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/* Soot - a J*va Optimization Framework
 * Copyright (C) 2003 Navindra Umanee 
 *
 * This library is free software; you can redistribute it and/or
 * modify it under the terms of the GNU Lesser General Public
 * License as published by the Free Software Foundation; either
 * version 2.1 of the License, or (at your option) any later version.
 *
 * This library is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
 * Lesser General Public License for more details.
 *
 * You should have received a copy of the GNU Lesser General Public
 * License along with this library; if not, write to the
 * Free Software Foundation, Inc., 59 Temple Place - Suite 330,
 * Boston, MA 02111-1307, USA.
 */

package soot.toolkits.graph;

import java.util.*;

/**
 * Constructs a dominator tree structure from the given
 * DominatorsFinder.  The nodes in DominatorTree are of type
 * DominatorNode.
 *
 * 

* * Note: DominatorTree does not currently implement DirectedGraph * since it provides 4 methods of navigating the nodes where the * meaning of getPredsOf and getSuccsOf diverge from the usual meaning * in a DirectedGraph implementation. * *

* * If you need a DirectedGraph implementation, see DominatorTreeAdapter. * * @author Navindra Umanee **/ public class DominatorTree { protected DominatorsFinder dominators; protected DirectedGraph graph; protected DominatorNode head; protected ArrayList tails; /** * "gode" is a node in the original graph, "dode" is a node in the * dominator tree. **/ protected HashMap godeToDode; public DominatorTree(DominatorsFinder dominators) { // if(Options.v().verbose()) // G.v().out.println("[" + graph.getBody().getMethod().getName() + // "] Constructing DominatorTree..."); this.dominators = dominators; this.graph = dominators.getGraph(); head = null; tails = new ArrayList(); godeToDode = new HashMap(); buildTree(); } /** * Returns the original graph to which the Dominator tree * pertains. **/ public DirectedGraph getGraph() { return dominators.getGraph(); } /** * Returns the root of the dominator tree. **/ public DominatorNode getHead() { return head; } /** * Returns a list of the tails of the dominator tree. **/ public List getTails() { return (List) tails.clone(); } /** * Returns the parent of node in the tree, null if the node is at * the root. **/ public DominatorNode getParentOf(DominatorNode node) { return node.getParent(); } /** * Returns the children of node in the tree. **/ public List getChildrenOf(DominatorNode node) { return (List)((ArrayList)node.getChildren()).clone(); } /** * Finds all the predecessors of node in the original * DirectedGraph and returns a list of the corresponding * DominatorNodes. **/ public List getPredsOf(DominatorNode node) { List preds = graph.getPredsOf(node.getGode()); List predNodes = new ArrayList(); for(Iterator predsIt = preds.iterator(); predsIt.hasNext();){ Object pred = predsIt.next(); predNodes.add(getDode(pred)); } return predNodes; } /** * Finds all the successors of node in the original DirectedGraph * and returns a list of the corresponding DominatorNodes. **/ public List getSuccsOf(DominatorNode node) { List succs = graph.getSuccsOf(node.getGode()); List succNodes = new ArrayList(); for(Iterator succsIt = succs.iterator(); succsIt.hasNext();){ Object succ = succsIt.next(); succNodes.add(getDode(succ)); } return succNodes; } /** * Returns true if idom immediately dominates node. **/ public boolean isImmediateDominatorOf(DominatorNode idom, DominatorNode node) { // node.getParent() could be null return (node.getParent() == idom); } /** * Returns true if dom dominates node. **/ public boolean isDominatorOf(DominatorNode dom, DominatorNode node) { return dominators.isDominatedBy(node.getGode(), dom.getGode()); } /** * Returns the DominatorNode for a given node in the original * DirectedGraph. **/ public DominatorNode getDode(Object gode) { DominatorNode dode = (DominatorNode) godeToDode.get(gode); if(dode == null) throw new RuntimeException("Assertion failed: Dominator tree does not have a corresponding dode for gode (" + gode + ")"); return dode; } /** * Returns an iterator over the nodes in the tree. No ordering is * implied. **/ public Iterator iterator() { return godeToDode.values().iterator(); } /** * Returns the number of nodes in the tree. **/ public int size() { return godeToDode.size(); } /** * Add all the necessary links between nodes to form a meaningful * tree structure. **/ protected void buildTree() { // hook up children with parents and vice-versa { for(Iterator godesIt = graph.iterator(); godesIt.hasNext();){ Object gode = godesIt.next(); DominatorNode dode = fetchDode(gode); DominatorNode parent = fetchParent(gode); if(parent == null){ if(head != null) throw new RuntimeException("Assertion failed."); head = dode; } else{ parent.addChild(dode); dode.setParent(parent); } } } // identify the tail nodes { for(Iterator dodesIt = this.iterator(); dodesIt.hasNext();){ DominatorNode dode = (DominatorNode) dodesIt.next(); if(dode.isTail()) tails.add(dode); } } } /** * Convenience method, ensures we don't create more than one * DominatorNode for a given block. **/ protected DominatorNode fetchDode(Object gode) { DominatorNode dode; if(godeToDode.containsKey(gode)){ dode = (DominatorNode) godeToDode.get(gode); } else{ dode = new DominatorNode(gode); godeToDode.put(gode, dode); } return dode; } protected DominatorNode fetchParent(Object gode) { Object immediateDominator = dominators.getImmediateDominator(gode); if(immediateDominator == null) return null; return fetchDode(immediateDominator); } }





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