Add explicit.PredecessorRelation class for computing / storing predecessor relation of models. [from Joachim Klein]

git-svn-id: https://www.prismmodelchecker.org/svn/prism/prism/trunk@10191 bbc10eb1-c90d-0410-af57-cb519fbb1720
11 years ago · 9babbf4bf1
1 changed files with 195 additions and 0 deletions
--- a/prism/src/explicit/PredecessorRelation.java
+++ b/prism/src/explicit/PredecessorRelation.java
@ -0,0 +1,195 @@
 //==============================================================================
 //	
 //	Copyright (c) 2014-
 //	Authors:
 //	* Joachim Klein <klein@tcs.inf.tu-dresden.de> (TU Dresden)
 //	
 //------------------------------------------------------------------------------
 //	
 //	This file is part of PRISM.
 //	
 //	PRISM is free software; you can redistribute it and/or modify
 //	it under the terms of the GNU General Public License as published by
 //	the Free Software Foundation; either version 2 of the License, or
 //	(at your option) any later version.
 //	
 //	PRISM 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 General Public License for more details.
 //	
 //	You should have received a copy of the GNU General Public License
 //	along with PRISM; if not, write to the Free Software Foundation,
 //	Inc., 59 Temple Place, Suite 330, Boston, MA  02111-1307  USA
 //	
 //==============================================================================
 package explicit;
 import java.util.ArrayList;
 import java.util.BitSet;
 import java.util.Iterator;
 import java.util.List;
 import java.util.Stack;
 import prism.PrismComponent;
 import common.IterableBitSet;
 /**
 * A class for storing and accessing the predecessor relation of an explicit Model.
 * <p>
 * As Model only provide easy access to successors of states,
 * the predecessor relation is computed and stored for subsequent efficient access.
 * <p>
 * Note: Naturally, if the model changes, the predecessor relation
 * has to be recomputed to remain accurate.
 */
 public class PredecessorRelation
 {
 	/**
 	 * pre[i] provides the list of predecessors of state with index i.
 	 */
 	List<ArrayList<Integer>> pre;
 	/**
 	 * Constructor. Computes the predecessor relation for the given model
 	 * by considering the successors of each state.
 	 *
 	 * @param model the Model
 	 */
 	public PredecessorRelation(Model model)
 	{
 		pre = new ArrayList<ArrayList<Integer>>(model.getNumStates());
 		// construct the (empty) array list for all states
 		for (int s = 0; s < model.getNumStates(); s++) {
 			pre.add(s, new ArrayList<Integer>());
 		}
 		compute(model);
 	}
 	/** Compute the predecessor relation using getSuccessorsIterator. */
 	private void compute(Model model)
 	{
 		int n = model.getNumStates();
 		for (int s = 0; s < n; s++) {
 			Iterator<Integer> it = model.getSuccessorsIterator(s);
 			while (it.hasNext()) {
 				Integer successor = it.next();
 				// Add the current state s to pre[successor].
 				//
 				// As getSuccessorsIterator guarantees that
 				// there are no duplicates in the successors,
 				// s will be added to successor exactly once.
 				pre.get(successor).add(s);
 			}
 		}
 	}
 	/**
 	 * Get an Iterable over the predecessor states of {@code s}.
 	 */
 	public Iterable<Integer> getPre(int s)
 	{
 		return pre.get(s);
 	}
 	/**
 	 * Get an Iterator over the predecessor states of {@code s}.
 	 */
 	public Iterator<Integer> getPredecessorsIterator(int s)
 	{
 		return pre.get(s).iterator();
 	}
 	/**
 	 * Static constructor to compute the predecessor relation for the given model.
 	 * Logs diagnostic information to the log of the given PrismComponent.
 	 *
 	 * @param parent a PrismComponent (for obtaining the log and settings)
 	 * @param model the model for which the predecessor relation should be computed
 	 * @returns the predecessor relation
 	 **/
 	public static PredecessorRelation forModel(PrismComponent parent, Model model)
 	{
 		long timer = System.currentTimeMillis();
 		parent.getLog().print("Calculating predecessor relation for "+model.getModelType().fullName()+"...  ");
 		parent.getLog().flush();
 		PredecessorRelation pre = new PredecessorRelation(model);
 		timer = System.currentTimeMillis() - timer;
 		parent.getLog().println("done (" + timer / 1000.0 + " seconds)");
 		return pre;
 	}
 	/**
 	 * Computes the set Pre*(target) via a DFS, i.e., all states that
 	 * are in {@code target} or can reach {@code target} via one or more transitions
 	 * from states contained in {@code remain}.
 	 * <br/>
 	 * If the parameter {@code remain} is {@code null}, then
 	 * {@code remain} is considered to include all states in the model.
 	 * <br/>
 	 * If the parameter {@code absorbing} is not {@code null},
 	 * then the states in {@code absorbing} are considered to be absorbing,
 	 * i.e., to have a single self-loop, disregarding other outgoing edges.
 	 * @param remain restriction on the states that may occur
 	 *               on the path to target, {@code null} = all states
 	 * @param target The set of target states
 	 * @param absorbing (optional) set of states that should be considered to be absorbing,
 	 *               i.e., their outgoing edges are ignored, {@code null} = no states
 	 * @return the set of states Pre*(target)
 	 */
 	public BitSet calculatePreStar(BitSet remain, BitSet target, BitSet absorbing)
 	{
 		BitSet result;
 		// all target states are in Pre*
 		result = (BitSet)target.clone();
 		// the stack of states whose predecessors have to be considered
 		Stack<Integer> todo = new Stack<Integer>();
 		// initial todo: all the target states
 		for (Integer s : IterableBitSet.getSetBits(target)) {
 			todo.add(s);
 		};
 		// the set of states that are finished
 		BitSet done = new BitSet();
 		while (!todo.isEmpty()) {
 			int s = todo.pop();
 			// already considered?
 			if (done.get(s)) continue;
 			done.set(s);
 			// for each predecessor in the graph
 			for (int p : getPre(s)) {
 				if (absorbing != null && absorbing.get(p)) {
 					// predecessor is absorbing, thus the edge is considered to not exist
 					continue;
 				}
 				if (remain == null || remain.get(p)) {
 					// can reach result (and is in remain)
 					result.set(p);
 					if (!done.get(p)) {
 						// add to stack
 						todo.add(p);
 					}
 				}
 			}
 		}
 		return result;
 	}
 }