(function(f){if(typeof exports==="object"&&typeof module!=="undefined"){module.exports=f()}else if(typeof define==="function"&&define.amd){define([],f)}else{var g;if(typeof window!=="undefined"){g=window}else if(typeof global!=="undefined"){g=global}else if(typeof self!=="undefined"){g=self}else{g=this}g.graphlib = f()}})(function(){var define,module,exports;return (function(){function r(e,n,t){function o(i,f){if(!n[i]){if(!e[i]){var c="function"==typeof require&&require;if(!f&&c)return c(i,!0);if(u)return u(i,!0);var a=new Error("Cannot find module '"+i+"'");throw a.code="MODULE_NOT_FOUND",a}var p=n[i]={exports:{}};e[i][0].call(p.exports,function(r){var n=e[i][1][r];return o(n||r)},p,p.exports,r,e,n,t)}return n[i].exports}for(var u="function"==typeof require&&require,i=0;i<t.length;i++)o(t[i]);return o}return r})()({1:[function(require,module,exports){
/**
* Copyright (c) 2014, Chris Pettitt
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. Neither the name of the copyright holder nor the names of its contributors
* may be used to endorse or promote products derived from this software without
* specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
* SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
* CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
* OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
var lib = require("./lib");
module.exports = {
Graph: lib.Graph,
json: require("./lib/json"),
alg: require("./lib/alg"),
version: lib.version
};
},{"./lib":17,"./lib/alg":8,"./lib/json":18}],2:[function(require,module,exports){
var _ = require("../lodash");
module.exports = components;
function components(g) {
var visited = {};
var cmpts = [];
var cmpt;
function dfs(v) {
if (_.has(visited, v)) return;
visited[v] = true;
cmpt.push(v);
_.each(g.successors(v), dfs);
_.each(g.predecessors(v), dfs);
}
_.each(g.nodes(), function(v) {
cmpt = [];
dfs(v);
if (cmpt.length) {
cmpts.push(cmpt);
}
});
return cmpts;
}
},{"../lodash":19}],3:[function(require,module,exports){
var _ = require("../lodash");
module.exports = dfs;
/*
* A helper that preforms a pre- or post-order traversal on the input graph
* and returns the nodes in the order they were visited. If the graph is
* undirected then this algorithm will navigate using neighbors. If the graph
* is directed then this algorithm will navigate using successors.
*
* Order must be one of "pre" or "post".
*/
function dfs(g, vs, order) {
if (!_.isArray(vs)) {
vs = [vs];
}
var navigation = (g.isDirected() ? g.successors : g.neighbors).bind(g);
var acc = [];
var visited = {};
_.each(vs, function(v) {
if (!g.hasNode(v)) {
throw new Error("Graph does not have node: " + v);
}
doDfs(g, v, order === "post", visited, navigation, acc);
});
return acc;
}
function doDfs(g, v, postorder, visited, navigation, acc) {
if (!_.has(visited, v)) {
visited[v] = true;
if (!postorder) { acc.push(v); }
_.each(navigation(v), function(w) {
doDfs(g, w, postorder, visited, navigation, acc);
});
if (postorder) { acc.push(v); }
}
}
},{"../lodash":19}],4:[function(require,module,exports){
var dijkstra = require("./dijkstra");
var _ = require("../lodash");
module.exports = dijkstraAll;
function dijkstraAll(g, weightFunc, edgeFunc) {
return _.transform(g.nodes(), function(acc, v) {
acc[v] = dijkstra(g, v, weightFunc, edgeFunc);
}, {});
}
},{"../lodash":19,"./dijkstra":5}],5:[function(require,module,exports){
var _ = require("../lodash");
var PriorityQueue = require("../data/priority-queue");
module.exports = dijkstra;
var DEFAULT_WEIGHT_FUNC = _.constant(1);
function dijkstra(g, source, weightFn, edgeFn) {
return runDijkstra(g, String(source),
weightFn || DEFAULT_WEIGHT_FUNC,
edgeFn || function(v) { return g.outEdges(v); });
}
function runDijkstra(g, source, weightFn, edgeFn) {
var results = {};
var pq = new PriorityQueue();
var v, vEntry;
var updateNeighbors = function(edge) {
var w = edge.v !== v ? edge.v : edge.w;
var wEntry = results[w];
var weight = weightFn(edge);
var distance = vEntry.distance + weight;
if (weight < 0) {
throw new Error("dijkstra does not allow negative edge weights. " +
"Bad edge: " + edge + " Weight: " + weight);
}
if (distance < wEntry.distance) {
wEntry.distance = distance;
wEntry.predecessor = v;
pq.decrease(w, distance);
}
};
g.nodes().forEach(function(v) {
var distance = v === source ? 0 : Number.POSITIVE_INFINITY;
results[v] = { distance: distance };
pq.add(v, distance);
});
while (pq.size() > 0) {
v = pq.removeMin();
vEntry = results[v];
if (vEntry.distance === Number.POSITIVE_INFINITY) {
break;
}
edgeFn(v).forEach(updateNeighbors);
}
return results;
}
},{"../data/priority-queue":15,"../lodash":19}],6:[function(require,module,exports){
var _ = require("../lodash");
var tarjan = require("./tarjan");
module.exports = findCycles;
function findCycles(g) {
return _.filter(tarjan(g), function(cmpt) {
return cmpt.length > 1 || (cmpt.length === 1 && g.hasEdge(cmpt[0], cmpt[0]));
});
}
},{"../lodash":19,"./tarjan":13}],7:[function(require,module,exports){
var _ = require("../lodash");
module.exports = floydWarshall;
var DEFAULT_WEIGHT_FUNC = _.constant(1);
function floydWarshall(g, weightFn, edgeFn) {
return runFloydWarshall(g,
weightFn || DEFAULT_WEIGHT_FUNC,
edgeFn || function(v) { return g.outEdges(v); });
}
function runFloydWarshall(g, weightFn, edgeFn) {
var results = {};
var nodes = g.nodes();
nodes.forEach(function(v) {
results[v] = {};
results[v][v] = { distance: 0 };
nodes.forEach(function(w) {
if (v !== w) {
results[v][w] = { distance: Number.POSITIVE_INFINITY };
}
});
edgeFn(v).forEach(function(edge) {
var w = edge.v === v ? edge.w : edge.v;
var d = weightFn(edge);
results[v][w] = { distance: d, predecessor: v };
});
});
nodes.forEach(function(k) {
var rowK = results[k];
nodes.forEach(function(i) {
var rowI = results[i];
nodes.forEach(function(j) {
var ik = rowI[k];
var kj = rowK[j];
var ij = rowI[j];
var altDistance = ik.distance + kj.distance;
if (altDistance < ij.distance) {
ij.distance = altDistance;
ij.predecessor = kj.predecessor;
}
});
});
});
return results;
}
},{"../lodash":19}],8:[function(require,module,exports){
module.exports = {
components: require("./components"),
dijkstra: require("./dijkstra"),
dijkstraAll: require("./dijkstra-all"),
findCycles: require("./find-cycles"),
floydWarshall: require("./floyd-warshall"),
isAcyclic: require("./is-acyclic"),
postorder: require("./postorder"),
preorder: require("./preorder"),
prim: require("./prim"),
tarjan: require("./tarjan"),
topsort: require("./topsort")
};
},{"./components":2,"./dijkstra":5,"./dijkstra-all":4,"./find-cycles":6,"./floyd-warshall":7,"./is-acyclic":9,"./postorder":10,"./preorder":11,"./prim":12,"./tarjan":13,"./topsort":14}],9:[function(require,module,exports){
var topsort = require("./topsort");
module.exports = isAcyclic;
function isAcyclic(g) {
try {
topsort(g);
} catch (e) {
if (e instanceof topsort.CycleException) {
return false;
}
throw e;
}
return true;
}
},{"./topsort":14}],10:[function(require,module,exports){
var dfs = require("./dfs");
module.exports = postorder;
function postorder(g, vs) {
return dfs(g, vs, "post");
}
},{"./dfs":3}],11:[function(require,module,exports){
var dfs = require("./dfs");
module.exports = preorder;
function preorder(g, vs) {
return dfs(g, vs, "pre");
}
},{"./dfs":3}],12:[function(require,module,exports){
var _ = require("../lodash");
var Graph = require("../graph");
var PriorityQueue = require("../data/priority-queue");
module.exports = prim;
function prim(g, weightFunc) {
var result = new Graph();
var parents = {};
var pq = new PriorityQueue();
var v;
function updateNeighbors(edge) {
var w = edge.v === v ? edge.w : edge.v;
var pri = pq.priority(w);
if (pri !== undefined) {
var edgeWeight = weightFunc(edge);
if (edgeWeight < pri) {
parents[w] = v;
pq.decrease(w, edgeWeight);
}
}
}
if (g.nodeCount() === 0) {
return result;
}
_.each(g.nodes(), function(v) {
pq.add(v, Number.POSITIVE_INFINITY);
result.setNode(v);
});
// Start from an arbitrary node
pq.decrease(g.nodes()[0], 0);
var init = false;
while (pq.size() > 0) {
v = pq.removeMin();
if (_.has(parents, v)) {
result.setEdge(v, parents[v]);
} else if (init) {
throw new Error("Input graph is not connected: " + g);
} else {
init = true;
}
g.nodeEdges(v).forEach(updateNeighbors);
}
return result;
}
},{"../data/priority-queue":15,"../graph":16,"../lodash":19}],13:[function(require,module,exports){
var _ = require("../lodash");
module.exports = tarjan;
function tarjan(g) {
var index = 0;
var stack = [];
var visited = {}; // node id -> { onStack, lowlink, index }
var results = [];
function dfs(v) {
var entry = visited[v] = {
onStack: true,
lowlink: index,
index: index++
};
stack.push(v);
g.successors(v).forEach(function(w) {
if (!_.has(visited, w)) {
dfs(w);
entry.lowlink = Math.min(entry.lowlink, visited[w].lowlink);
} else if (visited[w].onStack) {
entry.lowlink = Math.min(entry.lowlink, visited[w].index);
}
});
if (entry.lowlink === entry.index) {
var cmpt = [];
var w;
do {
w = stack.pop();
visited[w].onStack = false;
cmpt.push(w);
} while (v !== w);
results.push(cmpt);
}
}
g.nodes().forEach(function(v) {
if (!_.has(visited, v)) {
dfs(v);
}
});
return results;
}
},{"../lodash":19}],14:[function(require,module,exports){
var _ = require("../lodash");
module.exports = topsort;
topsort.CycleException = CycleException;
function topsort(g) {
var visited = {};
var stack = {};
var results = [];
function visit(node) {
if (_.has(stack, node)) {
throw new CycleException();
}
if (!_.has(visited, node)) {
stack[node] = true;
visited[node] = true;
_.each(g.predecessors(node), visit);
delete stack[node];
results.push(node);
}
}
_.each(g.sinks(), visit);
if (_.size(visited) !== g.nodeCount()) {
throw new CycleException();
}
return results;
}
function CycleException() {}
CycleException.prototype = new Error(); // must be an instance of Error to pass testing
},{"../lodash":19}],15:[function(require,module,exports){
var _ = require("../lodash");
module.exports = PriorityQueue;
/**
* A min-priority queue data structure. This algorithm is derived from Cormen,
* et al., "Introduction to Algorithms". The basic idea of a min-priority
* queue is that you can efficiently (in O(1) time) get the smallest key in
* the queue. Adding and removing elements takes O(log n) time. A key can
* have its priority decreased in O(log n) time.
*/
function PriorityQueue() {
this._arr = [];
this._keyIndices = {};
}
/**
* Returns the number of elements in the queue. Takes `O(1)` time.
*/
PriorityQueue.prototype.size = function() {
return this._arr.length;
};
/**
* Returns the keys that are in the queue. Takes `O(n)` time.
*/
PriorityQueue.prototype.keys = function() {
return this._arr.map(function(x) { return x.key; });
};
/**
* Returns `true` if **key** is in the queue and `false` if not.
*/
PriorityQueue.prototype.has = function(key) {
return _.has(this._keyIndices, key);
};
/**
* Returns the priority for **key**. If **key** is not present in the queue
* then this function returns `undefined`. Takes `O(1)` time.
*
* @param {Object} key
*/
PriorityQueue.prototype.priority = function(key) {
var index = this._keyIndices[key];
if (index !== undefined) {
return this._arr[index].priority;
}
};
/**
* Returns the key for the minimum element in this queue. If the queue is
* empty this function throws an Error. Takes `O(1)` time.
*/
PriorityQueue.prototype.min = function() {
if (this.size() === 0) {
throw new Error("Queue underflow");
}
return this._arr[0].key;
};
/**
* Inserts a new key into the priority queue. If the key already exists in
* the queue this function returns `false`; otherwise it will return `true`.
* Takes `O(n)` time.
*
* @param {Object} key the key to add
* @param {Number} priority the initial priority for the key
*/
PriorityQueue.prototype.add = function(key, priority) {
var keyIndices = this._keyIndices;
key = String(key);
if (!_.has(keyIndices, key)) {
var arr = this._arr;
var index = arr.length;
keyIndices[key] = index;
arr.push({key: key, priority: priority});
this._decrease(index);
return true;
}
return false;
};
/**
* Removes and returns the smallest key in the queue. Takes `O(log n)` time.
*/
PriorityQueue.prototype.removeMin = function() {
this._swap(0, this._arr.length - 1);
var min = this._arr.pop();
delete this._keyIndices[min.key];
this._heapify(0);
return min.key;
};
/**
* Decreases the priority for **key** to **priority**. If the new priority is
* greater than the previous priority, this function will throw an Error.
*
* @param {Object} key the key for which to raise priority
* @param {Number} priority the new priority for the key
*/
PriorityQueue.prototype.decrease = function(key, priority) {
var index = this._keyIndices[key];
if (priority > this._arr[index].priority) {
throw new Error("New priority is greater than current priority. " +
"Key: " + key + " Old: " + this._arr[index].priority + " New: " + priority);
}
this._arr[index].priority = priority;
this._decrease(index);
};
PriorityQueue.prototype._heapify = function(i) {
var arr = this._arr;
var l = 2 * i;
var r = l + 1;
var largest = i;
if (l < arr.length) {
largest = arr[l].priority < arr[largest].priority ? l : largest;
if (r < arr.length) {
largest = arr[r].priority < arr[largest].priority ? r : largest;
}
if (largest !== i) {
this._swap(i, largest);
this._heapify(largest);
}
}
};
PriorityQueue.prototype._decrease = function(index) {
var arr = this._arr;
var priority = arr[index].priority;
var parent;
while (index !== 0) {
parent = index >> 1;
if (arr[parent].priority < priority) {
break;
}
this._swap(index, parent);
index = parent;
}
};
PriorityQueue.prototype._swap = function(i, j) {
var arr = this._arr;
var keyIndices = this._keyIndices;
var origArrI = arr[i];
var origArrJ = arr[j];
arr[i] = origArrJ;
arr[j] = origArrI;
keyIndices[origArrJ.key] = i;
keyIndices[origArrI.key] = j;
};
},{"../lodash":19}],16:[function(require,module,exports){
"use strict";
var _ = require("./lodash");
module.exports = Graph;
var DEFAULT_EDGE_NAME = "\x00";
var GRAPH_NODE = "\x00";
var EDGE_KEY_DELIM = "\x01";
// Implementation notes:
//
// * Node id query functions should return string ids for the nodes
// * Edge id query functions should return an "edgeObj", edge object, that is
// composed of enough information to uniquely identify an edge: {v, w, name}.
// * Internally we use an "edgeId", a stringified form of the edgeObj, to
// reference edges. This is because we need a performant way to look these
// edges up and, object properties, which have string keys, are the closest
// we're going to get to a performant hashtable in JavaScript.
function Graph(opts) {
this._isDirected = _.has(opts, "directed") ? opts.directed : true;
this._isMultigraph = _.has(opts, "multigraph") ? opts.multigraph : false;
this._isCompound = _.has(opts, "compound") ? opts.compound : false;
// Label for the graph itself
this._label = undefined;
// Defaults to be set when creating a new node
this._defaultNodeLabelFn = _.constant(undefined);
// Defaults to be set when creating a new edge
this._defaultEdgeLabelFn = _.constant(undefined);
// v -> label
this._nodes = {};
if (this._isCompound) {
// v -> parent
this._parent = {};
// v -> children
this._children = {};
this._children[GRAPH_NODE] = {};
}
// v -> edgeObj
this._in = {};
// u -> v -> Number
this._preds = {};
// v -> edgeObj
this._out = {};
// v -> w -> Number
this._sucs = {};
// e -> edgeObj
this._edgeObjs = {};
// e -> label
this._edgeLabels = {};
}
/* Number of nodes in the graph. Should only be changed by the implementation. */
Graph.prototype._nodeCount = 0;
/* Number of edges in the graph. Should only be changed by the implementation. */
Graph.prototype._edgeCount = 0;
/* === Graph functions ========= */
Graph.prototype.isDirected = function() {
return this._isDirected;
};
Graph.prototype.isMultigraph = function() {
return this._isMultigraph;
};
Graph.prototype.isCompound = function() {
return this._isCompound;
};
Graph.prototype.setGraph = function(label) {
this._label = label;
return this;
};
Graph.prototype.graph = function() {
return this._label;
};
/* === Node functions ========== */
Graph.prototype.setDefaultNodeLabel = function(newDefault) {
if (!_.isFunction(newDefault)) {
newDefault = _.constant(newDefault);
}
this._defaultNodeLabelFn = newDefault;
return this;
};
Graph.prototype.nodeCount = function() {
return this._nodeCount;
};
Graph.prototype.nodes = function() {
return _.keys(this._nodes);
};
Graph.prototype.sources = function() {
var self = this;
return _.filter(this.nodes(), function(v) {
return _.isEmpty(self._in[v]);
});
};
Graph.prototype.sinks = function() {
var self = this;
return _.filter(this.nodes(), function(v) {
return _.isEmpty(self._out[v]);
});
};
Graph.prototype.setNodes = function(vs, value) {
var args = arguments;
var self = this;
_.each(vs, function(v) {
if (args.length > 1) {
self.setNode(v, value);
} else {
self.setNode(v);
}
});
return this;
};
Graph.prototype.setNode = function(v, value) {
if (_.has(this._nodes, v)) {
if (arguments.length > 1) {
this._nodes[v] = value;
}
return this;
}
this._nodes[v] = arguments.length > 1 ? value : this._defaultNodeLabelFn(v);
if (this._isCompound) {
this._parent[v] = GRAPH_NODE;
this._children[v] = {};
this._children[GRAPH_NODE][v] = true;
}
this._in[v] = {};
this._preds[v] = {};
this._out[v] = {};
this._sucs[v] = {};
++this._nodeCount;
return this;
};
Graph.prototype.node = function(v) {
return this._nodes[v];
};
Graph.prototype.hasNode = function(v) {
return _.has(this._nodes, v);
};
Graph.prototype.removeNode = function(v) {
var self = this;
if (_.has(this._nodes, v)) {
var removeEdge = function(e) { self.removeEdge(self._edgeObjs[e]); };
delete this._nodes[v];
if (this._isCompound) {
this._removeFromParentsChildList(v);
delete this._parent[v];
_.each(this.children(v), function(child) {
self.setParent(child);
});
delete this._children[v];
}
_.each(_.keys(this._in[v]), removeEdge);
delete this._in[v];
delete this._preds[v];
_.each(_.keys(this._out[v]), removeEdge);
delete this._out[v];
delete this._sucs[v];
--this._nodeCount;
}
return this;
};
Graph.prototype.setParent = function(v, parent) {
if (!this._isCompound) {
throw new Error("Cannot set parent in a non-compound graph");
}
if (_.isUndefined(parent)) {
parent = GRAPH_NODE;
} else {
// Coerce parent to string
parent += "";
for (var ancestor = parent;
!_.isUndefined(ancestor);
ancestor = this.parent(ancestor)) {
if (ancestor === v) {
throw new Error("Setting " + parent+ " as parent of " + v +
" would create a cycle");
}
}
this.setNode(parent);
}
this.setNode(v);
this._removeFromParentsChildList(v);
this._parent[v] = parent;
this._children[parent][v] = true;
return this;
};
Graph.prototype._removeFromParentsChildList = function(v) {
delete this._children[this._parent[v]][v];
};
Graph.prototype.parent = function(v) {
if (this._isCompound) {
var parent = this._parent[v];
if (parent !== GRAPH_NODE) {
return parent;
}
}
};
Graph.prototype.children = function(v) {
if (_.isUndefined(v)) {
v = GRAPH_NODE;
}
if (this._isCompound) {
var children = this._children[v];
if (children) {
return _.keys(children);
}
} else if (v === GRAPH_NODE) {
return this.nodes();
} else if (this.hasNode(v)) {
return [];
}
};
Graph.prototype.predecessors = function(v) {
var predsV = this._preds[v];
if (predsV) {
return _.keys(predsV);
}
};
Graph.prototype.successors = function(v) {
var sucsV = this._sucs[v];
if (sucsV) {
return _.keys(sucsV);
}
};
Graph.prototype.neighbors = function(v) {
var preds = this.predecessors(v);
if (preds) {
return _.union(preds, this.successors(v));
}
};
Graph.prototype.isLeaf = function (v) {
var neighbors;
if (this.isDirected()) {
neighbors = this.successors(v);
} else {
neighbors = this.neighbors(v);
}
return neighbors.length === 0;
};
Graph.prototype.filterNodes = function(filter) {
var copy = new this.constructor({
directed: this._isDirected,
multigraph: this._isMultigraph,
compound: this._isCompound
});
copy.setGraph(this.graph());
var self = this;
_.each(this._nodes, function(value, v) {
if (filter(v)) {
copy.setNode(v, value);
}
});
_.each(this._edgeObjs, function(e) {
if (copy.hasNode(e.v) && copy.hasNode(e.w)) {
copy.setEdge(e, self.edge(e));
}
});
var parents = {};
function findParent(v) {
var parent = self.parent(v);
if (parent === undefined || copy.hasNode(parent)) {
parents[v] = parent;
return parent;
} else if (parent in parents) {
return parents[parent];
} else {
return findParent(parent);
}
}
if (this._isCompound) {
_.each(copy.nodes(), function(v) {
copy.setParent(v, findParent(v));
});
}
return copy;
};
/* === Edge functions ========== */
Graph.prototype.setDefaultEdgeLabel = function(newDefault) {
if (!_.isFunction(newDefault)) {
newDefault = _.constant(newDefault);
}
this._defaultEdgeLabelFn = newDefault;
return this;
};
Graph.prototype.edgeCount = function() {
return this._edgeCount;
};
Graph.prototype.edges = function() {
return _.values(this._edgeObjs);
};
Graph.prototype.setPath = function(vs, value) {
var self = this;
var args = arguments;
_.reduce(vs, function(v, w) {
if (args.length > 1) {
self.setEdge(v, w, value);
} else {
self.setEdge(v, w);
}
return w;
});
return this;
};
/*
* setEdge(v, w, [value, [name]])
* setEdge({ v, w, [name] }, [value])
*/
Graph.prototype.setEdge = function() {
var v, w, name, value;
var valueSpecified = false;
var arg0 = arguments[0];
if (typeof arg0 === "object" && arg0 !== null && "v" in arg0) {
v = arg0.v;
w = arg0.w;
name = arg0.name;
if (arguments.length === 2) {
value = arguments[1];
valueSpecified = true;
}
} else {
v = arg0;
w = arguments[1];
name = arguments[3];
if (arguments.length > 2) {
value = arguments[2];
valueSpecified = true;
}
}
v = "" + v;
w = "" + w;
if (!_.isUndefined(name)) {
name = "" + name;
}
var e = edgeArgsToId(this._isDirected, v, w, name);
if (_.has(this._edgeLabels, e)) {
if (valueSpecified) {
this._edgeLabels[e] = value;
}
return this;
}
if (!_.isUndefined(name) && !this._isMultigraph) {
throw new Error("Cannot set a named edge when isMultigraph = false");
}
// It didn't exist, so we need to create it.
// First ensure the nodes exist.
this.setNode(v);
this.setNode(w);
this._edgeLabels[e] = valueSpecified ? value : this._defaultEdgeLabelFn(v, w, name);
var edgeObj = edgeArgsToObj(this._isDirected, v, w, name);
// Ensure we add undirected edges in a consistent way.
v = edgeObj.v;
w = edgeObj.w;
Object.freeze(edgeObj);
this._edgeObjs[e] = edgeObj;
incrementOrInitEntry(this._preds[w], v);
incrementOrInitEntry(this._sucs[v], w);
this._in[w][e] = edgeObj;
this._out[v][e] = edgeObj;
this._edgeCount++;
return this;
};
Graph.prototype.edge = function(v, w, name) {
var e = (arguments.length === 1
? edgeObjToId(this._isDirected, arguments[0])
: edgeArgsToId(this._isDirected, v, w, name));
return this._edgeLabels[e];
};
Graph.prototype.hasEdge = function(v, w, name) {
var e = (arguments.length === 1
? edgeObjToId(this._isDirected, arguments[0])
: edgeArgsToId(this._isDirected, v, w, name));
return _.has(this._edgeLabels, e);
};
Graph.prototype.removeEdge = function(v, w, name) {
var e = (arguments.length === 1
? edgeObjToId(this._isDirected, arguments[0])
: edgeArgsToId(this._isDirected, v, w, name));
var edge = this._edgeObjs[e];
if (edge) {
v = edge.v;
w = edge.w;
delete this._edgeLabels[e];
delete this._edgeObjs[e];
decrementOrRemoveEntry(this._preds[w], v);
decrementOrRemoveEntry(this._sucs[v], w);
delete this._in[w][e];
delete this._out[v][e];
this._edgeCount--;
}
return this;
};
Graph.prototype.inEdges = function(v, u) {
var inV = this._in[v];
if (inV) {
var edges = _.values(inV);
if (!u) {
return edges;
}
return _.filter(edges, function(edge) { return edge.v === u; });
}
};
Graph.prototype.outEdges = function(v, w) {
var outV = this._out[v];
if (outV) {
var edges = _.values(outV);
if (!w) {
return edges;
}
return _.filter(edges, function(edge) { return edge.w === w; });
}
};
Graph.prototype.nodeEdges = function(v, w) {
var inEdges = this.inEdges(v, w);
if (inEdges) {
return inEdges.concat(this.outEdges(v, w));
}
};
function incrementOrInitEntry(map, k) {
if (map[k]) {
map[k]++;
} else {
map[k] = 1;
}
}
function decrementOrRemoveEntry(map, k) {
if (!--map[k]) { delete map[k]; }
}
function edgeArgsToId(isDirected, v_, w_, name) {
var v = "" + v_;
var w = "" + w_;
if (!isDirected && v > w) {
var tmp = v;
v = w;
w = tmp;
}
return v + EDGE_KEY_DELIM + w + EDGE_KEY_DELIM +
(_.isUndefined(name) ? DEFAULT_EDGE_NAME : name);
}
function edgeArgsToObj(isDirected, v_, w_, name) {
var v = "" + v_;
var w = "" + w_;
if (!isDirected && v > w) {
var tmp = v;
v = w;
w = tmp;
}
var edgeObj = { v: v, w: w };
if (name) {
edgeObj.name = name;
}
return edgeObj;
}
function edgeObjToId(isDirected, edgeObj) {
return edgeArgsToId(isDirected, edgeObj.v, edgeObj.w, edgeObj.name);
}
},{"./lodash":19}],17:[function(require,module,exports){
// Includes only the "core" of graphlib
module.exports = {
Graph: require("./graph"),
version: require("./version")
};
},{"./graph":16,"./version":20}],18:[function(require,module,exports){
var _ = require("./lodash");
var Graph = require("./graph");
module.exports = {
write: write,
read: read
};
function write(g) {
var json = {
options: {
directed: g.isDirected(),
multigraph: g.isMultigraph(),
compound: g.isCompound()
},
nodes: writeNodes(g),
edges: writeEdges(g)
};
if (!_.isUndefined(g.graph())) {
json.value = _.clone(g.graph());
}
return json;
}
function writeNodes(g) {
return _.map(g.nodes(), function(v) {
var nodeValue = g.node(v);
var parent = g.parent(v);
var node = { v: v };
if (!_.isUndefined(nodeValue)) {
node.value = nodeValue;
}
if (!_.isUndefined(parent)) {
node.parent = parent;
}
return node;
});
}
function writeEdges(g) {
return _.map(g.edges(), function(e) {
var edgeValue = g.edge(e);
var edge = { v: e.v, w: e.w };
if (!_.isUndefined(e.name)) {
edge.name = e.name;
}
if (!_.isUndefined(edgeValue)) {
edge.value = edgeValue;
}
return edge;
});
}
function read(json) {
var g = new Graph(json.options).setGraph(json.value);
_.each(json.nodes, function(entry) {
g.setNode(entry.v, entry.value);
if (entry.parent) {
g.setParent(entry.v, entry.parent);
}
});
_.each(json.edges, function(entry) {
g.setEdge({ v: entry.v, w: entry.w, name: entry.name }, entry.value);
});
return g;
}
},{"./graph":16,"./lodash":19}],19:[function(require,module,exports){
/* global window */
var lodash;
if (typeof require === "function") {
try {
lodash = {
clone: require("lodash/clone"),
constant: require("lodash/constant"),
each: require("lodash/each"),
filter: require("lodash/filter"),
has: require("lodash/has"),
isArray: require("lodash/isArray"),
isEmpty: require("lodash/isEmpty"),
isFunction: require("lodash/isFunction"),
isUndefined: require("lodash/isUndefined"),
keys: require("lodash/keys"),
map: require("lodash/map"),
reduce: require("lodash/reduce"),
size: require("lodash/size"),
transform: require("lodash/transform"),
union: require("lodash/union"),
values: require("lodash/values")
};
} catch (e) {
// continue regardless of error
}
}
if (!lodash) {
lodash = window._;
}
module.exports = lodash;
},{"lodash/clone":undefined,"lodash/constant":undefined,"lodash/each":undefined,"lodash/filter":undefined,"lodash/has":undefined,"lodash/isArray":undefined,"lodash/isEmpty":undefined,"lodash/isFunction":undefined,"lodash/isUndefined":undefined,"lodash/keys":undefined,"lodash/map":undefined,"lodash/reduce":undefined,"lodash/size":undefined,"lodash/transform":undefined,"lodash/union":undefined,"lodash/values":undefined}],20:[function(require,module,exports){
module.exports = '2.1.8';
},{}]},{},[1])(1)
});