All Downloads are FREE. Search and download functionalities are using the official Maven repository.

com.google.javascript.jscomp.ControlFlowGraph Maven / Gradle / Ivy

Go to download

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.

There is a newer version: v20200830
Show newest version
/*
 * 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 com.google.javascript.jscomp.NodeTraversal.Callback;
import com.google.javascript.jscomp.graph.LinkedDirectedGraph;
import com.google.javascript.rhino.Node;
import java.util.Comparator;

/**
 * Control flow graph.
 *
 * @param  The instruction type of the control flow graph.
 */
public class ControlFlowGraph extends
    LinkedDirectedGraph {

  /**
   * A special node marked by the node value key null to a singleton
   * "return" when control is transferred outside of the current control flow
   * graph.
   */
  private final DiGraphNode implicitReturn;

  private final DiGraphNode entry;

  /**
   * Constructor.
   */
  ControlFlowGraph(
      N entry, boolean nodeAnnotations, boolean edgeAnnotations) {
    super(nodeAnnotations, edgeAnnotations);
    implicitReturn = createNode(null);
    this.entry = createNode(entry);
  }

  /**
   * Gets the implicit return node.
   *
   * @return Return node.
   */
  public DiGraphNode getImplicitReturn() {
    return implicitReturn;
  }

  /**
   * Gets the entry point of the control flow graph. In general, this should be
   * the beginning of the global script or beginning of a function.
   *
   * @return The entry point.
   */
  public DiGraphNode getEntry() {
    return entry;
  }

  /**
   * Checks whether node is the implicit return.
   *
   * @param node Node.
   * @return True if the node is the implicit return.
   */
  public boolean isImplicitReturn(
      DiGraphNode node) {
    return node == implicitReturn;
  }

  /**
   * Gets a comparator for the nodes. The default implementation returns
   * {@code null}. See {@link ControlFlowGraph#getOptionalNodeComparator}.
   * @param isForward Whether the comparator sorts the nodes in the direction of
   *    the flow.
   * @return a comparator or null (in particular, if not overridden)
   */
  public Comparator> getOptionalNodeComparator(
      boolean isForward) {
    return null;
  }

  /**
   * The edge object for the control flow graph.
   */
  public static enum Branch {
    /** Edge is taken if the condition is true. */
    ON_TRUE,
    /** Edge is taken if the condition is false. */
    ON_FALSE,
    /** Unconditional branch. */
    UNCOND,
    /**
     * Exception-handling code paths.
     * Conflates two kind of control flow passing:
     * - An exception is thrown, and falls into a catch or finally block
     * - During exception handling, a finally block finishes and control
     *   passes to the next finally block.
     * In theory, we need 2 different edge types. In practice, we
     * can just treat them as "the edges we can't really optimize".
     */
    ON_EX,
    /** Possible folded-away template */
    SYN_BLOCK;

    public boolean isConditional() {
      return this == ON_TRUE || this == ON_FALSE;
    }
  }

  /**
   * Abstract callback to visit a control flow graph node without going into
   * subtrees of the node that are also represented by other
   * control flow graph nodes.
   *
   * 

For example, traversing an IF node as root will visit the two subtrees * pointed by the {@link ControlFlowGraph.Branch#ON_TRUE} and * {@link ControlFlowGraph.Branch#ON_FALSE} edges. */ public abstract static class AbstractCfgNodeTraversalCallback implements Callback { @Override public final boolean shouldTraverse(NodeTraversal nodeTraversal, Node n, Node parent) { if (parent == null) { return true; } return !isEnteringNewCfgNode(n); } } /** * @return True if n should be represented by a new CFG node in the control * flow graph. */ public static boolean isEnteringNewCfgNode(Node n) { Node parent = n.getParent(); switch (parent.getToken()) { case BLOCK: case ROOT: case SCRIPT: case TRY: return true; case FUNCTION: // A function node represents the start of a function where the name // bleeds into the local scope and parameters are assigned // to the formal argument names. The node includes the name of the // function and the PARAM_LIST since we assume the whole set up process // is atomic without change in control flow. The next change of // control is going into the function's body, represented by the second // child. return n != parent.getSecondChild(); case WHILE: case DO: case IF: // These control structures are represented by a node that holds the // condition. Each of them is a branch node based on its condition. return NodeUtil.getConditionExpression(parent) != n; case FOR: // The FOR(;;) node differs from other control structures in that // it has an initialization and an increment statement. Those // two statements have corresponding CFG nodes to represent them. // The FOR node only represents the condition check for each iteration. // That way the following: // for(var x = 0; x < 10; x++) { } has a graph that is isomorphic to // var x = 0; while(x<10) { x++; } return NodeUtil.getConditionExpression(parent) != n; case FOR_IN: // TODO(user): Investigate how we should handle the case where // we have a very complex expression inside the FOR-IN header. return n != parent.getFirstChild(); case SWITCH: case CASE: case CATCH: case WITH: return n != parent.getFirstChild(); default: return false; } } @Override public String toString() { String s = "CFG:\n"; for (GraphvizEdge e : getGraphvizEdges()) { s += e.toString() + '\n'; } return s; } }





© 2015 - 2024 Weber Informatics LLC | Privacy Policy