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/*
 * Javassist, a Java-bytecode translator toolkit.
 * Copyright (C) 1999- Shigeru Chiba. All Rights Reserved.
 *
 * The contents of this file are subject to the Mozilla Public License Version
 * 1.1 (the "License"); you may not use this file except in compliance with
 * the License.  Alternatively, the contents of this file may be used under
 * the terms of the GNU Lesser General Public License Version 2.1 or later,
 * or the Apache License Version 2.0.
 *
 * Software distributed under the License is distributed on an "AS IS" basis,
 * WITHOUT WARRANTY OF ANY KIND, either express or implied. See the License
 * for the specific language governing rights and limitations under the
 * License.
 */

package javassist.bytecode.analysis;

import java.util.ArrayList;
import javassist.CtClass;
import javassist.CtMethod;
import javassist.bytecode.BadBytecode;
import javassist.bytecode.MethodInfo;
import javassist.bytecode.stackmap.BasicBlock;

/**
 * Represents the control flow graph of a given method.
 *
 * 

To obtain the control flow graph, do the following:

* *
CtMethod m = ...
 * ControlFlow cf = new ControlFlow(m);
 * Block[] blocks = cf.basicBlocks();
 * 
* *

blocks is an array of basic blocks in * that method body.

* * @see javassist.CtMethod * @see Block * @see Frame * @see Analyzer * @author Shigeru Chiba * @since 3.16 */ public class ControlFlow { private CtClass clazz; private MethodInfo methodInfo; private Block[] basicBlocks; private Frame[] frames; /** * Constructs a control-flow analyzer for the given method. */ public ControlFlow(CtMethod method) throws BadBytecode { this(method.getDeclaringClass(), method.getMethodInfo2()); } /** * Constructs a control-flow analyzer. */ public ControlFlow(CtClass ctclazz, MethodInfo minfo) throws BadBytecode { clazz = ctclazz; methodInfo = minfo; frames = null; basicBlocks = (Block[])new BasicBlock.Maker() { protected BasicBlock makeBlock(int pos) { return new Block(pos, methodInfo); } protected BasicBlock[] makeArray(int size) { return new Block[size]; } }.make(minfo); int size = basicBlocks.length; int[] counters = new int[size]; for (int i = 0; i < size; i++) { Block b = basicBlocks[i]; b.index = i; b.entrances = new Block[b.incomings()]; counters[i] = 0; } for (int i = 0; i < size; i++) { Block b = basicBlocks[i]; for (int k = 0; k < b.exits(); k++) { Block e = b.exit(k); e.entrances[counters[e.index]++] = b; } ControlFlow.Catcher[] catchers = b.catchers(); for (int k = 0; k < catchers.length; k++) { Block catchBlock = catchers[k].node; catchBlock.entrances[counters[catchBlock.index]++] = b; } } } /** * Returns all the basic blocks in the method body. */ public Block[] basicBlocks() { return basicBlocks; } /** * Returns the types of the local variables and stack frame entries * available at the given position. If the byte at the position is * not the first byte of an instruction, then this method returns * null. * * @param pos the position. */ public Frame frameAt(int pos) throws BadBytecode { if (frames == null) frames = new Analyzer().analyze(clazz, methodInfo); return frames[pos]; } /** * Constructs a dominator tree. This method returns an array of * the tree nodes. The first element of the array is the root * of the tree. * *

The order of the elements is the same as that * of the elements in the Block array returned * by the basicBlocks * method. If a Block object is at the i-th position * in the Block array, then * the Node object referring to that * Block object is at the i-th position in the * array returned by this method. * For every array element node, its index in the * array is equivalent to node.block().index(). * * @return an array of the tree nodes, or null if the method is abstract. * @see Node#block() * @see Block#index() */ public Node[] dominatorTree() { int size = basicBlocks.length; if (size == 0) return null; Node[] nodes = new Node[size]; boolean[] visited = new boolean[size]; int[] distance = new int[size]; for (int i = 0; i < size; i++) { nodes[i] = new Node(basicBlocks[i]); visited[i] = false; } Access access = new Access(nodes) { BasicBlock[] exits(Node n) { return n.block.getExit(); } BasicBlock[] entrances(Node n) { return n.block.entrances; } }; nodes[0].makeDepth1stTree(null, visited, 0, distance, access); do { for (int i = 0; i < size; i++) visited[i] = false; } while (nodes[0].makeDominatorTree(visited, distance, access)); Node.setChildren(nodes); return nodes; } /** * Constructs a post dominator tree. This method returns an array of * the tree nodes. Note that the tree has multiple roots. * The parent of the root nodes is null. * *

The order of the elements is the same as that * of the elements in the Block array returned * by the basicBlocks * method. If a Block object is at the i-th position * in the Block array, then * the Node object referring to that * Block object is at the i-th position in the * array returned by this method. * For every array element node, its index in the * array is equivalent to node.block().index(). * * @return an array of the tree nodes, or null if the method is abstract. * @see Node#block() * @see Block#index() */ public Node[] postDominatorTree() { int size = basicBlocks.length; if (size == 0) return null; Node[] nodes = new Node[size]; boolean[] visited = new boolean[size]; int[] distance = new int[size]; for (int i = 0; i < size; i++) { nodes[i] = new Node(basicBlocks[i]); visited[i] = false; } Access access = new Access(nodes) { BasicBlock[] exits(Node n) { return n.block.entrances; } BasicBlock[] entrances(Node n) { return n.block.getExit(); } }; int counter = 0; for (int i = 0; i < size; i++) if (nodes[i].block.exits() == 0) counter = nodes[i].makeDepth1stTree(null, visited, counter, distance, access); boolean changed; do { for (int i = 0; i < size; i++) visited[i] = false; changed = false; for (int i = 0; i < size; i++) if (nodes[i].block.exits() == 0) if (nodes[i].makeDominatorTree(visited, distance, access)) changed = true; } while (changed); Node.setChildren(nodes); return nodes; } /** * Basic block. * It is a sequence of contiguous instructions that do not contain * jump/branch instructions except the last one. * Since Java6 or later does not allow JSR, * we deal with JSR as a non-branch instruction. */ public static class Block extends BasicBlock { /** * A field that can be freely used for storing extra data. * A client program of this control-flow analyzer can append * an additional attribute to a Block object. * The Javassist library never accesses this field. */ public Object clientData = null; int index; MethodInfo method; Block[] entrances; Block(int pos, MethodInfo minfo) { super(pos); method = minfo; } protected void toString2(StringBuffer sbuf) { super.toString2(sbuf); sbuf.append(", incoming{"); for (int i = 0; i < entrances.length; i++) sbuf.append(entrances[i].position).append(", "); sbuf.append("}"); } BasicBlock[] getExit() { return exit; } /** * Returns the position of this block in the array of * basic blocks that the basicBlocks method * returns. * * @see #basicBlocks() */ public int index() { return index; } /** * Returns the position of the first instruction * in this block. */ public int position() { return position; } /** * Returns the length of this block. */ public int length() { return length; } /** * Returns the number of the control paths entering this block. */ public int incomings() { return incoming; } /** * Returns the block that the control may jump into this block from. */ public Block incoming(int n) { return entrances[n]; } /** * Return the number of the blocks that may be executed * after this block. */ public int exits() { return exit == null ? 0 : exit.length; } /** * Returns the n-th block that may be executed after this * block. * * @param n an index in the array of exit blocks. */ public Block exit(int n) { return (Block)exit[n]; } /** * Returns catch clauses that will catch an exception thrown * in this block. */ public Catcher[] catchers() { ArrayList catchers = new ArrayList(); BasicBlock.Catch c = toCatch; while (c != null) { catchers.add(new Catcher(c)); c = c.next; } return (Catcher[])catchers.toArray(new Catcher[catchers.size()]); } } static abstract class Access { Node[] all; Access(Node[] nodes) { all = nodes; } Node node(BasicBlock b) { return all[((Block)b).index]; } abstract BasicBlock[] exits(Node n); abstract BasicBlock[] entrances(Node n); } /** * A node of (post) dominator trees. */ public static class Node { private Block block; private Node parent; private Node[] children; Node(Block b) { block = b; parent = null; } /** * Returns a String representation. */ public String toString() { StringBuffer sbuf = new StringBuffer(); sbuf.append("Node[pos=").append(block().position()); sbuf.append(", parent="); sbuf.append(parent == null ? "*" : Integer.toString(parent.block().position())); sbuf.append(", children{"); for (int i = 0; i < children.length; i++) sbuf.append(children[i].block().position()).append(", "); sbuf.append("}]"); return sbuf.toString(); } /** * Returns the basic block indicated by this node. */ public Block block() { return block; } /** * Returns the parent of this node. */ public Node parent() { return parent; } /** * Returns the number of the children of this node. */ public int children() { return children.length; } /** * Returns the n-th child of this node. * * @param n an index in the array of children. */ public Node child(int n) { return children[n]; } /* * After executing this method, distance[] represents the post order of the tree nodes. * It also represents distances from the root; a bigger number represents a shorter * distance. parent is set to its parent in the depth first spanning tree. */ int makeDepth1stTree(Node caller, boolean[] visited, int counter, int[] distance, Access access) { int index = block.index; if (visited[index]) return counter; visited[index] = true; parent = caller; BasicBlock[] exits = access.exits(this); if (exits != null) for (int i = 0; i < exits.length; i++) { Node n = access.node(exits[i]); counter = n.makeDepth1stTree(this, visited, counter, distance, access); } distance[index] = counter++; return counter; } boolean makeDominatorTree(boolean[] visited, int[] distance, Access access) { int index = block.index; if (visited[index]) return false; visited[index] = true; boolean changed = false; BasicBlock[] exits = access.exits(this); if (exits != null) for (int i = 0; i < exits.length; i++) { Node n = access.node(exits[i]); if (n.makeDominatorTree(visited, distance, access)) changed = true; } BasicBlock[] entrances = access.entrances(this); if (entrances != null) for (int i = 0; i < entrances.length; i++) { if (parent != null) { Node n = getAncestor(parent, access.node(entrances[i]), distance); if (n != parent) { parent = n; changed = true; } } } return changed; } private static Node getAncestor(Node n1, Node n2, int[] distance) { while (n1 != n2) { if (distance[n1.block.index] < distance[n2.block.index]) n1 = n1.parent; else n2 = n2.parent; if (n1 == null || n2 == null) return null; } return n1; } private static void setChildren(Node[] all) { int size = all.length; int[] nchildren = new int[size]; for (int i = 0; i < size; i++) nchildren[i] = 0; for (int i = 0; i < size; i++) { Node p = all[i].parent; if (p != null) nchildren[p.block.index]++; } for (int i = 0; i < size; i++) all[i].children = new Node[nchildren[i]]; for (int i = 0; i < size; i++) nchildren[i] = 0; for (int i = 0; i < size; i++) { Node n = all[i]; Node p = n.parent; if (p != null) p.children[nchildren[p.block.index]++] = n; } } } /** * Represents a catch clause. */ public static class Catcher { private Block node; private int typeIndex; Catcher(BasicBlock.Catch c) { node = (Block)c.body; typeIndex = c.typeIndex; } /** * Returns the first block of the catch clause. */ public Block block() { return node; } /** * Returns the name of the exception type that * this catch clause catches. */ public String type() { if (typeIndex == 0) return "java.lang.Throwable"; else return node.method.getConstPool().getClassInfo(typeIndex); } } }





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