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

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

package com.google.javascript.jscomp;

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

import com.google.javascript.jscomp.ControlFlowGraph.AbstractCfgNodeTraversalCallback;
import com.google.javascript.jscomp.ControlFlowGraph.Branch;
import com.google.javascript.jscomp.graph.GraphNode;
import com.google.javascript.jscomp.graph.LatticeElement;
import com.google.javascript.rhino.Node;
import java.util.ArrayList;
import java.util.Collection;
import java.util.HashMap;
import java.util.HashSet;
import java.util.List;
import java.util.Map;
import java.util.Map.Entry;
import java.util.Set;
import javax.annotation.Nullable;

/**
 * Computes reaching definition for all use of each variables.
 *
 * A definition of {@code A} in {@code A = foo()} is a reaching definition of
 * the use of {@code A} in {@code alert(A)} if all paths from entry node must
 * reaches that definition and it is the last definition before the use.
 */
final class MustBeReachingVariableDef extends
    DataFlowAnalysis {

  // The scope of the function that we are analyzing.
  private final AbstractCompiler compiler;
  private final Set escaped;
  private final Map allVarsInFn;
  private final List orderedVars;

  MustBeReachingVariableDef(
      ControlFlowGraph cfg,
      Scope jsScope,
      AbstractCompiler compiler,
      SyntacticScopeCreator scopeCreator) {
    super(cfg, new MustDefJoin());
    this.compiler = compiler;
    this.escaped = new HashSet<>();
    this.allVarsInFn = new HashMap<>();
    this.orderedVars = new ArrayList<>();
    computeEscaped(jsScope.getParent(), escaped, compiler, scopeCreator);
    NodeUtil.getAllVarsDeclaredInFunction(
        allVarsInFn, orderedVars, compiler, scopeCreator, jsScope.getParent());
  }

  /**
   * Abstraction of a local variable definition. It represents the node which
   * a local variable is defined as well as a set of other local variables that
   * this definition reads from. For example N: a = b + foo.bar(c). The
   * definition node will be N, the depending set would be {b,c}.
   */
  static class Definition {
    final Node node;
    final Set depends = new HashSet<>();
    private boolean unknownDependencies = false;

    Definition(Node node) {
      this.node = node;
    }

    @Override
    public boolean equals(Object other) {
      if (!(other instanceof Definition)) {
        return false;
      }
      Definition otherDef = (Definition) other;
      // If the var has the same definition node we can assume they have the
      // same depends set.
      return otherDef.node == node;
    }

    @Override
    public String toString() {
      return "Definition@" + node;
    }

    @Override
    public int hashCode() {
      return node.hashCode();
    }
  }

  /**
   * Must reaching definition lattice representation. It captures a product
   * lattice for each local (non-escaped) variable. The sub-lattice is
   * a n + 2 element lattice with all the {@link Definition} in the program,
   * TOP and BOTTOM.
   *
   * 

Since this is a Must-Define analysis, BOTTOM represents the case where * there might be more than one reaching definition for the variable. * * * (TOP) * / | | \ * N1 N2 N3 ....Nn * \ | | / * (BOTTOM) * */ static final class MustDef implements LatticeElement { // TODO(user): Use bit vector instead of maps might get better // performance. Change it after this is tested to be fully functional. // When a Var "A" = "TOP", "A" does not exist in reachingDef's keySet. // When a Var "A" = Node N, "A" maps to that node. // When a Var "A" = "BOTTOM", "A" maps to null. final Map reachingDef; public MustDef() { reachingDef = new HashMap<>(); } public MustDef(Collection vars) { this(); for (Var var : vars) { reachingDef.put(var, new Definition(var.getScope().getRootNode())); } } /** * Copy constructor. * * @param other The constructed object is a replicated copy of this element. */ public MustDef(MustDef other) { reachingDef = new HashMap<>(other.reachingDef); } @Override public boolean equals(Object other) { return (other instanceof MustDef) && ((MustDef) other).reachingDef.equals(this.reachingDef); } @Override public int hashCode() { return reachingDef.hashCode(); } } private static class MustDefJoin extends JoinOp.BinaryJoinOp { @Override public MustDef apply(MustDef a, MustDef b) { MustDef result = new MustDef(); Map resultMap = result.reachingDef; // Take the join of all variables that are not TOP in this. for (Map.Entry varEntry : a.reachingDef.entrySet()) { Var var = varEntry.getKey(); Definition aDef = varEntry.getValue(); if (aDef == null) { // "a" is BOTTOM implies that the variable has more than one possible // definition. We set the join of this to be BOTTOM regardless of what // "b" might be. resultMap.put(var, null); continue; } if (b.reachingDef.containsKey(var)) { Definition bDef = b.reachingDef.get(var); if (aDef.equals(bDef)) { resultMap.put(var, aDef); } else { resultMap.put(var, null); } } else { resultMap.put(var, aDef); } } // Take the join of all variables that are not TOP in other but it is TOP // in this. for (Map.Entry entry : b.reachingDef.entrySet()) { Var var = entry.getKey(); if (!a.reachingDef.containsKey(var)) { resultMap.put(var, entry.getValue()); } } return result; } } @Override boolean isForward() { return true; } @Override MustDef createEntryLattice() { return new MustDef(allVarsInFn.values()); } @Override MustDef createInitialEstimateLattice() { return new MustDef(); } @Override MustDef flowThrough(Node n, MustDef input) { // TODO(user): We are doing a straight copy from input to output. There // might be some opportunities to cut down overhead. MustDef output = new MustDef(input); // TODO(user): This must know about ON_EX edges but it should handle // it better than what we did in liveness. Because we are in a forward mode, // we can used the branched forward analysis. computeMustDef(n, n, output, false); return output; } /** * @param n The node in question. * @param cfgNode The node to add * @param conditional true if the definition is not always executed. */ private void computeMustDef( Node n, Node cfgNode, MustDef output, boolean conditional) { switch (n.getToken()) { case BLOCK: case ROOT: case FUNCTION: return; case WHILE: case DO: case IF: computeMustDef( NodeUtil.getConditionExpression(n), cfgNode, output, conditional); return; case FOR: computeMustDef(NodeUtil.getConditionExpression(n), cfgNode, output, conditional); return; case FOR_IN: case FOR_OF: case FOR_AWAIT_OF: // for(x in y) {...} Node lhs = n.getFirstChild(); Node rhs = lhs.getNext(); if (NodeUtil.isNameDeclaration(lhs)) { lhs = lhs.getLastChild(); // for(var x in y) {...} } if (lhs.isName()) { // TODO(lharker): This doesn't seem right - given for (x in y), the value set to x isn't y addToDefIfLocal(lhs.getString(), cfgNode, rhs, output); } else if (lhs.isDestructuringLhs()) { lhs = lhs.getFirstChild(); } if (lhs.isDestructuringPattern()) { computeMustDef(lhs, cfgNode, output, true); } return; case AND: case OR: case COALESCE: computeMustDef(n.getFirstChild(), cfgNode, output, conditional); computeMustDef(n.getLastChild(), cfgNode, output, true); return; case HOOK: computeMustDef(n.getFirstChild(), cfgNode, output, conditional); computeMustDef(n.getSecondChild(), cfgNode, output, true); computeMustDef(n.getLastChild(), cfgNode, output, true); return; case LET: case CONST: case VAR: for (Node c = n.getFirstChild(); c != null; c = c.getNext()) { if (c.hasChildren()) { if (c.isName()) { computeMustDef(c.getFirstChild(), cfgNode, output, conditional); addToDefIfLocal(c.getString(), conditional ? null : cfgNode, c.getFirstChild(), output); } else { checkState(c.isDestructuringLhs(), c); computeMustDef(c.getSecondChild(), cfgNode, output, conditional); computeMustDef(c.getFirstChild(), cfgNode, output, conditional); } } } return; case DEFAULT_VALUE: if (n.getFirstChild().isDestructuringPattern()) { computeMustDef(n.getSecondChild(), cfgNode, output, true); computeMustDef(n.getFirstChild(), cfgNode, output, conditional); } else if (n.getFirstChild().isName()) { computeMustDef(n.getSecondChild(), cfgNode, output, true); addToDefIfLocal( n.getFirstChild().getString(), conditional ? null : cfgNode, null, output); } else { computeMustDef(n.getFirstChild(), cfgNode, output, conditional); computeMustDef(n.getSecondChild(), cfgNode, output, true); } break; case NAME: if (NodeUtil.isLhsByDestructuring(n)) { addToDefIfLocal(n.getString(), conditional ? null : cfgNode, null, output); } else if ("arguments".equals(n.getString())) { escapeParameters(output); } return; default: if (NodeUtil.isAssignmentOp(n)) { if (n.getFirstChild().isName()) { Node name = n.getFirstChild(); computeMustDef(name.getNext(), cfgNode, output, conditional); addToDefIfLocal( name.getString(), conditional ? null : cfgNode, n.getLastChild(), output); return; } else if (NodeUtil.isGet(n.getFirstChild())) { // Treat all assignments to arguments as redefining the // parameters itself. Node obj = n.getFirstFirstChild(); if (obj.isName() && "arguments".equals(obj.getString())) { // TODO(user): More accuracy can be introduced // i.e. We know exactly what arguments[x] is if x is a constant // number. escapeParameters(output); } } else if (n.getFirstChild().isDestructuringPattern()) { computeMustDef(n.getSecondChild(), cfgNode, output, conditional); computeMustDef(n.getFirstChild(), cfgNode, output, conditional); return; } } // DEC and INC actually defines the variable. if (n.isDec() || n.isInc()) { Node target = n.getFirstChild(); if (target.isName()) { addToDefIfLocal(target.getString(), conditional ? null : cfgNode, null, output); return; } } for (Node c = n.getFirstChild(); c != null; c = c.getNext()) { computeMustDef(c, cfgNode, output, conditional); } } } /** * Set the variable lattice for the given name to the node value in the def * lattice. Do nothing if the variable name is one of the escaped variable. * * @param node The CFG node where the definition should be record to. * {@code null} if this is a conditional define. */ private void addToDefIfLocal(String name, @Nullable Node node, @Nullable Node rValue, MustDef def) { Var var = allVarsInFn.get(name); // var might be null if the variable is defined in the externs if (var == null) { return; } for (Var other : def.reachingDef.keySet()) { Definition otherDef = def.reachingDef.get(other); if (otherDef == null) { continue; } if (otherDef.depends.contains(var)) { def.reachingDef.put(other, null); } } if (!escaped.contains(var)) { if (node == null) { def.reachingDef.put(var, null); } else { Definition definition = new Definition(node); if (rValue != null) { computeDependence(definition, rValue); } def.reachingDef.put(var, definition); } } } private void escapeParameters(MustDef output) { for (Var v : allVarsInFn.values()) { if (isParameter(v)) { // Assume we no longer know where the parameter comes from // anymore. output.reachingDef.put(v, null); } } // Also, assume we no longer know anything that depends on a parameter. for (Entry pair : output.reachingDef.entrySet()) { Definition value = pair.getValue(); if (value == null) { continue; } for (Var dep : value.depends) { if (isParameter(dep)) { output.reachingDef.put(pair.getKey(), null); } } } } private static boolean isParameter(Var v) { return v.isParam(); } /** * Computes all the local variables that rValue reads from and store that * in the def's depends set. */ private void computeDependence(final Definition def, Node rValue) { NodeTraversal.traverse( compiler, rValue, new AbstractCfgNodeTraversalCallback() { @Override public void visit(NodeTraversal t, Node n, Node parent) { if (n.isName()) { Var dep = allVarsInFn.get(n.getString()); if (dep == null) { def.unknownDependencies = true; } else { def.depends.add(dep); } } } }); } /** * Gets the must reaching definition of a given node. * * @param name name of the variable. It can only be names of local variable * that are not function parameters, escaped variables or variables * declared in catch. * @param useNode the location of the use where the definition reaches. */ Definition getDef(String name, Node useNode) { checkArgument(getCfg().hasNode(useNode)); GraphNode n = getCfg().getNode(useNode); FlowState state = n.getAnnotation(); return state.getIn().reachingDef.get(allVarsInFn.get(name)); } Node getDefNode(String name, Node useNode) { Definition def = getDef(name, useNode); return def == null ? null : def.node; } boolean dependsOnOuterScopeVars(Definition def) { if (def.unknownDependencies) { return true; } for (Var s : def.depends) { // Don't inline try catch if (s.getScope().isCatchScope()) { return true; } } return false; } }





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