/** * Returns null if the belief network <tt>bn</tt> has no directed cycles. Otherwise returns an * <tt>Enumeration</tt> of variables, which begins at a variable contained in a directed cycle, * leads through the cycle (parent by parent), and ends at that same variable. */ public static Enumeration has_directed_cycle(AbstractBeliefNetwork bn) throws RemoteException { // If is_ancestor returns true, then this stack contains a path from some variable all the // way back to that same variable. If is_ancestor returns false, then this stack remains empty. Stack path_stack = new Stack(); AbstractVariable[] u = bn.get_variables(); for (int i = 0; i < u.length; i++) { if (is_ancestor(u[i], u[i], path_stack)) { path_stack.push(u[i]); return path_stack.elements(); } } return null; }
public static Hashtable compile_all_paths(AbstractBeliefNetwork bn) throws RemoteException { Hashtable path_sets = new Hashtable(); // SHOULD SYNCHRONIZE ON bn TO PREVENT EDITING WHILE compile_all_paths IS RUNNING !!! AbstractVariable[] variables = bn.get_variables(); for (int i = 0; i < variables.length; i++) { // Skip through the other variables, up to and including the current variable; // we only need half the connectivity matrix, since it is symmetric. for (int j = i + 1; j < variables.length; j++) { compile_paths(variables[i], variables[j], path_sets); } } return path_sets; }
public static void main(String[] args) { boolean all_x = false, do_bind = false; String bn_name = "", context_name = ""; int i; for (i = 0; i < args.length; i++) { if (args[i].charAt(0) != '-') continue; switch (args[i].charAt(1)) { case 'b': bn_name = args[++i]; break; case 'c': context_name = args[++i]; break; case 'r': do_bind = true; break; } } AbstractBeliefNetworkContext bnc = null; AbstractBeliefNetwork bn = null; AbstractVariable x = null, e_var = null; try { if ("".equals(context_name)) { BeliefNetworkContext local_bnc = new BeliefNetworkContext(null); bnc = local_bnc; } else { String url = "rmi://" + context_name; System.err.println("Informativeness: url: " + url); long t0 = System.currentTimeMillis(); bnc = (AbstractBeliefNetworkContext) Naming.lookup(url); long tf = System.currentTimeMillis(); System.err.println( "Informativeness: Naming.lookup complete (for belief net context), elapsed time: " + ((tf - t0) / 1000.0) + " [s]"); } bn = (AbstractBeliefNetwork) bnc.load_network(bn_name); if (do_bind) { System.err.println("Informativeness: bind belief net."); bnc.bind(bn); } String e_name, x_name; double e_value; for (i = 0; i < args.length; i++) { if (args[i].charAt(0) != '-') continue; switch (args[i].charAt(1)) { case 'x': if ("-xall".equals(args[i])) { AbstractVariable[] u = bn.get_variables(); for (int j = 0; j < u.length; j++) { Distribution xposterior = bn.get_posterior(u[j]); System.out.println("Informativeness: posterior for " + u[j].get_name() + ":"); System.out.print(" " + xposterior.format_string(" ")); } } else { x_name = args[++i]; long t0 = System.currentTimeMillis(); x = (AbstractVariable) bn.name_lookup(x_name); long tf = System.currentTimeMillis(); System.err.println( "Informativeness: Naming.lookup complete (for variable ref), elapsed time: " + ((tf - t0) / 1000.0) + " [s]"); if (x == null) throw new Exception("name_lookup failed: x: " + x_name); Distribution xposterior = bn.get_posterior(x); System.out.println("Informativeness: posterior for " + x.get_name() + ":"); System.out.print(" " + xposterior.format_string(" ")); } break; case 'e': if (args[i].length() > 2 && args[i].charAt(2) == '-') { e_name = args[++i]; System.err.println("Informativeness.main: evidence: clear " + e_name); e_var = (AbstractVariable) bn.name_lookup(e_name); bn.clear_posterior(e_var); } else { e_name = args[++i]; e_value = Double.parseDouble(args[++i]); System.err.println( "Informativeness.main: evidence: set " + e_name + " to " + e_value); long t0 = System.currentTimeMillis(); e_var = (AbstractVariable) bn.name_lookup(e_name); long tf = System.currentTimeMillis(); System.err.println( "Informativeness: Naming.lookup complete (for variable ref), elapsed time: " + ((tf - t0) / 1000.0) + " [s]"); bn.assign_evidence(e_var, e_value); } break; default: continue; } } } catch (Exception e) { e.printStackTrace(); } System.exit(0); }
public static void main(String[] args) { boolean do_compile_all = false; String bn_name = "", x1_name = "", x2_name = ""; Vector evidence_names = new Vector(); for (int i = 0; i < args.length; i++) { if (args[i].charAt(0) != '-') continue; switch (args[i].charAt(1)) { case 'b': bn_name = args[++i]; break; case 'a': do_compile_all = true; break; case 'x': if (args[i].charAt(2) == '1') x1_name = args[++i]; else if (args[i].charAt(2) == '2') x2_name = args[++i]; else System.err.println("PathAnalysis.main: " + args[i] + " -- huh???"); break; case 'e': evidence_names.addElement(args[++i]); break; default: System.err.println("PathAnalysis.main: " + args[i] + " -- huh???"); } } try { BeliefNetworkContext bnc = new BeliefNetworkContext(null); bnc.add_path("/bechtel/users10/krarti/dodier/belief-nets/assorted"); AbstractBeliefNetwork bn = bnc.load_network(bn_name); Hashtable path_sets; Enumeration p; if ((p = PathAnalysis.has_directed_cycle(bn)) == null) System.err.println("PathAnalysis: no directed cycles found in " + bn_name); else { System.err.println("PathAnalysis.main: " + bn_name + " has a directed cycle; quit."); System.err.print(" cycle is: "); while (p.hasMoreElements()) { System.err.print(((AbstractVariable) p.nextElement()).get_name()); if (p.hasMoreElements()) System.err.print(" -> "); else System.err.println(""); } System.exit(1); } Vector evidence = new Vector(); if (evidence_names.size() > 0) { for (int i = 0; i < evidence_names.size(); i++) evidence.addElement(bn.name_lookup((String) (evidence_names.elementAt(i)))); } if (do_compile_all) { path_sets = PathAnalysis.compile_all_paths(bn); } else { AbstractVariable x1 = (AbstractVariable) bn.name_lookup(x1_name); AbstractVariable x2 = (AbstractVariable) bn.name_lookup(x2_name); path_sets = new Hashtable(); PathAnalysis.compile_paths(x1, x2, path_sets); if (PathAnalysis.are_d_connected(x1, x2, evidence)) System.err.print( x1.get_name() + " and " + x2.get_name() + " are d-connected given evidence "); else System.err.print( x1.get_name() + " and " + x2.get_name() + " are NOT d-connected given evidence "); for (int i = 0; i < evidence.size(); i++) System.err.print(((AbstractVariable) evidence.elementAt(i)).get_name() + " "); System.err.println(""); } System.err.println("PathAnalysis.main: results of path finding:"); AbstractVariable[] u = bn.get_variables(); for (int i = 0; i < u.length; i++) { System.err.println(" --- paths from: " + u[i].get_name() + " ---"); for (int j = i + 1; j < u.length; j++) { VariablePair vp = new VariablePair(u[i], u[j]); Vector path_set = (Vector) path_sets.get(vp); if (path_set == null) continue; Enumeration path_set_enum = path_set.elements(); while (path_set_enum.hasMoreElements()) { AbstractVariable[] path = (AbstractVariable[]) path_set_enum.nextElement(); System.err.print(" path: "); for (int k = 0; k < path.length; k++) System.err.print(path[k].get_name() + " "); System.err.println(""); } } } System.exit(0); } catch (Exception e) { System.err.println("PathAnalysis.main:"); e.printStackTrace(); System.exit(1); } }