[FIX] re-add Dracula removed in rev xmo@openerp.com-20120305103353-w8r6fk9cv8wjklts: turns out Process needs it
bzr revid: xmo@openerp.com-20120305110813-b00fhngx0e5p0efo
This commit is contained in:
parent
fc887bfb2f
commit
06abe5aa3d
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@ -5,8 +5,9 @@
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"""
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OpenERP Web process view.
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""",
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"depends" : ["web"],
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"depends" : ["diagram"],
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"js": [
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'static/lib/dracula/*.js',
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"static/src/js/process.js"
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],
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"css": [
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@ -0,0 +1,599 @@
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/*
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* Various algorithms and data structures, licensed under the MIT-license.
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* (c) 2010 by Johann Philipp Strathausen <strathausen@gmail.com>
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* http://strathausen.eu
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*
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*/
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/*
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Bellman-Ford
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Path-finding algorithm, finds the shortest paths from one node to all nodes.
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Complexity
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O( |E| · |V| ), where E = edges and V = vertices (nodes)
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Constraints
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Can run on graphs with negative edge weights as long as they do not have
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any negative weight cycles.
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*/
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function bellman_ford(g, source) {
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/* STEP 1: initialisation */
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for(var n in g.nodes)
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g.nodes[n].distance = Infinity;
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/* predecessors are implicitly null */
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source.distance = 0;
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step("Initially, all distances are infinite and all predecessors are null.");
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/* STEP 2: relax each edge (this is at the heart of Bellman-Ford) */
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/* repeat this for the number of nodes minus one */
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for(var i = 1; i < g.nodes.length; i++)
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/* for each edge */
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for(var e in g.edges) {
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var edge = g.edges[e];
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if(edge.source.distance + edge.weight < edge.target.distance) {
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step("Relax edge between " + edge.source.id + " and " + edge.target.id + ".");
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edge.target.distance = edge.source.distance + edge.weight;
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edge.target.predecessor = edge.source;
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}
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//Added by Jake Stothard (Needs to be tested)
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if(!edge.style.directed) {
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if(edge.target.distance + edge.weight < edge.source.distance) {
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g.snapShot("Relax edge between "+edge.target.id+" and "+edge.source.id+".");
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edge.source.distance = edge.target.distance + edge.weight;
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edge.source.predecessor = edge.target;
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}
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}
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}
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step("Ready.");
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/* STEP 3: TODO Check for negative cycles */
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/* For now we assume here that the graph does not contain any negative
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weights cycles. (this is left as an excercise to the reader[tm]) */
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}
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/*
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Path-finding algorithm Dijkstra
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- worst-case running time is O((|E| + |V|) · log |V| ) thus better than
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Bellman-Ford for sparse graphs (with less edges), but cannot handle
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negative edge weights
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*/
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function dijkstra(g, source) {
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/* initially, all distances are infinite and all predecessors are null */
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for(var n in g.nodes)
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g.nodes[n].distance = Infinity;
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/* predecessors are implicitly null */
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g.snapShot("Initially, all distances are infinite and all predecessors are null.");
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source.distance = 0;
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/* set of unoptimized nodes, sorted by their distance (but a Fibonacci heap
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would be better) */
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var q = new BinaryMinHeap(g.nodes, "distance");
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/* pointer to the node in focus */
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var node;
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/* get the node with the smallest distance
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as long as we have unoptimized nodes. q.min() can have O(log n). */
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while(q.min() != undefined) {
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/* remove the latest */
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node = q.extractMin();
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node.optimized = true;
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/* no nodes accessible from this one, should not happen */
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if(node.distance == Infinity)
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throw "Orphaned node!";
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/* for each neighbour of node */
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for(e in node.edges) {
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var other = (node == node.edges[e].target) ? node.edges[e].source : node.edges[e].target;
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if(other.optimized)
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continue;
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/* look for an alternative route */
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var alt = node.distance + node.edges[e].weight;
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/* update distance and route if a better one has been found */
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if (alt < other.distance) {
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/* update distance of neighbour */
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other.distance = alt;
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/* update priority queue */
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q.heapify();
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/* update path */
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other.predecessor = node;
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g.snapShot("Enhancing node.")
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}
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}
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}
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}
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/* All-Pairs-Shortest-Paths */
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/* Runs at worst in O(|V|³) and at best in Omega(|V|³) :-)
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complexity Sigma(|V|²) */
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/* This implementation is not yet ready for general use, but works with the
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Dracula graph library. */
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function floyd_warshall(g, source) {
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/* Step 1: initialising empty path matrix (second dimension is implicit) */
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var path = [];
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var next = [];
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var n = g.nodes.length;
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/* construct path matrix, initialize with Infinity */
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for(j in g.nodes) {
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path[j] = [];
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next[j] = [];
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for(i in g.nodes)
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path[j][i] = j == i ? 0 : Infinity;
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}
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/* initialize path with edge weights */
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for(e in g.edges)
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path[g.edges[e].source.id][g.edges[e].target.id] = g.edges[e].weight;
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/* Note: Usually, the initialisation is done by getting the edge weights
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from a node matrix representation of the graph, not by iterating through
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a list of edges as done here. */
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/* Step 2: find best distances (the heart of Floyd-Warshall) */
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for(k in g.nodes){
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for(i in g.nodes) {
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for(j in g.nodes)
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if(path[i][j] > path[i][k] + path[k][j]) {
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path[i][j] = path[i][k] + path[k][j];
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/* Step 2.b: remember the path */
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next[i][j] = k;
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}
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}
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}
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/* Step 3: Path reconstruction, get shortest path */
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function getPath(i, j) {
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if(path[i][j] == Infinity)
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throw "There is no path.";
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var intermediate = next[i][j];
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if(intermediate == undefined)
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return null;
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else
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return getPath(i, intermediate)
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.concat([intermediate])
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.concat(getPath(intermediate, j));
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}
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/* TODO use the knowledge, e.g. mark path in graph */
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}
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/*
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Ford-Fulkerson
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Max-Flow-Min-Cut Algorithm finding the maximum flow through a directed
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graph from source to sink.
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Complexity
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O(E * max(f)), max(f) being the maximum flow
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Description
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As long as there is an open path through the residual graph, send the
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minimum of the residual capacities on the path.
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Constraints
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The algorithm works only if all weights are integers. Otherwise it is
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possible that the Ford–Fulkerson algorithm will not converge to the maximum
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value.
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Input
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g - Graph object
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s - Source ID
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t - Target (sink) ID
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Output
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Maximum flow from Source s to Target t
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*/
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/*
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Edmonds-Karp
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Max-Flow-Min-Cut Algorithm finding the maximum flow through a directed
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graph from source to sink. An implementation of the Ford-Fulkerson
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algorithm.
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Complexity
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O(|V|*|E|²)
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Input
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g - Graph object (with node and edge lists, capacity is a property of edge)
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s - source ID
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t - sink ID
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*/
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function edmonds_karp(g, s, t) {
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}
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/*
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A simple binary min-heap serving as a priority queue
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- takes an array as the input, with elements having a key property
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- elements will look like this:
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{
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key: "... key property ...",
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value: "... element content ..."
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}
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- provides insert(), min(), extractMin() and heapify()
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- example usage (e.g. via the Firebug or Chromium console):
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var x = {foo: 20, hui: "bla"};
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var a = new BinaryMinHeap([x,{foo:3},{foo:10},{foo:20},{foo:30},{foo:6},{foo:1},{foo:3}],"foo");
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console.log(a.extractMin());
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console.log(a.extractMin());
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x.foo = 0; // update key
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a.heapify(); // call this always after having a key updated
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console.log(a.extractMin());
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console.log(a.extractMin());
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- can also be used on a simple array, like [9,7,8,5]
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*/
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function BinaryMinHeap(array, key) {
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/* Binary tree stored in an array, no need for a complicated data structure */
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var tree = [];
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var key = key || 'key';
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/* Calculate the index of the parent or a child */
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var parent = function(index) { return Math.floor((index - 1)/2); };
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var right = function(index) { return 2 * index + 2; };
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var left = function(index) { return 2 * index + 1; };
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/* Helper function to swap elements with their parent
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as long as the parent is bigger */
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function bubble_up(i) {
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var p = parent(i);
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while((p >= 0) && (tree[i][key] < tree[p][key])) {
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/* swap with parent */
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tree[i] = tree.splice(p, 1, tree[i])[0];
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/* go up one level */
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i = p;
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p = parent(i);
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}
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}
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/* Helper function to swap elements with the smaller of their children
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as long as there is one */
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function bubble_down(i) {
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var l = left(i);
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var r = right(i);
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/* as long as there are smaller children */
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while(tree[l] && (tree[i][key] > tree[l][key]) || tree[r] && (tree[i][key] > tree[r][key])) {
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/* find smaller child */
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var child = tree[l] ? tree[r] ? tree[l][key] > tree[r][key] ? r : l : l : l;
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/* swap with smaller child with current element */
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tree[i] = tree.splice(child, 1, tree[i])[0];
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/* go up one level */
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i = child;
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l = left(i);
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r = right(i);
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}
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}
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/* Insert a new element with respect to the heap property
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1. Insert the element at the end
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2. Bubble it up until it is smaller than its parent */
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this.insert = function(element) {
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/* make sure there's a key property */
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(element[key] == undefined) && (element = {key:element});
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/* insert element at the end */
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tree.push(element);
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/* bubble up the element */
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bubble_up(tree.length - 1);
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}
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/* Only show us the minimum */
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this.min = function() {
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return tree.length == 1 ? undefined : tree[0];
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}
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/* Return and remove the minimum
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1. Take the root as the minimum that we are looking for
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2. Move the last element to the root (thereby deleting the root)
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3. Compare the new root with both of its children, swap it with the
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smaller child and then check again from there (bubble down)
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*/
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this.extractMin = function() {
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var result = this.min();
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/* move the last element to the root or empty the tree completely */
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/* bubble down the new root if necessary */
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(tree.length == 1) && (tree = []) || (tree[0] = tree.pop()) && bubble_down(0);
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return result;
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}
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/* currently unused, TODO implement */
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this.changeKey = function(index, key) {
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throw "function not implemented";
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}
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this.heapify = function() {
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for(var start = Math.floor((tree.length - 2) / 2); start >= 0; start--) {
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bubble_down(start);
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}
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}
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/* insert the input elements one by one only when we don't have a key property (TODO can be done more elegant) */
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for(i in (array || []))
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this.insert(array[i]);
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}
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/*
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Quick Sort:
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1. Select some random value from the array, the median.
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2. Divide the array in three smaller arrays according to the elements
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being less, equal or greater than the median.
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3. Recursively sort the array containg the elements less than the
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median and the one containing elements greater than the median.
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4. Concatenate the three arrays (less, equal and greater).
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5. One or no element is always sorted.
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TODO: This could be implemented more efficiently by using only one array object and several pointers.
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*/
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function quickSort(arr) {
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/* recursion anchor: one element is always sorted */
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if(arr.length <= 1) return arr;
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/* randomly selecting some value */
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var median = arr[Math.floor(Math.random() * arr.length)];
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var arr1 = [], arr2 = [], arr3 = [];
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for(var i in arr) {
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arr[i] < median && arr1.push(arr[i]);
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arr[i] == median && arr2.push(arr[i]);
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arr[i] > median && arr3.push(arr[i]);
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}
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/* recursive sorting and assembling final result */
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return quickSort(arr1).concat(arr2).concat(quickSort(arr3));
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}
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/*
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Selection Sort:
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1. Select the minimum and remove it from the array
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2. Sort the rest recursively
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3. Return the minimum plus the sorted rest
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4. An array with only one element is already sorted
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*/
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function selectionSort(arr) {
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/* recursion anchor: one element is always sorted */
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if(arr.length == 1) return arr;
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var minimum = Infinity;
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var index;
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for(var i in arr) {
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if(arr[i] < minimum) {
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minimum = arr[i];
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index = i; /* remember the minimum index for later removal */
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}
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}
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/* remove the minimum */
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arr.splice(index, 1);
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/* assemble result and sort recursively (could be easily done iteratively as well)*/
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return [minimum].concat(selectionSort(arr));
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}
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/*
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Merge Sort:
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1. Cut the array in half
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2. Sort each of them recursively
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3. Merge the two sorted arrays
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4. An array with only one element is considered sorted
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*/
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function mergeSort(arr) {
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/* merges two sorted arrays into one sorted array */
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function merge(a, b) {
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/* result set */
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var c = [];
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/* as long as there are elements in the arrays to be merged */
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while(a.length > 0 || b.length > 0){
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/* are there elements to be merged, if yes, compare them and merge */
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var n = a.length > 0 && b.length > 0 ? a[0] < b[0] ? a.shift() : b.shift() : b.length > 0 ? b.shift() : a.length > 0 ? a.shift() : null;
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/* always push the smaller one onto the result set */
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n != null && c.push(n);
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}
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return c;
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}
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/* this mergeSort implementation cuts the array in half, wich should be fine with randomized arrays, but introduces the risk of a worst-case scenario */
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median = Math.floor(arr.length / 2);
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var part1 = arr.slice(0, median); /* for some reason it doesn't work if inserted directly in the return statement (tried so with firefox) */
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var part2 = arr.slice(median - arr.length);
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return arr.length <= 1 ? arr : merge(
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mergeSort(part1), /* first half */
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mergeSort(part2) /* second half */
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);
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}
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/* Balanced Red-Black-Tree */
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function RedBlackTree(arr) {
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}
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function BTree(arr) {
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}
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function NaryTree(n, arr) {
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}
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/**
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* Knuth-Morris-Pratt string matching algorithm - finds a pattern in a text.
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* FIXME: Doesn't work correctly yet.
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*/
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function kmp(p, t) {
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/**
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* PREFIX, OVERLAP or FALIURE function for KMP. Computes how many iterations
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* the algorithm can skip after a mismatch.
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*
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* @input p - pattern (string)
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* @result array of skippable iterations
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*/
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function prefix(p) {
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/* pi contains the computed skip marks */
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var pi = [0], k = 0;
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for(q = 1; q < p.length; q++) {
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while(k > 0 && (p.charAt(k) != p.charAt(q)))
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k = pi[k-1];
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(p.charAt(k) == p.charAt(q)) && k++;
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pi[q] = k;
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}
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return pi;
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}
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/* The actual KMP algorithm starts here. */
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var pi = prefix(p), q = 0, result = [];
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||||
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for(var i = 0; i < t.length; i++) {
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/* jump forward as long as the character doesn't match */
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while((q > 0) && (p.charAt(q) != t.charAt(i)))
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q = pi[q];
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||||
|
||||
(p.charAt(q) == t.charAt(i)) && q++;
|
||||
|
||||
(q == p.length) && result.push(i - p.length) && (q = pi[q]);
|
||||
}
|
||||
|
||||
return result;
|
||||
}
|
||||
|
||||
/* step for algorithm visualisation */
|
||||
function step(comment, funct) {
|
||||
//wait for input
|
||||
//display comment (before or after waiting)
|
||||
// next.wait();
|
||||
/* execute callback function */
|
||||
funct();
|
||||
}
|
||||
|
||||
/**
|
||||
* Curry - Function currying
|
||||
* Copyright (c) 2008 Ariel Flesler - aflesler(at)gmail(dot)com | http://flesler.blogspot.com
|
||||
* Licensed under BSD (http://www.opensource.org/licenses/bsd-license.php)
|
||||
* Date: 10/4/2008
|
||||
*
|
||||
* @author Ariel Flesler
|
||||
* @version 1.0.1
|
||||
*/
|
||||
function curry( fn ){
|
||||
return function(){
|
||||
var args = curry.args(arguments),
|
||||
master = arguments.callee,
|
||||
self = this;
|
||||
|
||||
return args.length >= fn.length ? fn.apply(self,args) : function(){
|
||||
return master.apply( self, args.concat(curry.args(arguments)) );
|
||||
};
|
||||
};
|
||||
};
|
||||
|
||||
curry.args = function( args ){
|
||||
return Array.prototype.slice.call(args);
|
||||
};
|
||||
|
||||
Function.prototype.curry = function(){
|
||||
return curry(this);
|
||||
};
|
||||
|
||||
/**
|
||||
* Topological Sort
|
||||
*
|
||||
* Sort a directed graph based on incoming edges
|
||||
*
|
||||
* Coded by Jake Stothard
|
||||
*/
|
||||
function topological_sort(g) {
|
||||
//Mark nodes as "deleted" instead of actually deleting them
|
||||
//That way we don't have to copy g
|
||||
|
||||
for(i in g.nodes)
|
||||
g.nodes[i].deleted = false;
|
||||
|
||||
var ret = topological_sort_helper(g);
|
||||
|
||||
//Cleanup: Remove the deleted property
|
||||
for(i in g.nodes)
|
||||
delete g.nodes[i].deleted
|
||||
|
||||
return ret;
|
||||
}
|
||||
function topological_sort_helper(g) {
|
||||
//Find node with no incoming edges
|
||||
var node;
|
||||
for(i in g.nodes) {
|
||||
if(g.nodes[i].deleted)
|
||||
continue; //Bad style, meh
|
||||
|
||||
var incoming = false;
|
||||
for(j in g.nodes[i].edges) {
|
||||
if(g.nodes[i].edges[j].target == g.nodes[i]
|
||||
&& g.nodes[i].edges[j].source.deleted == false) {
|
||||
incoming = true;
|
||||
break;
|
||||
}
|
||||
}
|
||||
if(!incoming) {
|
||||
node = g.nodes[i];
|
||||
break;
|
||||
}
|
||||
}
|
||||
|
||||
// Either unsortable or done. Either way, GTFO
|
||||
if(node == undefined)
|
||||
return [];
|
||||
|
||||
//"Delete" node from g
|
||||
node.deleted = true;
|
||||
|
||||
var tail = topological_sort_helper(g);
|
||||
|
||||
tail.unshift(node);
|
||||
|
||||
return tail;
|
||||
}
|
|
@ -0,0 +1,107 @@
|
|||
/**
|
||||
* Originally grabbed from the official RaphaelJS Documentation
|
||||
* http://raphaeljs.com/graffle.html
|
||||
* Adopted (arrows) and commented by Philipp Strathausen http://blog.ameisenbar.de
|
||||
* Licenced under the MIT licence.
|
||||
*/
|
||||
|
||||
/**
|
||||
* Usage:
|
||||
* connect two shapes
|
||||
* parameters:
|
||||
* source shape [or connection for redrawing],
|
||||
* target shape,
|
||||
* style with { fg : linecolor, bg : background color, directed: boolean }
|
||||
* returns:
|
||||
* connection { draw = function() }
|
||||
*/
|
||||
Raphael.fn.connection = function (obj1, obj2, style) {
|
||||
var selfRef = this;
|
||||
/* create and return new connection */
|
||||
var edge = {/*
|
||||
from : obj1,
|
||||
to : obj2,
|
||||
style : style,*/
|
||||
draw : function() {
|
||||
/* get bounding boxes of target and source */
|
||||
var bb1 = obj1.getBBox();
|
||||
var bb2 = obj2.getBBox();
|
||||
var off1 = 0;
|
||||
var off2 = 0;
|
||||
/* coordinates for potential connection coordinates from/to the objects */
|
||||
var p = [
|
||||
{x: bb1.x + bb1.width / 2, y: bb1.y - off1}, /* NORTH 1 */
|
||||
{x: bb1.x + bb1.width / 2, y: bb1.y + bb1.height + off1}, /* SOUTH 1 */
|
||||
{x: bb1.x - off1, y: bb1.y + bb1.height / 2}, /* WEST 1 */
|
||||
{x: bb1.x + bb1.width + off1, y: bb1.y + bb1.height / 2}, /* EAST 1 */
|
||||
{x: bb2.x + bb2.width / 2, y: bb2.y - off2}, /* NORTH 2 */
|
||||
{x: bb2.x + bb2.width / 2, y: bb2.y + bb2.height + off2}, /* SOUTH 2 */
|
||||
{x: bb2.x - off2, y: bb2.y + bb2.height / 2}, /* WEST 2 */
|
||||
{x: bb2.x + bb2.width + off2, y: bb2.y + bb2.height / 2} /* EAST 2 */
|
||||
];
|
||||
|
||||
/* distances between objects and according coordinates connection */
|
||||
var d = {}, dis = [];
|
||||
|
||||
/*
|
||||
* find out the best connection coordinates by trying all possible ways
|
||||
*/
|
||||
/* loop the first object's connection coordinates */
|
||||
for (var i = 0; i < 4; i++) {
|
||||
/* loop the seond object's connection coordinates */
|
||||
for (var j = 4; j < 8; j++) {
|
||||
var dx = Math.abs(p[i].x - p[j].x),
|
||||
dy = Math.abs(p[i].y - p[j].y);
|
||||
if ((i == j - 4) || (((i != 3 && j != 6) || p[i].x < p[j].x) && ((i != 2 && j != 7) || p[i].x > p[j].x) && ((i != 0 && j != 5) || p[i].y > p[j].y) && ((i != 1 && j != 4) || p[i].y < p[j].y))) {
|
||||
dis.push(dx + dy);
|
||||
d[dis[dis.length - 1].toFixed(3)] = [i, j];
|
||||
}
|
||||
}
|
||||
}
|
||||
var res = dis.length == 0 ? [0, 4] : d[Math.min.apply(Math, dis).toFixed(3)];
|
||||
/* bezier path */
|
||||
var x1 = p[res[0]].x,
|
||||
y1 = p[res[0]].y,
|
||||
x4 = p[res[1]].x,
|
||||
y4 = p[res[1]].y,
|
||||
dx = Math.max(Math.abs(x1 - x4) / 2, 10),
|
||||
dy = Math.max(Math.abs(y1 - y4) / 2, 10),
|
||||
x2 = [x1, x1, x1 - dx, x1 + dx][res[0]].toFixed(3),
|
||||
y2 = [y1 - dy, y1 + dy, y1, y1][res[0]].toFixed(3),
|
||||
x3 = [0, 0, 0, 0, x4, x4, x4 - dx, x4 + dx][res[1]].toFixed(3),
|
||||
y3 = [0, 0, 0, 0, y1 + dy, y1 - dy, y4, y4][res[1]].toFixed(3);
|
||||
/* assemble path and arrow */
|
||||
var path = ["M", x1.toFixed(3), y1.toFixed(3), "C", x2, y2, x3, y3, x4.toFixed(3), y4.toFixed(3)];
|
||||
/* arrow */
|
||||
if(style && style.directed) {
|
||||
/* magnitude, length of the last path vector */
|
||||
var mag = Math.sqrt((y4 - y3) * (y4 - y3) + (x4 - x3) * (x4 - x3));
|
||||
/* vector normalisation to specified length */
|
||||
var norm = function(x,l){return (-x*(l||5)/mag);};
|
||||
/* calculate array coordinates (two lines orthogonal to the path vector) */
|
||||
var arr = [
|
||||
{x:(norm(x4-x3)+norm(y4-y3)+x4).toFixed(3), y:(norm(y4-y3)+norm(x4-x3)+y4).toFixed(3)},
|
||||
{x:(norm(x4-x3)-norm(y4-y3)+x4).toFixed(3), y:(norm(y4-y3)-norm(x4-x3)+y4).toFixed(3)}
|
||||
];
|
||||
path.push("M", arr[0].x, arr[0].y, "L", x4, y4, "L", arr[1].x, arr[1].y, "L", arr[0].x, arr[0].y);
|
||||
}
|
||||
var svgpath = path.join(' ');
|
||||
/* function to be used for moving existent path(s), e.g. animate() or attr() */
|
||||
var move = "attr";
|
||||
/* applying path(s) */
|
||||
edge.fg && edge.fg[move]({path:svgpath})
|
||||
|| (edge.fg = selfRef.path(svgpath).attr({stroke: style && style.stroke || "#000", fill: "none"}).toBack());
|
||||
edge.bg && edge.bg[move]({path:svgpath})
|
||||
|| style && style.fill && (edge.bg = style.fill.split && selfRef.path(svgpath).attr({stroke: style.fill.split("|")[0], fill: "none", "stroke-width": style.fill.split("|")[1] || 3}).toBack());
|
||||
/* setting label */
|
||||
style && style.label
|
||||
&& (edge.label && edge.label.attr({x:(x1+x4)/2, y:(y1+y4)/2})
|
||||
|| (edge.label = selfRef.text((x1+x4)/2, (y1+y4)/2, style.label).attr({fill: "#000", "font-size": style["font-size"] || "12px"})));
|
||||
// && selfRef.text(x4, y4, style.label).attr({stroke: style && style.stroke || "#fff", "font-weight":"bold", "font-size":"20px"})
|
||||
// style && style.callback && style.callback(edge);
|
||||
}
|
||||
}
|
||||
edge.draw();
|
||||
return edge;
|
||||
};
|
||||
//Raphael.prototype.set.prototype.dodo=function(){console.log("works");};
|
|
@ -0,0 +1,524 @@
|
|||
###
|
||||
* Dracula Graph Layout and Drawing Framework 0.0.3alpha
|
||||
* (c) 2010 Philipp Strathausen <strathausen@gmail.com>, http://strathausen.eu
|
||||
*
|
||||
* Contributions by:
|
||||
* Branched by Jake Stothard <stothardj@gmail.com>.
|
||||
*
|
||||
* based on the Graph JavaScript framework, version 0.0.1
|
||||
* (c) 2006 Aslak Hellesoy <aslak.hellesoy@gmail.com>
|
||||
* (c) 2006 Dave Hoover <dave.hoover@gmail.com>
|
||||
*
|
||||
* Ported from Graph::Layouter::Spring in
|
||||
* http://search.cpan.org/~pasky/Graph-Layderer-0.02/
|
||||
* The algorithm is based on a spring-style layouter of a Java-based social
|
||||
* network tracker PieSpy written by Paul Mutton E<lt>paul@jibble.orgE<gt>.
|
||||
*
|
||||
* This code is freely distributable under the terms of an MIT-style license.
|
||||
* For details, see the Graph web site: http://dev.buildpatternd.com/trac
|
||||
*
|
||||
* Links:
|
||||
*
|
||||
* Graph Dracula JavaScript Framework:
|
||||
* http://graphdracula.net
|
||||
*
|
||||
* Demo of the original applet:
|
||||
* http://redsquirrel.com/dave/work/webdep/
|
||||
*
|
||||
* Mirrored original source code at snipplr:
|
||||
* http://snipplr.com/view/1950/graph-javascript-framework-version-001/
|
||||
*
|
||||
* Original usage example:
|
||||
* http://ajaxian.com/archives/new-javascriptcanvas-graph-library
|
||||
*
|
||||
###
|
||||
|
||||
|
||||
###
|
||||
Edge Factory
|
||||
###
|
||||
AbstractEdge = ->
|
||||
|
||||
AbstractEdge.prototype =
|
||||
hide: ->
|
||||
@connection.fg.hide()
|
||||
@connection.bg && @bg.connection.hide()
|
||||
|
||||
EdgeFactory = ->
|
||||
@template = new AbstractEdge()
|
||||
@template.style = new Object()
|
||||
@template.style.directed = false
|
||||
@template.weight = 1
|
||||
|
||||
EdgeFactory.prototype =
|
||||
build: (source, target) ->
|
||||
e = jQuery.extend true, {}, @template
|
||||
e.source = source
|
||||
e.target = target
|
||||
e
|
||||
|
||||
###
|
||||
Graph
|
||||
###
|
||||
Graph = ->
|
||||
@nodes = {}
|
||||
@edges = []
|
||||
@snapshots = [] # previous graph states TODO to be implemented
|
||||
@edgeFactory = new EdgeFactory()
|
||||
|
||||
Graph.prototype =
|
||||
###
|
||||
add a node
|
||||
@id the node's ID (string or number)
|
||||
@content (optional, dictionary) can contain any information that is
|
||||
being interpreted by the layout algorithm or the graph
|
||||
representation
|
||||
###
|
||||
addNode: (id, content) ->
|
||||
# testing if node is already existing in the graph
|
||||
if @nodes[id] == undefined
|
||||
@nodes[id] = new Graph.Node id, content
|
||||
@nodes[id]
|
||||
|
||||
addEdge: (source, target, style) ->
|
||||
s = @addNode source
|
||||
t = @addNode target
|
||||
var edge = @edgeFactory.build s, t
|
||||
jQuery.extend edge.style, style
|
||||
s.edges.push edge
|
||||
@edges.push edge
|
||||
# NOTE: Even directed edges are added to both nodes.
|
||||
t.edges.push edge
|
||||
|
||||
# TODO to be implemented
|
||||
# Preserve a copy of the graph state (nodes, positions, ...)
|
||||
# @comment a comment describing the state
|
||||
snapShot: (comment) ->
|
||||
###/* FIXME
|
||||
var graph = new Graph()
|
||||
graph.nodes = jQuery.extend(true, {}, @nodes)
|
||||
graph.edges = jQuery.extend(true, {}, @edges)
|
||||
@snapshots.push({comment: comment, graph: graph})
|
||||
*/
|
||||
###
|
||||
|
||||
removeNode: (id) ->
|
||||
delete @nodes[id]
|
||||
for i = 0; i < @edges.length; i++
|
||||
if @edges[i].source.id == id || @edges[i].target.id == id
|
||||
@edges.splice(i, 1)
|
||||
i--
|
||||
|
||||
/*
|
||||
* Node
|
||||
*/
|
||||
Graph.Node = (id, node) ->
|
||||
node = node || {}
|
||||
node.id = id
|
||||
node.edges = []
|
||||
node.hide = ->
|
||||
@hidden = true
|
||||
@shape && @shape.hide() # FIXME this is representation specific code and should be elsewhere */
|
||||
for(i in @edges)
|
||||
(@edges[i].source.id == id || @edges[i].target == id) && @edges[i].hide && @edges[i].hide()
|
||||
|
||||
node.show = ->
|
||||
@hidden = false
|
||||
@shape && @shape.show()
|
||||
for(i in @edges)
|
||||
(@edges[i].source.id == id || @edges[i].target == id) && @edges[i].show && @edges[i].show()
|
||||
|
||||
node
|
||||
|
||||
Graph.Node.prototype = { }
|
||||
|
||||
###
|
||||
Renderer base class
|
||||
###
|
||||
Graph.Renderer = { }
|
||||
|
||||
###
|
||||
Renderer implementation using RaphaelJS
|
||||
###
|
||||
Graph.Renderer.Raphael = (element, graph, width, height) ->
|
||||
@width = width || 400
|
||||
@height = height || 400
|
||||
var selfRef = this
|
||||
@r = Raphael element, @width, @height
|
||||
@radius = 40 # max dimension of a node
|
||||
@graph = graph
|
||||
@mouse_in = false
|
||||
|
||||
# TODO default node rendering
|
||||
if(!@graph.render) {
|
||||
@graph.render = ->
|
||||
return
|
||||
}
|
||||
}
|
||||
|
||||
/*
|
||||
* Dragging
|
||||
*/
|
||||
@isDrag = false
|
||||
@dragger = (e) ->
|
||||
@dx = e.clientX
|
||||
@dy = e.clientY
|
||||
selfRef.isDrag = this
|
||||
@set && @set.animate "fill-opacity": .1, 200 && @set.toFront()
|
||||
e.preventDefault && e.preventDefault()
|
||||
|
||||
document.onmousemove = (e) {
|
||||
e = e || window.event
|
||||
if (selfRef.isDrag) {
|
||||
var bBox = selfRef.isDrag.set.getBBox()
|
||||
// TODO round the coordinates here (eg. for proper image representation)
|
||||
var newX = e.clientX - selfRef.isDrag.dx + (bBox.x + bBox.width / 2)
|
||||
var newY = e.clientY - selfRef.isDrag.dy + (bBox.y + bBox.height / 2)
|
||||
/* prevent shapes from being dragged out of the canvas */
|
||||
var clientX = e.clientX - (newX < 20 ? newX - 20 : newX > selfRef.width - 20 ? newX - selfRef.width + 20 : 0)
|
||||
var clientY = e.clientY - (newY < 20 ? newY - 20 : newY > selfRef.height - 20 ? newY - selfRef.height + 20 : 0)
|
||||
selfRef.isDrag.set.translate(clientX - Math.round(selfRef.isDrag.dx), clientY - Math.round(selfRef.isDrag.dy))
|
||||
// console.log(clientX - Math.round(selfRef.isDrag.dx), clientY - Math.round(selfRef.isDrag.dy))
|
||||
for (var i in selfRef.graph.edges) {
|
||||
selfRef.graph.edges[i].connection && selfRef.graph.edges[i].connection.draw()
|
||||
}
|
||||
//selfRef.r.safari()
|
||||
selfRef.isDrag.dx = clientX
|
||||
selfRef.isDrag.dy = clientY
|
||||
}
|
||||
}
|
||||
document.onmouseup = ->
|
||||
selfRef.isDrag && selfRef.isDrag.set.animate({"fill-opacity": .6}, 500)
|
||||
selfRef.isDrag = false
|
||||
}
|
||||
@draw()
|
||||
}
|
||||
Graph.Renderer.Raphael.prototype = {
|
||||
translate: (point) {
|
||||
return [
|
||||
(point[0] - @graph.layoutMinX) * @factorX + @radius,
|
||||
(point[1] - @graph.layoutMinY) * @factorY + @radius
|
||||
]
|
||||
},
|
||||
|
||||
rotate: (point, length, angle) {
|
||||
var dx = length * Math.cos(angle)
|
||||
var dy = length * Math.sin(angle)
|
||||
return [point[0]+dx, point[1]+dy]
|
||||
},
|
||||
|
||||
draw: ->
|
||||
@factorX = (@width - 2 * @radius) / (@graph.layoutMaxX - @graph.layoutMinX)
|
||||
@factorY = (@height - 2 * @radius) / (@graph.layoutMaxY - @graph.layoutMinY)
|
||||
for (i in @graph.nodes) {
|
||||
@drawNode(@graph.nodes[i])
|
||||
}
|
||||
for (var i = 0; i < @graph.edges.length; i++) {
|
||||
@drawEdge(@graph.edges[i])
|
||||
}
|
||||
},
|
||||
|
||||
drawNode: (node) {
|
||||
var point = @translate([node.layoutPosX, node.layoutPosY])
|
||||
node.point = point
|
||||
|
||||
/* if node has already been drawn, move the nodes */
|
||||
if(node.shape) {
|
||||
var oBBox = node.shape.getBBox()
|
||||
var opoint = { x: oBBox.x + oBBox.width / 2, y: oBBox.y + oBBox.height / 2}
|
||||
node.shape.translate(Math.round(point[0] - opoint.x), Math.round(point[1] - opoint.y))
|
||||
@r.safari()
|
||||
return node
|
||||
}/* else, draw new nodes */
|
||||
|
||||
var shape
|
||||
|
||||
/* if a node renderer is provided by the user, then use it
|
||||
or the default render instead */
|
||||
if(!node.render) {
|
||||
node.render = (r, node) {
|
||||
/* the default node drawing */
|
||||
var color = Raphael.getColor()
|
||||
var ellipse = r.ellipse(0, 0, 30, 20).attr({fill: color, stroke: color, "stroke-width": 2})
|
||||
/* set DOM node ID */
|
||||
ellipse.node.id = node.label || node.id
|
||||
shape = r.set().
|
||||
push(ellipse).
|
||||
push(r.text(0, 30, node.label || node.id))
|
||||
return shape
|
||||
}
|
||||
}
|
||||
/* or check for an ajax representation of the nodes */
|
||||
if(node.shapes) {
|
||||
// TODO ajax representation evaluation
|
||||
}
|
||||
|
||||
shape = node.render(@r, node).hide()
|
||||
|
||||
shape.attr({"fill-opacity": .6})
|
||||
/* re-reference to the node an element belongs to, needed for dragging all elements of a node */
|
||||
shape.items.forEach((item){ item.set = shape; item.node.style.cursor = "move"; })
|
||||
shape.mousedown(@dragger)
|
||||
|
||||
var box = shape.getBBox()
|
||||
shape.translate(Math.round(point[0]-(box.x+box.width/2)),Math.round(point[1]-(box.y+box.height/2)))
|
||||
//console.log(box,point)
|
||||
node.hidden || shape.show()
|
||||
node.shape = shape
|
||||
},
|
||||
drawEdge: (edge) {
|
||||
/* if this edge already exists the other way around and is undirected */
|
||||
if(edge.backedge)
|
||||
return
|
||||
if(edge.source.hidden || edge.target.hidden) {
|
||||
edge.connection && edge.connection.fg.hide() | edge.connection.bg && edge.connection.bg.hide()
|
||||
return
|
||||
}
|
||||
/* if edge already has been drawn, only refresh the edge */
|
||||
if(!edge.connection) {
|
||||
edge.style && edge.style.callback && edge.style.callback(edge); // TODO move this somewhere else
|
||||
edge.connection = @r.connection(edge.source.shape, edge.target.shape, edge.style)
|
||||
return
|
||||
}
|
||||
//FIXME showing doesn't work well
|
||||
edge.connection.fg.show()
|
||||
edge.connection.bg && edge.connection.bg.show()
|
||||
edge.connection.draw()
|
||||
}
|
||||
}
|
||||
Graph.Layout = {}
|
||||
Graph.Layout.Spring = (graph) {
|
||||
@graph = graph
|
||||
@iterations = 500
|
||||
@maxRepulsiveForceDistance = 6
|
||||
@k = 2
|
||||
@c = 0.01
|
||||
@maxVertexMovement = 0.5
|
||||
@layout()
|
||||
}
|
||||
Graph.Layout.Spring.prototype = {
|
||||
layout: ->
|
||||
@layoutPrepare()
|
||||
for (var i = 0; i < @iterations; i++) {
|
||||
@layoutIteration()
|
||||
}
|
||||
@layoutCalcBounds()
|
||||
},
|
||||
|
||||
layoutPrepare: ->
|
||||
for (i in @graph.nodes) {
|
||||
var node = @graph.nodes[i]
|
||||
node.layoutPosX = 0
|
||||
node.layoutPosY = 0
|
||||
node.layoutForceX = 0
|
||||
node.layoutForceY = 0
|
||||
}
|
||||
|
||||
},
|
||||
|
||||
layoutCalcBounds: ->
|
||||
var minx = Infinity, maxx = -Infinity, miny = Infinity, maxy = -Infinity
|
||||
|
||||
for (i in @graph.nodes) {
|
||||
var x = @graph.nodes[i].layoutPosX
|
||||
var y = @graph.nodes[i].layoutPosY
|
||||
|
||||
if(x > maxx) maxx = x
|
||||
if(x < minx) minx = x
|
||||
if(y > maxy) maxy = y
|
||||
if(y < miny) miny = y
|
||||
}
|
||||
|
||||
@graph.layoutMinX = minx
|
||||
@graph.layoutMaxX = maxx
|
||||
@graph.layoutMinY = miny
|
||||
@graph.layoutMaxY = maxy
|
||||
},
|
||||
|
||||
layoutIteration: ->
|
||||
// Forces on nodes due to node-node repulsions
|
||||
|
||||
var prev = new Array()
|
||||
for(var c in @graph.nodes) {
|
||||
var node1 = @graph.nodes[c]
|
||||
for (var d in prev) {
|
||||
var node2 = @graph.nodes[prev[d]]
|
||||
@layoutRepulsive(node1, node2)
|
||||
|
||||
}
|
||||
prev.push(c)
|
||||
}
|
||||
|
||||
// Forces on nodes due to edge attractions
|
||||
for (var i = 0; i < @graph.edges.length; i++) {
|
||||
var edge = @graph.edges[i]
|
||||
@layoutAttractive(edge);
|
||||
}
|
||||
|
||||
// Move by the given force
|
||||
for (i in @graph.nodes) {
|
||||
var node = @graph.nodes[i]
|
||||
var xmove = @c * node.layoutForceX
|
||||
var ymove = @c * node.layoutForceY
|
||||
|
||||
var max = @maxVertexMovement
|
||||
if(xmove > max) xmove = max
|
||||
if(xmove < -max) xmove = -max
|
||||
if(ymove > max) ymove = max
|
||||
if(ymove < -max) ymove = -max
|
||||
|
||||
node.layoutPosX += xmove
|
||||
node.layoutPosY += ymove
|
||||
node.layoutForceX = 0
|
||||
node.layoutForceY = 0
|
||||
}
|
||||
},
|
||||
|
||||
layoutRepulsive: (node1, node2) {
|
||||
var dx = node2.layoutPosX - node1.layoutPosX
|
||||
var dy = node2.layoutPosY - node1.layoutPosY
|
||||
var d2 = dx * dx + dy * dy
|
||||
if(d2 < 0.01) {
|
||||
dx = 0.1 * Math.random() + 0.1
|
||||
dy = 0.1 * Math.random() + 0.1
|
||||
var d2 = dx * dx + dy * dy
|
||||
}
|
||||
var d = Math.sqrt(d2)
|
||||
if(d < @maxRepulsiveForceDistance) {
|
||||
var repulsiveForce = @k * @k / d
|
||||
node2.layoutForceX += repulsiveForce * dx / d
|
||||
node2.layoutForceY += repulsiveForce * dy / d
|
||||
node1.layoutForceX -= repulsiveForce * dx / d
|
||||
node1.layoutForceY -= repulsiveForce * dy / d
|
||||
}
|
||||
},
|
||||
|
||||
layoutAttractive: (edge) {
|
||||
var node1 = edge.source
|
||||
var node2 = edge.target
|
||||
|
||||
var dx = node2.layoutPosX - node1.layoutPosX
|
||||
var dy = node2.layoutPosY - node1.layoutPosY
|
||||
var d2 = dx * dx + dy * dy
|
||||
if(d2 < 0.01) {
|
||||
dx = 0.1 * Math.random() + 0.1
|
||||
dy = 0.1 * Math.random() + 0.1
|
||||
var d2 = dx * dx + dy * dy
|
||||
}
|
||||
var d = Math.sqrt(d2)
|
||||
if(d > @maxRepulsiveForceDistance) {
|
||||
d = @maxRepulsiveForceDistance
|
||||
d2 = d * d
|
||||
}
|
||||
var attractiveForce = (d2 - @k * @k) / @k
|
||||
if(edge.attraction == undefined) edge.attraction = 1
|
||||
attractiveForce *= Math.log(edge.attraction) * 0.5 + 1
|
||||
|
||||
node2.layoutForceX -= attractiveForce * dx / d
|
||||
node2.layoutForceY -= attractiveForce * dy / d
|
||||
node1.layoutForceX += attractiveForce * dx / d
|
||||
node1.layoutForceY += attractiveForce * dy / d
|
||||
}
|
||||
}
|
||||
|
||||
Graph.Layout.Ordered = (graph, order) {
|
||||
@graph = graph
|
||||
@order = order
|
||||
@layout()
|
||||
}
|
||||
Graph.Layout.Ordered.prototype = {
|
||||
layout: ->
|
||||
@layoutPrepare()
|
||||
@layoutCalcBounds()
|
||||
},
|
||||
|
||||
layoutPrepare: (order) {
|
||||
for (i in @graph.nodes) {
|
||||
var node = @graph.nodes[i]
|
||||
node.layoutPosX = 0
|
||||
node.layoutPosY = 0
|
||||
}
|
||||
var counter = 0
|
||||
for (i in @order) {
|
||||
var node = @order[i]
|
||||
node.layoutPosX = counter
|
||||
node.layoutPosY = Math.random()
|
||||
counter++
|
||||
}
|
||||
},
|
||||
|
||||
layoutCalcBounds: ->
|
||||
var minx = Infinity, maxx = -Infinity, miny = Infinity, maxy = -Infinity
|
||||
|
||||
for (i in @graph.nodes) {
|
||||
var x = @graph.nodes[i].layoutPosX
|
||||
var y = @graph.nodes[i].layoutPosY
|
||||
|
||||
if(x > maxx) maxx = x
|
||||
if(x < minx) minx = x
|
||||
if(y > maxy) maxy = y
|
||||
if(y < miny) miny = y
|
||||
}
|
||||
|
||||
@graph.layoutMinX = minx
|
||||
@graph.layoutMaxX = maxx
|
||||
|
||||
@graph.layoutMinY = miny
|
||||
@graph.layoutMaxY = maxy
|
||||
}
|
||||
}
|
||||
|
||||
/*
|
||||
* usefull JavaScript extensions,
|
||||
*/
|
||||
|
||||
log(a) {console.log&&console.log(a);}
|
||||
|
||||
/*
|
||||
* Raphael Tooltip Plugin
|
||||
* - attaches an element as a tooltip to another element
|
||||
*
|
||||
* Usage example, adding a rectangle as a tooltip to a circle:
|
||||
*
|
||||
* paper.circle(100,100,10).tooltip(paper.rect(0,0,20,30))
|
||||
*
|
||||
* If you want to use more shapes, you'll have to put them into a set.
|
||||
*
|
||||
*/
|
||||
Raphael.el.tooltip = (tp) {
|
||||
@tp = tp
|
||||
@tp.o = {x: 0, y: 0}
|
||||
@tp.hide()
|
||||
@hover(
|
||||
(event){
|
||||
@mousemove((event){
|
||||
@tp.translate(event.clientX -
|
||||
@tp.o.x,event.clientY - @tp.o.y)
|
||||
@tp.o = {x: event.clientX, y: event.clientY}
|
||||
})
|
||||
@tp.show().toFront()
|
||||
},
|
||||
(event){
|
||||
@tp.hide()
|
||||
@unmousemove()
|
||||
})
|
||||
return this
|
||||
}
|
||||
|
||||
/* For IE */
|
||||
if (!Array.prototype.forEach)
|
||||
{
|
||||
Array.prototype.forEach = (fun /*, thisp*/)
|
||||
{
|
||||
var len = @length
|
||||
if (typeof fun != "")
|
||||
throw new TypeError()
|
||||
|
||||
var thisp = arguments[1]
|
||||
for (var i = 0; i < len; i++)
|
||||
{
|
||||
if (i in this)
|
||||
fun.call(thisp, this[i], i, this)
|
||||
}
|
||||
}
|
||||
}
|
|
@ -0,0 +1,527 @@
|
|||
/*
|
||||
* Dracula Graph Layout and Drawing Framework 0.0.3alpha
|
||||
* (c) 2010 Philipp Strathausen <strathausen@gmail.com>, http://strathausen.eu
|
||||
* Contributions by Jake Stothard <stothardj@gmail.com>.
|
||||
*
|
||||
* based on the Graph JavaScript framework, version 0.0.1
|
||||
* (c) 2006 Aslak Hellesoy <aslak.hellesoy@gmail.com>
|
||||
* (c) 2006 Dave Hoover <dave.hoover@gmail.com>
|
||||
*
|
||||
* Ported from Graph::Layouter::Spring in
|
||||
* http://search.cpan.org/~pasky/Graph-Layderer-0.02/
|
||||
* The algorithm is based on a spring-style layouter of a Java-based social
|
||||
* network tracker PieSpy written by Paul Mutton <paul@jibble.org>.
|
||||
*
|
||||
* This code is freely distributable under the MIT license. Commercial use is
|
||||
* hereby granted without any cost or restriction.
|
||||
*
|
||||
* Links:
|
||||
*
|
||||
* Graph Dracula JavaScript Framework:
|
||||
* http://graphdracula.net
|
||||
*
|
||||
/*--------------------------------------------------------------------------*/
|
||||
|
||||
/*
|
||||
* Edge Factory
|
||||
*/
|
||||
var AbstractEdge = function() {
|
||||
}
|
||||
AbstractEdge.prototype = {
|
||||
hide: function() {
|
||||
this.connection.fg.hide();
|
||||
this.connection.bg && this.bg.connection.hide();
|
||||
}
|
||||
};
|
||||
var EdgeFactory = function() {
|
||||
this.template = new AbstractEdge();
|
||||
this.template.style = new Object();
|
||||
this.template.style.directed = false;
|
||||
this.template.weight = 1;
|
||||
};
|
||||
EdgeFactory.prototype = {
|
||||
build: function(source, target) {
|
||||
var e = jQuery.extend(true, {}, this.template);
|
||||
e.source = source;
|
||||
e.target = target;
|
||||
return e;
|
||||
}
|
||||
};
|
||||
|
||||
/*
|
||||
* Graph
|
||||
*/
|
||||
var Graph = function() {
|
||||
this.nodes = {};
|
||||
this.edges = [];
|
||||
this.snapshots = []; // previous graph states TODO to be implemented
|
||||
this.edgeFactory = new EdgeFactory();
|
||||
};
|
||||
Graph.prototype = {
|
||||
/*
|
||||
* add a node
|
||||
* @id the node's ID (string or number)
|
||||
* @content (optional, dictionary) can contain any information that is
|
||||
* being interpreted by the layout algorithm or the graph
|
||||
* representation
|
||||
*/
|
||||
addNode: function(id, content) {
|
||||
/* testing if node is already existing in the graph */
|
||||
if(this.nodes[id] == undefined) {
|
||||
this.nodes[id] = new Graph.Node(id, content);
|
||||
}
|
||||
return this.nodes[id];
|
||||
},
|
||||
|
||||
addEdge: function(source, target, style) {
|
||||
var s = this.addNode(source);
|
||||
var t = this.addNode(target);
|
||||
var edge = this.edgeFactory.build(s, t);
|
||||
jQuery.extend(edge.style,style);
|
||||
s.edges.push(edge);
|
||||
this.edges.push(edge);
|
||||
// NOTE: Even directed edges are added to both nodes.
|
||||
t.edges.push(edge);
|
||||
},
|
||||
|
||||
/* TODO to be implemented
|
||||
* Preserve a copy of the graph state (nodes, positions, ...)
|
||||
* @comment a comment describing the state
|
||||
*/
|
||||
snapShot: function(comment) {
|
||||
/* FIXME
|
||||
var graph = new Graph();
|
||||
graph.nodes = jQuery.extend(true, {}, this.nodes);
|
||||
graph.edges = jQuery.extend(true, {}, this.edges);
|
||||
this.snapshots.push({comment: comment, graph: graph});
|
||||
*/
|
||||
},
|
||||
removeNode: function(id) {
|
||||
delete this.nodes[id];
|
||||
for(var i = 0; i < this.edges.length; i++) {
|
||||
if (this.edges[i].source.id == id || this.edges[i].target.id == id) {
|
||||
this.edges.splice(i, 1);
|
||||
i--;
|
||||
}
|
||||
}
|
||||
}
|
||||
};
|
||||
|
||||
/*
|
||||
* Node
|
||||
*/
|
||||
Graph.Node = function(id, node){
|
||||
node = node || {};
|
||||
node.id = id;
|
||||
node.edges = [];
|
||||
node.hide = function() {
|
||||
this.hidden = true;
|
||||
this.shape && this.shape.hide(); /* FIXME this is representation specific code and should be elsewhere */
|
||||
for(i in this.edges)
|
||||
(this.edges[i].source.id == id || this.edges[i].target == id) && this.edges[i].hide && this.edges[i].hide();
|
||||
};
|
||||
node.show = function() {
|
||||
this.hidden = false;
|
||||
this.shape && this.shape.show();
|
||||
for(i in this.edges)
|
||||
(this.edges[i].source.id == id || this.edges[i].target == id) && this.edges[i].show && this.edges[i].show();
|
||||
};
|
||||
return node;
|
||||
};
|
||||
Graph.Node.prototype = {
|
||||
};
|
||||
|
||||
/*
|
||||
* Renderer base class
|
||||
*/
|
||||
Graph.Renderer = {};
|
||||
|
||||
/*
|
||||
* Renderer implementation using RaphaelJS
|
||||
*/
|
||||
Graph.Renderer.Raphael = function(element, graph, width, height) {
|
||||
this.width = width || 800;
|
||||
this.height = height || 800;
|
||||
var selfRef = this;
|
||||
this.r = Raphael(element, this.width, this.height);
|
||||
this.radius = 40; /* max dimension of a node */
|
||||
this.graph = graph;
|
||||
this.mouse_in = false;
|
||||
|
||||
/* TODO default node rendering function */
|
||||
if(!this.graph.render) {
|
||||
this.graph.render = function() {
|
||||
return;
|
||||
}
|
||||
}
|
||||
|
||||
/*
|
||||
* Dragging
|
||||
*/
|
||||
this.isDrag = false;
|
||||
this.dragger = function (e) {
|
||||
this.dx = e.clientX;
|
||||
this.dy = e.clientY;
|
||||
selfRef.isDrag = this;
|
||||
this.set && this.set.animate({"fill-opacity": .1}, 200);
|
||||
e.preventDefault && e.preventDefault();
|
||||
};
|
||||
|
||||
var d = document.getElementById(element);
|
||||
d.onmousemove = function (e) {
|
||||
e = e || window.event;
|
||||
if (selfRef.isDrag) {
|
||||
var bBox = selfRef.isDrag.set.getBBox();
|
||||
// TODO round the coordinates here (eg. for proper image representation)
|
||||
var newX = e.clientX - selfRef.isDrag.dx + (bBox.x + bBox.width / 2);
|
||||
var newY = e.clientY - selfRef.isDrag.dy + (bBox.y + bBox.height / 2);
|
||||
/* prevent shapes from being dragged out of the canvas */
|
||||
var clientX = e.clientX - (newX < 20 ? newX - 20 : newX > selfRef.width - 20 ? newX - selfRef.width + 20 : 0);
|
||||
var clientY = e.clientY - (newY < 20 ? newY - 20 : newY > selfRef.height - 20 ? newY - selfRef.height + 20 : 0);
|
||||
selfRef.isDrag.set.translate(clientX - Math.round(selfRef.isDrag.dx), clientY - Math.round(selfRef.isDrag.dy));
|
||||
// console.log(clientX - Math.round(selfRef.isDrag.dx), clientY - Math.round(selfRef.isDrag.dy));
|
||||
for (var i in selfRef.graph.edges) {
|
||||
selfRef.graph.edges[i].connection && selfRef.graph.edges[i].connection.draw();
|
||||
}
|
||||
//selfRef.r.safari();
|
||||
selfRef.isDrag.dx = clientX;
|
||||
selfRef.isDrag.dy = clientY;
|
||||
}
|
||||
};
|
||||
d.onmouseup = function () {
|
||||
selfRef.isDrag && selfRef.isDrag.set.animate({"fill-opacity": .6}, 500);
|
||||
selfRef.isDrag = false;
|
||||
};
|
||||
this.draw();
|
||||
};
|
||||
Graph.Renderer.Raphael.prototype = {
|
||||
translate: function(point) {
|
||||
return [
|
||||
(point[0] - this.graph.layoutMinX) * this.factorX + this.radius,
|
||||
(point[1] - this.graph.layoutMinY) * this.factorY + this.radius
|
||||
];
|
||||
},
|
||||
|
||||
rotate: function(point, length, angle) {
|
||||
var dx = length * Math.cos(angle);
|
||||
var dy = length * Math.sin(angle);
|
||||
return [point[0]+dx, point[1]+dy];
|
||||
},
|
||||
|
||||
draw: function() {
|
||||
this.factorX = (this.width - 2 * this.radius) / (this.graph.layoutMaxX - this.graph.layoutMinX);
|
||||
this.factorY = (this.height - 2 * this.radius) / (this.graph.layoutMaxY - this.graph.layoutMinY);
|
||||
for (i in this.graph.nodes) {
|
||||
this.drawNode(this.graph.nodes[i]);
|
||||
}
|
||||
for (var i = 0; i < this.graph.edges.length; i++) {
|
||||
this.drawEdge(this.graph.edges[i]);
|
||||
}
|
||||
},
|
||||
|
||||
drawNode: function(node) {
|
||||
var point = this.translate([node.layoutPosX, node.layoutPosY]);
|
||||
node.point = point;
|
||||
|
||||
/* if node has already been drawn, move the nodes */
|
||||
if(node.shape) {
|
||||
var oBBox = node.shape.getBBox();
|
||||
var opoint = { x: oBBox.x + oBBox.width / 2, y: oBBox.y + oBBox.height / 2};
|
||||
node.shape.translate(Math.round(point[0] - opoint.x), Math.round(point[1] - opoint.y));
|
||||
this.r.safari();
|
||||
return node;
|
||||
}/* else, draw new nodes */
|
||||
|
||||
var shape;
|
||||
|
||||
/* if a node renderer function is provided by the user, then use it
|
||||
or the default render function instead */
|
||||
if(!node.render) {
|
||||
node.render = function(r, node) {
|
||||
/* the default node drawing */
|
||||
var color = Raphael.getColor();
|
||||
var ellipse = r.ellipse(0, 0, 30, 20).attr({fill: color, stroke: color, "stroke-width": 2});
|
||||
/* set DOM node ID */
|
||||
ellipse.node.id = node.label || node.id;
|
||||
shape = r.set().
|
||||
push(ellipse).
|
||||
push(r.text(0, 30, node.label || node.id));
|
||||
return shape;
|
||||
}
|
||||
}
|
||||
/* or check for an ajax representation of the nodes */
|
||||
if(node.shapes) {
|
||||
// TODO ajax representation evaluation
|
||||
}
|
||||
|
||||
shape = node.render(this.r, node).hide();
|
||||
|
||||
shape.attr({"fill-opacity": .6});
|
||||
/* re-reference to the node an element belongs to, needed for dragging all elements of a node */
|
||||
shape.items.forEach(function(item){ item.set = shape; item.node.style.cursor = "move"; });
|
||||
shape.mousedown(this.dragger);
|
||||
|
||||
var box = shape.getBBox();
|
||||
shape.translate(Math.round(point[0]-(box.x+box.width/2)),Math.round(point[1]-(box.y+box.height/2)))
|
||||
//console.log(box,point);
|
||||
node.hidden || shape.show();
|
||||
node.shape = shape;
|
||||
},
|
||||
drawEdge: function(edge) {
|
||||
/* if this edge already exists the other way around and is undirected */
|
||||
if(edge.backedge)
|
||||
return;
|
||||
if(edge.source.hidden || edge.target.hidden) {
|
||||
edge.connection && edge.connection.fg.hide() | edge.connection.bg && edge.connection.bg.hide();
|
||||
return;
|
||||
}
|
||||
/* if edge already has been drawn, only refresh the edge */
|
||||
if(!edge.connection) {
|
||||
edge.style && edge.style.callback && edge.style.callback(edge); // TODO move this somewhere else
|
||||
edge.connection = this.r.connection(edge.source.shape, edge.target.shape, edge.style);
|
||||
return;
|
||||
}
|
||||
//FIXME showing doesn't work well
|
||||
edge.connection.fg.show();
|
||||
edge.connection.bg && edge.connection.bg.show();
|
||||
edge.connection.draw();
|
||||
}
|
||||
};
|
||||
Graph.Layout = {};
|
||||
Graph.Layout.Spring = function(graph) {
|
||||
this.graph = graph;
|
||||
this.iterations = 500;
|
||||
this.maxRepulsiveForceDistance = 6;
|
||||
this.k = 2;
|
||||
this.c = 0.01;
|
||||
this.maxVertexMovement = 0.5;
|
||||
this.layout();
|
||||
};
|
||||
Graph.Layout.Spring.prototype = {
|
||||
layout: function() {
|
||||
this.layoutPrepare();
|
||||
for (var i = 0; i < this.iterations; i++) {
|
||||
this.layoutIteration();
|
||||
}
|
||||
this.layoutCalcBounds();
|
||||
},
|
||||
|
||||
layoutPrepare: function() {
|
||||
for (i in this.graph.nodes) {
|
||||
var node = this.graph.nodes[i];
|
||||
node.layoutPosX = 0;
|
||||
node.layoutPosY = 0;
|
||||
node.layoutForceX = 0;
|
||||
node.layoutForceY = 0;
|
||||
}
|
||||
|
||||
},
|
||||
|
||||
layoutCalcBounds: function() {
|
||||
var minx = Infinity, maxx = -Infinity, miny = Infinity, maxy = -Infinity;
|
||||
|
||||
for (i in this.graph.nodes) {
|
||||
var x = this.graph.nodes[i].layoutPosX;
|
||||
var y = this.graph.nodes[i].layoutPosY;
|
||||
|
||||
if(x > maxx) maxx = x;
|
||||
if(x < minx) minx = x;
|
||||
if(y > maxy) maxy = y;
|
||||
if(y < miny) miny = y;
|
||||
}
|
||||
|
||||
this.graph.layoutMinX = minx;
|
||||
this.graph.layoutMaxX = maxx;
|
||||
this.graph.layoutMinY = miny;
|
||||
this.graph.layoutMaxY = maxy;
|
||||
},
|
||||
|
||||
layoutIteration: function() {
|
||||
// Forces on nodes due to node-node repulsions
|
||||
|
||||
var prev = new Array();
|
||||
for(var c in this.graph.nodes) {
|
||||
var node1 = this.graph.nodes[c];
|
||||
for (var d in prev) {
|
||||
var node2 = this.graph.nodes[prev[d]];
|
||||
this.layoutRepulsive(node1, node2);
|
||||
|
||||
}
|
||||
prev.push(c);
|
||||
}
|
||||
|
||||
// Forces on nodes due to edge attractions
|
||||
for (var i = 0; i < this.graph.edges.length; i++) {
|
||||
var edge = this.graph.edges[i];
|
||||
this.layoutAttractive(edge);
|
||||
}
|
||||
|
||||
// Move by the given force
|
||||
for (i in this.graph.nodes) {
|
||||
var node = this.graph.nodes[i];
|
||||
var xmove = this.c * node.layoutForceX;
|
||||
var ymove = this.c * node.layoutForceY;
|
||||
|
||||
var max = this.maxVertexMovement;
|
||||
if(xmove > max) xmove = max;
|
||||
if(xmove < -max) xmove = -max;
|
||||
if(ymove > max) ymove = max;
|
||||
if(ymove < -max) ymove = -max;
|
||||
|
||||
node.layoutPosX += xmove;
|
||||
node.layoutPosY += ymove;
|
||||
node.layoutForceX = 0;
|
||||
node.layoutForceY = 0;
|
||||
}
|
||||
},
|
||||
|
||||
layoutRepulsive: function(node1, node2) {
|
||||
if (typeof node1 == 'undefined' || typeof node2 == 'undefined')
|
||||
return;
|
||||
var dx = node2.layoutPosX - node1.layoutPosX;
|
||||
var dy = node2.layoutPosY - node1.layoutPosY;
|
||||
var d2 = dx * dx + dy * dy;
|
||||
if(d2 < 0.01) {
|
||||
dx = 0.1 * Math.random() + 0.1;
|
||||
dy = 0.1 * Math.random() + 0.1;
|
||||
var d2 = dx * dx + dy * dy;
|
||||
}
|
||||
var d = Math.sqrt(d2);
|
||||
if(d < this.maxRepulsiveForceDistance) {
|
||||
var repulsiveForce = this.k * this.k / d;
|
||||
node2.layoutForceX += repulsiveForce * dx / d;
|
||||
node2.layoutForceY += repulsiveForce * dy / d;
|
||||
node1.layoutForceX -= repulsiveForce * dx / d;
|
||||
node1.layoutForceY -= repulsiveForce * dy / d;
|
||||
}
|
||||
},
|
||||
|
||||
layoutAttractive: function(edge) {
|
||||
var node1 = edge.source;
|
||||
var node2 = edge.target;
|
||||
|
||||
var dx = node2.layoutPosX - node1.layoutPosX;
|
||||
var dy = node2.layoutPosY - node1.layoutPosY;
|
||||
var d2 = dx * dx + dy * dy;
|
||||
if(d2 < 0.01) {
|
||||
dx = 0.1 * Math.random() + 0.1;
|
||||
dy = 0.1 * Math.random() + 0.1;
|
||||
var d2 = dx * dx + dy * dy;
|
||||
}
|
||||
var d = Math.sqrt(d2);
|
||||
if(d > this.maxRepulsiveForceDistance) {
|
||||
d = this.maxRepulsiveForceDistance;
|
||||
d2 = d * d;
|
||||
}
|
||||
var attractiveForce = (d2 - this.k * this.k) / this.k;
|
||||
if(edge.attraction == undefined) edge.attraction = 1;
|
||||
attractiveForce *= Math.log(edge.attraction) * 0.5 + 1;
|
||||
|
||||
node2.layoutForceX -= attractiveForce * dx / d;
|
||||
node2.layoutForceY -= attractiveForce * dy / d;
|
||||
node1.layoutForceX += attractiveForce * dx / d;
|
||||
node1.layoutForceY += attractiveForce * dy / d;
|
||||
}
|
||||
};
|
||||
|
||||
Graph.Layout.Ordered = function(graph, order) {
|
||||
this.graph = graph;
|
||||
this.order = order;
|
||||
this.layout();
|
||||
};
|
||||
Graph.Layout.Ordered.prototype = {
|
||||
layout: function() {
|
||||
this.layoutPrepare();
|
||||
this.layoutCalcBounds();
|
||||
},
|
||||
|
||||
layoutPrepare: function(order) {
|
||||
for (i in this.graph.nodes) {
|
||||
var node = this.graph.nodes[i];
|
||||
node.layoutPosX = 0;
|
||||
node.layoutPosY = 0;
|
||||
}
|
||||
var counter = 0;
|
||||
for (i in this.order) {
|
||||
var node = this.order[i];
|
||||
node.layoutPosX = counter;
|
||||
node.layoutPosY = Math.random();
|
||||
counter++;
|
||||
}
|
||||
},
|
||||
|
||||
layoutCalcBounds: function() {
|
||||
var minx = Infinity, maxx = -Infinity, miny = Infinity, maxy = -Infinity;
|
||||
|
||||
for (i in this.graph.nodes) {
|
||||
var x = this.graph.nodes[i].layoutPosX;
|
||||
var y = this.graph.nodes[i].layoutPosY;
|
||||
|
||||
if(x > maxx) maxx = x;
|
||||
if(x < minx) minx = x;
|
||||
if(y > maxy) maxy = y;
|
||||
if(y < miny) miny = y;
|
||||
}
|
||||
|
||||
this.graph.layoutMinX = minx;
|
||||
this.graph.layoutMaxX = maxx;
|
||||
|
||||
this.graph.layoutMinY = miny;
|
||||
this.graph.layoutMaxY = maxy;
|
||||
}
|
||||
};
|
||||
|
||||
/*
|
||||
* usefull JavaScript extensions,
|
||||
*/
|
||||
|
||||
function log(a) {console.log&&console.log(a);}
|
||||
|
||||
/*
|
||||
* Raphael Tooltip Plugin
|
||||
* - attaches an element as a tooltip to another element
|
||||
*
|
||||
* Usage example, adding a rectangle as a tooltip to a circle:
|
||||
*
|
||||
* paper.circle(100,100,10).tooltip(paper.rect(0,0,20,30));
|
||||
*
|
||||
* If you want to use more shapes, you'll have to put them into a set.
|
||||
*
|
||||
*/
|
||||
Raphael.el.tooltip = function (tp) {
|
||||
this.tp = tp;
|
||||
this.tp.o = {x: 0, y: 0};
|
||||
this.tp.hide();
|
||||
this.hover(
|
||||
function(event){
|
||||
this.mousemove(function(event){
|
||||
this.tp.translate(event.clientX -
|
||||
this.tp.o.x,event.clientY - this.tp.o.y);
|
||||
this.tp.o = {x: event.clientX, y: event.clientY};
|
||||
});
|
||||
this.tp.show().toFront();
|
||||
},
|
||||
function(event){
|
||||
this.tp.hide();
|
||||
this.unmousemove();
|
||||
});
|
||||
return this;
|
||||
};
|
||||
|
||||
/* For IE */
|
||||
if (!Array.prototype.forEach)
|
||||
{
|
||||
Array.prototype.forEach = function(fun /*, thisp*/)
|
||||
{
|
||||
var len = this.length;
|
||||
if (typeof fun != "function")
|
||||
throw new TypeError();
|
||||
|
||||
var thisp = arguments[1];
|
||||
for (var i = 0; i < len; i++)
|
||||
{
|
||||
if (i in this)
|
||||
fun.call(thisp, this[i], i, this);
|
||||
}
|
||||
};
|
||||
}
|
Loading…
Reference in New Issue