
 * used across scopes.
 *
 * Multiple datastructures are used to accumulate nodes, some of which are
 * later removed. Since some nodes encompass a subtree of nodes, the removal
 * can sometimes pre-remove other nodes which are also referenced in these
 * datastructures for later removal. Attempting double-removal violates scope
 * change notification constraints so there is a desire to excise
 * already-removed subtree nodes from these datastructures. But not all of the
 * datastructures are conducive to flexible removal and the ones that are
 * conducive don't necessarily track all flavors of nodes. So instead of
 * updating datastructures on the fly a pre-check is performed to skip
 * already-removed nodes right before the moment an attempt to remove them
 * would otherwise be made.
 *
 * @author [email protected] (Nick Santos)
 */
class RemoveUnusedCode implements CompilerPass {

  // Properties that are implicitly used as part of the JS language.
  private static final ImmutableSet IMPLICITLY_USED_PROPERTIES =
      ImmutableSet.of("length", "toString", "valueOf", "constructor");

  private final AbstractCompiler compiler;
  private final AstAnalyzer astAnalyzer;

  private final CodingConvention codingConvention;

  private final boolean removeLocalVars;
  private final boolean removeGlobals;

  private final boolean preserveFunctionExpressionNames;

  /**
   * Used to hold continuations that need to be invoked.
   *
   * When we find a subtree of the AST that may not need to be traversed, we create a Continuation
   * for it. If we later discover that we do need to traverse it, we add it to this worklist
   * rather than traversing it immediately. If we invoked the traversal immediately, we could
   * end up modifying a data structure in the traversal as we're iterating over it.
   */
  private final Deque worklist = new ArrayDeque<>();

  private final Map varInfoMap = new HashMap<>();

  private final Set pinnedPropertyNames = new HashSet<>(IMPLICITLY_USED_PROPERTIES);

  /** Stores Removable objects for each property name that is currently considered removable. */
  private final Multimap removablesForPropertyNames = HashMultimap.create();

  /** Single value to use for all vars for which we cannot remove anything at all. */
  private final VarInfo canonicalUnremovableVarInfo;

  /**
   * Keep track of scopes that we've traversed.
   */
  private final List allFunctionParamScopes = new ArrayList<>();

  /**
   * Stores the names of all "leaf" properties that are polyfilled, to avoid unnecessary qualified
   * name matching and searches for all the other properties. This includes global names such as
   * "Promise" and "Map", static methods on global names such as "Array.from" and "Math.fround", and
   * instance properties such as "String.prototype.repeat" and "Promise.prototype.finally".
   */
  private final Multimap polyfills = HashMultimap.create();

  private final SyntacticScopeCreator scopeCreator;

  private final boolean removeUnusedPrototypeProperties;
  private final boolean allowRemovalOfExternProperties;
  private final boolean removeUnusedThisProperties;
  private final boolean removeUnusedStaticProperties;
  private final boolean removeUnusedObjectDefinePropertiesDefinitions;
  private final boolean removeUnusedPolyfills;
  private final boolean assumeGettersArePure;

  RemoveUnusedCode(Builder builder) {
    this.compiler = builder.compiler;
    this.astAnalyzer = compiler.getAstAnalyzer();
    this.codingConvention = builder.compiler.getCodingConvention();
    this.scopeCreator = new SyntacticScopeCreator(builder.compiler);

    this.removeLocalVars = builder.removeLocalVars;
    this.removeGlobals = builder.removeGlobals;
    this.preserveFunctionExpressionNames = builder.preserveFunctionExpressionNames;
    this.removeUnusedPrototypeProperties = builder.removeUnusedPrototypeProperties;
    this.allowRemovalOfExternProperties = builder.allowRemovalOfExternProperties;
    this.removeUnusedThisProperties = builder.removeUnusedThisProperties;
    this.removeUnusedStaticProperties = builder.removeUnusedStaticProperties;
    this.removeUnusedObjectDefinePropertiesDefinitions =
        builder.removeUnusedObjectDefinePropertiesDefinitions;
    this.removeUnusedPolyfills = builder.removeUnusedPolyfills;
    this.assumeGettersArePure = builder.assumeGettersArePure;

    // All Vars that are completely unremovable will share this VarInfo instance.
    canonicalUnremovableVarInfo = new VarInfo();
    canonicalUnremovableVarInfo.setIsExplicitlyNotRemovable();
  }

  public static class Builder {
    private final AbstractCompiler compiler;

    private boolean removeLocalVars = false;
    private boolean removeGlobals = false;
    private boolean preserveFunctionExpressionNames = false;
    private boolean removeUnusedPrototypeProperties = false;
    private boolean allowRemovalOfExternProperties = false;
    private boolean removeUnusedThisProperties = false;
    private boolean removeUnusedStaticProperties = false;
    private boolean removeUnusedObjectDefinePropertiesDefinitions = false;
    private boolean removeUnusedPolyfills = false;
    private boolean assumeGettersArePure = false;

    Builder(AbstractCompiler compiler) {
      this.compiler = compiler;
    }

    Builder removeLocalVars(boolean value) {
      this.removeLocalVars = value;
      return this;
    }

    Builder removeGlobals(boolean value) {
      this.removeGlobals = value;
      return this;
    }

    Builder preserveFunctionExpressionNames(boolean value) {
      this.preserveFunctionExpressionNames = value;
      return this;
    }

    Builder removeUnusedPrototypeProperties(boolean value) {
      this.removeUnusedPrototypeProperties = value;
      return this;
    }

    Builder allowRemovalOfExternProperties(boolean value) {
      this.allowRemovalOfExternProperties = value;
      return this;
    }

    Builder removeUnusedThisProperties(boolean value) {
      this.removeUnusedThisProperties = value;
      return this;
    }

    Builder removeUnusedConstructorProperties(boolean value) {
      this.removeUnusedStaticProperties = value;
      return this;
    }

    Builder removeUnusedObjectDefinePropertiesDefinitions(boolean value) {
      this.removeUnusedObjectDefinePropertiesDefinitions = value;
      return this;
    }

    Builder removeUnusedPolyfills(boolean value) {
      this.removeUnusedPolyfills = value;
      return this;
    }

    Builder assumeGettersArePure(boolean value) {
      this.assumeGettersArePure = value;
      return this;
    }

    RemoveUnusedCode build() {
      return new RemoveUnusedCode(this);
    }
  }

  /**
   * Traverses the root, removing all unused variables. Multiple traversals
   * may occur to ensure all unused variables are removed.
   */
  @Override
  public void process(Node externs, Node root) {
    checkState(compiler.getLifeCycleStage().isNormalized());
    if (!allowRemovalOfExternProperties) {
      pinnedPropertyNames.addAll(compiler.getExternProperties());
    }
    traverseAndRemoveUnusedReferences(root);
    // This pass may remove definitions of getter or setter properties.
    GatherGetterAndSetterProperties.update(compiler, externs, root);
  }

  /**
   * Traverses a node recursively. Call this once per pass.
   */
  private void traverseAndRemoveUnusedReferences(Node root) {
    // Create scope from parent of root node, which also has externs as a child, so we'll
    // have extern definitions in scope.
    Scope scope = scopeCreator.createScope(root.getParent(), null);
    if (!scope.hasSlot(NodeUtil.JSC_PROPERTY_NAME_FN)) {
      // TODO(b/70730762): Passes that add references to this should ensure it is declared.
      // NOTE: null input makes this an extern var.
      scope.declare(
          NodeUtil.JSC_PROPERTY_NAME_FN, /* no declaration node */ null, /* no input */ null);
    }
    worklist.add(new Continuation(root, scope));
    while (!worklist.isEmpty()) {
      Continuation continuation = worklist.remove();
      continuation.apply();
    }

    removeUnreferencedVarsAndPolyfills();
    removeIndependentlyRemovableProperties();
    for (Scope fparamScope : allFunctionParamScopes) {
      removeUnreferencedFunctionArgs(fparamScope);
    }
  }

  private void removeIndependentlyRemovableProperties() {
    for (Removable removable : removablesForPropertyNames.values()) {
      removable.remove(compiler);
    }
  }

  /**
   * Traverses everything in the current scope and marks variables that
   * are referenced.
   *
   * During traversal, we identify subtrees that will only be
   * referenced if their enclosing variables are referenced. Instead of
   * traversing those subtrees, we create a continuation for them,
   * and traverse them lazily.
   */
  private void traverseNode(Node n, Scope scope) {
    Node parent = n.getParent();
    Token type = n.getToken();
    switch (type) {
      case CATCH:
        traverseCatch(n, scope);
        break;

      case FUNCTION:
        {
          VarInfo varInfo = null;
          // If this function is a removable var, then create a continuation
          // for it instead of traversing immediately.
          if (NodeUtil.isFunctionDeclaration(n)) {
            varInfo = traverseNameNode(n.getFirstChild(), scope);
            FunctionDeclaration functionDeclaration =
                new RemovableBuilder()
                    .addContinuation(new Continuation(n, scope))
                    .buildFunctionDeclaration(n);
            varInfo.addRemovable(functionDeclaration);
            if (parent.isExport()) {
              varInfo.markAsReferenced();
            }
          } else {
            traverseFunction(n, scope);
          }
        }
        break;

      case ASSIGN:
        traverseAssign(n, scope);
        break;

      case ASSIGN_BITOR:
      case ASSIGN_BITXOR:
      case ASSIGN_BITAND:
      case ASSIGN_LSH:
      case ASSIGN_RSH:
      case ASSIGN_URSH:
      case ASSIGN_ADD:
      case ASSIGN_SUB:
      case ASSIGN_MUL:
      case ASSIGN_EXPONENT:
      case ASSIGN_DIV:
      case ASSIGN_MOD:
        traverseCompoundAssign(n, scope);
        break;

      case INC:
      case DEC:
        traverseIncrementOrDecrementOp(n, scope);
        break;

      case CALL:
        traverseCall(n, scope);
        break;

      case SWITCH:
      case BLOCK:
        // This case if for if there are let and const variables in block scopes.
        // Otherwise other variables will be hoisted up into the global scope and already be
        // handled.
        traverseChildren(
            n, NodeUtil.createsBlockScope(n) ? scopeCreator.createScope(n, scope) : scope);
        break;

      case MODULE_BODY:
        traverseChildren(n, scopeCreator.createScope(n, scope));
        break;

      case CLASS:
        traverseClass(n, scope);
        break;

      case CLASS_MEMBERS:
        traverseClassMembers(n, scope);
        break;

      case ARRAY_PATTERN:
      case PARAM_LIST:
        traverseIndirectAssignmentList(n, scope);
        break;

      case OBJECT_PATTERN:
        traverseObjectPattern(n, scope);
        break;

      case OBJECTLIT:
        traverseObjectLiteral(n, scope);
        break;

      case FOR:
        traverseVanillaFor(n, scope);
        break;

      case FOR_IN:
      case FOR_OF:
      case FOR_AWAIT_OF:
        traverseEnhancedFor(n, scope);
        break;

      case LET:
      case CONST:
      case VAR:
        // for-loop cases are handled by custom traversal methods.
        checkState(NodeUtil.isStatement(n));
        traverseDeclarationStatement(n, scope);
        break;

      case INSTANCEOF:
        traverseInstanceof(n, scope);
        break;

      case NAME:
        // The only cases that should reach this point are parameter declarations and references
        // to names. The name node does not have children in these cases.
        checkState(!n.hasChildren());
        // the parameter declaration is not a read of the name
        if (!parent.isParamList()) {
          // var|let|const name;
          // are handled at a higher level.
          checkState(!NodeUtil.isNameDeclaration(parent));
          // function name() {}
          // class name() {}
          // handled at a higher level
          checkState(!((parent.isFunction() || parent.isClass()) && parent.getFirstChild() == n));
          traverseNameNode(n, scope).markAsReferenced();
        }
        break;

      case GETPROP:
        traverseGetProp(n, scope);
        break;

      default:
        traverseChildren(n, scope);
        break;
    }
  }

  private void traverseInstanceof(Node instanceofNode, Scope scope) {
    checkArgument(instanceofNode.isInstanceOf(), instanceofNode);
    Node lhs = instanceofNode.getFirstChild();
    Node rhs = lhs.getNext();
    traverseNode(lhs, scope);
    if (rhs.isName()) {
      VarInfo varInfo = traverseNameNode(rhs, scope);
      RemovableBuilder builder = new RemovableBuilder();
      varInfo.addRemovable(builder.buildInstanceofName(instanceofNode));
    } else {
      traverseNode(rhs, scope);
    }
  }

  private void traverseGetProp(Node getProp, Scope scope) {
    Node objectNode = getProp.getFirstChild();
    Node propertyNameNode = objectNode.getNext();
    String propertyName = propertyNameNode.getString();

    if (polyfills.containsKey(propertyName)) {
      for (PolyfillInfo info : polyfills.get(propertyName)) {
        info.considerPossibleReference(getProp);
      }
    }

    if (NodeUtil.isExpressionResultUsed(getProp)
        || considerForAccessorSideEffects(getProp, PropertyAccessKind.GETTER_ONLY)) {
      // must record as reference to the property and continue traversal.
      markPropertyNameAsPinned(propertyName);
      traverseNode(objectNode, scope);
    } else if (objectNode.isThis()) {
      // this.propName;
      RemovableBuilder builder = new RemovableBuilder().setIsThisDotPropertyReference(true);
      considerForIndependentRemoval(builder.buildUnusedReadReference(getProp, propertyNameNode));
    } else if (isDotPrototype(objectNode)) {
      // (objExpression).prototype.propName;
      RemovableBuilder builder = new RemovableBuilder().setIsPrototypeDotPropertyReference(true);
      Node objExpression = objectNode.getFirstChild();
      if (objExpression.isName()) {
        // name.prototype.propName;
        VarInfo varInfo = traverseNameNode(objExpression, scope);
        varInfo.addRemovable(builder.buildUnusedReadReference(getProp, propertyNameNode));
      } else {
        // (objExpression).prototype.propName;
        if (astAnalyzer.mayHaveSideEffects(objExpression)) {
          traverseNode(objExpression, scope);
        } else {
          builder.addContinuation(new Continuation(objExpression, scope));
        }
        considerForIndependentRemoval(builder.buildUnusedReadReference(getProp, propertyNameNode));
      }
    } else {
      // TODO(bradfordcsmith): add removal of `varName.propName;`
      markPropertyNameAsPinned(propertyName);
      traverseNode(objectNode, scope);
    }
  }

  // TODO(b/137380742): Combine with `traverseCompoundAssign`.
  private void traverseIncrementOrDecrementOp(Node incOrDecOp, Scope scope) {
    checkArgument(incOrDecOp.isInc() || incOrDecOp.isDec(), incOrDecOp);
    Node arg = incOrDecOp.getOnlyChild();
    if (NodeUtil.isExpressionResultUsed(incOrDecOp)) {
      // If expression result is used, then this expression is definitely not removable.
      traverseNode(arg, scope);
    } else if (arg.isGetProp()) {
      Node getPropObj = arg.getFirstChild();
      Node propertyNameNode = arg.getLastChild();

      if (considerForAccessorSideEffects(arg, PropertyAccessKind.GETTER_AND_SETTER)) {
        traverseNode(getPropObj, scope); // Don't re-traverse the GETPROP as a read.
      } else if (getPropObj.isThis()) {
        // this.propName++
        RemovableBuilder builder = new RemovableBuilder().setIsThisDotPropertyReference(true);
        considerForIndependentRemoval(builder.buildIncOrDepOp(incOrDecOp, propertyNameNode, null));
      } else if (isDotPrototype(getPropObj)) {
        // someExpression.prototype.propName++
        Node exprObj = getPropObj.getFirstChild();
        RemovableBuilder builder = new RemovableBuilder().setIsPrototypeDotPropertyReference(true);
        if (exprObj.isName()) {
          // varName.prototype.propName++
          VarInfo varInfo = traverseNameNode(exprObj, scope);
          varInfo.addRemovable(builder.buildIncOrDepOp(incOrDecOp, propertyNameNode, null));
        } else {
          // (someExpression).prototype.propName++
          Node toPreserve = null;
          if (astAnalyzer.mayHaveSideEffects(exprObj)) {
            toPreserve = exprObj;
            traverseNode(exprObj, scope);
          } else {
            builder.addContinuation(new Continuation(exprObj, scope));
          }
          considerForIndependentRemoval(
              builder.buildIncOrDepOp(incOrDecOp, propertyNameNode, toPreserve));
        }
      } else {
        // someExpression.propName++ is not removable except in the cases covered above
        traverseNode(arg, scope);
      }
    } else {
      // TODO(bradfordcsmith): varName++ should be removable if varName is otherwise unused
      traverseNode(arg, scope);
    }
  }

  // TODO(b/137380742): Combine with `traverseIncrementOrDecrement`.
  private void traverseCompoundAssign(Node compoundAssignNode, Scope scope) {
    // We'll allow removal of compound assignment to a `this` property as long as the result of the
    // assignment is unused.
    // e.g. `this.x += 3;`
    // TODO(nickreid): Why do we treat `this` properties specially? It it because `this` is const?
    Node targetNode = compoundAssignNode.getFirstChild();
    Node valueNode = compoundAssignNode.getLastChild();
    if (targetNode.isGetProp()) {
      if (considerForAccessorSideEffects(targetNode, PropertyAccessKind.GETTER_AND_SETTER)) {
        traverseNode(targetNode.getFirstChild(), scope); // Don't re-traverse the GETPROP as a read.
        traverseNode(valueNode, scope);
      } else if (targetNode.getFirstChild().isThis()
          && !NodeUtil.isExpressionResultUsed(compoundAssignNode)) {
      RemovableBuilder builder = new RemovableBuilder().setIsThisDotPropertyReference(true);
      traverseRemovableAssignValue(valueNode, builder, scope);
      considerForIndependentRemoval(
          builder.buildNamedPropertyAssign(compoundAssignNode, targetNode.getLastChild()));
      } else {
        traverseNode(targetNode, scope);
        traverseNode(valueNode, scope);
      }
    } else {
      traverseNode(targetNode, scope);
      traverseNode(valueNode, scope);
    }
  }

  private VarInfo traverseNameNode(Node n, Scope scope) {
    if (polyfills.containsKey(n.getString())) {
      for (PolyfillInfo info : polyfills.get(n.getString())) {
        info.considerPossibleReference(n);
      }
    }

    return traverseVar(getVarForNameNode(n, scope));
  }

  private void traverseCall(Node callNode, Scope scope) {
    Node callee = callNode.getFirstChild();

    if (callee.isQualifiedName()
        && codingConvention.isPropertyRenameFunction(callee.getOriginalQualifiedName())) {
      Node propertyNameNode = checkNotNull(callee.getNext());
      if (propertyNameNode.isString()) {
        markPropertyNameAsPinned(propertyNameNode.getString());
      }
      traverseChildren(callNode, scope);
    } else if (NodeUtil.isObjectDefinePropertiesDefinition(callNode)) {
      // TODO(bradfordcsmith): Should also handle Object.create() and Object.defineProperty().
      traverseObjectDefinePropertiesCall(callNode, scope);
    } else if (removeUnusedPolyfills && isJscompPolyfill(callee)) {
      Node firstArg = callee.getNext();
      String polyfillName = firstArg.getString();
      PolyfillInfo info = createPolyfillInfo(callNode, scope, polyfillName);
      polyfills.put(info.key, info);
      // Only traverse the callee (to mark it as used).  The arguments may be traversed later.
      traverseNode(callNode.getFirstChild(), scope);
    } else {
      Node parent = callNode.getParent();
      String classVarName = null;

      // A call that is a statement unto itself or the left side of a comma expression might be
      // a call to a known method for doing class setup
      // e.g. $jscomp.inherits(Class, BaseClass) or goog.addSingletonGetter(Class)
      // Such methods never have meaningful return values, so we won't look for them in other
      // contexts
      if (parent.isExprResult() || (parent.isComma() && parent.getFirstChild() == callNode)) {
        SubclassRelationship subclassRelationship =
            codingConvention.getClassesDefinedByCall(callNode);
        if (subclassRelationship != null) {
          // e.g. goog.inherits(DerivedClass, BaseClass);
          // NOTE: DerivedClass and BaseClass must be QNames. Otherwise getClassesDefinedByCall()
          // will return null.
          classVarName = subclassRelationship.subclassName;
        } else {
          // Look for calls to addSingletonGetter calls.
          classVarName = codingConvention.getSingletonGetterClassName(callNode);
        }
      }

      Var classVar = null;
      if (classVarName != null && NodeUtil.isValidSimpleName(classVarName)) {
        classVar = checkNotNull(scope.getVar(classVarName), classVarName);
      }

      if (classVar == null || !classVar.isGlobal()) {
        // The call we are traversing does not modify a class definition,
        // or the class is not specified with a simple variable name,
        // or the variable name is not global.
        // TODO(bradfordcsmith): It would be more correct to check whether the class name
        // references a known constructor and expand to allow QNames.
        traverseChildren(callNode, scope);
      } else {
        RemovableBuilder builder = new RemovableBuilder();
        for (Node child = callNode.getFirstChild(); child != null; child = child.getNext()) {
          builder.addContinuation(new Continuation(child, scope));
        }
        traverseVar(classVar).addRemovable(builder.buildClassSetupCall(callNode));
      }
    }
  }

  /** Checks whether this is a recognizable call to $jscomp.polyfill. */
  private static boolean isJscompPolyfill(Node n) {
    switch (n.getToken()) {
      case NAME:
        // Need to work correctly after CollapseProperties.
        return n.getString().equals("$jscomp$polyfill") && n.getNext().isString();
      case GETPROP:
        // Need to work correctly without CollapseProperties.
        return n.getLastChild().getString().equals("polyfill")
            && n.getFirstChild().isName()
            && n.getFirstChild().getString().equals("$jscomp")
            && n.getNext().isString();
      default:
        return false;
    }
  }

  /** Traverse `Object.defineProperties(someObject, propertyDefinitions);`. */
  private void traverseObjectDefinePropertiesCall(Node callNode, Scope scope) {
    // First child is Object.defineProperties or some equivalent of it.
    Node callee = callNode.getFirstChild();
    Node targetObject = callNode.getSecondChild();
    Node propertyDefinitions = targetObject.getNext();

    if ((targetObject.isName() || isNameDotPrototype(targetObject))
        && !NodeUtil.isExpressionResultUsed(callNode)) {
      // NOTE: Object.defineProperties() returns its first argument, so if its return value is used
      // that counts as a use of the targetObject.
      Node nameNode = targetObject.isName() ? targetObject : targetObject.getFirstChild();
      VarInfo varInfo = traverseNameNode(nameNode, scope);
      RemovableBuilder builder = new RemovableBuilder();
      // TODO(bradfordcsmith): Is it really necessary to traverse the callee
      // (aka. Object.defineProperties)?
      builder.addContinuation(new Continuation(callee, scope));
      if (astAnalyzer.mayHaveSideEffects(propertyDefinitions)) {
        traverseNode(propertyDefinitions, scope);
      } else {
        builder.addContinuation(new Continuation(propertyDefinitions, scope));
      }
      varInfo.addRemovable(builder.buildClassSetupCall(callNode));
    } else {
      // TODO(bradfordcsmith): Is it really necessary to traverse the callee
      // (aka. Object.defineProperties)?
      traverseNode(callee, scope);
      traverseNode(targetObject, scope);
      traverseNode(propertyDefinitions, scope);
    }
  }

  /** Traverse the object literal passed as the second argument to `Object.defineProperties()`. */
  private void traverseObjectDefinePropertiesLiteral(Node propertyDefinitions, Scope scope) {
    for (Node property = propertyDefinitions.getFirstChild();
        property != null;
        property = property.getNext()) {
      if (property.isQuotedString()) {
        // Quoted property name counts as a reference to the property and protects it from removal.
        markPropertyNameAsPinned(property.getString());
        traverseNode(property.getOnlyChild(), scope);
      } else if (property.isStringKey()) {
        Node definition = property.getOnlyChild();
        if (astAnalyzer.mayHaveSideEffects(definition)) {
          traverseNode(definition, scope);
        } else {
          considerForIndependentRemoval(
              new RemovableBuilder()
                  .addContinuation(new Continuation(definition, scope))
                  .buildObjectDefinePropertiesDefinition(property));
        }
      } else {
        // TODO(bradfordcsmith): Maybe report error for anything other than a computed property,
        // since getters, setters, and methods don't make much sense in this context.
        traverseNode(property, scope);
      }
    }
  }

  private Var getVarForNameNode(Node nameNode, Scope scope) {
    return checkNotNull(scope.getVar(nameNode.getString()), nameNode);
  }

  private void traverseObjectLiteral(Node objectLiteral, Scope scope) {
    checkArgument(objectLiteral.isObjectLit(), objectLiteral);
    // Is this an object literal that is assigned directly to a 'prototype' property?
    if (isAssignmentToPrototype(objectLiteral.getParent())) {
      traversePrototypeLiteral(objectLiteral, scope);
    } else if (isObjectDefinePropertiesSecondArgument(objectLiteral)) {
      // TODO(bradfordcsmith): Consider restricting special handling of the properties literal to
      // cases where the target object is a known class, prototype, or this.
      traverseObjectDefinePropertiesLiteral(objectLiteral, scope);
    } else {
      traverseNonPrototypeObjectLiteral(objectLiteral, scope);
    }
  }

  private boolean isObjectDefinePropertiesSecondArgument(Node n) {
    Node parent = n.getParent();
    return NodeUtil.isObjectDefinePropertiesDefinition(parent) && parent.getLastChild() == n;
  }

  private void traverseNonPrototypeObjectLiteral(Node objectLiteral, Scope scope) {
    for (Node propertyNode = objectLiteral.getFirstChild();
        propertyNode != null;
        propertyNode = propertyNode.getNext()) {
      if (propertyNode.isStringKey()) {
        // A property name in an object literal counts as a reference,
        // because of some reflection patterns.
        // Note that we are intentionally treating both quoted and unquoted keys as
        // references.
        markPropertyNameAsPinned(propertyNode.getString());
        traverseNode(propertyNode.getFirstChild(), scope);
      } else {
        traverseNode(propertyNode, scope);
      }
    }
  }

  private void traversePrototypeLiteral(Node objectLiteral, Scope scope) {
    for (Node propertyNode = objectLiteral.getFirstChild();
        propertyNode != null;
        propertyNode = propertyNode.getNext()) {
      if (propertyNode.isComputedProp() || propertyNode.isQuotedString()) {
        traverseChildren(propertyNode, scope);
      } else {
        Node valueNode = propertyNode.getOnlyChild();
        if (astAnalyzer.mayHaveSideEffects(valueNode)) {
          // TODO(bradfordcsmith): Ideally we should preserve the side-effect without keeping the
          // property itself alive.
          traverseNode(valueNode, scope);
        } else {
          // If we've come this far, we already know we're keeping the prototype literal itself,
          // but we may be able to remove unreferenced properties in it.
          considerForIndependentRemoval(
              new RemovableBuilder()
                  .addContinuation(new Continuation(valueNode, scope))
                  .buildClassOrPrototypeNamedProperty(propertyNode));
        }
      }
    }
  }

  private boolean isAssignmentToPrototype(Node n) {
    return n.isAssign() && isDotPrototype(n.getFirstChild());
  }

  /** True for `someExpression.prototype`. */
  private static boolean isDotPrototype(Node n) {
    return n.isGetProp() && n.getLastChild().getString().equals("prototype");
  }

  private void traverseCatch(Node catchNode, Scope scope) {
    Node exceptionNameNode = catchNode.getFirstChild();
    Node block = exceptionNameNode.getNext();
    if (exceptionNameNode.isName()) {
      // exceptionNameNode can be an empty node if not using a binding in 2019.
      VarInfo exceptionVarInfo = traverseNameNode(exceptionNameNode, scope);
      exceptionVarInfo.setIsExplicitlyNotRemovable();
    }
    traverseNode(block, scope);
  }

  private void traverseEnhancedFor(Node enhancedFor, Scope scope) {
    Scope forScope = scopeCreator.createScope(enhancedFor, scope);
    // for (iterationTarget in|of collection) body;
    Node iterationTarget = enhancedFor.getFirstChild();
    Node collection = iterationTarget.getNext();
    Node body = collection.getNext();
    if (iterationTarget.isName()) {
      // using previously-declared loop variable. e.g.
      // `for (varName of collection) {}`
      VarInfo varInfo = traverseNameNode(iterationTarget, forScope);
      varInfo.setIsExplicitlyNotRemovable();
    } else if (NodeUtil.isNameDeclaration(iterationTarget)) {
      // loop has const/var/let declaration
      Node declNode = iterationTarget.getOnlyChild();
      if (declNode.isDestructuringLhs()) {
        // e.g.
        // `for (const [a, b] of pairList) {}`
        // destructuring is handled at a lower level
        // Note that destructuring assignments are always considered to set an unknown value
        // equivalent to what we set for the var name case above and below.
        // It isn't necessary to set the variable names as not removable, though, because the
        // thing that isn't removable is the destructuring pattern itself, which we never remove.
        // TODO(bradfordcsmith): The need to explain all the above shows this should be reworked.
        traverseNode(declNode, forScope);
      } else {
        // e.g.
        // `for (const varName of collection) {}`
        checkState(declNode.isName());
        checkState(!declNode.hasChildren());
        // We can never remove the loop variable of a for-in or for-of loop, because it's
        // essential to loop syntax.
        VarInfo varInfo = traverseNameNode(declNode, forScope);
        varInfo.setIsExplicitlyNotRemovable();
      }
    } else {
      // using some general LHS value e.g.
      // `for ([a, b] of collection) {}` destructuring with existing vars
      // `for (a.x of collection) {}` using a property as the loop var
      // TODO(bradfordcsmith): This should be considered a write if it's a property reference.
      traverseNode(iterationTarget, forScope);
    }
    traverseNode(collection, forScope);
    traverseNode(body, forScope);
  }

  private void traverseVanillaFor(Node forNode, Scope scope) {
    Scope forScope = scopeCreator.createScope(forNode, scope);
    Node initialization = forNode.getFirstChild();
    Node condition = initialization.getNext();
    Node update = condition.getNext();
    Node block = update.getNext();
    if (NodeUtil.isNameDeclaration(initialization)) {
      traverseVanillaForNameDeclarations(initialization, forScope);
    } else {
      traverseNode(initialization, forScope);
    }
    traverseNode(condition, forScope);
    traverseNode(update, forScope);
    traverseNode(block, forScope);
  }

  private void traverseVanillaForNameDeclarations(Node nameDeclaration, Scope scope) {
    for (Node child = nameDeclaration.getFirstChild(); child != null; child = child.getNext()) {
      if (!child.isName()) {
        // TODO(bradfordcsmith): Customize handling of destructuring
        traverseNode(child, scope);
      } else {
        Node nameNode = child;
        @Nullable Node valueNode = child.getFirstChild();
        VarInfo varInfo = traverseNameNode(nameNode, scope);
        if (valueNode == null) {
          varInfo.addRemovable(new RemovableBuilder().buildVanillaForNameDeclaration(nameNode));
        } else if (astAnalyzer.mayHaveSideEffects(valueNode)) {
          // TODO(bradfordcsmith): Actually allow for removing the variable while keeping the
          // valueNode for its side-effects.
          varInfo.setIsExplicitlyNotRemovable();
          traverseNode(valueNode, scope);
        } else {
          VanillaForNameDeclaration vanillaForNameDeclaration =
              new RemovableBuilder()
                  .addContinuation(new Continuation(valueNode, scope))
                  .buildVanillaForNameDeclaration(nameNode);
          varInfo.addRemovable(vanillaForNameDeclaration);
        }
      }
    }
  }

  private void traverseDeclarationStatement(Node declarationStatement, Scope scope) {
    // Normalization should ensure that declaration statements always have just one child.
    Node nameNode = declarationStatement.getOnlyChild();
    if (!nameNode.isName()) {
      // Destructuring declarations are handled elsewhere.
      traverseNode(nameNode, scope);
    } else {
      Node valueNode = nameNode.getFirstChild();
      VarInfo varInfo = traverseNameNode(nameNode, scope);
      RemovableBuilder builder = new RemovableBuilder();
      if (valueNode == null) {
        varInfo.addRemovable(builder.buildNameDeclarationStatement(declarationStatement));
      } else {
        if (astAnalyzer.mayHaveSideEffects(valueNode)) {
          traverseNode(valueNode, scope);
        } else {
          builder.addContinuation(new Continuation(valueNode, scope));
        }
        NameDeclarationStatement removable =
            builder.buildNameDeclarationStatement(declarationStatement);
        varInfo.addRemovable(removable);
      }
    }
  }

  private void traverseAssign(Node assignNode, Scope scope) {
    checkState(NodeUtil.isAssignmentOp(assignNode));

    Node lhs = assignNode.getFirstChild();
    Node valueNode = assignNode.getLastChild();
    if (lhs.isName()) {
      // varName = something
      VarInfo varInfo = traverseNameNode(lhs, scope);
      RemovableBuilder builder = new RemovableBuilder();
      traverseRemovableAssignValue(valueNode, builder, scope);
      varInfo.addRemovable(builder.buildVariableAssign(assignNode));
    } else if (lhs.isGetElem()) {
      Node getElemObj = lhs.getFirstChild();
      Node getElemKey = lhs.getLastChild();
      Node varNameNode =
          getElemObj.isName()
              ? getElemObj
              : isNameDotPrototype(getElemObj) ? getElemObj.getFirstChild() : null;

      if (varNameNode != null) {
        // varName[someExpression] = someValue
        // OR
        // varName.prototype[someExpression] = someValue
        VarInfo varInfo = traverseNameNode(varNameNode, scope);
        RemovableBuilder builder = new RemovableBuilder();
        if (astAnalyzer.mayHaveSideEffects(getElemKey)) {
          traverseNode(getElemKey, scope);
        } else {
          builder.addContinuation(new Continuation(getElemKey, scope));
        }
        traverseRemovableAssignValue(valueNode, builder, scope);
        varInfo.addRemovable(builder.buildComputedPropertyAssign(assignNode, getElemKey));
      } else {
        traverseNode(getElemObj, scope);
        traverseNode(getElemKey, scope);
        traverseNode(valueNode, scope);
      }
    } else if (lhs.isGetProp()) {
      Node getPropLhs = lhs.getFirstChild();
      Node propNameNode = lhs.getLastChild();

      if (considerForAccessorSideEffects(lhs, PropertyAccessKind.SETTER_ONLY)) {
        // And the possible side-effects mean we can't do any removal. We don't use the
        // `AstAnalyzer` because we only want to consider side-effect from the assignment, not the
        // entire l-value subtree.
        traverseNode(getPropLhs, scope); // Don't re-traverse the GETPROP as a read.
        traverseNode(valueNode, scope);
      } else if (getPropLhs.isName()) {
        // varName.propertyName = someValue
        VarInfo varInfo = traverseNameNode(getPropLhs, scope);
        RemovableBuilder builder = new RemovableBuilder();
        traverseRemovableAssignValue(valueNode, builder, scope);
        varInfo.addRemovable(builder.buildNamedPropertyAssign(assignNode, propNameNode));
      } else if (isDotPrototype(getPropLhs)) {
        // objExpression.prototype.propertyName = someValue
        Node objExpression = getPropLhs.getFirstChild();
        RemovableBuilder builder = new RemovableBuilder().setIsPrototypeDotPropertyReference(true);
        traverseRemovableAssignValue(valueNode, builder, scope);
        if (objExpression.isName()) {
          // varName.prototype.propertyName = someValue
          VarInfo varInfo = traverseNameNode(getPropLhs.getFirstChild(), scope);
          varInfo.addRemovable(builder.buildNamedPropertyAssign(assignNode, propNameNode));
        } else {
          // (someExpression).prototype.propertyName = someValue
          if (astAnalyzer.mayHaveSideEffects(objExpression)) {
            traverseNode(objExpression, scope);
          } else {
            builder.addContinuation(new Continuation(objExpression, scope));
          }
          considerForIndependentRemoval(
              builder.buildAnonymousPrototypeNamedPropertyAssign(
                  assignNode, propNameNode.getString()));
        }
      } else if (getPropLhs.isThis()) {
        // this.propertyName = someValue
        RemovableBuilder builder = new RemovableBuilder().setIsThisDotPropertyReference(true);
        traverseRemovableAssignValue(valueNode, builder, scope);
        considerForIndependentRemoval(builder.buildNamedPropertyAssign(assignNode, propNameNode));
      } else {
        traverseNode(lhs, scope);
        traverseNode(valueNode, scope);
      }
    } else {
      // no other cases are removable
      traverseNode(lhs, scope);
      traverseNode(valueNode, scope);
    }
  }

  private void traverseRemovableAssignValue(Node valueNode, RemovableBuilder builder, Scope scope) {
    if (astAnalyzer.mayHaveSideEffects(valueNode)
        || NodeUtil.isExpressionResultUsed(valueNode.getParent())) {
      traverseNode(valueNode, scope);
    } else {
      builder.addContinuation(new Continuation(valueNode, scope));
    }
  }

  private boolean isNameDotPrototype(Node n) {
    return n.isGetProp()
        && n.getFirstChild().isName()
        && n.getLastChild().getString().equals("prototype");
  }

  private void traverseObjectPattern(Node pattern, Scope scope) {
    checkState(pattern.isObjectPattern(), pattern);

    for (Node elem = pattern.getFirstChild(); elem != null; elem = elem.getNext()) {
      switch (elem.getToken()) {
        case COMPUTED_PROP:
          traverseIndirectAssignment(elem, elem.getSecondChild(), scope);
          break;

        case STRING_KEY:
          if (!elem.isQuotedString()) {
            markPropertyNameAsPinned(elem.getString());
          }
          traverseIndirectAssignment(elem, elem.getOnlyChild(), scope);
          break;

        case ITER_REST:
        case OBJECT_REST:
          // Recall that the rest target can be any l-value expression
          traverseIndirectAssignment(elem, elem.getOnlyChild(), scope);
          break;

        default:
          throw new IllegalStateException(
              "Unexpected child of " + pattern.getToken() + ": " + elem.toStringTree());
      }
    }
  }

  private void traverseIndirectAssignmentList(Node list, Scope scope) {
    checkState(list.isArrayPattern() || list.isParamList(), list);

    for (Node elem = list.getFirstChild(); elem != null; elem = elem.getNext()) {
      switch (elem.getToken()) {
        case EMPTY:
          break;

        case ARRAY_PATTERN:
        case DEFAULT_VALUE:
        case GETELEM:
        case GETPROP:
        case NAME:
        case OBJECT_PATTERN:
          traverseIndirectAssignment(elem, elem, scope);
          break;

        case ITER_REST:
        case OBJECT_REST:
          traverseIndirectAssignment(elem, elem.getOnlyChild(), scope);
          break;

        default:
          throw new IllegalStateException(
              "Unexpected child of " + list.getToken() + ": " + elem.toStringTree());
      }
    }
  }

  /**
   * Traverse an AST structure representing an assignment operation for which the target and value
   * are far apart.
   *
   * 

Examples include destructurings and function parameters. * * @param root The root of the assignment subtree. * @param target The l-value expression being assigned to. */ private void traverseIndirectAssignment(Node root, Node target, Scope scope) { Node rootParent = root.getParent(); checkArgument(rootParent.isDestructuringPattern() || rootParent.isParamList(), rootParent); // Flatten out the case where the target is a default value. We always have to consider it. if (target.isDefaultValue()) { target = target.getFirstChild(); } if (target.isGetProp()) { considerForAccessorSideEffects(target, PropertyAccessKind.SETTER_ONLY); } RemovableBuilder builder = new RemovableBuilder().addContinuation(new Continuation(root, scope)); if (astAnalyzer.mayHaveSideEffects(root)) { // If anywhere in the assignment subtree has side-effects, it means that even if the target is // removable the subtree is not. traverseNode(root, scope); // TODO(bradfordcsmith): Preserve side effects without preventing removal of variables and // properties. We could probably do this by subbing in an empty object pattern. } else if (target.isName()) { VarInfo varInfo = traverseNameNode(target, scope); varInfo.addRemovable(builder.buildIndirectAssign(root, target)); } else if (isNameDotPrototype(target) || isThisDotProperty(target)) { considerForIndependentRemoval(builder.buildIndirectAssign(root, target)); } else { // TODO(bradfordcsmith): Handle property assignments also // e.g. `({a: foo.bar, b: foo.baz}) = {a: 1, b: 2}` traverseNode(root, scope); } } private void traverseChildren(Node n, Scope scope) { for (Node c = n.getFirstChild(); c != null; c = c.getNext()) { traverseNode(c, scope); } } /** * Handle a class that is not the RHS child of an assignment or a variable declaration * initializer. * *

For * @param classNode * @param scope */ private void traverseClass(Node classNode, Scope scope) { checkArgument(classNode.isClass()); if (NodeUtil.isClassDeclaration(classNode)) { traverseClassDeclaration(classNode, scope); } else { traverseClassExpression(classNode, scope); } } private void traverseClassDeclaration(Node classNode, Scope scope) { checkArgument(classNode.isClass()); Node classNameNode = classNode.getFirstChild(); Node baseClassExpression = classNameNode.getNext(); Node classBodyNode = baseClassExpression.getNext(); Scope classScope = scopeCreator.createScope(classNode, scope); VarInfo varInfo = traverseNameNode(classNameNode, scope); if (classNode.getParent().isExport()) { // Cannot remove an exported class. varInfo.setIsExplicitlyNotRemovable(); traverseNode(baseClassExpression, scope); // Use traverseChildren() here, because we should not consider any properties on the exported // class to be removable. traverseChildren(classBodyNode, classScope); } else if (astAnalyzer.mayHaveSideEffects(baseClassExpression)) { // TODO(bradfordcsmith): implement removal without losing side-effects for this case varInfo.setIsExplicitlyNotRemovable(); traverseNode(baseClassExpression, scope); traverseClassMembers(classBodyNode, classScope); } else { RemovableBuilder builder = new RemovableBuilder() .addContinuation(new Continuation(baseClassExpression, classScope)) .addContinuation(new Continuation(classBodyNode, classScope)); varInfo.addRemovable(builder.buildClassDeclaration(classNode)); } } private void traverseClassExpression(Node classNode, Scope scope) { checkArgument(classNode.isClass()); Node classNameNode = classNode.getFirstChild(); Node baseClassExpression = classNameNode.getNext(); Node classBodyNode = baseClassExpression.getNext(); Scope classScope = scopeCreator.createScope(classNode, scope); if (classNameNode.isName()) { // We may be able to remove the name node if nothing ends up referring to it. VarInfo varInfo = traverseNameNode(classNameNode, classScope); varInfo.addRemovable(new RemovableBuilder().buildNamedClassExpression(classNode)); } // If we're traversing the class expression, we've already decided we cannot remove it. traverseNode(baseClassExpression, scope); traverseClassMembers(classBodyNode, classScope); } private void traverseClassMembers(Node node, Scope scope) { checkArgument(node.isClassMembers(), node); if (!removeUnusedPrototypeProperties) { traverseChildren(node, scope); return; } for (Node member = node.getFirstChild(); member != null; member = member.getNext()) { switch (member.getToken()) { case GETTER_DEF: case SETTER_DEF: case MEMBER_FUNCTION_DEF: // If we get as far as traversing the members of a class, we've already decided that // we cannot remove the class itself, so just consider individual members for removal. considerForIndependentRemoval( new RemovableBuilder() .addContinuation(new Continuation(member, scope)) .buildClassOrPrototypeNamedProperty(member)); break; case COMPUTED_PROP: traverseChildren(member, scope); break; default: throw new IllegalStateException( "Unexpected child of CLASS_MEMBERS: " + member.toStringTree()); } } } /** * Traverses a function * * ES6 scopes of a function include the parameter scope and the body scope * of the function. * * Note that CATCH blocks also create a new scope, but only for the * catch variable. Declarations within the block actually belong to the * enclosing scope. Because we don't remove catch variables, there's * no need to treat CATCH blocks differently like we do functions. */ private void traverseFunction(Node function, Scope parentScope) { checkState(function.hasXChildren(3), function); checkState(function.isFunction(), function); final Node paramlist = NodeUtil.getFunctionParameters(function); final Node body = function.getLastChild(); checkState(body.getNext() == null && body.isBlock(), body); // Checking the parameters Scope fparamScope = scopeCreator.createScope(function, parentScope); // Checking the function body Scope fbodyScope = scopeCreator.createScope(body, fparamScope); Node nameNode = function.getFirstChild(); if (!nameNode.getString().isEmpty()) { // var x = function funcName() {}; // make sure funcName gets into the varInfoMap so it will be considered for removal. VarInfo varInfo = traverseNameNode(nameNode, fparamScope); if (NodeUtil.isExpressionResultUsed(function)) { // var f = function g() {}; // The f is an alias for g, so g escapes from the scope where it is defined. varInfo.hasNonLocalOrNonLiteralValue = true; } } traverseNode(paramlist, fparamScope); traverseChildren(body, fbodyScope); allFunctionParamScopes.add(fparamScope); } private boolean canRemoveParameters(Node parameterList) { checkState(parameterList.isParamList()); Node function = parameterList.getParent(); return removeGlobals && !NodeUtil.isGetOrSetKey(function.getParent()); } /** * Removes unreferenced arguments from a function declaration and when * possible the function's callSites. * * @param fparamScope The function parameter */ private void removeUnreferencedFunctionArgs(Scope fparamScope) { // Notice that removing unreferenced function args breaks // Function.prototype.length. In advanced mode, we don't really care // about this: we consider "length" the equivalent of reflecting on // the function's lexical source. // // Rather than create a new option for this, we assume that if the user // is removing globals, then it's OK to remove unused function args. // // See http://blickly.github.io/closure-compiler-issues/#253 if (!removeGlobals) { return; } Node function = fparamScope.getRootNode(); checkState(function.isFunction()); if (NodeUtil.isGetOrSetKey(function.getParent())) { // The parameters object literal setters can not be removed. return; } Node argList = NodeUtil.getFunctionParameters(function); // Strip as many unreferenced args off the end of the function declaration as possible. maybeRemoveUnusedTrailingParameters(argList, fparamScope); // Mark any remaining unused parameters are unused to OptimizeParameters can try to remove // them. markUnusedParameters(argList, fparamScope); } private void markPropertyNameAsPinned(String propertyName) { if (pinnedPropertyNames.add(propertyName)) { // Continue traversal of all of the property name's values and no longer consider them for // removal. for (Removable removable : removablesForPropertyNames.removeAll(propertyName)) { removable.applyContinuations(); } } } private void considerForIndependentRemoval(Removable removable) { if (removable.isNamedProperty()) { String propertyName = removable.getPropertyName(); if (pinnedPropertyNames.contains(propertyName) || codingConvention.isExported(propertyName)) { // Referenced or exported, so not removable. removable.applyContinuations(); } else if (isIndependentlyRemovable(removable)) { // Store for possible removal later. removablesForPropertyNames.put(propertyName, removable); } else { removable.applyContinuations(); // This assignment counts as a reference, since we won't be removing it. // This is necessary in order to preserve getters and setters for the property. markPropertyNameAsPinned(propertyName); } } else { removable.applyContinuations(); } } /** @return Whether or not accessor side-effect are a possibility. */ private boolean considerForAccessorSideEffects(Node getprop, PropertyAccessKind usage) { checkState(getprop.isGetProp(), getprop); // Other node types may make sense in the future. String propName = getprop.getSecondChild().getString(); PropertyAccessKind recorded = compiler.getAccessorSummary().getKind(propName); if ((recorded.hasGetter() && usage.hasGetter() && !assumeGettersArePure) || (recorded.hasSetter() && usage.hasSetter())) { markPropertyNameAsPinned(propName); return true; } return false; } private boolean isIndependentlyRemovable(Removable removable) { return (removeUnusedPrototypeProperties && removable.isPrototypeProperty()) || (removeUnusedThisProperties && removable.isThisDotPropertyReference()) || (removeUnusedObjectDefinePropertiesDefinitions && removable.isObjectDefinePropertiesDefinition()) || (removeUnusedStaticProperties && removable.isStaticProperty()); } /** * Mark any remaining unused parameters as being unused so it can be used elsewhere. * * @param paramList list of function's parameters * @param fparamScope */ private void markUnusedParameters(Node paramList, Scope fparamScope) { for (Node param = paramList.getFirstChild(); param != null; param = param.getNext()) { if (param.isUnusedParameter()) { continue; } Node lValue = nameOfParam(param); if (lValue == null) { continue; } VarInfo varInfo = traverseNameNode(lValue, fparamScope); if (varInfo.isRemovable()) { param.setUnusedParameter(true); compiler.reportChangeToEnclosingScope(paramList); } } } /** * Strip as many unreferenced args off the end of the function declaration as possible. We start * from the end of the function declaration because removing parameters from the middle of the * param list could mess up the interpretation of parameters being sent over by any function * calls. * * @param argList list of function's arguments * @param fparamScope */ private void maybeRemoveUnusedTrailingParameters(Node argList, Scope fparamScope) { Node lastArg; while ((lastArg = argList.getLastChild()) != null) { Node lValue = lastArg; if (lastArg.isDefaultValue()) { lValue = lastArg.getFirstChild(); if (astAnalyzer.mayHaveSideEffects(lastArg.getLastChild())) { break; } } if (lValue.isRest()) { lValue = lValue.getFirstChild(); } if (lValue.isDestructuringPattern()) { if (lValue.hasChildren()) { // TODO(johnlenz): handle the case where there are no assignments. break; } else { // Remove empty destructuring patterns and their associated object literal assignment // if it exists and if the right hand side does not have side effects. Note, a // destructuring pattern with a "leftover" property key as in {a:{}} is not considered // empty in this case! NodeUtil.deleteNode(lastArg, compiler); continue; } } VarInfo varInfo = getVarInfo(getVarForNameNode(lValue, fparamScope)); if (varInfo.isRemovable()) { NodeUtil.deleteNode(lastArg, compiler); } else { break; } } } /** * Handles a variable reference seen during traversal and returns a {@link VarInfo} object * appropriate for the given {@link Var}. * *

This is a wrapper for {@link #getVarInfo} that handles additional logic needed when we're * getting the {@link VarInfo} during traversal. */ private VarInfo traverseVar(Var var) { checkNotNull(var); if (removeLocalVars && var.isArguments()) { // If we are considering removing local variables, that includes parameters. // If `arguments` is used in a function we must consider all parameters to be referenced. Scope functionScope = var.getScope().getClosestHoistScope(); Node paramList = NodeUtil.getFunctionParameters(functionScope.getRootNode()); for (Node param = paramList.getFirstChild(); param != null; param = param.getNext()) { Node lValue = nameOfParam(param); if (lValue == null) { continue; } getVarInfo(getVarForNameNode(lValue, functionScope)).markAsReferenced(); } // `arguments` is never removable. return canonicalUnremovableVarInfo; } else { return getVarInfo(var); } } /** * Return the NAME node associated with a function parameter (the child of a PARAM_LIST), or null * if there is no single name. */ @Nullable private static Node nameOfParam(Node param) { switch (param.getToken()) { case NAME: return param; case DEFAULT_VALUE: return nameOfParam(param.getFirstChild()); case ITER_REST: return nameOfParam(param.getOnlyChild()); case ARRAY_PATTERN: case OBJECT_PATTERN: return null; default: throw new IllegalStateException("Unexpected child of PARAM_LIST: " + param.toStringTree()); } } /** * Get the right {@link VarInfo} object to use for the given {@link Var}. * *

This method is responsible for managing the entries in {@link #varInfoMap}. *

Note: Several {@link Var}s may share the same {@link VarInfo} when they should be treated * the same way. */ private VarInfo getVarInfo(Var var) { checkNotNull(var); boolean isGlobal = var.isGlobal(); if (var.isExtern()) { return canonicalUnremovableVarInfo; } else if (isGlobal && !removeGlobals) { return canonicalUnremovableVarInfo; } else if (!isGlobal && !removeLocalVars) { return canonicalUnremovableVarInfo; } else if (codingConvention.isExported(var.getName(), !isGlobal)) { return canonicalUnremovableVarInfo; } else if (var.isArguments()) { return canonicalUnremovableVarInfo; } else { VarInfo varInfo = varInfoMap.get(var); if (varInfo == null) { varInfo = new VarInfo(); if (var.getParentNode().isParamList()) { varInfo.hasNonLocalOrNonLiteralValue = true; } varInfoMap.put(var, varInfo); } return varInfo; } } /** * Removes any vars in the scope that were not referenced. Removes any assignments to those * variables as well. */ private void removeUnreferencedVarsAndPolyfills() { for (Entry entry : varInfoMap.entrySet()) { Var var = entry.getKey(); VarInfo varInfo = entry.getValue(); if (!varInfo.isRemovable()) { continue; } // Regardless of what happens to the original declaration, // we need to remove all assigns, because they may contain references // to other unreferenced variables. varInfo.removeAllRemovables(); Node nameNode = var.nameNode; Node toRemove = nameNode.getParent(); if (toRemove == null || alreadyRemoved(toRemove)) { // assignedVarInfo.removeAllRemovables () already removed it } else if (NodeUtil.isFunctionExpression(toRemove)) { // TODO(bradfordcsmith): Add a Removable for this case. if (!preserveFunctionExpressionNames) { Node fnNameNode = toRemove.getFirstChild(); compiler.reportChangeToEnclosingScope(fnNameNode); fnNameNode.setString(""); } } else { // Removables are not created for theses cases. // function foo(unused1 = someSideEffectingValue, ...unused2) {} // removeUnreferencedFunctionArgs() is responsible for removing these. // TODO(bradfordcsmith): handle parameter declarations with removables checkState( toRemove.isParamList() || (toRemove.getParent().isParamList() && (toRemove.isDefaultValue() || toRemove.isRest())), "unremoved code: %s", toRemove); } } Iterator iter = polyfills.values().iterator(); while (iter.hasNext()) { PolyfillInfo polyfill = iter.next(); if (polyfill.isRemovable) { polyfill.removable.remove(compiler); iter.remove(); } } } /** * Our progress in a traversal can be expressed completely as the * current node and scope. The continuation lets us save that * information so that we can continue the traversal later. */ private class Continuation { private final Node node; private final Scope scope; Continuation(Node node, Scope scope) { this.node = node; this.scope = scope; } void apply() { if (node.isFunction()) { // Calling traverseNode here would create infinite recursion for a function declaration traverseFunction(node, scope); } else { traverseNode(node, scope); } } } /** Represents a portion of the AST that can be removed. */ private abstract class Removable { private final List continuations; @Nullable private final String propertyName; private final boolean isPrototypeDotPropertyReference; private final boolean isThisDotPropertyReference; private boolean continuationsAreApplied = false; private boolean isRemoved = false; Removable(RemovableBuilder builder) { continuations = builder.continuations; propertyName = builder.propertyName; isPrototypeDotPropertyReference = builder.isPrototypeDotPropertyReference; isThisDotPropertyReference = builder.isThisDotPropertyReference; } String getPropertyName() { return checkNotNull(propertyName); } /** Remove the associated nodes from the AST. */ abstract void removeInternal(AbstractCompiler compiler); /** Remove the associated nodes from the AST, unless they've already been removed. */ void remove(AbstractCompiler compiler) { if (!isRemoved) { isRemoved = true; removeInternal(compiler); } } public void applyContinuations() { if (!continuationsAreApplied) { continuationsAreApplied = true; for (Continuation c : continuations) { // Enqueue the continuation for processing. // Don't invoke the continuation immediately, because that can lead to concurrent // modification of data structures. worklist.add(c); } continuations.clear(); } } /** True if this object represents assignment to a variable. */ boolean isVariableAssignment() { return false; } /** True if this object represents a named property, either assignment or declaration. */ boolean isNamedProperty() { return propertyName != null; } /** * True if this object represents assignment to a named property. * *

This does not include class or object literal member declarations. */ boolean isNamedPropertyAssignment() { return false; } boolean isAssignedValueLocal() { return false; // assume non-local by default } /** Is this a direct assignment to `varName.prototype`? */ boolean isPrototypeAssignment() { return isNamedPropertyAssignment() && propertyName.equals("prototype"); } /** Is this an assignment to a property on a prototype object? */ boolean isPrototypeDotPropertyReference() { return isPrototypeDotPropertyReference; } boolean isClassOrPrototypeNamedProperty() { return false; } boolean isPrototypeProperty() { return isPrototypeDotPropertyReference() || isClassOrPrototypeNamedProperty(); } boolean isThisDotPropertyReference() { return isThisDotPropertyReference; } public boolean isObjectDefinePropertiesDefinition() { return false; } public boolean isStaticProperty() { return false; } /** * Would a nonlocal or nonliteral value prevent removal of a variable associated with this * {@link Removable}? * *

True if the nature of this removable is such that a variable associated with it must not * be removed if its value or its prototype is not a local, literal value. * *

e.g. When X or X.prototype is nonlocal and / or nonliteral we don't know whether it is * safe to remove code like this. * *


     *   X.propName = something; // Don't know the effect of setting X.propName
     *   use(something instanceof X); // can't be certain there are no instances of X
     * 
*/ public boolean preventsRemovalOfVariableWithNonLocalValueOrPrototype() { return false; } } private class RemovableBuilder { final List continuations = new ArrayList<>(); @Nullable String propertyName = null; boolean isPrototypeDotPropertyReference = false; boolean isThisDotPropertyReference = false; RemovableBuilder addContinuation(Continuation continuation) { continuations.add(continuation); return this; } RemovableBuilder setIsPrototypeDotPropertyReference(boolean value) { this.isPrototypeDotPropertyReference = value; return this; } RemovableBuilder setIsThisDotPropertyReference(boolean value) { this.isThisDotPropertyReference = value; return this; } IndirectAssign buildIndirectAssign(Node root, Node targetNode) { return new IndirectAssign(this, root, targetNode); } Polyfill buildPolyfill(Node polyfillNode) { return new Polyfill(this, polyfillNode); } ClassDeclaration buildClassDeclaration(Node classNode) { return new ClassDeclaration(this, classNode); } NamedClassExpression buildNamedClassExpression(Node classNode) { return new NamedClassExpression(this, classNode); } ClassOrPrototypeNamedProperty buildClassOrPrototypeNamedProperty(Node propertyNode) { checkArgument( propertyNode.isMemberFunctionDef() || NodeUtil.isGetOrSetKey(propertyNode) || (propertyNode.isStringKey() && !propertyNode.isQuotedString()), propertyNode); this.propertyName = propertyNode.getString(); return new ClassOrPrototypeNamedProperty(this, propertyNode); } ObjectDefinePropertiesDefinition buildObjectDefinePropertiesDefinition(Node propertyNode) { this.propertyName = propertyNode.getString(); return new ObjectDefinePropertiesDefinition(this, propertyNode); } FunctionDeclaration buildFunctionDeclaration(Node functionNode) { return new FunctionDeclaration(this, functionNode); } NameDeclarationStatement buildNameDeclarationStatement(Node declarationStatement) { return new NameDeclarationStatement(this, declarationStatement); } Assign buildNamedPropertyAssign(Node assignNode, Node propertyNode) { this.propertyName = propertyNode.getString(); return new Assign(this, assignNode, Kind.NAMED_PROPERTY, propertyNode); } Assign buildComputedPropertyAssign(Node assignNode, Node propertyNode) { return new Assign(this, assignNode, Kind.COMPUTED_PROPERTY, propertyNode); } Assign buildVariableAssign(Node assignNode) { return new Assign(this, assignNode, Kind.VARIABLE, /* propertyNode */ null); } ClassSetupCall buildClassSetupCall(Node callNode) { return new ClassSetupCall(this, callNode); } VanillaForNameDeclaration buildVanillaForNameDeclaration(Node nameNode) { return new VanillaForNameDeclaration(this, nameNode); } AnonymousPrototypeNamedPropertyAssign buildAnonymousPrototypeNamedPropertyAssign( Node assignNode, String propertyName) { this.propertyName = propertyName; return new AnonymousPrototypeNamedPropertyAssign(this, assignNode); } IncOrDecOp buildIncOrDepOp(Node incOrDecOp, Node propertyNode, @Nullable Node toPreseve) { this.propertyName = propertyNode.getString(); return new IncOrDecOp(this, incOrDecOp, toPreseve); } UnusedReadReference buildUnusedReadReference(Node referenceNode, Node propertyNode) { this.propertyName = propertyNode.getString(); return new UnusedReadReference(this, referenceNode); } public Removable buildInstanceofName(Node instanceofNode) { return new InstanceofName(this, instanceofNode); } } /** Represents a read reference whose value is not used. */ private class UnusedReadReference extends Removable { final Node referenceNode; UnusedReadReference(RemovableBuilder builder, Node referenceNode) { super(builder); // TODO(bradfordcsmith): handle `name;` and `name.property;` references checkState( isThisDotProperty(referenceNode) || isDotPrototypeDotProperty(referenceNode), referenceNode); this.referenceNode = referenceNode; } @Override void removeInternal(AbstractCompiler compiler) { if (!alreadyRemoved(referenceNode)) { if (isThisDotProperty(referenceNode)) { removeExpressionCompletely(referenceNode); } else { checkState(isDotPrototypeDotProperty(referenceNode), referenceNode); // objExpression.prototype.propertyName Node objExpression = referenceNode.getFirstFirstChild(); if (astAnalyzer.mayHaveSideEffects(objExpression)) { replaceNodeWith(referenceNode, objExpression.detach()); } else { removeExpressionCompletely(referenceNode); } } } } @Override public String toString() { return "UnusedReadReference:" + referenceNode; } } /** * Represents `something instanceof varName`. * *

If `varName` is removed, this expression can be replaced with `false` or * `(something, false)` to preserve side effects. */ private class InstanceofName extends Removable { final Node instanceofNode; InstanceofName(RemovableBuilder builder, Node instanceofNode) { super(builder); checkArgument(instanceofNode.isInstanceOf(), instanceofNode); this.instanceofNode = instanceofNode; } @Override void removeInternal(AbstractCompiler compiler) { if (!alreadyRemoved(instanceofNode)) { Node lhs = instanceofNode.getFirstChild(); Node falseNode = IR.falseNode().srcref(instanceofNode); if (astAnalyzer.mayHaveSideEffects(lhs)) { replaceNodeWith(instanceofNode, IR.comma(lhs.detach(), falseNode).srcref(instanceofNode)); } else { replaceNodeWith(instanceofNode, falseNode); } } } @Override public boolean preventsRemovalOfVariableWithNonLocalValueOrPrototype() { // If we aren't sure where X comes from and what aliases it might have, we cannot be sure // there are no instances of it. return true; } @Override public String toString() { return "InstanceofName:" + instanceofNode; } } /** Represents an increment or decrement operation that could be removed. */ private class IncOrDecOp extends Removable { final Node incOrDecNode; @Nullable final Node toPreserve; IncOrDecOp(RemovableBuilder builder, Node incOrDecNode, @Nullable Node toPreserve) { super(builder); checkArgument(incOrDecNode.isInc() || incOrDecNode.isDec(), incOrDecNode); Node arg = incOrDecNode.getOnlyChild(); // TODO(bradfordcsmith): handle `name;` and `name.property;` references checkState(isThisDotProperty(arg) || isDotPrototypeDotProperty(arg), arg); this.incOrDecNode = incOrDecNode; this.toPreserve = toPreserve; } @Override void removeInternal(AbstractCompiler compiler) { if (alreadyRemoved(incOrDecNode)) { return; } Node arg = incOrDecNode.getOnlyChild(); checkState(arg.isGetProp(), arg); if (this.toPreserve == null) { removeExpressionCompletely(incOrDecNode); } else { replaceNodeWith(incOrDecNode, toPreserve.detach()); } } @Override public String toString() { return "IncOrDecOp:" + incOrDecNode; } } /** True for `this.propertyName` */ private static boolean isThisDotProperty(Node n) { return n.isGetProp() && n.getFirstChild().isThis(); } /** True for `(something).prototype.propertyName` */ private static boolean isDotPrototypeDotProperty(Node n) { return n.isGetProp() && isDotPrototype(n.getFirstChild()); } private class IndirectAssign extends Removable { /** The subtree which can be removed if the assignment is removable. */ final Node root; /** The l-value expression below root. */ final Node targetNode; IndirectAssign(RemovableBuilder builder, Node root, Node targetNode) { super(builder); Node rootParent = root.getParent(); checkState(rootParent.isDestructuringPattern() || rootParent.isParamList(), rootParent); checkState(targetNode.isName() || targetNode.isGetProp(), targetNode); this.root = root; this.targetNode = targetNode; } @Override boolean isVariableAssignment() { return targetNode.isName(); } @Override boolean isThisDotPropertyReference() { return isThisDotProperty(targetNode); } @Override boolean isNamedProperty() { return targetNode.isGetProp(); } @Override public boolean preventsRemovalOfVariableWithNonLocalValueOrPrototype() { if (targetNode.isGetProp()) { Node getPropLhs = targetNode.getFirstChild(); // assignment to varName.property or varName.prototype.property // cannot be removed unless varName and varName.prototype have literal, local values. return getPropLhs.isName() || isNameDotPrototype(getPropLhs); } else { return false; } } @Override boolean isNamedPropertyAssignment() { return targetNode.isGetProp(); } @Override String getPropertyName() { checkState(targetNode.isGetProp(), targetNode); return targetNode.getLastChild().getString(); } @Override public void removeInternal(AbstractCompiler compiler) { if (!alreadyRemoved(targetNode)) { removeRoot(); } } private void removeRoot() { Node rootParent = root.getParent(); switch (rootParent.getToken()) { case ARRAY_PATTERN: // [a, root, b] = something; // [a, root] = something; // Replace root with an empty node to avoid messing up the order of patterns, // then clean up trailing empties. replaceNodeWith(root, IR.empty().srcref(root)); // We prefer `[a, b]` to `[a, b, , , , ]` // So remove any trailing empty nodes. for (Node maybeEmpty = rootParent.getLastChild(); maybeEmpty != null && maybeEmpty.isEmpty(); maybeEmpty = rootParent.getLastChild()) { maybeEmpty.detach(); } compiler.reportChangeToEnclosingScope(rootParent); // TODO(bradfordcsmith): If the array pattern is now empty, try to remove it entirely. break; case PARAM_LIST: if (!root.isDefaultValue()) { // removeUnreferencedFunctionArgs() is responsible for removal of function parameter // positions, so all we can do here is remove the default value. // NOTE: traverseRest() avoids creating a removable for a rest parameter. // TODO(bradfordcsmith): Handle parameter removal consistently with other removals. return; } // function(removableName = removableValue) compiler.reportChangeToEnclosingScope(rootParent); // preserve the slot in the parameter list Node name = root.getFirstChild(); checkState(name.isName()); if (root == rootParent.getLastChild() && removeGlobals && canRemoveParameters(rootParent)) { // function(p1, removableName = removableDefault) // and we're allowed to remove the parameter entirely root.detach(); } else { // function(removableName = removableDefault, otherParam) // or removableName is at the end, but cannot be completely removed. root.replaceWith(name.detach()); } NodeUtil.markFunctionsDeleted(root, compiler); break; case OBJECT_PATTERN: // ({ [propExpression]: root } = something) // becomes // ({} = something) NodeUtil.deleteNode(root, compiler); break; default: throw new IllegalStateException( "Unexpected parent of indirect assignment: " + rootParent.toStringTree()); } } } /** A call to $jscomp.polyfill that can be removed if it is no longer referenced. */ private class Polyfill extends Removable { final Node polyfillNode; Polyfill(RemovableBuilder builder, Node polyfillNode) { super(builder); this.polyfillNode = polyfillNode; } @Override public void removeInternal(AbstractCompiler compiler) { NodeUtil.deleteNode(polyfillNode, compiler); } @Override public String toString() { return "Polyfill:" + polyfillNode; } } private class ClassDeclaration extends Removable { final Node classDeclarationNode; ClassDeclaration(RemovableBuilder builder, Node classDeclarationNode) { super(builder); this.classDeclarationNode = classDeclarationNode; } @Override public void removeInternal(AbstractCompiler compiler) { NodeUtil.deleteNode(classDeclarationNode, compiler); } @Override public String toString() { return "ClassDeclaration:" + classDeclarationNode; } } private class NamedClassExpression extends Removable { final Node classNode; NamedClassExpression(RemovableBuilder builder, Node classNode) { super(builder); this.classNode = classNode; } @Override public void removeInternal(AbstractCompiler compiler) { if (!alreadyRemoved(classNode)) { Node nameNode = classNode.getFirstChild(); if (!nameNode.isEmpty()) { // Just empty the class's name. If the expression is assigned to an unused variable, // then the whole class might still be removed as part of that assignment. classNode.replaceChild(nameNode, IR.empty().useSourceInfoFrom(nameNode)); compiler.reportChangeToEnclosingScope(classNode); } } } @Override public String toString() { return "NamedClassExpression:" + classNode; } } private class ClassOrPrototypeNamedProperty extends Removable { final Node propertyNode; ClassOrPrototypeNamedProperty(RemovableBuilder builder, Node propertyNode) { super(builder); this.propertyNode = propertyNode; } @Override public boolean isStaticProperty() { return propertyNode.isStaticMember(); } @Override boolean isClassOrPrototypeNamedProperty() { return !isStaticProperty(); } @Override void removeInternal(AbstractCompiler compiler) { NodeUtil.deleteNode(propertyNode, compiler); } @Override public String toString() { return "ClassOrPrototypeNamedProperty:" + propertyNode; } } /** * Represents a single property definition in the object literal passed as the second argument to * e.g. `Object.defineProperties(obj, {p1: {value: 1}, p2: {value: 3}});`. */ private class ObjectDefinePropertiesDefinition extends Removable { final Node propertyNode; ObjectDefinePropertiesDefinition(RemovableBuilder builder, Node propertyNode) { super(builder); this.propertyNode = propertyNode; } @Override public boolean isObjectDefinePropertiesDefinition() { return true; } @Override void removeInternal(AbstractCompiler compiler) { NodeUtil.deleteNode(propertyNode, compiler); } } private class FunctionDeclaration extends Removable { final Node functionDeclarationNode; FunctionDeclaration(RemovableBuilder builder, Node functionDeclarationNode) { super(builder); this.functionDeclarationNode = functionDeclarationNode; } @Override public void removeInternal(AbstractCompiler compiler) { NodeUtil.deleteNode(functionDeclarationNode, compiler); } @Override boolean isAssignedValueLocal() { // The declared function is always created locally. return true; } @Override public String toString() { return "FunctionDeclaration:" + functionDeclarationNode; } } private class NameDeclarationStatement extends Removable { private final Node declarationStatement; public NameDeclarationStatement(RemovableBuilder builder, Node declarationStatement) { super(builder); checkArgument(NodeUtil.isNameDeclaration(declarationStatement), declarationStatement); this.declarationStatement = declarationStatement; } @Override void removeInternal(AbstractCompiler compiler) { Node nameNode = declarationStatement.getOnlyChild(); Node valueNode = nameNode.getFirstChild(); if (valueNode != null && astAnalyzer.mayHaveSideEffects(valueNode)) { compiler.reportChangeToEnclosingScope(declarationStatement); valueNode.detach(); declarationStatement.replaceWith(IR.exprResult(valueNode).useSourceInfoFrom(valueNode)); } else { NodeUtil.deleteNode(declarationStatement, compiler); } } @Override boolean isVariableAssignment() { return true; } @Override boolean isAssignedValueLocal() { Node nameNode = declarationStatement.getOnlyChild(); Node valueNode = nameNode.getFirstChild(); return valueNode == null || isLocalDefaultValueAssignment(nameNode, valueNode) || NodeUtil.evaluatesToLocalValue(valueNode); } @Override public String toString() { return "NameDeclStmt:" + declarationStatement; } } /** * True if targetNode is a qualified name and the valueNode is of the form `targetQualifiedName || * localValue`. */ private static boolean isLocalDefaultValueAssignment(Node targetNode, Node valueNode) { return valueNode.isOr() && targetNode.isQualifiedName() && valueNode.getFirstChild().isEquivalentTo(targetNode) && NodeUtil.evaluatesToLocalValue(valueNode.getLastChild()); } enum Kind { // X = something; VARIABLE, // X.propertyName = something; // X.prototype.propertyName = something; NAMED_PROPERTY, // X[expression] = something; // X.prototype[expression] = something; COMPUTED_PROPERTY; } private class Assign extends Removable { final Node assignNode; final Kind kind; Assign( RemovableBuilder builder, Node assignNode, Kind kind, @Nullable Node propertyNode) { super(builder); checkArgument(NodeUtil.isAssignmentOp(assignNode), assignNode); if (kind == Kind.VARIABLE) { checkArgument( propertyNode == null, "got property node for simple variable assignment: %s", propertyNode); } else { checkArgument(propertyNode != null, "missing property node"); if (kind == Kind.NAMED_PROPERTY) { checkArgument(propertyNode.isString(), "property name is not a string: %s", propertyNode); } } this.assignNode = assignNode; this.kind = kind; } /** True for `varName = value` assignments. */ @Override boolean isVariableAssignment() { return kind == Kind.VARIABLE; } @Override boolean isAssignedValueLocal() { if (NodeUtil.isExpressionResultUsed(assignNode)) { // assigned value may escape or be aliased return false; } else { Node targetNode = assignNode.getFirstChild(); Node valueNode = targetNode.getNext(); return NodeUtil.evaluatesToLocalValue(valueNode) || isLocalDefaultValueAssignment(targetNode, valueNode); } } @Override public boolean preventsRemovalOfVariableWithNonLocalValueOrPrototype() { // If we don't know where the variable comes from or where it may go, then we don't know // whether it is safe to remove assignments to properties on it. return isNamedPropertyAssignment() || isComputedPropertyAssignment(); } /** True for `varName.propName = value` and `varName.prototype.propName = value` assignments. */ @Override boolean isNamedPropertyAssignment() { return kind == Kind.NAMED_PROPERTY; } /** True for `varName[expr] = value` and `varName.prototype[expr] = value` assignments. */ boolean isComputedPropertyAssignment() { return kind == Kind.COMPUTED_PROPERTY; } @Override public boolean isStaticProperty() { Node lhs = assignNode.getFirstChild(); if (lhs.isGetProp()) { // something.propName = someValue Node getPropLhs = lhs.getFirstChild(); JSType typeI = getPropLhs.getJSType(); return typeI != null && (typeI.isConstructor() || typeI.isInterface()); } else { return false; } } /** Replace the current assign with its right hand side. */ @Override public void removeInternal(AbstractCompiler compiler) { if (alreadyRemoved(assignNode)) { return; } Node parent = assignNode.getParent(); compiler.reportChangeToEnclosingScope(parent); Node lhs = assignNode.getFirstChild(); Node rhs = assignNode.getSecondChild(); boolean mustPreserveRhs = astAnalyzer.mayHaveSideEffects(rhs) || NodeUtil.isExpressionResultUsed(assignNode); boolean mustPreserveGetElmExpr = lhs.isGetElem() && astAnalyzer.mayHaveSideEffects(lhs.getLastChild()); if (mustPreserveRhs && mustPreserveGetElmExpr) { Node replacement = IR.comma(lhs.getLastChild().detach(), rhs.detach()).useSourceInfoFrom(assignNode); replaceNodeWith(assignNode, replacement); } else if (mustPreserveGetElmExpr) { replaceNodeWith(assignNode, lhs.getLastChild().detach()); } else if (mustPreserveRhs) { replaceNodeWith(assignNode, rhs.detach()); } else { removeExpressionCompletely(assignNode); } } @Override public String toString() { return "Assign:" + assignNode; } } /** Represents `(someObjectExpression).prototype.propertyName = someValue`. */ private class AnonymousPrototypeNamedPropertyAssign extends Removable { final Node assignNode; AnonymousPrototypeNamedPropertyAssign(RemovableBuilder builder, Node assignNode) { super(builder); checkNotNull(builder.propertyName); checkArgument(assignNode.isAssign(), assignNode); this.assignNode = assignNode; } @Override void removeInternal(AbstractCompiler compiler) { if (alreadyRemoved(assignNode)) { return; } Node parent = assignNode.getParent(); compiler.reportChangeToEnclosingScope(parent); Node lhs = assignNode.getFirstChild(); Node rhs = assignNode.getLastChild(); checkState(lhs.isGetProp(), lhs); Node objDotPrototype = lhs.getFirstChild(); checkState(objDotPrototype.isGetProp(), objDotPrototype); Node objExpression = objDotPrototype.getFirstChild(); Node prototype = objDotPrototype.getLastChild(); checkState(prototype.getString().equals("prototype"), prototype); boolean mustPreserveRhs = astAnalyzer.mayHaveSideEffects(rhs) || NodeUtil.isExpressionResultUsed(assignNode); boolean mustPreserveObjExpression = astAnalyzer.mayHaveSideEffects(objExpression); if (mustPreserveRhs && mustPreserveObjExpression) { Node replacement = IR.comma(objExpression.detach(), rhs.detach()).useSourceInfoFrom(assignNode); replaceNodeWith(assignNode, replacement); } else if (mustPreserveObjExpression) { replaceNodeWith(assignNode, objExpression.detach()); } else if (mustPreserveRhs) { replaceNodeWith(assignNode, rhs.detach()); } else { removeExpressionCompletely(assignNode); } } @Override boolean isPrototypeProperty() { return true; } @Override public String toString() { return "AnonymousPrototypeNamedPropertyAssign:" + assignNode; } } /** * Represents a call to a class setup method such as `goog.inherits()` or * `goog.addSingletonGetter()`. */ private class ClassSetupCall extends Removable { final Node callNode; ClassSetupCall(RemovableBuilder builder, Node callNode) { super(builder); this.callNode = callNode; } @Override public void removeInternal(AbstractCompiler compiler) { Node parent = callNode.getParent(); Node replacement = null; // Need to keep call args that have side effects. // Easiest thing to do is break apart the call node as we go. // First child is the callee (aka. Object.defineProperties or equivalent) callNode.removeFirstChild(); for (Node arg = callNode.getLastChild(); arg != null; arg = callNode.getLastChild()) { arg.detach(); if (astAnalyzer.mayHaveSideEffects(arg)) { if (replacement == null) { replacement = arg; } else { replacement = IR.comma(arg, replacement).srcref(callNode); } } else { NodeUtil.markFunctionsDeleted(arg, compiler); } } // NOTE: The call must either be its own statement or the LHS of a comma expression, // because it doesn't have a meaningful return value. if (replacement != null) { replaceNodeWith(callNode, replacement); } else if (parent.isExprResult()) { NodeUtil.deleteNode(parent, compiler); } else { // `(goog.inherits(A, B), something)` -> `something` checkState(parent.isComma()); Node rhs = checkNotNull(callNode.getNext()); compiler.reportChangeToEnclosingScope(parent); parent.replaceWith(rhs.detach()); } } @Override public boolean preventsRemovalOfVariableWithNonLocalValueOrPrototype() { // If we aren't sure where X comes from and what aliases it might have, we cannot be sure // it's safe to remove the class setup for it. return true; } @Override public String toString() { return "ClassSetupCall:" + callNode; } } private static boolean alreadyRemoved(Node n) { Node parent = n.getParent(); if (parent == null) { return true; } if (parent.isRoot()) { return false; } return alreadyRemoved(parent); } private class VarInfo { /** * Objects that represent variable declarations, assignments, or class setup calls that can * be removed. * * NOTE: Once we realize that we cannot remove the variable, this list will be cleared and * no more will be added. */ final List removables = new ArrayList<>(); boolean isEntirelyRemovable = true; boolean hasNonLocalOrNonLiteralValue = false; boolean requiresLocalLiteralValueForRemoval = false; void addRemovable(Removable removable) { if (!removable.isAssignedValueLocal() && (removable.isVariableAssignment() || removable.isPrototypeAssignment())) { hasNonLocalOrNonLiteralValue = true; } if (removable.preventsRemovalOfVariableWithNonLocalValueOrPrototype()) { requiresLocalLiteralValueForRemoval = true; } if (hasNonLocalOrNonLiteralValue && requiresLocalLiteralValueForRemoval) { setIsExplicitlyNotRemovable(); } if (isEntirelyRemovable) { // Store for possible removal later. removables.add(removable); } else { considerForIndependentRemoval(removable); } } /** * Marks this variable as referenced and evaluates any continuations if not previously marked as * referenced. * * @return true if the variable was not already marked as referenced */ boolean markAsReferenced() { return setIsExplicitlyNotRemovable(); } boolean isRemovable() { return isEntirelyRemovable; } boolean setIsExplicitlyNotRemovable() { if (isEntirelyRemovable) { isEntirelyRemovable = false; for (Removable r : removables) { considerForIndependentRemoval(r); } removables.clear(); return true; } else { return false; } } void removeAllRemovables() { checkState(isEntirelyRemovable); for (Removable removable : removables) { removable.remove(compiler); } removables.clear(); } } /** * Makes a new PolyfillInfo, including the correct Removable. Parses the name to determine whether * this is a global, static, or prototype polyfill. */ private PolyfillInfo createPolyfillInfo(Node call, Scope scope, String name) { checkState(scope.isGlobal()); checkState(call.getParent().isExprResult()); // Make the removable and polyfill info. Add continuations for all arguments. RemovableBuilder builder = new RemovableBuilder(); for (Node n = call.getFirstChild().getNext(); n != null; n = n.getNext()) { builder.addContinuation(new Continuation(n, scope)); } Polyfill removable = builder.buildPolyfill(call.getParent()); int lastDot = name.lastIndexOf("."); if (lastDot < 0) { return new GlobalPolyfillInfo(removable, name); } String owner = name.substring(0, lastDot); String prop = name.substring(lastDot + 1); boolean typed = call.getJSType() != null; if (owner.endsWith(DOT_PROTOTYPE)) { owner = owner.substring(0, owner.length() - DOT_PROTOTYPE.length()); return new PrototypePropertyPolyfillInfo( removable, prop, typed ? compiler.getTypeRegistry().getType(scope, owner) : null); } ObjectType ownerInstanceType = typed ? ObjectType.cast(compiler.getTypeRegistry().getType(scope, owner)) : null; JSType ownerCtorType = ownerInstanceType != null ? ownerInstanceType.getConstructor() : null; return new StaticPropertyPolyfillInfo(removable, prop, ownerCtorType, owner); } private static final String DOT_PROTOTYPE = ".prototype"; /** * Stores information about definitions and usages of polyfills. * *

The polyfill removal strategy is as follows. First, look for all the polyfill definitions, * whose names are stores as strings passed as the first argument to {@code $jscomp.polyfill}. * Each definition falls into one of three categories: (1) global names, such as {@code Map} or * {@code Promise}; (2) static properties, such as {@code Array.from} or {@code Reflect.get}, * which must always have exactly two name components; or (3) prototype properties, such as {@code * String.prototype.repeat} or {@code Promise.prorotype.finally}, which must always have exactly * three name components. The definition can be removed once it is found that there is an * unguarded reference to it. References guarded by existence or truthiness checks (such as * {@code if (Promise) return Promise.resolve('ok');} do not prevent removal of the polyfill * definition. * *

Determining whether a node is a reference (guarded or not) depends on the type of polyfill. * When type information is available, the type of the expected owner (i.e. the global object for * global polyfills, the namespace or class for static polyfills, or an instance of the owning * class (or its implicit prototype) for prototype polyfills) is used exclusively to determine * this with very good accuracy. Types are considered to match if a direct cast would be allowed * without a warning (i.e. some element of the union is a direct subtype or supertype). * *

When type information is not available (or is too loose) then we fall back on a heuristic: * *

    *
  • globals are referenced by any same-named NAME node or any GETPROP node whose last child * has the same string (this allows matching {@code goog.global.Map}, but will also match * {@code MyOuter.Map}). *
  • static properties are referenced by any GETPROP node whose last child is the same as the * polyfill's property name and whose owner references the polyfill owner per the above * rule. *
  • prototype properties are referenced by any GETPROP node whose last child is the same as * the polyfill's property name, regardless of its owner. *
* *

Note that this results in both false positives and false negatives in untyped code: we may * remove polyfills that are actually used (e.g. if {@code Array.from} is accessed via a subclass * as {@code SubArray.from} or in a subclass' static method as {@code this.from}) and we may * retain polyfills that are not used (e.g. if a user-defined nested class shares the same name as * a global builtin, as in {@code Foo.Map}). For greater consistency we may shift this balance in * the future to eliminate the possibility of incorrect removals, at the cost of more incorrect * retentions. */ private abstract static class PolyfillInfo { /** The {@link Polyfill} instance corresponding to the polyfill's definition. */ final Polyfill removable; /** The rightmost component of the polyfill's qualified name (does not contain a dot). */ final String key; /** Whether the polyfill is unreferenced and this can be removed safely. */ boolean isRemovable = true; PolyfillInfo(Polyfill removable, String key) { this.removable = removable; this.key = key; } /** * Accepts a NAME or GETPROP node whose (property) string matches {@code key} and checks whether * the node should be considered as a possible reference to this polyfill. If so, mark the * polyfill as referenced and therefore not removable. */ void considerPossibleReference(Node n) { if (isRemovable) { considerPossibleReferenceInternal(n); if (!isRemovable) { removable.applyContinuations(); } } } /** Template method to check the node. */ abstract void considerPossibleReferenceInternal(Node n); } private class GlobalPolyfillInfo extends PolyfillInfo { GlobalPolyfillInfo(Polyfill removable, String name) { super(removable, name); } @Override void considerPossibleReferenceInternal(Node possiblyReferencingNode) { if (possiblyReferencingNode.isName()) { // A matching NAME node must be a reference (there's no need to check that the referenced // Var is global, since local variables have all been renamed by normalization). isRemovable = false; } else if (possiblyReferencingNode.isGetProp()) { // Does the owner have type information? If so then this is a reference only if the owner // could be the global 'this' type. Absent type information, just always assume it might be. JSType ownerType = possiblyReferencingNode.getFirstChild().getJSType(); if (ownerType == null || ownerType.canCastTo( compiler.getTypeRegistry().getNativeType(JSTypeNative.GLOBAL_THIS))) { isRemovable = false; } } } } private class StaticPropertyPolyfillInfo extends PolyfillInfo { // Type of the owner, if available. @Nullable final JSType polyfillOwnerType; // Name of the owning type, used only when there's no type information. final String polyfillOwnerName; StaticPropertyPolyfillInfo( Polyfill removable, String key, @Nullable JSType owner, String ownerName) { super(removable, key); this.polyfillOwnerName = ownerName; this.polyfillOwnerType = owner; } @Override void considerPossibleReferenceInternal(Node possiblyReferencingNode) { if (!possiblyReferencingNode.isGetProp()) { return; } Node nodeOwner = possiblyReferencingNode.getFirstChild(); JSType nodeOwnerType = nodeOwner.getJSType(); if (polyfillOwnerType != null && nodeOwnerType != null) { if (typesAreRelated(polyfillOwnerType, nodeOwnerType)) { isRemovable = false; } return; } // no type information: check polyfillOwnerName instead. if ((nodeOwner.isGetProp() && nodeOwner.getLastChild().getString().equals(polyfillOwnerName)) || (nodeOwner.isName() && nodeOwner.getString().equals(polyfillOwnerName))) { isRemovable = false; } } } private class PrototypePropertyPolyfillInfo extends PolyfillInfo { @Nullable final JSType polyfillOwnerType; PrototypePropertyPolyfillInfo(Polyfill removable, String key, @Nullable JSType owner) { super(removable, key); this.polyfillOwnerType = owner; } @Override void considerPossibleReferenceInternal(Node possiblyReferencingNode) { if (!possiblyReferencingNode.isGetProp()) { return; } JSType nodeOwnerType = possiblyReferencingNode.getFirstChild().getJSType(); if (polyfillOwnerType != null && nodeOwnerType != null) { if (typesAreRelated(polyfillOwnerType, nodeOwnerType)) { isRemovable = false; } return; } // Fallback for no type information: prototype properties are simply not removable. isRemovable = false; } } private static boolean typesAreRelated(JSType expected, JSType actual) { if (actual.isConstructor() && expected.isConstructor()) { // All constructors can cast to one another, even if they're incompatible. // If both types are constructors then compare the instance types instead. actual = actual.toMaybeFunctionType().getInstanceType(); expected = expected.toMaybeFunctionType().getInstanceType(); } actual = firstNonNull(actual.autobox(), actual); return actual.canCastTo(expected); } /** * Represents declarations in the standard for-loop initialization. * *

e.g. the `let i = 0` part of `for (let i = 0; i < 10; ++i) {...}`. These must be handled * differently from declaration statements because: * *

    *
  1. For-loop declarations may declare more than one variable. The normalization doesn't break * them up as it does for declaration statements. *
  2. Removal must be handled differently. *
  3. We don't currently preserve initializers with side effects here. Instead, we just * consider such cases non-removable. *
*/ private class VanillaForNameDeclaration extends Removable { private final Node nameNode; private VanillaForNameDeclaration(RemovableBuilder builder, Node nameNode) { super(builder); this.nameNode = nameNode; } @Override void removeInternal(AbstractCompiler compiler) { Node declaration = checkNotNull(nameNode.getParent()); compiler.reportChangeToEnclosingScope(declaration); // NOTE: We don't need to preserve the initializer value, because we currently do not remove // for-loop vars whose initializing values have side effects. if (nameNode.getPrevious() == null && nameNode.getNext() == null) { // only child, so we can remove the whole declaration declaration.replaceWith(IR.empty().useSourceInfoFrom(declaration)); } else { declaration.removeChild(nameNode); } NodeUtil.markFunctionsDeleted(nameNode, compiler); } } void removeExpressionCompletely(Node expression) { checkState(!NodeUtil.isExpressionResultUsed(expression), expression); Node parent = expression.getParent(); if (parent.isExprResult()) { NodeUtil.deleteNode(parent, compiler); } else if (parent.isComma()) { // Expression is probably the first child of the comma, // but it could be the second if the entire comma expression value is unused. Node otherChild = expression.getNext(); if (otherChild == null) { otherChild = expression.getPrevious(); } replaceNodeWith(parent, otherChild.detach()); } else { // value isn't needed, but we need to keep the AST valid. replaceNodeWith(expression, IR.number(0).useSourceInfoFrom(expression)); } } void replaceNodeWith(Node n, Node replacement) { compiler.reportChangeToEnclosingScope(n); n.replaceWith(replacement); NodeUtil.markFunctionsDeleted(n, compiler); } }




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