/** {@inheritDoc} */ @Override public Evidence[] mapEdgeToEvidence(Graph graph, Edge edge) { if (graph == null) throw new NullPointerException("graph cannot be null"); if (edge == null) throw new NullPointerException("edge cannot be null"); if (edge.metadata == null) return new Evidence[0]; Object evidences = edge.metadata.get("evidences"); if (evidences == null || !(evidences instanceof List)) return new Evidence[0]; List<Map> evidenceMap = typedList(((List) evidences), Map.class); List<Evidence> evidenceList = new ArrayList<Evidence>(); for (Map item : evidenceMap) { @SuppressWarnings("unchecked") Map<String, Object> evMap = (Map<String, Object>) item; Evidence ev = new Evidence(); ev.belStatement = getOrEmptyString("bel_statement", evMap).replace("\\\"", "\""); ev.summaryText = getOrEmptyString("summary_text", evMap); Citation citation = new Citation(); @SuppressWarnings("unchecked") Map<String, Object> citationMap = (Map<String, Object>) evMap.get("citation"); if (citationMap != null) { citation.id = getOrEmptyString("id", citationMap); citation.type = getOrEmptyString("type", citationMap); citation.name = getOrEmptyString("name", citationMap); } ev.citation = citation; BiologicalContext context = new BiologicalContext(); @SuppressWarnings("unchecked") Map<String, Object> contextMap = (Map<String, Object>) evMap.get("biological_context"); if (contextMap != null) { context.speciesCommonName = getOrEmptyString("species_common_name", contextMap); context.ncbiTaxId = getOrZero("ncbi_tax_id", contextMap); Set<String> varying = new HashSet<String>(contextMap.keySet()); varying.removeAll(asList("species_common_name", "ncbi_tax_id")); for (String key : varying) { context.variedAnnotations.put(key, contextMap.get(key)); } ev.biologicalContext = context; } evidenceList.add(ev); } return evidenceList.toArray(new Evidence[evidenceList.size()]); }
/** * Calculates the node distances. * * @return the <code>int[][]</code> array of calculated distances or null if the task was canceled * or there was an error */ public int[][] calculate() { int currentProgress = 0; this.maxValue = distances.length; CyNode[] nodes = new CyNode[nodesList.size()]; // TODO: REMOVE // System.err.println( "Calculating all node distances.. for: " // +nodesList.size()+" and "+nodes.length ); // We don't have to make new Integers all the time, so we store the index // Objects in this array for reuse. Integer[] integers = new Integer[nodes.length]; // Fill the nodes array with the nodes in their proper index locations. // int index; CyNode from_node; for (int i = 0; i < nodes.length; i++) { from_node = (CyNode) nodesList.get(i); if (from_node == null) { continue; } int index = ((Integer) nodeIndexToMatrixIndexMap.get(from_node.getSUID())).intValue(); // index = ((Integer) nodeIndexToMatrixIndexMap.get(new // Integer(from_node.getRootGraphIndex()))).intValue(); if ((index < 0) || (index >= nodes.length)) { System.err.println( "WARNING: GraphNode \"" + from_node + "\" has an index value that is out of range: " + index + ". Graph indices should be maintained such " + "that no index is unused."); return null; } if (nodes[index] != null) { System.err.println( "WARNING: GraphNode \"" + from_node + "\" has an index value ( " + index + " ) that is the same as " + "that of another GraphNode ( \"" + nodes[index] + "\" ). Graph indices should be maintained such " + "that indices are unique."); return null; } nodes[index] = from_node; Integer in = new Integer(index); integers[index] = in; } LinkedList queue = new LinkedList(); boolean[] completed_nodes = new boolean[nodes.length]; Iterator neighbors; CyNode to_node; CyNode neighbor; int neighbor_index; int to_node_distance; int neighbor_distance; for (int from_node_index = 0; from_node_index < nodes.length; from_node_index++) { if (this.interrupted) { // The task was canceled this.distances = null; return this.distances; } from_node = nodes[from_node_index]; if (from_node == null) { // Make the distances in this row all Integer.MAX_VALUE. if (distances[from_node_index] == null) { distances[from_node_index] = new int[nodes.length]; } Arrays.fill(distances[from_node_index], Integer.MAX_VALUE); continue; } // TODO: REMOVE // System.err.print( "Calculating node distances from graph node " + // from_node ); // System.err.flush(); // Make the distances row and initialize it. if (distances[from_node_index] == null) { distances[from_node_index] = new int[nodes.length]; } Arrays.fill(distances[from_node_index], Integer.MAX_VALUE); distances[from_node_index][from_node_index] = 0; // Reset the completed nodes array. Arrays.fill(completed_nodes, false); // Add the start node to the queue. queue.add(integers[from_node_index]); while (!(queue.isEmpty())) { if (this.interrupted) { // The task was canceled this.distances = null; return this.distances; } int index = ((Integer) queue.removeFirst()).intValue(); if (completed_nodes[index]) { continue; } completed_nodes[index] = true; to_node = nodes[index]; to_node_distance = distances[from_node_index][index]; if (index < from_node_index) { // Oh boy. We've already got every distance from/to this node. int distance_through_to_node; for (int i = 0; i < nodes.length; i++) { if (distances[index][i] == Integer.MAX_VALUE) { continue; } distance_through_to_node = to_node_distance + distances[index][i]; if (distance_through_to_node <= distances[from_node_index][i]) { // Any immediate neighbor of a node that's already been // calculated for that does not already have a shorter path // calculated from from_node never will, and is thus complete. if (distances[index][i] == 1) { completed_nodes[i] = true; } distances[from_node_index][i] = distance_through_to_node; } } // End for every node, update the distance using the distance from // to_node. // So now we don't need to put any neighbors on the queue or // anything, since they've already been taken care of by the previous // calculation. continue; } // End if to_node has already had all of its distances calculated. neighbors = getNeighbors(to_node).iterator(); // neighbors = perspective.neighborsList(to_node).iterator(); while (neighbors.hasNext()) { if (this.interrupted) { this.distances = null; return this.distances; } neighbor = (CyNode) neighbors.next(); neighbor_index = ((Integer) nodeIndexToMatrixIndexMap.get(neighbor.getSUID())).intValue(); // neighbor_index = ((Integer) nodeIndexToMatrixIndexMap.get(new // Integer(neighbor.getRootGraphIndex()))).intValue(); // If this neighbor was not in the incoming List, we cannot include // it in any paths. if (nodes[neighbor_index] == null) { distances[from_node_index][neighbor_index] = Integer.MAX_VALUE; continue; } if (completed_nodes[neighbor_index]) { // We've already done everything we can here. continue; } neighbor_distance = distances[from_node_index][neighbor_index]; if ((to_node_distance != Integer.MAX_VALUE) && (neighbor_distance > (to_node_distance + 1))) { distances[from_node_index][neighbor_index] = (to_node_distance + 1); queue.addLast(integers[neighbor_index]); } // TODO: REMOVE // System.out.print( "." ); // System.out.flush(); } // For each of the next nodes' neighbors // TODO: REMOVE // System.out.print( "|" ); // System.out.flush(); } // For each to_node, in order of their (present) distances // TODO: REMOVE /* System.err.println( "done." ); */ // Calculate Percentage. This must be a value between 0..100. int percentComplete = (int) (((double) currentProgress / maxValue) * 100); // Estimate Time Remaining long timeRemaining = maxValue - currentProgress; // Update the Task Monitor. // This automatically updates the UI Component w/ progress bar. if (taskMonitor != null) { taskMonitor.setProgress(percentComplete); taskMonitor.setStatusMessage( "Calculating Node Distances: " + currentProgress + "of " + maxValue); // taskMonitor.setEstimatedTimeRemaining(timeRemaining); } currentProgress++; } // For each from_node // TODO: REMOVE // System.err.println( "..Done calculating all node distances." ); return distances; } // calculate