;(function(undefined) { 'use strict'; var __instances = {}; /** * This is the sigma instances constructor. One instance of sigma represent * one graph. It is possible to represent this grapĥ with several renderers * at the same time. By default, the default renderer (WebGL + Canvas * polyfill) will be used as the only renderer, with the container specified * in the configuration. * * @param {?*} conf The configuration of the instance. There are a lot of * different recognized forms to instantiate sigma, check * example files, documentation in this file and unit * tests to know more. * @return {sigma} The fresh new sigma instance. * * Instanciating sigma: * ******************** * If no parameter is given to the constructor, the instance will be created * without any renderer or camera. It will just instantiate the graph, and * other modules will have to be instantiated through the public methods, * like "addRenderer" etc: * * > s0 = new sigma(); * > s0.addRenderer({ * > type: 'canvas', * > container: 'my-container-id' * > }); * * In most of the cases, sigma will simply be used with the default renderer. * Then, since the only required parameter is the DOM container, there are * some simpler way to call the constructor. The four following calls do the * exact same things: * * > s1 = new sigma('my-container-id'); * > s2 = new sigma(document.getElementById('my-container-id')); * > s3 = new sigma({ * > container: document.getElementById('my-container-id') * > }); * > s4 = new sigma({ * > renderers: [{ * > container: document.getElementById('my-container-id') * > }] * > }); * * Recognized parameters: * ********************** * Here is the exhaustive list of every accepted parameters, when calling the * constructor with to top level configuration object (fourth case in the * previous examples): * * {?string} id The id of the instance. It will be generated * automatically if not specified. * {?array} renderers An array containing objects describing renderers. * {?object} graph An object containing an array of nodes and an array * of edges, to avoid having to add them by hand later. * {?object} settings An object containing instance specific settings that * will override the default ones defined in the object * sigma.settings. */ var sigma = function(conf) { // Local variables: // **************** var i, l, a, c, o, id; sigma.classes.dispatcher.extend(this); // Private attributes: // ******************* var _self = this, _conf = conf || {}; // Little shortcut: // **************** // The configuration is supposed to have a list of the configuration // objects for each renderer. // - If there are no configuration at all, then nothing is done. // - If there are no renderer list, the given configuration object will be // considered as describing the first and only renderer. // - If there are no renderer list nor "container" object, it will be // considered as the container itself (a DOM element). // - If the argument passed to sigma() is a string, it will be considered // as the ID of the DOM container. if ( typeof _conf === 'string' || _conf instanceof HTMLElement ) _conf = { renderers: [_conf] }; else if (Object.prototype.toString.call(_conf) === '[object Array]') _conf = { renderers: _conf }; // Also check "renderer" and "container" keys: o = _conf.renderers || _conf.renderer || _conf.container; if (!_conf.renderers || _conf.renderers.length === 0) if ( typeof o === 'string' || o instanceof HTMLElement || (typeof o === 'object' && 'container' in o) ) _conf.renderers = [o]; // Recense the instance: if (_conf.id) { if (__instances[_conf.id]) throw 'sigma: Instance "' + _conf.id + '" already exists.'; Object.defineProperty(this, 'id', { value: _conf.id }); } else { id = 0; while (__instances[id]) id++; Object.defineProperty(this, 'id', { value: '' + id }); } __instances[this.id] = this; // Initialize settings function: this.settings = new sigma.classes.configurable( sigma.settings, _conf.settings || {} ); // Initialize locked attributes: Object.defineProperty(this, 'graph', { value: new sigma.classes.graph(this.settings), configurable: true }); Object.defineProperty(this, 'middlewares', { value: [], configurable: true }); Object.defineProperty(this, 'cameras', { value: {}, configurable: true }); Object.defineProperty(this, 'renderers', { value: {}, configurable: true }); Object.defineProperty(this, 'renderersPerCamera', { value: {}, configurable: true }); Object.defineProperty(this, 'cameraFrames', { value: {}, configurable: true }); Object.defineProperty(this, 'camera', { get: function() { return this.cameras[0]; } }); Object.defineProperty(this, 'events', { value: [ 'click', 'rightClick', 'clickStage', 'doubleClickStage', 'rightClickStage', 'clickNode', 'clickNodes', 'doubleClickNode', 'doubleClickNodes', 'rightClickNode', 'rightClickNodes', 'overNode', 'overNodes', 'outNode', 'outNodes', 'downNode', 'downNodes', 'upNode', 'upNodes' ], configurable: true }); // Add a custom handler, to redispatch events from renderers: this._handler = (function(e) { var k, data = {}; for (k in e.data) data[k] = e.data[k]; data.renderer = e.target; this.dispatchEvent(e.type, data); }).bind(this); // Initialize renderers: a = _conf.renderers || []; for (i = 0, l = a.length; i < l; i++) this.addRenderer(a[i]); // Initialize middlewares: a = _conf.middlewares || []; for (i = 0, l = a.length; i < l; i++) this.middlewares.push( typeof a[i] === 'string' ? sigma.middlewares[a[i]] : a[i] ); // Check if there is already a graph to fill in: if (typeof _conf.graph === 'object' && _conf.graph) { this.graph.read(_conf.graph); // If a graph is given to the to the instance, the "refresh" method is // directly called: this.refresh(); } // Deal with resize: window.addEventListener('resize', function() { if (_self.settings) _self.refresh(); }); }; /** * This methods will instantiate and reference a new camera. If no id is * specified, then an automatic id will be generated. * * @param {?string} id Eventually the camera id. * @return {sigma.classes.camera} The fresh new camera instance. */ sigma.prototype.addCamera = function(id) { var self = this, camera; if (!arguments.length) { id = 0; while (this.cameras['' + id]) id++; id = '' + id; } if (this.cameras[id]) throw 'sigma.addCamera: The camera "' + id + '" already exists.'; camera = new sigma.classes.camera(id, this.graph, this.settings); this.cameras[id] = camera; // Add a quadtree to the camera: camera.quadtree = new sigma.classes.quad(); // Add an edgequadtree to the camera: if (sigma.classes.edgequad !== undefined) { camera.edgequadtree = new sigma.classes.edgequad(); } camera.bind('coordinatesUpdated', function(e) { self.renderCamera(camera, camera.isAnimated); }); this.renderersPerCamera[id] = []; return camera; }; /** * This method kills a camera, and every renderer attached to it. * * @param {string|camera} v The camera to kill or its ID. * @return {sigma} Returns the instance. */ sigma.prototype.killCamera = function(v) { v = typeof v === 'string' ? this.cameras[v] : v; if (!v) throw 'sigma.killCamera: The camera is undefined.'; var i, l, a = this.renderersPerCamera[v.id]; for (l = a.length, i = l - 1; i >= 0; i--) this.killRenderer(a[i]); delete this.renderersPerCamera[v.id]; delete this.cameraFrames[v.id]; delete this.cameras[v.id]; if (v.kill) v.kill(); return this; }; /** * This methods will instantiate and reference a new renderer. The "type" * argument can be the constructor or its name in the "sigma.renderers" * package. If no type is specified, then "sigma.renderers.def" will be used. * If no id is specified, then an automatic id will be generated. * * @param {?object} options Eventually some options to give to the renderer * constructor. * @return {renderer} The fresh new renderer instance. * * Recognized parameters: * ********************** * Here is the exhaustive list of every accepted parameters in the "options" * object: * * {?string} id Eventually the renderer id. * {?(function|string)} type Eventually the renderer constructor or its * name in the "sigma.renderers" package. * {?(camera|string)} camera Eventually the renderer camera or its * id. */ sigma.prototype.addRenderer = function(options) { var id, fn, camera, renderer, o = options || {}; // Polymorphism: if (typeof o === 'string') o = { container: document.getElementById(o) }; else if (o instanceof HTMLElement) o = { container: o }; // If the container still is a string, we get it by id if (typeof o.container === 'string') o.container = document.getElementById(o.container); // Reference the new renderer: if (!('id' in o)) { id = 0; while (this.renderers['' + id]) id++; id = '' + id; } else id = o.id; if (this.renderers[id]) throw 'sigma.addRenderer: The renderer "' + id + '" already exists.'; // Find the good constructor: fn = typeof o.type === 'function' ? o.type : sigma.renderers[o.type]; fn = fn || sigma.renderers.def; // Find the good camera: camera = 'camera' in o ? ( o.camera instanceof sigma.classes.camera ? o.camera : this.cameras[o.camera] || this.addCamera(o.camera) ) : this.addCamera(); if (this.cameras[camera.id] !== camera) throw 'sigma.addRenderer: The camera is not properly referenced.'; // Instantiate: renderer = new fn(this.graph, camera, this.settings, o); this.renderers[id] = renderer; Object.defineProperty(renderer, 'id', { value: id }); // Bind events: if (renderer.bind) renderer.bind( [ 'click', 'rightClick', 'clickStage', 'doubleClickStage', 'rightClickStage', 'clickNode', 'clickNodes', 'clickEdge', 'clickEdges', 'doubleClickNode', 'doubleClickNodes', 'doubleClickEdge', 'doubleClickEdges', 'rightClickNode', 'rightClickNodes', 'rightClickEdge', 'rightClickEdges', 'overNode', 'overNodes', 'overEdge', 'overEdges', 'outNode', 'outNodes', 'outEdge', 'outEdges', 'downNode', 'downNodes', 'downEdge', 'downEdges', 'upNode', 'upNodes', 'upEdge', 'upEdges' ], this._handler ); // Reference the renderer by its camera: this.renderersPerCamera[camera.id].push(renderer); return renderer; }; /** * This method kills a renderer. * * @param {string|renderer} v The renderer to kill or its ID. * @return {sigma} Returns the instance. */ sigma.prototype.killRenderer = function(v) { v = typeof v === 'string' ? this.renderers[v] : v; if (!v) throw 'sigma.killRenderer: The renderer is undefined.'; var a = this.renderersPerCamera[v.camera.id], i = a.indexOf(v); if (i >= 0) a.splice(i, 1); if (v.kill) v.kill(); delete this.renderers[v.id]; return this; }; /** * This method calls the "render" method of each renderer, with the same * arguments than the "render" method, but will also check if the renderer * has a "process" method, and call it if it exists. * * It is useful for quadtrees or WebGL processing, for instance. * * @param {?object} options Eventually some options to give to the refresh * method. * @return {sigma} Returns the instance itself. * * Recognized parameters: * ********************** * Here is the exhaustive list of every accepted parameters in the "options" * object: * * {?boolean} skipIndexation A flag specifying wether or not the refresh * function should reindex the graph in the * quadtrees or not (default: false). */ sigma.prototype.refresh = function(options) { var i, l, k, a, c, bounds, prefix = 0; options = options || {}; // Call each middleware: a = this.middlewares || []; for (i = 0, l = a.length; i < l; i++) a[i].call( this, (i === 0) ? '' : 'tmp' + prefix + ':', (i === l - 1) ? 'ready:' : ('tmp' + (++prefix) + ':') ); // Then, for each camera, call the "rescale" middleware, unless the // settings specify not to: for (k in this.cameras) { c = this.cameras[k]; if ( c.settings('autoRescale') && this.renderersPerCamera[c.id] && this.renderersPerCamera[c.id].length ) sigma.middlewares.rescale.call( this, a.length ? 'ready:' : '', c.readPrefix, { width: this.renderersPerCamera[c.id][0].width, height: this.renderersPerCamera[c.id][0].height } ); else sigma.middlewares.copy.call( this, a.length ? 'ready:' : '', c.readPrefix ); if (!options.skipIndexation) { // Find graph boundaries: bounds = sigma.utils.getBoundaries( this.graph, c.readPrefix ); // Refresh quadtree: c.quadtree.index(this.graph.nodes(), { prefix: c.readPrefix, bounds: { x: bounds.minX, y: bounds.minY, width: bounds.maxX - bounds.minX, height: bounds.maxY - bounds.minY } }); // Refresh edgequadtree: if ( c.edgequadtree !== undefined && c.settings('drawEdges') && c.settings('enableEdgeHovering') ) { c.edgequadtree.index(this.graph, { prefix: c.readPrefix, bounds: { x: bounds.minX, y: bounds.minY, width: bounds.maxX - bounds.minX, height: bounds.maxY - bounds.minY } }); } } } // Call each renderer: a = Object.keys(this.renderers); for (i = 0, l = a.length; i < l; i++) if (this.renderers[a[i]].process) { if (this.settings('skipErrors')) try { this.renderers[a[i]].process(); } catch (e) { console.log( 'Warning: The renderer "' + a[i] + '" crashed on ".process()"' ); } else this.renderers[a[i]].process(); } this.render(); return this; }; /** * This method calls the "render" method of each renderer. * * @return {sigma} Returns the instance itself. */ sigma.prototype.render = function() { var i, l, a, prefix = 0; // Call each renderer: a = Object.keys(this.renderers); for (i = 0, l = a.length; i < l; i++) if (this.settings('skipErrors')) try { this.renderers[a[i]].render(); } catch (e) { if (this.settings('verbose')) console.log( 'Warning: The renderer "' + a[i] + '" crashed on ".render()"' ); } else this.renderers[a[i]].render(); return this; }; /** * This method calls the "render" method of each renderer that is bound to * the specified camera. To improve the performances, if this method is * called too often, the number of effective renderings is limitated to one * per frame, unless you are using the "force" flag. * * @param {sigma.classes.camera} camera The camera to render. * @param {?boolean} force If true, will render the camera * directly. * @return {sigma} Returns the instance itself. */ sigma.prototype.renderCamera = function(camera, force) { var i, l, a, self = this; if (force) { a = this.renderersPerCamera[camera.id]; for (i = 0, l = a.length; i < l; i++) if (this.settings('skipErrors')) try { a[i].render(); } catch (e) { if (this.settings('verbose')) console.log( 'Warning: The renderer "' + a[i].id + '" crashed on ".render()"' ); } else a[i].render(); } else { if (!this.cameraFrames[camera.id]) { a = this.renderersPerCamera[camera.id]; for (i = 0, l = a.length; i < l; i++) if (this.settings('skipErrors')) try { a[i].render(); } catch (e) { if (this.settings('verbose')) console.log( 'Warning: The renderer "' + a[i].id + '" crashed on ".render()"' ); } else a[i].render(); this.cameraFrames[camera.id] = requestAnimationFrame(function() { delete self.cameraFrames[camera.id]; }); } } return this; }; /** * This method calls the "kill" method of each module and destroys any * reference from the instance. */ sigma.prototype.kill = function() { var k; // Dispatching event this.dispatchEvent('kill'); // Kill graph: this.graph.kill(); // Kill middlewares: delete this.middlewares; // Kill each renderer: for (k in this.renderers) this.killRenderer(this.renderers[k]); // Kill each camera: for (k in this.cameras) this.killCamera(this.cameras[k]); delete this.renderers; delete this.cameras; // Kill everything else: for (k in this) if (this.hasOwnProperty(k)) delete this[k]; delete __instances[this.id]; }; /** * Returns a clone of the instances object or a specific running instance. * * @param {?string} id Eventually an instance ID. * @return {object} The related instance or a clone of the instances * object. */ sigma.instances = function(id) { return arguments.length ? __instances[id] : sigma.utils.extend({}, __instances); }; /** * The current version of sigma: */ sigma.version = '1.0.3'; /** * EXPORT: * ******* */ if (typeof this.sigma !== 'undefined') throw 'An object called sigma is already in the global scope.'; this.sigma = sigma; }).call(this); /** * conrad.js is a tiny JavaScript jobs scheduler, * * Version: 0.1.0 * Sources: http://github.com/jacomyal/conrad.js * Doc: http://github.com/jacomyal/conrad.js#readme * * License: * -------- * Copyright © 2013 Alexis Jacomy, Sciences-Po médialab * * Permission is hereby granted, free of charge, to any person obtaining a copy * of this software and associated documentation files (the "Software"), to * deal in the Software without restriction, including without limitation the * rights to use, copy, modify, merge, publish, distribute, sublicense, and/or * sell copies of the Software, and to permit persons to whom the Software is * furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * The Software is provided "as is", without warranty of any kind, express or * implied, including but not limited to the warranties of merchantability, * fitness for a particular purpose and noninfringement. In no event shall the * authors or copyright holders be liable for any claim, damages or other * liability, whether in an action of contract, tort or otherwise, arising * from, out of or in connection with the software or the use or other dealings * in the Software. */ (function(global) { 'use strict'; // Check that conrad.js has not been loaded yet: if (global.conrad) throw new Error('conrad already exists'); /** * PRIVATE VARIABLES: * ****************** */ /** * A flag indicating whether conrad is running or not. * * @type {Number} */ var _lastFrameTime; /** * A flag indicating whether conrad is running or not. * * @type {Boolean} */ var _isRunning = false; /** * The hash of registered jobs. Each job must at least have a unique ID * under the key "id" and a function under the key "job". This hash * contains each running job and each waiting job. * * @type {Object} */ var _jobs = {}; /** * The hash of currently running jobs. * * @type {Object} */ var _runningJobs = {}; /** * The array of currently running jobs, sorted by priority. * * @type {Array} */ var _sortedByPriorityJobs = []; /** * The array of currently waiting jobs. * * @type {Object} */ var _waitingJobs = {}; /** * The array of finished jobs. They are stored in an array, since two jobs * with the same "id" can happen at two different times. * * @type {Array} */ var _doneJobs = []; /** * A dirty flag to keep conrad from starting: Indeed, when addJob() is called * with several jobs, conrad must be started only at the end. This flag keeps * me from duplicating the code that effectively adds a job. * * @type {Boolean} */ var _noStart = false; /** * An hash containing some global settings about how conrad.js should * behave. * * @type {Object} */ var _parameters = { frameDuration: 20, history: true }; /** * This object contains every handlers bound to conrad events. It does not * requirea any DOM implementation, since the events are all JavaScript. * * @type {Object} */ var _handlers = Object.create(null); /** * PRIVATE FUNCTIONS: * ****************** */ /** * Will execute the handler everytime that the indicated event (or the * indicated events) will be triggered. * * @param {string|array|object} events The name of the event (or the events * separated by spaces). * @param {function(Object)} handler The handler to bind. * @return {Object} Returns conrad. */ function _bind(events, handler) { var i, i_end, event, eArray; if (!arguments.length) return; else if ( arguments.length === 1 && Object(arguments[0]) === arguments[0] ) for (events in arguments[0]) _bind(events, arguments[0][events]); else if (arguments.length > 1) { eArray = Array.isArray(events) ? events : events.split(/ /); for (i = 0, i_end = eArray.length; i !== i_end; i += 1) { event = eArray[i]; if (!_handlers[event]) _handlers[event] = []; // Using an object instead of directly the handler will make possible // later to add flags _handlers[event].push({ handler: handler }); } } } /** * Removes the handler from a specified event (or specified events). * * @param {?string} events The name of the event (or the events * separated by spaces). If undefined, * then all handlers are removed. * @param {?function(Object)} handler The handler to unbind. If undefined, * each handler bound to the event or the * events will be removed. * @return {Object} Returns conrad. */ function _unbind(events, handler) { var i, i_end, j, j_end, a, event, eArray = Array.isArray(events) ? events : events.split(/ /); if (!arguments.length) _handlers = Object.create(null); else if (handler) { for (i = 0, i_end = eArray.length; i !== i_end; i += 1) { event = eArray[i]; if (_handlers[event]) { a = []; for (j = 0, j_end = _handlers[event].length; j !== j_end; j += 1) if (_handlers[event][j].handler !== handler) a.push(_handlers[event][j]); _handlers[event] = a; } if (_handlers[event] && _handlers[event].length === 0) delete _handlers[event]; } } else for (i = 0, i_end = eArray.length; i !== i_end; i += 1) delete _handlers[eArray[i]]; } /** * Executes each handler bound to the event. * * @param {string} events The name of the event (or the events separated * by spaces). * @param {?Object} data The content of the event (optional). * @return {Object} Returns conrad. */ function _dispatch(events, data) { var i, j, i_end, j_end, event, eventName, eArray = Array.isArray(events) ? events : events.split(/ /); data = data === undefined ? {} : data; for (i = 0, i_end = eArray.length; i !== i_end; i += 1) { eventName = eArray[i]; if (_handlers[eventName]) { event = { type: eventName, data: data || {} }; for (j = 0, j_end = _handlers[eventName].length; j !== j_end; j += 1) try { _handlers[eventName][j].handler(event); } catch (e) {} } } } /** * Executes the most prioritary job once, and deals with filling the stats * (done, time, averageTime, currentTime, etc...). * * @return {?Object} Returns the job object if it has to be killed, null else. */ function _executeFirstJob() { var i, l, test, kill, pushed = false, time = __dateNow(), job = _sortedByPriorityJobs.shift(); // Execute the job and look at the result: test = job.job(); // Deal with stats: time = __dateNow() - time; job.done++; job.time += time; job.currentTime += time; job.weightTime = job.currentTime / (job.weight || 1); job.averageTime = job.time / job.done; // Check if the job has to be killed: kill = job.count ? (job.count <= job.done) : !test; // Reset priorities: if (!kill) { for (i = 0, l = _sortedByPriorityJobs.length; i < l; i++) if (_sortedByPriorityJobs[i].weightTime > job.weightTime) { _sortedByPriorityJobs.splice(i, 0, job); pushed = true; break; } if (!pushed) _sortedByPriorityJobs.push(job); } return kill ? job : null; } /** * Activates a job, by adding it to the _runningJobs object and the * _sortedByPriorityJobs array. It also initializes its currentTime value. * * @param {Object} job The job to activate. */ function _activateJob(job) { var l = _sortedByPriorityJobs.length; // Add the job to the running jobs: _runningJobs[job.id] = job; job.status = 'running'; // Add the job to the priorities: if (l) { job.weightTime = _sortedByPriorityJobs[l - 1].weightTime; job.currentTime = job.weightTime * (job.weight || 1); } // Initialize the job and dispatch: job.startTime = __dateNow(); _dispatch('jobStarted', __clone(job)); _sortedByPriorityJobs.push(job); } /** * The main loop of conrad.js: * . It executes job such that they all occupate the same processing time. * . It stops jobs that do not need to be executed anymore. * . It triggers callbacks when it is relevant. * . It starts waiting jobs when they need to be started. * . It injects frames to keep a constant frapes per second ratio. * . It stops itself when there are no more jobs to execute. */ function _loop() { var k, o, l, job, time, deadJob; // Deal with the newly added jobs (the _jobs object): for (k in _jobs) { job = _jobs[k]; if (job.after) _waitingJobs[k] = job; else _activateJob(job); delete _jobs[k]; } // Set the _isRunning flag to false if there are no running job: _isRunning = !!_sortedByPriorityJobs.length; // Deal with the running jobs (the _runningJobs object): while ( _sortedByPriorityJobs.length && __dateNow() - _lastFrameTime < _parameters.frameDuration ) { deadJob = _executeFirstJob(); // Deal with the case where the job has ended: if (deadJob) { _killJob(deadJob.id); // Check for waiting jobs: for (k in _waitingJobs) if (_waitingJobs[k].after === deadJob.id) { _activateJob(_waitingJobs[k]); delete _waitingJobs[k]; } } } // Check if conrad still has jobs to deal with, and kill it if not: if (_isRunning) { // Update the _lastFrameTime: _lastFrameTime = __dateNow(); _dispatch('enterFrame'); setTimeout(_loop, 0); } else _dispatch('stop'); } /** * Adds one or more jobs, and starts the loop if no job was running before. A * job is at least a unique string "id" and a function, and there are some * parameters that you can specify for each job to modify the way conrad will * execute it. If a job is added with the "id" of another job that is waiting * or still running, an error will be thrown. * * When a job is added, it is referenced in the _jobs object, by its id. * Then, if it has to be executed right now, it will be also referenced in * the _runningJobs object. If it has to wait, then it will be added into the * _waitingJobs object, until it can start. * * Keep reading this documentation to see how to call this method. * * @return {Object} Returns conrad. * * Adding one job: * *************** * Basically, a job is defined by its string id and a function (the job). It * is also possible to add some parameters: * * > conrad.addJob('myJobId', myJobFunction); * > conrad.addJob('myJobId', { * > job: myJobFunction, * > someParameter: someValue * > }); * > conrad.addJob({ * > id: 'myJobId', * > job: myJobFunction, * > someParameter: someValue * > }); * * Adding several jobs: * ******************** * When adding several jobs at the same time, it is possible to specify * parameters for each one individually or for all: * * > conrad.addJob([ * > { * > id: 'myJobId1', * > job: myJobFunction1, * > someParameter1: someValue1 * > }, * > { * > id: 'myJobId2', * > job: myJobFunction2, * > someParameter2: someValue2 * > } * > ], { * > someCommonParameter: someCommonValue * > }); * > conrad.addJob({ * > myJobId1: {, * > job: myJobFunction1, * > someParameter1: someValue1 * > }, * > myJobId2: {, * > job: myJobFunction2, * > someParameter2: someValue2 * > } * > }, { * > someCommonParameter: someCommonValue * > }); * > conrad.addJob({ * > myJobId1: myJobFunction1, * > myJobId2: myJobFunction2 * > }, { * > someCommonParameter: someCommonValue * > }); * * Recognized parameters: * ********************** * Here is the exhaustive list of every accepted parameters: * * {?Function} end A callback to execute when the job is ended. It is * not executed if the job is killed instead of ended * "naturally". * {?Integer} count The number of time the job has to be executed. * {?Number} weight If specified, the job will be executed as it was * added "weight" times. * {?String} after The id of another job (eventually not added yet). * If specified, this job will start only when the * specified "after" job is ended. */ function _addJob(v1, v2) { var i, l, o; // Array of jobs: if (Array.isArray(v1)) { // Keep conrad to start until the last job is added: _noStart = true; for (i = 0, l = v1.length; i < l; i++) _addJob(v1[i].id, __extend(v1[i], v2)); _noStart = false; if (!_isRunning) { // Update the _lastFrameTime: _lastFrameTime = __dateNow(); _dispatch('start'); _loop(); } } else if (typeof v1 === 'object') { // One job (object): if (typeof v1.id === 'string') _addJob(v1.id, v1); // Hash of jobs: else { // Keep conrad to start until the last job is added: _noStart = true; for (i in v1) if (typeof v1[i] === 'function') _addJob(i, __extend({ job: v1[i] }, v2)); else _addJob(i, __extend(v1[i], v2)); _noStart = false; if (!_isRunning) { // Update the _lastFrameTime: _lastFrameTime = __dateNow(); _dispatch('start'); _loop(); } } // One job (string, *): } else if (typeof v1 === 'string') { if (_hasJob(v1)) throw new Error( '[conrad.addJob] Job with id "' + v1 + '" already exists.' ); // One job (string, function): if (typeof v2 === 'function') { o = { id: v1, done: 0, time: 0, status: 'waiting', currentTime: 0, averageTime: 0, weightTime: 0, job: v2 }; // One job (string, object): } else if (typeof v2 === 'object') { o = __extend( { id: v1, done: 0, time: 0, status: 'waiting', currentTime: 0, averageTime: 0, weightTime: 0 }, v2 ); // If none of those cases, throw an error: } else throw new Error('[conrad.addJob] Wrong arguments.'); // Effectively add the job: _jobs[v1] = o; _dispatch('jobAdded', __clone(o)); // Check if the loop has to be started: if (!_isRunning && !_noStart) { // Update the _lastFrameTime: _lastFrameTime = __dateNow(); _dispatch('start'); _loop(); } // If none of those cases, throw an error: } else throw new Error('[conrad.addJob] Wrong arguments.'); return this; } /** * Kills one or more jobs, indicated by their ids. It is only possible to * kill running jobs or waiting jobs. If you try to kill a job that does not * exists or that is already killed, a warning will be thrown. * * @param {Array|String} v1 A string job id or an array of job ids. * @return {Object} Returns conrad. */ function _killJob(v1) { var i, l, k, a, job, found = false; // Array of job ids: if (Array.isArray(v1)) for (i = 0, l = v1.length; i < l; i++) _killJob(v1[i]); // One job's id: else if (typeof v1 === 'string') { a = [_runningJobs, _waitingJobs, _jobs]; // Remove the job from the hashes: for (i = 0, l = a.length; i < l; i++) if (v1 in a[i]) { job = a[i][v1]; if (_parameters.history) { job.status = 'done'; _doneJobs.push(job); } _dispatch('jobEnded', __clone(job)); delete a[i][v1]; if (typeof job.end === 'function') job.end(); found = true; } // Remove the priorities array: a = _sortedByPriorityJobs; for (i = 0, l = a.length; i < l; i++) if (a[i].id === v1) { a.splice(i, 1); break; } if (!found) throw new Error('[conrad.killJob] Job "' + v1 + '" not found.'); // If none of those cases, throw an error: } else throw new Error('[conrad.killJob] Wrong arguments.'); return this; } /** * Kills every running, waiting, and just added jobs. * * @return {Object} Returns conrad. */ function _killAll() { var k, jobs = __extend(_jobs, _runningJobs, _waitingJobs); // Take every jobs and push them into the _doneJobs object: if (_parameters.history) for (k in jobs) { jobs[k].status = 'done'; _doneJobs.push(jobs[k]); if (typeof jobs[k].end === 'function') jobs[k].end(); } // Reinitialize the different jobs lists: _jobs = {}; _waitingJobs = {}; _runningJobs = {}; _sortedByPriorityJobs = []; // In case some jobs are added right after the kill: _isRunning = false; return this; } /** * Returns true if a job with the specified id is currently running or * waiting, and false else. * * @param {String} id The id of the job. * @return {?Object} Returns the job object if it exists. */ function _hasJob(id) { var job = _jobs[id] || _runningJobs[id] || _waitingJobs[id]; return job ? __extend(job) : null; } /** * This method will set the setting specified by "v1" to the value specified * by "v2" if both are given, and else return the current value of the * settings "v1". * * @param {String} v1 The name of the property. * @param {?*} v2 Eventually, a value to set to the specified * property. * @return {Object|*} Returns the specified settings value if "v2" is not * given, and conrad else. */ function _settings(v1, v2) { var o; if (typeof a1 === 'string' && arguments.length === 1) return _parameters[a1]; else { o = (typeof a1 === 'object' && arguments.length === 1) ? a1 || {} : {}; if (typeof a1 === 'string') o[a1] = a2; for (var k in o) if (o[k] !== undefined) _parameters[k] = o[k]; else delete _parameters[k]; return this; } } /** * Returns true if conrad is currently running, and false else. * * @return {Boolean} Returns _isRunning. */ function _getIsRunning() { return _isRunning; } /** * Unreference every jobs that are stored in the _doneJobs object. It will * not be possible anymore to get stats about these jobs, but it will release * the memory. * * @return {Object} Returns conrad. */ function _clearHistory() { _doneJobs = []; return this; } /** * Returns a snapshot of every data about jobs that wait to be started, are * currently running or are done. * * It is possible to get only running, waiting or done jobs by giving * "running", "waiting" or "done" as fist argument. * * It is also possible to get every job with a specified id by giving it as * first argument. Also, using a RegExp instead of an id will return every * jobs whose ids match the RegExp. And these two last use cases work as well * by giving before "running", "waiting" or "done". * * @return {Array} The array of the matching jobs. * * Some call examples: * ******************* * > conrad.getStats('running') * > conrad.getStats('waiting') * > conrad.getStats('done') * > conrad.getStats('myJob') * > conrad.getStats(/test/) * > conrad.getStats('running', 'myRunningJob') * > conrad.getStats('running', /test/) */ function _getStats(v1, v2) { var a, k, i, l, stats, pattern, isPatternString; if (!arguments.length) { stats = []; for (k in _jobs) stats.push(_jobs[k]); for (k in _waitingJobs) stats.push(_waitingJobs[k]); for (k in _runningJobs) stats.push(_runningJobs[k]); stats = stats.concat(_doneJobs); } if (typeof v1 === 'string') switch (v1) { case 'waiting': stats = __objectValues(_waitingJobs); break; case 'running': stats = __objectValues(_runningJobs); break; case 'done': stats = _doneJobs; break; default: pattern = v1; } if (v1 instanceof RegExp) pattern = v1; if (!pattern && (typeof v2 === 'string' || v2 instanceof RegExp)) pattern = v2; // Filter jobs if a pattern is given: if (pattern) { isPatternString = typeof pattern === 'string'; if (stats instanceof Array) { a = stats; } else if (typeof stats === 'object') { a = []; for (k in stats) a = a.concat(stats[k]); } else { a = []; for (k in _jobs) a.push(_jobs[k]); for (k in _waitingJobs) a.push(_waitingJobs[k]); for (k in _runningJobs) a.push(_runningJobs[k]); a = a.concat(_doneJobs); } stats = []; for (i = 0, l = a.length; i < l; i++) if (isPatternString ? a[i].id === pattern : a[i].id.match(pattern)) stats.push(a[i]); } return __clone(stats); } /** * TOOLS FUNCTIONS: * **************** */ /** * This function takes any number of objects as arguments, copies from each * of these objects each pair key/value into a new object, and finally * returns this object. * * The arguments are parsed from the last one to the first one, such that * when two objects have keys in common, the "earliest" object wins. * * Example: * ******** * > var o1 = { * > a: 1, * > b: 2, * > c: '3' * > }, * > o2 = { * > c: '4', * > d: [ 5 ] * > }; * > __extend(o1, o2); * > // Returns: { * > // a: 1, * > // b: 2, * > // c: '3', * > // d: [ 5 ] * > // }; * * @param {Object+} Any number of objects. * @return {Object} The merged object. */ function __extend() { var i, k, res = {}, l = arguments.length; for (i = l - 1; i >= 0; i--) for (k in arguments[i]) res[k] = arguments[i][k]; return res; } /** * This function simply clones an object. This object must contain only * objects, arrays and immutable values. Since it is not public, it does not * deal with cyclic references, DOM elements and instantiated objects - so * use it carefully. * * @param {Object} The object to clone. * @return {Object} The clone. */ function __clone(item) { var result, i, k, l; if (!item) return item; if (Array.isArray(item)) { result = []; for (i = 0, l = item.length; i < l; i++) result.push(__clone(item[i])); } else if (typeof item === 'object') { result = {}; for (i in item) result[i] = __clone(item[i]); } else result = item; return result; } /** * Returns an array containing the values of an object. * * @param {Object} The object. * @return {Array} The array of values. */ function __objectValues(o) { var k, a = []; for (k in o) a.push(o[k]); return a; } /** * A short "Date.now()" polyfill. * * @return {Number} The current time (in ms). */ function __dateNow() { return Date.now ? Date.now() : new Date().getTime(); } /** * Polyfill for the Array.isArray function: */ if (!Array.isArray) Array.isArray = function(v) { return Object.prototype.toString.call(v) === '[object Array]'; }; /** * EXPORT PUBLIC API: * ****************** */ var conrad = { hasJob: _hasJob, addJob: _addJob, killJob: _killJob, killAll: _killAll, settings: _settings, getStats: _getStats, isRunning: _getIsRunning, clearHistory: _clearHistory, // Events management: bind: _bind, unbind: _unbind, // Version: version: '0.1.0' }; if (typeof exports !== 'undefined') { if (typeof module !== 'undefined' && module.exports) exports = module.exports = conrad; exports.conrad = conrad; } global.conrad = conrad; })(this); ;(function(undefined) { 'use strict'; if (typeof sigma === 'undefined') throw 'sigma is not declared'; var _root = this; // Initialize packages: sigma.utils = sigma.utils || {}; /** * MISC UTILS: */ /** * This function takes any number of objects as arguments, copies from each * of these objects each pair key/value into a new object, and finally * returns this object. * * The arguments are parsed from the last one to the first one, such that * when several objects have keys in common, the "earliest" object wins. * * Example: * ******** * > var o1 = { * > a: 1, * > b: 2, * > c: '3' * > }, * > o2 = { * > c: '4', * > d: [ 5 ] * > }; * > sigma.utils.extend(o1, o2); * > // Returns: { * > // a: 1, * > // b: 2, * > // c: '3', * > // d: [ 5 ] * > // }; * * @param {object+} Any number of objects. * @return {object} The merged object. */ sigma.utils.extend = function() { var i, k, res = {}, l = arguments.length; for (i = l - 1; i >= 0; i--) for (k in arguments[i]) res[k] = arguments[i][k]; return res; }; /** * A short "Date.now()" polyfill. * * @return {Number} The current time (in ms). */ sigma.utils.dateNow = function() { return Date.now ? Date.now() : new Date().getTime(); }; /** * Takes a package name as parameter and checks at each lebel if it exists, * and if it does not, creates it. * * Example: * ******** * > sigma.utils.pkg('a.b.c'); * > a.b.c; * > // Object {}; * > * > sigma.utils.pkg('a.b.d'); * > a.b; * > // Object { c: {}, d: {} }; * * @param {string} pkgName The name of the package to create/find. * @return {object} The related package. */ sigma.utils.pkg = function(pkgName) { return (pkgName || '').split('.').reduce(function(context, objName) { return (objName in context) ? context[objName] : (context[objName] = {}); }, _root); }; /** * Returns a unique incremental number ID. * * Example: * ******** * > sigma.utils.id(); * > // 1; * > * > sigma.utils.id(); * > // 2; * > * > sigma.utils.id(); * > // 3; * * @param {string} pkgName The name of the package to create/find. * @return {object} The related package. */ sigma.utils.id = (function() { var i = 0; return function() { return ++i; }; })(); /** * This function takes an hexa color (for instance "#ffcc00" or "#fc0") or a * rgb / rgba color (like "rgb(255,255,12)" or "rgba(255,255,12,1)") and * returns an integer equal to "r * 255 * 255 + g * 255 + b", to gain some * memory in the data given to WebGL shaders. * * @param {string} val The hexa or rgba color. * @return {number} The number value. */ sigma.utils.floatColor = function(val) { var result = [0, 0, 0]; if (val.match(/^#/)) { val = (val || '').replace(/^#/, ''); result = (val.length === 3) ? [ parseInt(val.charAt(0) + val.charAt(0), 16), parseInt(val.charAt(1) + val.charAt(1), 16), parseInt(val.charAt(2) + val.charAt(2), 16) ] : [ parseInt(val.charAt(0) + val.charAt(1), 16), parseInt(val.charAt(2) + val.charAt(3), 16), parseInt(val.charAt(4) + val.charAt(5), 16) ]; } else if (val.match(/^ *rgba? *\(/)) { val = val.match( /^ *rgba? *\( *([0-9]*) *, *([0-9]*) *, *([0-9]*) *(,.*)?\) *$/ ); result = [ +val[1], +val[2], +val[3] ]; } return ( result[0] * 256 * 256 + result[1] * 256 + result[2] ); }; /** * Perform a zoom into a camera, with or without animation, to the * coordinates indicated using a specified ratio. * * Recognized parameters: * ********************** * Here is the exhaustive list of every accepted parameters in the animation * object: * * {?number} duration An amount of time that means the duration of the * animation. If this parameter doesn't exist the * zoom will be performed without animation. * {?function} onComplete A function to perform it after the animation. It * will be performed even if there is no duration. * * @param {camera} The camera where perform the zoom. * @param {x} The X coordiantion where the zoom goes. * @param {y} The Y coordiantion where the zoom goes. * @param {ratio} The ratio to apply it to the current camera ratio. * @param {?animation} A dictionary with options for a possible animation. */ sigma.utils.zoomTo = function(camera, x, y, ratio, animation) { var settings = camera.settings, count, newRatio, animationSettings, coordinates; // Create the newRatio dealing with min / max: newRatio = Math.max( settings('zoomMin'), Math.min( settings('zoomMax'), camera.ratio * ratio ) ); // Check that the new ratio is different from the initial one: if (newRatio !== camera.ratio) { // Create the coordinates variable: ratio = newRatio / camera.ratio; coordinates = { x: x * (1 - ratio) + camera.x, y: y * (1 - ratio) + camera.y, ratio: newRatio }; if (animation && animation.duration) { // Complete the animation setings: count = sigma.misc.animation.killAll(camera); animation = sigma.utils.extend( animation, { easing: count ? 'quadraticOut' : 'quadraticInOut' } ); sigma.misc.animation.camera(camera, coordinates, animation); } else { camera.goTo(coordinates); if (animation && animation.onComplete) animation.onComplete(); } } }; /** * Return the control point coordinates for a quadratic bezier curve. * * @param {number} x1 The X coordinate of the start point. * @param {number} y1 The Y coordinate of the start point. * @param {number} x2 The X coordinate of the end point. * @param {number} y2 The Y coordinate of the end point. * @return {x,y} The control point coordinates. */ sigma.utils.getQuadraticControlPoint = function(x1, y1, x2, y2) { return { x: (x1 + x2) / 2 + (y2 - y1) / 4, y: (y1 + y2) / 2 + (x1 - x2) / 4 }; }; /** * Compute the coordinates of the point positioned * at length t in the quadratic bezier curve. * * @param {number} t In [0,1] the step percentage to reach * the point in the curve from the context point. * @param {number} x1 The X coordinate of the context point. * @param {number} y1 The Y coordinate of the context point. * @param {number} x2 The X coordinate of the ending point. * @param {number} y2 The Y coordinate of the ending point. * @param {number} xi The X coordinate of the control point. * @param {number} yi The Y coordinate of the control point. * @return {object} {x,y}. */ sigma.utils.getPointOnQuadraticCurve = function(t, x1, y1, x2, y2, xi, yi) { // http://stackoverflow.com/a/5634528 return { x: Math.pow(1 - t, 2) * x1 + 2 * (1 - t) * t * xi + Math.pow(t, 2) * x2, y: Math.pow(1 - t, 2) * y1 + 2 * (1 - t) * t * yi + Math.pow(t, 2) * y2 }; }; /** * Compute the coordinates of the point positioned * at length t in the cubic bezier curve. * * @param {number} t In [0,1] the step percentage to reach * the point in the curve from the context point. * @param {number} x1 The X coordinate of the context point. * @param {number} y1 The Y coordinate of the context point. * @param {number} x2 The X coordinate of the end point. * @param {number} y2 The Y coordinate of the end point. * @param {number} cx The X coordinate of the first control point. * @param {number} cy The Y coordinate of the first control point. * @param {number} dx The X coordinate of the second control point. * @param {number} dy The Y coordinate of the second control point. * @return {object} {x,y} The point at t. */ sigma.utils.getPointOnBezierCurve = function(t, x1, y1, x2, y2, cx, cy, dx, dy) { // http://stackoverflow.com/a/15397596 // Blending functions: var B0_t = Math.pow(1 - t, 3), B1_t = 3 * t * Math.pow(1 - t, 2), B2_t = 3 * Math.pow(t, 2) * (1 - t), B3_t = Math.pow(t, 3); return { x: (B0_t * x1) + (B1_t * cx) + (B2_t * dx) + (B3_t * x2), y: (B0_t * y1) + (B1_t * cy) + (B2_t * dy) + (B3_t * y2) }; }; /** * Return the coordinates of the two control points for a self loop (i.e. * where the start point is also the end point) computed as a cubic bezier * curve. * * @param {number} x The X coordinate of the node. * @param {number} y The Y coordinate of the node. * @param {number} size The node size. * @return {x1,y1,x2,y2} The coordinates of the two control points. */ sigma.utils.getSelfLoopControlPoints = function(x , y, size) { return { x1: x - size * 7, y1: y, x2: x, y2: y + size * 7 }; }; /** * Return the euclidian distance between two points of a plane * with an orthonormal basis. * * @param {number} x1 The X coordinate of the first point. * @param {number} y1 The Y coordinate of the first point. * @param {number} x2 The X coordinate of the second point. * @param {number} y2 The Y coordinate of the second point. * @return {number} The euclidian distance. */ sigma.utils.getDistance = function(x0, y0, x1, y1) { return Math.sqrt(Math.pow(x1 - x0, 2) + Math.pow(y1 - y0, 2)); }; /** * Return the coordinates of the intersection points of two circles. * * @param {number} x0 The X coordinate of center location of the first * circle. * @param {number} y0 The Y coordinate of center location of the first * circle. * @param {number} r0 The radius of the first circle. * @param {number} x1 The X coordinate of center location of the second * circle. * @param {number} y1 The Y coordinate of center location of the second * circle. * @param {number} r1 The radius of the second circle. * @return {xi,yi} The coordinates of the intersection points. */ sigma.utils.getCircleIntersection = function(x0, y0, r0, x1, y1, r1) { // http://stackoverflow.com/a/12219802 var a, dx, dy, d, h, rx, ry, x2, y2; // dx and dy are the vertical and horizontal distances between the circle // centers: dx = x1 - x0; dy = y1 - y0; // Determine the straight-line distance between the centers: d = Math.sqrt((dy * dy) + (dx * dx)); // Check for solvability: if (d > (r0 + r1)) { // No solution. circles do not intersect. return false; } if (d < Math.abs(r0 - r1)) { // No solution. one circle is contained in the other. return false; } //'point 2' is the point where the line through the circle intersection // points crosses the line between the circle centers. // Determine the distance from point 0 to point 2: a = ((r0 * r0) - (r1 * r1) + (d * d)) / (2.0 * d); // Determine the coordinates of point 2: x2 = x0 + (dx * a / d); y2 = y0 + (dy * a / d); // Determine the distance from point 2 to either of the intersection // points: h = Math.sqrt((r0 * r0) - (a * a)); // Determine the offsets of the intersection points from point 2: rx = -dy * (h / d); ry = dx * (h / d); // Determine the absolute intersection points: var xi = x2 + rx; var xi_prime = x2 - rx; var yi = y2 + ry; var yi_prime = y2 - ry; return {xi: xi, xi_prime: xi_prime, yi: yi, yi_prime: yi_prime}; }; /** * Check if a point is on a line segment. * * @param {number} x The X coordinate of the point to check. * @param {number} y The Y coordinate of the point to check. * @param {number} x1 The X coordinate of the line start point. * @param {number} y1 The Y coordinate of the line start point. * @param {number} x2 The X coordinate of the line end point. * @param {number} y2 The Y coordinate of the line end point. * @param {number} epsilon The precision (consider the line thickness). * @return {boolean} True if point is "close to" the line * segment, false otherwise. */ sigma.utils.isPointOnSegment = function(x, y, x1, y1, x2, y2, epsilon) { // http://stackoverflow.com/a/328122 var crossProduct = Math.abs((y - y1) * (x2 - x1) - (x - x1) * (y2 - y1)), d = sigma.utils.getDistance(x1, y1, x2, y2), nCrossProduct = crossProduct / d; // normalized cross product return (nCrossProduct < epsilon && Math.min(x1, x2) <= x && x <= Math.max(x1, x2) && Math.min(y1, y2) <= y && y <= Math.max(y1, y2)); }; /** * Check if a point is on a quadratic bezier curve segment with a thickness. * * @param {number} x The X coordinate of the point to check. * @param {number} y The Y coordinate of the point to check. * @param {number} x1 The X coordinate of the curve start point. * @param {number} y1 The Y coordinate of the curve start point. * @param {number} x2 The X coordinate of the curve end point. * @param {number} y2 The Y coordinate of the curve end point. * @param {number} cpx The X coordinate of the curve control point. * @param {number} cpy The Y coordinate of the curve control point. * @param {number} epsilon The precision (consider the line thickness). * @return {boolean} True if (x,y) is on the curve segment, * false otherwise. */ sigma.utils.isPointOnQuadraticCurve = function(x, y, x1, y1, x2, y2, cpx, cpy, epsilon) { // Fails if the point is too far from the extremities of the segment, // preventing for more costly computation: var dP1P2 = sigma.utils.getDistance(x1, y1, x2, y2); if (Math.abs(x - x1) > dP1P2 || Math.abs(y - y1) > dP1P2) { return false; } var dP1 = sigma.utils.getDistance(x, y, x1, y1), dP2 = sigma.utils.getDistance(x, y, x2, y2), t = 0.5, r = (dP1 < dP2) ? -0.01 : 0.01, rThreshold = 0.001, i = 100, pt = sigma.utils.getPointOnQuadraticCurve(t, x1, y1, x2, y2, cpx, cpy), dt = sigma.utils.getDistance(x, y, pt.x, pt.y), old_dt; // This algorithm minimizes the distance from the point to the curve. It // find the optimal t value where t=0 is the start point and t=1 is the end // point of the curve, starting from t=0.5. // It terminates because it runs a maximum of i interations. while (i-- > 0 && t >= 0 && t <= 1 && (dt > epsilon) && (r > rThreshold || r < -rThreshold)) { old_dt = dt; pt = sigma.utils.getPointOnQuadraticCurve(t, x1, y1, x2, y2, cpx, cpy); dt = sigma.utils.getDistance(x, y, pt.x, pt.y); if (dt > old_dt) { // not the right direction: // halfstep in the opposite direction r = -r / 2; t += r; } else if (t + r < 0 || t + r > 1) { // oops, we've gone too far: // revert with a halfstep r = r / 2; dt = old_dt; } else { // progress: t += r; } } return dt < epsilon; }; /** * Check if a point is on a cubic bezier curve segment with a thickness. * * @param {number} x The X coordinate of the point to check. * @param {number} y The Y coordinate of the point to check. * @param {number} x1 The X coordinate of the curve start point. * @param {number} y1 The Y coordinate of the curve start point. * @param {number} x2 The X coordinate of the curve end point. * @param {number} y2 The Y coordinate of the curve end point. * @param {number} cpx1 The X coordinate of the 1st curve control point. * @param {number} cpy1 The Y coordinate of the 1st curve control point. * @param {number} cpx2 The X coordinate of the 2nd curve control point. * @param {number} cpy2 The Y coordinate of the 2nd curve control point. * @param {number} epsilon The precision (consider the line thickness). * @return {boolean} True if (x,y) is on the curve segment, * false otherwise. */ sigma.utils.isPointOnBezierCurve = function(x, y, x1, y1, x2, y2, cpx1, cpy1, cpx2, cpy2, epsilon) { // Fails if the point is too far from the extremities of the segment, // preventing for more costly computation: var dP1CP1 = sigma.utils.getDistance(x1, y1, cpx1, cpy1); if (Math.abs(x - x1) > dP1CP1 || Math.abs(y - y1) > dP1CP1) { return false; } var dP1 = sigma.utils.getDistance(x, y, x1, y1), dP2 = sigma.utils.getDistance(x, y, x2, y2), t = 0.5, r = (dP1 < dP2) ? -0.01 : 0.01, rThreshold = 0.001, i = 100, pt = sigma.utils.getPointOnBezierCurve( t, x1, y1, x2, y2, cpx1, cpy1, cpx2, cpy2), dt = sigma.utils.getDistance(x, y, pt.x, pt.y), old_dt; // This algorithm minimizes the distance from the point to the curve. It // find the optimal t value where t=0 is the start point and t=1 is the end // point of the curve, starting from t=0.5. // It terminates because it runs a maximum of i interations. while (i-- > 0 && t >= 0 && t <= 1 && (dt > epsilon) && (r > rThreshold || r < -rThreshold)) { old_dt = dt; pt = sigma.utils.getPointOnBezierCurve( t, x1, y1, x2, y2, cpx1, cpy1, cpx2, cpy2); dt = sigma.utils.getDistance(x, y, pt.x, pt.y); if (dt > old_dt) { // not the right direction: // halfstep in the opposite direction r = -r / 2; t += r; } else if (t + r < 0 || t + r > 1) { // oops, we've gone too far: // revert with a halfstep r = r / 2; dt = old_dt; } else { // progress: t += r; } } return dt < epsilon; }; /** * ************ * EVENTS UTILS: * ************ */ /** * Here are some useful functions to unify extraction of the information we * need with mouse events and touch events, from different browsers: */ /** * Extract the local X position from a mouse or touch event. * * @param {event} e A mouse or touch event. * @return {number} The local X value of the mouse. */ sigma.utils.getX = function(e) { return ( (e.offsetX !== undefined && e.offsetX) || (e.layerX !== undefined && e.layerX) || (e.clientX !== undefined && e.clientX) ); }; /** * Extract the local Y position from a mouse or touch event. * * @param {event} e A mouse or touch event. * @return {number} The local Y value of the mouse. */ sigma.utils.getY = function(e) { return ( (e.offsetY !== undefined && e.offsetY) || (e.layerY !== undefined && e.layerY) || (e.clientY !== undefined && e.clientY) ); }; /** * Extract the width from a mouse or touch event. * * @param {event} e A mouse or touch event. * @return {number} The width of the event's target. */ sigma.utils.getWidth = function(e) { var w = (!e.target.ownerSVGElement) ? e.target.width : e.target.ownerSVGElement.width; return ( (typeof w === 'number' && w) || (w !== undefined && w.baseVal !== undefined && w.baseVal.value) ); }; /** * Extract the height from a mouse or touch event. * * @param {event} e A mouse or touch event. * @return {number} The height of the event's target. */ sigma.utils.getHeight = function(e) { var h = (!e.target.ownerSVGElement) ? e.target.height : e.target.ownerSVGElement.height; return ( (typeof h === 'number' && h) || (h !== undefined && h.baseVal !== undefined && h.baseVal.value) ); }; /** * Extract the wheel delta from a mouse or touch event. * * @param {event} e A mouse or touch event. * @return {number} The wheel delta of the mouse. */ sigma.utils.getDelta = function(e) { return ( (e.wheelDelta !== undefined && e.wheelDelta) || (e.detail !== undefined && -e.detail) ); }; /** * Returns the offset of a DOM element. * * @param {DOMElement} dom The element to retrieve the position. * @return {object} The offset of the DOM element (top, left). */ sigma.utils.getOffset = function(dom) { var left = 0, top = 0; while (dom) { top = top + parseInt(dom.offsetTop); left = left + parseInt(dom.offsetLeft); dom = dom.offsetParent; } return { top: top, left: left }; }; /** * Simulates a "double click" event. * * @param {HTMLElement} target The event target. * @param {string} type The event type. * @param {function} callback The callback to execute. */ sigma.utils.doubleClick = function(target, type, callback) { var clicks = 0, self = this, handlers; target._doubleClickHandler = target._doubleClickHandler || {}; target._doubleClickHandler[type] = target._doubleClickHandler[type] || []; handlers = target._doubleClickHandler[type]; handlers.push(function(e) { clicks++; if (clicks === 2) { clicks = 0; return callback(e); } else if (clicks === 1) { setTimeout(function() { clicks = 0; }, sigma.settings.doubleClickTimeout); } }); target.addEventListener(type, handlers[handlers.length - 1], false); }; /** * Unbind simulated "double click" events. * * @param {HTMLElement} target The event target. * @param {string} type The event type. */ sigma.utils.unbindDoubleClick = function(target, type) { var handler, handlers = (target._doubleClickHandler || {})[type] || []; while ((handler = handlers.pop())) { target.removeEventListener(type, handler); } delete (target._doubleClickHandler || {})[type]; }; /** * Here are just some of the most basic easing functions, used for the * animated camera "goTo" calls. * * If you need some more easings functions, don't hesitate to add them to * sigma.utils.easings. But I will not add some more here or merge PRs * containing, because I do not want sigma sources full of overkill and never * used stuff... */ sigma.utils.easings = sigma.utils.easings || {}; sigma.utils.easings.linearNone = function(k) { return k; }; sigma.utils.easings.quadraticIn = function(k) { return k * k; }; sigma.utils.easings.quadraticOut = function(k) { return k * (2 - k); }; sigma.utils.easings.quadraticInOut = function(k) { if ((k *= 2) < 1) return 0.5 * k * k; return - 0.5 * (--k * (k - 2) - 1); }; sigma.utils.easings.cubicIn = function(k) { return k * k * k; }; sigma.utils.easings.cubicOut = function(k) { return --k * k * k + 1; }; sigma.utils.easings.cubicInOut = function(k) { if ((k *= 2) < 1) return 0.5 * k * k * k; return 0.5 * ((k -= 2) * k * k + 2); }; /** * ************ * WEBGL UTILS: * ************ */ /** * Loads a WebGL shader and returns it. * * @param {WebGLContext} gl The WebGLContext to use. * @param {string} shaderSource The shader source. * @param {number} shaderType The type of shader. * @param {function(string): void} error Callback for errors. * @return {WebGLShader} The created shader. */ sigma.utils.loadShader = function(gl, shaderSource, shaderType, error) { var compiled, shader = gl.createShader(shaderType); // Load the shader source gl.shaderSource(shader, shaderSource); // Compile the shader gl.compileShader(shader); // Check the compile status compiled = gl.getShaderParameter(shader, gl.COMPILE_STATUS); // If something went wrong: if (!compiled) { if (error) { error( 'Error compiling shader "' + shader + '":' + gl.getShaderInfoLog(shader) ); } gl.deleteShader(shader); return null; } return shader; }; /** * Creates a program, attaches shaders, binds attrib locations, links the * program and calls useProgram. * * @param {Array.} shaders The shaders to attach. * @param {Array.} attribs The attribs names. * @param {Array.} locations The locations for the attribs. * @param {function(string): void} error Callback for errors. * @return {WebGLProgram} The created program. */ sigma.utils.loadProgram = function(gl, shaders, attribs, loc, error) { var i, linked, program = gl.createProgram(); for (i = 0; i < shaders.length; ++i) gl.attachShader(program, shaders[i]); if (attribs) for (i = 0; i < attribs.length; ++i) gl.bindAttribLocation( program, locations ? locations[i] : i, opt_attribs[i] ); gl.linkProgram(program); // Check the link status linked = gl.getProgramParameter(program, gl.LINK_STATUS); if (!linked) { if (error) error('Error in program linking: ' + gl.getProgramInfoLog(program)); gl.deleteProgram(program); return null; } return program; }; /** * ********* * MATRICES: * ********* * The following utils are just here to help generating the transformation * matrices for the WebGL renderers. */ sigma.utils.pkg('sigma.utils.matrices'); /** * The returns a 3x3 translation matrix. * * @param {number} dx The X translation. * @param {number} dy The Y translation. * @return {array} Returns the matrix. */ sigma.utils.matrices.translation = function(dx, dy) { return [ 1, 0, 0, 0, 1, 0, dx, dy, 1 ]; }; /** * The returns a 3x3 or 2x2 rotation matrix. * * @param {number} angle The rotation angle. * @param {boolean} m2 If true, the function will return a 2x2 matrix. * @return {array} Returns the matrix. */ sigma.utils.matrices.rotation = function(angle, m2) { var cos = Math.cos(angle), sin = Math.sin(angle); return m2 ? [ cos, -sin, sin, cos ] : [ cos, -sin, 0, sin, cos, 0, 0, 0, 1 ]; }; /** * The returns a 3x3 or 2x2 homothetic transformation matrix. * * @param {number} ratio The scaling ratio. * @param {boolean} m2 If true, the function will return a 2x2 matrix. * @return {array} Returns the matrix. */ sigma.utils.matrices.scale = function(ratio, m2) { return m2 ? [ ratio, 0, 0, ratio ] : [ ratio, 0, 0, 0, ratio, 0, 0, 0, 1 ]; }; /** * The returns a 3x3 or 2x2 homothetic transformation matrix. * * @param {array} a The first matrix. * @param {array} b The second matrix. * @param {boolean} m2 If true, the function will assume both matrices are * 2x2. * @return {array} Returns the matrix. */ sigma.utils.matrices.multiply = function(a, b, m2) { var l = m2 ? 2 : 3, a00 = a[0 * l + 0], a01 = a[0 * l + 1], a02 = a[0 * l + 2], a10 = a[1 * l + 0], a11 = a[1 * l + 1], a12 = a[1 * l + 2], a20 = a[2 * l + 0], a21 = a[2 * l + 1], a22 = a[2 * l + 2], b00 = b[0 * l + 0], b01 = b[0 * l + 1], b02 = b[0 * l + 2], b10 = b[1 * l + 0], b11 = b[1 * l + 1], b12 = b[1 * l + 2], b20 = b[2 * l + 0], b21 = b[2 * l + 1], b22 = b[2 * l + 2]; return m2 ? [ a00 * b00 + a01 * b10, a00 * b01 + a01 * b11, a10 * b00 + a11 * b10, a10 * b01 + a11 * b11 ] : [ a00 * b00 + a01 * b10 + a02 * b20, a00 * b01 + a01 * b11 + a02 * b21, a00 * b02 + a01 * b12 + a02 * b22, a10 * b00 + a11 * b10 + a12 * b20, a10 * b01 + a11 * b11 + a12 * b21, a10 * b02 + a11 * b12 + a12 * b22, a20 * b00 + a21 * b10 + a22 * b20, a20 * b01 + a21 * b11 + a22 * b21, a20 * b02 + a21 * b12 + a22 * b22 ]; }; }).call(this); ;(function(global) { 'use strict'; /** * http://paulirish.com/2011/requestanimationframe-for-smart-animating/ * http://my.opera.com/emoller/blog/2011/12/20/requestanimationframe-for-smart-er-animating * requestAnimationFrame polyfill by Erik Möller. * fixes from Paul Irish and Tino Zijdel * MIT license */ var x, lastTime = 0, vendors = ['ms', 'moz', 'webkit', 'o']; for (x = 0; x < vendors.length && !global.requestAnimationFrame; x++) { global.requestAnimationFrame = global[vendors[x] + 'RequestAnimationFrame']; global.cancelAnimationFrame = global[vendors[x] + 'CancelAnimationFrame'] || global[vendors[x] + 'CancelRequestAnimationFrame']; } if (!global.requestAnimationFrame) global.requestAnimationFrame = function(callback, element) { var currTime = new Date().getTime(), timeToCall = Math.max(0, 16 - (currTime - lastTime)), id = global.setTimeout( function() { callback(currTime + timeToCall); }, timeToCall ); lastTime = currTime + timeToCall; return id; }; if (!global.cancelAnimationFrame) global.cancelAnimationFrame = function(id) { clearTimeout(id); }; /** * Function.prototype.bind polyfill found on MDN. * https://developer.mozilla.org/en-US/docs/Web/JavaScript/Reference/Global_Objects/Function/bind#Compatibility * Public domain */ if (!Function.prototype.bind) Function.prototype.bind = function(oThis) { if (typeof this !== 'function') // Closest thing possible to the ECMAScript 5 internal IsCallable // function: throw new TypeError( 'Function.prototype.bind - what is trying to be bound is not callable' ); var aArgs = Array.prototype.slice.call(arguments, 1), fToBind = this, fNOP, fBound; fNOP = function() {}; fBound = function() { return fToBind.apply( this instanceof fNOP && oThis ? this : oThis, aArgs.concat(Array.prototype.slice.call(arguments)) ); }; fNOP.prototype = this.prototype; fBound.prototype = new fNOP(); return fBound; }; })(this); ;(function(undefined) { 'use strict'; if (typeof sigma === 'undefined') throw 'sigma is not declared'; // Packages initialization: sigma.utils.pkg('sigma.settings'); var settings = { /** * GRAPH SETTINGS: * *************** */ // {boolean} Indicates if the data have to be cloned in methods to add // nodes or edges. clone: true, // {boolean} Indicates if nodes "id" values and edges "id", "source" and // "target" values must be set as immutable. immutable: true, // {boolean} Indicates if sigma can log its errors and warnings. verbose: false, /** * RENDERERS SETTINGS: * ******************* */ // {string} classPrefix: 'sigma', // {string} defaultNodeType: 'def', // {string} defaultEdgeType: 'def', // {string} defaultLabelColor: '#000', // {string} defaultEdgeColor: '#000', // {string} defaultNodeColor: '#000', // {string} defaultLabelSize: 14, // {string} Indicates how to choose the edges color. Available values: // "source", "target", "default" edgeColor: 'source', // {number} Defines the minimal edge's arrow display size. minArrowSize: 0, // {string} font: 'arial', // {string} Example: 'bold' fontStyle: '', // {string} Indicates how to choose the labels color. Available values: // "node", "default" labelColor: 'default', // {string} Indicates how to choose the labels size. Available values: // "fixed", "proportional" labelSize: 'fixed', // {string} The ratio between the font size of the label and the node size. labelSizeRatio: 1, // {number} The minimum size a node must have to see its label displayed. labelThreshold: 8, // {number} The oversampling factor used in WebGL renderer. webglOversamplingRatio: 2, // {number} The size of the border of hovered nodes. borderSize: 0, // {number} The default hovered node border's color. defaultNodeBorderColor: '#000', // {number} The hovered node's label font. If not specified, will heritate // the "font" value. hoverFont: '', // {boolean} If true, then only one node can be hovered at a time. singleHover: false, // {string} Example: 'bold' hoverFontStyle: '', // {string} Indicates how to choose the hovered nodes shadow color. // Available values: "node", "default" labelHoverShadow: 'default', // {string} labelHoverShadowColor: '#000', // {string} Indicates how to choose the hovered nodes color. // Available values: "node", "default" nodeHoverColor: 'node', // {string} defaultNodeHoverColor: '#000', // {string} Indicates how to choose the hovered nodes background color. // Available values: "node", "default" labelHoverBGColor: 'default', // {string} defaultHoverLabelBGColor: '#fff', // {string} Indicates how to choose the hovered labels color. // Available values: "node", "default" labelHoverColor: 'default', // {string} defaultLabelHoverColor: '#000', // {string} Indicates how to choose the edges hover color. Available values: // "edge", "default" edgeHoverColor: 'edge', // {number} The size multiplicator of hovered edges. edgeHoverSizeRatio: 1, // {string} defaultEdgeHoverColor: '#000', // {boolean} Indicates if the edge extremities must be hovered when the // edge is hovered. edgeHoverExtremities: false, // {booleans} The different drawing modes: // false: Layered not displayed. // true: Layered displayed. drawEdges: true, drawNodes: true, drawLabels: true, drawEdgeLabels: false, // {boolean} Indicates if the edges must be drawn in several frames or in // one frame, as the nodes and labels are drawn. batchEdgesDrawing: false, // {boolean} Indicates if the edges must be hidden during dragging and // animations. hideEdgesOnMove: false, // {numbers} The different batch sizes, when elements are displayed in // several frames. canvasEdgesBatchSize: 500, webglEdgesBatchSize: 1000, /** * RESCALE SETTINGS: * ***************** */ // {string} Indicates of to scale the graph relatively to its container. // Available values: "inside", "outside" scalingMode: 'inside', // {number} The margin to keep around the graph. sideMargin: 0, // {number} Determine the size of the smallest and the biggest node / edges // on the screen. This mapping makes easier to display the graph, // avoiding too big nodes that take half of the screen, or too // small ones that are not readable. If the two parameters are // equals, then the minimal display size will be 0. And if they // are both equal to 0, then there is no mapping, and the radius // of the nodes will be their size. minEdgeSize: 0.5, maxEdgeSize: 1, minNodeSize: 1, maxNodeSize: 8, /** * CAPTORS SETTINGS: * ***************** */ // {boolean} touchEnabled: true, // {boolean} mouseEnabled: true, // {boolean} mouseWheelEnabled: true, // {boolean} doubleClickEnabled: true, // {boolean} Defines whether the custom events such as "clickNode" can be // used. eventsEnabled: true, // {number} Defines by how much multiplicating the zooming level when the // user zooms with the mouse-wheel. zoomingRatio: 1.7, // {number} Defines by how much multiplicating the zooming level when the // user zooms by double clicking. doubleClickZoomingRatio: 2.2, // {number} The minimum zooming level. zoomMin: 0.0625, // {number} The maximum zooming level. zoomMax: 2, // {number} The duration of animations following a mouse scrolling. mouseZoomDuration: 200, // {number} The duration of animations following a mouse double click. doubleClickZoomDuration: 200, // {number} The duration of animations following a mouse dropping. mouseInertiaDuration: 200, // {number} The inertia power (mouse captor). mouseInertiaRatio: 3, // {number} The duration of animations following a touch dropping. touchInertiaDuration: 200, // {number} The inertia power (touch captor). touchInertiaRatio: 3, // {number} The maximum time between two clicks to make it a double click. doubleClickTimeout: 300, // {number} The maximum time between two taps to make it a double tap. doubleTapTimeout: 300, // {number} The maximum time of dragging to trigger intertia. dragTimeout: 200, /** * GLOBAL SETTINGS: * **************** */ // {boolean} Determines whether the instance has to refresh itself // automatically when a "resize" event is dispatched from the // window object. autoResize: true, // {boolean} Determines whether the "rescale" middleware has to be called // automatically for each camera on refresh. autoRescale: true, // {boolean} If set to false, the camera method "goTo" will basically do // nothing. enableCamera: true, // {boolean} If set to false, the nodes cannot be hovered. enableHovering: true, // {boolean} If set to true, the edges can be hovered. enableEdgeHovering: false, // {number} The size of the area around the edges to activate hovering. edgeHoverPrecision: 5, // {boolean} If set to true, the rescale middleware will ignore node sizes // to determine the graphs boundings. rescaleIgnoreSize: false, // {boolean} Determines if the core has to try to catch errors on // rendering. skipErrors: false, /** * CAMERA SETTINGS: * **************** */ // {number} The power degrees applied to the nodes/edges size relatively to // the zooming level. Basically: // > onScreenR = Math.pow(zoom, nodesPowRatio) * R // > onScreenT = Math.pow(zoom, edgesPowRatio) * T nodesPowRatio: 0.5, edgesPowRatio: 0.5, /** * ANIMATIONS SETTINGS: * ******************** */ // {number} The default animation time. animationsTime: 200 }; // Export the previously designed settings: sigma.settings = sigma.utils.extend(sigma.settings || {}, settings); }).call(this); ;(function() { 'use strict'; /** * Dispatcher constructor. * * @return {dispatcher} The new dispatcher instance. */ var dispatcher = function() { Object.defineProperty(this, '_handlers', { value: {} }); }; /** * Will execute the handler everytime that the indicated event (or the * indicated events) will be triggered. * * @param {string} events The name of the event (or the events * separated by spaces). * @param {function(Object)} handler The handler to bind. * @return {dispatcher} Returns the instance itself. */ dispatcher.prototype.bind = function(events, handler) { var i, l, event, eArray; if ( arguments.length === 1 && typeof arguments[0] === 'object' ) for (events in arguments[0]) this.bind(events, arguments[0][events]); else if ( arguments.length === 2 && typeof arguments[1] === 'function' ) { eArray = typeof events === 'string' ? events.split(' ') : events; for (i = 0, l = eArray.length; i !== l; i += 1) { event = eArray[i]; // Check that event is not '': if (!event) continue; if (!this._handlers[event]) this._handlers[event] = []; // Using an object instead of directly the handler will make possible // later to add flags this._handlers[event].push({ handler: handler }); } } else throw 'bind: Wrong arguments.'; return this; }; /** * Removes the handler from a specified event (or specified events). * * @param {?string} events The name of the event (or the events * separated by spaces). If undefined, * then all handlers are removed. * @param {?function(object)} handler The handler to unbind. If undefined, * each handler bound to the event or the * events will be removed. * @return {dispatcher} Returns the instance itself. */ dispatcher.prototype.unbind = function(events, handler) { var i, n, j, m, k, a, event, eArray = typeof events === 'string' ? events.split(' ') : events; if (!arguments.length) { for (k in this._handlers) delete this._handlers[k]; return this; } if (handler) { for (i = 0, n = eArray.length; i !== n; i += 1) { event = eArray[i]; if (this._handlers[event]) { a = []; for (j = 0, m = this._handlers[event].length; j !== m; j += 1) if (this._handlers[event][j].handler !== handler) a.push(this._handlers[event][j]); this._handlers[event] = a; } if (this._handlers[event] && this._handlers[event].length === 0) delete this._handlers[event]; } } else for (i = 0, n = eArray.length; i !== n; i += 1) delete this._handlers[eArray[i]]; return this; }; /** * Executes each handler bound to the event * * @param {string} events The name of the event (or the events separated * by spaces). * @param {?object} data The content of the event (optional). * @return {dispatcher} Returns the instance itself. */ dispatcher.prototype.dispatchEvent = function(events, data) { var i, n, j, m, a, event, eventName, self = this, eArray = typeof events === 'string' ? events.split(' ') : events; data = data === undefined ? {} : data; for (i = 0, n = eArray.length; i !== n; i += 1) { eventName = eArray[i]; if (this._handlers[eventName]) { event = self.getEvent(eventName, data); a = []; for (j = 0, m = this._handlers[eventName].length; j !== m; j += 1) { this._handlers[eventName][j].handler(event); if (!this._handlers[eventName][j].one) a.push(this._handlers[eventName][j]); } this._handlers[eventName] = a; } } return this; }; /** * Return an event object. * * @param {string} events The name of the event. * @param {?object} data The content of the event (optional). * @return {object} Returns the instance itself. */ dispatcher.prototype.getEvent = function(event, data) { return { type: event, data: data || {}, target: this }; }; /** * A useful function to deal with inheritance. It will make the target * inherit the prototype of the class dispatcher as well as its constructor. * * @param {object} target The target. */ dispatcher.extend = function(target, args) { var k; for (k in dispatcher.prototype) if (dispatcher.prototype.hasOwnProperty(k)) target[k] = dispatcher.prototype[k]; dispatcher.apply(target, args); }; /** * EXPORT: * ******* */ if (typeof this.sigma !== 'undefined') { this.sigma.classes = this.sigma.classes || {}; this.sigma.classes.dispatcher = dispatcher; } else if (typeof exports !== 'undefined') { if (typeof module !== 'undefined' && module.exports) exports = module.exports = dispatcher; exports.dispatcher = dispatcher; } else this.dispatcher = dispatcher; }).call(this); ;(function() { 'use strict'; /** * This utils aims to facilitate the manipulation of each instance setting. * Using a function instead of an object brings two main advantages: First, * it will be easier in the future to catch settings updates through a * function than an object. Second, giving it a full object will "merge" it * to the settings object properly, keeping us to have to always add a loop. * * @return {configurable} The "settings" function. */ var configurable = function() { var i, l, data = {}, datas = Array.prototype.slice.call(arguments, 0); /** * The method to use to set or get any property of this instance. * * @param {string|object} a1 If it is a string and if a2 is undefined, * then it will return the corresponding * property. If it is a string and if a2 is * set, then it will set a2 as the property * corresponding to a1, and return this. If * it is an object, then each pair string + * object(or any other type) will be set as a * property. * @param {*?} a2 The new property corresponding to a1 if a1 * is a string. * @return {*|configurable} Returns itself or the corresponding * property. * * Polymorphism: * ************* * Here are some basic use examples: * * > settings = new configurable(); * > settings('mySetting', 42); * > settings('mySetting'); // Logs: 42 * > settings('mySetting', 123); * > settings('mySetting'); // Logs: 123 * > settings({mySetting: 456}); * > settings('mySetting'); // Logs: 456 * * Also, it is possible to use the function as a fallback: * > settings({mySetting: 'abc'}, 'mySetting'); // Logs: 'abc' * > settings({hisSetting: 'abc'}, 'mySetting'); // Logs: 456 */ var settings = function(a1, a2) { var o, k; if (arguments.length === 1 && typeof a1 === 'string') { if ((a1 in data) && data[a1] !== undefined) return data[a1]; for (i = 0, l = datas.length; i < l; i++) if ((a1 in datas[i]) && datas[i][a1] !== undefined) return datas[i][a1]; return undefined; } else if (typeof a1 === 'object' && typeof a2 === 'string') { return a2 in (a1 || {}) ? a1[a2] : settings(a2); } else { o = (typeof a1 === 'object' && a2 === undefined) ? a1 : {}; if (typeof a1 === 'string') o[a1] = a2; for (k in o) data[k] = o[k]; return this; } }; /** * This method returns a new configurable function, with new objects * * @param {object*} Any number of objects to search in. * @return {function} Returns the function. Check its documentation to know * more about how it works. */ settings.embedObjects = function() { var args = datas.concat( data ).concat( Array.prototype.splice.call(arguments, 0) ); return configurable.apply({}, args); }; // Initialize for (i = 0, l = arguments.length; i < l; i++) settings(arguments[i]); return settings; }; /** * EXPORT: * ******* */ if (typeof this.sigma !== 'undefined') { this.sigma.classes = this.sigma.classes || {}; this.sigma.classes.configurable = configurable; } else if (typeof exports !== 'undefined') { if (typeof module !== 'undefined' && module.exports) exports = module.exports = configurable; exports.configurable = configurable; } else this.configurable = configurable; }).call(this); ;(function(undefined) { 'use strict'; var _methods = Object.create(null), _indexes = Object.create(null), _initBindings = Object.create(null), _methodBindings = Object.create(null), _methodBeforeBindings = Object.create(null), _defaultSettings = { immutable: true, clone: true }, _defaultSettingsFunction = function(key) { return _defaultSettings[key]; }; /** * The graph constructor. It initializes the data and the indexes, and binds * the custom indexes and methods to its own scope. * * Recognized parameters: * ********************** * Here is the exhaustive list of every accepted parameters in the settings * object: * * {boolean} clone Indicates if the data have to be cloned in methods * to add nodes or edges. * {boolean} immutable Indicates if nodes "id" values and edges "id", * "source" and "target" values must be set as * immutable. * * @param {?configurable} settings Eventually a settings function. * @return {graph} The new graph instance. */ var graph = function(settings) { var k, fn, data; /** * DATA: * ***** * Every data that is callable from graph methods are stored in this "data" * object. This object will be served as context for all these methods, * and it is possible to add other type of data in it. */ data = { /** * SETTINGS FUNCTION: * ****************** */ settings: settings || _defaultSettingsFunction, /** * MAIN DATA: * ********** */ nodesArray: [], edgesArray: [], /** * GLOBAL INDEXES: * *************** * These indexes just index data by ids. */ nodesIndex: Object.create(null), edgesIndex: Object.create(null), /** * LOCAL INDEXES: * ************** * These indexes refer from node to nodes. Each key is an id, and each * value is the array of the ids of related nodes. */ inNeighborsCount: Object.create(null), outNeighborsCount: Object.create(null), allNeighborsCount: Object.create(null) }; // Execute bindings: for (k in _initBindings) _initBindings[k].call(data); // Add methods to both the scope and the data objects: for (k in _methods) { fn = __bindGraphMethod(k, data, _methods[k]); this[k] = fn; data[k] = fn; } }; /** * A custom tool to bind methods such that function that are bound to it will * be executed anytime the method is called. * * @param {string} methodName The name of the method to bind. * @param {object} scope The scope where the method must be executed. * @param {function} fn The method itself. * @return {function} The new method. */ function __bindGraphMethod(methodName, scope, fn) { var result = function() { var k, res; // Execute "before" bound functions: for (k in _methodBeforeBindings[methodName]) _methodBeforeBindings[methodName][k].apply(scope, arguments); // Apply the method: res = fn.apply(scope, arguments); // Execute bound functions: for (k in _methodBindings[methodName]) _methodBindings[methodName][k].apply(scope, arguments); // Return res: return res; }; return result; } /** * This custom tool function removes every pair key/value from an hash. The * goal is to avoid creating a new object while some other references are * still hanging in some scopes... * * @param {object} obj The object to empty. * @return {object} The empty object. */ sigma.utils.emptyObject = function(obj) { var k; for (k in obj) if (!('hasOwnProperty' in obj) || obj.hasOwnProperty(k)) delete obj[k]; return obj; }; /** * This global method adds a method that will be bound to the futurly created * graph instances. * * Since these methods will be bound to their scope when the instances are * created, it does not use the prototype. Because of that, methods have to * be added before instances are created to make them available. * * Here is an example: * * > graph.addMethod('getNodesCount', function() { * > return this.nodesArray.length; * > }); * > * > var myGraph = new graph(); * > console.log(myGraph.getNodesCount()); // outputs 0 * * @param {string} methodName The name of the method. * @param {function} fn The method itself. * @return {object} The global graph constructor. */ graph.addMethod = function(methodName, fn) { if ( typeof methodName !== 'string' || typeof fn !== 'function' || arguments.length !== 2 ) throw 'addMethod: Wrong arguments.'; if (_methods[methodName] || graph[methodName]) throw 'The method "' + methodName + '" already exists.'; _methods[methodName] = fn; _methodBindings[methodName] = Object.create(null); _methodBeforeBindings[methodName] = Object.create(null); return this; }; /** * This global method returns true if the method has already been added, and * false else. * * Here are some examples: * * > graph.hasMethod('addNode'); // returns true * > graph.hasMethod('hasMethod'); // returns true * > graph.hasMethod('unexistingMethod'); // returns false * * @param {string} methodName The name of the method. * @return {boolean} The result. */ graph.hasMethod = function(methodName) { return !!(_methods[methodName] || graph[methodName]); }; /** * This global methods attaches a function to a method. Anytime the specified * method is called, the attached function is called right after, with the * same arguments and in the same scope. The attached function is called * right before if the last argument is true, unless the method is the graph * constructor. * * To attach a function to the graph constructor, use 'constructor' as the * method name (first argument). * * The main idea is to have a clean way to keep custom indexes up to date, * for instance: * * > var timesAddNodeCalled = 0; * > graph.attach('addNode', 'timesAddNodeCalledInc', function() { * > timesAddNodeCalled++; * > }); * > * > var myGraph = new graph(); * > console.log(timesAddNodeCalled); // outputs 0 * > * > myGraph.addNode({ id: '1' }).addNode({ id: '2' }); * > console.log(timesAddNodeCalled); // outputs 2 * * The idea for calling a function before is to provide pre-processors, for * instance: * * > var colorPalette = { Person: '#C3CBE1', Place: '#9BDEBD' }; * > graph.attach('addNode', 'applyNodeColorPalette', function(n) { * > n.color = colorPalette[n.category]; * > }, true); * > * > var myGraph = new graph(); * > myGraph.addNode({ id: 'n0', category: 'Person' }); * > console.log(myGraph.nodes('n0').color); // outputs '#C3CBE1' * * @param {string} methodName The name of the related method or * "constructor". * @param {string} key The key to identify the function to attach. * @param {function} fn The function to bind. * @param {boolean} before If true the function is called right before. * @return {object} The global graph constructor. */ graph.attach = function(methodName, key, fn, before) { if ( typeof methodName !== 'string' || typeof key !== 'string' || typeof fn !== 'function' || arguments.length < 3 || arguments.length > 4 ) throw 'attach: Wrong arguments.'; var bindings; if (methodName === 'constructor') bindings = _initBindings; else { if (before) { if (!_methodBeforeBindings[methodName]) throw 'The method "' + methodName + '" does not exist.'; bindings = _methodBeforeBindings[methodName]; } else { if (!_methodBindings[methodName]) throw 'The method "' + methodName + '" does not exist.'; bindings = _methodBindings[methodName]; } } if (bindings[key]) throw 'A function "' + key + '" is already attached ' + 'to the method "' + methodName + '".'; bindings[key] = fn; return this; }; /** * Alias of attach(methodName, key, fn, true). */ graph.attachBefore = function(methodName, key, fn) { return this.attach(methodName, key, fn, true); }; /** * This methods is just an helper to deal with custom indexes. It takes as * arguments the name of the index and an object containing all the different * functions to bind to the methods. * * Here is a basic example, that creates an index to keep the number of nodes * in the current graph. It also adds a method to provide a getter on that * new index: * * > sigma.classes.graph.addIndex('nodesCount', { * > constructor: function() { * > this.nodesCount = 0; * > }, * > addNode: function() { * > this.nodesCount++; * > }, * > dropNode: function() { * > this.nodesCount--; * > } * > }); * > * > sigma.classes.graph.addMethod('getNodesCount', function() { * > return this.nodesCount; * > }); * > * > var myGraph = new sigma.classes.graph(); * > console.log(myGraph.getNodesCount()); // outputs 0 * > * > myGraph.addNode({ id: '1' }).addNode({ id: '2' }); * > console.log(myGraph.getNodesCount()); // outputs 2 * * @param {string} name The name of the index. * @param {object} bindings The object containing the functions to bind. * @return {object} The global graph constructor. */ graph.addIndex = function(name, bindings) { if ( typeof name !== 'string' || Object(bindings) !== bindings || arguments.length !== 2 ) throw 'addIndex: Wrong arguments.'; if (_indexes[name]) throw 'The index "' + name + '" already exists.'; var k; // Store the bindings: _indexes[name] = bindings; // Attach the bindings: for (k in bindings) if (typeof bindings[k] === 'object') graph.attach(k, name, bindings[k].fn, bindings[k].before); else if (typeof bindings[k] === 'function') graph.attach(k, name, bindings[k]); else throw 'The bindings must be functions.'; return this; }; /** * This method adds a node to the graph. The node must be an object, with a * string under the key "id". Except for this, it is possible to add any * other attribute, that will be preserved all along the manipulations. * * If the graph option "clone" has a truthy value, the node will be cloned * when added to the graph. Also, if the graph option "immutable" has a * truthy value, its id will be defined as immutable. * * @param {object} node The node to add. * @return {object} The graph instance. */ graph.addMethod('addNode', function(node) { // Check that the node is an object and has an id: if (Object(node) !== node || arguments.length !== 1) throw 'addNode: Wrong arguments.'; if (typeof node.id !== 'string' && typeof node.id !== 'number') throw 'The node must have a string or number id.'; if (this.nodesIndex[node.id]) throw 'The node "' + node.id + '" already exists.'; var k, id = node.id, validNode = Object.create(null); // Check the "clone" option: if (this.settings('clone')) { for (k in node) if (k !== 'id') validNode[k] = node[k]; } else validNode = node; // Check the "immutable" option: if (this.settings('immutable')) Object.defineProperty(validNode, 'id', { value: id, enumerable: true }); else validNode.id = id; // Reinitialize counts: this.inNeighborsCount[id] = 0; this.outNeighborsCount[id] = 0; this.allNeighborsCount[id] = 0; // Add the node to indexes: this.nodesArray.push(validNode); this.nodesIndex[validNode.id] = validNode; // Return the current instance: return this; }); /** * This method adds an edge to the graph. The edge must be an object, with a * string under the key "id", and strings under the keys "source" and * "target" that design existing nodes. Except for this, it is possible to * add any other attribute, that will be preserved all along the * manipulations. * * If the graph option "clone" has a truthy value, the edge will be cloned * when added to the graph. Also, if the graph option "immutable" has a * truthy value, its id, source and target will be defined as immutable. * * @param {object} edge The edge to add. * @return {object} The graph instance. */ graph.addMethod('addEdge', function(edge) { // Check that the edge is an object and has an id: if (Object(edge) !== edge || arguments.length !== 1) throw 'addEdge: Wrong arguments.'; if (typeof edge.id !== 'string' && typeof edge.id !== 'number') throw 'The edge must have a string or number id.'; if ((typeof edge.source !== 'string' && typeof edge.source !== 'number') || !this.nodesIndex[edge.source]) throw 'The edge source must have an existing node id.'; if ((typeof edge.target !== 'string' && typeof edge.target !== 'number') || !this.nodesIndex[edge.target]) throw 'The edge target must have an existing node id.'; if (this.edgesIndex[edge.id]) throw 'The edge "' + edge.id + '" already exists.'; var k, validEdge = Object.create(null); // Check the "clone" option: if (this.settings('clone')) { for (k in edge) if (k !== 'id' && k !== 'source' && k !== 'target') validEdge[k] = edge[k]; } else validEdge = edge; // Check the "immutable" option: if (this.settings('immutable')) { Object.defineProperty(validEdge, 'id', { value: edge.id, enumerable: true }); Object.defineProperty(validEdge, 'source', { value: edge.source, enumerable: true }); Object.defineProperty(validEdge, 'target', { value: edge.target, enumerable: true }); } else { validEdge.id = edge.id; validEdge.source = edge.source; validEdge.target = edge.target; } // Add the edge to indexes: this.edgesArray.push(validEdge); this.edgesIndex[validEdge.id] = validEdge; // Keep counts up to date: this.inNeighborsCount[validEdge.target]++; this.outNeighborsCount[validEdge.source]++; this.allNeighborsCount[validEdge.target]++; this.allNeighborsCount[validEdge.source]++; return this; }); /** * This method drops a node from the graph. It also removes each edge that is * bound to it, through the dropEdge method. An error is thrown if the node * does not exist. * * @param {string} id The node id. * @return {object} The graph instance. */ graph.addMethod('dropNode', function(id) { // Check that the arguments are valid: if ((typeof id !== 'string' && typeof id !== 'number') || arguments.length !== 1) throw 'dropNode: Wrong arguments.'; if (!this.nodesIndex[id]) throw 'The node "' + id + '" does not exist.'; var i, k, l; // Remove the node from indexes: delete this.nodesIndex[id]; for (i = 0, l = this.nodesArray.length; i < l; i++) if (this.nodesArray[i].id === id) { this.nodesArray.splice(i, 1); break; } // Remove related edges: for (i = this.edgesArray.length - 1; i >= 0; i--) if (this.edgesArray[i].source === id || this.edgesArray[i].target === id) this.dropEdge(this.edgesArray[i].id); // Remove related edge indexes: delete this.inNeighborsCount[id]; delete this.outNeighborsCount[id]; delete this.allNeighborsCount[id]; return this; }); /** * This method drops an edge from the graph. An error is thrown if the edge * does not exist. * * @param {string} id The edge id. * @return {object} The graph instance. */ graph.addMethod('dropEdge', function(id) { // Check that the arguments are valid: if ((typeof id !== 'string' && typeof id !== 'number') || arguments.length !== 1) throw 'dropEdge: Wrong arguments.'; if (!this.edgesIndex[id]) throw 'The edge "' + id + '" does not exist.'; var i, l, edge; // Remove the edge from indexes: edge = this.edgesIndex[id]; delete this.edgesIndex[id]; for (i = 0, l = this.edgesArray.length; i < l; i++) if (this.edgesArray[i].id === id) { this.edgesArray.splice(i, 1); break; } this.inNeighborsCount[edge.target]--; this.outNeighborsCount[edge.source]--; this.allNeighborsCount[edge.source]--; this.allNeighborsCount[edge.target]--; return this; }); /** * This method destroys the current instance. It basically empties each index * and methods attached to the graph. */ graph.addMethod('kill', function() { // Delete arrays: this.nodesArray.length = 0; this.edgesArray.length = 0; delete this.nodesArray; delete this.edgesArray; // Delete indexes: delete this.nodesIndex; delete this.edgesIndex; delete this.inNeighborsCount; delete this.outNeighborsCount; delete this.allNeighborsCount; }); /** * This method empties the nodes and edges arrays, as well as the different * indexes. * * @return {object} The graph instance. */ graph.addMethod('clear', function() { this.nodesArray.length = 0; this.edgesArray.length = 0; // Due to GC issues, I prefer not to create new object. These objects are // only available from the methods and attached functions, but still, it is // better to prevent ghost references to unrelevant data... sigma.utils.emptyObject(this.nodesIndex); sigma.utils.emptyObject(this.edgesIndex); sigma.utils.emptyObject(this.nodesIndex); sigma.utils.emptyObject(this.inNeighborsCount); sigma.utils.emptyObject(this.outNeighborsCount); sigma.utils.emptyObject(this.allNeighborsCount); return this; }); /** * This method reads an object and adds the nodes and edges, through the * proper methods "addNode" and "addEdge". * * Here is an example: * * > var myGraph = new graph(); * > myGraph.read({ * > nodes: [ * > { id: 'n0' }, * > { id: 'n1' } * > ], * > edges: [ * > { * > id: 'e0', * > source: 'n0', * > target: 'n1' * > } * > ] * > }); * > * > console.log( * > myGraph.nodes().length, * > myGraph.edges().length * > ); // outputs 2 1 * * @param {object} g The graph object. * @return {object} The graph instance. */ graph.addMethod('read', function(g) { var i, a, l; a = g.nodes || []; for (i = 0, l = a.length; i < l; i++) this.addNode(a[i]); a = g.edges || []; for (i = 0, l = a.length; i < l; i++) this.addEdge(a[i]); return this; }); /** * This methods returns one or several nodes, depending on how it is called. * * To get the array of nodes, call "nodes" without argument. To get a * specific node, call it with the id of the node. The get multiple node, * call it with an array of ids, and it will return the array of nodes, in * the same order. * * @param {?(string|array)} v Eventually one id, an array of ids. * @return {object|array} The related node or array of nodes. */ graph.addMethod('nodes', function(v) { // Clone the array of nodes and return it: if (!arguments.length) return this.nodesArray.slice(0); // Return the related node: if (arguments.length === 1 && (typeof v === 'string' || typeof v === 'number')) return this.nodesIndex[v]; // Return an array of the related node: if ( arguments.length === 1 && Object.prototype.toString.call(v) === '[object Array]' ) { var i, l, a = []; for (i = 0, l = v.length; i < l; i++) if (typeof v[i] === 'string' || typeof v[i] === 'number') a.push(this.nodesIndex[v[i]]); else throw 'nodes: Wrong arguments.'; return a; } throw 'nodes: Wrong arguments.'; }); /** * This methods returns the degree of one or several nodes, depending on how * it is called. It is also possible to get incoming or outcoming degrees * instead by specifying 'in' or 'out' as a second argument. * * @param {string|array} v One id, an array of ids. * @param {?string} which Which degree is required. Values are 'in', * 'out', and by default the normal degree. * @return {number|array} The related degree or array of degrees. */ graph.addMethod('degree', function(v, which) { // Check which degree is required: which = { 'in': this.inNeighborsCount, 'out': this.outNeighborsCount }[which || ''] || this.allNeighborsCount; // Return the related node: if (typeof v === 'string' || typeof v === 'number') return which[v]; // Return an array of the related node: if (Object.prototype.toString.call(v) === '[object Array]') { var i, l, a = []; for (i = 0, l = v.length; i < l; i++) if (typeof v[i] === 'string' || typeof v[i] === 'number') a.push(which[v[i]]); else throw 'degree: Wrong arguments.'; return a; } throw 'degree: Wrong arguments.'; }); /** * This methods returns one or several edges, depending on how it is called. * * To get the array of edges, call "edges" without argument. To get a * specific edge, call it with the id of the edge. The get multiple edge, * call it with an array of ids, and it will return the array of edges, in * the same order. * * @param {?(string|array)} v Eventually one id, an array of ids. * @return {object|array} The related edge or array of edges. */ graph.addMethod('edges', function(v) { // Clone the array of edges and return it: if (!arguments.length) return this.edgesArray.slice(0); // Return the related edge: if (arguments.length === 1 && (typeof v === 'string' || typeof v === 'number')) return this.edgesIndex[v]; // Return an array of the related edge: if ( arguments.length === 1 && Object.prototype.toString.call(v) === '[object Array]' ) { var i, l, a = []; for (i = 0, l = v.length; i < l; i++) if (typeof v[i] === 'string' || typeof v[i] === 'number') a.push(this.edgesIndex[v[i]]); else throw 'edges: Wrong arguments.'; return a; } throw 'edges: Wrong arguments.'; }); /** * EXPORT: * ******* */ if (typeof sigma !== 'undefined') { sigma.classes = sigma.classes || Object.create(null); sigma.classes.graph = graph; } else if (typeof exports !== 'undefined') { if (typeof module !== 'undefined' && module.exports) exports = module.exports = graph; exports.graph = graph; } else this.graph = graph; }).call(this); ;(function(undefined) { 'use strict'; if (typeof sigma === 'undefined') throw 'sigma is not declared'; sigma.utils.pkg('sigma.classes'); /** * The camera constructor. It just initializes its attributes and methods. * * @param {string} id The id. * @param {sigma.classes.graph} graph The graph. * @param {configurable} settings The settings function. * @param {?object} options Eventually some overriding options. * @return {camera} Returns the fresh new camera instance. */ sigma.classes.camera = function(id, graph, settings, options) { sigma.classes.dispatcher.extend(this); Object.defineProperty(this, 'graph', { value: graph }); Object.defineProperty(this, 'id', { value: id }); Object.defineProperty(this, 'readPrefix', { value: 'read_cam' + id + ':' }); Object.defineProperty(this, 'prefix', { value: 'cam' + id + ':' }); this.x = 0; this.y = 0; this.ratio = 1; this.angle = 0; this.isAnimated = false; this.settings = (typeof options === 'object' && options) ? settings.embedObject(options) : settings; }; /** * Updates the camera position. * * @param {object} coordinates The new coordinates object. * @return {camera} Returns the camera. */ sigma.classes.camera.prototype.goTo = function(coordinates) { if (!this.settings('enableCamera')) return this; var i, l, c = coordinates || {}, keys = ['x', 'y', 'ratio', 'angle']; for (i = 0, l = keys.length; i < l; i++) if (c[keys[i]] !== undefined) { if (typeof c[keys[i]] === 'number' && !isNaN(c[keys[i]])) this[keys[i]] = c[keys[i]]; else throw 'Value for "' + keys[i] + '" is not a number.'; } this.dispatchEvent('coordinatesUpdated'); return this; }; /** * This method takes a graph and computes for each node and edges its * coordinates relatively to the center of the camera. Basically, it will * compute the coordinates that will be used by the graphic renderers. * * Since it should be possible to use different cameras and different * renderers, it is possible to specify a prefix to put before the new * coordinates (to get something like "node.camera1_x") * * @param {?string} read The prefix of the coordinates to read. * @param {?string} write The prefix of the coordinates to write. * @param {?object} options Eventually an object of options. Those can be: * - A restricted nodes array. * - A restricted edges array. * - A width. * - A height. * @return {camera} Returns the camera. */ sigma.classes.camera.prototype.applyView = function(read, write, options) { options = options || {}; write = write !== undefined ? write : this.prefix; read = read !== undefined ? read : this.readPrefix; var nodes = options.nodes || this.graph.nodes(), edges = options.edges || this.graph.edges(); var i, l, node, cos = Math.cos(this.angle), sin = Math.sin(this.angle); for (i = 0, l = nodes.length; i < l; i++) { node = nodes[i]; node[write + 'x'] = ( ((node[read + 'x'] || 0) - this.x) * cos + ((node[read + 'y'] || 0) - this.y) * sin ) / this.ratio + (options.width || 0) / 2; node[write + 'y'] = ( ((node[read + 'y'] || 0) - this.y) * cos - ((node[read + 'x'] || 0) - this.x) * sin ) / this.ratio + (options.height || 0) / 2; node[write + 'size'] = (node[read + 'size'] || 0) / Math.pow(this.ratio, this.settings('nodesPowRatio')); } for (i = 0, l = edges.length; i < l; i++) { edges[i][write + 'size'] = (edges[i][read + 'size'] || 0) / Math.pow(this.ratio, this.settings('edgesPowRatio')); } return this; }; /** * This function converts the coordinates of a point from the frame of the * camera to the frame of the graph. * * @param {number} x The X coordinate of the point in the frame of the * camera. * @param {number} y The Y coordinate of the point in the frame of the * camera. * @return {object} The point coordinates in the frame of the graph. */ sigma.classes.camera.prototype.graphPosition = function(x, y, vector) { var X = 0, Y = 0, cos = Math.cos(this.angle), sin = Math.sin(this.angle); // Revert the origin differential vector: if (!vector) { X = - (this.x * cos + this.y * sin) / this.ratio; Y = - (this.y * cos - this.x * sin) / this.ratio; } return { x: (x * cos + y * sin) / this.ratio + X, y: (y * cos - x * sin) / this.ratio + Y }; }; /** * This function converts the coordinates of a point from the frame of the * graph to the frame of the camera. * * @param {number} x The X coordinate of the point in the frame of the * graph. * @param {number} y The Y coordinate of the point in the frame of the * graph. * @return {object} The point coordinates in the frame of the camera. */ sigma.classes.camera.prototype.cameraPosition = function(x, y, vector) { var X = 0, Y = 0, cos = Math.cos(this.angle), sin = Math.sin(this.angle); // Revert the origin differential vector: if (!vector) { X = - (this.x * cos + this.y * sin) / this.ratio; Y = - (this.y * cos - this.x * sin) / this.ratio; } return { x: ((x - X) * cos - (y - Y) * sin) * this.ratio, y: ((y - Y) * cos + (x - X) * sin) * this.ratio }; }; /** * This method returns the transformation matrix of the camera. This is * especially useful to apply the camera view directly in shaders, in case of * WebGL rendering. * * @return {array} The transformation matrix. */ sigma.classes.camera.prototype.getMatrix = function() { var scale = sigma.utils.matrices.scale(1 / this.ratio), rotation = sigma.utils.matrices.rotation(this.angle), translation = sigma.utils.matrices.translation(-this.x, -this.y), matrix = sigma.utils.matrices.multiply( translation, sigma.utils.matrices.multiply( rotation, scale ) ); return matrix; }; /** * Taking a width and a height as parameters, this method returns the * coordinates of the rectangle representing the camera on screen, in the * graph's referentiel. * * To keep displaying labels of nodes going out of the screen, the method * keeps a margin around the screen in the returned rectangle. * * @param {number} width The width of the screen. * @param {number} height The height of the screen. * @return {object} The rectangle as x1, y1, x2 and y2, representing * two opposite points. */ sigma.classes.camera.prototype.getRectangle = function(width, height) { var widthVect = this.cameraPosition(width, 0, true), heightVect = this.cameraPosition(0, height, true), centerVect = this.cameraPosition(width / 2, height / 2, true), marginX = this.cameraPosition(width / 4, 0, true).x, marginY = this.cameraPosition(0, height / 4, true).y; return { x1: this.x - centerVect.x - marginX, y1: this.y - centerVect.y - marginY, x2: this.x - centerVect.x + marginX + widthVect.x, y2: this.y - centerVect.y - marginY + widthVect.y, height: Math.sqrt( Math.pow(heightVect.x, 2) + Math.pow(heightVect.y + 2 * marginY, 2) ) }; }; }).call(this); ;(function(undefined) { 'use strict'; /** * Sigma Quadtree Module * ===================== * * Author: Guillaume Plique (Yomguithereal) * Version: 0.2 */ /** * Quad Geometric Operations * ------------------------- * * A useful batch of geometric operations used by the quadtree. */ var _geom = { /** * Transforms a graph node with x, y and size into an * axis-aligned square. * * @param {object} A graph node with at least a point (x, y) and a size. * @return {object} A square: two points (x1, y1), (x2, y2) and height. */ pointToSquare: function(n) { return { x1: n.x - n.size, y1: n.y - n.size, x2: n.x + n.size, y2: n.y - n.size, height: n.size * 2 }; }, /** * Checks whether a rectangle is axis-aligned. * * @param {object} A rectangle defined by two points * (x1, y1) and (x2, y2). * @return {boolean} True if the rectangle is axis-aligned. */ isAxisAligned: function(r) { return r.x1 === r.x2 || r.y1 === r.y2; }, /** * Compute top points of an axis-aligned rectangle. This is useful in * cases when the rectangle has been rotated (left, right or bottom up) and * later operations need to know the top points. * * @param {object} An axis-aligned rectangle defined by two points * (x1, y1), (x2, y2) and height. * @return {object} A rectangle: two points (x1, y1), (x2, y2) and height. */ axisAlignedTopPoints: function(r) { // Basic if (r.y1 === r.y2 && r.x1 < r.x2) return r; // Rotated to right if (r.x1 === r.x2 && r.y2 > r.y1) return { x1: r.x1 - r.height, y1: r.y1, x2: r.x1, y2: r.y1, height: r.height }; // Rotated to left if (r.x1 === r.x2 && r.y2 < r.y1) return { x1: r.x1, y1: r.y2, x2: r.x2 + r.height, y2: r.y2, height: r.height }; // Bottom's up return { x1: r.x2, y1: r.y1 - r.height, x2: r.x1, y2: r.y1 - r.height, height: r.height }; }, /** * Get coordinates of a rectangle's lower left corner from its top points. * * @param {object} A rectangle defined by two points (x1, y1) and (x2, y2). * @return {object} Coordinates of the corner (x, y). */ lowerLeftCoor: function(r) { var width = ( Math.sqrt( Math.pow(r.x2 - r.x1, 2) + Math.pow(r.y2 - r.y1, 2) ) ); return { x: r.x1 - (r.y2 - r.y1) * r.height / width, y: r.y1 + (r.x2 - r.x1) * r.height / width }; }, /** * Get coordinates of a rectangle's lower right corner from its top points * and its lower left corner. * * @param {object} A rectangle defined by two points (x1, y1) and (x2, y2). * @param {object} A corner's coordinates (x, y). * @return {object} Coordinates of the corner (x, y). */ lowerRightCoor: function(r, llc) { return { x: llc.x - r.x1 + r.x2, y: llc.y - r.y1 + r.y2 }; }, /** * Get the coordinates of all the corners of a rectangle from its top point. * * @param {object} A rectangle defined by two points (x1, y1) and (x2, y2). * @return {array} An array of the four corners' coordinates (x, y). */ rectangleCorners: function(r) { var llc = this.lowerLeftCoor(r), lrc = this.lowerRightCoor(r, llc); return [ {x: r.x1, y: r.y1}, {x: r.x2, y: r.y2}, {x: llc.x, y: llc.y}, {x: lrc.x, y: lrc.y} ]; }, /** * Split a square defined by its boundaries into four. * * @param {object} Boundaries of the square (x, y, width, height). * @return {array} An array containing the four new squares, themselves * defined by an array of their four corners (x, y). */ splitSquare: function(b) { return [ [ {x: b.x, y: b.y}, {x: b.x + b.width / 2, y: b.y}, {x: b.x, y: b.y + b.height / 2}, {x: b.x + b.width / 2, y: b.y + b.height / 2} ], [ {x: b.x + b.width / 2, y: b.y}, {x: b.x + b.width, y: b.y}, {x: b.x + b.width / 2, y: b.y + b.height / 2}, {x: b.x + b.width, y: b.y + b.height / 2} ], [ {x: b.x, y: b.y + b.height / 2}, {x: b.x + b.width / 2, y: b.y + b.height / 2}, {x: b.x, y: b.y + b.height}, {x: b.x + b.width / 2, y: b.y + b.height} ], [ {x: b.x + b.width / 2, y: b.y + b.height / 2}, {x: b.x + b.width, y: b.y + b.height / 2}, {x: b.x + b.width / 2, y: b.y + b.height}, {x: b.x + b.width, y: b.y + b.height} ] ]; }, /** * Compute the four axis between corners of rectangle A and corners of * rectangle B. This is needed later to check an eventual collision. * * @param {array} An array of rectangle A's four corners (x, y). * @param {array} An array of rectangle B's four corners (x, y). * @return {array} An array of four axis defined by their coordinates (x,y). */ axis: function(c1, c2) { return [ {x: c1[1].x - c1[0].x, y: c1[1].y - c1[0].y}, {x: c1[1].x - c1[3].x, y: c1[1].y - c1[3].y}, {x: c2[0].x - c2[2].x, y: c2[0].y - c2[2].y}, {x: c2[0].x - c2[1].x, y: c2[0].y - c2[1].y} ]; }, /** * Project a rectangle's corner on an axis. * * @param {object} Coordinates of a corner (x, y). * @param {object} Coordinates of an axis (x, y). * @return {object} The projection defined by coordinates (x, y). */ projection: function(c, a) { var l = ( (c.x * a.x + c.y * a.y) / (Math.pow(a.x, 2) + Math.pow(a.y, 2)) ); return { x: l * a.x, y: l * a.y }; }, /** * Check whether two rectangles collide on one particular axis. * * @param {object} An axis' coordinates (x, y). * @param {array} Rectangle A's corners. * @param {array} Rectangle B's corners. * @return {boolean} True if the rectangles collide on the axis. */ axisCollision: function(a, c1, c2) { var sc1 = [], sc2 = []; for (var ci = 0; ci < 4; ci++) { var p1 = this.projection(c1[ci], a), p2 = this.projection(c2[ci], a); sc1.push(p1.x * a.x + p1.y * a.y); sc2.push(p2.x * a.x + p2.y * a.y); } var maxc1 = Math.max.apply(Math, sc1), maxc2 = Math.max.apply(Math, sc2), minc1 = Math.min.apply(Math, sc1), minc2 = Math.min.apply(Math, sc2); return (minc2 <= maxc1 && maxc2 >= minc1); }, /** * Check whether two rectangles collide on each one of their four axis. If * all axis collide, then the two rectangles do collide on the plane. * * @param {array} Rectangle A's corners. * @param {array} Rectangle B's corners. * @return {boolean} True if the rectangles collide. */ collision: function(c1, c2) { var axis = this.axis(c1, c2), col = true; for (var i = 0; i < 4; i++) { col *= this.axisCollision(axis[i], c1, c2); } return !!col; } }; /** * Quad Functions * ------------ * * The Quadtree functions themselves. * For each of those functions, we consider that in a splitted quad, the * index of each node is the following: * 0: top left * 1: top right * 2: bottom left * 3: bottom right * * Moreover, the hereafter quad's philosophy is to consider that if an element * collides with more than one nodes, this element belongs to each of the * nodes it collides with where other would let it lie on a higher node. */ /** * Get the index of the node containing the point in the quad * * @param {object} point A point defined by coordinates (x, y). * @param {object} quadBounds Boundaries of the quad (x, y, width, heigth). * @return {integer} The index of the node containing the point. */ function _quadIndex(point, quadBounds) { var xmp = quadBounds.x + quadBounds.width / 2, ymp = quadBounds.y + quadBounds.height / 2, top = (point.y < ymp), left = (point.x < xmp); if (top) { if (left) return 0; else return 1; } else { if (left) return 2; else return 3; } } /** * Get a list of indexes of nodes containing an axis-aligned rectangle * * @param {object} rectangle A rectangle defined by two points (x1, y1), * (x2, y2) and height. * @param {array} quadCorners An array of the quad nodes' corners. * @return {array} An array of indexes containing one to * four integers. */ function _quadIndexes(rectangle, quadCorners) { var indexes = []; // Iterating through quads for (var i = 0; i < 4; i++) if ((rectangle.x2 >= quadCorners[i][0].x) && (rectangle.x1 <= quadCorners[i][1].x) && (rectangle.y1 + rectangle.height >= quadCorners[i][0].y) && (rectangle.y1 <= quadCorners[i][2].y)) indexes.push(i); return indexes; } /** * Get a list of indexes of nodes containing a non-axis-aligned rectangle * * @param {array} corners An array containing each corner of the * rectangle defined by its coordinates (x, y). * @param {array} quadCorners An array of the quad nodes' corners. * @return {array} An array of indexes containing one to * four integers. */ function _quadCollision(corners, quadCorners) { var indexes = []; // Iterating through quads for (var i = 0; i < 4; i++) if (_geom.collision(corners, quadCorners[i])) indexes.push(i); return indexes; } /** * Subdivide a quad by creating a node at a precise index. The function does * not generate all four nodes not to potentially create unused nodes. * * @param {integer} index The index of the node to create. * @param {object} quad The quad object to subdivide. * @return {object} A new quad representing the node created. */ function _quadSubdivide(index, quad) { var next = quad.level + 1, subw = Math.round(quad.bounds.width / 2), subh = Math.round(quad.bounds.height / 2), qx = Math.round(quad.bounds.x), qy = Math.round(quad.bounds.y), x, y; switch (index) { case 0: x = qx; y = qy; break; case 1: x = qx + subw; y = qy; break; case 2: x = qx; y = qy + subh; break; case 3: x = qx + subw; y = qy + subh; break; } return _quadTree( {x: x, y: y, width: subw, height: subh}, next, quad.maxElements, quad.maxLevel ); } /** * Recursively insert an element into the quadtree. Only points * with size, i.e. axis-aligned squares, may be inserted with this * method. * * @param {object} el The element to insert in the quadtree. * @param {object} sizedPoint A sized point defined by two top points * (x1, y1), (x2, y2) and height. * @param {object} quad The quad in which to insert the element. * @return {undefined} The function does not return anything. */ function _quadInsert(el, sizedPoint, quad) { if (quad.level < quad.maxLevel) { // Searching appropriate quads var indexes = _quadIndexes(sizedPoint, quad.corners); // Iterating for (var i = 0, l = indexes.length; i < l; i++) { // Subdividing if necessary if (quad.nodes[indexes[i]] === undefined) quad.nodes[indexes[i]] = _quadSubdivide(indexes[i], quad); // Recursion _quadInsert(el, sizedPoint, quad.nodes[indexes[i]]); } } else { // Pushing the element in a leaf node quad.elements.push(el); } } /** * Recursively retrieve every elements held by the node containing the * searched point. * * @param {object} point The searched point (x, y). * @param {object} quad The searched quad. * @return {array} An array of elements contained in the relevant * node. */ function _quadRetrievePoint(point, quad) { if (quad.level < quad.maxLevel) { var index = _quadIndex(point, quad.bounds); // If node does not exist we return an empty list if (quad.nodes[index] !== undefined) { return _quadRetrievePoint(point, quad.nodes[index]); } else { return []; } } else { return quad.elements; } } /** * Recursively retrieve every elements contained within an rectangular area * that may or may not be axis-aligned. * * @param {object|array} rectData The searched area defined either by * an array of four corners (x, y) in * the case of a non-axis-aligned * rectangle or an object with two top * points (x1, y1), (x2, y2) and height. * @param {object} quad The searched quad. * @param {function} collisionFunc The collision function used to search * for node indexes. * @param {array?} els The retrieved elements. * @return {array} An array of elements contained in the * area. */ function _quadRetrieveArea(rectData, quad, collisionFunc, els) { els = els || {}; if (quad.level < quad.maxLevel) { var indexes = collisionFunc(rectData, quad.corners); for (var i = 0, l = indexes.length; i < l; i++) if (quad.nodes[indexes[i]] !== undefined) _quadRetrieveArea( rectData, quad.nodes[indexes[i]], collisionFunc, els ); } else for (var j = 0, m = quad.elements.length; j < m; j++) if (els[quad.elements[j].id] === undefined) els[quad.elements[j].id] = quad.elements[j]; return els; } /** * Creates the quadtree object itself. * * @param {object} bounds The boundaries of the quad defined by an * origin (x, y), width and heigth. * @param {integer} level The level of the quad in the tree. * @param {integer} maxElements The max number of element in a leaf node. * @param {integer} maxLevel The max recursion level of the tree. * @return {object} The quadtree object. */ function _quadTree(bounds, level, maxElements, maxLevel) { return { level: level || 0, bounds: bounds, corners: _geom.splitSquare(bounds), maxElements: maxElements || 20, maxLevel: maxLevel || 4, elements: [], nodes: [] }; } /** * Sigma Quad Constructor * ---------------------- * * The quad API as exposed to sigma. */ /** * The quad core that will become the sigma interface with the quadtree. * * property {object} _tree Property holding the quadtree object. * property {object} _geom Exposition of the _geom namespace for testing. * property {object} _cache Cache for the area method. */ var quad = function() { this._geom = _geom; this._tree = null; this._cache = { query: false, result: false }; }; /** * Index a graph by inserting its nodes into the quadtree. * * @param {array} nodes An array of nodes to index. * @param {object} params An object of parameters with at least the quad * bounds. * @return {object} The quadtree object. * * Parameters: * ---------- * bounds: {object} boundaries of the quad defined by its origin (x, y) * width and heigth. * prefix: {string?} a prefix for node geometric attributes. * maxElements: {integer?} the max number of elements in a leaf node. * maxLevel: {integer?} the max recursion level of the tree. */ quad.prototype.index = function(nodes, params) { // Enforcing presence of boundaries if (!params.bounds) throw 'sigma.classes.quad.index: bounds information not given.'; // Prefix var prefix = params.prefix || ''; // Building the tree this._tree = _quadTree( params.bounds, 0, params.maxElements, params.maxLevel ); // Inserting graph nodes into the tree for (var i = 0, l = nodes.length; i < l; i++) { // Inserting node _quadInsert( nodes[i], _geom.pointToSquare({ x: nodes[i][prefix + 'x'], y: nodes[i][prefix + 'y'], size: nodes[i][prefix + 'size'] }), this._tree ); } // Reset cache: this._cache = { query: false, result: false }; // remove? return this._tree; }; /** * Retrieve every graph nodes held by the quadtree node containing the * searched point. * * @param {number} x of the point. * @param {number} y of the point. * @return {array} An array of nodes retrieved. */ quad.prototype.point = function(x, y) { return this._tree ? _quadRetrievePoint({x: x, y: y}, this._tree) || [] : []; }; /** * Retrieve every graph nodes within a rectangular area. The methods keep the * last area queried in cache for optimization reason and will act differently * for the same reason if the area is axis-aligned or not. * * @param {object} A rectangle defined by two top points (x1, y1), (x2, y2) * and height. * @return {array} An array of nodes retrieved. */ quad.prototype.area = function(rect) { var serialized = JSON.stringify(rect), collisionFunc, rectData; // Returning cache? if (this._cache.query === serialized) return this._cache.result; // Axis aligned ? if (_geom.isAxisAligned(rect)) { collisionFunc = _quadIndexes; rectData = _geom.axisAlignedTopPoints(rect); } else { collisionFunc = _quadCollision; rectData = _geom.rectangleCorners(rect); } // Retrieving nodes var nodes = this._tree ? _quadRetrieveArea( rectData, this._tree, collisionFunc ) : []; // Object to array var nodesArray = []; for (var i in nodes) nodesArray.push(nodes[i]); // Caching this._cache.query = serialized; this._cache.result = nodesArray; return nodesArray; }; /** * EXPORT: * ******* */ if (typeof this.sigma !== 'undefined') { this.sigma.classes = this.sigma.classes || {}; this.sigma.classes.quad = quad; } else if (typeof exports !== 'undefined') { if (typeof module !== 'undefined' && module.exports) exports = module.exports = quad; exports.quad = quad; } else this.quad = quad; }).call(this); ;(function(undefined) { 'use strict'; /** * Sigma Quadtree Module for edges * =============================== * * Author: Sébastien Heymann, * from the quad of Guillaume Plique (Yomguithereal) * Version: 0.2 */ /** * Quad Geometric Operations * ------------------------- * * A useful batch of geometric operations used by the quadtree. */ var _geom = { /** * Transforms a graph node with x, y and size into an * axis-aligned square. * * @param {object} A graph node with at least a point (x, y) and a size. * @return {object} A square: two points (x1, y1), (x2, y2) and height. */ pointToSquare: function(n) { return { x1: n.x - n.size, y1: n.y - n.size, x2: n.x + n.size, y2: n.y - n.size, height: n.size * 2 }; }, /** * Transforms a graph edge with x1, y1, x2, y2 and size into an * axis-aligned square. * * @param {object} A graph edge with at least two points * (x1, y1), (x2, y2) and a size. * @return {object} A square: two points (x1, y1), (x2, y2) and height. */ lineToSquare: function(e) { if (e.y1 < e.y2) { // (e.x1, e.y1) on top if (e.x1 < e.x2) { // (e.x1, e.y1) on left return { x1: e.x1 - e.size, y1: e.y1 - e.size, x2: e.x2 + e.size, y2: e.y1 - e.size, height: e.y2 - e.y1 + e.size * 2 }; } // (e.x1, e.y1) on right return { x1: e.x2 - e.size, y1: e.y1 - e.size, x2: e.x1 + e.size, y2: e.y1 - e.size, height: e.y2 - e.y1 + e.size * 2 }; } // (e.x2, e.y2) on top if (e.x1 < e.x2) { // (e.x1, e.y1) on left return { x1: e.x1 - e.size, y1: e.y2 - e.size, x2: e.x2 + e.size, y2: e.y2 - e.size, height: e.y1 - e.y2 + e.size * 2 }; } // (e.x2, e.y2) on right return { x1: e.x2 - e.size, y1: e.y2 - e.size, x2: e.x1 + e.size, y2: e.y2 - e.size, height: e.y1 - e.y2 + e.size * 2 }; }, /** * Transforms a graph edge of type 'curve' with x1, y1, x2, y2, * control point and size into an axis-aligned square. * * @param {object} e A graph edge with at least two points * (x1, y1), (x2, y2) and a size. * @param {object} cp A control point (x,y). * @return {object} A square: two points (x1, y1), (x2, y2) and height. */ quadraticCurveToSquare: function(e, cp) { var pt = sigma.utils.getPointOnQuadraticCurve( 0.5, e.x1, e.y1, e.x2, e.y2, cp.x, cp.y ); // Bounding box of the two points and the point at the middle of the // curve: var minX = Math.min(e.x1, e.x2, pt.x), maxX = Math.max(e.x1, e.x2, pt.x), minY = Math.min(e.y1, e.y2, pt.y), maxY = Math.max(e.y1, e.y2, pt.y); return { x1: minX - e.size, y1: minY - e.size, x2: maxX + e.size, y2: minY - e.size, height: maxY - minY + e.size * 2 }; }, /** * Transforms a graph self loop into an axis-aligned square. * * @param {object} n A graph node with a point (x, y) and a size. * @return {object} A square: two points (x1, y1), (x2, y2) and height. */ selfLoopToSquare: function(n) { // Fitting to the curve is too costly, we compute a larger bounding box // using the control points: var cp = sigma.utils.getSelfLoopControlPoints(n.x, n.y, n.size); // Bounding box of the point and the two control points: var minX = Math.min(n.x, cp.x1, cp.x2), maxX = Math.max(n.x, cp.x1, cp.x2), minY = Math.min(n.y, cp.y1, cp.y2), maxY = Math.max(n.y, cp.y1, cp.y2); return { x1: minX - n.size, y1: minY - n.size, x2: maxX + n.size, y2: minY - n.size, height: maxY - minY + n.size * 2 }; }, /** * Checks whether a rectangle is axis-aligned. * * @param {object} A rectangle defined by two points * (x1, y1) and (x2, y2). * @return {boolean} True if the rectangle is axis-aligned. */ isAxisAligned: function(r) { return r.x1 === r.x2 || r.y1 === r.y2; }, /** * Compute top points of an axis-aligned rectangle. This is useful in * cases when the rectangle has been rotated (left, right or bottom up) and * later operations need to know the top points. * * @param {object} An axis-aligned rectangle defined by two points * (x1, y1), (x2, y2) and height. * @return {object} A rectangle: two points (x1, y1), (x2, y2) and height. */ axisAlignedTopPoints: function(r) { // Basic if (r.y1 === r.y2 && r.x1 < r.x2) return r; // Rotated to right if (r.x1 === r.x2 && r.y2 > r.y1) return { x1: r.x1 - r.height, y1: r.y1, x2: r.x1, y2: r.y1, height: r.height }; // Rotated to left if (r.x1 === r.x2 && r.y2 < r.y1) return { x1: r.x1, y1: r.y2, x2: r.x2 + r.height, y2: r.y2, height: r.height }; // Bottom's up return { x1: r.x2, y1: r.y1 - r.height, x2: r.x1, y2: r.y1 - r.height, height: r.height }; }, /** * Get coordinates of a rectangle's lower left corner from its top points. * * @param {object} A rectangle defined by two points (x1, y1) and (x2, y2). * @return {object} Coordinates of the corner (x, y). */ lowerLeftCoor: function(r) { var width = ( Math.sqrt( Math.pow(r.x2 - r.x1, 2) + Math.pow(r.y2 - r.y1, 2) ) ); return { x: r.x1 - (r.y2 - r.y1) * r.height / width, y: r.y1 + (r.x2 - r.x1) * r.height / width }; }, /** * Get coordinates of a rectangle's lower right corner from its top points * and its lower left corner. * * @param {object} A rectangle defined by two points (x1, y1) and (x2, y2). * @param {object} A corner's coordinates (x, y). * @return {object} Coordinates of the corner (x, y). */ lowerRightCoor: function(r, llc) { return { x: llc.x - r.x1 + r.x2, y: llc.y - r.y1 + r.y2 }; }, /** * Get the coordinates of all the corners of a rectangle from its top point. * * @param {object} A rectangle defined by two points (x1, y1) and (x2, y2). * @return {array} An array of the four corners' coordinates (x, y). */ rectangleCorners: function(r) { var llc = this.lowerLeftCoor(r), lrc = this.lowerRightCoor(r, llc); return [ {x: r.x1, y: r.y1}, {x: r.x2, y: r.y2}, {x: llc.x, y: llc.y}, {x: lrc.x, y: lrc.y} ]; }, /** * Split a square defined by its boundaries into four. * * @param {object} Boundaries of the square (x, y, width, height). * @return {array} An array containing the four new squares, themselves * defined by an array of their four corners (x, y). */ splitSquare: function(b) { return [ [ {x: b.x, y: b.y}, {x: b.x + b.width / 2, y: b.y}, {x: b.x, y: b.y + b.height / 2}, {x: b.x + b.width / 2, y: b.y + b.height / 2} ], [ {x: b.x + b.width / 2, y: b.y}, {x: b.x + b.width, y: b.y}, {x: b.x + b.width / 2, y: b.y + b.height / 2}, {x: b.x + b.width, y: b.y + b.height / 2} ], [ {x: b.x, y: b.y + b.height / 2}, {x: b.x + b.width / 2, y: b.y + b.height / 2}, {x: b.x, y: b.y + b.height}, {x: b.x + b.width / 2, y: b.y + b.height} ], [ {x: b.x + b.width / 2, y: b.y + b.height / 2}, {x: b.x + b.width, y: b.y + b.height / 2}, {x: b.x + b.width / 2, y: b.y + b.height}, {x: b.x + b.width, y: b.y + b.height} ] ]; }, /** * Compute the four axis between corners of rectangle A and corners of * rectangle B. This is needed later to check an eventual collision. * * @param {array} An array of rectangle A's four corners (x, y). * @param {array} An array of rectangle B's four corners (x, y). * @return {array} An array of four axis defined by their coordinates (x,y). */ axis: function(c1, c2) { return [ {x: c1[1].x - c1[0].x, y: c1[1].y - c1[0].y}, {x: c1[1].x - c1[3].x, y: c1[1].y - c1[3].y}, {x: c2[0].x - c2[2].x, y: c2[0].y - c2[2].y}, {x: c2[0].x - c2[1].x, y: c2[0].y - c2[1].y} ]; }, /** * Project a rectangle's corner on an axis. * * @param {object} Coordinates of a corner (x, y). * @param {object} Coordinates of an axis (x, y). * @return {object} The projection defined by coordinates (x, y). */ projection: function(c, a) { var l = ( (c.x * a.x + c.y * a.y) / (Math.pow(a.x, 2) + Math.pow(a.y, 2)) ); return { x: l * a.x, y: l * a.y }; }, /** * Check whether two rectangles collide on one particular axis. * * @param {object} An axis' coordinates (x, y). * @param {array} Rectangle A's corners. * @param {array} Rectangle B's corners. * @return {boolean} True if the rectangles collide on the axis. */ axisCollision: function(a, c1, c2) { var sc1 = [], sc2 = []; for (var ci = 0; ci < 4; ci++) { var p1 = this.projection(c1[ci], a), p2 = this.projection(c2[ci], a); sc1.push(p1.x * a.x + p1.y * a.y); sc2.push(p2.x * a.x + p2.y * a.y); } var maxc1 = Math.max.apply(Math, sc1), maxc2 = Math.max.apply(Math, sc2), minc1 = Math.min.apply(Math, sc1), minc2 = Math.min.apply(Math, sc2); return (minc2 <= maxc1 && maxc2 >= minc1); }, /** * Check whether two rectangles collide on each one of their four axis. If * all axis collide, then the two rectangles do collide on the plane. * * @param {array} Rectangle A's corners. * @param {array} Rectangle B's corners. * @return {boolean} True if the rectangles collide. */ collision: function(c1, c2) { var axis = this.axis(c1, c2), col = true; for (var i = 0; i < 4; i++) { col *= this.axisCollision(axis[i], c1, c2); } return !!col; } }; /** * Quad Functions * ------------ * * The Quadtree functions themselves. * For each of those functions, we consider that in a splitted quad, the * index of each node is the following: * 0: top left * 1: top right * 2: bottom left * 3: bottom right * * Moreover, the hereafter quad's philosophy is to consider that if an element * collides with more than one nodes, this element belongs to each of the * nodes it collides with where other would let it lie on a higher node. */ /** * Get the index of the node containing the point in the quad * * @param {object} point A point defined by coordinates (x, y). * @param {object} quadBounds Boundaries of the quad (x, y, width, heigth). * @return {integer} The index of the node containing the point. */ function _quadIndex(point, quadBounds) { var xmp = quadBounds.x + quadBounds.width / 2, ymp = quadBounds.y + quadBounds.height / 2, top = (point.y < ymp), left = (point.x < xmp); if (top) { if (left) return 0; else return 1; } else { if (left) return 2; else return 3; } } /** * Get a list of indexes of nodes containing an axis-aligned rectangle * * @param {object} rectangle A rectangle defined by two points (x1, y1), * (x2, y2) and height. * @param {array} quadCorners An array of the quad nodes' corners. * @return {array} An array of indexes containing one to * four integers. */ function _quadIndexes(rectangle, quadCorners) { var indexes = []; // Iterating through quads for (var i = 0; i < 4; i++) if ((rectangle.x2 >= quadCorners[i][0].x) && (rectangle.x1 <= quadCorners[i][1].x) && (rectangle.y1 + rectangle.height >= quadCorners[i][0].y) && (rectangle.y1 <= quadCorners[i][2].y)) indexes.push(i); return indexes; } /** * Get a list of indexes of nodes containing a non-axis-aligned rectangle * * @param {array} corners An array containing each corner of the * rectangle defined by its coordinates (x, y). * @param {array} quadCorners An array of the quad nodes' corners. * @return {array} An array of indexes containing one to * four integers. */ function _quadCollision(corners, quadCorners) { var indexes = []; // Iterating through quads for (var i = 0; i < 4; i++) if (_geom.collision(corners, quadCorners[i])) indexes.push(i); return indexes; } /** * Subdivide a quad by creating a node at a precise index. The function does * not generate all four nodes not to potentially create unused nodes. * * @param {integer} index The index of the node to create. * @param {object} quad The quad object to subdivide. * @return {object} A new quad representing the node created. */ function _quadSubdivide(index, quad) { var next = quad.level + 1, subw = Math.round(quad.bounds.width / 2), subh = Math.round(quad.bounds.height / 2), qx = Math.round(quad.bounds.x), qy = Math.round(quad.bounds.y), x, y; switch (index) { case 0: x = qx; y = qy; break; case 1: x = qx + subw; y = qy; break; case 2: x = qx; y = qy + subh; break; case 3: x = qx + subw; y = qy + subh; break; } return _quadTree( {x: x, y: y, width: subw, height: subh}, next, quad.maxElements, quad.maxLevel ); } /** * Recursively insert an element into the quadtree. Only points * with size, i.e. axis-aligned squares, may be inserted with this * method. * * @param {object} el The element to insert in the quadtree. * @param {object} sizedPoint A sized point defined by two top points * (x1, y1), (x2, y2) and height. * @param {object} quad The quad in which to insert the element. * @return {undefined} The function does not return anything. */ function _quadInsert(el, sizedPoint, quad) { if (quad.level < quad.maxLevel) { // Searching appropriate quads var indexes = _quadIndexes(sizedPoint, quad.corners); // Iterating for (var i = 0, l = indexes.length; i < l; i++) { // Subdividing if necessary if (quad.nodes[indexes[i]] === undefined) quad.nodes[indexes[i]] = _quadSubdivide(indexes[i], quad); // Recursion _quadInsert(el, sizedPoint, quad.nodes[indexes[i]]); } } else { // Pushing the element in a leaf node quad.elements.push(el); } } /** * Recursively retrieve every elements held by the node containing the * searched point. * * @param {object} point The searched point (x, y). * @param {object} quad The searched quad. * @return {array} An array of elements contained in the relevant * node. */ function _quadRetrievePoint(point, quad) { if (quad.level < quad.maxLevel) { var index = _quadIndex(point, quad.bounds); // If node does not exist we return an empty list if (quad.nodes[index] !== undefined) { return _quadRetrievePoint(point, quad.nodes[index]); } else { return []; } } else { return quad.elements; } } /** * Recursively retrieve every elements contained within an rectangular area * that may or may not be axis-aligned. * * @param {object|array} rectData The searched area defined either by * an array of four corners (x, y) in * the case of a non-axis-aligned * rectangle or an object with two top * points (x1, y1), (x2, y2) and height. * @param {object} quad The searched quad. * @param {function} collisionFunc The collision function used to search * for node indexes. * @param {array?} els The retrieved elements. * @return {array} An array of elements contained in the * area. */ function _quadRetrieveArea(rectData, quad, collisionFunc, els) { els = els || {}; if (quad.level < quad.maxLevel) { var indexes = collisionFunc(rectData, quad.corners); for (var i = 0, l = indexes.length; i < l; i++) if (quad.nodes[indexes[i]] !== undefined) _quadRetrieveArea( rectData, quad.nodes[indexes[i]], collisionFunc, els ); } else for (var j = 0, m = quad.elements.length; j < m; j++) if (els[quad.elements[j].id] === undefined) els[quad.elements[j].id] = quad.elements[j]; return els; } /** * Creates the quadtree object itself. * * @param {object} bounds The boundaries of the quad defined by an * origin (x, y), width and heigth. * @param {integer} level The level of the quad in the tree. * @param {integer} maxElements The max number of element in a leaf node. * @param {integer} maxLevel The max recursion level of the tree. * @return {object} The quadtree object. */ function _quadTree(bounds, level, maxElements, maxLevel) { return { level: level || 0, bounds: bounds, corners: _geom.splitSquare(bounds), maxElements: maxElements || 40, maxLevel: maxLevel || 8, elements: [], nodes: [] }; } /** * Sigma Quad Constructor * ---------------------- * * The edgequad API as exposed to sigma. */ /** * The edgequad core that will become the sigma interface with the quadtree. * * property {object} _tree Property holding the quadtree object. * property {object} _geom Exposition of the _geom namespace for testing. * property {object} _cache Cache for the area method. * property {boolean} _enabled Can index and retreive elements. */ var edgequad = function() { this._geom = _geom; this._tree = null; this._cache = { query: false, result: false }; this._enabled = true; }; /** * Index a graph by inserting its edges into the quadtree. * * @param {object} graph A graph instance. * @param {object} params An object of parameters with at least the quad * bounds. * @return {object} The quadtree object. * * Parameters: * ---------- * bounds: {object} boundaries of the quad defined by its origin (x, y) * width and heigth. * prefix: {string?} a prefix for edge geometric attributes. * maxElements: {integer?} the max number of elements in a leaf node. * maxLevel: {integer?} the max recursion level of the tree. */ edgequad.prototype.index = function(graph, params) { if (!this._enabled) return this._tree; // Enforcing presence of boundaries if (!params.bounds) throw 'sigma.classes.edgequad.index: bounds information not given.'; // Prefix var prefix = params.prefix || '', cp, source, target, n, e; // Building the tree this._tree = _quadTree( params.bounds, 0, params.maxElements, params.maxLevel ); var edges = graph.edges(); // Inserting graph edges into the tree for (var i = 0, l = edges.length; i < l; i++) { source = graph.nodes(edges[i].source); target = graph.nodes(edges[i].target); e = { x1: source[prefix + 'x'], y1: source[prefix + 'y'], x2: target[prefix + 'x'], y2: target[prefix + 'y'], size: edges[i][prefix + 'size'] || 0 }; // Inserting edge if (edges[i].type === 'curve' || edges[i].type === 'curvedArrow') { if (source.id === target.id) { n = { x: source[prefix + 'x'], y: source[prefix + 'y'], size: source[prefix + 'size'] || 0 }; _quadInsert( edges[i], _geom.selfLoopToSquare(n), this._tree); } else { cp = sigma.utils.getQuadraticControlPoint(e.x1, e.y1, e.x2, e.y2); _quadInsert( edges[i], _geom.quadraticCurveToSquare(e, cp), this._tree); } } else { _quadInsert( edges[i], _geom.lineToSquare(e), this._tree); } } // Reset cache: this._cache = { query: false, result: false }; // remove? return this._tree; }; /** * Retrieve every graph edges held by the quadtree node containing the * searched point. * * @param {number} x of the point. * @param {number} y of the point. * @return {array} An array of edges retrieved. */ edgequad.prototype.point = function(x, y) { if (!this._enabled) return []; return this._tree ? _quadRetrievePoint({x: x, y: y}, this._tree) || [] : []; }; /** * Retrieve every graph edges within a rectangular area. The methods keep the * last area queried in cache for optimization reason and will act differently * for the same reason if the area is axis-aligned or not. * * @param {object} A rectangle defined by two top points (x1, y1), (x2, y2) * and height. * @return {array} An array of edges retrieved. */ edgequad.prototype.area = function(rect) { if (!this._enabled) return []; var serialized = JSON.stringify(rect), collisionFunc, rectData; // Returning cache? if (this._cache.query === serialized) return this._cache.result; // Axis aligned ? if (_geom.isAxisAligned(rect)) { collisionFunc = _quadIndexes; rectData = _geom.axisAlignedTopPoints(rect); } else { collisionFunc = _quadCollision; rectData = _geom.rectangleCorners(rect); } // Retrieving edges var edges = this._tree ? _quadRetrieveArea( rectData, this._tree, collisionFunc ) : []; // Object to array var edgesArray = []; for (var i in edges) edgesArray.push(edges[i]); // Caching this._cache.query = serialized; this._cache.result = edgesArray; return edgesArray; }; /** * EXPORT: * ******* */ if (typeof this.sigma !== 'undefined') { this.sigma.classes = this.sigma.classes || {}; this.sigma.classes.edgequad = edgequad; } else if (typeof exports !== 'undefined') { if (typeof module !== 'undefined' && module.exports) exports = module.exports = edgequad; exports.edgequad = edgequad; } else this.edgequad = edgequad; }).call(this); ;(function(undefined) { 'use strict'; if (typeof sigma === 'undefined') throw 'sigma is not declared'; // Initialize packages: sigma.utils.pkg('sigma.captors'); /** * The user inputs default captor. It deals with mouse events, keyboards * events and touch events. * * @param {DOMElement} target The DOM element where the listeners will be * bound. * @param {camera} camera The camera related to the target. * @param {configurable} settings The settings function. * @return {sigma.captor} The fresh new captor instance. */ sigma.captors.mouse = function(target, camera, settings) { var _self = this, _target = target, _camera = camera, _settings = settings, // CAMERA MANAGEMENT: // ****************** // The camera position when the user starts dragging: _startCameraX, _startCameraY, _startCameraAngle, // The latest stage position: _lastCameraX, _lastCameraY, _lastCameraAngle, _lastCameraRatio, // MOUSE MANAGEMENT: // ***************** // The mouse position when the user starts dragging: _startMouseX, _startMouseY, _isMouseDown, _isMoving, _hasDragged, _downStartTime, _movingTimeoutId; sigma.classes.dispatcher.extend(this); sigma.utils.doubleClick(_target, 'click', _doubleClickHandler); _target.addEventListener('DOMMouseScroll', _wheelHandler, false); _target.addEventListener('mousewheel', _wheelHandler, false); _target.addEventListener('mousemove', _moveHandler, false); _target.addEventListener('mousedown', _downHandler, false); _target.addEventListener('click', _clickHandler, false); _target.addEventListener('mouseout', _outHandler, false); document.addEventListener('mouseup', _upHandler, false); /** * This method unbinds every handlers that makes the captor work. */ this.kill = function() { sigma.utils.unbindDoubleClick(_target, 'click'); _target.removeEventListener('DOMMouseScroll', _wheelHandler); _target.removeEventListener('mousewheel', _wheelHandler); _target.removeEventListener('mousemove', _moveHandler); _target.removeEventListener('mousedown', _downHandler); _target.removeEventListener('click', _clickHandler); _target.removeEventListener('mouseout', _outHandler); document.removeEventListener('mouseup', _upHandler); }; // MOUSE EVENTS: // ************* /** * The handler listening to the 'move' mouse event. It will effectively * drag the graph. * * @param {event} e A mouse event. */ function _moveHandler(e) { var x, y, pos; // Dispatch event: if (_settings('mouseEnabled')) _self.dispatchEvent('mousemove', { x: sigma.utils.getX(e) - sigma.utils.getWidth(e) / 2, y: sigma.utils.getY(e) - sigma.utils.getHeight(e) / 2, clientX: e.clientX, clientY: e.clientY, ctrlKey: e.ctrlKey, metaKey: e.metaKey, altKey: e.altKey, shiftKey: e.shiftKey }); if (_settings('mouseEnabled') && _isMouseDown) { _isMoving = true; _hasDragged = true; if (_movingTimeoutId) clearTimeout(_movingTimeoutId); _movingTimeoutId = setTimeout(function() { _isMoving = false; }, _settings('dragTimeout')); sigma.misc.animation.killAll(_camera); _camera.isMoving = true; pos = _camera.cameraPosition( sigma.utils.getX(e) - _startMouseX, sigma.utils.getY(e) - _startMouseY, true ); x = _startCameraX - pos.x; y = _startCameraY - pos.y; if (x !== _camera.x || y !== _camera.y) { _lastCameraX = _camera.x; _lastCameraY = _camera.y; _camera.goTo({ x: x, y: y }); } if (e.preventDefault) e.preventDefault(); else e.returnValue = false; e.stopPropagation(); return false; } } /** * The handler listening to the 'up' mouse event. It will stop dragging the * graph. * * @param {event} e A mouse event. */ function _upHandler(e) { if (_settings('mouseEnabled') && _isMouseDown) { _isMouseDown = false; if (_movingTimeoutId) clearTimeout(_movingTimeoutId); _camera.isMoving = false; var x = sigma.utils.getX(e), y = sigma.utils.getY(e); if (_isMoving) { sigma.misc.animation.killAll(_camera); sigma.misc.animation.camera( _camera, { x: _camera.x + _settings('mouseInertiaRatio') * (_camera.x - _lastCameraX), y: _camera.y + _settings('mouseInertiaRatio') * (_camera.y - _lastCameraY) }, { easing: 'quadraticOut', duration: _settings('mouseInertiaDuration') } ); } else if ( _startMouseX !== x || _startMouseY !== y ) _camera.goTo({ x: _camera.x, y: _camera.y }); _self.dispatchEvent('mouseup', { x: x - sigma.utils.getWidth(e) / 2, y: y - sigma.utils.getHeight(e) / 2, clientX: e.clientX, clientY: e.clientY, ctrlKey: e.ctrlKey, metaKey: e.metaKey, altKey: e.altKey, shiftKey: e.shiftKey }); // Update _isMoving flag: _isMoving = false; } } /** * The handler listening to the 'down' mouse event. It will start observing * the mouse position for dragging the graph. * * @param {event} e A mouse event. */ function _downHandler(e) { if (_settings('mouseEnabled')) { _startCameraX = _camera.x; _startCameraY = _camera.y; _lastCameraX = _camera.x; _lastCameraY = _camera.y; _startMouseX = sigma.utils.getX(e); _startMouseY = sigma.utils.getY(e); _hasDragged = false; _downStartTime = (new Date()).getTime(); switch (e.which) { case 2: // Middle mouse button pressed // Do nothing. break; case 3: // Right mouse button pressed _self.dispatchEvent('rightclick', { x: _startMouseX - sigma.utils.getWidth(e) / 2, y: _startMouseY - sigma.utils.getHeight(e) / 2, clientX: e.clientX, clientY: e.clientY, ctrlKey: e.ctrlKey, metaKey: e.metaKey, altKey: e.altKey, shiftKey: e.shiftKey }); break; // case 1: default: // Left mouse button pressed _isMouseDown = true; _self.dispatchEvent('mousedown', { x: _startMouseX - sigma.utils.getWidth(e) / 2, y: _startMouseY - sigma.utils.getHeight(e) / 2, clientX: e.clientX, clientY: e.clientY, ctrlKey: e.ctrlKey, metaKey: e.metaKey, altKey: e.altKey, shiftKey: e.shiftKey }); } } } /** * The handler listening to the 'out' mouse event. It will just redispatch * the event. * * @param {event} e A mouse event. */ function _outHandler(e) { if (_settings('mouseEnabled')) _self.dispatchEvent('mouseout'); } /** * The handler listening to the 'click' mouse event. It will redispatch the * click event, but with normalized X and Y coordinates. * * @param {event} e A mouse event. */ function _clickHandler(e) { if (_settings('mouseEnabled')) _self.dispatchEvent('click', { x: sigma.utils.getX(e) - sigma.utils.getWidth(e) / 2, y: sigma.utils.getY(e) - sigma.utils.getHeight(e) / 2, clientX: e.clientX, clientY: e.clientY, ctrlKey: e.ctrlKey, metaKey: e.metaKey, altKey: e.altKey, shiftKey: e.shiftKey, isDragging: (((new Date()).getTime() - _downStartTime) > 100) && _hasDragged }); if (e.preventDefault) e.preventDefault(); else e.returnValue = false; e.stopPropagation(); return false; } /** * The handler listening to the double click custom event. It will * basically zoom into the graph. * * @param {event} e A mouse event. */ function _doubleClickHandler(e) { var pos, ratio, animation; if (_settings('mouseEnabled')) { ratio = 1 / _settings('doubleClickZoomingRatio'); _self.dispatchEvent('doubleclick', { x: _startMouseX - sigma.utils.getWidth(e) / 2, y: _startMouseY - sigma.utils.getHeight(e) / 2, clientX: e.clientX, clientY: e.clientY, ctrlKey: e.ctrlKey, metaKey: e.metaKey, altKey: e.altKey, shiftKey: e.shiftKey }); if (_settings('doubleClickEnabled')) { pos = _camera.cameraPosition( sigma.utils.getX(e) - sigma.utils.getWidth(e) / 2, sigma.utils.getY(e) - sigma.utils.getHeight(e) / 2, true ); animation = { duration: _settings('doubleClickZoomDuration') }; sigma.utils.zoomTo(_camera, pos.x, pos.y, ratio, animation); } if (e.preventDefault) e.preventDefault(); else e.returnValue = false; e.stopPropagation(); return false; } } /** * The handler listening to the 'wheel' mouse event. It will basically zoom * in or not into the graph. * * @param {event} e A mouse event. */ function _wheelHandler(e) { var pos, ratio, animation; if (_settings('mouseEnabled') && _settings('mouseWheelEnabled')) { ratio = sigma.utils.getDelta(e) > 0 ? 1 / _settings('zoomingRatio') : _settings('zoomingRatio'); pos = _camera.cameraPosition( sigma.utils.getX(e) - sigma.utils.getWidth(e) / 2, sigma.utils.getY(e) - sigma.utils.getHeight(e) / 2, true ); animation = { duration: _settings('mouseZoomDuration') }; sigma.utils.zoomTo(_camera, pos.x, pos.y, ratio, animation); if (e.preventDefault) e.preventDefault(); else e.returnValue = false; e.stopPropagation(); return false; } } }; }).call(this); ;(function(undefined) { 'use strict'; if (typeof sigma === 'undefined') throw 'sigma is not declared'; // Initialize packages: sigma.utils.pkg('sigma.captors'); /** * The user inputs default captor. It deals with mouse events, keyboards * events and touch events. * * @param {DOMElement} target The DOM element where the listeners will be * bound. * @param {camera} camera The camera related to the target. * @param {configurable} settings The settings function. * @return {sigma.captor} The fresh new captor instance. */ sigma.captors.touch = function(target, camera, settings) { var _self = this, _target = target, _camera = camera, _settings = settings, // CAMERA MANAGEMENT: // ****************** // The camera position when the user starts dragging: _startCameraX, _startCameraY, _startCameraAngle, _startCameraRatio, // The latest stage position: _lastCameraX, _lastCameraY, _lastCameraAngle, _lastCameraRatio, // TOUCH MANAGEMENT: // ***************** // Touches that are down: _downTouches = [], _startTouchX0, _startTouchY0, _startTouchX1, _startTouchY1, _startTouchAngle, _startTouchDistance, _touchMode, _isMoving, _doubleTap, _movingTimeoutId; sigma.classes.dispatcher.extend(this); sigma.utils.doubleClick(_target, 'touchstart', _doubleTapHandler); _target.addEventListener('touchstart', _handleStart, false); _target.addEventListener('touchend', _handleLeave, false); _target.addEventListener('touchcancel', _handleLeave, false); _target.addEventListener('touchleave', _handleLeave, false); _target.addEventListener('touchmove', _handleMove, false); function position(e) { var offset = sigma.utils.getOffset(_target); return { x: e.pageX - offset.left, y: e.pageY - offset.top }; } /** * This method unbinds every handlers that makes the captor work. */ this.kill = function() { sigma.utils.unbindDoubleClick(_target, 'touchstart'); _target.addEventListener('touchstart', _handleStart); _target.addEventListener('touchend', _handleLeave); _target.addEventListener('touchcancel', _handleLeave); _target.addEventListener('touchleave', _handleLeave); _target.addEventListener('touchmove', _handleMove); }; // TOUCH EVENTS: // ************* /** * The handler listening to the 'touchstart' event. It will set the touch * mode ("_touchMode") and start observing the user touch moves. * * @param {event} e A touch event. */ function _handleStart(e) { if (_settings('touchEnabled')) { var x0, x1, y0, y1, pos0, pos1; _downTouches = e.touches; switch (_downTouches.length) { case 1: _camera.isMoving = true; _touchMode = 1; _startCameraX = _camera.x; _startCameraY = _camera.y; _lastCameraX = _camera.x; _lastCameraY = _camera.y; pos0 = position(_downTouches[0]); _startTouchX0 = pos0.x; _startTouchY0 = pos0.y; break; case 2: _camera.isMoving = true; _touchMode = 2; pos0 = position(_downTouches[0]); pos1 = position(_downTouches[1]); x0 = pos0.x; y0 = pos0.y; x1 = pos1.x; y1 = pos1.y; _lastCameraX = _camera.x; _lastCameraY = _camera.y; _startCameraAngle = _camera.angle; _startCameraRatio = _camera.ratio; _startCameraX = _camera.x; _startCameraY = _camera.y; _startTouchX0 = x0; _startTouchY0 = y0; _startTouchX1 = x1; _startTouchY1 = y1; _startTouchAngle = Math.atan2( _startTouchY1 - _startTouchY0, _startTouchX1 - _startTouchX0 ); _startTouchDistance = Math.sqrt( Math.pow(_startTouchY1 - _startTouchY0, 2) + Math.pow(_startTouchX1 - _startTouchX0, 2) ); e.preventDefault(); return false; } } } /** * The handler listening to the 'touchend', 'touchcancel' and 'touchleave' * event. It will update the touch mode if there are still at least one * finger, and stop dragging else. * * @param {event} e A touch event. */ function _handleLeave(e) { if (_settings('touchEnabled')) { _downTouches = e.touches; var inertiaRatio = _settings('touchInertiaRatio'); if (_movingTimeoutId) { _isMoving = false; clearTimeout(_movingTimeoutId); } switch (_touchMode) { case 2: if (e.touches.length === 1) { _handleStart(e); e.preventDefault(); break; } /* falls through */ case 1: _camera.isMoving = false; _self.dispatchEvent('stopDrag'); if (_isMoving) { _doubleTap = false; sigma.misc.animation.camera( _camera, { x: _camera.x + inertiaRatio * (_camera.x - _lastCameraX), y: _camera.y + inertiaRatio * (_camera.y - _lastCameraY) }, { easing: 'quadraticOut', duration: _settings('touchInertiaDuration') } ); } _isMoving = false; _touchMode = 0; break; } } } /** * The handler listening to the 'touchmove' event. It will effectively drag * the graph, and eventually zooms and turn it if the user is using two * fingers. * * @param {event} e A touch event. */ function _handleMove(e) { if (!_doubleTap && _settings('touchEnabled')) { var x0, x1, y0, y1, cos, sin, end, pos0, pos1, diff, start, dAngle, dRatio, newStageX, newStageY, newStageRatio, newStageAngle; _downTouches = e.touches; _isMoving = true; if (_movingTimeoutId) clearTimeout(_movingTimeoutId); _movingTimeoutId = setTimeout(function() { _isMoving = false; }, _settings('dragTimeout')); switch (_touchMode) { case 1: pos0 = position(_downTouches[0]); x0 = pos0.x; y0 = pos0.y; diff = _camera.cameraPosition( x0 - _startTouchX0, y0 - _startTouchY0, true ); newStageX = _startCameraX - diff.x; newStageY = _startCameraY - diff.y; if (newStageX !== _camera.x || newStageY !== _camera.y) { _lastCameraX = _camera.x; _lastCameraY = _camera.y; _camera.goTo({ x: newStageX, y: newStageY }); _self.dispatchEvent('mousemove', { x: pos0.x - sigma.utils.getWidth(e) / 2, y: pos0.y - sigma.utils.getHeight(e) / 2, clientX: e.clientX, clientY: e.clientY, ctrlKey: e.ctrlKey, metaKey: e.metaKey, altKey: e.altKey, shiftKey: e.shiftKey }); _self.dispatchEvent('drag'); } break; case 2: pos0 = position(_downTouches[0]); pos1 = position(_downTouches[1]); x0 = pos0.x; y0 = pos0.y; x1 = pos1.x; y1 = pos1.y; start = _camera.cameraPosition( (_startTouchX0 + _startTouchX1) / 2 - sigma.utils.getWidth(e) / 2, (_startTouchY0 + _startTouchY1) / 2 - sigma.utils.getHeight(e) / 2, true ); end = _camera.cameraPosition( (x0 + x1) / 2 - sigma.utils.getWidth(e) / 2, (y0 + y1) / 2 - sigma.utils.getHeight(e) / 2, true ); dAngle = Math.atan2(y1 - y0, x1 - x0) - _startTouchAngle; dRatio = Math.sqrt( Math.pow(y1 - y0, 2) + Math.pow(x1 - x0, 2) ) / _startTouchDistance; // Translation: x0 = start.x; y0 = start.y; // Homothetic transformation: newStageRatio = _startCameraRatio / dRatio; x0 = x0 * dRatio; y0 = y0 * dRatio; // Rotation: newStageAngle = _startCameraAngle - dAngle; cos = Math.cos(-dAngle); sin = Math.sin(-dAngle); x1 = x0 * cos + y0 * sin; y1 = y0 * cos - x0 * sin; x0 = x1; y0 = y1; // Finalize: newStageX = x0 - end.x + _startCameraX; newStageY = y0 - end.y + _startCameraY; if ( newStageRatio !== _camera.ratio || newStageAngle !== _camera.angle || newStageX !== _camera.x || newStageY !== _camera.y ) { _lastCameraX = _camera.x; _lastCameraY = _camera.y; _lastCameraAngle = _camera.angle; _lastCameraRatio = _camera.ratio; _camera.goTo({ x: newStageX, y: newStageY, angle: newStageAngle, ratio: newStageRatio }); _self.dispatchEvent('drag'); } break; } e.preventDefault(); return false; } } /** * The handler listening to the double tap custom event. It will * basically zoom into the graph. * * @param {event} e A touch event. */ function _doubleTapHandler(e) { var pos, ratio, animation; if (e.touches && e.touches.length === 1 && _settings('touchEnabled')) { _doubleTap = true; ratio = 1 / _settings('doubleClickZoomingRatio'); pos = position(e.touches[0]); _self.dispatchEvent('doubleclick', { x: pos.x - sigma.utils.getWidth(e) / 2, y: pos.y - sigma.utils.getHeight(e) / 2, clientX: e.clientX, clientY: e.clientY, ctrlKey: e.ctrlKey, metaKey: e.metaKey, altKey: e.altKey, shiftKey: e.shiftKey }); if (_settings('doubleClickEnabled')) { pos = _camera.cameraPosition( pos.x - sigma.utils.getWidth(e) / 2, pos.y - sigma.utils.getHeight(e) / 2, true ); animation = { duration: _settings('doubleClickZoomDuration'), onComplete: function() { _doubleTap = false; } }; sigma.utils.zoomTo(_camera, pos.x, pos.y, ratio, animation); } if (e.preventDefault) e.preventDefault(); else e.returnValue = false; e.stopPropagation(); return false; } } }; }).call(this); ;(function(undefined) { 'use strict'; if (typeof sigma === 'undefined') throw 'sigma is not declared'; if (typeof conrad === 'undefined') throw 'conrad is not declared'; // Initialize packages: sigma.utils.pkg('sigma.renderers'); /** * This function is the constructor of the canvas sigma's renderer. * * @param {sigma.classes.graph} graph The graph to render. * @param {sigma.classes.camera} camera The camera. * @param {configurable} settings The sigma instance settings * function. * @param {object} object The options object. * @return {sigma.renderers.canvas} The renderer instance. */ sigma.renderers.canvas = function(graph, camera, settings, options) { if (typeof options !== 'object') throw 'sigma.renderers.canvas: Wrong arguments.'; if (!(options.container instanceof HTMLElement)) throw 'Container not found.'; var k, i, l, a, fn, self = this; sigma.classes.dispatcher.extend(this); // Initialize main attributes: Object.defineProperty(this, 'conradId', { value: sigma.utils.id() }); this.graph = graph; this.camera = camera; this.contexts = {}; this.domElements = {}; this.options = options; this.container = this.options.container; this.settings = ( typeof options.settings === 'object' && options.settings ) ? settings.embedObjects(options.settings) : settings; // Node indexes: this.nodesOnScreen = []; this.edgesOnScreen = []; // Conrad related attributes: this.jobs = {}; // Find the prefix: this.options.prefix = 'renderer' + this.conradId + ':'; // Initialize the DOM elements: if ( !this.settings('batchEdgesDrawing') ) { this.initDOM('canvas', 'scene'); this.contexts.edges = this.contexts.scene; this.contexts.nodes = this.contexts.scene; this.contexts.labels = this.contexts.scene; } else { this.initDOM('canvas', 'edges'); this.initDOM('canvas', 'scene'); this.contexts.nodes = this.contexts.scene; this.contexts.labels = this.contexts.scene; } this.initDOM('canvas', 'mouse'); this.contexts.hover = this.contexts.mouse; // Initialize captors: this.captors = []; a = this.options.captors || [sigma.captors.mouse, sigma.captors.touch]; for (i = 0, l = a.length; i < l; i++) { fn = typeof a[i] === 'function' ? a[i] : sigma.captors[a[i]]; this.captors.push( new fn( this.domElements.mouse, this.camera, this.settings ) ); } // Deal with sigma events: sigma.misc.bindEvents.call(this, this.options.prefix); sigma.misc.drawHovers.call(this, this.options.prefix); this.resize(false); }; /** * This method renders the graph on the canvases. * * @param {?object} options Eventually an object of options. * @return {sigma.renderers.canvas} Returns the instance itself. */ sigma.renderers.canvas.prototype.render = function(options) { options = options || {}; var a, i, k, l, o, id, end, job, start, edges, renderers, rendererType, batchSize, tempGCO, index = {}, graph = this.graph, nodes = this.graph.nodes, prefix = this.options.prefix || '', drawEdges = this.settings(options, 'drawEdges'), drawNodes = this.settings(options, 'drawNodes'), drawLabels = this.settings(options, 'drawLabels'), drawEdgeLabels = this.settings(options, 'drawEdgeLabels'), embedSettings = this.settings.embedObjects(options, { prefix: this.options.prefix }); // Call the resize function: this.resize(false); // Check the 'hideEdgesOnMove' setting: if (this.settings(options, 'hideEdgesOnMove')) if (this.camera.isAnimated || this.camera.isMoving) drawEdges = false; // Apply the camera's view: this.camera.applyView( undefined, this.options.prefix, { width: this.width, height: this.height } ); // Clear canvases: this.clear(); // Kill running jobs: for (k in this.jobs) if (conrad.hasJob(k)) conrad.killJob(k); // Find which nodes are on screen: this.edgesOnScreen = []; this.nodesOnScreen = this.camera.quadtree.area( this.camera.getRectangle(this.width, this.height) ); for (a = this.nodesOnScreen, i = 0, l = a.length; i < l; i++) index[a[i].id] = a[i]; // Draw edges: // - If settings('batchEdgesDrawing') is true, the edges are displayed per // batches. If not, they are drawn in one frame. if (drawEdges) { // First, let's identify which edges to draw. To do this, we just keep // every edges that have at least one extremity displayed according to // the quadtree and the "hidden" attribute. We also do not keep hidden // edges. for (a = graph.edges(), i = 0, l = a.length; i < l; i++) { o = a[i]; if ( (index[o.source] || index[o.target]) && (!o.hidden && !nodes(o.source).hidden && !nodes(o.target).hidden) ) this.edgesOnScreen.push(o); } // If the "batchEdgesDrawing" settings is true, edges are batched: if (this.settings(options, 'batchEdgesDrawing')) { id = 'edges_' + this.conradId; batchSize = embedSettings('canvasEdgesBatchSize'); edges = this.edgesOnScreen; l = edges.length; start = 0; end = Math.min(edges.length, start + batchSize); job = function() { tempGCO = this.contexts.edges.globalCompositeOperation; this.contexts.edges.globalCompositeOperation = 'destination-over'; renderers = sigma.canvas.edges; for (i = start; i < end; i++) { o = edges[i]; (renderers[ o.type || this.settings(options, 'defaultEdgeType') ] || renderers.def)( o, graph.nodes(o.source), graph.nodes(o.target), this.contexts.edges, embedSettings ); } // Draw edge labels: if (drawEdgeLabels) { renderers = sigma.canvas.edges.labels; for (i = start; i < end; i++) { o = edges[i]; if (!o.hidden) (renderers[ o.type || this.settings(options, 'defaultEdgeType') ] || renderers.def)( o, graph.nodes(o.source), graph.nodes(o.target), this.contexts.labels, embedSettings ); } } // Restore original globalCompositeOperation: this.contexts.edges.globalCompositeOperation = tempGCO; // Catch job's end: if (end === edges.length) { delete this.jobs[id]; return false; } start = end + 1; end = Math.min(edges.length, start + batchSize); return true; }; this.jobs[id] = job; conrad.addJob(id, job.bind(this)); // If not, they are drawn in one frame: } else { renderers = sigma.canvas.edges; for (a = this.edgesOnScreen, i = 0, l = a.length; i < l; i++) { o = a[i]; (renderers[ o.type || this.settings(options, 'defaultEdgeType') ] || renderers.def)( o, graph.nodes(o.source), graph.nodes(o.target), this.contexts.edges, embedSettings ); } // Draw edge labels: // - No batching if (drawEdgeLabels) { renderers = sigma.canvas.edges.labels; for (a = this.edgesOnScreen, i = 0, l = a.length; i < l; i++) if (!a[i].hidden) (renderers[ a[i].type || this.settings(options, 'defaultEdgeType') ] || renderers.def)( a[i], graph.nodes(a[i].source), graph.nodes(a[i].target), this.contexts.labels, embedSettings ); } } } // Draw nodes: // - No batching if (drawNodes) { renderers = sigma.canvas.nodes; for (a = this.nodesOnScreen, i = 0, l = a.length; i < l; i++) if (!a[i].hidden) (renderers[ a[i].type || this.settings(options, 'defaultNodeType') ] || renderers.def)( a[i], this.contexts.nodes, embedSettings ); } // Draw labels: // - No batching if (drawLabels) { renderers = sigma.canvas.labels; for (a = this.nodesOnScreen, i = 0, l = a.length; i < l; i++) if (!a[i].hidden) (renderers[ a[i].type || this.settings(options, 'defaultNodeType') ] || renderers.def)( a[i], this.contexts.labels, embedSettings ); } this.dispatchEvent('render'); return this; }; /** * This method creates a DOM element of the specified type, switches its * position to "absolute", references it to the domElements attribute, and * finally appends it to the container. * * @param {string} tag The label tag. * @param {string} id The id of the element (to store it in "domElements"). */ sigma.renderers.canvas.prototype.initDOM = function(tag, id) { var dom = document.createElement(tag); dom.style.position = 'absolute'; dom.setAttribute('class', 'sigma-' + id); this.domElements[id] = dom; this.container.appendChild(dom); if (tag.toLowerCase() === 'canvas') this.contexts[id] = dom.getContext('2d'); }; /** * This method resizes each DOM elements in the container and stores the new * dimensions. Then, it renders the graph. * * @param {?number} width The new width of the container. * @param {?number} height The new height of the container. * @return {sigma.renderers.canvas} Returns the instance itself. */ sigma.renderers.canvas.prototype.resize = function(w, h) { var k, oldWidth = this.width, oldHeight = this.height, pixelRatio = 1; // TODO: // ***** // This pixelRatio is the solution to display with the good definition // on canvases on Retina displays (ie oversampling). Unfortunately, it // has a huge performance cost... // > pixelRatio = window.devicePixelRatio || 1; if (w !== undefined && h !== undefined) { this.width = w; this.height = h; } else { this.width = this.container.offsetWidth; this.height = this.container.offsetHeight; w = this.width; h = this.height; } if (oldWidth !== this.width || oldHeight !== this.height) { for (k in this.domElements) { this.domElements[k].style.width = w + 'px'; this.domElements[k].style.height = h + 'px'; if (this.domElements[k].tagName.toLowerCase() === 'canvas') { this.domElements[k].setAttribute('width', (w * pixelRatio) + 'px'); this.domElements[k].setAttribute('height', (h * pixelRatio) + 'px'); if (pixelRatio !== 1) this.contexts[k].scale(pixelRatio, pixelRatio); } } } return this; }; /** * This method clears each canvas. * * @return {sigma.renderers.canvas} Returns the instance itself. */ sigma.renderers.canvas.prototype.clear = function() { var k; for (k in this.domElements) if (this.domElements[k].tagName === 'CANVAS') this.domElements[k].width = this.domElements[k].width; return this; }; /** * This method kills contexts and other attributes. */ sigma.renderers.canvas.prototype.kill = function() { var k, captor; // Kill captors: while ((captor = this.captors.pop())) captor.kill(); delete this.captors; // Kill contexts: for (k in this.domElements) { this.domElements[k].parentNode.removeChild(this.domElements[k]); delete this.domElements[k]; delete this.contexts[k]; } delete this.domElements; delete this.contexts; }; /** * The labels, nodes and edges renderers are stored in the three following * objects. When an element is drawn, its type will be checked and if a * renderer with the same name exists, it will be used. If not found, the * default renderer will be used instead. * * They are stored in different files, in the "./canvas" folder. */ sigma.utils.pkg('sigma.canvas.nodes'); sigma.utils.pkg('sigma.canvas.edges'); sigma.utils.pkg('sigma.canvas.labels'); }).call(this); ;(function(undefined) { 'use strict'; if (typeof sigma === 'undefined') throw 'sigma is not declared'; // Initialize packages: sigma.utils.pkg('sigma.renderers'); /** * This function is the constructor of the canvas sigma's renderer. * * @param {sigma.classes.graph} graph The graph to render. * @param {sigma.classes.camera} camera The camera. * @param {configurable} settings The sigma instance settings * function. * @param {object} object The options object. * @return {sigma.renderers.canvas} The renderer instance. */ sigma.renderers.webgl = function(graph, camera, settings, options) { if (typeof options !== 'object') throw 'sigma.renderers.webgl: Wrong arguments.'; if (!(options.container instanceof HTMLElement)) throw 'Container not found.'; var k, i, l, a, fn, _self = this; sigma.classes.dispatcher.extend(this); // Conrad related attributes: this.jobs = {}; Object.defineProperty(this, 'conradId', { value: sigma.utils.id() }); // Initialize main attributes: this.graph = graph; this.camera = camera; this.contexts = {}; this.domElements = {}; this.options = options; this.container = this.options.container; this.settings = ( typeof options.settings === 'object' && options.settings ) ? settings.embedObjects(options.settings) : settings; // Find the prefix: this.options.prefix = this.camera.readPrefix; // Initialize programs hash Object.defineProperty(this, 'nodePrograms', { value: {} }); Object.defineProperty(this, 'edgePrograms', { value: {} }); Object.defineProperty(this, 'nodeFloatArrays', { value: {} }); Object.defineProperty(this, 'edgeFloatArrays', { value: {} }); // Initialize the DOM elements: if (this.settings(options, 'batchEdgesDrawing')) { this.initDOM('canvas', 'edges', true); this.initDOM('canvas', 'nodes', true); } else { this.initDOM('canvas', 'scene', true); this.contexts.nodes = this.contexts.scene; this.contexts.edges = this.contexts.scene; } this.initDOM('canvas', 'labels'); this.initDOM('canvas', 'mouse'); this.contexts.hover = this.contexts.mouse; // Initialize captors: this.captors = []; a = this.options.captors || [sigma.captors.mouse, sigma.captors.touch]; for (i = 0, l = a.length; i < l; i++) { fn = typeof a[i] === 'function' ? a[i] : sigma.captors[a[i]]; this.captors.push( new fn( this.domElements.mouse, this.camera, this.settings ) ); } // Deal with sigma events: sigma.misc.bindEvents.call(this, this.camera.prefix); sigma.misc.drawHovers.call(this, this.camera.prefix); this.resize(); }; /** * This method will generate the nodes and edges float arrays. This step is * separated from the "render" method, because to keep WebGL efficient, since * all the camera and middlewares are modelised as matrices and they do not * require the float arrays to be regenerated. * * Basically, when the user moves the camera or applies some specific linear * transformations, this process step will be skipped, and the "render" * method will efficiently refresh the rendering. * * And when the user modifies the graph colors or positions (applying a new * layout or filtering the colors, for instance), this "process" step will be * required to regenerate the float arrays. * * @return {sigma.renderers.webgl} Returns the instance itself. */ sigma.renderers.webgl.prototype.process = function() { var a, i, l, k, type, renderer, graph = this.graph, options = sigma.utils.extend(options, this.options); // Empty float arrays: for (k in this.nodeFloatArrays) delete this.nodeFloatArrays[k]; for (k in this.edgeFloatArrays) delete this.edgeFloatArrays[k]; // Sort edges and nodes per types: for (a = graph.edges(), i = 0, l = a.length; i < l; i++) { type = a[i].type || this.settings(options, 'defaultEdgeType'); k = (type && sigma.webgl.edges[type]) ? type : 'def'; if (!this.edgeFloatArrays[k]) this.edgeFloatArrays[k] = { edges: [] }; this.edgeFloatArrays[k].edges.push(a[i]); } for (a = graph.nodes(), i = 0, l = a.length; i < l; i++) { type = a[i].type || this.settings(options, 'defaultNodeType'); k = (type && sigma.webgl.nodes[type]) ? type : 'def'; if (!this.nodeFloatArrays[k]) this.nodeFloatArrays[k] = { nodes: [] }; this.nodeFloatArrays[k].nodes.push(a[i]); } // Push edges: for (k in this.edgeFloatArrays) { renderer = sigma.webgl.edges[k]; for (a = this.edgeFloatArrays[k].edges, i = 0, l = a.length; i < l; i++) { if (!this.edgeFloatArrays[k].array) this.edgeFloatArrays[k].array = new Float32Array( a.length * renderer.POINTS * renderer.ATTRIBUTES ); // Just check that the edge and both its extremities are visible: if ( !a[i].hidden && !graph.nodes(a[i].source).hidden && !graph.nodes(a[i].target).hidden ) renderer.addEdge( a[i], graph.nodes(a[i].source), graph.nodes(a[i].target), this.edgeFloatArrays[k].array, i * renderer.POINTS * renderer.ATTRIBUTES, options.prefix, this.settings ); } } // Push nodes: for (k in this.nodeFloatArrays) { renderer = sigma.webgl.nodes[k]; for (a = this.nodeFloatArrays[k].nodes, i = 0, l = a.length; i < l; i++) { if (!this.nodeFloatArrays[k].array) this.nodeFloatArrays[k].array = new Float32Array( a.length * renderer.POINTS * renderer.ATTRIBUTES ); // Just check that the edge and both its extremities are visible: if ( !a[i].hidden ) renderer.addNode( a[i], this.nodeFloatArrays[k].array, i * renderer.POINTS * renderer.ATTRIBUTES, options.prefix, this.settings ); } } return this; }; /** * This method renders the graph. It basically calls each program (and * generate them if they do not exist yet) to render nodes and edges, batched * per renderer. * * As in the canvas renderer, it is possible to display edges, nodes and / or * labels in batches, to make the whole thing way more scalable. * * @param {?object} params Eventually an object of options. * @return {sigma.renderers.webgl} Returns the instance itself. */ sigma.renderers.webgl.prototype.render = function(params) { var a, i, l, k, o, program, renderer, self = this, graph = this.graph, nodesGl = this.contexts.nodes, edgesGl = this.contexts.edges, matrix = this.camera.getMatrix(), options = sigma.utils.extend(params, this.options), drawLabels = this.settings(options, 'drawLabels'), drawEdges = this.settings(options, 'drawEdges'), drawNodes = this.settings(options, 'drawNodes'); // Call the resize function: this.resize(false); // Check the 'hideEdgesOnMove' setting: if (this.settings(options, 'hideEdgesOnMove')) if (this.camera.isAnimated || this.camera.isMoving) drawEdges = false; // Clear canvases: this.clear(); // Translate matrix to [width/2, height/2]: matrix = sigma.utils.matrices.multiply( matrix, sigma.utils.matrices.translation(this.width / 2, this.height / 2) ); // Kill running jobs: for (k in this.jobs) if (conrad.hasJob(k)) conrad.killJob(k); if (drawEdges) { if (this.settings(options, 'batchEdgesDrawing')) (function() { var a, k, i, id, job, arr, end, start, renderer, batchSize, currentProgram; id = 'edges_' + this.conradId; batchSize = this.settings(options, 'webglEdgesBatchSize'); a = Object.keys(this.edgeFloatArrays); if (!a.length) return; i = 0; renderer = sigma.webgl.edges[a[i]]; arr = this.edgeFloatArrays[a[i]].array; start = 0; end = Math.min( start + batchSize * renderer.POINTS, arr.length / renderer.ATTRIBUTES ); job = function() { // Check program: if (!this.edgePrograms[a[i]]) this.edgePrograms[a[i]] = renderer.initProgram(edgesGl); if (start < end) { edgesGl.useProgram(this.edgePrograms[a[i]]); renderer.render( edgesGl, this.edgePrograms[a[i]], arr, { settings: this.settings, matrix: matrix, width: this.width, height: this.height, ratio: this.camera.ratio, scalingRatio: this.settings( options, 'webglOversamplingRatio' ), start: start, count: end - start } ); } // Catch job's end: if ( end >= arr.length / renderer.ATTRIBUTES && i === a.length - 1 ) { delete this.jobs[id]; return false; } if (end >= arr.length / renderer.ATTRIBUTES) { i++; arr = this.edgeFloatArrays[a[i]].array; renderer = sigma.webgl.edges[a[i]]; start = 0; end = Math.min( start + batchSize * renderer.POINTS, arr.length / renderer.ATTRIBUTES ); } else { start = end; end = Math.min( start + batchSize * renderer.POINTS, arr.length / renderer.ATTRIBUTES ); } return true; }; this.jobs[id] = job; conrad.addJob(id, job.bind(this)); }).call(this); else { for (k in this.edgeFloatArrays) { renderer = sigma.webgl.edges[k]; // Check program: if (!this.edgePrograms[k]) this.edgePrograms[k] = renderer.initProgram(edgesGl); // Render if (this.edgeFloatArrays[k]) { edgesGl.useProgram(this.edgePrograms[k]); renderer.render( edgesGl, this.edgePrograms[k], this.edgeFloatArrays[k].array, { settings: this.settings, matrix: matrix, width: this.width, height: this.height, ratio: this.camera.ratio, scalingRatio: this.settings(options, 'webglOversamplingRatio') } ); } } } } if (drawNodes) { // Enable blending: nodesGl.blendFunc(nodesGl.SRC_ALPHA, nodesGl.ONE_MINUS_SRC_ALPHA); nodesGl.enable(nodesGl.BLEND); for (k in this.nodeFloatArrays) { renderer = sigma.webgl.nodes[k]; // Check program: if (!this.nodePrograms[k]) this.nodePrograms[k] = renderer.initProgram(nodesGl); // Render if (this.nodeFloatArrays[k]) { nodesGl.useProgram(this.nodePrograms[k]); renderer.render( nodesGl, this.nodePrograms[k], this.nodeFloatArrays[k].array, { settings: this.settings, matrix: matrix, width: this.width, height: this.height, ratio: this.camera.ratio, scalingRatio: this.settings(options, 'webglOversamplingRatio') } ); } } } if (drawLabels) { a = this.camera.quadtree.area( this.camera.getRectangle(this.width, this.height) ); // Apply camera view to these nodes: this.camera.applyView( undefined, undefined, { nodes: a, edges: [], width: this.width, height: this.height } ); o = function(key) { return self.settings({ prefix: self.camera.prefix }, key); }; for (i = 0, l = a.length; i < l; i++) if (!a[i].hidden) ( sigma.canvas.labels[ a[i].type || this.settings(options, 'defaultNodeType') ] || sigma.canvas.labels.def )(a[i], this.contexts.labels, o); } this.dispatchEvent('render'); return this; }; /** * This method creates a DOM element of the specified type, switches its * position to "absolute", references it to the domElements attribute, and * finally appends it to the container. * * @param {string} tag The label tag. * @param {string} id The id of the element (to store it in * "domElements"). * @param {?boolean} webgl Will init the WebGL context if true. */ sigma.renderers.webgl.prototype.initDOM = function(tag, id, webgl) { var gl, dom = document.createElement(tag), self = this; dom.style.position = 'absolute'; dom.setAttribute('class', 'sigma-' + id); this.domElements[id] = dom; this.container.appendChild(dom); if (tag.toLowerCase() === 'canvas') { this.contexts[id] = dom.getContext(webgl ? 'experimental-webgl' : '2d', { preserveDrawingBuffer: true }); // Adding webgl context loss listeners if (webgl) { dom.addEventListener('webglcontextlost', function(e) { e.preventDefault(); }, false); dom.addEventListener('webglcontextrestored', function(e) { self.render(); }, false); } } }; /** * This method resizes each DOM elements in the container and stores the new * dimensions. Then, it renders the graph. * * @param {?number} width The new width of the container. * @param {?number} height The new height of the container. * @return {sigma.renderers.webgl} Returns the instance itself. */ sigma.renderers.webgl.prototype.resize = function(w, h) { var k, oldWidth = this.width, oldHeight = this.height; if (w !== undefined && h !== undefined) { this.width = w; this.height = h; } else { this.width = this.container.offsetWidth; this.height = this.container.offsetHeight; w = this.width; h = this.height; } if (oldWidth !== this.width || oldHeight !== this.height) { for (k in this.domElements) { this.domElements[k].style.width = w + 'px'; this.domElements[k].style.height = h + 'px'; if (this.domElements[k].tagName.toLowerCase() === 'canvas') { // If simple 2D canvas: if (this.contexts[k] && this.contexts[k].scale) { this.domElements[k].setAttribute('width', w + 'px'); this.domElements[k].setAttribute('height', h + 'px'); } else { this.domElements[k].setAttribute( 'width', (w * this.settings('webglOversamplingRatio')) + 'px' ); this.domElements[k].setAttribute( 'height', (h * this.settings('webglOversamplingRatio')) + 'px' ); } } } } // Scale: for (k in this.contexts) if (this.contexts[k] && this.contexts[k].viewport) this.contexts[k].viewport( 0, 0, this.width * this.settings('webglOversamplingRatio'), this.height * this.settings('webglOversamplingRatio') ); return this; }; /** * This method clears each canvas. * * @return {sigma.renderers.webgl} Returns the instance itself. */ sigma.renderers.webgl.prototype.clear = function() { var k; for (k in this.domElements) if (this.domElements[k].tagName === 'CANVAS') this.domElements[k].width = this.domElements[k].width; this.contexts.nodes.clear(this.contexts.nodes.COLOR_BUFFER_BIT); this.contexts.edges.clear(this.contexts.edges.COLOR_BUFFER_BIT); return this; }; /** * This method kills contexts and other attributes. */ sigma.renderers.webgl.prototype.kill = function() { var k, captor; // Kill captors: while ((captor = this.captors.pop())) captor.kill(); delete this.captors; // Kill contexts: for (k in this.domElements) { this.domElements[k].parentNode.removeChild(this.domElements[k]); delete this.domElements[k]; delete this.contexts[k]; } delete this.domElements; delete this.contexts; }; /** * The object "sigma.webgl.nodes" contains the different WebGL node * renderers. The default one draw nodes as discs. Here are the attributes * any node renderer must have: * * {number} POINTS The number of points required to draw a node. * {number} ATTRIBUTES The number of attributes needed to draw one point. * {function} addNode A function that adds a node to the data stack that * will be given to the buffer. Here is the arguments: * > {object} node * > {number} index The node index in the * nodes array. * > {Float32Array} data The stack. * > {object} options Some options. * {function} render The function that will effectively render the nodes * into the buffer. * > {WebGLRenderingContext} gl * > {WebGLProgram} program * > {Float32Array} data The stack to give to the * buffer. * > {object} params An object containing some * options, like width, * height, the camera ratio. * {function} initProgram The function that will initiate the program, with * the relevant shaders and parameters. It must return * the newly created program. * * Check sigma.webgl.nodes.def or sigma.webgl.nodes.fast to see how it * works more precisely. */ sigma.utils.pkg('sigma.webgl.nodes'); /** * The object "sigma.webgl.edges" contains the different WebGL edge * renderers. The default one draw edges as direct lines. Here are the * attributes any edge renderer must have: * * {number} POINTS The number of points required to draw an edge. * {number} ATTRIBUTES The number of attributes needed to draw one point. * {function} addEdge A function that adds an edge to the data stack that * will be given to the buffer. Here is the arguments: * > {object} edge * > {object} source * > {object} target * > {Float32Array} data The stack. * > {object} options Some options. * {function} render The function that will effectively render the edges * into the buffer. * > {WebGLRenderingContext} gl * > {WebGLProgram} program * > {Float32Array} data The stack to give to the * buffer. * > {object} params An object containing some * options, like width, * height, the camera ratio. * {function} initProgram The function that will initiate the program, with * the relevant shaders and parameters. It must return * the newly created program. * * Check sigma.webgl.edges.def or sigma.webgl.edges.fast to see how it * works more precisely. */ sigma.utils.pkg('sigma.webgl.edges'); /** * The object "sigma.canvas.labels" contains the different * label renderers for the WebGL renderer. Since displaying texts in WebGL is * definitely painful and since there a way less labels to display than nodes * or edges, the default renderer simply renders them in a canvas. * * A labels renderer is a simple function, taking as arguments the related * node, the renderer and a settings function. */ sigma.utils.pkg('sigma.canvas.labels'); }).call(this); ;(function(undefined) { 'use strict'; if (typeof sigma === 'undefined') throw 'sigma is not declared'; if (typeof conrad === 'undefined') throw 'conrad is not declared'; // Initialize packages: sigma.utils.pkg('sigma.renderers'); /** * This function is the constructor of the svg sigma's renderer. * * @param {sigma.classes.graph} graph The graph to render. * @param {sigma.classes.camera} camera The camera. * @param {configurable} settings The sigma instance settings * function. * @param {object} object The options object. * @return {sigma.renderers.svg} The renderer instance. */ sigma.renderers.svg = function(graph, camera, settings, options) { if (typeof options !== 'object') throw 'sigma.renderers.svg: Wrong arguments.'; if (!(options.container instanceof HTMLElement)) throw 'Container not found.'; var i, l, a, fn, self = this; sigma.classes.dispatcher.extend(this); // Initialize main attributes: this.graph = graph; this.camera = camera; this.domElements = { graph: null, groups: {}, nodes: {}, edges: {}, labels: {}, hovers: {} }; this.measurementCanvas = null; this.options = options; this.container = this.options.container; this.settings = ( typeof options.settings === 'object' && options.settings ) ? settings.embedObjects(options.settings) : settings; // Is the renderer meant to be freestyle? this.settings('freeStyle', !!this.options.freeStyle); // SVG xmlns this.settings('xmlns', 'http://www.w3.org/2000/svg'); // Indexes: this.nodesOnScreen = []; this.edgesOnScreen = []; // Find the prefix: this.options.prefix = 'renderer' + sigma.utils.id() + ':'; // Initialize the DOM elements this.initDOM('svg'); // Initialize captors: this.captors = []; a = this.options.captors || [sigma.captors.mouse, sigma.captors.touch]; for (i = 0, l = a.length; i < l; i++) { fn = typeof a[i] === 'function' ? a[i] : sigma.captors[a[i]]; this.captors.push( new fn( this.domElements.graph, this.camera, this.settings ) ); } // Bind resize: window.addEventListener('resize', function() { self.resize(); }); // Deal with sigma events: // TODO: keep an option to override the DOM events? sigma.misc.bindDOMEvents.call(this, this.domElements.graph); this.bindHovers(this.options.prefix); // Resize this.resize(false); }; /** * This method renders the graph on the svg scene. * * @param {?object} options Eventually an object of options. * @return {sigma.renderers.svg} Returns the instance itself. */ sigma.renderers.svg.prototype.render = function(options) { options = options || {}; var a, i, k, e, l, o, source, target, start, edges, renderers, subrenderers, index = {}, graph = this.graph, nodes = this.graph.nodes, prefix = this.options.prefix || '', drawEdges = this.settings(options, 'drawEdges'), drawNodes = this.settings(options, 'drawNodes'), drawLabels = this.settings(options, 'drawLabels'), embedSettings = this.settings.embedObjects(options, { prefix: this.options.prefix, forceLabels: this.options.forceLabels }); // Check the 'hideEdgesOnMove' setting: if (this.settings(options, 'hideEdgesOnMove')) if (this.camera.isAnimated || this.camera.isMoving) drawEdges = false; // Apply the camera's view: this.camera.applyView( undefined, this.options.prefix, { width: this.width, height: this.height } ); // Hiding everything // TODO: find a more sensible way to perform this operation this.hideDOMElements(this.domElements.nodes); this.hideDOMElements(this.domElements.edges); this.hideDOMElements(this.domElements.labels); // Find which nodes are on screen this.edgesOnScreen = []; this.nodesOnScreen = this.camera.quadtree.area( this.camera.getRectangle(this.width, this.height) ); // Node index for (a = this.nodesOnScreen, i = 0, l = a.length; i < l; i++) index[a[i].id] = a[i]; // Find which edges are on screen for (a = graph.edges(), i = 0, l = a.length; i < l; i++) { o = a[i]; if ( (index[o.source] || index[o.target]) && (!o.hidden && !nodes(o.source).hidden && !nodes(o.target).hidden) ) this.edgesOnScreen.push(o); } // Display nodes //--------------- renderers = sigma.svg.nodes; subrenderers = sigma.svg.labels; //-- First we create the nodes which are not already created if (drawNodes) for (a = this.nodesOnScreen, i = 0, l = a.length; i < l; i++) { if (!a[i].hidden && !this.domElements.nodes[a[i].id]) { // Node e = (renderers[a[i].type] || renderers.def).create( a[i], embedSettings ); this.domElements.nodes[a[i].id] = e; this.domElements.groups.nodes.appendChild(e); // Label e = (subrenderers[a[i].type] || subrenderers.def).create( a[i], embedSettings ); this.domElements.labels[a[i].id] = e; this.domElements.groups.labels.appendChild(e); } } //-- Second we update the nodes if (drawNodes) for (a = this.nodesOnScreen, i = 0, l = a.length; i < l; i++) { if (a[i].hidden) continue; // Node (renderers[a[i].type] || renderers.def).update( a[i], this.domElements.nodes[a[i].id], embedSettings ); // Label (subrenderers[a[i].type] || subrenderers.def).update( a[i], this.domElements.labels[a[i].id], embedSettings ); } // Display edges //--------------- renderers = sigma.svg.edges; //-- First we create the edges which are not already created if (drawEdges) for (a = this.edgesOnScreen, i = 0, l = a.length; i < l; i++) { if (!this.domElements.edges[a[i].id]) { source = nodes(a[i].source); target = nodes(a[i].target); e = (renderers[a[i].type] || renderers.def).create( a[i], source, target, embedSettings ); this.domElements.edges[a[i].id] = e; this.domElements.groups.edges.appendChild(e); } } //-- Second we update the edges if (drawEdges) for (a = this.edgesOnScreen, i = 0, l = a.length; i < l; i++) { source = nodes(a[i].source); target = nodes(a[i].target); (renderers[a[i].type] || renderers.def).update( a[i], this.domElements.edges[a[i].id], source, target, embedSettings ); } this.dispatchEvent('render'); return this; }; /** * This method creates a DOM element of the specified type, switches its * position to "absolute", references it to the domElements attribute, and * finally appends it to the container. * * @param {string} tag The label tag. * @param {string} id The id of the element (to store it in "domElements"). */ sigma.renderers.svg.prototype.initDOM = function(tag) { var dom = document.createElementNS(this.settings('xmlns'), tag), c = this.settings('classPrefix'), g, l, i; dom.style.position = 'absolute'; dom.setAttribute('class', c + '-svg'); // Setting SVG namespace dom.setAttribute('xmlns', this.settings('xmlns')); dom.setAttribute('xmlns:xlink', 'http://www.w3.org/1999/xlink'); dom.setAttribute('version', '1.1'); // Creating the measurement canvas var canvas = document.createElement('canvas'); canvas.setAttribute('class', c + '-measurement-canvas'); // Appending elements this.domElements.graph = this.container.appendChild(dom); // Creating groups var groups = ['edges', 'nodes', 'labels', 'hovers']; for (i = 0, l = groups.length; i < l; i++) { g = document.createElementNS(this.settings('xmlns'), 'g'); g.setAttributeNS(null, 'id', c + '-group-' + groups[i]); g.setAttributeNS(null, 'class', c + '-group'); this.domElements.groups[groups[i]] = this.domElements.graph.appendChild(g); } // Appending measurement canvas this.container.appendChild(canvas); this.measurementCanvas = canvas.getContext('2d'); }; /** * This method hides a batch of SVG DOM elements. * * @param {array} elements An array of elements to hide. * @param {object} renderer The renderer to use. * @return {sigma.renderers.svg} Returns the instance itself. */ sigma.renderers.svg.prototype.hideDOMElements = function(elements) { var o, i; for (i in elements) { o = elements[i]; sigma.svg.utils.hide(o); } return this; }; /** * This method binds the hover events to the renderer. * * @param {string} prefix The renderer prefix. */ // TODO: add option about whether to display hovers or not sigma.renderers.svg.prototype.bindHovers = function(prefix) { var renderers = sigma.svg.hovers, self = this, hoveredNode; function overNode(e) { var node = e.data.node, embedSettings = self.settings.embedObjects({ prefix: prefix }); if (!embedSettings('enableHovering')) return; var hover = (renderers[node.type] || renderers.def).create( node, self.domElements.nodes[node.id], self.measurementCanvas, embedSettings ); self.domElements.hovers[node.id] = hover; // Inserting the hover in the dom self.domElements.groups.hovers.appendChild(hover); hoveredNode = node; } function outNode(e) { var node = e.data.node, embedSettings = self.settings.embedObjects({ prefix: prefix }); if (!embedSettings('enableHovering')) return; // Deleting element self.domElements.groups.hovers.removeChild( self.domElements.hovers[node.id] ); hoveredNode = null; delete self.domElements.hovers[node.id]; // Reinstate self.domElements.groups.nodes.appendChild( self.domElements.nodes[node.id] ); } // OPTIMIZE: perform a real update rather than a deletion function update() { if (!hoveredNode) return; var embedSettings = self.settings.embedObjects({ prefix: prefix }); // Deleting element before update self.domElements.groups.hovers.removeChild( self.domElements.hovers[hoveredNode.id] ); delete self.domElements.hovers[hoveredNode.id]; var hover = (renderers[hoveredNode.type] || renderers.def).create( hoveredNode, self.domElements.nodes[hoveredNode.id], self.measurementCanvas, embedSettings ); self.domElements.hovers[hoveredNode.id] = hover; // Inserting the hover in the dom self.domElements.groups.hovers.appendChild(hover); } // Binding events this.bind('overNode', overNode); this.bind('outNode', outNode); // Update on render this.bind('render', update); }; /** * This method resizes each DOM elements in the container and stores the new * dimensions. Then, it renders the graph. * * @param {?number} width The new width of the container. * @param {?number} height The new height of the container. * @return {sigma.renderers.svg} Returns the instance itself. */ sigma.renderers.svg.prototype.resize = function(w, h) { var oldWidth = this.width, oldHeight = this.height, pixelRatio = 1; if (w !== undefined && h !== undefined) { this.width = w; this.height = h; } else { this.width = this.container.offsetWidth; this.height = this.container.offsetHeight; w = this.width; h = this.height; } if (oldWidth !== this.width || oldHeight !== this.height) { this.domElements.graph.style.width = w + 'px'; this.domElements.graph.style.height = h + 'px'; if (this.domElements.graph.tagName.toLowerCase() === 'svg') { this.domElements.graph.setAttribute('width', (w * pixelRatio)); this.domElements.graph.setAttribute('height', (h * pixelRatio)); } } return this; }; /** * The labels, nodes and edges renderers are stored in the three following * objects. When an element is drawn, its type will be checked and if a * renderer with the same name exists, it will be used. If not found, the * default renderer will be used instead. * * They are stored in different files, in the "./svg" folder. */ sigma.utils.pkg('sigma.svg.nodes'); sigma.utils.pkg('sigma.svg.edges'); sigma.utils.pkg('sigma.svg.labels'); }).call(this); ;(function(global) { 'use strict'; if (typeof sigma === 'undefined') throw 'sigma is not declared'; // Initialize packages: sigma.utils.pkg('sigma.renderers'); // Check if WebGL is enabled: var canvas, webgl = !!global.WebGLRenderingContext; if (webgl) { canvas = document.createElement('canvas'); try { webgl = !!( canvas.getContext('webgl') || canvas.getContext('experimental-webgl') ); } catch (e) { webgl = false; } } // Copy the good renderer: sigma.renderers.def = webgl ? sigma.renderers.webgl : sigma.renderers.canvas; })(this); ;(function() { 'use strict'; sigma.utils.pkg('sigma.webgl.nodes'); /** * This node renderer will display nodes as discs, shaped in triangles with * the gl.TRIANGLES display mode. So, to be more precise, to draw one node, * it will store three times the center of node, with the color and the size, * and an angle indicating which "corner" of the triangle to draw. * * The fragment shader does not deal with anti-aliasing, so make sure that * you deal with it somewhere else in the code (by default, the WebGL * renderer will oversample the rendering through the webglOversamplingRatio * value). */ sigma.webgl.nodes.def = { POINTS: 3, ATTRIBUTES: 5, addNode: function(node, data, i, prefix, settings) { var color = sigma.utils.floatColor( node.color || settings('defaultNodeColor') ); data[i++] = node[prefix + 'x']; data[i++] = node[prefix + 'y']; data[i++] = node[prefix + 'size']; data[i++] = color; data[i++] = 0; data[i++] = node[prefix + 'x']; data[i++] = node[prefix + 'y']; data[i++] = node[prefix + 'size']; data[i++] = color; data[i++] = 2 * Math.PI / 3; data[i++] = node[prefix + 'x']; data[i++] = node[prefix + 'y']; data[i++] = node[prefix + 'size']; data[i++] = color; data[i++] = 4 * Math.PI / 3; }, render: function(gl, program, data, params) { var buffer; // Define attributes: var positionLocation = gl.getAttribLocation(program, 'a_position'), sizeLocation = gl.getAttribLocation(program, 'a_size'), colorLocation = gl.getAttribLocation(program, 'a_color'), angleLocation = gl.getAttribLocation(program, 'a_angle'), resolutionLocation = gl.getUniformLocation(program, 'u_resolution'), matrixLocation = gl.getUniformLocation(program, 'u_matrix'), ratioLocation = gl.getUniformLocation(program, 'u_ratio'), scaleLocation = gl.getUniformLocation(program, 'u_scale'); buffer = gl.createBuffer(); gl.bindBuffer(gl.ARRAY_BUFFER, buffer); gl.bufferData(gl.ARRAY_BUFFER, data, gl.DYNAMIC_DRAW); gl.uniform2f(resolutionLocation, params.width, params.height); gl.uniform1f( ratioLocation, 1 / Math.pow(params.ratio, params.settings('nodesPowRatio')) ); gl.uniform1f(scaleLocation, params.scalingRatio); gl.uniformMatrix3fv(matrixLocation, false, params.matrix); gl.enableVertexAttribArray(positionLocation); gl.enableVertexAttribArray(sizeLocation); gl.enableVertexAttribArray(colorLocation); gl.enableVertexAttribArray(angleLocation); gl.vertexAttribPointer( positionLocation, 2, gl.FLOAT, false, this.ATTRIBUTES * Float32Array.BYTES_PER_ELEMENT, 0 ); gl.vertexAttribPointer( sizeLocation, 1, gl.FLOAT, false, this.ATTRIBUTES * Float32Array.BYTES_PER_ELEMENT, 8 ); gl.vertexAttribPointer( colorLocation, 1, gl.FLOAT, false, this.ATTRIBUTES * Float32Array.BYTES_PER_ELEMENT, 12 ); gl.vertexAttribPointer( angleLocation, 1, gl.FLOAT, false, this.ATTRIBUTES * Float32Array.BYTES_PER_ELEMENT, 16 ); gl.drawArrays( gl.TRIANGLES, params.start || 0, params.count || (data.length / this.ATTRIBUTES) ); }, initProgram: function(gl) { var vertexShader, fragmentShader, program; vertexShader = sigma.utils.loadShader( gl, [ 'attribute vec2 a_position;', 'attribute float a_size;', 'attribute float a_color;', 'attribute float a_angle;', 'uniform vec2 u_resolution;', 'uniform float u_ratio;', 'uniform float u_scale;', 'uniform mat3 u_matrix;', 'varying vec4 color;', 'varying vec2 center;', 'varying float radius;', 'void main() {', // Multiply the point size twice: 'radius = a_size * u_ratio;', // Scale from [[-1 1] [-1 1]] to the container: 'vec2 position = (u_matrix * vec3(a_position, 1)).xy;', // 'center = (position / u_resolution * 2.0 - 1.0) * vec2(1, -1);', 'center = position * u_scale;', 'center = vec2(center.x, u_scale * u_resolution.y - center.y);', 'position = position +', '2.0 * radius * vec2(cos(a_angle), sin(a_angle));', 'position = (position / u_resolution * 2.0 - 1.0) * vec2(1, -1);', 'radius = radius * u_scale;', 'gl_Position = vec4(position, 0, 1);', // Extract the color: 'float c = a_color;', 'color.b = mod(c, 256.0); c = floor(c / 256.0);', 'color.g = mod(c, 256.0); c = floor(c / 256.0);', 'color.r = mod(c, 256.0); c = floor(c / 256.0); color /= 255.0;', 'color.a = 1.0;', '}' ].join('\n'), gl.VERTEX_SHADER ); fragmentShader = sigma.utils.loadShader( gl, [ 'precision mediump float;', 'varying vec4 color;', 'varying vec2 center;', 'varying float radius;', 'void main(void) {', 'vec4 color0 = vec4(0.0, 0.0, 0.0, 0.0);', 'vec2 m = gl_FragCoord.xy - center;', 'float diff = radius - sqrt(m.x * m.x + m.y * m.y);', // Here is how we draw a disc instead of a square: 'if (diff > 0.0)', 'gl_FragColor = color;', 'else', 'gl_FragColor = color0;', '}' ].join('\n'), gl.FRAGMENT_SHADER ); program = sigma.utils.loadProgram(gl, [vertexShader, fragmentShader]); return program; } }; })(); ;(function() { 'use strict'; sigma.utils.pkg('sigma.webgl.nodes'); /** * This node renderer will display nodes in the fastest way: Nodes are basic * squares, drawn through the gl.POINTS drawing method. The size of the nodes * are represented with the "gl_PointSize" value in the vertex shader. * * It is the fastest node renderer here since the buffer just takes one line * to draw each node (with attributes "x", "y", "size" and "color"). * * Nevertheless, this method has some problems, especially due to some issues * with the gl.POINTS: * - First, if the center of a node is outside the scene, the point will not * be drawn, even if it should be partly on screen. * - I tried applying a fragment shader similar to the one in the default * node renderer to display them as discs, but it did not work fine on * some computers settings, filling the discs with weird gradients not * depending on the actual color. */ sigma.webgl.nodes.fast = { POINTS: 1, ATTRIBUTES: 4, addNode: function(node, data, i, prefix, settings) { data[i++] = node[prefix + 'x']; data[i++] = node[prefix + 'y']; data[i++] = node[prefix + 'size']; data[i++] = sigma.utils.floatColor( node.color || settings('defaultNodeColor') ); }, render: function(gl, program, data, params) { var buffer; // Define attributes: var positionLocation = gl.getAttribLocation(program, 'a_position'), sizeLocation = gl.getAttribLocation(program, 'a_size'), colorLocation = gl.getAttribLocation(program, 'a_color'), resolutionLocation = gl.getUniformLocation(program, 'u_resolution'), matrixLocation = gl.getUniformLocation(program, 'u_matrix'), ratioLocation = gl.getUniformLocation(program, 'u_ratio'), scaleLocation = gl.getUniformLocation(program, 'u_scale'); buffer = gl.createBuffer(); gl.bindBuffer(gl.ARRAY_BUFFER, buffer); gl.bufferData(gl.ARRAY_BUFFER, data, gl.DYNAMIC_DRAW); gl.uniform2f(resolutionLocation, params.width, params.height); gl.uniform1f( ratioLocation, 1 / Math.pow(params.ratio, params.settings('nodesPowRatio')) ); gl.uniform1f(scaleLocation, params.scalingRatio); gl.uniformMatrix3fv(matrixLocation, false, params.matrix); gl.enableVertexAttribArray(positionLocation); gl.enableVertexAttribArray(sizeLocation); gl.enableVertexAttribArray(colorLocation); gl.vertexAttribPointer( positionLocation, 2, gl.FLOAT, false, this.ATTRIBUTES * Float32Array.BYTES_PER_ELEMENT, 0 ); gl.vertexAttribPointer( sizeLocation, 1, gl.FLOAT, false, this.ATTRIBUTES * Float32Array.BYTES_PER_ELEMENT, 8 ); gl.vertexAttribPointer( colorLocation, 1, gl.FLOAT, false, this.ATTRIBUTES * Float32Array.BYTES_PER_ELEMENT, 12 ); gl.drawArrays( gl.POINTS, params.start || 0, params.count || (data.length / this.ATTRIBUTES) ); }, initProgram: function(gl) { var vertexShader, fragmentShader, program; vertexShader = sigma.utils.loadShader( gl, [ 'attribute vec2 a_position;', 'attribute float a_size;', 'attribute float a_color;', 'uniform vec2 u_resolution;', 'uniform float u_ratio;', 'uniform float u_scale;', 'uniform mat3 u_matrix;', 'varying vec4 color;', 'void main() {', // Scale from [[-1 1] [-1 1]] to the container: 'gl_Position = vec4(', '((u_matrix * vec3(a_position, 1)).xy /', 'u_resolution * 2.0 - 1.0) * vec2(1, -1),', '0,', '1', ');', // Multiply the point size twice: // - x SCALING_RATIO to correct the canvas scaling // - x 2 to correct the formulae 'gl_PointSize = a_size * u_ratio * u_scale * 2.0;', // Extract the color: 'float c = a_color;', 'color.b = mod(c, 256.0); c = floor(c / 256.0);', 'color.g = mod(c, 256.0); c = floor(c / 256.0);', 'color.r = mod(c, 256.0); c = floor(c / 256.0); color /= 255.0;', 'color.a = 1.0;', '}' ].join('\n'), gl.VERTEX_SHADER ); fragmentShader = sigma.utils.loadShader( gl, [ 'precision mediump float;', 'varying vec4 color;', 'void main(void) {', 'gl_FragColor = color;', '}' ].join('\n'), gl.FRAGMENT_SHADER ); program = sigma.utils.loadProgram(gl, [vertexShader, fragmentShader]); return program; } }; })(); ;(function() { 'use strict'; sigma.utils.pkg('sigma.webgl.edges'); /** * This edge renderer will display edges as lines going from the source node * to the target node. To deal with edge thicknesses, the lines are made of * two triangles forming rectangles, with the gl.TRIANGLES drawing mode. * * It is expensive, since drawing a single edge requires 6 points, each * having 7 attributes (source position, target position, thickness, color * and a flag indicating which vertice of the rectangle it is). */ sigma.webgl.edges.def = { POINTS: 6, ATTRIBUTES: 7, addEdge: function(edge, source, target, data, i, prefix, settings) { var w = (edge[prefix + 'size'] || 1) / 2, x1 = source[prefix + 'x'], y1 = source[prefix + 'y'], x2 = target[prefix + 'x'], y2 = target[prefix + 'y'], color = edge.color; if (!color) switch (settings('edgeColor')) { case 'source': color = source.color || settings('defaultNodeColor'); break; case 'target': color = target.color || settings('defaultNodeColor'); break; default: color = settings('defaultEdgeColor'); break; } // Normalize color: color = sigma.utils.floatColor(color); data[i++] = x1; data[i++] = y1; data[i++] = x2; data[i++] = y2; data[i++] = w; data[i++] = 0.0; data[i++] = color; data[i++] = x2; data[i++] = y2; data[i++] = x1; data[i++] = y1; data[i++] = w; data[i++] = 1.0; data[i++] = color; data[i++] = x2; data[i++] = y2; data[i++] = x1; data[i++] = y1; data[i++] = w; data[i++] = 0.0; data[i++] = color; data[i++] = x2; data[i++] = y2; data[i++] = x1; data[i++] = y1; data[i++] = w; data[i++] = 0.0; data[i++] = color; data[i++] = x1; data[i++] = y1; data[i++] = x2; data[i++] = y2; data[i++] = w; data[i++] = 1.0; data[i++] = color; data[i++] = x1; data[i++] = y1; data[i++] = x2; data[i++] = y2; data[i++] = w; data[i++] = 0.0; data[i++] = color; }, render: function(gl, program, data, params) { var buffer; // Define attributes: var colorLocation = gl.getAttribLocation(program, 'a_color'), positionLocation1 = gl.getAttribLocation(program, 'a_position1'), positionLocation2 = gl.getAttribLocation(program, 'a_position2'), thicknessLocation = gl.getAttribLocation(program, 'a_thickness'), minusLocation = gl.getAttribLocation(program, 'a_minus'), resolutionLocation = gl.getUniformLocation(program, 'u_resolution'), matrixLocation = gl.getUniformLocation(program, 'u_matrix'), matrixHalfPiLocation = gl.getUniformLocation(program, 'u_matrixHalfPi'), matrixHalfPiMinusLocation = gl.getUniformLocation(program, 'u_matrixHalfPiMinus'), ratioLocation = gl.getUniformLocation(program, 'u_ratio'), scaleLocation = gl.getUniformLocation(program, 'u_scale'); buffer = gl.createBuffer(); gl.bindBuffer(gl.ARRAY_BUFFER, buffer); gl.bufferData(gl.ARRAY_BUFFER, data, gl.STATIC_DRAW); gl.uniform2f(resolutionLocation, params.width, params.height); gl.uniform1f( ratioLocation, params.ratio / Math.pow(params.ratio, params.settings('edgesPowRatio')) ); gl.uniform1f(scaleLocation, params.scalingRatio); gl.uniformMatrix3fv(matrixLocation, false, params.matrix); gl.uniformMatrix2fv( matrixHalfPiLocation, false, sigma.utils.matrices.rotation(Math.PI / 2, true) ); gl.uniformMatrix2fv( matrixHalfPiMinusLocation, false, sigma.utils.matrices.rotation(-Math.PI / 2, true) ); gl.enableVertexAttribArray(colorLocation); gl.enableVertexAttribArray(positionLocation1); gl.enableVertexAttribArray(positionLocation2); gl.enableVertexAttribArray(thicknessLocation); gl.enableVertexAttribArray(minusLocation); gl.vertexAttribPointer(positionLocation1, 2, gl.FLOAT, false, this.ATTRIBUTES * Float32Array.BYTES_PER_ELEMENT, 0 ); gl.vertexAttribPointer(positionLocation2, 2, gl.FLOAT, false, this.ATTRIBUTES * Float32Array.BYTES_PER_ELEMENT, 8 ); gl.vertexAttribPointer(thicknessLocation, 1, gl.FLOAT, false, this.ATTRIBUTES * Float32Array.BYTES_PER_ELEMENT, 16 ); gl.vertexAttribPointer(minusLocation, 1, gl.FLOAT, false, this.ATTRIBUTES * Float32Array.BYTES_PER_ELEMENT, 20 ); gl.vertexAttribPointer(colorLocation, 1, gl.FLOAT, false, this.ATTRIBUTES * Float32Array.BYTES_PER_ELEMENT, 24 ); gl.drawArrays( gl.TRIANGLES, params.start || 0, params.count || (data.length / this.ATTRIBUTES) ); }, initProgram: function(gl) { var vertexShader, fragmentShader, program; vertexShader = sigma.utils.loadShader( gl, [ 'attribute vec2 a_position1;', 'attribute vec2 a_position2;', 'attribute float a_thickness;', 'attribute float a_minus;', 'attribute float a_color;', 'uniform vec2 u_resolution;', 'uniform float u_ratio;', 'uniform float u_scale;', 'uniform mat3 u_matrix;', 'uniform mat2 u_matrixHalfPi;', 'uniform mat2 u_matrixHalfPiMinus;', 'varying vec4 color;', 'void main() {', // Find the good point: 'vec2 position = a_thickness * u_ratio *', 'normalize(a_position2 - a_position1);', 'mat2 matrix = a_minus * u_matrixHalfPiMinus +', '(1.0 - a_minus) * u_matrixHalfPi;', 'position = matrix * position + a_position1;', // Scale from [[-1 1] [-1 1]] to the container: 'gl_Position = vec4(', '((u_matrix * vec3(position, 1)).xy /', 'u_resolution * 2.0 - 1.0) * vec2(1, -1),', '0,', '1', ');', // Extract the color: 'float c = a_color;', 'color.b = mod(c, 256.0); c = floor(c / 256.0);', 'color.g = mod(c, 256.0); c = floor(c / 256.0);', 'color.r = mod(c, 256.0); c = floor(c / 256.0); color /= 255.0;', 'color.a = 1.0;', '}' ].join('\n'), gl.VERTEX_SHADER ); fragmentShader = sigma.utils.loadShader( gl, [ 'precision mediump float;', 'varying vec4 color;', 'void main(void) {', 'gl_FragColor = color;', '}' ].join('\n'), gl.FRAGMENT_SHADER ); program = sigma.utils.loadProgram(gl, [vertexShader, fragmentShader]); return program; } }; })(); ;(function() { 'use strict'; sigma.utils.pkg('sigma.webgl.edges'); /** * This edge renderer will display edges as lines with the gl.LINES display * mode. Since this mode does not support well thickness, edges are all drawn * with the same thickness (3px), independantly of the edge attributes or the * zooming ratio. */ sigma.webgl.edges.fast = { POINTS: 2, ATTRIBUTES: 3, addEdge: function(edge, source, target, data, i, prefix, settings) { var w = (edge[prefix + 'size'] || 1) / 2, x1 = source[prefix + 'x'], y1 = source[prefix + 'y'], x2 = target[prefix + 'x'], y2 = target[prefix + 'y'], color = edge.color; if (!color) switch (settings('edgeColor')) { case 'source': color = source.color || settings('defaultNodeColor'); break; case 'target': color = target.color || settings('defaultNodeColor'); break; default: color = settings('defaultEdgeColor'); break; } // Normalize color: color = sigma.utils.floatColor(color); data[i++] = x1; data[i++] = y1; data[i++] = color; data[i++] = x2; data[i++] = y2; data[i++] = color; }, render: function(gl, program, data, params) { var buffer; // Define attributes: var colorLocation = gl.getAttribLocation(program, 'a_color'), positionLocation = gl.getAttribLocation(program, 'a_position'), resolutionLocation = gl.getUniformLocation(program, 'u_resolution'), matrixLocation = gl.getUniformLocation(program, 'u_matrix'); buffer = gl.createBuffer(); gl.bindBuffer(gl.ARRAY_BUFFER, buffer); gl.bufferData(gl.ARRAY_BUFFER, data, gl.DYNAMIC_DRAW); gl.uniform2f(resolutionLocation, params.width, params.height); gl.uniformMatrix3fv(matrixLocation, false, params.matrix); gl.enableVertexAttribArray(positionLocation); gl.enableVertexAttribArray(colorLocation); gl.vertexAttribPointer(positionLocation, 2, gl.FLOAT, false, this.ATTRIBUTES * Float32Array.BYTES_PER_ELEMENT, 0 ); gl.vertexAttribPointer(colorLocation, 1, gl.FLOAT, false, this.ATTRIBUTES * Float32Array.BYTES_PER_ELEMENT, 8 ); gl.lineWidth(3); gl.drawArrays( gl.LINES, params.start || 0, params.count || (data.length / this.ATTRIBUTES) ); }, initProgram: function(gl) { var vertexShader, fragmentShader, program; vertexShader = sigma.utils.loadShader( gl, [ 'attribute vec2 a_position;', 'attribute float a_color;', 'uniform vec2 u_resolution;', 'uniform mat3 u_matrix;', 'varying vec4 color;', 'void main() {', // Scale from [[-1 1] [-1 1]] to the container: 'gl_Position = vec4(', '((u_matrix * vec3(a_position, 1)).xy /', 'u_resolution * 2.0 - 1.0) * vec2(1, -1),', '0,', '1', ');', // Extract the color: 'float c = a_color;', 'color.b = mod(c, 256.0); c = floor(c / 256.0);', 'color.g = mod(c, 256.0); c = floor(c / 256.0);', 'color.r = mod(c, 256.0); c = floor(c / 256.0); color /= 255.0;', 'color.a = 1.0;', '}' ].join('\n'), gl.VERTEX_SHADER ); fragmentShader = sigma.utils.loadShader( gl, [ 'precision mediump float;', 'varying vec4 color;', 'void main(void) {', 'gl_FragColor = color;', '}' ].join('\n'), gl.FRAGMENT_SHADER ); program = sigma.utils.loadProgram(gl, [vertexShader, fragmentShader]); return program; } }; })(); ;(function() { 'use strict'; sigma.utils.pkg('sigma.webgl.edges'); /** * This edge renderer will display edges as arrows going from the source node * to the target node. To deal with edge thicknesses, the lines are made of * three triangles: two forming rectangles, with the gl.TRIANGLES drawing * mode. * * It is expensive, since drawing a single edge requires 9 points, each * having a lot of attributes. */ sigma.webgl.edges.arrow = { POINTS: 9, ATTRIBUTES: 11, addEdge: function(edge, source, target, data, i, prefix, settings) { var w = (edge[prefix + 'size'] || 1) / 2, x1 = source[prefix + 'x'], y1 = source[prefix + 'y'], x2 = target[prefix + 'x'], y2 = target[prefix + 'y'], targetSize = target[prefix + 'size'], color = edge.color; if (!color) switch (settings('edgeColor')) { case 'source': color = source.color || settings('defaultNodeColor'); break; case 'target': color = target.color || settings('defaultNodeColor'); break; default: color = settings('defaultEdgeColor'); break; } // Normalize color: color = sigma.utils.floatColor(color); data[i++] = x1; data[i++] = y1; data[i++] = x2; data[i++] = y2; data[i++] = w; data[i++] = targetSize; data[i++] = 0.0; data[i++] = 0.0; data[i++] = 0.0; data[i++] = 0.0; data[i++] = color; data[i++] = x2; data[i++] = y2; data[i++] = x1; data[i++] = y1; data[i++] = w; data[i++] = targetSize; data[i++] = 1.0; data[i++] = 1.0; data[i++] = 0.0; data[i++] = 0.0; data[i++] = color; data[i++] = x2; data[i++] = y2; data[i++] = x1; data[i++] = y1; data[i++] = w; data[i++] = targetSize; data[i++] = 1.0; data[i++] = 0.0; data[i++] = 0.0; data[i++] = 0.0; data[i++] = color; data[i++] = x2; data[i++] = y2; data[i++] = x1; data[i++] = y1; data[i++] = w; data[i++] = targetSize; data[i++] = 1.0; data[i++] = 0.0; data[i++] = 0.0; data[i++] = 0.0; data[i++] = color; data[i++] = x1; data[i++] = y1; data[i++] = x2; data[i++] = y2; data[i++] = w; data[i++] = targetSize; data[i++] = 0.0; data[i++] = 1.0; data[i++] = 0.0; data[i++] = 0.0; data[i++] = color; data[i++] = x1; data[i++] = y1; data[i++] = x2; data[i++] = y2; data[i++] = w; data[i++] = targetSize; data[i++] = 0.0; data[i++] = 0.0; data[i++] = 0.0; data[i++] = 0.0; data[i++] = color; // Arrow head: data[i++] = x2; data[i++] = y2; data[i++] = x1; data[i++] = y1; data[i++] = w; data[i++] = targetSize; data[i++] = 1.0; data[i++] = 0.0; data[i++] = 1.0; data[i++] = -1.0; data[i++] = color; data[i++] = x2; data[i++] = y2; data[i++] = x1; data[i++] = y1; data[i++] = w; data[i++] = targetSize; data[i++] = 1.0; data[i++] = 0.0; data[i++] = 1.0; data[i++] = 0.0; data[i++] = color; data[i++] = x2; data[i++] = y2; data[i++] = x1; data[i++] = y1; data[i++] = w; data[i++] = targetSize; data[i++] = 1.0; data[i++] = 0.0; data[i++] = 1.0; data[i++] = 1.0; data[i++] = color; }, render: function(gl, program, data, params) { var buffer; // Define attributes: var positionLocation1 = gl.getAttribLocation(program, 'a_pos1'), positionLocation2 = gl.getAttribLocation(program, 'a_pos2'), thicknessLocation = gl.getAttribLocation(program, 'a_thickness'), targetSizeLocation = gl.getAttribLocation(program, 'a_tSize'), delayLocation = gl.getAttribLocation(program, 'a_delay'), minusLocation = gl.getAttribLocation(program, 'a_minus'), headLocation = gl.getAttribLocation(program, 'a_head'), headPositionLocation = gl.getAttribLocation(program, 'a_headPosition'), colorLocation = gl.getAttribLocation(program, 'a_color'), resolutionLocation = gl.getUniformLocation(program, 'u_resolution'), matrixLocation = gl.getUniformLocation(program, 'u_matrix'), matrixHalfPiLocation = gl.getUniformLocation(program, 'u_matrixHalfPi'), matrixHalfPiMinusLocation = gl.getUniformLocation(program, 'u_matrixHalfPiMinus'), ratioLocation = gl.getUniformLocation(program, 'u_ratio'), nodeRatioLocation = gl.getUniformLocation(program, 'u_nodeRatio'), arrowHeadLocation = gl.getUniformLocation(program, 'u_arrowHead'), scaleLocation = gl.getUniformLocation(program, 'u_scale'); buffer = gl.createBuffer(); gl.bindBuffer(gl.ARRAY_BUFFER, buffer); gl.bufferData(gl.ARRAY_BUFFER, data, gl.STATIC_DRAW); gl.uniform2f(resolutionLocation, params.width, params.height); gl.uniform1f( ratioLocation, params.ratio / Math.pow(params.ratio, params.settings('edgesPowRatio')) ); gl.uniform1f( nodeRatioLocation, Math.pow(params.ratio, params.settings('nodesPowRatio')) / params.ratio ); gl.uniform1f(arrowHeadLocation, 5.0); gl.uniform1f(scaleLocation, params.scalingRatio); gl.uniformMatrix3fv(matrixLocation, false, params.matrix); gl.uniformMatrix2fv( matrixHalfPiLocation, false, sigma.utils.matrices.rotation(Math.PI / 2, true) ); gl.uniformMatrix2fv( matrixHalfPiMinusLocation, false, sigma.utils.matrices.rotation(-Math.PI / 2, true) ); gl.enableVertexAttribArray(positionLocation1); gl.enableVertexAttribArray(positionLocation2); gl.enableVertexAttribArray(thicknessLocation); gl.enableVertexAttribArray(targetSizeLocation); gl.enableVertexAttribArray(delayLocation); gl.enableVertexAttribArray(minusLocation); gl.enableVertexAttribArray(headLocation); gl.enableVertexAttribArray(headPositionLocation); gl.enableVertexAttribArray(colorLocation); gl.vertexAttribPointer(positionLocation1, 2, gl.FLOAT, false, this.ATTRIBUTES * Float32Array.BYTES_PER_ELEMENT, 0 ); gl.vertexAttribPointer(positionLocation2, 2, gl.FLOAT, false, this.ATTRIBUTES * Float32Array.BYTES_PER_ELEMENT, 8 ); gl.vertexAttribPointer(thicknessLocation, 1, gl.FLOAT, false, this.ATTRIBUTES * Float32Array.BYTES_PER_ELEMENT, 16 ); gl.vertexAttribPointer(targetSizeLocation, 1, gl.FLOAT, false, this.ATTRIBUTES * Float32Array.BYTES_PER_ELEMENT, 20 ); gl.vertexAttribPointer(delayLocation, 1, gl.FLOAT, false, this.ATTRIBUTES * Float32Array.BYTES_PER_ELEMENT, 24 ); gl.vertexAttribPointer(minusLocation, 1, gl.FLOAT, false, this.ATTRIBUTES * Float32Array.BYTES_PER_ELEMENT, 28 ); gl.vertexAttribPointer(headLocation, 1, gl.FLOAT, false, this.ATTRIBUTES * Float32Array.BYTES_PER_ELEMENT, 32 ); gl.vertexAttribPointer(headPositionLocation, 1, gl.FLOAT, false, this.ATTRIBUTES * Float32Array.BYTES_PER_ELEMENT, 36 ); gl.vertexAttribPointer(colorLocation, 1, gl.FLOAT, false, this.ATTRIBUTES * Float32Array.BYTES_PER_ELEMENT, 40 ); gl.drawArrays( gl.TRIANGLES, params.start || 0, params.count || (data.length / this.ATTRIBUTES) ); }, initProgram: function(gl) { var vertexShader, fragmentShader, program; vertexShader = sigma.utils.loadShader( gl, [ 'attribute vec2 a_pos1;', 'attribute vec2 a_pos2;', 'attribute float a_thickness;', 'attribute float a_tSize;', 'attribute float a_delay;', 'attribute float a_minus;', 'attribute float a_head;', 'attribute float a_headPosition;', 'attribute float a_color;', 'uniform vec2 u_resolution;', 'uniform float u_ratio;', 'uniform float u_nodeRatio;', 'uniform float u_arrowHead;', 'uniform float u_scale;', 'uniform mat3 u_matrix;', 'uniform mat2 u_matrixHalfPi;', 'uniform mat2 u_matrixHalfPiMinus;', 'varying vec4 color;', 'void main() {', // Find the good point: 'vec2 pos = normalize(a_pos2 - a_pos1);', 'mat2 matrix = (1.0 - a_head) *', '(', 'a_minus * u_matrixHalfPiMinus +', '(1.0 - a_minus) * u_matrixHalfPi', ') + a_head * (', 'a_headPosition * u_matrixHalfPiMinus * 0.6 +', '(a_headPosition * a_headPosition - 1.0) * mat2(1.0)', ');', 'pos = a_pos1 + (', // Deal with body: '(1.0 - a_head) * a_thickness * u_ratio * matrix * pos +', // Deal with head: 'a_head * u_arrowHead * a_thickness * u_ratio * matrix * pos +', // Deal with delay: 'a_delay * pos * (', 'a_tSize / u_nodeRatio +', 'u_arrowHead * a_thickness * u_ratio', ')', ');', // Scale from [[-1 1] [-1 1]] to the container: 'gl_Position = vec4(', '((u_matrix * vec3(pos, 1)).xy /', 'u_resolution * 2.0 - 1.0) * vec2(1, -1),', '0,', '1', ');', // Extract the color: 'float c = a_color;', 'color.b = mod(c, 256.0); c = floor(c / 256.0);', 'color.g = mod(c, 256.0); c = floor(c / 256.0);', 'color.r = mod(c, 256.0); c = floor(c / 256.0); color /= 255.0;', 'color.a = 1.0;', '}' ].join('\n'), gl.VERTEX_SHADER ); fragmentShader = sigma.utils.loadShader( gl, [ 'precision mediump float;', 'varying vec4 color;', 'void main(void) {', 'gl_FragColor = color;', '}' ].join('\n'), gl.FRAGMENT_SHADER ); program = sigma.utils.loadProgram(gl, [vertexShader, fragmentShader]); return program; } }; })(); ;(function(undefined) { 'use strict'; if (typeof sigma === 'undefined') throw 'sigma is not declared'; // Initialize packages: sigma.utils.pkg('sigma.canvas.labels'); /** * This label renderer will just display the label on the right of the node. * * @param {object} node The node object. * @param {CanvasRenderingContext2D} context The canvas context. * @param {configurable} settings The settings function. */ sigma.canvas.labels.def = function(node, context, settings) { var fontSize, prefix = settings('prefix') || '', size = node[prefix + 'size']; if (size < settings('labelThreshold')) return; if (!node.label || typeof node.label !== 'string') return; fontSize = (settings('labelSize') === 'fixed') ? settings('defaultLabelSize') : settings('labelSizeRatio') * size; context.font = (settings('fontStyle') ? settings('fontStyle') + ' ' : '') + fontSize + 'px ' + settings('font'); context.fillStyle = (settings('labelColor') === 'node') ? (node.color || settings('defaultNodeColor')) : settings('defaultLabelColor'); context.fillText( node.label, Math.round(node[prefix + 'x'] + size + 3), Math.round(node[prefix + 'y'] + fontSize / 3) ); }; }).call(this); ;(function(undefined) { 'use strict'; if (typeof sigma === 'undefined') throw 'sigma is not declared'; // Initialize packages: sigma.utils.pkg('sigma.canvas.hovers'); /** * This hover renderer will basically display the label with a background. * * @param {object} node The node object. * @param {CanvasRenderingContext2D} context The canvas context. * @param {configurable} settings The settings function. */ sigma.canvas.hovers.def = function(node, context, settings) { var x, y, w, h, e, fontStyle = settings('hoverFontStyle') || settings('fontStyle'), prefix = settings('prefix') || '', size = node[prefix + 'size'], fontSize = (settings('labelSize') === 'fixed') ? settings('defaultLabelSize') : settings('labelSizeRatio') * size; // Label background: context.font = (fontStyle ? fontStyle + ' ' : '') + fontSize + 'px ' + (settings('hoverFont') || settings('font')); context.beginPath(); context.fillStyle = settings('labelHoverBGColor') === 'node' ? (node.color || settings('defaultNodeColor')) : settings('defaultHoverLabelBGColor'); if (node.label && settings('labelHoverShadow')) { context.shadowOffsetX = 0; context.shadowOffsetY = 0; context.shadowBlur = 8; context.shadowColor = settings('labelHoverShadowColor'); } if (node.label && typeof node.label === 'string') { x = Math.round(node[prefix + 'x'] - fontSize / 2 - 2); y = Math.round(node[prefix + 'y'] - fontSize / 2 - 2); w = Math.round( context.measureText(node.label).width + fontSize / 2 + size + 7 ); h = Math.round(fontSize + 4); e = Math.round(fontSize / 2 + 2); context.moveTo(x, y + e); context.arcTo(x, y, x + e, y, e); context.lineTo(x + w, y); context.lineTo(x + w, y + h); context.lineTo(x + e, y + h); context.arcTo(x, y + h, x, y + h - e, e); context.lineTo(x, y + e); context.closePath(); context.fill(); context.shadowOffsetX = 0; context.shadowOffsetY = 0; context.shadowBlur = 0; } // Node border: if (settings('borderSize') > 0) { context.beginPath(); context.fillStyle = settings('nodeBorderColor') === 'node' ? (node.color || settings('defaultNodeColor')) : settings('defaultNodeBorderColor'); context.arc( node[prefix + 'x'], node[prefix + 'y'], size + settings('borderSize'), 0, Math.PI * 2, true ); context.closePath(); context.fill(); } // Node: var nodeRenderer = sigma.canvas.nodes[node.type] || sigma.canvas.nodes.def; nodeRenderer(node, context, settings); // Display the label: if (node.label && typeof node.label === 'string') { context.fillStyle = (settings('labelHoverColor') === 'node') ? (node.color || settings('defaultNodeColor')) : settings('defaultLabelHoverColor'); context.fillText( node.label, Math.round(node[prefix + 'x'] + size + 3), Math.round(node[prefix + 'y'] + fontSize / 3) ); } }; }).call(this); ;(function() { 'use strict'; sigma.utils.pkg('sigma.canvas.nodes'); /** * The default node renderer. It renders the node as a simple disc. * * @param {object} node The node object. * @param {CanvasRenderingContext2D} context The canvas context. * @param {configurable} settings The settings function. */ sigma.canvas.nodes.def = function(node, context, settings) { var prefix = settings('prefix') || ''; context.fillStyle = node.color || settings('defaultNodeColor'); context.beginPath(); context.arc( node[prefix + 'x'], node[prefix + 'y'], node[prefix + 'size'], 0, Math.PI * 2, true ); context.closePath(); context.fill(); }; })(); ;(function() { 'use strict'; sigma.utils.pkg('sigma.canvas.edges'); /** * The default edge renderer. It renders the edge as a simple line. * * @param {object} edge The edge object. * @param {object} source node The edge source node. * @param {object} target node The edge target node. * @param {CanvasRenderingContext2D} context The canvas context. * @param {configurable} settings The settings function. */ sigma.canvas.edges.def = function(edge, source, target, context, settings) { var color = edge.color, prefix = settings('prefix') || '', size = edge[prefix + 'size'] || 1, edgeColor = settings('edgeColor'), defaultNodeColor = settings('defaultNodeColor'), defaultEdgeColor = settings('defaultEdgeColor'); if (!color) switch (edgeColor) { case 'source': color = source.color || defaultNodeColor; break; case 'target': color = target.color || defaultNodeColor; break; default: color = defaultEdgeColor; break; } context.strokeStyle = color; context.lineWidth = size; context.beginPath(); context.moveTo( source[prefix + 'x'], source[prefix + 'y'] ); context.lineTo( target[prefix + 'x'], target[prefix + 'y'] ); context.stroke(); }; })(); ;(function() { 'use strict'; sigma.utils.pkg('sigma.canvas.edges'); /** * This edge renderer will display edges as curves. * * @param {object} edge The edge object. * @param {object} source node The edge source node. * @param {object} target node The edge target node. * @param {CanvasRenderingContext2D} context The canvas context. * @param {configurable} settings The settings function. */ sigma.canvas.edges.curve = function(edge, source, target, context, settings) { var color = edge.color, prefix = settings('prefix') || '', size = edge[prefix + 'size'] || 1, edgeColor = settings('edgeColor'), defaultNodeColor = settings('defaultNodeColor'), defaultEdgeColor = settings('defaultEdgeColor'), cp = {}, sSize = source[prefix + 'size'], sX = source[prefix + 'x'], sY = source[prefix + 'y'], tX = target[prefix + 'x'], tY = target[prefix + 'y']; cp = (source.id === target.id) ? sigma.utils.getSelfLoopControlPoints(sX, sY, sSize) : sigma.utils.getQuadraticControlPoint(sX, sY, tX, tY); if (!color) switch (edgeColor) { case 'source': color = source.color || defaultNodeColor; break; case 'target': color = target.color || defaultNodeColor; break; default: color = defaultEdgeColor; break; } context.strokeStyle = color; context.lineWidth = size; context.beginPath(); context.moveTo(sX, sY); if (source.id === target.id) { context.bezierCurveTo(cp.x1, cp.y1, cp.x2, cp.y2, tX, tY); } else { context.quadraticCurveTo(cp.x, cp.y, tX, tY); } context.stroke(); }; })(); ;(function() { 'use strict'; sigma.utils.pkg('sigma.canvas.edges'); /** * This edge renderer will display edges as arrows going from the source node * * @param {object} edge The edge object. * @param {object} source node The edge source node. * @param {object} target node The edge target node. * @param {CanvasRenderingContext2D} context The canvas context. * @param {configurable} settings The settings function. */ sigma.canvas.edges.arrow = function(edge, source, target, context, settings) { var color = edge.color, prefix = settings('prefix') || '', edgeColor = settings('edgeColor'), defaultNodeColor = settings('defaultNodeColor'), defaultEdgeColor = settings('defaultEdgeColor'), size = edge[prefix + 'size'] || 1, tSize = target[prefix + 'size'], sX = source[prefix + 'x'], sY = source[prefix + 'y'], tX = target[prefix + 'x'], tY = target[prefix + 'y'], aSize = Math.max(size * 2.5, settings('minArrowSize')), d = Math.sqrt(Math.pow(tX - sX, 2) + Math.pow(tY - sY, 2)), aX = sX + (tX - sX) * (d - aSize - tSize) / d, aY = sY + (tY - sY) * (d - aSize - tSize) / d, vX = (tX - sX) * aSize / d, vY = (tY - sY) * aSize / d; if (!color) switch (edgeColor) { case 'source': color = source.color || defaultNodeColor; break; case 'target': color = target.color || defaultNodeColor; break; default: color = defaultEdgeColor; break; } context.strokeStyle = color; context.lineWidth = size; context.beginPath(); context.moveTo(sX, sY); context.lineTo( aX, aY ); context.stroke(); context.fillStyle = color; context.beginPath(); context.moveTo(aX + vX, aY + vY); context.lineTo(aX + vY * 0.6, aY - vX * 0.6); context.lineTo(aX - vY * 0.6, aY + vX * 0.6); context.lineTo(aX + vX, aY + vY); context.closePath(); context.fill(); }; })(); ;(function() { 'use strict'; sigma.utils.pkg('sigma.canvas.edges'); /** * This edge renderer will display edges as curves with arrow heading. * * @param {object} edge The edge object. * @param {object} source node The edge source node. * @param {object} target node The edge target node. * @param {CanvasRenderingContext2D} context The canvas context. * @param {configurable} settings The settings function. */ sigma.canvas.edges.curvedArrow = function(edge, source, target, context, settings) { var color = edge.color, prefix = settings('prefix') || '', edgeColor = settings('edgeColor'), defaultNodeColor = settings('defaultNodeColor'), defaultEdgeColor = settings('defaultEdgeColor'), cp = {}, size = edge[prefix + 'size'] || 1, tSize = target[prefix + 'size'], sX = source[prefix + 'x'], sY = source[prefix + 'y'], tX = target[prefix + 'x'], tY = target[prefix + 'y'], aSize = Math.max(size * 2.5, settings('minArrowSize')), d, aX, aY, vX, vY; cp = (source.id === target.id) ? sigma.utils.getSelfLoopControlPoints(sX, sY, tSize) : sigma.utils.getQuadraticControlPoint(sX, sY, tX, tY); if (source.id === target.id) { d = Math.sqrt(Math.pow(tX - cp.x1, 2) + Math.pow(tY - cp.y1, 2)); aX = cp.x1 + (tX - cp.x1) * (d - aSize - tSize) / d; aY = cp.y1 + (tY - cp.y1) * (d - aSize - tSize) / d; vX = (tX - cp.x1) * aSize / d; vY = (tY - cp.y1) * aSize / d; } else { d = Math.sqrt(Math.pow(tX - cp.x, 2) + Math.pow(tY - cp.y, 2)); aX = cp.x + (tX - cp.x) * (d - aSize - tSize) / d; aY = cp.y + (tY - cp.y) * (d - aSize - tSize) / d; vX = (tX - cp.x) * aSize / d; vY = (tY - cp.y) * aSize / d; } if (!color) switch (edgeColor) { case 'source': color = source.color || defaultNodeColor; break; case 'target': color = target.color || defaultNodeColor; break; default: color = defaultEdgeColor; break; } context.strokeStyle = color; context.lineWidth = size; context.beginPath(); context.moveTo(sX, sY); if (source.id === target.id) { context.bezierCurveTo(cp.x2, cp.y2, cp.x1, cp.y1, aX, aY); } else { context.quadraticCurveTo(cp.x, cp.y, aX, aY); } context.stroke(); context.fillStyle = color; context.beginPath(); context.moveTo(aX + vX, aY + vY); context.lineTo(aX + vY * 0.6, aY - vX * 0.6); context.lineTo(aX - vY * 0.6, aY + vX * 0.6); context.lineTo(aX + vX, aY + vY); context.closePath(); context.fill(); }; })(); ;(function() { 'use strict'; sigma.utils.pkg('sigma.canvas.edgehovers'); /** * This hover renderer will display the edge with a different color or size. * * @param {object} edge The edge object. * @param {object} source node The edge source node. * @param {object} target node The edge target node. * @param {CanvasRenderingContext2D} context The canvas context. * @param {configurable} settings The settings function. */ sigma.canvas.edgehovers.def = function(edge, source, target, context, settings) { var color = edge.color, prefix = settings('prefix') || '', size = edge[prefix + 'size'] || 1, edgeColor = settings('edgeColor'), defaultNodeColor = settings('defaultNodeColor'), defaultEdgeColor = settings('defaultEdgeColor'); if (!color) switch (edgeColor) { case 'source': color = source.color || defaultNodeColor; break; case 'target': color = target.color || defaultNodeColor; break; default: color = defaultEdgeColor; break; } if (settings('edgeHoverColor') === 'edge') { color = edge.hover_color || color; } else { color = edge.hover_color || settings('defaultEdgeHoverColor') || color; } size *= settings('edgeHoverSizeRatio'); context.strokeStyle = color; context.lineWidth = size; context.beginPath(); context.moveTo( source[prefix + 'x'], source[prefix + 'y'] ); context.lineTo( target[prefix + 'x'], target[prefix + 'y'] ); context.stroke(); }; })(); ;(function() { 'use strict'; sigma.utils.pkg('sigma.canvas.edgehovers'); /** * This hover renderer will display the edge with a different color or size. * * @param {object} edge The edge object. * @param {object} source node The edge source node. * @param {object} target node The edge target node. * @param {CanvasRenderingContext2D} context The canvas context. * @param {configurable} settings The settings function. */ sigma.canvas.edgehovers.curve = function(edge, source, target, context, settings) { var color = edge.color, prefix = settings('prefix') || '', size = settings('edgeHoverSizeRatio') * (edge[prefix + 'size'] || 1), edgeColor = settings('edgeColor'), defaultNodeColor = settings('defaultNodeColor'), defaultEdgeColor = settings('defaultEdgeColor'), cp = {}, sSize = source[prefix + 'size'], sX = source[prefix + 'x'], sY = source[prefix + 'y'], tX = target[prefix + 'x'], tY = target[prefix + 'y']; cp = (source.id === target.id) ? sigma.utils.getSelfLoopControlPoints(sX, sY, sSize) : sigma.utils.getQuadraticControlPoint(sX, sY, tX, tY); if (!color) switch (edgeColor) { case 'source': color = source.color || defaultNodeColor; break; case 'target': color = target.color || defaultNodeColor; break; default: color = defaultEdgeColor; break; } if (settings('edgeHoverColor') === 'edge') { color = edge.hover_color || color; } else { color = edge.hover_color || settings('defaultEdgeHoverColor') || color; } context.strokeStyle = color; context.lineWidth = size; context.beginPath(); context.moveTo(sX, sY); if (source.id === target.id) { context.bezierCurveTo(cp.x1, cp.y1, cp.x2, cp.y2, tX, tY); } else { context.quadraticCurveTo(cp.x, cp.y, tX, tY); } context.stroke(); }; })(); ;(function() { 'use strict'; sigma.utils.pkg('sigma.canvas.edgehovers'); /** * This hover renderer will display the edge with a different color or size. * * @param {object} edge The edge object. * @param {object} source node The edge source node. * @param {object} target node The edge target node. * @param {CanvasRenderingContext2D} context The canvas context. * @param {configurable} settings The settings function. */ sigma.canvas.edgehovers.arrow = function(edge, source, target, context, settings) { var color = edge.color, prefix = settings('prefix') || '', edgeColor = settings('edgeColor'), defaultNodeColor = settings('defaultNodeColor'), defaultEdgeColor = settings('defaultEdgeColor'), size = edge[prefix + 'size'] || 1, tSize = target[prefix + 'size'], sX = source[prefix + 'x'], sY = source[prefix + 'y'], tX = target[prefix + 'x'], tY = target[prefix + 'y']; size = (edge.hover) ? settings('edgeHoverSizeRatio') * size : size; var aSize = size * 2.5, d = Math.sqrt(Math.pow(tX - sX, 2) + Math.pow(tY - sY, 2)), aX = sX + (tX - sX) * (d - aSize - tSize) / d, aY = sY + (tY - sY) * (d - aSize - tSize) / d, vX = (tX - sX) * aSize / d, vY = (tY - sY) * aSize / d; if (!color) switch (edgeColor) { case 'source': color = source.color || defaultNodeColor; break; case 'target': color = target.color || defaultNodeColor; break; default: color = defaultEdgeColor; break; } if (settings('edgeHoverColor') === 'edge') { color = edge.hover_color || color; } else { color = edge.hover_color || settings('defaultEdgeHoverColor') || color; } context.strokeStyle = color; context.lineWidth = size; context.beginPath(); context.moveTo(sX, sY); context.lineTo( aX, aY ); context.stroke(); context.fillStyle = color; context.beginPath(); context.moveTo(aX + vX, aY + vY); context.lineTo(aX + vY * 0.6, aY - vX * 0.6); context.lineTo(aX - vY * 0.6, aY + vX * 0.6); context.lineTo(aX + vX, aY + vY); context.closePath(); context.fill(); }; })(); ;(function() { 'use strict'; sigma.utils.pkg('sigma.canvas.edgehovers'); /** * This hover renderer will display the edge with a different color or size. * * @param {object} edge The edge object. * @param {object} source node The edge source node. * @param {object} target node The edge target node. * @param {CanvasRenderingContext2D} context The canvas context. * @param {configurable} settings The settings function. */ sigma.canvas.edgehovers.curvedArrow = function(edge, source, target, context, settings) { var color = edge.color, prefix = settings('prefix') || '', edgeColor = settings('edgeColor'), defaultNodeColor = settings('defaultNodeColor'), defaultEdgeColor = settings('defaultEdgeColor'), cp = {}, size = settings('edgeHoverSizeRatio') * (edge[prefix + 'size'] || 1), tSize = target[prefix + 'size'], sX = source[prefix + 'x'], sY = source[prefix + 'y'], tX = target[prefix + 'x'], tY = target[prefix + 'y'], d, aSize, aX, aY, vX, vY; cp = (source.id === target.id) ? sigma.utils.getSelfLoopControlPoints(sX, sY, tSize) : sigma.utils.getQuadraticControlPoint(sX, sY, tX, tY); if (source.id === target.id) { d = Math.sqrt(Math.pow(tX - cp.x1, 2) + Math.pow(tY - cp.y1, 2)); aSize = size * 2.5; aX = cp.x1 + (tX - cp.x1) * (d - aSize - tSize) / d; aY = cp.y1 + (tY - cp.y1) * (d - aSize - tSize) / d; vX = (tX - cp.x1) * aSize / d; vY = (tY - cp.y1) * aSize / d; } else { d = Math.sqrt(Math.pow(tX - cp.x, 2) + Math.pow(tY - cp.y, 2)); aSize = size * 2.5; aX = cp.x + (tX - cp.x) * (d - aSize - tSize) / d; aY = cp.y + (tY - cp.y) * (d - aSize - tSize) / d; vX = (tX - cp.x) * aSize / d; vY = (tY - cp.y) * aSize / d; } if (!color) switch (edgeColor) { case 'source': color = source.color || defaultNodeColor; break; case 'target': color = target.color || defaultNodeColor; break; default: color = defaultEdgeColor; break; } if (settings('edgeHoverColor') === 'edge') { color = edge.hover_color || color; } else { color = edge.hover_color || settings('defaultEdgeHoverColor') || color; } context.strokeStyle = color; context.lineWidth = size; context.beginPath(); context.moveTo(sX, sY); if (source.id === target.id) { context.bezierCurveTo(cp.x2, cp.y2, cp.x1, cp.y1, aX, aY); } else { context.quadraticCurveTo(cp.x, cp.y, aX, aY); } context.stroke(); context.fillStyle = color; context.beginPath(); context.moveTo(aX + vX, aY + vY); context.lineTo(aX + vY * 0.6, aY - vX * 0.6); context.lineTo(aX - vY * 0.6, aY + vX * 0.6); context.lineTo(aX + vX, aY + vY); context.closePath(); context.fill(); }; })(); ;(function(undefined) { 'use strict'; if (typeof sigma === 'undefined') throw 'sigma is not declared'; // Initialize packages: sigma.utils.pkg('sigma.canvas.extremities'); /** * The default renderer for hovered edge extremities. It renders the edge * extremities as hovered. * * @param {object} edge The edge object. * @param {object} source node The edge source node. * @param {object} target node The edge target node. * @param {CanvasRenderingContext2D} context The canvas context. * @param {configurable} settings The settings function. */ sigma.canvas.extremities.def = function(edge, source, target, context, settings) { // Source Node: ( sigma.canvas.hovers[source.type] || sigma.canvas.hovers.def ) ( source, context, settings ); // Target Node: ( sigma.canvas.hovers[target.type] || sigma.canvas.hovers.def ) ( target, context, settings ); }; }).call(this); ;(function() { 'use strict'; sigma.utils.pkg('sigma.svg.utils'); /** * Some useful functions used by sigma's SVG renderer. */ sigma.svg.utils = { /** * SVG Element show. * * @param {DOMElement} element The DOM element to show. */ show: function(element) { element.style.display = ''; return this; }, /** * SVG Element hide. * * @param {DOMElement} element The DOM element to hide. */ hide: function(element) { element.style.display = 'none'; return this; } }; })(); ;(function() { 'use strict'; sigma.utils.pkg('sigma.svg.nodes'); /** * The default node renderer. It renders the node as a simple disc. */ sigma.svg.nodes.def = { /** * SVG Element creation. * * @param {object} node The node object. * @param {configurable} settings The settings function. */ create: function(node, settings) { var prefix = settings('prefix') || '', circle = document.createElementNS(settings('xmlns'), 'circle'); // Defining the node's circle circle.setAttributeNS(null, 'data-node-id', node.id); circle.setAttributeNS(null, 'class', settings('classPrefix') + '-node'); circle.setAttributeNS( null, 'fill', node.color || settings('defaultNodeColor')); // Returning the DOM Element return circle; }, /** * SVG Element update. * * @param {object} node The node object. * @param {DOMElement} circle The node DOM element. * @param {configurable} settings The settings function. */ update: function(node, circle, settings) { var prefix = settings('prefix') || ''; // Applying changes // TODO: optimize - check if necessary circle.setAttributeNS(null, 'cx', node[prefix + 'x']); circle.setAttributeNS(null, 'cy', node[prefix + 'y']); circle.setAttributeNS(null, 'r', node[prefix + 'size']); // Updating only if not freestyle if (!settings('freeStyle')) circle.setAttributeNS( null, 'fill', node.color || settings('defaultNodeColor')); // Showing circle.style.display = ''; return this; } }; })(); ;(function() { 'use strict'; sigma.utils.pkg('sigma.svg.edges'); /** * The default edge renderer. It renders the node as a simple line. */ sigma.svg.edges.def = { /** * SVG Element creation. * * @param {object} edge The edge object. * @param {object} source The source node object. * @param {object} target The target node object. * @param {configurable} settings The settings function. */ create: function(edge, source, target, settings) { var color = edge.color, prefix = settings('prefix') || '', edgeColor = settings('edgeColor'), defaultNodeColor = settings('defaultNodeColor'), defaultEdgeColor = settings('defaultEdgeColor'); if (!color) switch (edgeColor) { case 'source': color = source.color || defaultNodeColor; break; case 'target': color = target.color || defaultNodeColor; break; default: color = defaultEdgeColor; break; } var line = document.createElementNS(settings('xmlns'), 'line'); // Attributes line.setAttributeNS(null, 'data-edge-id', edge.id); line.setAttributeNS(null, 'class', settings('classPrefix') + '-edge'); line.setAttributeNS(null, 'stroke', color); return line; }, /** * SVG Element update. * * @param {object} edge The edge object. * @param {DOMElement} line The line DOM Element. * @param {object} source The source node object. * @param {object} target The target node object. * @param {configurable} settings The settings function. */ update: function(edge, line, source, target, settings) { var prefix = settings('prefix') || ''; line.setAttributeNS(null, 'stroke-width', edge[prefix + 'size'] || 1); line.setAttributeNS(null, 'x1', source[prefix + 'x']); line.setAttributeNS(null, 'y1', source[prefix + 'y']); line.setAttributeNS(null, 'x2', target[prefix + 'x']); line.setAttributeNS(null, 'y2', target[prefix + 'y']); // Showing line.style.display = ''; return this; } }; })(); ;(function() { 'use strict'; sigma.utils.pkg('sigma.svg.edges'); /** * The curve edge renderer. It renders the node as a bezier curve. */ sigma.svg.edges.curve = { /** * SVG Element creation. * * @param {object} edge The edge object. * @param {object} source The source node object. * @param {object} target The target node object. * @param {configurable} settings The settings function. */ create: function(edge, source, target, settings) { var color = edge.color, prefix = settings('prefix') || '', edgeColor = settings('edgeColor'), defaultNodeColor = settings('defaultNodeColor'), defaultEdgeColor = settings('defaultEdgeColor'); if (!color) switch (edgeColor) { case 'source': color = source.color || defaultNodeColor; break; case 'target': color = target.color || defaultNodeColor; break; default: color = defaultEdgeColor; break; } var path = document.createElementNS(settings('xmlns'), 'path'); // Attributes path.setAttributeNS(null, 'data-edge-id', edge.id); path.setAttributeNS(null, 'class', settings('classPrefix') + '-edge'); path.setAttributeNS(null, 'stroke', color); return path; }, /** * SVG Element update. * * @param {object} edge The edge object. * @param {DOMElement} line The line DOM Element. * @param {object} source The source node object. * @param {object} target The target node object. * @param {configurable} settings The settings function. */ update: function(edge, path, source, target, settings) { var prefix = settings('prefix') || ''; path.setAttributeNS(null, 'stroke-width', edge[prefix + 'size'] || 1); // Control point var cx = (source[prefix + 'x'] + target[prefix + 'x']) / 2 + (target[prefix + 'y'] - source[prefix + 'y']) / 4, cy = (source[prefix + 'y'] + target[prefix + 'y']) / 2 + (source[prefix + 'x'] - target[prefix + 'x']) / 4; // Path var p = 'M' + source[prefix + 'x'] + ',' + source[prefix + 'y'] + ' ' + 'Q' + cx + ',' + cy + ' ' + target[prefix + 'x'] + ',' + target[prefix + 'y']; // Updating attributes path.setAttributeNS(null, 'd', p); path.setAttributeNS(null, 'fill', 'none'); // Showing path.style.display = ''; return this; } }; })(); ;(function(undefined) { 'use strict'; if (typeof sigma === 'undefined') throw 'sigma is not declared'; // Initialize packages: sigma.utils.pkg('sigma.svg.labels'); /** * The default label renderer. It renders the label as a simple text. */ sigma.svg.labels.def = { /** * SVG Element creation. * * @param {object} node The node object. * @param {configurable} settings The settings function. */ create: function(node, settings) { var prefix = settings('prefix') || '', size = node[prefix + 'size'], text = document.createElementNS(settings('xmlns'), 'text'); var fontSize = (settings('labelSize') === 'fixed') ? settings('defaultLabelSize') : settings('labelSizeRatio') * size; var fontColor = (settings('labelColor') === 'node') ? (node.color || settings('defaultNodeColor')) : settings('defaultLabelColor'); text.setAttributeNS(null, 'data-label-target', node.id); text.setAttributeNS(null, 'class', settings('classPrefix') + '-label'); text.setAttributeNS(null, 'font-size', fontSize); text.setAttributeNS(null, 'font-family', settings('font')); text.setAttributeNS(null, 'fill', fontColor); text.innerHTML = node.label; text.textContent = node.label; return text; }, /** * SVG Element update. * * @param {object} node The node object. * @param {DOMElement} text The label DOM element. * @param {configurable} settings The settings function. */ update: function(node, text, settings) { var prefix = settings('prefix') || '', size = node[prefix + 'size']; var fontSize = (settings('labelSize') === 'fixed') ? settings('defaultLabelSize') : settings('labelSizeRatio') * size; // Case when we don't want to display the label if (!settings('forceLabels') && size < settings('labelThreshold')) return; if (typeof node.label !== 'string') return; // Updating text.setAttributeNS(null, 'x', Math.round(node[prefix + 'x'] + size + 3)); text.setAttributeNS(null, 'y', Math.round(node[prefix + 'y'] + fontSize / 3)); // Showing text.style.display = ''; return this; } }; }).call(this); ;(function(undefined) { 'use strict'; if (typeof sigma === 'undefined') throw 'sigma is not declared'; // Initialize packages: sigma.utils.pkg('sigma.svg.hovers'); /** * The default hover renderer. */ sigma.svg.hovers.def = { /** * SVG Element creation. * * @param {object} node The node object. * @param {CanvasElement} measurementCanvas A fake canvas handled by * the svg to perform some measurements and * passed by the renderer. * @param {DOMElement} nodeCircle The node DOM Element. * @param {configurable} settings The settings function. */ create: function(node, nodeCircle, measurementCanvas, settings) { // Defining visual properties var x, y, w, h, e, d, fontStyle = settings('hoverFontStyle') || settings('fontStyle'), prefix = settings('prefix') || '', size = node[prefix + 'size'], fontSize = (settings('labelSize') === 'fixed') ? settings('defaultLabelSize') : settings('labelSizeRatio') * size, fontColor = (settings('labelHoverColor') === 'node') ? (node.color || settings('defaultNodeColor')) : settings('defaultLabelHoverColor'); // Creating elements var group = document.createElementNS(settings('xmlns'), 'g'), rectangle = document.createElementNS(settings('xmlns'), 'rect'), circle = document.createElementNS(settings('xmlns'), 'circle'), text = document.createElementNS(settings('xmlns'), 'text'); // Defining properties group.setAttributeNS(null, 'class', settings('classPrefix') + '-hover'); group.setAttributeNS(null, 'data-node-id', node.id); if (typeof node.label === 'string') { // Text text.innerHTML = node.label; text.textContent = node.label; text.setAttributeNS( null, 'class', settings('classPrefix') + '-hover-label'); text.setAttributeNS(null, 'font-size', fontSize); text.setAttributeNS(null, 'font-family', settings('font')); text.setAttributeNS(null, 'fill', fontColor); text.setAttributeNS(null, 'x', Math.round(node[prefix + 'x'] + size + 3)); text.setAttributeNS(null, 'y', Math.round(node[prefix + 'y'] + fontSize / 3)); // Measures // OPTIMIZE: Find a better way than a measurement canvas x = Math.round(node[prefix + 'x'] - fontSize / 2 - 2); y = Math.round(node[prefix + 'y'] - fontSize / 2 - 2); w = Math.round( measurementCanvas.measureText(node.label).width + fontSize / 2 + size + 9 ); h = Math.round(fontSize + 4); e = Math.round(fontSize / 2 + 2); // Circle circle.setAttributeNS( null, 'class', settings('classPrefix') + '-hover-area'); circle.setAttributeNS(null, 'fill', '#fff'); circle.setAttributeNS(null, 'cx', node[prefix + 'x']); circle.setAttributeNS(null, 'cy', node[prefix + 'y']); circle.setAttributeNS(null, 'r', e); // Rectangle rectangle.setAttributeNS( null, 'class', settings('classPrefix') + '-hover-area'); rectangle.setAttributeNS(null, 'fill', '#fff'); rectangle.setAttributeNS(null, 'x', node[prefix + 'x'] + e / 4); rectangle.setAttributeNS(null, 'y', node[prefix + 'y'] - e); rectangle.setAttributeNS(null, 'width', w); rectangle.setAttributeNS(null, 'height', h); } // Appending childs group.appendChild(circle); group.appendChild(rectangle); group.appendChild(text); group.appendChild(nodeCircle); return group; } }; }).call(this); ;(function(undefined) { 'use strict'; if (typeof sigma === 'undefined') throw 'sigma is not declared'; // Initialize packages: sigma.utils.pkg('sigma.middlewares'); sigma.utils.pkg('sigma.utils'); /** * This middleware will rescale the graph such that it takes an optimal space * on the renderer. * * As each middleware, this function is executed in the scope of the sigma * instance. * * @param {?string} readPrefix The read prefix. * @param {?string} writePrefix The write prefix. * @param {object} options The parameters. */ sigma.middlewares.rescale = function(readPrefix, writePrefix, options) { var i, l, a, b, c, d, scale, margin, n = this.graph.nodes(), e = this.graph.edges(), settings = this.settings.embedObjects(options || {}), bounds = settings('bounds') || sigma.utils.getBoundaries( this.graph, readPrefix, true ), minX = bounds.minX, minY = bounds.minY, maxX = bounds.maxX, maxY = bounds.maxY, sizeMax = bounds.sizeMax, weightMax = bounds.weightMax, w = settings('width') || 1, h = settings('height') || 1, rescaleSettings = settings('autoRescale'), validSettings = { nodePosition: 1, nodeSize: 1, edgeSize: 1 }; /** * What elements should we rescale? */ if (!(rescaleSettings instanceof Array)) rescaleSettings = ['nodePosition', 'nodeSize', 'edgeSize']; for (i = 0, l = rescaleSettings.length; i < l; i++) if (!validSettings[rescaleSettings[i]]) throw new Error( 'The rescale setting "' + rescaleSettings[i] + '" is not recognized.' ); var np = ~rescaleSettings.indexOf('nodePosition'), ns = ~rescaleSettings.indexOf('nodeSize'), es = ~rescaleSettings.indexOf('edgeSize'); /** * First, we compute the scaling ratio, without considering the sizes * of the nodes : Each node will have its center in the canvas, but might * be partially out of it. */ scale = settings('scalingMode') === 'outside' ? Math.max( w / Math.max(maxX - minX, 1), h / Math.max(maxY - minY, 1) ) : Math.min( w / Math.max(maxX - minX, 1), h / Math.max(maxY - minY, 1) ); /** * Then, we correct that scaling ratio considering a margin, which is * basically the size of the biggest node. * This has to be done as a correction since to compare the size of the * biggest node to the X and Y values, we have to first get an * approximation of the scaling ratio. **/ margin = ( settings('rescaleIgnoreSize') ? 0 : (settings('maxNodeSize') || sizeMax) / scale ) + (settings('sideMargin') || 0); maxX += margin; minX -= margin; maxY += margin; minY -= margin; // Fix the scaling with the new extrema: scale = settings('scalingMode') === 'outside' ? Math.max( w / Math.max(maxX - minX, 1), h / Math.max(maxY - minY, 1) ) : Math.min( w / Math.max(maxX - minX, 1), h / Math.max(maxY - minY, 1) ); // Size homothetic parameters: if (!settings('maxNodeSize') && !settings('minNodeSize')) { a = 1; b = 0; } else if (settings('maxNodeSize') === settings('minNodeSize')) { a = 0; b = +settings('maxNodeSize'); } else { a = (settings('maxNodeSize') - settings('minNodeSize')) / sizeMax; b = +settings('minNodeSize'); } if (!settings('maxEdgeSize') && !settings('minEdgeSize')) { c = 1; d = 0; } else if (settings('maxEdgeSize') === settings('minEdgeSize')) { c = 0; d = +settings('minEdgeSize'); } else { c = (settings('maxEdgeSize') - settings('minEdgeSize')) / weightMax; d = +settings('minEdgeSize'); } // Rescale the nodes and edges: for (i = 0, l = e.length; i < l; i++) e[i][writePrefix + 'size'] = e[i][readPrefix + 'size'] * (es ? c : 1) + (es ? d : 0); for (i = 0, l = n.length; i < l; i++) { n[i][writePrefix + 'size'] = n[i][readPrefix + 'size'] * (ns ? a : 1) + (ns ? b : 0); n[i][writePrefix + 'x'] = (n[i][readPrefix + 'x'] - (maxX + minX) / 2) * (np ? scale : 1); n[i][writePrefix + 'y'] = (n[i][readPrefix + 'y'] - (maxY + minY) / 2) * (np ? scale : 1); } }; sigma.utils.getBoundaries = function(graph, prefix, doEdges) { var i, l, e = graph.edges(), n = graph.nodes(), weightMax = -Infinity, sizeMax = -Infinity, minX = Infinity, minY = Infinity, maxX = -Infinity, maxY = -Infinity; if (doEdges) for (i = 0, l = e.length; i < l; i++) weightMax = Math.max(e[i][prefix + 'size'], weightMax); for (i = 0, l = n.length; i < l; i++) { sizeMax = Math.max(n[i][prefix + 'size'], sizeMax); maxX = Math.max(n[i][prefix + 'x'], maxX); minX = Math.min(n[i][prefix + 'x'], minX); maxY = Math.max(n[i][prefix + 'y'], maxY); minY = Math.min(n[i][prefix + 'y'], minY); } weightMax = weightMax || 1; sizeMax = sizeMax || 1; return { weightMax: weightMax, sizeMax: sizeMax, minX: minX, minY: minY, maxX: maxX, maxY: maxY }; }; }).call(this); ;(function(undefined) { 'use strict'; if (typeof sigma === 'undefined') throw 'sigma is not declared'; // Initialize packages: sigma.utils.pkg('sigma.middlewares'); /** * This middleware will just copy the graphic properties. * * @param {?string} readPrefix The read prefix. * @param {?string} writePrefix The write prefix. */ sigma.middlewares.copy = function(readPrefix, writePrefix) { var i, l, a; if (writePrefix + '' === readPrefix + '') return; a = this.graph.nodes(); for (i = 0, l = a.length; i < l; i++) { a[i][writePrefix + 'x'] = a[i][readPrefix + 'x']; a[i][writePrefix + 'y'] = a[i][readPrefix + 'y']; a[i][writePrefix + 'size'] = a[i][readPrefix + 'size']; } a = this.graph.edges(); for (i = 0, l = a.length; i < l; i++) a[i][writePrefix + 'size'] = a[i][readPrefix + 'size']; }; }).call(this); ;(function(undefined) { 'use strict'; if (typeof sigma === 'undefined') throw 'sigma is not declared'; // Initialize packages: sigma.utils.pkg('sigma.misc.animation.running'); /** * Generates a unique ID for the animation. * * @return {string} Returns the new ID. */ var _getID = (function() { var id = 0; return function() { return '' + (++id); }; })(); /** * This function animates a camera. It has to be called with the camera to * animate, the values of the coordinates to reach and eventually some * options. It returns a number id, that you can use to kill the animation, * with the method sigma.misc.animation.kill(id). * * The available options are: * * {?number} duration The duration of the animation. * {?function} onNewFrame A callback to execute when the animation * enter a new frame. * {?function} onComplete A callback to execute when the animation * is completed or killed. * {?(string|function)} easing The name of a function from the package * sigma.utils.easings, or a custom easing * function. * * @param {camera} camera The camera to animate. * @param {object} target The coordinates to reach. * @param {?object} options Eventually an object to specify some options to * the function. The available options are * presented in the description of the function. * @return {number} The animation id, to make it easy to kill * through the method "sigma.misc.animation.kill". */ sigma.misc.animation.camera = function(camera, val, options) { if ( !(camera instanceof sigma.classes.camera) || typeof val !== 'object' || !val ) throw 'animation.camera: Wrong arguments.'; if ( typeof val.x !== 'number' && typeof val.y !== 'number' && typeof val.ratio !== 'number' && typeof val.angle !== 'number' ) throw 'There must be at least one valid coordinate in the given val.'; var fn, id, anim, easing, duration, initialVal, o = options || {}, start = sigma.utils.dateNow(); // Store initial values: initialVal = { x: camera.x, y: camera.y, ratio: camera.ratio, angle: camera.angle }; duration = o.duration; easing = typeof o.easing !== 'function' ? sigma.utils.easings[o.easing || 'quadraticInOut'] : o.easing; fn = function() { var coef, t = o.duration ? (sigma.utils.dateNow() - start) / o.duration : 1; // If the animation is over: if (t >= 1) { camera.isAnimated = false; camera.goTo({ x: val.x !== undefined ? val.x : initialVal.x, y: val.y !== undefined ? val.y : initialVal.y, ratio: val.ratio !== undefined ? val.ratio : initialVal.ratio, angle: val.angle !== undefined ? val.angle : initialVal.angle }); cancelAnimationFrame(id); delete sigma.misc.animation.running[id]; // Check callbacks: if (typeof o.onComplete === 'function') o.onComplete(); // Else, let's keep going: } else { coef = easing(t); camera.isAnimated = true; camera.goTo({ x: val.x !== undefined ? initialVal.x + (val.x - initialVal.x) * coef : initialVal.x, y: val.y !== undefined ? initialVal.y + (val.y - initialVal.y) * coef : initialVal.y, ratio: val.ratio !== undefined ? initialVal.ratio + (val.ratio - initialVal.ratio) * coef : initialVal.ratio, angle: val.angle !== undefined ? initialVal.angle + (val.angle - initialVal.angle) * coef : initialVal.angle }); // Check callbacks: if (typeof o.onNewFrame === 'function') o.onNewFrame(); anim.frameId = requestAnimationFrame(fn); } }; id = _getID(); anim = { frameId: requestAnimationFrame(fn), target: camera, type: 'camera', options: o, fn: fn }; sigma.misc.animation.running[id] = anim; return id; }; /** * Kills a running animation. It triggers the eventual onComplete callback. * * @param {number} id The id of the animation to kill. * @return {object} Returns the sigma.misc.animation package. */ sigma.misc.animation.kill = function(id) { if (arguments.length !== 1 || typeof id !== 'number') throw 'animation.kill: Wrong arguments.'; var o = sigma.misc.animation.running[id]; if (o) { cancelAnimationFrame(id); delete sigma.misc.animation.running[o.frameId]; if (o.type === 'camera') o.target.isAnimated = false; // Check callbacks: if (typeof (o.options || {}).onComplete === 'function') o.options.onComplete(); } return this; }; /** * Kills every running animations, or only the one with the specified type, * if a string parameter is given. * * @param {?(string|object)} filter A string to filter the animations to kill * on their type (example: "camera"), or an * object to filter on their target. * @return {number} Returns the number of animations killed * that way. */ sigma.misc.animation.killAll = function(filter) { var o, id, count = 0, type = typeof filter === 'string' ? filter : null, target = typeof filter === 'object' ? filter : null, running = sigma.misc.animation.running; for (id in running) if ( (!type || running[id].type === type) && (!target || running[id].target === target) ) { o = sigma.misc.animation.running[id]; cancelAnimationFrame(o.frameId); delete sigma.misc.animation.running[id]; if (o.type === 'camera') o.target.isAnimated = false; // Increment counter: count++; // Check callbacks: if (typeof (o.options || {}).onComplete === 'function') o.options.onComplete(); } return count; }; /** * Returns "true" if any animation that is currently still running matches * the filter given to the function. * * @param {string|object} filter A string to filter the animations to kill * on their type (example: "camera"), or an * object to filter on their target. * @return {boolean} Returns true if any running animation * matches. */ sigma.misc.animation.has = function(filter) { var id, type = typeof filter === 'string' ? filter : null, target = typeof filter === 'object' ? filter : null, running = sigma.misc.animation.running; for (id in running) if ( (!type || running[id].type === type) && (!target || running[id].target === target) ) return true; return false; }; }).call(this); ;(function(undefined) { 'use strict'; if (typeof sigma === 'undefined') throw 'sigma is not declared'; // Initialize packages: sigma.utils.pkg('sigma.misc'); /** * This helper will bind any no-DOM renderer (for instance canvas or WebGL) * to its captors, to properly dispatch the good events to the sigma instance * to manage clicking, hovering etc... * * It has to be called in the scope of the related renderer. */ sigma.misc.bindEvents = function(prefix) { var i, l, mX, mY, captor, self = this; function getNodes(e) { if (e) { mX = 'x' in e.data ? e.data.x : mX; mY = 'y' in e.data ? e.data.y : mY; } var i, j, l, n, x, y, s, inserted, selected = [], modifiedX = mX + self.width / 2, modifiedY = mY + self.height / 2, point = self.camera.cameraPosition( mX, mY ), nodes = self.camera.quadtree.point( point.x, point.y ); if (nodes.length) for (i = 0, l = nodes.length; i < l; i++) { n = nodes[i]; x = n[prefix + 'x']; y = n[prefix + 'y']; s = n[prefix + 'size']; if ( !n.hidden && modifiedX > x - s && modifiedX < x + s && modifiedY > y - s && modifiedY < y + s && Math.sqrt( Math.pow(modifiedX - x, 2) + Math.pow(modifiedY - y, 2) ) < s ) { // Insert the node: inserted = false; for (j = 0; j < selected.length; j++) if (n.size > selected[j].size) { selected.splice(j, 0, n); inserted = true; break; } if (!inserted) selected.push(n); } } return selected; } function getEdges(e) { if (!self.settings('enableEdgeHovering')) { // No event if the setting is off: return []; } var isCanvas = ( sigma.renderers.canvas && self instanceof sigma.renderers.canvas); if (!isCanvas) { // A quick hardcoded rule to prevent people from using this feature // with the WebGL renderer (which is not good enough at the moment): throw new Error( 'The edge events feature is not compatible with the WebGL renderer' ); } if (e) { mX = 'x' in e.data ? e.data.x : mX; mY = 'y' in e.data ? e.data.y : mY; } var i, j, l, a, edge, s, maxEpsilon = self.settings('edgeHoverPrecision'), source, target, cp, nodeIndex = {}, inserted, selected = [], modifiedX = mX + self.width / 2, modifiedY = mY + self.height / 2, point = self.camera.cameraPosition( mX, mY ), edges = []; if (isCanvas) { var nodesOnScreen = self.camera.quadtree.area( self.camera.getRectangle(self.width, self.height) ); for (a = nodesOnScreen, i = 0, l = a.length; i < l; i++) nodeIndex[a[i].id] = a[i]; } if (self.camera.edgequadtree !== undefined) { edges = self.camera.edgequadtree.point( point.x, point.y ); } function insertEdge(selected, edge) { inserted = false; for (j = 0; j < selected.length; j++) if (edge.size > selected[j].size) { selected.splice(j, 0, edge); inserted = true; break; } if (!inserted) selected.push(edge); } if (edges.length) for (i = 0, l = edges.length; i < l; i++) { edge = edges[i]; source = self.graph.nodes(edge.source); target = self.graph.nodes(edge.target); // (HACK) we can't get edge[prefix + 'size'] on WebGL renderer: s = edge[prefix + 'size'] || edge['read_' + prefix + 'size']; // First, let's identify which edges are drawn. To do this, we keep // every edges that have at least one extremity displayed according to // the quadtree and the "hidden" attribute. We also do not keep hidden // edges. // Then, let's check if the mouse is on the edge (we suppose that it // is a line segment). if ( !edge.hidden && !source.hidden && !target.hidden && (!isCanvas || (nodeIndex[edge.source] || nodeIndex[edge.target])) && sigma.utils.getDistance( source[prefix + 'x'], source[prefix + 'y'], modifiedX, modifiedY) > source[prefix + 'size'] && sigma.utils.getDistance( target[prefix + 'x'], target[prefix + 'y'], modifiedX, modifiedY) > target[prefix + 'size'] ) { if (edge.type == 'curve' || edge.type == 'curvedArrow') { if (source.id === target.id) { cp = sigma.utils.getSelfLoopControlPoints( source[prefix + 'x'], source[prefix + 'y'], source[prefix + 'size'] ); if ( sigma.utils.isPointOnBezierCurve( modifiedX, modifiedY, source[prefix + 'x'], source[prefix + 'y'], target[prefix + 'x'], target[prefix + 'y'], cp.x1, cp.y1, cp.x2, cp.y2, Math.max(s, maxEpsilon) )) { insertEdge(selected, edge); } } else { cp = sigma.utils.getQuadraticControlPoint( source[prefix + 'x'], source[prefix + 'y'], target[prefix + 'x'], target[prefix + 'y']); if ( sigma.utils.isPointOnQuadraticCurve( modifiedX, modifiedY, source[prefix + 'x'], source[prefix + 'y'], target[prefix + 'x'], target[prefix + 'y'], cp.x, cp.y, Math.max(s, maxEpsilon) )) { insertEdge(selected, edge); } } } else if ( sigma.utils.isPointOnSegment( modifiedX, modifiedY, source[prefix + 'x'], source[prefix + 'y'], target[prefix + 'x'], target[prefix + 'y'], Math.max(s, maxEpsilon) )) { insertEdge(selected, edge); } } } return selected; } function bindCaptor(captor) { var nodes, edges, overNodes = {}, overEdges = {}; function onClick(e) { if (!self.settings('eventsEnabled')) return; self.dispatchEvent('click', e.data); nodes = getNodes(e); edges = getEdges(e); if (nodes.length) { self.dispatchEvent('clickNode', { node: nodes[0], captor: e.data }); self.dispatchEvent('clickNodes', { node: nodes, captor: e.data }); } else if (edges.length) { self.dispatchEvent('clickEdge', { edge: edges[0], captor: e.data }); self.dispatchEvent('clickEdges', { edge: edges, captor: e.data }); } else self.dispatchEvent('clickStage', {captor: e.data}); } function onDoubleClick(e) { if (!self.settings('eventsEnabled')) return; self.dispatchEvent('doubleClick', e.data); nodes = getNodes(e); edges = getEdges(e); if (nodes.length) { self.dispatchEvent('doubleClickNode', { node: nodes[0], captor: e.data }); self.dispatchEvent('doubleClickNodes', { node: nodes, captor: e.data }); } else if (edges.length) { self.dispatchEvent('doubleClickEdge', { edge: edges[0], captor: e.data }); self.dispatchEvent('doubleClickEdges', { edge: edges, captor: e.data }); } else self.dispatchEvent('doubleClickStage', {captor: e.data}); } function onRightClick(e) { if (!self.settings('eventsEnabled')) return; self.dispatchEvent('rightClick', e.data); nodes = getNodes(e); edges = getEdges(e); if (nodes.length) { self.dispatchEvent('rightClickNode', { node: nodes[0], captor: e.data }); self.dispatchEvent('rightClickNodes', { node: nodes, captor: e.data }); } else if (edges.length) { self.dispatchEvent('rightClickEdge', { edge: edges[0], captor: e.data }); self.dispatchEvent('rightClickEdges', { edge: edges, captor: e.data }); } else self.dispatchEvent('rightClickStage', {captor: e.data}); } function onOut(e) { if (!self.settings('eventsEnabled')) return; var k, i, l, le, outNodes = [], outEdges = []; for (k in overNodes) outNodes.push(overNodes[k]); overNodes = {}; // Dispatch both single and multi events: for (i = 0, l = outNodes.length; i < l; i++) self.dispatchEvent('outNode', { node: outNodes[i], captor: e.data }); if (outNodes.length) self.dispatchEvent('outNodes', { nodes: outNodes, captor: e.data }); overEdges = {}; // Dispatch both single and multi events: for (i = 0, le = outEdges.length; i < le; i++) self.dispatchEvent('outEdge', { edge: outEdges[i], captor: e.data }); if (outEdges.length) self.dispatchEvent('outEdges', { edges: outEdges, captor: e.data }); } function onMove(e) { if (!self.settings('eventsEnabled')) return; nodes = getNodes(e); edges = getEdges(e); var i, k, node, edge, newOutNodes = [], newOverNodes = [], currentOverNodes = {}, l = nodes.length, newOutEdges = [], newOverEdges = [], currentOverEdges = {}, le = edges.length; // Check newly overred nodes: for (i = 0; i < l; i++) { node = nodes[i]; currentOverNodes[node.id] = node; if (!overNodes[node.id]) { newOverNodes.push(node); overNodes[node.id] = node; } } // Check no more overred nodes: for (k in overNodes) if (!currentOverNodes[k]) { newOutNodes.push(overNodes[k]); delete overNodes[k]; } // Dispatch both single and multi events: for (i = 0, l = newOverNodes.length; i < l; i++) self.dispatchEvent('overNode', { node: newOverNodes[i], captor: e.data }); for (i = 0, l = newOutNodes.length; i < l; i++) self.dispatchEvent('outNode', { node: newOutNodes[i], captor: e.data }); if (newOverNodes.length) self.dispatchEvent('overNodes', { nodes: newOverNodes, captor: e.data }); if (newOutNodes.length) self.dispatchEvent('outNodes', { nodes: newOutNodes, captor: e.data }); // Check newly overred edges: for (i = 0; i < le; i++) { edge = edges[i]; currentOverEdges[edge.id] = edge; if (!overEdges[edge.id]) { newOverEdges.push(edge); overEdges[edge.id] = edge; } } // Check no more overred edges: for (k in overEdges) if (!currentOverEdges[k]) { newOutEdges.push(overEdges[k]); delete overEdges[k]; } // Dispatch both single and multi events: for (i = 0, le = newOverEdges.length; i < le; i++) self.dispatchEvent('overEdge', { edge: newOverEdges[i], captor: e.data }); for (i = 0, le = newOutEdges.length; i < le; i++) self.dispatchEvent('outEdge', { edge: newOutEdges[i], captor: e.data }); if (newOverEdges.length) self.dispatchEvent('overEdges', { edges: newOverEdges, captor: e.data }); if (newOutEdges.length) self.dispatchEvent('outEdges', { edges: newOutEdges, captor: e.data }); } // Bind events: captor.bind('click', onClick); captor.bind('mousedown', onMove); captor.bind('mouseup', onMove); captor.bind('mousemove', onMove); captor.bind('mouseout', onOut); captor.bind('doubleclick', onDoubleClick); captor.bind('rightclick', onRightClick); self.bind('render', onMove); } for (i = 0, l = this.captors.length; i < l; i++) bindCaptor(this.captors[i]); }; }).call(this); ;(function(undefined) { 'use strict'; if (typeof sigma === 'undefined') throw 'sigma is not declared'; // Initialize packages: sigma.utils.pkg('sigma.misc'); /** * This helper will bind any DOM renderer (for instance svg) * to its captors, to properly dispatch the good events to the sigma instance * to manage clicking, hovering etc... * * It has to be called in the scope of the related renderer. */ sigma.misc.bindDOMEvents = function(container) { var self = this, graph = this.graph; // DOMElement abstraction function Element(domElement) { // Helpers this.attr = function(attrName) { return domElement.getAttributeNS(null, attrName); }; // Properties this.tag = domElement.tagName; this.class = this.attr('class'); this.id = this.attr('id'); // Methods this.isNode = function() { return !!~this.class.indexOf(self.settings('classPrefix') + '-node'); }; this.isEdge = function() { return !!~this.class.indexOf(self.settings('classPrefix') + '-edge'); }; this.isHover = function() { return !!~this.class.indexOf(self.settings('classPrefix') + '-hover'); }; } // Click function click(e) { if (!self.settings('eventsEnabled')) return; // Generic event self.dispatchEvent('click', e); // Are we on a node? var element = new Element(e.target); if (element.isNode()) self.dispatchEvent('clickNode', { node: graph.nodes(element.attr('data-node-id')) }); else self.dispatchEvent('clickStage'); e.preventDefault(); e.stopPropagation(); } // Double click function doubleClick(e) { if (!self.settings('eventsEnabled')) return; // Generic event self.dispatchEvent('doubleClick', e); // Are we on a node? var element = new Element(e.target); if (element.isNode()) self.dispatchEvent('doubleClickNode', { node: graph.nodes(element.attr('data-node-id')) }); else self.dispatchEvent('doubleClickStage'); e.preventDefault(); e.stopPropagation(); } // On over function onOver(e) { var target = e.toElement || e.target; if (!self.settings('eventsEnabled') || !target) return; var el = new Element(target); if (el.isNode()) { self.dispatchEvent('overNode', { node: graph.nodes(el.attr('data-node-id')) }); } else if (el.isEdge()) { var edge = graph.edges(el.attr('data-edge-id')); self.dispatchEvent('overEdge', { edge: edge, source: graph.nodes(edge.source), target: graph.nodes(edge.target) }); } } // On out function onOut(e) { var target = e.fromElement || e.originalTarget; if (!self.settings('eventsEnabled')) return; var el = new Element(target); if (el.isNode()) { self.dispatchEvent('outNode', { node: graph.nodes(el.attr('data-node-id')) }); } else if (el.isEdge()) { var edge = graph.edges(el.attr('data-edge-id')); self.dispatchEvent('outEdge', { edge: edge, source: graph.nodes(edge.source), target: graph.nodes(edge.target) }); } } // Registering Events: // Click container.addEventListener('click', click, false); sigma.utils.doubleClick(container, 'click', doubleClick); // Touch counterparts container.addEventListener('touchstart', click, false); sigma.utils.doubleClick(container, 'touchstart', doubleClick); // Mouseover container.addEventListener('mouseover', onOver, true); // Mouseout container.addEventListener('mouseout', onOut, true); }; }).call(this); ;(function(undefined) { 'use strict'; if (typeof sigma === 'undefined') throw 'sigma is not declared'; // Initialize packages: sigma.utils.pkg('sigma.misc'); /** * This method listens to "overNode", "outNode", "overEdge" and "outEdge" * events from a renderer and renders the nodes differently on the top layer. * The goal is to make any node label readable with the mouse, and to * highlight hovered nodes and edges. * * It has to be called in the scope of the related renderer. */ sigma.misc.drawHovers = function(prefix) { var self = this, hoveredNodes = {}, hoveredEdges = {}; this.bind('overNode', function(event) { var node = event.data.node; if (!node.hidden) { hoveredNodes[node.id] = node; draw(); } }); this.bind('outNode', function(event) { delete hoveredNodes[event.data.node.id]; draw(); }); this.bind('overEdge', function(event) { var edge = event.data.edge; if (!edge.hidden) { hoveredEdges[edge.id] = edge; draw(); } }); this.bind('outEdge', function(event) { delete hoveredEdges[event.data.edge.id]; draw(); }); this.bind('render', function(event) { draw(); }); function draw() { // Clear self.contexts.hover: self.contexts.hover.canvas.width = self.contexts.hover.canvas.width; var k, source, target, hoveredNode, hoveredEdge, defaultNodeType = self.settings('defaultNodeType'), defaultEdgeType = self.settings('defaultEdgeType'), nodeRenderers = sigma.canvas.hovers, edgeRenderers = sigma.canvas.edgehovers, extremitiesRenderers = sigma.canvas.extremities, embedSettings = self.settings.embedObjects({ prefix: prefix }); // Node render: single hover if ( embedSettings('enableHovering') && embedSettings('singleHover') && Object.keys(hoveredNodes).length ) { hoveredNode = hoveredNodes[Object.keys(hoveredNodes)[0]]; ( nodeRenderers[hoveredNode.type] || nodeRenderers[defaultNodeType] || nodeRenderers.def )( hoveredNode, self.contexts.hover, embedSettings ); } // Node render: multiple hover if ( embedSettings('enableHovering') && !embedSettings('singleHover') ) for (k in hoveredNodes) ( nodeRenderers[hoveredNodes[k].type] || nodeRenderers[defaultNodeType] || nodeRenderers.def )( hoveredNodes[k], self.contexts.hover, embedSettings ); // Edge render: single hover if ( embedSettings('enableEdgeHovering') && embedSettings('singleHover') && Object.keys(hoveredEdges).length ) { hoveredEdge = hoveredEdges[Object.keys(hoveredEdges)[0]]; source = self.graph.nodes(hoveredEdge.source); target = self.graph.nodes(hoveredEdge.target); if (! hoveredEdge.hidden) { ( edgeRenderers[hoveredEdge.type] || edgeRenderers[defaultEdgeType] || edgeRenderers.def ) ( hoveredEdge, source, target, self.contexts.hover, embedSettings ); if (embedSettings('edgeHoverExtremities')) { ( extremitiesRenderers[hoveredEdge.type] || extremitiesRenderers.def )( hoveredEdge, source, target, self.contexts.hover, embedSettings ); } else { // Avoid edges rendered over nodes: ( sigma.canvas.nodes[source.type] || sigma.canvas.nodes.def ) ( source, self.contexts.hover, embedSettings ); ( sigma.canvas.nodes[target.type] || sigma.canvas.nodes.def ) ( target, self.contexts.hover, embedSettings ); } } } // Edge render: multiple hover if ( embedSettings('enableEdgeHovering') && !embedSettings('singleHover') ) { for (k in hoveredEdges) { hoveredEdge = hoveredEdges[k]; source = self.graph.nodes(hoveredEdge.source); target = self.graph.nodes(hoveredEdge.target); if (!hoveredEdge.hidden) { ( edgeRenderers[hoveredEdge.type] || edgeRenderers[defaultEdgeType] || edgeRenderers.def ) ( hoveredEdge, source, target, self.contexts.hover, embedSettings ); if (embedSettings('edgeHoverExtremities')) { ( extremitiesRenderers[hoveredEdge.type] || extremitiesRenderers.def )( hoveredEdge, source, target, self.contexts.hover, embedSettings ); } else { // Avoid edges rendered over nodes: ( sigma.canvas.nodes[source.type] || sigma.canvas.nodes.def ) ( source, self.contexts.hover, embedSettings ); ( sigma.canvas.nodes[target.type] || sigma.canvas.nodes.def ) ( target, self.contexts.hover, embedSettings ); } } } } } }; }).call(this);