/*! * @overview Ember - JavaScript Application Framework * @copyright Copyright 2011-2014 Tilde Inc. and contributors * Portions Copyright 2006-2011 Strobe Inc. * Portions Copyright 2008-2011 Apple Inc. All rights reserved. * @license Licensed under MIT license * See https://raw.github.com/emberjs/ember.js/master/LICENSE * @version 1.4.0-beta.2 */ (function() { var define, requireModule, require, requirejs; (function() { var registry = {}, seen = {}; define = function(name, deps, callback) { registry[name] = { deps: deps, callback: callback }; }; requirejs = require = requireModule = function(name) { requirejs._eak_seen = registry; if (seen[name]) { return seen[name]; } seen[name] = {}; if (!registry[name]) { throw new Error("Could not find module " + name); } var mod = registry[name], deps = mod.deps, callback = mod.callback, reified = [], exports; for (var i=0, l=deps.length; i -1; }; // From: https://developer.mozilla.org/en/JavaScript/Reference/Global_Objects/array/map var arrayMap = isNativeFunc(Array.prototype.map) ? Array.prototype.map : function(fun /*, thisp */) { //"use strict"; if (this === void 0 || this === null) { throw new TypeError(); } var t = Object(this); var len = t.length >>> 0; if (typeof fun !== "function") { throw new TypeError(); } var res = new Array(len); var thisp = arguments[1]; for (var i = 0; i < len; i++) { if (i in t) { res[i] = fun.call(thisp, t[i], i, t); } } return res; }; // From: https://developer.mozilla.org/en/JavaScript/Reference/Global_Objects/array/foreach var arrayForEach = isNativeFunc(Array.prototype.forEach) ? Array.prototype.forEach : function(fun /*, thisp */) { //"use strict"; if (this === void 0 || this === null) { throw new TypeError(); } var t = Object(this); var len = t.length >>> 0; if (typeof fun !== "function") { throw new TypeError(); } var thisp = arguments[1]; for (var i = 0; i < len; i++) { if (i in t) { fun.call(thisp, t[i], i, t); } } }; var arrayIndexOf = isNativeFunc(Array.prototype.indexOf) ? Array.prototype.indexOf : function (obj, fromIndex) { if (fromIndex === null || fromIndex === undefined) { fromIndex = 0; } else if (fromIndex < 0) { fromIndex = Math.max(0, this.length + fromIndex); } for (var i = fromIndex, j = this.length; i < j; i++) { if (this[i] === obj) { return i; } } return -1; }; /** Array polyfills to support ES5 features in older browsers. @namespace Ember @property ArrayPolyfills */ Ember.ArrayPolyfills = { map: arrayMap, forEach: arrayForEach, indexOf: arrayIndexOf }; if (Ember.SHIM_ES5) { if (!Array.prototype.map) { Array.prototype.map = arrayMap; } if (!Array.prototype.forEach) { Array.prototype.forEach = arrayForEach; } if (!Array.prototype.indexOf) { Array.prototype.indexOf = arrayIndexOf; } } })(); (function() { var errorProps = ['description', 'fileName', 'lineNumber', 'message', 'name', 'number', 'stack']; /** A subclass of the JavaScript Error object for use in Ember. @class Error @namespace Ember @extends Error @constructor */ Ember.Error = function() { var tmp = Error.apply(this, arguments); // Adds a `stack` property to the given error object that will yield the // stack trace at the time captureStackTrace was called. // When collecting the stack trace all frames above the topmost call // to this function, including that call, will be left out of the // stack trace. // This is useful because we can hide Ember implementation details // that are not very helpful for the user. if (Error.captureStackTrace) { Error.captureStackTrace(this, Ember.Error); } // Unfortunately errors are not enumerable in Chrome (at least), so `for prop in tmp` doesn't work. for (var idx = 0; idx < errorProps.length; idx++) { this[errorProps[idx]] = tmp[errorProps[idx]]; } }; Ember.Error.prototype = Ember.create(Error.prototype); // .......................................................... // ERROR HANDLING // /** A function may be assigned to `Ember.onerror` to be called when Ember internals encounter an error. This is useful for specialized error handling and reporting code. ```javascript Ember.onerror = function(error) { Em.$.ajax('/report-error', 'POST', { stack: error.stack, otherInformation: 'whatever app state you want to provide' }); }; ``` @event onerror @for Ember @param {Exception} error the error object */ Ember.onerror = null; /** Wrap code block in a try/catch if `Ember.onerror` is set. @private @method handleErrors @for Ember @param {Function} func @param [context] */ Ember.handleErrors = function(func, context) { // Unfortunately in some browsers we lose the backtrace if we rethrow the existing error, // so in the event that we don't have an `onerror` handler we don't wrap in a try/catch if ('function' === typeof Ember.onerror) { try { return func.call(context || this); } catch (error) { Ember.onerror(error); } } else { return func.call(context || this); } }; })(); (function() { /** @module ember-metal */ /** Prefix used for guids through out Ember. @private */ Ember.GUID_PREFIX = 'ember'; var o_defineProperty = Ember.platform.defineProperty, o_create = Ember.create, // Used for guid generation... GUID_KEY = '__ember'+ (+ new Date()), uuid = 0, numberCache = [], stringCache = {}; var MANDATORY_SETTER = Ember.ENV.MANDATORY_SETTER; /** A unique key used to assign guids and other private metadata to objects. If you inspect an object in your browser debugger you will often see these. They can be safely ignored. On browsers that support it, these properties are added with enumeration disabled so they won't show up when you iterate over your properties. @private @property GUID_KEY @for Ember @type String @final */ Ember.GUID_KEY = GUID_KEY; var GUID_DESC = { writable: false, configurable: false, enumerable: false, value: null }; /** Generates a new guid, optionally saving the guid to the object that you pass in. You will rarely need to use this method. Instead you should call `Ember.guidFor(obj)`, which return an existing guid if available. @private @method generateGuid @for Ember @param {Object} [obj] Object the guid will be used for. If passed in, the guid will be saved on the object and reused whenever you pass the same object again. If no object is passed, just generate a new guid. @param {String} [prefix] Prefix to place in front of the guid. Useful when you want to separate the guid into separate namespaces. @return {String} the guid */ Ember.generateGuid = function generateGuid(obj, prefix) { if (!prefix) prefix = Ember.GUID_PREFIX; var ret = (prefix + (uuid++)); if (obj) { GUID_DESC.value = ret; o_defineProperty(obj, GUID_KEY, GUID_DESC); } return ret; }; /** Returns a unique id for the object. If the object does not yet have a guid, one will be assigned to it. You can call this on any object, `Ember.Object`-based or not, but be aware that it will add a `_guid` property. You can also use this method on DOM Element objects. @private @method guidFor @for Ember @param {Object} obj any object, string, number, Element, or primitive @return {String} the unique guid for this instance. */ Ember.guidFor = function guidFor(obj) { // special cases where we don't want to add a key to object if (obj === undefined) return "(undefined)"; if (obj === null) return "(null)"; var ret; var type = typeof obj; // Don't allow prototype changes to String etc. to change the guidFor switch(type) { case 'number': ret = numberCache[obj]; if (!ret) ret = numberCache[obj] = 'nu'+obj; return ret; case 'string': ret = stringCache[obj]; if (!ret) ret = stringCache[obj] = 'st'+(uuid++); return ret; case 'boolean': return obj ? '(true)' : '(false)'; default: if (obj[GUID_KEY]) return obj[GUID_KEY]; if (obj === Object) return '(Object)'; if (obj === Array) return '(Array)'; ret = 'ember'+(uuid++); GUID_DESC.value = ret; o_defineProperty(obj, GUID_KEY, GUID_DESC); return ret; } }; // .......................................................... // META // var META_DESC = Ember.META_DESC = { writable: true, configurable: false, enumerable: false, value: null }; var META_KEY = Ember.GUID_KEY+'_meta'; /** The key used to store meta information on object for property observing. @property META_KEY @for Ember @private @final @type String */ Ember.META_KEY = META_KEY; var isDefinePropertySimulated = Ember.platform.defineProperty.isSimulated; function Meta(obj) { this.descs = {}; this.watching = {}; this.cache = {}; this.source = obj; } Meta.prototype = { descs: null, deps: null, watching: null, listeners: null, cache: null, source: null, mixins: null, bindings: null, chains: null, chainWatchers: null, values: null, proto: null }; if (isDefinePropertySimulated) { // on platforms that don't support enumerable false // make meta fail jQuery.isPlainObject() to hide from // jQuery.extend() by having a property that fails // hasOwnProperty check. Meta.prototype.__preventPlainObject__ = true; // Without non-enumerable properties, meta objects will be output in JSON // unless explicitly suppressed Meta.prototype.toJSON = function () { }; } // Placeholder for non-writable metas. var EMPTY_META = new Meta(null); if (MANDATORY_SETTER) { EMPTY_META.values = {}; } Ember.EMPTY_META = EMPTY_META; /** Retrieves the meta hash for an object. If `writable` is true ensures the hash is writable for this object as well. The meta object contains information about computed property descriptors as well as any watched properties and other information. You generally will not access this information directly but instead work with higher level methods that manipulate this hash indirectly. @method meta @for Ember @private @param {Object} obj The object to retrieve meta for @param {Boolean} [writable=true] Pass `false` if you do not intend to modify the meta hash, allowing the method to avoid making an unnecessary copy. @return {Object} the meta hash for an object */ Ember.meta = function meta(obj, writable) { var ret = obj[META_KEY]; if (writable===false) return ret || EMPTY_META; if (!ret) { if (!isDefinePropertySimulated) o_defineProperty(obj, META_KEY, META_DESC); ret = new Meta(obj); if (MANDATORY_SETTER) { ret.values = {}; } obj[META_KEY] = ret; // make sure we don't accidentally try to create constructor like desc ret.descs.constructor = null; } else if (ret.source !== obj) { if (!isDefinePropertySimulated) o_defineProperty(obj, META_KEY, META_DESC); ret = o_create(ret); ret.descs = o_create(ret.descs); ret.watching = o_create(ret.watching); ret.cache = {}; ret.source = obj; if (MANDATORY_SETTER) { ret.values = o_create(ret.values); } obj[META_KEY] = ret; } return ret; }; Ember.getMeta = function getMeta(obj, property) { var meta = Ember.meta(obj, false); return meta[property]; }; Ember.setMeta = function setMeta(obj, property, value) { var meta = Ember.meta(obj, true); meta[property] = value; return value; }; /** @deprecated @private In order to store defaults for a class, a prototype may need to create a default meta object, which will be inherited by any objects instantiated from the class's constructor. However, the properties of that meta object are only shallow-cloned, so if a property is a hash (like the event system's `listeners` hash), it will by default be shared across all instances of that class. This method allows extensions to deeply clone a series of nested hashes or other complex objects. For instance, the event system might pass `['listeners', 'foo:change', 'ember157']` to `prepareMetaPath`, which will walk down the keys provided. For each key, if the key does not exist, it is created. If it already exists and it was inherited from its constructor, the constructor's key is cloned. You can also pass false for `writable`, which will simply return undefined if `prepareMetaPath` discovers any part of the path that shared or undefined. @method metaPath @for Ember @param {Object} obj The object whose meta we are examining @param {Array} path An array of keys to walk down @param {Boolean} writable whether or not to create a new meta (or meta property) if one does not already exist or if it's shared with its constructor */ Ember.metaPath = function metaPath(obj, path, writable) { var meta = Ember.meta(obj, writable), keyName, value; for (var i=0, l=path.length; i size ? size : ends; if (count <= 0) { count = 0; } chunk = args.splice(0, size); chunk = [start, count].concat(chunk); start += size; ends -= count; ret = ret.concat(splice.apply(array, chunk)); } return ret; }, /** * Replaces objects in an array with the passed objects. * * ```javascript * var array = [1,2,3]; * Ember.EnumerableUtils.replace(array, 1, 2, [4, 5]); // [1, 4, 5] * * var array = [1,2,3]; * Ember.EnumerableUtils.replace(array, 1, 1, [4, 5]); // [1, 4, 5, 3] * * var array = [1,2,3]; * Ember.EnumerableUtils.replace(array, 10, 1, [4, 5]); // [1, 2, 3, 4, 5] * ``` * * @method replace * @param {Array} array The array the objects should be inserted into. * @param {Number} idx Starting index in the array to replace. If *idx* >= * length, then append to the end of the array. * @param {Number} amt Number of elements that should be remove from the array, * starting at *idx* * @param {Array} objects An array of zero or more objects that should be * inserted into the array at *idx* * * @return {Array} The changed array. */ replace: function(array, idx, amt, objects) { if (array.replace) { return array.replace(idx, amt, objects); } else { return utils._replace(array, idx, amt, objects); } }, /** * Calculates the intersection of two arrays. This method returns a new array * filled with the records that the two passed arrays share with each other. * If there is no intersection, an empty array will be returned. * * ```javascript * var array1 = [1, 2, 3, 4, 5]; * var array2 = [1, 3, 5, 6, 7]; * * Ember.EnumerableUtils.intersection(array1, array2); // [1, 3, 5] * * var array1 = [1, 2, 3]; * var array2 = [4, 5, 6]; * * Ember.EnumerableUtils.intersection(array1, array2); // [] * ``` * * @method intersection * @param {Array} array1 The first array * @param {Array} array2 The second array * * @return {Array} The intersection of the two passed arrays. */ intersection: function(array1, array2) { var intersection = []; utils.forEach(array1, function(element) { if (utils.indexOf(array2, element) >= 0) { intersection.push(element); } }); return intersection; } }; })(); (function() { /** @module ember-metal */ var META_KEY = Ember.META_KEY, get; var MANDATORY_SETTER = Ember.ENV.MANDATORY_SETTER; var IS_GLOBAL_PATH = /^([A-Z$]|([0-9][A-Z$])).*[\.\*]/; var HAS_THIS = /^this[\.\*]/; var FIRST_KEY = /^([^\.\*]+)/; // .......................................................... // GET AND SET // // If we are on a platform that supports accessors we can use those. // Otherwise simulate accessors by looking up the property directly on the // object. /** Gets the value of a property on an object. If the property is computed, the function will be invoked. If the property is not defined but the object implements the `unknownProperty` method then that will be invoked. If you plan to run on IE8 and older browsers then you should use this method anytime you want to retrieve a property on an object that you don't know for sure is private. (Properties beginning with an underscore '_' are considered private.) On all newer browsers, you only need to use this method to retrieve properties if the property might not be defined on the object and you want to respect the `unknownProperty` handler. Otherwise you can ignore this method. Note that if the object itself is `undefined`, this method will throw an error. @method get @for Ember @param {Object} obj The object to retrieve from. @param {String} keyName The property key to retrieve @return {Object} the property value or `null`. */ get = function get(obj, keyName) { // Helpers that operate with 'this' within an #each if (keyName === '') { return obj; } if (!keyName && 'string'===typeof obj) { keyName = obj; obj = null; } if (obj === null || keyName.indexOf('.') !== -1) { return getPath(obj, keyName); } var meta = obj[META_KEY], desc = meta && meta.descs[keyName], ret; if (desc) { return desc.get(obj, keyName); } else { if (MANDATORY_SETTER && meta && meta.watching[keyName] > 0) { ret = meta.values[keyName]; } else { ret = obj[keyName]; } if (ret === undefined && 'object' === typeof obj && !(keyName in obj) && 'function' === typeof obj.unknownProperty) { return obj.unknownProperty(keyName); } return ret; } }; // Currently used only by Ember Data tests if (Ember.config.overrideAccessors) { Ember.get = get; Ember.config.overrideAccessors(); get = Ember.get; } /** Normalizes a target/path pair to reflect that actual target/path that should be observed, etc. This takes into account passing in global property paths (i.e. a path beginning with a captial letter not defined on the target) and * separators. @private @method normalizeTuple @for Ember @param {Object} target The current target. May be `null`. @param {String} path A path on the target or a global property path. @return {Array} a temporary array with the normalized target/path pair. */ var normalizeTuple = Ember.normalizeTuple = function(target, path) { var hasThis = HAS_THIS.test(path), isGlobal = !hasThis && IS_GLOBAL_PATH.test(path), key; if (!target || isGlobal) target = Ember.lookup; if (hasThis) path = path.slice(5); if (target === Ember.lookup) { key = path.match(FIRST_KEY)[0]; target = get(target, key); path = path.slice(key.length+1); } // must return some kind of path to be valid else other things will break. if (!path || path.length===0) throw new Ember.Error('Path cannot be empty'); return [ target, path ]; }; var getPath = Ember._getPath = function(root, path) { var hasThis, parts, tuple, idx, len; // If there is no root and path is a key name, return that // property from the global object. // E.g. get('Ember') -> Ember if (root === null && path.indexOf('.') === -1) { return get(Ember.lookup, path); } // detect complicated paths and normalize them hasThis = HAS_THIS.test(path); if (!root || hasThis) { tuple = normalizeTuple(root, path); root = tuple[0]; path = tuple[1]; tuple.length = 0; } parts = path.split("."); len = parts.length; for (idx = 0; root != null && idx < len; idx++) { root = get(root, parts[idx], true); if (root && root.isDestroyed) { return undefined; } } return root; }; Ember.getWithDefault = function(root, key, defaultValue) { var value = get(root, key); if (value === undefined) { return defaultValue; } return value; }; Ember.get = get; })(); (function() { /** @module ember-metal */ var o_create = Ember.create, metaFor = Ember.meta, META_KEY = Ember.META_KEY, a_slice = [].slice, /* listener flags */ ONCE = 1, SUSPENDED = 2; /* The event system uses a series of nested hashes to store listeners on an object. When a listener is registered, or when an event arrives, these hashes are consulted to determine which target and action pair to invoke. The hashes are stored in the object's meta hash, and look like this: // Object's meta hash { listeners: { // variable name: `listenerSet` "foo:changed": [ // variable name: `actions` target, method, flags ] } } */ function indexOf(array, target, method) { var index = -1; for (var i = 0, l = array.length; i < l; i += 3) { if (target === array[i] && method === array[i+1]) { index = i; break; } } return index; } function actionsFor(obj, eventName) { var meta = metaFor(obj, true), actions; if (!meta.listeners) { meta.listeners = {}; } if (!meta.hasOwnProperty('listeners')) { // setup inherited copy of the listeners object meta.listeners = o_create(meta.listeners); } actions = meta.listeners[eventName]; // if there are actions, but the eventName doesn't exist in our listeners, then copy them from the prototype if (actions && !meta.listeners.hasOwnProperty(eventName)) { actions = meta.listeners[eventName] = meta.listeners[eventName].slice(); } else if (!actions) { actions = meta.listeners[eventName] = []; } return actions; } function actionsUnion(obj, eventName, otherActions) { var meta = obj[META_KEY], actions = meta && meta.listeners && meta.listeners[eventName]; if (!actions) { return; } for (var i = actions.length - 3; i >= 0; i -= 3) { var target = actions[i], method = actions[i+1], flags = actions[i+2], actionIndex = indexOf(otherActions, target, method); if (actionIndex === -1) { otherActions.push(target, method, flags); } } } function actionsDiff(obj, eventName, otherActions) { var meta = obj[META_KEY], actions = meta && meta.listeners && meta.listeners[eventName], diffActions = []; if (!actions) { return; } for (var i = actions.length - 3; i >= 0; i -= 3) { var target = actions[i], method = actions[i+1], flags = actions[i+2], actionIndex = indexOf(otherActions, target, method); if (actionIndex !== -1) { continue; } otherActions.push(target, method, flags); diffActions.push(target, method, flags); } return diffActions; } /** Add an event listener @method addListener @for Ember @param obj @param {String} eventName @param {Object|Function} targetOrMethod A target object or a function @param {Function|String} method A function or the name of a function to be called on `target` @param {Boolean} once A flag whether a function should only be called once */ function addListener(obj, eventName, target, method, once) { if (!method && 'function' === typeof target) { method = target; target = null; } var actions = actionsFor(obj, eventName), actionIndex = indexOf(actions, target, method), flags = 0; if (once) flags |= ONCE; if (actionIndex !== -1) { return; } actions.push(target, method, flags); if ('function' === typeof obj.didAddListener) { obj.didAddListener(eventName, target, method); } } /** Remove an event listener Arguments should match those passed to `Ember.addListener`. @method removeListener @for Ember @param obj @param {String} eventName @param {Object|Function} targetOrMethod A target object or a function @param {Function|String} method A function or the name of a function to be called on `target` */ function removeListener(obj, eventName, target, method) { if (!method && 'function' === typeof target) { method = target; target = null; } function _removeListener(target, method) { var actions = actionsFor(obj, eventName), actionIndex = indexOf(actions, target, method); // action doesn't exist, give up silently if (actionIndex === -1) { return; } actions.splice(actionIndex, 3); if ('function' === typeof obj.didRemoveListener) { obj.didRemoveListener(eventName, target, method); } } if (method) { _removeListener(target, method); } else { var meta = obj[META_KEY], actions = meta && meta.listeners && meta.listeners[eventName]; if (!actions) { return; } for (var i = actions.length - 3; i >= 0; i -= 3) { _removeListener(actions[i], actions[i+1]); } } } /** Suspend listener during callback. This should only be used by the target of the event listener when it is taking an action that would cause the event, e.g. an object might suspend its property change listener while it is setting that property. @private @method suspendListener @for Ember @param obj @param {String} eventName @param {Object|Function} targetOrMethod A target object or a function @param {Function|String} method A function or the name of a function to be called on `target` @param {Function} callback */ function suspendListener(obj, eventName, target, method, callback) { if (!method && 'function' === typeof target) { method = target; target = null; } var actions = actionsFor(obj, eventName), actionIndex = indexOf(actions, target, method); if (actionIndex !== -1) { actions[actionIndex+2] |= SUSPENDED; // mark the action as suspended } function tryable() { return callback.call(target); } function finalizer() { if (actionIndex !== -1) { actions[actionIndex+2] &= ~SUSPENDED; } } return Ember.tryFinally(tryable, finalizer); } /** Suspends multiple listeners during a callback. @private @method suspendListeners @for Ember @param obj @param {Array} eventName Array of event names @param {Object|Function} targetOrMethod A target object or a function @param {Function|String} method A function or the name of a function to be called on `target` @param {Function} callback */ function suspendListeners(obj, eventNames, target, method, callback) { if (!method && 'function' === typeof target) { method = target; target = null; } var suspendedActions = [], actionsList = [], eventName, actions, i, l; for (i=0, l=eventNames.length; i= 0; i -= 3) { // looping in reverse for once listeners var target = actions[i], method = actions[i+1], flags = actions[i+2]; if (!method) { continue; } if (flags & SUSPENDED) { continue; } if (flags & ONCE) { removeListener(obj, eventName, target, method); } if (!target) { target = obj; } if ('string' === typeof method) { method = target[method]; } if (params) { method.apply(target, params); } else { method.call(target); } } return true; } /** @private @method hasListeners @for Ember @param obj @param {String} eventName */ function hasListeners(obj, eventName) { var meta = obj[META_KEY], actions = meta && meta.listeners && meta.listeners[eventName]; return !!(actions && actions.length); } /** @private @method listenersFor @for Ember @param obj @param {String} eventName */ function listenersFor(obj, eventName) { var ret = []; var meta = obj[META_KEY], actions = meta && meta.listeners && meta.listeners[eventName]; if (!actions) { return ret; } for (var i = 0, l = actions.length; i < l; i += 3) { var target = actions[i], method = actions[i+1]; ret.push([target, method]); } return ret; } /** Define a property as a function that should be executed when a specified event or events are triggered. ``` javascript var Job = Ember.Object.extend({ logCompleted: Ember.on('completed', function(){ console.log('Job completed!'); }) }); var job = Job.create(); Ember.sendEvent(job, 'completed'); // Logs "Job completed!" ``` @method on @for Ember @param {String} eventNames* @param {Function} func @return func */ Ember.on = function(){ var func = a_slice.call(arguments, -1)[0], events = a_slice.call(arguments, 0, -1); func.__ember_listens__ = events; return func; }; Ember.addListener = addListener; Ember.removeListener = removeListener; Ember._suspendListener = suspendListener; Ember._suspendListeners = suspendListeners; Ember.sendEvent = sendEvent; Ember.hasListeners = hasListeners; Ember.watchedEvents = watchedEvents; Ember.listenersFor = listenersFor; Ember.listenersDiff = actionsDiff; Ember.listenersUnion = actionsUnion; })(); (function() { var guidFor = Ember.guidFor, sendEvent = Ember.sendEvent; /* this.observerSet = { [senderGuid]: { // variable name: `keySet` [keyName]: listIndex } }, this.observers = [ { sender: obj, keyName: keyName, eventName: eventName, listeners: [ [target, method, flags] ] }, ... ] */ var ObserverSet = Ember._ObserverSet = function() { this.clear(); }; ObserverSet.prototype.add = function(sender, keyName, eventName) { var observerSet = this.observerSet, observers = this.observers, senderGuid = guidFor(sender), keySet = observerSet[senderGuid], index; if (!keySet) { observerSet[senderGuid] = keySet = {}; } index = keySet[keyName]; if (index === undefined) { index = observers.push({ sender: sender, keyName: keyName, eventName: eventName, listeners: [] }) - 1; keySet[keyName] = index; } return observers[index].listeners; }; ObserverSet.prototype.flush = function() { var observers = this.observers, i, len, observer, sender; this.clear(); for (i=0, len=observers.length; i < len; ++i) { observer = observers[i]; sender = observer.sender; if (sender.isDestroying || sender.isDestroyed) { continue; } sendEvent(sender, observer.eventName, [sender, observer.keyName], observer.listeners); } }; ObserverSet.prototype.clear = function() { this.observerSet = {}; this.observers = []; }; })(); (function() { var META_KEY = Ember.META_KEY, guidFor = Ember.guidFor, tryFinally = Ember.tryFinally, sendEvent = Ember.sendEvent, listenersUnion = Ember.listenersUnion, listenersDiff = Ember.listenersDiff, ObserverSet = Ember._ObserverSet, beforeObserverSet = new ObserverSet(), observerSet = new ObserverSet(), deferred = 0; // .......................................................... // PROPERTY CHANGES // /** This function is called just before an object property is about to change. It will notify any before observers and prepare caches among other things. Normally you will not need to call this method directly but if for some reason you can't directly watch a property you can invoke this method manually along with `Ember.propertyDidChange()` which you should call just after the property value changes. @method propertyWillChange @for Ember @param {Object} obj The object with the property that will change @param {String} keyName The property key (or path) that will change. @return {void} */ function propertyWillChange(obj, keyName) { var m = obj[META_KEY], watching = (m && m.watching[keyName] > 0) || keyName === 'length', proto = m && m.proto, desc = m && m.descs[keyName]; if (!watching) { return; } if (proto === obj) { return; } if (desc && desc.willChange) { desc.willChange(obj, keyName); } dependentKeysWillChange(obj, keyName, m); chainsWillChange(obj, keyName, m); notifyBeforeObservers(obj, keyName); } Ember.propertyWillChange = propertyWillChange; /** This function is called just after an object property has changed. It will notify any observers and clear caches among other things. Normally you will not need to call this method directly but if for some reason you can't directly watch a property you can invoke this method manually along with `Ember.propertyWillChange()` which you should call just before the property value changes. @method propertyDidChange @for Ember @param {Object} obj The object with the property that will change @param {String} keyName The property key (or path) that will change. @return {void} */ function propertyDidChange(obj, keyName) { var m = obj[META_KEY], watching = (m && m.watching[keyName] > 0) || keyName === 'length', proto = m && m.proto, desc = m && m.descs[keyName]; if (proto === obj) { return; } // shouldn't this mean that we're watching this key? if (desc && desc.didChange) { desc.didChange(obj, keyName); } if (!watching && keyName !== 'length') { return; } dependentKeysDidChange(obj, keyName, m); chainsDidChange(obj, keyName, m, false); notifyObservers(obj, keyName); } Ember.propertyDidChange = propertyDidChange; var WILL_SEEN, DID_SEEN; // called whenever a property is about to change to clear the cache of any dependent keys (and notify those properties of changes, etc...) function dependentKeysWillChange(obj, depKey, meta) { if (obj.isDestroying) { return; } var seen = WILL_SEEN, top = !seen; if (top) { seen = WILL_SEEN = {}; } iterDeps(propertyWillChange, obj, depKey, seen, meta); if (top) { WILL_SEEN = null; } } // called whenever a property has just changed to update dependent keys function dependentKeysDidChange(obj, depKey, meta) { if (obj.isDestroying) { return; } var seen = DID_SEEN, top = !seen; if (top) { seen = DID_SEEN = {}; } iterDeps(propertyDidChange, obj, depKey, seen, meta); if (top) { DID_SEEN = null; } } function iterDeps(method, obj, depKey, seen, meta) { var guid = guidFor(obj); if (!seen[guid]) seen[guid] = {}; if (seen[guid][depKey]) return; seen[guid][depKey] = true; var deps = meta.deps; deps = deps && deps[depKey]; if (deps) { for(var key in deps) { var desc = meta.descs[key]; if (desc && desc._suspended === obj) continue; method(obj, key); } } } function chainsWillChange(obj, keyName, m) { if (!(m.hasOwnProperty('chainWatchers') && m.chainWatchers[keyName])) { return; } var nodes = m.chainWatchers[keyName], events = [], i, l; for(i = 0, l = nodes.length; i < l; i++) { nodes[i].willChange(events); } for (i = 0, l = events.length; i < l; i += 2) { propertyWillChange(events[i], events[i+1]); } } function chainsDidChange(obj, keyName, m, suppressEvents) { if (!(m && m.hasOwnProperty('chainWatchers') && m.chainWatchers[keyName])) { return; } var nodes = m.chainWatchers[keyName], events = suppressEvents ? null : [], i, l; for(i = 0, l = nodes.length; i < l; i++) { nodes[i].didChange(events); } if (suppressEvents) { return; } for (i = 0, l = events.length; i < l; i += 2) { propertyDidChange(events[i], events[i+1]); } } Ember.overrideChains = function(obj, keyName, m) { chainsDidChange(obj, keyName, m, true); }; /** @method beginPropertyChanges @chainable @private */ function beginPropertyChanges() { deferred++; } Ember.beginPropertyChanges = beginPropertyChanges; /** @method endPropertyChanges @private */ function endPropertyChanges() { deferred--; if (deferred<=0) { beforeObserverSet.clear(); observerSet.flush(); } } Ember.endPropertyChanges = endPropertyChanges; /** Make a series of property changes together in an exception-safe way. ```javascript Ember.changeProperties(function() { obj1.set('foo', mayBlowUpWhenSet); obj2.set('bar', baz); }); ``` @method changeProperties @param {Function} callback @param [binding] */ Ember.changeProperties = function(cb, binding) { beginPropertyChanges(); tryFinally(cb, endPropertyChanges, binding); }; function notifyBeforeObservers(obj, keyName) { if (obj.isDestroying) { return; } var eventName = keyName + ':before', listeners, diff; if (deferred) { listeners = beforeObserverSet.add(obj, keyName, eventName); diff = listenersDiff(obj, eventName, listeners); sendEvent(obj, eventName, [obj, keyName], diff); } else { sendEvent(obj, eventName, [obj, keyName]); } } function notifyObservers(obj, keyName) { if (obj.isDestroying) { return; } var eventName = keyName + ':change', listeners; if (deferred) { listeners = observerSet.add(obj, keyName, eventName); listenersUnion(obj, eventName, listeners); } else { sendEvent(obj, eventName, [obj, keyName]); } } })(); (function() { // META_KEY // _getPath // propertyWillChange, propertyDidChange var META_KEY = Ember.META_KEY, MANDATORY_SETTER = Ember.ENV.MANDATORY_SETTER, IS_GLOBAL = /^([A-Z$]|([0-9][A-Z$]))/, getPath = Ember._getPath; /** Sets the value of a property on an object, respecting computed properties and notifying observers and other listeners of the change. If the property is not defined but the object implements the `setUnknownProperty` method then that will be invoked as well. If you plan to run on IE8 and older browsers then you should use this method anytime you want to set a property on an object that you don't know for sure is private. (Properties beginning with an underscore '_' are considered private.) On all newer browsers, you only need to use this method to set properties if the property might not be defined on the object and you want to respect the `setUnknownProperty` handler. Otherwise you can ignore this method. @method set @for Ember @param {Object} obj The object to modify. @param {String} keyName The property key to set @param {Object} value The value to set @return {Object} the passed value. */ var set = function set(obj, keyName, value, tolerant) { if (typeof obj === 'string') { value = keyName; keyName = obj; obj = null; } if (!obj || keyName.indexOf('.') !== -1) { return setPath(obj, keyName, value, tolerant); } var meta = obj[META_KEY], desc = meta && meta.descs[keyName], isUnknown, currentValue; if (desc) { desc.set(obj, keyName, value); } else { isUnknown = 'object' === typeof obj && !(keyName in obj); // setUnknownProperty is called if `obj` is an object, // the property does not already exist, and the // `setUnknownProperty` method exists on the object if (isUnknown && 'function' === typeof obj.setUnknownProperty) { obj.setUnknownProperty(keyName, value); } else if (meta && meta.watching[keyName] > 0) { if (MANDATORY_SETTER) { currentValue = meta.values[keyName]; } else { currentValue = obj[keyName]; } // only trigger a change if the value has changed if (value !== currentValue) { Ember.propertyWillChange(obj, keyName); if (MANDATORY_SETTER) { if ((currentValue === undefined && !(keyName in obj)) || !obj.propertyIsEnumerable(keyName)) { Ember.defineProperty(obj, keyName, null, value); // setup mandatory setter } else { meta.values[keyName] = value; } } else { obj[keyName] = value; } Ember.propertyDidChange(obj, keyName); } } else { obj[keyName] = value; } } return value; }; // Currently used only by Ember Data tests if (Ember.config.overrideAccessors) { Ember.set = set; Ember.config.overrideAccessors(); set = Ember.set; } function setPath(root, path, value, tolerant) { var keyName; // get the last part of the path keyName = path.slice(path.lastIndexOf('.') + 1); // get the first part of the part path = (path === keyName) ? keyName : path.slice(0, path.length-(keyName.length+1)); // unless the path is this, look up the first part to // get the root if (path !== 'this') { root = getPath(root, path); } if (!keyName || keyName.length === 0) { throw new Ember.Error('Property set failed: You passed an empty path'); } if (!root) { if (tolerant) { return; } else { throw new Ember.Error('Property set failed: object in path "'+path+'" could not be found or was destroyed.'); } } return set(root, keyName, value); } Ember.set = set; /** Error-tolerant form of `Ember.set`. Will not blow up if any part of the chain is `undefined`, `null`, or destroyed. This is primarily used when syncing bindings, which may try to update after an object has been destroyed. @method trySet @for Ember @param {Object} obj The object to modify. @param {String} path The property path to set @param {Object} value The value to set */ Ember.trySet = function(root, path, value) { return set(root, path, value, true); }; })(); (function() { /** @module ember-metal */ /* JavaScript (before ES6) does not have a Map implementation. Objects, which are often used as dictionaries, may only have Strings as keys. Because Ember has a way to get a unique identifier for every object via `Ember.guidFor`, we can implement a performant Map with arbitrary keys. Because it is commonly used in low-level bookkeeping, Map is implemented as a pure JavaScript object for performance. This implementation follows the current iteration of the ES6 proposal for maps (http://wiki.ecmascript.org/doku.php?id=harmony:simple_maps_and_sets), with two exceptions. First, because we need our implementation to be pleasant on older browsers, we do not use the `delete` name (using `remove` instead). Second, as we do not have the luxury of in-VM iteration, we implement a forEach method for iteration. Map is mocked out to look like an Ember object, so you can do `Ember.Map.create()` for symmetry with other Ember classes. */ var set = Ember.set, guidFor = Ember.guidFor, indexOf = Ember.ArrayPolyfills.indexOf; var copy = function(obj) { var output = {}; for (var prop in obj) { if (obj.hasOwnProperty(prop)) { output[prop] = obj[prop]; } } return output; }; var copyMap = function(original, newObject) { var keys = original.keys.copy(), values = copy(original.values); newObject.keys = keys; newObject.values = values; newObject.length = original.length; return newObject; }; /** This class is used internally by Ember and Ember Data. Please do not use it at this time. We plan to clean it up and add many tests soon. @class OrderedSet @namespace Ember @constructor @private */ var OrderedSet = Ember.OrderedSet = function() { this.clear(); }; /** @method create @static @return {Ember.OrderedSet} */ OrderedSet.create = function() { return new OrderedSet(); }; OrderedSet.prototype = { /** @method clear */ clear: function() { this.presenceSet = {}; this.list = []; }, /** @method add @param obj */ add: function(obj) { var guid = guidFor(obj), presenceSet = this.presenceSet, list = this.list; if (guid in presenceSet) { return; } presenceSet[guid] = true; list.push(obj); }, /** @method remove @param obj */ remove: function(obj) { var guid = guidFor(obj), presenceSet = this.presenceSet, list = this.list; delete presenceSet[guid]; var index = indexOf.call(list, obj); if (index > -1) { list.splice(index, 1); } }, /** @method isEmpty @return {Boolean} */ isEmpty: function() { return this.list.length === 0; }, /** @method has @param obj @return {Boolean} */ has: function(obj) { var guid = guidFor(obj), presenceSet = this.presenceSet; return guid in presenceSet; }, /** @method forEach @param {Function} fn @param self */ forEach: function(fn, self) { // allow mutation during iteration var list = this.toArray(); for (var i = 0, j = list.length; i < j; i++) { fn.call(self, list[i]); } }, /** @method toArray @return {Array} */ toArray: function() { return this.list.slice(); }, /** @method copy @return {Ember.OrderedSet} */ copy: function() { var set = new OrderedSet(); set.presenceSet = copy(this.presenceSet); set.list = this.toArray(); return set; } }; /** A Map stores values indexed by keys. Unlike JavaScript's default Objects, the keys of a Map can be any JavaScript object. Internally, a Map has two data structures: 1. `keys`: an OrderedSet of all of the existing keys 2. `values`: a JavaScript Object indexed by the `Ember.guidFor(key)` When a key/value pair is added for the first time, we add the key to the `keys` OrderedSet, and create or replace an entry in `values`. When an entry is deleted, we delete its entry in `keys` and `values`. @class Map @namespace Ember @private @constructor */ var Map = Ember.Map = function() { this.keys = Ember.OrderedSet.create(); this.values = {}; }; /** @method create @static */ Map.create = function() { return new Map(); }; Map.prototype = { /** This property will change as the number of objects in the map changes. @property length @type number @default 0 */ length: 0, /** Retrieve the value associated with a given key. @method get @param {*} key @return {*} the value associated with the key, or `undefined` */ get: function(key) { var values = this.values, guid = guidFor(key); return values[guid]; }, /** Adds a value to the map. If a value for the given key has already been provided, the new value will replace the old value. @method set @param {*} key @param {*} value */ set: function(key, value) { var keys = this.keys, values = this.values, guid = guidFor(key); keys.add(key); values[guid] = value; set(this, 'length', keys.list.length); }, /** Removes a value from the map for an associated key. @method remove @param {*} key @return {Boolean} true if an item was removed, false otherwise */ remove: function(key) { // don't use ES6 "delete" because it will be annoying // to use in browsers that are not ES6 friendly; var keys = this.keys, values = this.values, guid = guidFor(key); if (values.hasOwnProperty(guid)) { keys.remove(key); delete values[guid]; set(this, 'length', keys.list.length); return true; } else { return false; } }, /** Check whether a key is present. @method has @param {*} key @return {Boolean} true if the item was present, false otherwise */ has: function(key) { var values = this.values, guid = guidFor(key); return values.hasOwnProperty(guid); }, /** Iterate over all the keys and values. Calls the function once for each key, passing in the key and value, in that order. The keys are guaranteed to be iterated over in insertion order. @method forEach @param {Function} callback @param {*} self if passed, the `this` value inside the callback. By default, `this` is the map. */ forEach: function(callback, self) { var keys = this.keys, values = this.values; keys.forEach(function(key) { var guid = guidFor(key); callback.call(self, key, values[guid]); }); }, /** @method copy @return {Ember.Map} */ copy: function() { return copyMap(this, new Map()); } }; /** @class MapWithDefault @namespace Ember @extends Ember.Map @private @constructor @param [options] @param {*} [options.defaultValue] */ var MapWithDefault = Ember.MapWithDefault = function(options) { Map.call(this); this.defaultValue = options.defaultValue; }; /** @method create @static @param [options] @param {*} [options.defaultValue] @return {Ember.MapWithDefault|Ember.Map} If options are passed, returns `Ember.MapWithDefault` otherwise returns `Ember.Map` */ MapWithDefault.create = function(options) { if (options) { return new MapWithDefault(options); } else { return new Map(); } }; MapWithDefault.prototype = Ember.create(Map.prototype); /** Retrieve the value associated with a given key. @method get @param {*} key @return {*} the value associated with the key, or the default value */ MapWithDefault.prototype.get = function(key) { var hasValue = this.has(key); if (hasValue) { return Map.prototype.get.call(this, key); } else { var defaultValue = this.defaultValue(key); this.set(key, defaultValue); return defaultValue; } }; /** @method copy @return {Ember.MapWithDefault} */ MapWithDefault.prototype.copy = function() { return copyMap(this, new MapWithDefault({ defaultValue: this.defaultValue })); }; })(); (function() { function consoleMethod(name) { var consoleObj, logToConsole; if (Ember.imports.console) { consoleObj = Ember.imports.console; } else if (typeof console !== 'undefined') { consoleObj = console; } var method = typeof consoleObj === 'object' ? consoleObj[name] : null; if (method) { // Older IE doesn't support apply, but Chrome needs it if (method.apply) { logToConsole = function() { method.apply(consoleObj, arguments); }; logToConsole.displayName = 'console.' + name; return logToConsole; } else { return function() { var message = Array.prototype.join.call(arguments, ', '); method(message); }; } } } function assertPolyfill(test, message) { if (!test) { try { // attempt to preserve the stack throw new Ember.Error("assertion failed: " + message); } catch(error) { setTimeout(function() { throw error; }, 0); } } } /** Inside Ember-Metal, simply uses the methods from `imports.console`. Override this to provide more robust logging functionality. @class Logger @namespace Ember */ Ember.Logger = { /** Logs the arguments to the console. You can pass as many arguments as you want and they will be joined together with a space. ```javascript var foo = 1; Ember.Logger.log('log value of foo:', foo); // "log value of foo: 1" will be printed to the console ``` @method log @for Ember.Logger @param {*} arguments */ log: consoleMethod('log') || Ember.K, /** Prints the arguments to the console with a warning icon. You can pass as many arguments as you want and they will be joined together with a space. ```javascript Ember.Logger.warn('Something happened!'); // "Something happened!" will be printed to the console with a warning icon. ``` @method warn @for Ember.Logger @param {*} arguments */ warn: consoleMethod('warn') || Ember.K, /** Prints the arguments to the console with an error icon, red text and a stack trace. You can pass as many arguments as you want and they will be joined together with a space. ```javascript Ember.Logger.error('Danger! Danger!'); // "Danger! Danger!" will be printed to the console in red text. ``` @method error @for Ember.Logger @param {*} arguments */ error: consoleMethod('error') || Ember.K, /** Logs the arguments to the console. You can pass as many arguments as you want and they will be joined together with a space. ```javascript var foo = 1; Ember.Logger.info('log value of foo:', foo); // "log value of foo: 1" will be printed to the console ``` @method info @for Ember.Logger @param {*} arguments */ info: consoleMethod('info') || Ember.K, /** Logs the arguments to the console in blue text. You can pass as many arguments as you want and they will be joined together with a space. ```javascript var foo = 1; Ember.Logger.debug('log value of foo:', foo); // "log value of foo: 1" will be printed to the console ``` @method debug @for Ember.Logger @param {*} arguments */ debug: consoleMethod('debug') || consoleMethod('info') || Ember.K, /** If the value passed into `Ember.Logger.assert` is not truthy it will throw an error with a stack trace. ```javascript Ember.Logger.assert(true); // undefined Ember.Logger.assert(true === false); // Throws an Assertion failed error. ``` @method assert @for Ember.Logger @param {Boolean} bool Value to test */ assert: consoleMethod('assert') || assertPolyfill }; })(); (function() { /** @module ember-metal */ var META_KEY = Ember.META_KEY, metaFor = Ember.meta, objectDefineProperty = Ember.platform.defineProperty; var MANDATORY_SETTER = Ember.ENV.MANDATORY_SETTER; // .......................................................... // DESCRIPTOR // /** Objects of this type can implement an interface to respond to requests to get and set. The default implementation handles simple properties. You generally won't need to create or subclass this directly. @class Descriptor @namespace Ember @private @constructor */ Ember.Descriptor = function() {}; // .......................................................... // DEFINING PROPERTIES API // var MANDATORY_SETTER_FUNCTION = Ember.MANDATORY_SETTER_FUNCTION = function(value) { }; var DEFAULT_GETTER_FUNCTION = Ember.DEFAULT_GETTER_FUNCTION = function(name) { return function() { var meta = this[META_KEY]; return meta && meta.values[name]; }; }; /** NOTE: This is a low-level method used by other parts of the API. You almost never want to call this method directly. Instead you should use `Ember.mixin()` to define new properties. Defines a property on an object. This method works much like the ES5 `Object.defineProperty()` method except that it can also accept computed properties and other special descriptors. Normally this method takes only three parameters. However if you pass an instance of `Ember.Descriptor` as the third param then you can pass an optional value as the fourth parameter. This is often more efficient than creating new descriptor hashes for each property. ## Examples ```javascript // ES5 compatible mode Ember.defineProperty(contact, 'firstName', { writable: true, configurable: false, enumerable: true, value: 'Charles' }); // define a simple property Ember.defineProperty(contact, 'lastName', undefined, 'Jolley'); // define a computed property Ember.defineProperty(contact, 'fullName', Ember.computed(function() { return this.firstName+' '+this.lastName; }).property('firstName', 'lastName')); ``` @private @method defineProperty @for Ember @param {Object} obj the object to define this property on. This may be a prototype. @param {String} keyName the name of the property @param {Ember.Descriptor} [desc] an instance of `Ember.Descriptor` (typically a computed property) or an ES5 descriptor. You must provide this or `data` but not both. @param {*} [data] something other than a descriptor, that will become the explicit value of this property. */ Ember.defineProperty = function(obj, keyName, desc, data, meta) { var descs, existingDesc, watching, value; if (!meta) meta = metaFor(obj); descs = meta.descs; existingDesc = meta.descs[keyName]; watching = meta.watching[keyName] > 0; if (existingDesc instanceof Ember.Descriptor) { existingDesc.teardown(obj, keyName); } if (desc instanceof Ember.Descriptor) { value = desc; descs[keyName] = desc; if (MANDATORY_SETTER && watching) { objectDefineProperty(obj, keyName, { configurable: true, enumerable: true, writable: true, value: undefined // make enumerable }); } else { obj[keyName] = undefined; // make enumerable } if (desc.func && desc._dependentCPs) { addImplicitCPs(obj, desc._dependentCPs, meta); } } else { descs[keyName] = undefined; // shadow descriptor in proto if (desc == null) { value = data; if (MANDATORY_SETTER && watching) { meta.values[keyName] = data; objectDefineProperty(obj, keyName, { configurable: true, enumerable: true, set: MANDATORY_SETTER_FUNCTION, get: DEFAULT_GETTER_FUNCTION(keyName) }); } else { obj[keyName] = data; } } else { value = desc; // compatibility with ES5 objectDefineProperty(obj, keyName, desc); } } // if key is being watched, override chains that // were initialized with the prototype if (watching) { Ember.overrideChains(obj, keyName, meta); } // The `value` passed to the `didDefineProperty` hook is // either the descriptor or data, whichever was passed. if (obj.didDefineProperty) { obj.didDefineProperty(obj, keyName, value); } return this; }; var addImplicitCPs = function defineImplicitCPs(obj, implicitCPs, meta) { var cp, key, length = implicitCPs.length; for (var i=0; i 1) { watching[keyName]--; } }; })(); (function() { var metaFor = Ember.meta, // utils.js get = Ember.get, // property_get.js normalizeTuple = Ember.normalizeTuple, // property_get.js forEach = Ember.ArrayPolyfills.forEach, // array.js warn = Ember.warn, watchKey = Ember.watchKey, unwatchKey = Ember.unwatchKey, FIRST_KEY = /^([^\.\*]+)/, META_KEY = Ember.META_KEY; function firstKey(path) { return path.match(FIRST_KEY)[0]; } var pendingQueue = []; // attempts to add the pendingQueue chains again. If some of them end up // back in the queue and reschedule is true, schedules a timeout to try // again. Ember.flushPendingChains = function() { if (pendingQueue.length === 0) { return; } // nothing to do var queue = pendingQueue; pendingQueue = []; forEach.call(queue, function(q) { q[0].add(q[1]); }); warn('Watching an undefined global, Ember expects watched globals to be setup by the time the run loop is flushed, check for typos', pendingQueue.length === 0); }; function addChainWatcher(obj, keyName, node) { if (!obj || ('object' !== typeof obj)) { return; } // nothing to do var m = metaFor(obj), nodes = m.chainWatchers; if (!m.hasOwnProperty('chainWatchers')) { nodes = m.chainWatchers = {}; } if (!nodes[keyName]) { nodes[keyName] = []; } nodes[keyName].push(node); watchKey(obj, keyName, m); } var removeChainWatcher = Ember.removeChainWatcher = function(obj, keyName, node) { if (!obj || 'object' !== typeof obj) { return; } // nothing to do var m = obj[META_KEY]; if (m && !m.hasOwnProperty('chainWatchers')) { return; } // nothing to do var nodes = m && m.chainWatchers; if (nodes && nodes[keyName]) { nodes = nodes[keyName]; for (var i = 0, l = nodes.length; i < l; i++) { if (nodes[i] === node) { nodes.splice(i, 1); } } } unwatchKey(obj, keyName, m); }; // A ChainNode watches a single key on an object. If you provide a starting // value for the key then the node won't actually watch it. For a root node // pass null for parent and key and object for value. var ChainNode = Ember._ChainNode = function(parent, key, value) { this._parent = parent; this._key = key; // _watching is true when calling get(this._parent, this._key) will // return the value of this node. // // It is false for the root of a chain (because we have no parent) // and for global paths (because the parent node is the object with // the observer on it) this._watching = value===undefined; this._value = value; this._paths = {}; if (this._watching) { this._object = parent.value(); if (this._object) { addChainWatcher(this._object, this._key, this); } } // Special-case: the EachProxy relies on immediate evaluation to // establish its observers. // // TODO: Replace this with an efficient callback that the EachProxy // can implement. if (this._parent && this._parent._key === '@each') { this.value(); } }; var ChainNodePrototype = ChainNode.prototype; function lazyGet(obj, key) { if (!obj) return undefined; var meta = obj[META_KEY]; // check if object meant only to be a prototype if (meta && meta.proto === obj) return undefined; if (key === "@each") return get(obj, key); // if a CP only return cached value var desc = meta && meta.descs[key]; if (desc && desc._cacheable) { if (key in meta.cache) { return meta.cache[key]; } else { return undefined; } } return get(obj, key); } ChainNodePrototype.value = function() { if (this._value === undefined && this._watching) { var obj = this._parent.value(); this._value = lazyGet(obj, this._key); } return this._value; }; ChainNodePrototype.destroy = function() { if (this._watching) { var obj = this._object; if (obj) { removeChainWatcher(obj, this._key, this); } this._watching = false; // so future calls do nothing } }; // copies a top level object only ChainNodePrototype.copy = function(obj) { var ret = new ChainNode(null, null, obj), paths = this._paths, path; for (path in paths) { if (paths[path] <= 0) { continue; } // this check will also catch non-number vals. ret.add(path); } return ret; }; // called on the root node of a chain to setup watchers on the specified // path. ChainNodePrototype.add = function(path) { var obj, tuple, key, src, paths; paths = this._paths; paths[path] = (paths[path] || 0) + 1; obj = this.value(); tuple = normalizeTuple(obj, path); // the path was a local path if (tuple[0] && tuple[0] === obj) { path = tuple[1]; key = firstKey(path); path = path.slice(key.length+1); // global path, but object does not exist yet. // put into a queue and try to connect later. } else if (!tuple[0]) { pendingQueue.push([this, path]); tuple.length = 0; return; // global path, and object already exists } else { src = tuple[0]; key = path.slice(0, 0-(tuple[1].length+1)); path = tuple[1]; } tuple.length = 0; this.chain(key, path, src); }; // called on the root node of a chain to teardown watcher on the specified // path ChainNodePrototype.remove = function(path) { var obj, tuple, key, src, paths; paths = this._paths; if (paths[path] > 0) { paths[path]--; } obj = this.value(); tuple = normalizeTuple(obj, path); if (tuple[0] === obj) { path = tuple[1]; key = firstKey(path); path = path.slice(key.length+1); } else { src = tuple[0]; key = path.slice(0, 0-(tuple[1].length+1)); path = tuple[1]; } tuple.length = 0; this.unchain(key, path); }; ChainNodePrototype.count = 0; ChainNodePrototype.chain = function(key, path, src) { var chains = this._chains, node; if (!chains) { chains = this._chains = {}; } node = chains[key]; if (!node) { node = chains[key] = new ChainNode(this, key, src); } node.count++; // count chains... // chain rest of path if there is one if (path && path.length>0) { key = firstKey(path); path = path.slice(key.length+1); node.chain(key, path); // NOTE: no src means it will observe changes... } }; ChainNodePrototype.unchain = function(key, path) { var chains = this._chains, node = chains[key]; // unchain rest of path first... if (path && path.length>1) { key = firstKey(path); path = path.slice(key.length+1); node.unchain(key, path); } // delete node if needed. node.count--; if (node.count<=0) { delete chains[node._key]; node.destroy(); } }; ChainNodePrototype.willChange = function(events) { var chains = this._chains; if (chains) { for(var key in chains) { if (!chains.hasOwnProperty(key)) { continue; } chains[key].willChange(events); } } if (this._parent) { this._parent.chainWillChange(this, this._key, 1, events); } }; ChainNodePrototype.chainWillChange = function(chain, path, depth, events) { if (this._key) { path = this._key + '.' + path; } if (this._parent) { this._parent.chainWillChange(this, path, depth+1, events); } else { if (depth > 1) { events.push(this.value(), path); } path = 'this.' + path; if (this._paths[path] > 0) { events.push(this.value(), path); } } }; ChainNodePrototype.chainDidChange = function(chain, path, depth, events) { if (this._key) { path = this._key + '.' + path; } if (this._parent) { this._parent.chainDidChange(this, path, depth+1, events); } else { if (depth > 1) { events.push(this.value(), path); } path = 'this.' + path; if (this._paths[path] > 0) { events.push(this.value(), path); } } }; ChainNodePrototype.didChange = function(events) { // invalidate my own value first. if (this._watching) { var obj = this._parent.value(); if (obj !== this._object) { removeChainWatcher(this._object, this._key, this); this._object = obj; addChainWatcher(obj, this._key, this); } this._value = undefined; // Special-case: the EachProxy relies on immediate evaluation to // establish its observers. if (this._parent && this._parent._key === '@each') this.value(); } // then notify chains... var chains = this._chains; if (chains) { for(var key in chains) { if (!chains.hasOwnProperty(key)) { continue; } chains[key].didChange(events); } } // if no events are passed in then we only care about the above wiring update if (events === null) { return; } // and finally tell parent about my path changing... if (this._parent) { this._parent.chainDidChange(this, this._key, 1, events); } }; Ember.finishChains = function(obj) { // We only create meta if we really have to var m = obj[META_KEY], chains = m && m.chains; if (chains) { if (chains.value() !== obj) { metaFor(obj).chains = chains = chains.copy(obj); } else { chains.didChange(null); } } }; })(); (function() { /** @module ember-metal */ var forEach = Ember.EnumerableUtils.forEach, BRACE_EXPANSION = /^((?:[^\.]*\.)*)\{(.*)\}$/; /** Expands `pattern`, invoking `callback` for each expansion. The only pattern supported is brace-expansion, anything else will be passed once to `callback` directly. Brace expansion can only appear at the end of a pattern, for example as the last item in a chain. Example ```js function echo(arg){ console.log(arg); } Ember.expandProperties('foo.bar', echo); //=> 'foo.bar' Ember.expandProperties('{foo,bar}', echo); //=> 'foo', 'bar' Ember.expandProperties('foo.{bar,baz}', echo); //=> 'foo.bar', 'foo.baz' Ember.expandProperties('{foo,bar}.baz', echo); //=> '{foo,bar}.baz' ``` @method @private @param {string} pattern The property pattern to expand. @param {function} callback The callback to invoke. It is invoked once per expansion, and is passed the expansion. */ Ember.expandProperties = function (pattern, callback) { var match, prefix, list; if (match = BRACE_EXPANSION.exec(pattern)) { prefix = match[1]; list = match[2]; forEach(list.split(','), function (suffix) { callback(prefix + suffix); }); } else { callback(pattern); } }; })(); (function() { var metaFor = Ember.meta, // utils.js typeOf = Ember.typeOf, // utils.js ChainNode = Ember._ChainNode; // chains.js // get the chains for the current object. If the current object has // chains inherited from the proto they will be cloned and reconfigured for // the current object. function chainsFor(obj, meta) { var m = meta || metaFor(obj), ret = m.chains; if (!ret) { ret = m.chains = new ChainNode(null, null, obj); } else if (ret.value() !== obj) { ret = m.chains = ret.copy(obj); } return ret; } Ember.watchPath = function(obj, keyPath, meta) { // can't watch length on Array - it is special... if (keyPath === 'length' && typeOf(obj) === 'array') { return; } var m = meta || metaFor(obj), watching = m.watching; if (!watching[keyPath]) { // activate watching first time watching[keyPath] = 1; chainsFor(obj, m).add(keyPath); } else { watching[keyPath] = (watching[keyPath] || 0) + 1; } }; Ember.unwatchPath = function(obj, keyPath, meta) { var m = meta || metaFor(obj), watching = m.watching; if (watching[keyPath] === 1) { watching[keyPath] = 0; chainsFor(obj, m).remove(keyPath); } else if (watching[keyPath] > 1) { watching[keyPath]--; } }; })(); (function() { /** @module ember-metal */ var metaFor = Ember.meta, // utils.js GUID_KEY = Ember.GUID_KEY, // utils.js META_KEY = Ember.META_KEY, // utils.js removeChainWatcher = Ember.removeChainWatcher, watchKey = Ember.watchKey, // watch_key.js unwatchKey = Ember.unwatchKey, watchPath = Ember.watchPath, // watch_path.js unwatchPath = Ember.unwatchPath, typeOf = Ember.typeOf, // utils.js generateGuid = Ember.generateGuid, IS_PATH = /[\.\*]/; // returns true if the passed path is just a keyName function isKeyName(path) { return path==='*' || !IS_PATH.test(path); } /** Starts watching a property on an object. Whenever the property changes, invokes `Ember.propertyWillChange` and `Ember.propertyDidChange`. This is the primitive used by observers and dependent keys; usually you will never call this method directly but instead use higher level methods like `Ember.addObserver()` @private @method watch @for Ember @param obj @param {String} keyName */ Ember.watch = function(obj, _keyPath, m) { // can't watch length on Array - it is special... if (_keyPath === 'length' && typeOf(obj) === 'array') { return; } if (isKeyName(_keyPath)) { watchKey(obj, _keyPath, m); } else { watchPath(obj, _keyPath, m); } }; Ember.isWatching = function isWatching(obj, key) { var meta = obj[META_KEY]; return (meta && meta.watching[key]) > 0; }; Ember.watch.flushPending = Ember.flushPendingChains; Ember.unwatch = function(obj, _keyPath, m) { // can't watch length on Array - it is special... if (_keyPath === 'length' && typeOf(obj) === 'array') { return; } if (isKeyName(_keyPath)) { unwatchKey(obj, _keyPath, m); } else { unwatchPath(obj, _keyPath, m); } }; /** Call on an object when you first beget it from another object. This will setup any chained watchers on the object instance as needed. This method is safe to call multiple times. @private @method rewatch @for Ember @param obj */ Ember.rewatch = function(obj) { var m = obj[META_KEY], chains = m && m.chains; // make sure the object has its own guid. if (GUID_KEY in obj && !obj.hasOwnProperty(GUID_KEY)) { generateGuid(obj); } // make sure any chained watchers update. if (chains && chains.value() !== obj) { m.chains = chains.copy(obj); } }; var NODE_STACK = []; /** Tears down the meta on an object so that it can be garbage collected. Multiple calls will have no effect. @method destroy @for Ember @param {Object} obj the object to destroy @return {void} */ Ember.destroy = function (obj) { var meta = obj[META_KEY], node, nodes, key, nodeObject; if (meta) { obj[META_KEY] = null; // remove chainWatchers to remove circular references that would prevent GC node = meta.chains; if (node) { NODE_STACK.push(node); // process tree while (NODE_STACK.length > 0) { node = NODE_STACK.pop(); // push children nodes = node._chains; if (nodes) { for (key in nodes) { if (nodes.hasOwnProperty(key)) { NODE_STACK.push(nodes[key]); } } } // remove chainWatcher in node object if (node._watching) { nodeObject = node._object; if (nodeObject) { removeChainWatcher(nodeObject, node._key, node); } } } } } }; })(); (function() { /** @module ember-metal */ var get = Ember.get, set = Ember.set, metaFor = Ember.meta, a_slice = [].slice, o_create = Ember.create, META_KEY = Ember.META_KEY, watch = Ember.watch, unwatch = Ember.unwatch; var expandProperties = Ember.expandProperties; // .......................................................... // DEPENDENT KEYS // // data structure: // meta.deps = { // 'depKey': { // 'keyName': count, // } // } /* This function returns a map of unique dependencies for a given object and key. */ function keysForDep(depsMeta, depKey) { var keys = depsMeta[depKey]; if (!keys) { // if there are no dependencies yet for a the given key // create a new empty list of dependencies for the key keys = depsMeta[depKey] = {}; } else if (!depsMeta.hasOwnProperty(depKey)) { // otherwise if the dependency list is inherited from // a superclass, clone the hash keys = depsMeta[depKey] = o_create(keys); } return keys; } function metaForDeps(meta) { return keysForDep(meta, 'deps'); } function addDependentKeys(desc, obj, keyName, meta) { // the descriptor has a list of dependent keys, so // add all of its dependent keys. var depKeys = desc._dependentKeys, depsMeta, idx, len, depKey, keys; if (!depKeys) return; depsMeta = metaForDeps(meta); for(idx = 0, len = depKeys.length; idx < len; idx++) { depKey = depKeys[idx]; // Lookup keys meta for depKey keys = keysForDep(depsMeta, depKey); // Increment the number of times depKey depends on keyName. keys[keyName] = (keys[keyName] || 0) + 1; // Watch the depKey watch(obj, depKey, meta); } } function removeDependentKeys(desc, obj, keyName, meta) { // the descriptor has a list of dependent keys, so // add all of its dependent keys. var depKeys = desc._dependentKeys, depsMeta, idx, len, depKey, keys; if (!depKeys) return; depsMeta = metaForDeps(meta); for(idx = 0, len = depKeys.length; idx < len; idx++) { depKey = depKeys[idx]; // Lookup keys meta for depKey keys = keysForDep(depsMeta, depKey); // Increment the number of times depKey depends on keyName. keys[keyName] = (keys[keyName] || 0) - 1; // Watch the depKey unwatch(obj, depKey, meta); } } // .......................................................... // COMPUTED PROPERTY // /** A computed property transforms an objects function into a property. By default the function backing the computed property will only be called once and the result will be cached. You can specify various properties that your computed property is dependent on. This will force the cached result to be recomputed if the dependencies are modified. In the following example we declare a computed property (by calling `.property()` on the fullName function) and setup the properties dependencies (depending on firstName and lastName). The fullName function will be called once (regardless of how many times it is accessed) as long as it's dependencies have not been changed. Once firstName or lastName are updated any future calls (or anything bound) to fullName will incorporate the new values. ```javascript Person = Ember.Object.extend({ // these will be supplied by `create` firstName: null, lastName: null, fullName: function() { var firstName = this.get('firstName'); var lastName = this.get('lastName'); return firstName + ' ' + lastName; }.property('firstName', 'lastName') }); var tom = Person.create({ firstName: "Tom", lastName: "Dale" }); tom.get('fullName') // "Tom Dale" ``` You can also define what Ember should do when setting a computed property. If you try to set a computed property, it will be invoked with the key and value you want to set it to. You can also accept the previous value as the third parameter. ```javascript Person = Ember.Object.extend({ // these will be supplied by `create` firstName: null, lastName: null, fullName: function(key, value, oldValue) { // getter if (arguments.length === 1) { var firstName = this.get('firstName'); var lastName = this.get('lastName'); return firstName + ' ' + lastName; // setter } else { var name = value.split(" "); this.set('firstName', name[0]); this.set('lastName', name[1]); return value; } }.property('firstName', 'lastName') }); var person = Person.create(); person.set('fullName', "Peter Wagenet"); person.get('firstName') // Peter person.get('lastName') // Wagenet ``` @class ComputedProperty @namespace Ember @extends Ember.Descriptor @constructor */ function ComputedProperty(func, opts) { this.func = func; setDependentKeys(this, opts && opts.dependentKeys); this._cacheable = (opts && opts.cacheable !== undefined) ? opts.cacheable : true; this._readOnly = opts && (opts.readOnly !== undefined || !!opts.readOnly); } Ember.ComputedProperty = ComputedProperty; ComputedProperty.prototype = new Ember.Descriptor(); var ComputedPropertyPrototype = ComputedProperty.prototype; ComputedPropertyPrototype.toString = function() { if (this.implicitCPKey) { return this.implicitCPKey; } return Ember.Descriptor.prototype.toString.apply(this, arguments); }; /** Properties are cacheable by default. Computed property will automatically cache the return value of your function until one of the dependent keys changes. Call `volatile()` to set it into non-cached mode. When in this mode the computed property will not automatically cache the return value. However, if a property is properly observable, there is no reason to disable caching. @method cacheable @param {Boolean} aFlag optional set to `false` to disable caching @return {Ember.ComputedProperty} this @chainable */ ComputedPropertyPrototype.cacheable = function(aFlag) { this._cacheable = aFlag !== false; return this; }; /** Call on a computed property to set it into non-cached mode. When in this mode the computed property will not automatically cache the return value. ```javascript MyApp.outsideService = Ember.Object.extend({ value: function() { return OutsideService.getValue(); }.property().volatile() }).create(); ``` @method volatile @return {Ember.ComputedProperty} this @chainable */ ComputedPropertyPrototype.volatile = function() { return this.cacheable(false); }; /** Call on a computed property to set it into read-only mode. When in this mode the computed property will throw an error when set. ```javascript MyApp.Person = Ember.Object.extend({ guid: function() { return 'guid-guid-guid'; }.property().readOnly() }); MyApp.person = MyApp.Person.create(); MyApp.person.set('guid', 'new-guid'); // will throw an exception ``` @method readOnly @return {Ember.ComputedProperty} this @chainable */ ComputedPropertyPrototype.readOnly = function(readOnly) { this._readOnly = readOnly === undefined || !!readOnly; return this; }; /** Sets the dependent keys on this computed property. Pass any number of arguments containing key paths that this computed property depends on. ```javascript MyApp.President = Ember.Object.extend({ fullName: Ember.computed(function() { return this.get('firstName') + ' ' + this.get('lastName'); // Tell Ember that this computed property depends on firstName // and lastName }).property('firstName', 'lastName') }); MyApp.president = MyApp.President.create({ firstName: 'Barack', lastName: 'Obama', }); MyApp.president.get('fullName'); // Barack Obama ``` @method property @param {String} path* zero or more property paths @return {Ember.ComputedProperty} this @chainable */ ComputedPropertyPrototype.property = function() { var args; var addArg = function (property) { args.push(property); }; args = []; for (var i = 0, l = arguments.length; i < l; i++) { expandProperties(arguments[i], addArg); } setDependentKeys(this, args); return this; }; /** In some cases, you may want to annotate computed properties with additional metadata about how they function or what values they operate on. For example, computed property functions may close over variables that are then no longer available for introspection. You can pass a hash of these values to a computed property like this: ``` person: function() { var personId = this.get('personId'); return App.Person.create({ id: personId }); }.property().meta({ type: App.Person }) ``` The hash that you pass to the `meta()` function will be saved on the computed property descriptor under the `_meta` key. Ember runtime exposes a public API for retrieving these values from classes, via the `metaForProperty()` function. @method meta @param {Hash} meta @chainable */ ComputedPropertyPrototype.meta = function(meta) { if (arguments.length === 0) { return this._meta || {}; } else { this._meta = meta; return this; } }; /* impl descriptor API */ ComputedPropertyPrototype.didChange = function(obj, keyName) { // _suspended is set via a CP.set to ensure we don't clear // the cached value set by the setter if (this._cacheable && this._suspended !== obj) { var meta = metaFor(obj); if (keyName in meta.cache) { delete meta.cache[keyName]; removeDependentKeys(this, obj, keyName, meta); } } }; function finishChains(chainNodes) { for (var i=0, l=chainNodes.length; i 1) { args = a_slice.call(arguments, 0, -1); func = a_slice.call(arguments, -1)[0]; } if (typeof func !== "function") { throw new Ember.Error("Computed Property declared without a property function"); } var cp = new ComputedProperty(func); if (args) { cp.property.apply(cp, args); } return cp; }; /** Returns the cached value for a property, if one exists. This can be useful for peeking at the value of a computed property that is generated lazily, without accidentally causing it to be created. @method cacheFor @for Ember @param {Object} obj the object whose property you want to check @param {String} key the name of the property whose cached value you want to return @return {Object} the cached value */ Ember.cacheFor = function cacheFor(obj, key) { var meta = obj[META_KEY], cache = meta && meta.cache; if (cache && key in cache) { return cache[key]; } }; function getProperties(self, propertyNames) { var ret = {}; for(var i = 0; i < propertyNames.length; i++) { ret[propertyNames[i]] = get(self, propertyNames[i]); } return ret; } var registerComputed, registerComputedWithProperties; var guidFor = Ember.guidFor, map = Ember.EnumerableUtils.map, filter = Ember.EnumerableUtils.filter, typeOf = Ember.typeOf; var implicitKey = function (cp) { return [guidFor(cp)].concat(cp._dependentKeys).join('_'); }; var normalizeDependentKey = function (key) { if (key instanceof Ember.ComputedProperty) { return implicitKey(key); } else if (typeof key === 'string' || key instanceof String || typeof key === 'object' || typeof key === 'number') { return key; } else { } }; var normalizeDependentKeys = function (keys) { return map(keys, function (key) { return normalizeDependentKey(key); }); }; var selectDependentCPs = function (keys) { return filter(keys, function (key) { return key instanceof Ember.ComputedProperty; }); }; var setDependentKeys = function(cp, dependentKeys) { if (dependentKeys) { cp._dependentKeys = normalizeDependentKeys(dependentKeys); cp._dependentCPs = selectDependentCPs(dependentKeys); cp.implicitCPKey = implicitKey(cp); } else { cp._dependentKeys = cp._dependentCPs = []; delete cp.implicitCPKey; } }; // expose `normalizeDependentKey[s]` so user CP macros can easily support // composition Ember.computed.normalizeDependentKey = normalizeDependentKey; Ember.computed.normalizeDependentKeys = normalizeDependentKeys; registerComputed = function (name, macro) { Ember.computed[name] = function(dependentKey) { var args = normalizeDependentKeys(a_slice.call(arguments)); return Ember.computed(dependentKey, function() { return macro.apply(this, args); }); }; }; registerComputedWithProperties = function(name, macro) { Ember.computed[name] = function() { var args = a_slice.call(arguments); var properties = normalizeDependentKeys(args); var computed = Ember.computed(function() { return macro.apply(this, [getProperties(this, properties)]); }); return computed.property.apply(computed, args); }; }; Ember.computed.literal = function (value) { return Ember.computed(function () { return value; }); }; /** A computed property that returns true if the value of the dependent property is null, an empty string, empty array, or empty function. Note: When using `Ember.computed.empty` to watch an array make sure to use the `array.[]` syntax so the computed can subscribe to transitions from empty to non-empty states. Example ```javascript var ToDoList = Ember.Object.extend({ done: Ember.computed.empty('todos.[]') // detect array changes }); var todoList = ToDoList.create({todos: ['Unit Test', 'Documentation', 'Release']}); todoList.get('done'); // false todoList.get('todos').clear(); // [] todoList.get('done'); // true ``` @method computed.empty @for Ember @param {String} dependentKey @return {Ember.ComputedProperty} computed property which negate the original value for property */ registerComputed('empty', function(dependentKey) { return Ember.isEmpty(get(this, dependentKey)); }); /** A computed property that returns true if the value of the dependent property is NOT null, an empty string, empty array, or empty function. Note: When using `Ember.computed.notEmpty` to watch an array make sure to use the `array.[]` syntax so the computed can subscribe to transitions from empty to non-empty states. Example ```javascript var Hamster = Ember.Object.extend({ hasStuff: Ember.computed.notEmpty('backpack.[]') }); var hamster = Hamster.create({backpack: ['Food', 'Sleeping Bag', 'Tent']}); hamster.get('hasStuff'); // true hamster.get('backpack').clear(); // [] hamster.get('hasStuff'); // false ``` @method computed.notEmpty @for Ember @param {String} dependentKey @return {Ember.ComputedProperty} computed property which returns true if original value for property is not empty. */ registerComputed('notEmpty', function(dependentKey) { return !Ember.isEmpty(get(this, dependentKey)); }); /** A computed property that returns true if the value of the dependent property is null or undefined. This avoids errors from JSLint complaining about use of ==, which can be technically confusing. Example ```javascript var Hamster = Ember.Object.extend({ isHungry: Ember.computed.none('food') }); var hamster = Hamster.create(); hamster.get('isHungry'); // true hamster.set('food', 'Banana'); hamster.get('isHungry'); // false hamster.set('food', null); hamster.get('isHungry'); // true ``` @method computed.none @for Ember @param {String} dependentKey @return {Ember.ComputedProperty} computed property which returns true if original value for property is null or undefined. */ registerComputed('none', function(dependentKey) { return Ember.isNone(get(this, dependentKey)); }); /** A computed property that returns the inverse boolean value of the original value for the dependent property. Example ```javascript var User = Ember.Object.extend({ isAnonymous: Ember.computed.not('loggedIn') }); var user = User.create({loggedIn: false}); user.get('isAnonymous'); // true user.set('loggedIn', true); user.get('isAnonymous'); // false ``` @method computed.not @for Ember @param {String} dependentKey @return {Ember.ComputedProperty} computed property which returns inverse of the original value for property */ registerComputed('not', function(dependentKey) { return !get(this, dependentKey); }); /** A computed property that converts the provided dependent property into a boolean value. ```javascript var Hamster = Ember.Object.extend({ hasBananas: Ember.computed.bool('numBananas') }); var hamster = Hamster.create(); hamster.get('hasBananas'); // false hamster.set('numBananas', 0); hamster.get('hasBananas'); // false hamster.set('numBananas', 1); hamster.get('hasBananas'); // true hamster.set('numBananas', null); hamster.get('hasBananas'); // false ``` @method computed.bool @for Ember @param {String} dependentKey @return {Ember.ComputedProperty} computed property which converts to boolean the original value for property */ registerComputed('bool', function(dependentKey) { return !!get(this, dependentKey); }); /** A computed property which matches the original value for the dependent property against a given RegExp, returning `true` if they values matches the RegExp and `false` if it does not. Example ```javascript var User = Ember.Object.extend({ hasValidEmail: Ember.computed.match('email', /^.+@.+\..+$/) }); var user = User.create({loggedIn: false}); user.get('hasValidEmail'); // false user.set('email', ''); user.get('hasValidEmail'); // false user.set('email', 'ember_hamster@example.com'); user.get('hasValidEmail'); // true ``` @method computed.match @for Ember @param {String} dependentKey @param {RegExp} regexp @return {Ember.ComputedProperty} computed property which match the original value for property against a given RegExp */ registerComputed('match', function(dependentKey, regexp) { var value = get(this, dependentKey); return typeof value === 'string' ? regexp.test(value) : false; }); /** A computed property that returns true if the provided dependent property is equal to the given value. Example ```javascript var Hamster = Ember.Object.extend({ napTime: Ember.computed.equal('state', 'sleepy') }); var hamster = Hamster.create(); hamster.get('napTime'); // false hamster.set('state', 'sleepy'); hamster.get('napTime'); // true hamster.set('state', 'hungry'); hamster.get('napTime'); // false ``` @method computed.equal @for Ember @param {String} dependentKey @param {String|Number|Object} value @return {Ember.ComputedProperty} computed property which returns true if the original value for property is equal to the given value. */ registerComputed('equal', function(dependentKey, value) { return get(this, dependentKey) === value; }); /** A computed property that returns true if the provied dependent property is greater than the provided value. Example ```javascript var Hamster = Ember.Object.extend({ hasTooManyBananas: Ember.computed.gt('numBananas', 10) }); var hamster = Hamster.create(); hamster.get('hasTooManyBananas'); // false hamster.set('numBananas', 3); hamster.get('hasTooManyBananas'); // false hamster.set('numBananas', 11); hamster.get('hasTooManyBananas'); // true ``` @method computed.gt @for Ember @param {String} dependentKey @param {Number} value @return {Ember.ComputedProperty} computed property which returns true if the original value for property is greater then given value. */ registerComputed('gt', function(dependentKey, value) { return get(this, dependentKey) > value; }); /** A computed property that returns true if the provided dependent property is greater than or equal to the provided value. Example ```javascript var Hamster = Ember.Object.extend({ hasTooManyBananas: Ember.computed.gte('numBananas', 10) }); var hamster = Hamster.create(); hamster.get('hasTooManyBananas'); // false hamster.set('numBananas', 3); hamster.get('hasTooManyBananas'); // false hamster.set('numBananas', 10); hamster.get('hasTooManyBananas'); // true ``` @method computed.gte @for Ember @param {String} dependentKey @param {Number} value @return {Ember.ComputedProperty} computed property which returns true if the original value for property is greater or equal then given value. */ registerComputed('gte', function(dependentKey, value) { return get(this, dependentKey) >= value; }); /** A computed property that returns true if the provided dependent property is less than the provided value. Example ```javascript var Hamster = Ember.Object.extend({ needsMoreBananas: Ember.computed.lt('numBananas', 3) }); var hamster = Hamster.create(); hamster.get('needsMoreBananas'); // true hamster.set('numBananas', 3); hamster.get('needsMoreBananas'); // false hamster.set('numBananas', 2); hamster.get('needsMoreBananas'); // true ``` @method computed.lt @for Ember @param {String} dependentKey @param {Number} value @return {Ember.ComputedProperty} computed property which returns true if the original value for property is less then given value. */ registerComputed('lt', function(dependentKey, value) { return get(this, dependentKey) < value; }); /** A computed property that returns true if the provided dependent property is less than or equal to the provided value. Example ```javascript var Hamster = Ember.Object.extend({ needsMoreBananas: Ember.computed.lte('numBananas', 3) }); var hamster = Hamster.create(); hamster.get('needsMoreBananas'); // true hamster.set('numBananas', 5); hamster.get('needsMoreBananas'); // false hamster.set('numBananas', 3); hamster.get('needsMoreBananas'); // true ``` @method computed.lte @for Ember @param {String} dependentKey @param {Number} value @return {Ember.ComputedProperty} computed property which returns true if the original value for property is less or equal then given value. */ registerComputed('lte', function(dependentKey, value) { return get(this, dependentKey) <= value; }); /** A computed property that performs a logical `and` on the original values for the provided dependent properties. Example ```javascript var Hamster = Ember.Object.extend({ readyForCamp: Ember.computed.and('hasTent', 'hasBackpack') }); var hamster = Hamster.create(); hamster.get('readyForCamp'); // false hamster.set('hasTent', true); hamster.get('readyForCamp'); // false hamster.set('hasBackpack', true); hamster.get('readyForCamp'); // true ``` @method computed.and @for Ember @param {String} dependentKey* @return {Ember.ComputedProperty} computed property which performs a logical `and` on the values of all the original values for properties. */ registerComputedWithProperties('and', function(properties) { for (var key in properties) { if (properties.hasOwnProperty(key) && !properties[key]) { return false; } } return true; }); /** A computed property which performs a logical `or` on the original values for the provided dependent properties. Example ```javascript var Hamster = Ember.Object.extend({ readyForRain: Ember.computed.or('hasJacket', 'hasUmbrella') }); var hamster = Hamster.create(); hamster.get('readyForRain'); // false hamster.set('hasJacket', true); hamster.get('readyForRain'); // true ``` @method computed.or @for Ember @param {String} dependentKey* @return {Ember.ComputedProperty} computed property which performs a logical `or` on the values of all the original values for properties. */ registerComputedWithProperties('or', function(properties) { for (var key in properties) { if (properties.hasOwnProperty(key) && properties[key]) { return true; } } return false; }); /** A computed property that returns the first truthy value from a list of dependent properties. Example ```javascript var Hamster = Ember.Object.extend({ hasClothes: Ember.computed.any('hat', 'shirt') }); var hamster = Hamster.create(); hamster.get('hasClothes'); // null hamster.set('shirt', 'Hawaiian Shirt'); hamster.get('hasClothes'); // 'Hawaiian Shirt' ``` @method computed.any @for Ember @param {String} dependentKey* @return {Ember.ComputedProperty} computed property which returns the first truthy value of given list of properties. */ registerComputedWithProperties('any', function(properties) { for (var key in properties) { if (properties.hasOwnProperty(key) && properties[key]) { return properties[key]; } } return null; }); /** A computed property that returns the array of values for the provided dependent properties. Example ```javascript var Hamster = Ember.Object.extend({ clothes: Ember.computed.collect('hat', 'shirt') }); var hamster = Hamster.create(); hamster.get('clothes'); // [null, null] hamster.set('hat', 'Camp Hat'); hamster.set('shirt', 'Camp Shirt'); hamster.get('clothes'); // ['Camp Hat', 'Camp Shirt'] ``` @method computed.collect @for Ember @param {String} dependentKey* @return {Ember.ComputedProperty} computed property which maps values of all passed properties in to an array. */ registerComputedWithProperties('collect', function(properties) { var res = []; for (var key in properties) { if (properties.hasOwnProperty(key)) { if (Ember.isNone(properties[key])) { res.push(null); } else { res.push(properties[key]); } } } return res; }); /** Creates a new property that is an alias for another property on an object. Calls to `get` or `set` this property behave as though they were called on the original property. ```javascript Person = Ember.Object.extend({ name: 'Alex Matchneer', nomen: Ember.computed.alias('name') }); alex = Person.create(); alex.get('nomen'); // 'Alex Matchneer' alex.get('name'); // 'Alex Matchneer' alex.set('nomen', '@machty'); alex.get('name'); // '@machty' ``` @method computed.alias @for Ember @param {String} dependentKey @return {Ember.ComputedProperty} computed property which creates an alias to the original value for property. */ Ember.computed.alias = function(dependentKey) { return Ember.computed(dependentKey, function(key, value) { if (arguments.length > 1) { set(this, dependentKey, value); return value; } else { return get(this, dependentKey); } }); }; /** Where `computed.alias` aliases `get` and `set`, and allows for bidirectional data flow, `computed.oneWay` only provides an aliased `get`. The `set` will not mutate the upstream property, rather causes the current property to become the value set. This causes the downstream property to permentantly diverge from the upstream property. Example ```javascript User = Ember.Object.extend({ firstName: null, lastName: null, nickName: Ember.computed.oneWay('firstName') }); user = User.create({ firstName: 'Teddy', lastName: 'Zeenny' }); user.get('nickName'); # 'Teddy' user.set('nickName', 'TeddyBear'); # 'TeddyBear' user.get('firstName'); # 'Teddy' ``` @method computed.oneWay @for Ember @param {String} dependentKey @return {Ember.ComputedProperty} computed property which creates a one way computed property to the original value for property. */ Ember.computed.oneWay = function(dependentKey) { return Ember.computed(dependentKey, function() { return get(this, dependentKey); }); }; if (Ember.FEATURES.isEnabled('computed-read-only')) { /** Where `computed.oneWay` provides oneWay bindings, `computed.readOnly` provides a readOnly one way binding. Very often when using `computed.oneWay` one does not also want changes to propogate back up, as they will replace the value. This prevents the reverse flow, and also throws an exception when it occurs. Example ```javascript User = Ember.Object.extend({ firstName: null, lastName: null, nickName: Ember.computed.readOnly('firstName') }); user = User.create({ firstName: 'Teddy', lastName: 'Zeenny' }); user.get('nickName'); # 'Teddy' user.set('nickName', 'TeddyBear'); # throws Exception # throw new Ember.Error('Cannot Set: nickName on: ' );` user.get('firstName'); # 'Teddy' ``` @method computed.readOnly @for Ember @param {String} dependentKey @return {Ember.ComputedProperty} computed property which creates a one way computed property to the original value for property. */ Ember.computed.readOnly = function(dependentKey) { return Ember.computed(dependentKey, function() { return get(this, dependentKey); }).readOnly(); }; } /** A computed property that acts like a standard getter and setter, but returns the value at the provided `defaultPath` if the property itself has not been set to a value Example ```javascript var Hamster = Ember.Object.extend({ wishList: Ember.computed.defaultTo('favoriteFood') }); var hamster = Hamster.create({favoriteFood: 'Banana'}); hamster.get('wishList'); // 'Banana' hamster.set('wishList', 'More Unit Tests'); hamster.get('wishList'); // 'More Unit Tests' hamster.get('favoriteFood'); // 'Banana' ``` @method computed.defaultTo @for Ember @param {String} defaultPath @return {Ember.ComputedProperty} computed property which acts like a standard getter and setter, but defaults to the value from `defaultPath`. */ Ember.computed.defaultTo = function(defaultPath) { return Ember.computed(function(key, newValue, cachedValue) { if (arguments.length === 1) { return cachedValue != null ? cachedValue : get(this, defaultPath); } return newValue != null ? newValue : get(this, defaultPath); }); }; })(); (function() { // Ember.tryFinally /** @module ember-metal */ var AFTER_OBSERVERS = ':change', BEFORE_OBSERVERS = ':before'; function changeEvent(keyName) { return keyName+AFTER_OBSERVERS; } function beforeEvent(keyName) { return keyName+BEFORE_OBSERVERS; } /** @method addObserver @param obj @param {String} path @param {Object|Function} targetOrMethod @param {Function|String} [method] */ Ember.addObserver = function(obj, _path, target, method) { Ember.addListener(obj, changeEvent(_path), target, method); Ember.watch(obj, _path); return this; }; Ember.observersFor = function(obj, path) { return Ember.listenersFor(obj, changeEvent(path)); }; /** @method removeObserver @param obj @param {String} path @param {Object|Function} targetOrMethod @param {Function|String} [method] */ Ember.removeObserver = function(obj, _path, target, method) { Ember.unwatch(obj, _path); Ember.removeListener(obj, changeEvent(_path), target, method); return this; }; /** @method addBeforeObserver @param obj @param {String} path @param {Object|Function} targetOrMethod @param {Function|String} [method] */ Ember.addBeforeObserver = function(obj, _path, target, method) { Ember.addListener(obj, beforeEvent(_path), target, method); Ember.watch(obj, _path); return this; }; // Suspend observer during callback. // // This should only be used by the target of the observer // while it is setting the observed path. Ember._suspendBeforeObserver = function(obj, path, target, method, callback) { return Ember._suspendListener(obj, beforeEvent(path), target, method, callback); }; Ember._suspendObserver = function(obj, path, target, method, callback) { return Ember._suspendListener(obj, changeEvent(path), target, method, callback); }; var map = Ember.ArrayPolyfills.map; Ember._suspendBeforeObservers = function(obj, paths, target, method, callback) { var events = map.call(paths, beforeEvent); return Ember._suspendListeners(obj, events, target, method, callback); }; Ember._suspendObservers = function(obj, paths, target, method, callback) { var events = map.call(paths, changeEvent); return Ember._suspendListeners(obj, events, target, method, callback); }; Ember.beforeObserversFor = function(obj, path) { return Ember.listenersFor(obj, beforeEvent(path)); }; /** @method removeBeforeObserver @param obj @param {String} path @param {Object|Function} targetOrMethod @param {Function|String} [method] */ Ember.removeBeforeObserver = function(obj, _path, target, method) { Ember.unwatch(obj, _path); Ember.removeListener(obj, beforeEvent(_path), target, method); return this; }; })(); (function() { define("backburner/queue", ["exports"], function(__exports__) { "use strict"; function Queue(daq, name, options) { this.daq = daq; this.name = name; this.options = options; this._queue = []; } Queue.prototype = { daq: null, name: null, options: null, _queue: null, push: function(target, method, args, stack) { var queue = this._queue; queue.push(target, method, args, stack); return {queue: this, target: target, method: method}; }, pushUnique: function(target, method, args, stack) { var queue = this._queue, currentTarget, currentMethod, i, l; for (i = 0, l = queue.length; i < l; i += 4) { currentTarget = queue[i]; currentMethod = queue[i+1]; if (currentTarget === target && currentMethod === method) { queue[i+2] = args; // replace args queue[i+3] = stack; // replace stack return {queue: this, target: target, method: method}; // TODO: test this code path } } this._queue.push(target, method, args, stack); return {queue: this, target: target, method: method}; }, // TODO: remove me, only being used for Ember.run.sync flush: function() { var queue = this._queue, options = this.options, before = options && options.before, after = options && options.after, target, method, args, stack, i, l = queue.length; if (l && before) { before(); } for (i = 0; i < l; i += 4) { target = queue[i]; method = queue[i+1]; args = queue[i+2]; stack = queue[i+3]; // Debugging assistance // TODO: error handling if (args && args.length > 0) { method.apply(target, args); } else { method.call(target); } } if (l && after) { after(); } // check if new items have been added if (queue.length > l) { this._queue = queue.slice(l); this.flush(); } else { this._queue.length = 0; } }, cancel: function(actionToCancel) { var queue = this._queue, currentTarget, currentMethod, i, l; for (i = 0, l = queue.length; i < l; i += 4) { currentTarget = queue[i]; currentMethod = queue[i+1]; if (currentTarget === actionToCancel.target && currentMethod === actionToCancel.method) { queue.splice(i, 4); return true; } } // if not found in current queue // could be in the queue that is being flushed queue = this._queueBeingFlushed; if (!queue) { return; } for (i = 0, l = queue.length; i < l; i += 4) { currentTarget = queue[i]; currentMethod = queue[i+1]; if (currentTarget === actionToCancel.target && currentMethod === actionToCancel.method) { // don't mess with array during flush // just nullify the method queue[i+1] = null; return true; } } } }; __exports__.Queue = Queue; }); define("backburner/deferred_action_queues", ["backburner/queue","exports"], function(__dependency1__, __exports__) { "use strict"; var Queue = __dependency1__.Queue; function DeferredActionQueues(queueNames, options) { var queues = this.queues = {}; this.queueNames = queueNames = queueNames || []; var queueName; for (var i = 0, l = queueNames.length; i < l; i++) { queueName = queueNames[i]; queues[queueName] = new Queue(this, queueName, options[queueName]); } } DeferredActionQueues.prototype = { queueNames: null, queues: null, schedule: function(queueName, target, method, args, onceFlag, stack) { var queues = this.queues, queue = queues[queueName]; if (!queue) { throw new Error("You attempted to schedule an action in a queue (" + queueName + ") that doesn't exist"); } if (onceFlag) { return queue.pushUnique(target, method, args, stack); } else { return queue.push(target, method, args, stack); } }, flush: function() { var queues = this.queues, queueNames = this.queueNames, queueName, queue, queueItems, priorQueueNameIndex, queueNameIndex = 0, numberOfQueues = queueNames.length; outerloop: while (queueNameIndex < numberOfQueues) { queueName = queueNames[queueNameIndex]; queue = queues[queueName]; queueItems = queue._queueBeingFlushed = queue._queue.slice(); queue._queue = []; var options = queue.options, before = options && options.before, after = options && options.after, target, method, args, stack, queueIndex = 0, numberOfQueueItems = queueItems.length; if (numberOfQueueItems && before) { before(); } while (queueIndex < numberOfQueueItems) { target = queueItems[queueIndex]; method = queueItems[queueIndex+1]; args = queueItems[queueIndex+2]; stack = queueItems[queueIndex+3]; // Debugging assistance if (typeof method === 'string') { method = target[method]; } // method could have been nullified / canceled during flush if (method) { // TODO: error handling if (args && args.length > 0) { method.apply(target, args); } else { method.call(target); } } queueIndex += 4; } queue._queueBeingFlushed = null; if (numberOfQueueItems && after) { after(); } if ((priorQueueNameIndex = indexOfPriorQueueWithActions(this, queueNameIndex)) !== -1) { queueNameIndex = priorQueueNameIndex; continue outerloop; } queueNameIndex++; } } }; function indexOfPriorQueueWithActions(daq, currentQueueIndex) { var queueName, queue; for (var i = 0, l = currentQueueIndex; i <= l; i++) { queueName = daq.queueNames[i]; queue = daq.queues[queueName]; if (queue._queue.length) { return i; } } return -1; } __exports__.DeferredActionQueues = DeferredActionQueues; }); define("backburner", ["backburner/deferred_action_queues","exports"], function(__dependency1__, __exports__) { "use strict"; var DeferredActionQueues = __dependency1__.DeferredActionQueues; var slice = [].slice, pop = [].pop, throttlers = [], debouncees = [], timers = [], autorun, laterTimer, laterTimerExpiresAt, global = this, NUMBER = /\d+/; function isCoercableNumber(number) { return typeof number === 'number' || NUMBER.test(number); } function Backburner(queueNames, options) { this.queueNames = queueNames; this.options = options || {}; if (!this.options.defaultQueue) { this.options.defaultQueue = queueNames[0]; } this.instanceStack = []; } Backburner.prototype = { queueNames: null, options: null, currentInstance: null, instanceStack: null, begin: function() { var onBegin = this.options && this.options.onBegin, previousInstance = this.currentInstance; if (previousInstance) { this.instanceStack.push(previousInstance); } this.currentInstance = new DeferredActionQueues(this.queueNames, this.options); if (onBegin) { onBegin(this.currentInstance, previousInstance); } }, end: function() { var onEnd = this.options && this.options.onEnd, currentInstance = this.currentInstance, nextInstance = null; try { currentInstance.flush(); } finally { this.currentInstance = null; if (this.instanceStack.length) { nextInstance = this.instanceStack.pop(); this.currentInstance = nextInstance; } if (onEnd) { onEnd(currentInstance, nextInstance); } } }, run: function(target, method /*, args */) { var ret; this.begin(); if (!method) { method = target; target = null; } if (typeof method === 'string') { method = target[method]; } // Prevent Safari double-finally. var finallyAlreadyCalled = false; try { if (arguments.length > 2) { ret = method.apply(target, slice.call(arguments, 2)); } else { ret = method.call(target); } } finally { if (!finallyAlreadyCalled) { finallyAlreadyCalled = true; this.end(); } } return ret; }, defer: function(queueName, target, method /* , args */) { if (!method) { method = target; target = null; } if (typeof method === 'string') { method = target[method]; } var stack = this.DEBUG ? new Error() : undefined, args = arguments.length > 3 ? slice.call(arguments, 3) : undefined; if (!this.currentInstance) { createAutorun(this); } return this.currentInstance.schedule(queueName, target, method, args, false, stack); }, deferOnce: function(queueName, target, method /* , args */) { if (!method) { method = target; target = null; } if (typeof method === 'string') { method = target[method]; } var stack = this.DEBUG ? new Error() : undefined, args = arguments.length > 3 ? slice.call(arguments, 3) : undefined; if (!this.currentInstance) { createAutorun(this); } return this.currentInstance.schedule(queueName, target, method, args, true, stack); }, setTimeout: function() { var args = slice.call(arguments); var length = args.length; var method, wait, target; var self = this; var methodOrTarget, methodOrWait, methodOrArgs; if (length === 0) { return; } else if (length === 1) { method = args.shift(); wait = 0; } else if (length === 2) { methodOrTarget = args[0]; methodOrWait = args[1]; if (typeof methodOrWait === 'function' || typeof methodOrTarget[methodOrWait] === 'function') { target = args.shift(); method = args.shift(); wait = 0; } else if (isCoercableNumber(methodOrWait)) { method = args.shift(); wait = args.shift(); } else { method = args.shift(); wait = 0; } } else { var last = args[args.length - 1]; if (isCoercableNumber(last)) { wait = args.pop(); } methodOrTarget = args[0]; methodOrArgs = args[1]; if (typeof methodOrArgs === 'function' || (typeof methodOrArgs === 'string' && methodOrTarget !== null && methodOrArgs in methodOrTarget)) { target = args.shift(); method = args.shift(); } else { method = args.shift(); } } var executeAt = (+new Date()) + parseInt(wait, 10); if (typeof method === 'string') { method = target[method]; } function fn() { method.apply(target, args); } // find position to insert - TODO: binary search var i, l; for (i = 0, l = timers.length; i < l; i += 2) { if (executeAt < timers[i]) { break; } } timers.splice(i, 0, executeAt, fn); updateLaterTimer(self, executeAt, wait); return fn; }, throttle: function(target, method /* , args, wait */) { var self = this, args = arguments, wait = parseInt(pop.call(args), 10), throttler, index, timer; index = findThrottler(target, method); if (index > -1) { return throttlers[index]; } // throttled timer = global.setTimeout(function() { self.run.apply(self, args); var index = findThrottler(target, method); if (index > -1) { throttlers.splice(index, 1); } }, wait); throttler = [target, method, timer]; throttlers.push(throttler); return throttler; }, debounce: function(target, method /* , args, wait, [immediate] */) { var self = this, args = arguments, immediate = pop.call(args), wait, index, debouncee, timer; if (typeof immediate === "number" || typeof immediate === "string") { wait = immediate; immediate = false; } else { wait = pop.call(args); } wait = parseInt(wait, 10); // Remove debouncee index = findDebouncee(target, method); if (index > -1) { debouncee = debouncees[index]; debouncees.splice(index, 1); clearTimeout(debouncee[2]); } timer = global.setTimeout(function() { if (!immediate) { self.run.apply(self, args); } var index = findDebouncee(target, method); if (index > -1) { debouncees.splice(index, 1); } }, wait); if (immediate && index === -1) { self.run.apply(self, args); } debouncee = [target, method, timer]; debouncees.push(debouncee); return debouncee; }, cancelTimers: function() { var i, len; for (i = 0, len = throttlers.length; i < len; i++) { clearTimeout(throttlers[i][2]); } throttlers = []; for (i = 0, len = debouncees.length; i < len; i++) { clearTimeout(debouncees[i][2]); } debouncees = []; if (laterTimer) { clearTimeout(laterTimer); laterTimer = null; } timers = []; if (autorun) { clearTimeout(autorun); autorun = null; } }, hasTimers: function() { return !!timers.length || autorun; }, cancel: function(timer) { var timerType = typeof timer; if (timer && timerType === 'object' && timer.queue && timer.method) { // we're cancelling a deferOnce return timer.queue.cancel(timer); } else if (timerType === 'function') { // we're cancelling a setTimeout for (var i = 0, l = timers.length; i < l; i += 2) { if (timers[i + 1] === timer) { timers.splice(i, 2); // remove the two elements return true; } } } else if (window.toString.call(timer) === "[object Array]"){ // we're cancelling a throttle or debounce return this._cancelItem(findThrottler, throttlers, timer) || this._cancelItem(findDebouncee, debouncees, timer); } else { return; // timer was null or not a timer } }, _cancelItem: function(findMethod, array, timer){ var item, index; if (timer.length < 3) { return false; } index = findMethod(timer[0], timer[1]); if(index > -1) { item = array[index]; if(item[2] === timer[2]){ array.splice(index, 1); clearTimeout(timer[2]); return true; } } return false; } }; Backburner.prototype.schedule = Backburner.prototype.defer; Backburner.prototype.scheduleOnce = Backburner.prototype.deferOnce; Backburner.prototype.later = Backburner.prototype.setTimeout; function createAutorun(backburner) { backburner.begin(); autorun = global.setTimeout(function() { autorun = null; backburner.end(); }); } function updateLaterTimer(self, executeAt, wait) { if (!laterTimer || executeAt < laterTimerExpiresAt) { if (laterTimer) { clearTimeout(laterTimer); } laterTimer = global.setTimeout(function() { laterTimer = null; laterTimerExpiresAt = null; executeTimers(self); }, wait); laterTimerExpiresAt = executeAt; } } function executeTimers(self) { var now = +new Date(), time, fns, i, l; self.run(function() { // TODO: binary search for (i = 0, l = timers.length; i < l; i += 2) { time = timers[i]; if (time > now) { break; } } fns = timers.splice(0, i); for (i = 1, l = fns.length; i < l; i += 2) { self.schedule(self.options.defaultQueue, null, fns[i]); } }); if (timers.length) { updateLaterTimer(self, timers[0], timers[0] - now); } } function findDebouncee(target, method) { var debouncee, index = -1; for (var i = 0, l = debouncees.length; i < l; i++) { debouncee = debouncees[i]; if (debouncee[0] === target && debouncee[1] === method) { index = i; break; } } return index; } function findThrottler(target, method) { var throttler, index = -1; for (var i = 0, l = throttlers.length; i < l; i++) { throttler = throttlers[i]; if (throttler[0] === target && throttler[1] === method) { index = i; break; } } return index; } __exports__.Backburner = Backburner; }); })(); (function() { var onBegin = function(current) { Ember.run.currentRunLoop = current; }; var onEnd = function(current, next) { Ember.run.currentRunLoop = next; }; var Backburner = requireModule('backburner').Backburner, backburner = new Backburner(['sync', 'actions', 'destroy'], { sync: { before: Ember.beginPropertyChanges, after: Ember.endPropertyChanges }, defaultQueue: 'actions', onBegin: onBegin, onEnd: onEnd }), slice = [].slice, concat = [].concat; // .......................................................... // Ember.run - this is ideally the only public API the dev sees // /** Runs the passed target and method inside of a RunLoop, ensuring any deferred actions including bindings and views updates are flushed at the end. Normally you should not need to invoke this method yourself. However if you are implementing raw event handlers when interfacing with other libraries or plugins, you should probably wrap all of your code inside this call. ```javascript Ember.run(function() { // code to be execute within a RunLoop }); ``` @class run @namespace Ember @static @constructor @param {Object} [target] target of method to call @param {Function|String} method Method to invoke. May be a function or a string. If you pass a string then it will be looked up on the passed target. @param {Object} [args*] Any additional arguments you wish to pass to the method. @return {Object} return value from invoking the passed function. */ Ember.run = function(target, method) { var ret; if (Ember.onerror) { try { ret = backburner.run.apply(backburner, arguments); } catch (e) { Ember.onerror(e); } } else { ret = backburner.run.apply(backburner, arguments); } return ret; }; /** If no run-loop is present, it creates a new one. If a run loop is present it will queue itself to run on the existing run-loops action queue. Please note: This is not for normal usage, and should be used sparingly. If invoked when not within a run loop: ```javascript Ember.run.join(function() { // creates a new run-loop }); ``` Alternatively, if called within an existing run loop: ```javascript Ember.run(function() { // creates a new run-loop Ember.run.join(function() { // joins with the existing run-loop, and queues for invocation on // the existing run-loops action queue. }); }); ``` @method join @namespace Ember @param {Object} [target] target of method to call @param {Function|String} method Method to invoke. May be a function or a string. If you pass a string then it will be looked up on the passed target. @param {Object} [args*] Any additional arguments you wish to pass to the method. @return {Object} Return value from invoking the passed function. Please note, when called within an existing loop, no return value is possible. */ Ember.run.join = function(target, method /* args */) { if (!Ember.run.currentRunLoop) { return Ember.run.apply(Ember.run, arguments); } var args = slice.call(arguments); args.unshift('actions'); Ember.run.schedule.apply(Ember.run, args); }; /** Provides a useful utility for when integrating with non-Ember libraries that provide asynchronous callbacks. Ember utilizes a run-loop to batch and coalesce changes. This works by marking the start and end of Ember-related Javascript execution. When using events such as a View's click handler, Ember wraps the event handler in a run-loop, but when integrating with non-Ember libraries this can be tedious. For example, the following is rather verbose but is the correct way to combine third-party events and Ember code. ```javascript var that = this; jQuery(window).on('resize', function(){ Ember.run(function(){ that.handleResize(); }); }); ``` To reduce the boilerplate, the following can be used to construct a run-loop-wrapped callback handler. ```javascript jQuery(window).on('resize', Ember.run.bind(this, this.triggerResize)); ``` @method bind @namespace Ember.run @param {Object} [target] target of method to call @param {Function|String} method Method to invoke. May be a function or a string. If you pass a string then it will be looked up on the passed target. @param {Object} [args*] Any additional arguments you wish to pass to the method. @return {Object} return value from invoking the passed function. Please note, when called within an existing loop, no return value is possible. */ Ember.run.bind = function(target, method /* args*/) { var args = arguments; return function() { return Ember.run.join.apply(Ember.run, args); }; }; Ember.run.backburner = backburner; var run = Ember.run; Ember.run.currentRunLoop = null; Ember.run.queues = backburner.queueNames; /** Begins a new RunLoop. Any deferred actions invoked after the begin will be buffered until you invoke a matching call to `Ember.run.end()`. This is a lower-level way to use a RunLoop instead of using `Ember.run()`. ```javascript Ember.run.begin(); // code to be execute within a RunLoop Ember.run.end(); ``` @method begin @return {void} */ Ember.run.begin = function() { backburner.begin(); }; /** Ends a RunLoop. This must be called sometime after you call `Ember.run.begin()` to flush any deferred actions. This is a lower-level way to use a RunLoop instead of using `Ember.run()`. ```javascript Ember.run.begin(); // code to be execute within a RunLoop Ember.run.end(); ``` @method end @return {void} */ Ember.run.end = function() { backburner.end(); }; /** Array of named queues. This array determines the order in which queues are flushed at the end of the RunLoop. You can define your own queues by simply adding the queue name to this array. Normally you should not need to inspect or modify this property. @property queues @type Array @default ['sync', 'actions', 'destroy'] */ /** Adds the passed target/method and any optional arguments to the named queue to be executed at the end of the RunLoop. If you have not already started a RunLoop when calling this method one will be started for you automatically. At the end of a RunLoop, any methods scheduled in this way will be invoked. Methods will be invoked in an order matching the named queues defined in the `Ember.run.queues` property. ```javascript Ember.run.schedule('sync', this, function() { // this will be executed in the first RunLoop queue, when bindings are synced console.log("scheduled on sync queue"); }); Ember.run.schedule('actions', this, function() { // this will be executed in the 'actions' queue, after bindings have synced. console.log("scheduled on actions queue"); }); // Note the functions will be run in order based on the run queues order. // Output would be: // scheduled on sync queue // scheduled on actions queue ``` @method schedule @param {String} queue The name of the queue to schedule against. Default queues are 'sync' and 'actions' @param {Object} [target] target object to use as the context when invoking a method. @param {String|Function} method The method to invoke. If you pass a string it will be resolved on the target object at the time the scheduled item is invoked allowing you to change the target function. @param {Object} [arguments*] Optional arguments to be passed to the queued method. @return {void} */ Ember.run.schedule = function(queue, target, method) { checkAutoRun(); backburner.schedule.apply(backburner, arguments); }; // Used by global test teardown Ember.run.hasScheduledTimers = function() { return backburner.hasTimers(); }; // Used by global test teardown Ember.run.cancelTimers = function () { backburner.cancelTimers(); }; /** Immediately flushes any events scheduled in the 'sync' queue. Bindings use this queue so this method is a useful way to immediately force all bindings in the application to sync. You should call this method anytime you need any changed state to propagate throughout the app immediately without repainting the UI (which happens in the later 'render' queue added by the `ember-views` package). ```javascript Ember.run.sync(); ``` @method sync @return {void} */ Ember.run.sync = function() { if (backburner.currentInstance) { backburner.currentInstance.queues.sync.flush(); } }; /** Invokes the passed target/method and optional arguments after a specified period if time. The last parameter of this method must always be a number of milliseconds. You should use this method whenever you need to run some action after a period of time instead of using `setTimeout()`. This method will ensure that items that expire during the same script execution cycle all execute together, which is often more efficient than using a real setTimeout. ```javascript Ember.run.later(myContext, function() { // code here will execute within a RunLoop in about 500ms with this == myContext }, 500); ``` @method later @param {Object} [target] target of method to invoke @param {Function|String} method The method to invoke. If you pass a string it will be resolved on the target at the time the method is invoked. @param {Object} [args*] Optional arguments to pass to the timeout. @param {Number} wait Number of milliseconds to wait. @return {String} a string you can use to cancel the timer in `Ember.run.cancel` later. */ Ember.run.later = function(target, method) { return backburner.later.apply(backburner, arguments); }; /** Schedule a function to run one time during the current RunLoop. This is equivalent to calling `scheduleOnce` with the "actions" queue. @method once @param {Object} [target] The target of the method to invoke. @param {Function|String} method The method to invoke. If you pass a string it will be resolved on the target at the time the method is invoked. @param {Object} [args*] Optional arguments to pass to the timeout. @return {Object} Timer information for use in cancelling, see `Ember.run.cancel`. */ Ember.run.once = function(target, method) { checkAutoRun(); var args = slice.call(arguments); args.unshift('actions'); return backburner.scheduleOnce.apply(backburner, args); }; /** Schedules a function to run one time in a given queue of the current RunLoop. Calling this method with the same queue/target/method combination will have no effect (past the initial call). Note that although you can pass optional arguments these will not be considered when looking for duplicates. New arguments will replace previous calls. ```javascript Ember.run(function() { var sayHi = function() { console.log('hi'); } Ember.run.scheduleOnce('afterRender', myContext, sayHi); Ember.run.scheduleOnce('afterRender', myContext, sayHi); // sayHi will only be executed once, in the afterRender queue of the RunLoop }); ``` Also note that passing an anonymous function to `Ember.run.scheduleOnce` will not prevent additional calls with an identical anonymous function from scheduling the items multiple times, e.g.: ```javascript function scheduleIt() { Ember.run.scheduleOnce('actions', myContext, function() { console.log("Closure"); }); } scheduleIt(); scheduleIt(); // "Closure" will print twice, even though we're using `Ember.run.scheduleOnce`, // because the function we pass to it is anonymous and won't match the // previously scheduled operation. ``` Available queues, and their order, can be found at `Ember.run.queues` @method scheduleOnce @param {String} [queue] The name of the queue to schedule against. Default queues are 'sync' and 'actions'. @param {Object} [target] The target of the method to invoke. @param {Function|String} method The method to invoke. If you pass a string it will be resolved on the target at the time the method is invoked. @param {Object} [args*] Optional arguments to pass to the timeout. @return {Object} Timer information for use in cancelling, see `Ember.run.cancel`. */ Ember.run.scheduleOnce = function(queue, target, method) { checkAutoRun(); return backburner.scheduleOnce.apply(backburner, arguments); }; /** Schedules an item to run from within a separate run loop, after control has been returned to the system. This is equivalent to calling `Ember.run.later` with a wait time of 1ms. ```javascript Ember.run.next(myContext, function() { // code to be executed in the next run loop, // which will be scheduled after the current one }); ``` Multiple operations scheduled with `Ember.run.next` will coalesce into the same later run loop, along with any other operations scheduled by `Ember.run.later` that expire right around the same time that `Ember.run.next` operations will fire. Note that there are often alternatives to using `Ember.run.next`. For instance, if you'd like to schedule an operation to happen after all DOM element operations have completed within the current run loop, you can make use of the `afterRender` run loop queue (added by the `ember-views` package, along with the preceding `render` queue where all the DOM element operations happen). Example: ```javascript App.MyCollectionView = Ember.CollectionView.extend({ didInsertElement: function() { Ember.run.scheduleOnce('afterRender', this, 'processChildElements'); }, processChildElements: function() { // ... do something with collectionView's child view // elements after they've finished rendering, which // can't be done within the CollectionView's // `didInsertElement` hook because that gets run // before the child elements have been added to the DOM. } }); ``` One benefit of the above approach compared to using `Ember.run.next` is that you will be able to perform DOM/CSS operations before unprocessed elements are rendered to the screen, which may prevent flickering or other artifacts caused by delaying processing until after rendering. The other major benefit to the above approach is that `Ember.run.next` introduces an element of non-determinism, which can make things much harder to test, due to its reliance on `setTimeout`; it's much harder to guarantee the order of scheduled operations when they are scheduled outside of the current run loop, i.e. with `Ember.run.next`. @method next @param {Object} [target] target of method to invoke @param {Function|String} method The method to invoke. If you pass a string it will be resolved on the target at the time the method is invoked. @param {Object} [args*] Optional arguments to pass to the timeout. @return {Object} Timer information for use in cancelling, see `Ember.run.cancel`. */ Ember.run.next = function() { var args = slice.call(arguments); args.push(1); return backburner.later.apply(backburner, args); }; /** Cancels a scheduled item. Must be a value returned by `Ember.run.later()`, `Ember.run.once()`, `Ember.run.next()`, `Ember.run.debounce()`, or `Ember.run.throttle()`. ```javascript var runNext = Ember.run.next(myContext, function() { // will not be executed }); Ember.run.cancel(runNext); var runLater = Ember.run.later(myContext, function() { // will not be executed }, 500); Ember.run.cancel(runLater); var runOnce = Ember.run.once(myContext, function() { // will not be executed }); Ember.run.cancel(runOnce); var throttle = Ember.run.throttle(myContext, function() { // will not be executed }, 1); Ember.run.cancel(throttle); var debounce = Ember.run.debounce(myContext, function() { // will not be executed }, 1); Ember.run.cancel(debounce); var debounceImmediate = Ember.run.debounce(myContext, function() { // will be executed since we passed in true (immediate) }, 100, true); // the 100ms delay until this method can be called again will be cancelled Ember.run.cancel(debounceImmediate); ``` ``` ``` @method cancel @param {Object} timer Timer object to cancel @return {Boolean} true if cancelled or false/undefined if it wasn't found */ Ember.run.cancel = function(timer) { return backburner.cancel(timer); }; /** Delay calling the target method until the debounce period has elapsed with no additional debounce calls. If `debounce` is called again before the specified time has elapsed, the timer is reset and the entire period must pass again before the target method is called. This method should be used when an event may be called multiple times but the action should only be called once when the event is done firing. A common example is for scroll events where you only want updates to happen once scrolling has ceased. ```javascript var myFunc = function() { console.log(this.name + ' ran.'); }; var myContext = {name: 'debounce'}; Ember.run.debounce(myContext, myFunc, 150); // less than 150ms passes Ember.run.debounce(myContext, myFunc, 150); // 150ms passes // myFunc is invoked with context myContext // console logs 'debounce ran.' one time. ``` Immediate allows you to run the function immediately, but debounce other calls for this function until the wait time has elapsed. If `debounce` is called again before the specified time has elapsed, the timer is reset and the entire period msut pass again before the method can be called again. ```javascript var myFunc = function() { console.log(this.name + ' ran.'); }; var myContext = {name: 'debounce'}; Ember.run.debounce(myContext, myFunc, 150, true); // console logs 'debounce ran.' one time immediately. // 100ms passes Ember.run.debounce(myContext, myFunc, 150, true); // 150ms passes and nothing else is logged to the console and // the debouncee is no longer being watched Ember.run.debounce(myContext, myFunc, 150, true); // console logs 'debounce ran.' one time immediately. // 150ms passes and nothing else is logged tot he console and // the debouncee is no longer being watched ``` @method debounce @param {Object} [target] target of method to invoke @param {Function|String} method The method to invoke. May be a function or a string. If you pass a string then it will be looked up on the passed target. @param {Object} [args*] Optional arguments to pass to the timeout. @param {Number} wait Number of milliseconds to wait. @param {Boolean} immediate Trigger the function on the leading instead of the trailing edge of the wait interval. @return {Array} Timer information for use in cancelling, see `Ember.run.cancel`. */ Ember.run.debounce = function() { return backburner.debounce.apply(backburner, arguments); }; /** Ensure that the target method is never called more frequently than the specified spacing period. ```javascript var myFunc = function() { console.log(this.name + ' ran.'); }; var myContext = {name: 'throttle'}; Ember.run.throttle(myContext, myFunc, 150); // 50ms passes Ember.run.throttle(myContext, myFunc, 150); // 50ms passes Ember.run.throttle(myContext, myFunc, 150); // 50ms passes Ember.run.throttle(myContext, myFunc, 150); // 150ms passes // myFunc is invoked with context myContext // console logs 'throttle ran.' twice, 150ms apart. ``` @method throttle @param {Object} [target] target of method to invoke @param {Function|String} method The method to invoke. May be a function or a string. If you pass a string then it will be looked up on the passed target. @param {Object} [args*] Optional arguments to pass to the timeout. @param {Number} spacing Number of milliseconds to space out requests. @return {Array} Timer information for use in cancelling, see `Ember.run.cancel`. */ Ember.run.throttle = function() { return backburner.throttle.apply(backburner, arguments); }; // Make sure it's not an autorun during testing function checkAutoRun() { if (!Ember.run.currentRunLoop) { } } })(); (function() { // Ember.Logger // get // set // guidFor, meta // addObserver, removeObserver // Ember.run.schedule /** @module ember-metal */ // .......................................................... // CONSTANTS // /** Debug parameter you can turn on. This will log all bindings that fire to the console. This should be disabled in production code. Note that you can also enable this from the console or temporarily. @property LOG_BINDINGS @for Ember @type Boolean @default false */ Ember.LOG_BINDINGS = false || !!Ember.ENV.LOG_BINDINGS; var get = Ember.get, set = Ember.set, guidFor = Ember.guidFor, IS_GLOBAL = /^([A-Z$]|([0-9][A-Z$]))/; /** Returns true if the provided path is global (e.g., `MyApp.fooController.bar`) instead of local (`foo.bar.baz`). @method isGlobalPath @for Ember @private @param {String} path @return Boolean */ var isGlobalPath = Ember.isGlobalPath = function(path) { return IS_GLOBAL.test(path); }; function getWithGlobals(obj, path) { return get(isGlobalPath(path) ? Ember.lookup : obj, path); } // .......................................................... // BINDING // var Binding = function(toPath, fromPath) { this._direction = 'fwd'; this._from = fromPath; this._to = toPath; this._directionMap = Ember.Map.create(); }; /** @class Binding @namespace Ember */ Binding.prototype = { /** This copies the Binding so it can be connected to another object. @method copy @return {Ember.Binding} `this` */ copy: function () { var copy = new Binding(this._to, this._from); if (this._oneWay) { copy._oneWay = true; } return copy; }, // .......................................................... // CONFIG // /** This will set `from` property path to the specified value. It will not attempt to resolve this property path to an actual object until you connect the binding. The binding will search for the property path starting at the root object you pass when you `connect()` the binding. It follows the same rules as `get()` - see that method for more information. @method from @param {String} path the property path to connect to @return {Ember.Binding} `this` */ from: function(path) { this._from = path; return this; }, /** This will set the `to` property path to the specified value. It will not attempt to resolve this property path to an actual object until you connect the binding. The binding will search for the property path starting at the root object you pass when you `connect()` the binding. It follows the same rules as `get()` - see that method for more information. @method to @param {String|Tuple} path A property path or tuple @return {Ember.Binding} `this` */ to: function(path) { this._to = path; return this; }, /** Configures the binding as one way. A one-way binding will relay changes on the `from` side to the `to` side, but not the other way around. This means that if you change the `to` side directly, the `from` side may have a different value. @method oneWay @return {Ember.Binding} `this` */ oneWay: function() { this._oneWay = true; return this; }, /** @method toString @return {String} string representation of binding */ toString: function() { var oneWay = this._oneWay ? '[oneWay]' : ''; return "Ember.Binding<" + guidFor(this) + ">(" + this._from + " -> " + this._to + ")" + oneWay; }, // .......................................................... // CONNECT AND SYNC // /** Attempts to connect this binding instance so that it can receive and relay changes. This method will raise an exception if you have not set the from/to properties yet. @method connect @param {Object} obj The root object for this binding. @return {Ember.Binding} `this` */ connect: function(obj) { var fromPath = this._from, toPath = this._to; Ember.trySet(obj, toPath, getWithGlobals(obj, fromPath)); // add an observer on the object to be notified when the binding should be updated Ember.addObserver(obj, fromPath, this, this.fromDidChange); // if the binding is a two-way binding, also set up an observer on the target if (!this._oneWay) { Ember.addObserver(obj, toPath, this, this.toDidChange); } this._readyToSync = true; return this; }, /** Disconnects the binding instance. Changes will no longer be relayed. You will not usually need to call this method. @method disconnect @param {Object} obj The root object you passed when connecting the binding. @return {Ember.Binding} `this` */ disconnect: function(obj) { var twoWay = !this._oneWay; // remove an observer on the object so we're no longer notified of // changes that should update bindings. Ember.removeObserver(obj, this._from, this, this.fromDidChange); // if the binding is two-way, remove the observer from the target as well if (twoWay) { Ember.removeObserver(obj, this._to, this, this.toDidChange); } this._readyToSync = false; // disable scheduled syncs... return this; }, // .......................................................... // PRIVATE // /* called when the from side changes */ fromDidChange: function(target) { this._scheduleSync(target, 'fwd'); }, /* called when the to side changes */ toDidChange: function(target) { this._scheduleSync(target, 'back'); }, _scheduleSync: function(obj, dir) { var directionMap = this._directionMap; var existingDir = directionMap.get(obj); // if we haven't scheduled the binding yet, schedule it if (!existingDir) { Ember.run.schedule('sync', this, this._sync, obj); directionMap.set(obj, dir); } // If both a 'back' and 'fwd' sync have been scheduled on the same object, // default to a 'fwd' sync so that it remains deterministic. if (existingDir === 'back' && dir === 'fwd') { directionMap.set(obj, 'fwd'); } }, _sync: function(obj) { var log = Ember.LOG_BINDINGS; // don't synchronize destroyed objects or disconnected bindings if (obj.isDestroyed || !this._readyToSync) { return; } // get the direction of the binding for the object we are // synchronizing from var directionMap = this._directionMap; var direction = directionMap.get(obj); var fromPath = this._from, toPath = this._to; directionMap.remove(obj); // if we're synchronizing from the remote object... if (direction === 'fwd') { var fromValue = getWithGlobals(obj, this._from); if (log) { Ember.Logger.log(' ', this.toString(), '->', fromValue, obj); } if (this._oneWay) { Ember.trySet(obj, toPath, fromValue); } else { Ember._suspendObserver(obj, toPath, this, this.toDidChange, function () { Ember.trySet(obj, toPath, fromValue); }); } // if we're synchronizing *to* the remote object } else if (direction === 'back') { var toValue = get(obj, this._to); if (log) { Ember.Logger.log(' ', this.toString(), '<-', toValue, obj); } Ember._suspendObserver(obj, fromPath, this, this.fromDidChange, function () { Ember.trySet(Ember.isGlobalPath(fromPath) ? Ember.lookup : obj, fromPath, toValue); }); } } }; function mixinProperties(to, from) { for (var key in from) { if (from.hasOwnProperty(key)) { to[key] = from[key]; } } } mixinProperties(Binding, { /* See `Ember.Binding.from`. @method from @static */ from: function() { var C = this, binding = new C(); return binding.from.apply(binding, arguments); }, /* See `Ember.Binding.to`. @method to @static */ to: function() { var C = this, binding = new C(); return binding.to.apply(binding, arguments); }, /** Creates a new Binding instance and makes it apply in a single direction. A one-way binding will relay changes on the `from` side object (supplied as the `from` argument) the `to` side, but not the other way around. This means that if you change the "to" side directly, the "from" side may have a different value. See `Binding.oneWay`. @method oneWay @param {String} from from path. @param {Boolean} [flag] (Optional) passing nothing here will make the binding `oneWay`. You can instead pass `false` to disable `oneWay`, making the binding two way again. @return {Ember.Binding} `this` */ oneWay: function(from, flag) { var C = this, binding = new C(null, from); return binding.oneWay(flag); } }); /** An `Ember.Binding` connects the properties of two objects so that whenever the value of one property changes, the other property will be changed also. ## Automatic Creation of Bindings with `/^*Binding/`-named Properties You do not usually create Binding objects directly but instead describe bindings in your class or object definition using automatic binding detection. Properties ending in a `Binding` suffix will be converted to `Ember.Binding` instances. The value of this property should be a string representing a path to another object or a custom binding instanced created using Binding helpers (see "One Way Bindings"): ``` valueBinding: "MyApp.someController.title" ``` This will create a binding from `MyApp.someController.title` to the `value` property of your object instance automatically. Now the two values will be kept in sync. ## One Way Bindings One especially useful binding customization you can use is the `oneWay()` helper. This helper tells Ember that you are only interested in receiving changes on the object you are binding from. For example, if you are binding to a preference and you want to be notified if the preference has changed, but your object will not be changing the preference itself, you could do: ``` bigTitlesBinding: Ember.Binding.oneWay("MyApp.preferencesController.bigTitles") ``` This way if the value of `MyApp.preferencesController.bigTitles` changes the `bigTitles` property of your object will change also. However, if you change the value of your `bigTitles` property, it will not update the `preferencesController`. One way bindings are almost twice as fast to setup and twice as fast to execute because the binding only has to worry about changes to one side. You should consider using one way bindings anytime you have an object that may be created frequently and you do not intend to change a property; only to monitor it for changes (such as in the example above). ## Adding Bindings Manually All of the examples above show you how to configure a custom binding, but the result of these customizations will be a binding template, not a fully active Binding instance. The binding will actually become active only when you instantiate the object the binding belongs to. It is useful however, to understand what actually happens when the binding is activated. For a binding to function it must have at least a `from` property and a `to` property. The `from` property path points to the object/key that you want to bind from while the `to` path points to the object/key you want to bind to. When you define a custom binding, you are usually describing the property you want to bind from (such as `MyApp.someController.value` in the examples above). When your object is created, it will automatically assign the value you want to bind `to` based on the name of your binding key. In the examples above, during init, Ember objects will effectively call something like this on your binding: ```javascript binding = Ember.Binding.from(this.valueBinding).to("value"); ``` This creates a new binding instance based on the template you provide, and sets the to path to the `value` property of the new object. Now that the binding is fully configured with a `from` and a `to`, it simply needs to be connected to become active. This is done through the `connect()` method: ```javascript binding.connect(this); ``` Note that when you connect a binding you pass the object you want it to be connected to. This object will be used as the root for both the from and to side of the binding when inspecting relative paths. This allows the binding to be automatically inherited by subclassed objects as well. Now that the binding is connected, it will observe both the from and to side and relay changes. If you ever needed to do so (you almost never will, but it is useful to understand this anyway), you could manually create an active binding by using the `Ember.bind()` helper method. (This is the same method used by to setup your bindings on objects): ```javascript Ember.bind(MyApp.anotherObject, "value", "MyApp.someController.value"); ``` Both of these code fragments have the same effect as doing the most friendly form of binding creation like so: ```javascript MyApp.anotherObject = Ember.Object.create({ valueBinding: "MyApp.someController.value", // OTHER CODE FOR THIS OBJECT... }); ``` Ember's built in binding creation method makes it easy to automatically create bindings for you. You should always use the highest-level APIs available, even if you understand how it works underneath. @class Binding @namespace Ember @since Ember 0.9 */ Ember.Binding = Binding; /** Global helper method to create a new binding. Just pass the root object along with a `to` and `from` path to create and connect the binding. @method bind @for Ember @param {Object} obj The root object of the transform. @param {String} to The path to the 'to' side of the binding. Must be relative to obj. @param {String} from The path to the 'from' side of the binding. Must be relative to obj or a global path. @return {Ember.Binding} binding instance */ Ember.bind = function(obj, to, from) { return new Ember.Binding(to, from).connect(obj); }; /** @method oneWay @for Ember @param {Object} obj The root object of the transform. @param {String} to The path to the 'to' side of the binding. Must be relative to obj. @param {String} from The path to the 'from' side of the binding. Must be relative to obj or a global path. @return {Ember.Binding} binding instance */ Ember.oneWay = function(obj, to, from) { return new Ember.Binding(to, from).oneWay().connect(obj); }; })(); (function() { /** @module ember @submodule ember-metal */ var Mixin, REQUIRED, Alias, a_map = Ember.ArrayPolyfills.map, a_indexOf = Ember.ArrayPolyfills.indexOf, a_forEach = Ember.ArrayPolyfills.forEach, a_slice = [].slice, o_create = Ember.create, defineProperty = Ember.defineProperty, guidFor = Ember.guidFor, metaFor = Ember.meta, META_KEY = Ember.META_KEY; var expandProperties = Ember.expandProperties; function mixinsMeta(obj) { var m = metaFor(obj, true), ret = m.mixins; if (!ret) { ret = m.mixins = {}; } else if (!m.hasOwnProperty('mixins')) { ret = m.mixins = o_create(ret); } return ret; } function initMixin(mixin, args) { if (args && args.length > 0) { mixin.mixins = a_map.call(args, function(x) { if (x instanceof Mixin) { return x; } // Note: Manually setup a primitive mixin here. This is the only // way to actually get a primitive mixin. This way normal creation // of mixins will give you combined mixins... var mixin = new Mixin(); mixin.properties = x; return mixin; }); } return mixin; } function isMethod(obj) { return 'function' === typeof obj && obj.isMethod !== false && obj !== Boolean && obj !== Object && obj !== Number && obj !== Array && obj !== Date && obj !== String; } var CONTINUE = {}; function mixinProperties(mixinsMeta, mixin) { var guid; if (mixin instanceof Mixin) { guid = guidFor(mixin); if (mixinsMeta[guid]) { return CONTINUE; } mixinsMeta[guid] = mixin; return mixin.properties; } else { return mixin; // apply anonymous mixin properties } } function concatenatedMixinProperties(concatProp, props, values, base) { var concats; // reset before adding each new mixin to pickup concats from previous concats = values[concatProp] || base[concatProp]; if (props[concatProp]) { concats = concats ? concats.concat(props[concatProp]) : props[concatProp]; } return concats; } function giveDescriptorSuper(meta, key, property, values, descs) { var superProperty; // Computed properties override methods, and do not call super to them if (values[key] === undefined) { // Find the original descriptor in a parent mixin superProperty = descs[key]; } // If we didn't find the original descriptor in a parent mixin, find // it on the original object. superProperty = superProperty || meta.descs[key]; if (!superProperty || !(superProperty instanceof Ember.ComputedProperty)) { return property; } // Since multiple mixins may inherit from the same parent, we need // to clone the computed property so that other mixins do not receive // the wrapped version. property = o_create(property); property.func = Ember.wrap(property.func, superProperty.func); return property; } function giveMethodSuper(obj, key, method, values, descs) { var superMethod; // Methods overwrite computed properties, and do not call super to them. if (descs[key] === undefined) { // Find the original method in a parent mixin superMethod = values[key]; } // If we didn't find the original value in a parent mixin, find it in // the original object superMethod = superMethod || obj[key]; // Only wrap the new method if the original method was a function if ('function' !== typeof superMethod) { return method; } return Ember.wrap(method, superMethod); } function applyConcatenatedProperties(obj, key, value, values) { var baseValue = values[key] || obj[key]; if (baseValue) { if ('function' === typeof baseValue.concat) { return baseValue.concat(value); } else { return Ember.makeArray(baseValue).concat(value); } } else { return Ember.makeArray(value); } } function applyMergedProperties(obj, key, value, values) { var baseValue = values[key] || obj[key]; if (!baseValue) { return value; } var newBase = Ember.merge({}, baseValue); for (var prop in value) { if (!value.hasOwnProperty(prop)) { continue; } var propValue = value[prop]; if (isMethod(propValue)) { // TODO: support for Computed Properties, etc? newBase[prop] = giveMethodSuper(obj, prop, propValue, baseValue, {}); } else { newBase[prop] = propValue; } } return newBase; } function addNormalizedProperty(base, key, value, meta, descs, values, concats, mergings) { if (value instanceof Ember.Descriptor) { if (value === REQUIRED && descs[key]) { return CONTINUE; } // Wrap descriptor function to implement // _super() if needed if (value.func) { value = giveDescriptorSuper(meta, key, value, values, descs); } descs[key] = value; values[key] = undefined; } else { if ((concats && a_indexOf.call(concats, key) >= 0) || key === 'concatenatedProperties' || key === 'mergedProperties') { value = applyConcatenatedProperties(base, key, value, values); } else if ((mergings && a_indexOf.call(mergings, key) >= 0)) { value = applyMergedProperties(base, key, value, values); } else if (isMethod(value)) { value = giveMethodSuper(base, key, value, values, descs); } descs[key] = undefined; values[key] = value; } } function mergeMixins(mixins, m, descs, values, base, keys) { var mixin, props, key, concats, mergings, meta; function removeKeys(keyName) { delete descs[keyName]; delete values[keyName]; } for(var i=0, l=mixins.length; i= 0) { if (_detect(mixins[loc], targetMixin, seen)) { return true; } } return false; } /** @method detect @param obj @return {Boolean} */ MixinPrototype.detect = function(obj) { if (!obj) { return false; } if (obj instanceof Mixin) { return _detect(obj, this, {}); } var m = obj[META_KEY], mixins = m && m.mixins; if (mixins) { return !!mixins[guidFor(this)]; } return false; }; MixinPrototype.without = function() { var ret = new Mixin(this); ret._without = a_slice.call(arguments); return ret; }; function _keys(ret, mixin, seen) { if (seen[guidFor(mixin)]) { return; } seen[guidFor(mixin)] = true; if (mixin.properties) { var props = mixin.properties; for (var key in props) { if (props.hasOwnProperty(key)) { ret[key] = true; } } } else if (mixin.mixins) { a_forEach.call(mixin.mixins, function(x) { _keys(ret, x, seen); }); } } MixinPrototype.keys = function() { var keys = {}, seen = {}, ret = []; _keys(keys, this, seen); for(var key in keys) { if (keys.hasOwnProperty(key)) { ret.push(key); } } return ret; }; // returns the mixins currently applied to the specified object // TODO: Make Ember.mixin Mixin.mixins = function(obj) { var m = obj[META_KEY], mixins = m && m.mixins, ret = []; if (!mixins) { return ret; } for (var key in mixins) { var mixin = mixins[key]; // skip primitive mixins since these are always anonymous if (!mixin.properties) { ret.push(mixin); } } return ret; }; REQUIRED = new Ember.Descriptor(); REQUIRED.toString = function() { return '(Required Property)'; }; /** Denotes a required property for a mixin @method required @for Ember */ Ember.required = function() { return REQUIRED; }; Alias = function(methodName) { this.methodName = methodName; }; Alias.prototype = new Ember.Descriptor(); /** Makes a method available via an additional name. ```javascript App.Person = Ember.Object.extend({ name: function() { return 'Tomhuda Katzdale'; }, moniker: Ember.aliasMethod('name') }); var goodGuy = App.Person.create() ``` @method aliasMethod @for Ember @param {String} methodName name of the method to alias @return {Ember.Descriptor} */ Ember.aliasMethod = function(methodName) { return new Alias(methodName); }; // .......................................................... // OBSERVER HELPER // /** Specify a method that observes property changes. ```javascript Ember.Object.extend({ valueObserver: Ember.observer('value', function() { // Executes whenever the "value" property changes }) }); ``` In the future this method may become asynchronous. If you want to ensure synchronous behavior, use `immediateObserver`. Also available as `Function.prototype.observes` if prototype extensions are enabled. @method observer @for Ember @param {String} propertyNames* @param {Function} func @return func */ Ember.observer = function() { var func = a_slice.call(arguments, -1)[0]; var paths; var addWatchedProperty = function (path) { paths.push(path); }; var _paths = a_slice.call(arguments, 0, -1); if (typeof func !== "function") { // revert to old, soft-deprecated argument ordering func = arguments[0]; _paths = a_slice.call(arguments, 1); } paths = []; for (var i=0; i<_paths.length; ++i) { expandProperties(_paths[i], addWatchedProperty); } if (typeof func !== "function") { throw new Ember.Error("Ember.observer called without a function"); } func.__ember_observes__ = paths; return func; }; /** Specify a method that observes property changes. ```javascript Ember.Object.extend({ valueObserver: Ember.immediateObserver('value', function() { // Executes whenever the "value" property changes }) }); ``` In the future, `Ember.observer` may become asynchronous. In this event, `Ember.immediateObserver` will maintain the synchronous behavior. Also available as `Function.prototype.observesImmediately` if prototype extensions are enabled. @method immediateObserver @for Ember @param {String} propertyNames* @param {Function} func @return func */ Ember.immediateObserver = function() { for (var i=0, l=arguments.length; i this.changingFrom ? 'green' : 'red'; // logic } }), friendsDidChange: Ember.observer('friends.@each.name', function(obj, keyName) { // some logic // obj.get(keyName) returns friends array }) }); ``` Also available as `Function.prototype.observesBefore` if prototype extensions are enabled. @method beforeObserver @for Ember @param {String} propertyNames* @param {Function} func @return func */ Ember.beforeObserver = function() { var func = a_slice.call(arguments, -1)[0]; var paths; var addWatchedProperty = function(path) { paths.push(path); }; var _paths = a_slice.call(arguments, 0, -1); if (typeof func !== "function") { // revert to old, soft-deprecated argument ordering func = arguments[0]; _paths = a_slice.call(arguments, 1); } paths = []; for (var i=0; i<_paths.length; ++i) { expandProperties(_paths[i], addWatchedProperty); } if (typeof func !== "function") { throw new Ember.Error("Ember.beforeObserver called without a function"); } func.__ember_observesBefore__ = paths; return func; }; })(); (function() { // Provides a way to register library versions with ember. var forEach = Ember.EnumerableUtils.forEach, indexOf = Ember.EnumerableUtils.indexOf; Ember.libraries = function() { var libraries = []; var coreLibIndex = 0; var getLibrary = function(name) { for (var i = 0; i < libraries.length; i++) { if (libraries[i].name === name) { return libraries[i]; } } }; libraries.register = function(name, version) { if (!getLibrary(name)) { libraries.push({name: name, version: version}); } }; libraries.registerCoreLibrary = function(name, version) { if (!getLibrary(name)) { libraries.splice(coreLibIndex++, 0, {name: name, version: version}); } }; libraries.deRegister = function(name) { var lib = getLibrary(name); if (lib) libraries.splice(indexOf(libraries, lib), 1); }; libraries.each = function (callback) { forEach(libraries, function(lib) { callback(lib.name, lib.version); }); }; return libraries; }(); Ember.libraries.registerCoreLibrary('Ember', Ember.VERSION); })(); (function() { /** Ember Metal @module ember @submodule ember-metal */ })(); (function() { /** @class RSVP @module RSVP */ define("rsvp/all", ["./promise","exports"], function(__dependency1__, __exports__) { "use strict"; var Promise = __dependency1__["default"]; /** This is a convenient alias for `RSVP.Promise.all`. @method all @for RSVP @param {Array} array Array of promises. @param {String} label An optional label. This is useful for tooling. @static */ __exports__["default"] = function all(array, label) { return Promise.all(array, label); }; }); define("rsvp/all_settled", ["./promise","./utils","exports"], function(__dependency1__, __dependency2__, __exports__) { "use strict"; var Promise = __dependency1__["default"]; var isArray = __dependency2__.isArray; var isNonThenable = __dependency2__.isNonThenable; /** `RSVP.allSettled` is similar to `RSVP.all`, but instead of implementing a fail-fast method, it waits until all the promises have returned and shows you all the results. This is useful if you want to handle multiple promises' failure states together as a set. Returns a promise that is fulfilled when all the given promises have been settled. The return promise is fulfilled with an array of the states of the promises passed into the `promises` array argument. Each state object will either indicate fulfillment or rejection, and provide the corresponding value or reason. The states will take one of the following formats: ```javascript { state: 'fulfilled', value: value } or { state: 'rejected', reason: reason } ``` Example: ```javascript var promise1 = RSVP.Promise.resolve(1); var promise2 = RSVP.Promise.reject(new Error('2')); var promise3 = RSVP.Promise.reject(new Error('3')); var promises = [ promise1, promise2, promise3 ]; RSVP.allSettled(promises).then(function(array){ // array == [ // { state: 'fulfilled', value: 1 }, // { state: 'rejected', reason: Error }, // { state: 'rejected', reason: Error } // ] // Note that for the second item, reason.message will be "2", and for the // third item, reason.message will be "3". }, function(error) { // Not run. (This block would only be called if allSettled had failed, // for instance if passed an incorrect argument type.) }); ``` @method allSettled @for RSVP @param {Array} promises @param {String} label - optional string that describes the promise. Useful for tooling. @return {Promise} promise that is fulfilled with an array of the settled states of the constituent promises. @static */ __exports__["default"] = function allSettled(entries, label) { return new Promise(function(resolve, reject) { if (!isArray(entries)) { throw new TypeError('You must pass an array to allSettled.'); } var remaining = entries.length; var entry; if (remaining === 0) { resolve([]); return; } var results = new Array(remaining); function fulfilledResolver(index) { return function(value) { resolveAll(index, fulfilled(value)); }; } function rejectedResolver(index) { return function(reason) { resolveAll(index, rejected(reason)); }; } function resolveAll(index, value) { results[index] = value; if (--remaining === 0) { resolve(results); } } for (var index = 0; index < entries.length; index++) { entry = entries[index]; if (isNonThenable(entry)) { resolveAll(index, fulfilled(entry)); } else { Promise.cast(entry).then(fulfilledResolver(index), rejectedResolver(index)); } } }, label); }; function fulfilled(value) { return { state: 'fulfilled', value: value }; } function rejected(reason) { return { state: 'rejected', reason: reason }; } }); define("rsvp/config", ["./events","exports"], function(__dependency1__, __exports__) { "use strict"; var EventTarget = __dependency1__["default"]; var config = { instrument: false }; EventTarget.mixin(config); function configure(name, value) { if (name === 'onerror') { // handle for legacy users that expect the actual // error to be passed to their function added via // `RSVP.configure('onerror', someFunctionHere);` config.on('error', value); return; } if (arguments.length === 2) { config[name] = value; } else { return config[name]; } } __exports__.config = config; __exports__.configure = configure; }); define("rsvp/defer", ["./promise","exports"], function(__dependency1__, __exports__) { "use strict"; var Promise = __dependency1__["default"]; /** `RSVP.defer` returns an object similar to jQuery's `$.Deferred`. `RSVP.defer` should be used when porting over code reliant on `$.Deferred`'s interface. New code should use the `RSVP.Promise` constructor instead. The object returned from `RSVP.defer` is a plain object with three properties: * promise - an `RSVP.Promise`. * reject - a function that causes the `promise` property on this object to become rejected * resolve - a function that causes the `promise` property on this object to become fulfilled. Example: ```javascript var deferred = RSVP.defer(); deferred.resolve("Success!"); defered.promise.then(function(value){ // value here is "Success!" }); ``` @method defer @for RSVP @param {String} label optional string for labeling the promise. Useful for tooling. @return {Object} */ __exports__["default"] = function defer(label) { var deferred = { }; deferred.promise = new Promise(function(resolve, reject) { deferred.resolve = resolve; deferred.reject = reject; }, label); return deferred; }; }); define("rsvp/events", ["exports"], function(__exports__) { "use strict"; var indexOf = function(callbacks, callback) { for (var i=0, l=callbacks.length; i 1; }; RSVP.filter(promises, filterFn).then(function(result){ // result is [ 2, 3 ] }); ``` If any of the `promises` given to `RSVP.filter` are rejected, the first promise that is rejected will be given as an argument to the returned promise's rejection handler. For example: ```javascript var promise1 = RSVP.resolve(1); var promise2 = RSVP.reject(new Error("2")); var promise3 = RSVP.reject(new Error("3")); var promises = [ promise1, promise2, promise3 ]; var filterFn = function(item){ return item > 1; }; RSVP.filter(promises, filterFn).then(function(array){ // Code here never runs because there are rejected promises! }, function(reason) { // reason.message === "2" }); ``` `RSVP.filter` will also wait for any promises returned from `filterFn`. For instance, you may want to fetch a list of users then return a subset of those users based on some asynchronous operation: ```javascript var alice = { name: 'alice' }; var bob = { name: 'bob' }; var users = [ alice, bob ]; var promises = users.map(function(user){ return RSVP.resolve(user); }); var filterFn = function(user){ // Here, Alice has permissions to create a blog post, but Bob does not. return getPrivilegesForUser(user).then(function(privs){ return privs.can_create_blog_post === true; }); }; RSVP.filter(promises, filterFn).then(function(users){ // true, because the server told us only Alice can create a blog post. users.length === 1; // false, because Alice is the only user present in `users` users[0] === bob; }); ``` @method filter @for RSVP @param {Array} promises @param {Function} filterFn - function to be called on each resolved value to filter the final results. @param {String} label optional string describing the promise. Useful for tooling. @return {Promise} */ function filter(promises, filterFn, label) { return all(promises, label).then(function(values){ if (!isArray(promises)) { throw new TypeError('You must pass an array to filter.'); } if (!isFunction(filterFn)){ throw new TypeError("You must pass a function to filter's second argument."); } return map(promises, filterFn, label).then(function(filterResults){ var i, valuesLen = values.length, filtered = []; for (i = 0; i < valuesLen; i++){ if(filterResults[i]) filtered.push(values[i]); } return filtered; }); }); } __exports__["default"] = filter; }); define("rsvp/hash", ["./promise","./utils","exports"], function(__dependency1__, __dependency2__, __exports__) { "use strict"; var Promise = __dependency1__["default"]; var isNonThenable = __dependency2__.isNonThenable; var keysOf = __dependency2__.keysOf; /** `RSVP.hash` is similar to `RSVP.all`, but takes an object instead of an array for its `promises` argument. Returns a promise that is fulfilled when all the given promises have been fulfilled, or rejected if any of them become rejected. The returned promise is fulfilled with a hash that has the same key names as the `promises` object argument. If any of the values in the object are not promises, they will simply be copied over to the fulfilled object. Example: ```javascript var promises = { myPromise: RSVP.resolve(1), yourPromise: RSVP.resolve(2), theirPromise: RSVP.resolve(3), notAPromise: 4 }; RSVP.hash(promises).then(function(hash){ // hash here is an object that looks like: // { // myPromise: 1, // yourPromise: 2, // theirPromise: 3, // notAPromise: 4 // } }); ```` If any of the `promises` given to `RSVP.hash` are rejected, the first promise that is rejected will be given as the reason to the rejection handler. Example: ```javascript var promises = { myPromise: RSVP.resolve(1), rejectedPromise: RSVP.reject(new Error("rejectedPromise")), anotherRejectedPromise: RSVP.reject(new Error("anotherRejectedPromise")), }; RSVP.hash(promises).then(function(hash){ // Code here never runs because there are rejected promises! }, function(reason) { // reason.message === "rejectedPromise" }); ``` An important note: `RSVP.hash` is intended for plain JavaScript objects that are just a set of keys and values. `RSVP.hash` will NOT preserve prototype chains. Example: ```javascript function MyConstructor(){ this.example = RSVP.resolve("Example"); } MyConstructor.prototype = { protoProperty: RSVP.resolve("Proto Property") }; var myObject = new MyConstructor(); RSVP.hash(myObject).then(function(hash){ // protoProperty will not be present, instead you will just have an // object that looks like: // { // example: "Example" // } // // hash.hasOwnProperty('protoProperty'); // false // 'undefined' === typeof hash.protoProperty }); ``` @method hash @for RSVP @param {Object} promises @param {String} label optional string that describes the promise. Useful for tooling. @return {Promise} promise that is fulfilled when all properties of `promises` have been fulfilled, or rejected if any of them become rejected. @static */ __exports__["default"] = function hash(object, label) { return new Promise(function(resolve, reject){ var results = {}; var keys = keysOf(object); var remaining = keys.length; var entry, property; if (remaining === 0) { resolve(results); return; } function fulfilledTo(property) { return function(value) { results[property] = value; if (--remaining === 0) { resolve(results); } }; } function onRejection(reason) { remaining = 0; reject(reason); } for (var i = 0; i < keys.length; i++) { property = keys[i]; entry = object[property]; if (isNonThenable(entry)) { results[property] = entry; if (--remaining === 0) { resolve(results); } } else { Promise.cast(entry).then(fulfilledTo(property), onRejection); } } }); }; }); define("rsvp/instrument", ["./config","./utils","exports"], function(__dependency1__, __dependency2__, __exports__) { "use strict"; var config = __dependency1__.config; var now = __dependency2__.now; __exports__["default"] = function instrument(eventName, promise, child) { // instrumentation should not disrupt normal usage. try { config.trigger(eventName, { guid: promise._guidKey + promise._id, eventName: eventName, detail: promise._detail, childGuid: child && promise._guidKey + child._id, label: promise._label, timeStamp: now(), stack: new Error(promise._label).stack }); } catch(error) { setTimeout(function(){ throw error; }, 0); } }; }); define("rsvp/map", ["./promise","./all","./utils","exports"], function(__dependency1__, __dependency2__, __dependency3__, __exports__) { "use strict"; var Promise = __dependency1__["default"]; var all = __dependency2__["default"]; var isArray = __dependency3__.isArray; var isFunction = __dependency3__.isFunction; /** `RSVP.map` is similar to JavaScript's native `map` method, except that it waits for all promises to become fulfilled before running the `mapFn` on each item in given to `promises`. `RSVP.map` returns a promise that will become fulfilled with the result of running `mapFn` on the values the promises become fulfilled with. For example: ```javascript var promise1 = RSVP.resolve(1); var promise2 = RSVP.resolve(2); var promise3 = RSVP.resolve(3); var promises = [ promise1, promise2, promise3 ]; var mapFn = function(item){ return item + 1; }; RSVP.map(promises, mapFn).then(function(result){ // result is [ 2, 3, 4 ] }); ``` If any of the `promises` given to `RSVP.map` are rejected, the first promise that is rejected will be given as an argument to the returned promise's rejection handler. For example: ```javascript var promise1 = RSVP.resolve(1); var promise2 = RSVP.reject(new Error("2")); var promise3 = RSVP.reject(new Error("3")); var promises = [ promise1, promise2, promise3 ]; var mapFn = function(item){ return item + 1; }; RSVP.map(promises, mapFn).then(function(array){ // Code here never runs because there are rejected promises! }, function(reason) { // reason.message === "2" }); ``` `RSVP.map` will also wait if a promise is returned from `mapFn`. For example, say you want to get all comments from a set of blog posts, but you need the blog posts first becuase they contain a url to those comments. ```javscript var mapFn = function(blogPost){ // getComments does some ajax and returns an RSVP.Promise that is fulfilled // with some comments data return getComments(blogPost.comments_url); }; // getBlogPosts does some ajax and returns an RSVP.Promise that is fulfilled // with some blog post data RSVP.map(getBlogPosts(), mapFn).then(function(comments){ // comments is the result of asking the server for the comments // of all blog posts returned from getBlogPosts() }); ``` @method map @for RSVP @param {Array} promises @param {Function} mapFn function to be called on each fulfilled promise. @param {String} label optional string for labeling the promise. Useful for tooling. @return {Promise} promise that is fulfilled with the result of calling `mapFn` on each fulfilled promise or value when they become fulfilled. The promise will be rejected if any of the given `promises` become rejected. @static */ __exports__["default"] = function map(promises, mapFn, label) { return all(promises, label).then(function(results){ if (!isArray(promises)) { throw new TypeError('You must pass an array to map.'); } if (!isFunction(mapFn)){ throw new TypeError("You must pass a function to map's second argument."); } var resultLen = results.length, mappedResults = [], i; for (i = 0; i < resultLen; i++){ mappedResults.push(mapFn(results[i])); } return all(mappedResults, label); }); }; }); define("rsvp/node", ["./promise","exports"], function(__dependency1__, __exports__) { "use strict"; var Promise = __dependency1__["default"]; var slice = Array.prototype.slice; function makeNodeCallbackFor(resolve, reject) { return function (error, value) { if (error) { reject(error); } else if (arguments.length > 2) { resolve(slice.call(arguments, 1)); } else { resolve(value); } }; } /** `RSVP.denodeify` takes a "node-style" function and returns a function that will return an `RSVP.Promise`. You can use `denodeify` in Node.js or the browser when you'd prefer to use promises over using callbacks. For example, `denodeify` transforms the following: ```javascript var fs = require('fs'); fs.readFile('myfile.txt', function(err, data){ if (err) return handleError(err); handleData(data); }); ``` into: ```javascript var fs = require('fs'); var readFile = RSVP.denodeify(fs.readFile); readFile('myfile.txt').then(handleData, handleError); ``` Using `denodeify` makes it easier to compose asynchronous operations instead of using callbacks. For example, instead of: ```javascript var fs = require('fs'); var log = require('some-async-logger'); fs.readFile('myfile.txt', function(err, data){ if (err) return handleError(err); fs.writeFile('myfile2.txt', data, function(err){ if (err) throw err; log('success', function(err) { if (err) throw err; }); }); }); ``` You can chain the operations together using `then` from the returned promise: ```javascript var fs = require('fs'); var denodeify = RSVP.denodeify; var readFile = denodeify(fs.readFile); var writeFile = denodeify(fs.writeFile); var log = denodeify(require('some-async-logger')); readFile('myfile.txt').then(function(data){ return writeFile('myfile2.txt', data); }).then(function(){ return log('SUCCESS'); }).then(function(){ // success handler }, function(reason){ // rejection handler }); ``` @method denodeify @for RSVP @param {Function} nodeFunc a "node-style" function that takes a callback as its last argument. The callback expects an error to be passed as its first argument (if an error occurred, otherwise null), and the value from the operation as its second argument ("function(err, value){ }"). @param {Any} binding optional argument for binding the "this" value when calling the `nodeFunc` function. @return {Function} a function that wraps `nodeFunc` to return an `RSVP.Promise` @static */ __exports__["default"] = function denodeify(nodeFunc, binding) { return function() { var nodeArgs = slice.call(arguments), resolve, reject; var thisArg = this || binding; return new Promise(function(resolve, reject) { Promise.all(nodeArgs).then(function(nodeArgs) { try { nodeArgs.push(makeNodeCallbackFor(resolve, reject)); nodeFunc.apply(thisArg, nodeArgs); } catch(e) { reject(e); } }); }); }; }; }); define("rsvp/promise", ["./config","./events","./instrument","./utils","./promise/cast","./promise/all","./promise/race","./promise/resolve","./promise/reject","exports"], function(__dependency1__, __dependency2__, __dependency3__, __dependency4__, __dependency5__, __dependency6__, __dependency7__, __dependency8__, __dependency9__, __exports__) { "use strict"; var config = __dependency1__.config; var EventTarget = __dependency2__["default"]; var instrument = __dependency3__["default"]; var objectOrFunction = __dependency4__.objectOrFunction; var isFunction = __dependency4__.isFunction; var now = __dependency4__.now; var cast = __dependency5__["default"]; var all = __dependency6__["default"]; var race = __dependency7__["default"]; var Resolve = __dependency8__["default"]; var Reject = __dependency9__["default"]; var guidKey = 'rsvp_' + now() + '-'; var counter = 0; function noop() {} __exports__["default"] = Promise; /** Promise objects represent the eventual result of an asynchronous operation. The primary way of interacting with a promise is through its `then` method, which registers callbacks to receive either a promise’s eventual value or the reason why the promise cannot be fulfilled. Terminology ----------- - `promise` is an object or function with a `then` method whose behavior conforms to this specification. - `thenable` is an object or function that defines a `then` method. - `value` is any legal JavaScript value (including undefined, a thenable, or a promise). - `exception` is a value that is thrown using the throw statement. - `reason` is a value that indicates why a promise was rejected. - `settled` the final resting state of a promise, fulfilled or rejected. A promise can be in one of three states: pending, fulfilled, or rejected. Promises that are fulfilled have a fulfillment value and are in the fulfilled state. Promises that are rejected have a rejection reason and are in the rejected state. A fulfillment value is never a thenable. Similarly, a rejection reason is never a thenable. Promises can also be said to *resolve* a value. If this value is also a promise, then the original promise's settled state will match the value's settled state. So a promise that *resolves* a promise that rejects will itself reject, and a promise that *resolves* a promise that fulfills will itself fulfill. Basic Usage: ------------ ```js var promise = new Promise(function(resolve, reject) { // on success resolve(value); // on failure reject(reason); }); promise.then(function(value) { // on fulfillment }, function(reason) { // on rejection }); ``` Advanced Usage: --------------- Promises shine when abstracting away asynchronous interactions such as `XMLHttpRequest`s. ```js function getJSON(url) { return new Promise(function(resolve, reject){ var xhr = new XMLHttpRequest(); xhr.open('GET', url); xhr.onreadystatechange = handler; xhr.responseType = 'json'; xhr.setRequestHeader('Accept', 'application/json'); xhr.send(); function handler() { if (this.readyState === this.DONE) { if (this.status === 200) { resolve(this.response); } else { reject(new Error("getJSON: `" + url + "` failed with status: [" + this.status + "]"); } } }; }); } getJSON('/posts.json').then(function(json) { // on fulfillment }, function(reason) { // on rejection }); ``` Unlike callbacks, promises are great composable primitives. ```js Promise.all([ getJSON('/posts'), getJSON('/comments') ]).then(function(values){ values[0] // => postsJSON values[1] // => commentsJSON return values; }); ``` @class RSVP.Promise @param {function} @param {String} label optional string for labeling the promise. Useful for tooling. @constructor */ function Promise(resolver, label) { if (!isFunction(resolver)) { throw new TypeError('You must pass a resolver function as the first argument to the promise constructor'); } if (!(this instanceof Promise)) { throw new TypeError("Failed to construct 'Promise': Please use the 'new' operator, this object constructor cannot be called as a function."); } this._id = counter++; this._label = label; this._subscribers = []; if (config.instrument) { instrument('created', this); } if (noop !== resolver) { invokeResolver(resolver, this); } } function invokeResolver(resolver, promise) { function resolvePromise(value) { resolve(promise, value); } function rejectPromise(reason) { reject(promise, reason); } try { resolver(resolvePromise, rejectPromise); } catch(e) { rejectPromise(e); } } Promise.cast = cast; Promise.all = all; Promise.race = race; Promise.resolve = Resolve; Promise.reject = Reject; var PENDING = void 0; var SEALED = 0; var FULFILLED = 1; var REJECTED = 2; function subscribe(parent, child, onFulfillment, onRejection) { var subscribers = parent._subscribers; var length = subscribers.length; subscribers[length] = child; subscribers[length + FULFILLED] = onFulfillment; subscribers[length + REJECTED] = onRejection; } function publish(promise, settled) { var child, callback, subscribers = promise._subscribers, detail = promise._detail; if (config.instrument) { instrument(settled === FULFILLED ? 'fulfilled' : 'rejected', promise); } for (var i = 0; i < subscribers.length; i += 3) { child = subscribers[i]; callback = subscribers[i + settled]; invokeCallback(settled, child, callback, detail); } promise._subscribers = null; } Promise.prototype = { constructor: Promise, _id: undefined, _guidKey: guidKey, _label: undefined, _state: undefined, _detail: undefined, _subscribers: undefined, _onerror: function (reason) { config.trigger('error', reason); }, /** The primary way of interacting with a promise is through its `then` method, which registers callbacks to receive either a promise's eventual value or the reason why the promise cannot be fulfilled. ```js findUser().then(function(user){ // user is available }, function(reason){ // user is unavailable, and you are given the reason why }); ``` Chaining -------- The return value of `then` is itself a promise. This second, "downstream" promise is resolved with the return value of the first promise's fulfillment or rejection handler, or rejected if the handler throws an exception. ```js findUser().then(function (user) { return user.name; }, function (reason) { return "default name"; }).then(function (userName) { // If `findUser` fulfilled, `userName` will be the user's name, otherwise it // will be `"default name"` }); findUser().then(function (user) { throw new Error("Found user, but still unhappy"); }, function (reason) { throw new Error("`findUser` rejected and we're unhappy"); }).then(function (value) { // never reached }, function (reason) { // if `findUser` fulfilled, `reason` will be "Found user, but still unhappy". // If `findUser` rejected, `reason` will be "`findUser` rejected and we're unhappy". }); ``` If the downstream promise does not specify a rejection handler, rejection reasons will be propagated further downstream. ```js findUser().then(function (user) { throw new PedagogicalException("Upstream error"); }).then(function (value) { // never reached }).then(function (value) { // never reached }, function (reason) { // The `PedgagocialException` is propagated all the way down to here }); ``` Assimilation ------------ Sometimes the value you want to propagate to a downstream promise can only be retrieved asynchronously. This can be achieved by returning a promise in the fulfillment or rejection handler. The downstream promise will then be pending until the returned promise is settled. This is called *assimilation*. ```js findUser().then(function (user) { return findCommentsByAuthor(user); }).then(function (comments) { // The user's comments are now available }); ``` If the assimliated promise rejects, then the downstream promise will also reject. ```js findUser().then(function (user) { return findCommentsByAuthor(user); }).then(function (comments) { // If `findCommentsByAuthor` fulfills, we'll have the value here }, function (reason) { // If `findCommentsByAuthor` rejects, we'll have the reason here }); ``` Simple Example -------------- Synchronous Example ```javascript var result; try { result = findResult(); // success } catch(reason) { // failure } ``` Errback Example ```js findResult(function(result, err){ if (err) { // failure } else { // success } }); ``` Promise Example; ```javascript findResult().then(function(result){ // success }, function(reason){ // failure }); ``` Advanced Example -------------- Synchronous Example ```javascript var author, books; try { author = findAuthor(); books = findBooksByAuthor(author); // success } catch(reason) { // failure } ``` Errback Example ```js function foundBooks(books) { } function failure(reason) { } findAuthor(function(author, err){ if (err) { failure(err); // failure } else { try { findBoooksByAuthor(author, function(books, err) { if (err) { failure(err); } else { try { foundBooks(books); } catch(reason) { failure(reason); } } }); } catch(error) { failure(err); } // success } }); ``` Promise Example; ```javascript findAuthor(). then(findBooksByAuthor). then(function(books){ // found books }).catch(function(reason){ // something went wrong }); ``` @method then @param {Function} onFulfilled @param {Function} onRejected @param {String} label optional string for labeling the promise. Useful for tooling. @return {Promise} */ then: function(onFulfillment, onRejection, label) { var promise = this; this._onerror = null; var thenPromise = new this.constructor(noop, label); if (this._state) { var callbacks = arguments; config.async(function invokePromiseCallback() { invokeCallback(promise._state, thenPromise, callbacks[promise._state - 1], promise._detail); }); } else { subscribe(this, thenPromise, onFulfillment, onRejection); } if (config.instrument) { instrument('chained', promise, thenPromise); } return thenPromise; }, /** `catch` is simply sugar for `then(undefined, onRejection)` which makes it the same as the catch block of a try/catch statement. ```js function findAuthor(){ throw new Error("couldn't find that author"); } // synchronous try { findAuthor(); } catch(reason) { // something went wrong } // async with promises findAuthor().catch(function(reason){ // something went wrong }); ``` @method catch @param {Function} onRejection @param {String} label optional string for labeling the promise. Useful for tooling. @return {Promise} */ 'catch': function(onRejection, label) { return this.then(null, onRejection, label); }, /** `finally` will be invoked regardless of the promise's fate just as native try/catch/finally behaves Synchronous example: ```js findAuthor() { if (Math.random() > 0.5) { throw new Error(); } return new Author(); } try { return findAuthor(); // succeed or fail } catch(error) { return findOtherAuther(); } finally { // always runs // doesn't affect the return value } ``` Asynchronous example: ```js findAuthor().catch(function(reason){ return findOtherAuther(); }).finally(function(){ // author was either found, or not }); ``` @method finally @param {Function} callback @param {String} label optional string for labeling the promise. Useful for tooling. @return {Promise} */ 'finally': function(callback, label) { var constructor = this.constructor; return this.then(function(value) { return constructor.cast(callback()).then(function(){ return value; }); }, function(reason) { return constructor.cast(callback()).then(function(){ throw reason; }); }, label); } }; function invokeCallback(settled, promise, callback, detail) { var hasCallback = isFunction(callback), value, error, succeeded, failed; if (hasCallback) { try { value = callback(detail); succeeded = true; } catch(e) { failed = true; error = e; } } else { value = detail; succeeded = true; } if (handleThenable(promise, value)) { return; } else if (hasCallback && succeeded) { resolve(promise, value); } else if (failed) { reject(promise, error); } else if (settled === FULFILLED) { resolve(promise, value); } else if (settled === REJECTED) { reject(promise, value); } } function handleThenable(promise, value) { var then = null, resolved; try { if (promise === value) { throw new TypeError("A promises callback cannot return that same promise."); } if (objectOrFunction(value)) { then = value.then; if (isFunction(then)) { then.call(value, function(val) { if (resolved) { return true; } resolved = true; if (value !== val) { resolve(promise, val); } else { fulfill(promise, val); } }, function(val) { if (resolved) { return true; } resolved = true; reject(promise, val); }, 'derived from: ' + (promise._label || ' unknown promise')); return true; } } } catch (error) { if (resolved) { return true; } reject(promise, error); return true; } return false; } function resolve(promise, value) { if (promise === value) { fulfill(promise, value); } else if (!handleThenable(promise, value)) { fulfill(promise, value); } } function fulfill(promise, value) { if (promise._state !== PENDING) { return; } promise._state = SEALED; promise._detail = value; config.async(publishFulfillment, promise); } function reject(promise, reason) { if (promise._state !== PENDING) { return; } promise._state = SEALED; promise._detail = reason; config.async(publishRejection, promise); } function publishFulfillment(promise) { publish(promise, promise._state = FULFILLED); } function publishRejection(promise) { if (promise._onerror) { promise._onerror(promise._detail); } publish(promise, promise._state = REJECTED); } }); define("rsvp/promise/all", ["../utils","exports"], function(__dependency1__, __exports__) { "use strict"; var isArray = __dependency1__.isArray; var isNonThenable = __dependency1__.isNonThenable; /** `RSVP.Promise.all` accepts an array of promises, and returns a new promise which is fulfilled with an array of fulfillment values for the passed promises, or rejected with the reason of the first passed promise to be rejected. It casts all elements of the passed iterable to promises as it runs this algorithm. Example: ```javascript var promise1 = RSVP.resolve(1); var promise2 = RSVP.resolve(2); var promise3 = RSVP.resolve(3); var promises = [ promise1, promise2, promise3 ]; RSVP.Promise.all(promises).then(function(array){ // The array here would be [ 1, 2, 3 ]; }); ``` If any of the `promises` given to `RSVP.all` are rejected, the first promise that is rejected will be given as an argument to the returned promises's rejection handler. For example: Example: ```javascript var promise1 = RSVP.resolve(1); var promise2 = RSVP.reject(new Error("2")); var promise3 = RSVP.reject(new Error("3")); var promises = [ promise1, promise2, promise3 ]; RSVP.Promise.all(promises).then(function(array){ // Code here never runs because there are rejected promises! }, function(error) { // error.message === "2" }); ``` @method all @for Ember.RSVP.Promise @param {Array} entries array of promises @param {String} label optional string for labeling the promise. Useful for tooling. @return {Promise} promise that is fulfilled when all `promises` have been fulfilled, or rejected if any of them become rejected. @static */ __exports__["default"] = function all(entries, label) { /*jshint validthis:true */ var Constructor = this; return new Constructor(function(resolve, reject) { if (!isArray(entries)) { throw new TypeError('You must pass an array to all.'); } var remaining = entries.length; var results = new Array(remaining); var entry, pending = true; if (remaining === 0) { resolve(results); return; } function fulfillmentAt(index) { return function(value) { results[index] = value; if (--remaining === 0) { resolve(results); } }; } function onRejection(reason) { remaining = 0; reject(reason); } for (var index = 0; index < entries.length; index++) { entry = entries[index]; if (isNonThenable(entry)) { results[index] = entry; if (--remaining === 0) { resolve(results); } } else { Constructor.cast(entry).then(fulfillmentAt(index), onRejection); } } }, label); }; }); define("rsvp/promise/cast", ["exports"], function(__exports__) { "use strict"; /** `RSVP.Promise.cast` coerces its argument to a promise, or returns the argument if it is already a promise which shares a constructor with the caster. Example: ```javascript var promise = RSVP.Promise.resolve(1); var casted = RSVP.Promise.cast(promise); console.log(promise === casted); // true ``` In the case of a promise whose constructor does not match, it is assimilated. The resulting promise will fulfill or reject based on the outcome of the promise being casted. Example: ```javascript var thennable = $.getJSON('/api/foo'); var casted = RSVP.Promise.cast(thennable); console.log(thennable === casted); // false console.log(casted instanceof RSVP.Promise) // true casted.then(function(data) { // data is the value getJSON fulfills with }); ``` In the case of a non-promise, a promise which will fulfill with that value is returned. Example: ```javascript var value = 1; // could be a number, boolean, string, undefined... var casted = RSVP.Promise.cast(value); console.log(value === casted); // false console.log(casted instanceof RSVP.Promise) // true casted.then(function(val) { val === value // => true }); ``` `RSVP.Promise.cast` is similar to `RSVP.Promise.resolve`, but `RSVP.Promise.cast` differs in the following ways: * `RSVP.Promise.cast` serves as a memory-efficient way of getting a promise, when you have something that could either be a promise or a value. RSVP.resolve will have the same effect but will create a new promise wrapper if the argument is a promise. * `RSVP.Promise.cast` is a way of casting incoming thenables or promise subclasses to promises of the exact class specified, so that the resulting object's `then` is ensured to have the behavior of the constructor you are calling cast on (i.e., RSVP.Promise). @method cast @param {Object} object to be casted @param {String} label optional string for labeling the promise. Useful for tooling. @return {Promise} promise @static */ __exports__["default"] = function cast(object, label) { /*jshint validthis:true */ var Constructor = this; if (object && typeof object === 'object' && object.constructor === Constructor) { return object; } return new Constructor(function(resolve) { resolve(object); }, label); }; }); define("rsvp/promise/race", ["../utils","exports"], function(__dependency1__, __exports__) { "use strict"; /* global toString */ var isArray = __dependency1__.isArray; var isFunction = __dependency1__.isFunction; var isNonThenable = __dependency1__.isNonThenable; /** `RSVP.Promise.race` returns a new promise which is settled in the same way as the first passed promise to settle. Example: ```javascript var promise1 = new RSVP.Promise(function(resolve, reject){ setTimeout(function(){ resolve("promise 1"); }, 200); }); var promise2 = new RSVP.Promise(function(resolve, reject){ setTimeout(function(){ resolve("promise 2"); }, 100); }); RSVP.Promise.race([promise1, promise2]).then(function(result){ // result === "promise 2" because it was resolved before promise1 // was resolved. }); ``` `RSVP.Promise.race` is deterministic in that only the state of the first settled promise matters. For example, even if other promises given to the `promises` array argument are resolved, but the first settled promise has become rejected before the other promises became fulfilled, the returned promise will become rejected: ```javascript var promise1 = new RSVP.Promise(function(resolve, reject){ setTimeout(function(){ resolve("promise 1"); }, 200); }); var promise2 = new RSVP.Promise(function(resolve, reject){ setTimeout(function(){ reject(new Error("promise 2")); }, 100); }); RSVP.Promise.race([promise1, promise2]).then(function(result){ // Code here never runs }, function(reason){ // reason.message === "promise2" because promise 2 became rejected before // promise 1 became fulfilled }); ``` An example real-world use case is implementing timeouts: ```javascript RSVP.Promise.race([ajax('foo.json'), timeout(5000)]) ``` @method race @param {Array} promises array of promises to observe @param {String} label optional string for describing the promise returned. Useful for tooling. @return {Promise} a promise which settles in the same way as the first passed promise to settle. @static */ __exports__["default"] = function race(entries, label) { /*jshint validthis:true */ var Constructor = this, entry; return new Constructor(function(resolve, reject) { if (!isArray(entries)) { throw new TypeError('You must pass an array to race.'); } var pending = true; function onFulfillment(value) { if (pending) { pending = false; resolve(value); } } function onRejection(reason) { if (pending) { pending = false; reject(reason); } } for (var i = 0; i < entries.length; i++) { entry = entries[i]; if (isNonThenable(entry)) { pending = false; resolve(entry); return; } else { Constructor.cast(entry).then(onFulfillment, onRejection); } } }, label); }; }); define("rsvp/promise/reject", ["exports"], function(__exports__) { "use strict"; /** `RSVP.Promise.reject` returns a promise rejected with the passed `reason`. It is shorthand for the following: ```javascript var promise = new RSVP.Promise(function(resolve, reject){ reject(new Error('WHOOPS')); }); promise.then(function(value){ // Code here doesn't run because the promise is rejected! }, function(reason){ // reason.message === 'WHOOPS' }); ``` Instead of writing the above, your code now simply becomes the following: ```javascript var promise = RSVP.Promise.reject(new Error('WHOOPS')); promise.then(function(value){ // Code here doesn't run because the promise is rejected! }, function(reason){ // reason.message === 'WHOOPS' }); ``` @method reject @param {Any} reason value that the returned promise will be rejected with. @param {String} label optional string for identifying the returned promise. Useful for tooling. @return {Promise} a promise rejected with the given `reason`. @static */ __exports__["default"] = function reject(reason, label) { /*jshint validthis:true */ var Constructor = this; return new Constructor(function (resolve, reject) { reject(reason); }, label); }; }); define("rsvp/promise/resolve", ["exports"], function(__exports__) { "use strict"; /** `RSVP.Promise.resolve` returns a promise that will become resolved with the passed `value`. It is shorthand for the following: ```javascript var promise = new RSVP.Promise(function(resolve, reject){ resolve(1); }); promise.then(function(value){ // value === 1 }); ``` Instead of writing the above, your code now simply becomes the following: ```javascript var promise = RSVP.Promise.resolve(1); promise.then(function(value){ // value === 1 }); ``` @method resolve @param {Any} value value that the returned promise will be resolved with @param {String} label optional string for identifying the returned promise. Useful for tooling. @return {Promise} a promise that will become fulfilled with the given `value` @static */ __exports__["default"] = function resolve(value, label) { /*jshint validthis:true */ var Constructor = this; return new Constructor(function(resolve, reject) { resolve(value); }, label); }; }); define("rsvp/race", ["./promise","exports"], function(__dependency1__, __exports__) { "use strict"; var Promise = __dependency1__["default"]; /** This is a convenient alias for `RSVP.Promise.race`. @method race @param {Array} array Array of promises. @param {String} label An optional label. This is useful for tooling. @static */ __exports__["default"] = function race(array, label) { return Promise.race(array, label); }; }); define("rsvp/reject", ["./promise","exports"], function(__dependency1__, __exports__) { "use strict"; var Promise = __dependency1__["default"]; /** This is a convenient alias for `RSVP.Promise.reject`. @method reject @for RSVP @param {Any} reason value that the returned promise will be rejected with. @param {String} label optional string for identifying the returned promise. Useful for tooling. @return {Promise} a promise rejected with the given `reason`. @static */ __exports__["default"] = function reject(reason, label) { return Promise.reject(reason, label); }; }); define("rsvp/resolve", ["./promise","exports"], function(__dependency1__, __exports__) { "use strict"; var Promise = __dependency1__["default"]; /** This is a convenient alias for `RSVP.Promise.resolve`. @method resolve @for RSVP @param {Any} value value that the returned promise will be resolved with @param {String} label optional string for identifying the returned promise. Useful for tooling. @return {Promise} a promise that will become fulfilled with the given `value` @static */ __exports__["default"] = function resolve(value, label) { return Promise.resolve(value, label); }; }); define("rsvp/rethrow", ["exports"], function(__exports__) { "use strict"; /** `RSVP.rethrow` will rethrow an error on the next turn of the JavaScript event loop in order to aid debugging. Promises A+ specifies that any exceptions that occur with a promise must be caught by the promises implementation and bubbled to the last handler. For this reason, it is recommended that you always specify a second rejection handler function to `then`. However, `RSVP.rethrow` will throw the exception outside of the promise, so it bubbles up to your console if in the browser, or domain/cause uncaught exception in Node. `rethrow` will also throw the error again so the error can be handled by the promise per the spec. ```javascript function throws(){ throw new Error('Whoops!'); } var promise = new RSVP.Promise(function(resolve, reject){ throws(); }); promise.catch(RSVP.rethrow).then(function(){ // Code here doesn't run because the promise became rejected due to an // error! }, function (err){ // handle the error here }); ``` The 'Whoops' error will be thrown on the next turn of the event loop and you can watch for it in your console. You can also handle it using a rejection handler given to `.then` or `.catch` on the returned promise. @method rethrow @for RSVP @param {Error} reason reason the promise became rejected. @throws Error @static */ __exports__["default"] = function rethrow(reason) { setTimeout(function() { throw reason; }); throw reason; }; }); define("rsvp/utils", ["exports"], function(__exports__) { "use strict"; function objectOrFunction(x) { return typeof x === "function" || (typeof x === "object" && x !== null); } __exports__.objectOrFunction = objectOrFunction;function isFunction(x) { return typeof x === "function"; } __exports__.isFunction = isFunction;function isNonThenable(x) { return !objectOrFunction(x); } __exports__.isNonThenable = isNonThenable;function isArray(x) { return Object.prototype.toString.call(x) === "[object Array]"; } __exports__.isArray = isArray;// Date.now is not available in browsers < IE9 // https://developer.mozilla.org/en-US/docs/Web/JavaScript/Reference/Global_Objects/Date/now#Compatibility var now = Date.now || function() { return new Date().getTime(); }; __exports__.now = now; var keysOf = Object.keys || function(object) { var result = []; for (var prop in object) { result.push(prop); } return result; }; __exports__.keysOf = keysOf; }); define("rsvp", ["./rsvp/promise","./rsvp/events","./rsvp/node","./rsvp/all","./rsvp/all_settled","./rsvp/race","./rsvp/hash","./rsvp/rethrow","./rsvp/defer","./rsvp/config","./rsvp/map","./rsvp/resolve","./rsvp/reject","./rsvp/filter","exports"], function(__dependency1__, __dependency2__, __dependency3__, __dependency4__, __dependency5__, __dependency6__, __dependency7__, __dependency8__, __dependency9__, __dependency10__, __dependency11__, __dependency12__, __dependency13__, __dependency14__, __exports__) { "use strict"; var Promise = __dependency1__["default"]; var EventTarget = __dependency2__["default"]; var denodeify = __dependency3__["default"]; var all = __dependency4__["default"]; var allSettled = __dependency5__["default"]; var race = __dependency6__["default"]; var hash = __dependency7__["default"]; var rethrow = __dependency8__["default"]; var defer = __dependency9__["default"]; var config = __dependency10__.config; var configure = __dependency10__.configure; var map = __dependency11__["default"]; var resolve = __dependency12__["default"]; var reject = __dependency13__["default"]; var filter = __dependency14__["default"]; function async(callback, arg) { config.async(callback, arg); } function on() { config.on.apply(config, arguments); } function off() { config.off.apply(config, arguments); } // Set up instrumentation through `window.__PROMISE_INTRUMENTATION__` if (typeof window !== 'undefined' && typeof window.__PROMISE_INSTRUMENTATION__ === 'object') { var callbacks = window.__PROMISE_INSTRUMENTATION__; configure('instrument', true); for (var eventName in callbacks) { if (callbacks.hasOwnProperty(eventName)) { on(eventName, callbacks[eventName]); } } } __exports__.Promise = Promise; __exports__.EventTarget = EventTarget; __exports__.all = all; __exports__.allSettled = allSettled; __exports__.race = race; __exports__.hash = hash; __exports__.rethrow = rethrow; __exports__.defer = defer; __exports__.denodeify = denodeify; __exports__.configure = configure; __exports__.on = on; __exports__.off = off; __exports__.resolve = resolve; __exports__.reject = reject; __exports__.async = async; __exports__.map = map; __exports__.filter = filter; }); })(); (function() { /** Public api for the container is still in flux. The public api, specified on the application namespace should be considered the stable api. // @module container @private */ /* Flag to enable/disable model factory injections (disabled by default) If model factory injections are enabled, models should not be accessed globally (only through `container.lookupFactory('model:modelName'))`); */ Ember.MODEL_FACTORY_INJECTIONS = false || !!Ember.ENV.MODEL_FACTORY_INJECTIONS; define("container", [], function() { "use strict"; // A safe and simple inheriting object. function InheritingDict(parent) { this.parent = parent; this.dict = {}; } InheritingDict.prototype = { /** @property parent @type InheritingDict @default null */ parent: null, /** Object used to store the current nodes data. @property dict @type Object @default Object */ dict: null, /** Retrieve the value given a key, if the value is present at the current level use it, otherwise walk up the parent hierarchy and try again. If no matching key is found, return undefined. @method get @param {String} key @return {any} */ get: function(key) { var dict = this.dict; if (dict.hasOwnProperty(key)) { return dict[key]; } if (this.parent) { return this.parent.get(key); } }, /** Set the given value for the given key, at the current level. @method set @param {String} key @param {Any} value */ set: function(key, value) { this.dict[key] = value; }, /** Delete the given key @method remove @param {String} key */ remove: function(key) { delete this.dict[key]; }, /** Check for the existence of given a key, if the key is present at the current level return true, otherwise walk up the parent hierarchy and try again. If no matching key is found, return false. @method has @param {String} key @return {Boolean} */ has: function(key) { var dict = this.dict; if (dict.hasOwnProperty(key)) { return true; } if (this.parent) { return this.parent.has(key); } return false; }, /** Iterate and invoke a callback for each local key-value pair. @method eachLocal @param {Function} callback @param {Object} binding */ eachLocal: function(callback, binding) { var dict = this.dict; for (var prop in dict) { if (dict.hasOwnProperty(prop)) { callback.call(binding, prop, dict[prop]); } } } }; // A lightweight container that helps to assemble and decouple components. // Public api for the container is still in flux. // The public api, specified on the application namespace should be considered the stable api. function Container(parent) { this.parent = parent; this.children = []; this.resolver = parent && parent.resolver || function() {}; this.registry = new InheritingDict(parent && parent.registry); this.cache = new InheritingDict(parent && parent.cache); this.factoryCache = new InheritingDict(parent && parent.factoryCache); this.resolveCache = new InheritingDict(parent && parent.resolveCache); this.typeInjections = new InheritingDict(parent && parent.typeInjections); this.injections = {}; this.factoryTypeInjections = new InheritingDict(parent && parent.factoryTypeInjections); this.factoryInjections = {}; this._options = new InheritingDict(parent && parent._options); this._typeOptions = new InheritingDict(parent && parent._typeOptions); } Container.prototype = { /** @property parent @type Container @default null */ parent: null, /** @property children @type Array @default [] */ children: null, /** @property resolver @type function */ resolver: null, /** @property registry @type InheritingDict */ registry: null, /** @property cache @type InheritingDict */ cache: null, /** @property typeInjections @type InheritingDict */ typeInjections: null, /** @property injections @type Object @default {} */ injections: null, /** @private @property _options @type InheritingDict @default null */ _options: null, /** @private @property _typeOptions @type InheritingDict */ _typeOptions: null, /** Returns a new child of the current container. These children are configured to correctly inherit from the current container. @method child @return {Container} */ child: function() { var container = new Container(this); this.children.push(container); return container; }, /** Sets a key-value pair on the current container. If a parent container, has the same key, once set on a child, the parent and child will diverge as expected. @method set @param {Object} object @param {String} key @param {any} value */ set: function(object, key, value) { object[key] = value; }, /** Registers a factory for later injection. Example: ```javascript var container = new Container(); container.register('model:user', Person, {singleton: false }); container.register('fruit:favorite', Orange); container.register('communication:main', Email, {singleton: false}); ``` @method register @param {String} fullName @param {Function} factory @param {Object} options */ register: function(fullName, factory, options) { validateFullName(fullName); if (factory === undefined) { throw new TypeError('Attempting to register an unknown factory: `' + fullName + '`'); } var normalizedName = this.normalize(fullName); if (this.cache.has(normalizedName)) { throw new Error('Cannot re-register: `' + fullName +'`, as it has already been looked up.'); } this.registry.set(normalizedName, factory); this._options.set(normalizedName, options || {}); }, /** Unregister a fullName ```javascript var container = new Container(); container.register('model:user', User); container.lookup('model:user') instanceof User //=> true container.unregister('model:user') container.lookup('model:user') === undefined //=> true ``` @method unregister @param {String} fullName */ unregister: function(fullName) { validateFullName(fullName); var normalizedName = this.normalize(fullName); this.registry.remove(normalizedName); this.cache.remove(normalizedName); this.factoryCache.remove(normalizedName); this.resolveCache.remove(normalizedName); this._options.remove(normalizedName); }, /** Given a fullName return the corresponding factory. By default `resolve` will retrieve the factory from its container's registry. ```javascript var container = new Container(); container.register('api:twitter', Twitter); container.resolve('api:twitter') // => Twitter ``` Optionally the container can be provided with a custom resolver. If provided, `resolve` will first provide the custom resolver the oppertunity to resolve the fullName, otherwise it will fallback to the registry. ```javascript var container = new Container(); container.resolver = function(fullName) { // lookup via the module system of choice }; // the twitter factory is added to the module system container.resolve('api:twitter') // => Twitter ``` @method resolve @param {String} fullName @return {Function} fullName's factory */ resolve: function(fullName) { validateFullName(fullName); var normalizedName = this.normalize(fullName); var cached = this.resolveCache.get(normalizedName); if (cached) { return cached; } var resolved = this.resolver(normalizedName) || this.registry.get(normalizedName); this.resolveCache.set(normalizedName, resolved); return resolved; }, /** A hook that can be used to describe how the resolver will attempt to find the factory. For example, the default Ember `.describe` returns the full class name (including namespace) where Ember's resolver expects to find the `fullName`. @method describe @param {String} fullName @return {string} described fullName */ describe: function(fullName) { return fullName; }, /** A hook to enable custom fullName normalization behaviour @method normalize @param {String} fullName @return {string} normalized fullName */ normalize: function(fullName) { return fullName; }, /** @method makeToString @param {any} factory @param {string} fullName @return {function} toString function */ makeToString: function(factory, fullName) { return factory.toString(); }, /** Given a fullName return a corresponding instance. The default behaviour is for lookup to return a singleton instance. The singleton is scoped to the container, allowing multiple containers to all have their own locally scoped singletons. ```javascript var container = new Container(); container.register('api:twitter', Twitter); var twitter = container.lookup('api:twitter'); twitter instanceof Twitter; // => true // by default the container will return singletons var twitter2 = container.lookup('api:twitter'); twitter instanceof Twitter; // => true twitter === twitter2; //=> true ``` If singletons are not wanted an optional flag can be provided at lookup. ```javascript var container = new Container(); container.register('api:twitter', Twitter); var twitter = container.lookup('api:twitter', { singleton: false }); var twitter2 = container.lookup('api:twitter', { singleton: false }); twitter === twitter2; //=> false ``` @method lookup @param {String} fullName @param {Object} options @return {any} */ lookup: function(fullName, options) { validateFullName(fullName); return lookup(this, this.normalize(fullName), options); }, /** Given a fullName return the corresponding factory. @method lookupFactory @param {String} fullName @return {any} */ lookupFactory: function(fullName) { validateFullName(fullName); return factoryFor(this, this.normalize(fullName)); }, /** Given a fullName check if the container is aware of its factory or singleton instance. @method has @param {String} fullName @return {Boolean} */ has: function(fullName) { validateFullName(fullName); return has(this, this.normalize(fullName)); }, /** Allow registering options for all factories of a type. ```javascript var container = new Container(); // if all of type `connection` must not be singletons container.optionsForType('connection', { singleton: false }); container.register('connection:twitter', TwitterConnection); container.register('connection:facebook', FacebookConnection); var twitter = container.lookup('connection:twitter'); var twitter2 = container.lookup('connection:twitter'); twitter === twitter2; // => false var facebook = container.lookup('connection:facebook'); var facebook2 = container.lookup('connection:facebook'); facebook === facebook2; // => false ``` @method optionsForType @param {String} type @param {Object} options */ optionsForType: function(type, options) { if (this.parent) { illegalChildOperation('optionsForType'); } this._typeOptions.set(type, options); }, /** @method options @param {String} type @param {Object} options */ options: function(type, options) { this.optionsForType(type, options); }, /** Used only via `injection`. Provides a specialized form of injection, specifically enabling all objects of one type to be injected with a reference to another object. For example, provided each object of type `controller` needed a `router`. one would do the following: ```javascript var container = new Container(); container.register('router:main', Router); container.register('controller:user', UserController); container.register('controller:post', PostController); container.typeInjection('controller', 'router', 'router:main'); var user = container.lookup('controller:user'); var post = container.lookup('controller:post'); user.router instanceof Router; //=> true post.router instanceof Router; //=> true // both controllers share the same router user.router === post.router; //=> true ``` @private @method typeInjection @param {String} type @param {String} property @param {String} fullName */ typeInjection: function(type, property, fullName) { validateFullName(fullName); if (this.parent) { illegalChildOperation('typeInjection'); } addTypeInjection(this.typeInjections, type, property, fullName); }, /** Defines injection rules. These rules are used to inject dependencies onto objects when they are instantiated. Two forms of injections are possible: * Injecting one fullName on another fullName * Injecting one fullName on a type Example: ```javascript var container = new Container(); container.register('source:main', Source); container.register('model:user', User); container.register('model:post', Post); // injecting one fullName on another fullName // eg. each user model gets a post model container.injection('model:user', 'post', 'model:post'); // injecting one fullName on another type container.injection('model', 'source', 'source:main'); var user = container.lookup('model:user'); var post = container.lookup('model:post'); user.source instanceof Source; //=> true post.source instanceof Source; //=> true user.post instanceof Post; //=> true // and both models share the same source user.source === post.source; //=> true ``` @method injection @param {String} factoryName @param {String} property @param {String} injectionName */ injection: function(fullName, property, injectionName) { if (this.parent) { illegalChildOperation('injection'); } validateFullName(injectionName); var normalizedInjectionName = this.normalize(injectionName); if (fullName.indexOf(':') === -1) { return this.typeInjection(fullName, property, normalizedInjectionName); } validateFullName(fullName); var normalizedName = this.normalize(fullName); addInjection(this.injections, normalizedName, property, normalizedInjectionName); }, /** Used only via `factoryInjection`. Provides a specialized form of injection, specifically enabling all factory of one type to be injected with a reference to another object. For example, provided each factory of type `model` needed a `store`. one would do the following: ```javascript var container = new Container(); container.register('store:main', SomeStore); container.factoryTypeInjection('model', 'store', 'store:main'); var store = container.lookup('store:main'); var UserFactory = container.lookupFactory('model:user'); UserFactory.store instanceof SomeStore; //=> true ``` @private @method factoryTypeInjection @param {String} type @param {String} property @param {String} fullName */ factoryTypeInjection: function(type, property, fullName) { if (this.parent) { illegalChildOperation('factoryTypeInjection'); } addTypeInjection(this.factoryTypeInjections, type, property, this.normalize(fullName)); }, /** Defines factory injection rules. Similar to regular injection rules, but are run against factories, via `Container#lookupFactory`. These rules are used to inject objects onto factories when they are looked up. Two forms of injections are possible: * Injecting one fullName on another fullName * Injecting one fullName on a type Example: ```javascript var container = new Container(); container.register('store:main', Store); container.register('store:secondary', OtherStore); container.register('model:user', User); container.register('model:post', Post); // injecting one fullName on another type container.factoryInjection('model', 'store', 'store:main'); // injecting one fullName on another fullName container.factoryInjection('model:post', 'secondaryStore', 'store:secondary'); var UserFactory = container.lookupFactory('model:user'); var PostFactory = container.lookupFactory('model:post'); var store = container.lookup('store:main'); UserFactory.store instanceof Store; //=> true UserFactory.secondaryStore instanceof OtherStore; //=> false PostFactory.store instanceof Store; //=> true PostFactory.secondaryStore instanceof OtherStore; //=> true // and both models share the same source instance UserFactory.store === PostFactory.store; //=> true ``` @method factoryInjection @param {String} factoryName @param {String} property @param {String} injectionName */ factoryInjection: function(fullName, property, injectionName) { if (this.parent) { illegalChildOperation('injection'); } var normalizedName = this.normalize(fullName); var normalizedInjectionName = this.normalize(injectionName); validateFullName(injectionName); if (fullName.indexOf(':') === -1) { return this.factoryTypeInjection(normalizedName, property, normalizedInjectionName); } validateFullName(fullName); addInjection(this.factoryInjections, normalizedName, property, normalizedInjectionName); }, /** A depth first traversal, destroying the container, its descendant containers and all their managed objects. @method destroy */ destroy: function() { for (var i=0, l=this.children.length; i w. */ Ember.compare = function compare(v, w) { if (v === w) { return 0; } var type1 = Ember.typeOf(v); var type2 = Ember.typeOf(w); var Comparable = Ember.Comparable; if (Comparable) { if (type1==='instance' && Comparable.detect(v.constructor)) { return v.constructor.compare(v, w); } if (type2 === 'instance' && Comparable.detect(w.constructor)) { return 1-w.constructor.compare(w, v); } } // If we haven't yet generated a reverse-mapping of Ember.ORDER_DEFINITION, // do so now. var mapping = Ember.ORDER_DEFINITION_MAPPING; if (!mapping) { var order = Ember.ORDER_DEFINITION; mapping = Ember.ORDER_DEFINITION_MAPPING = {}; var idx, len; for (idx = 0, len = order.length; idx < len; ++idx) { mapping[order[idx]] = idx; } // We no longer need Ember.ORDER_DEFINITION. delete Ember.ORDER_DEFINITION; } var type1Index = mapping[type1]; var type2Index = mapping[type2]; if (type1Index < type2Index) { return -1; } if (type1Index > type2Index) { return 1; } // types are equal - so we have to check values now switch (type1) { case 'boolean': case 'number': if (v < w) { return -1; } if (v > w) { return 1; } return 0; case 'string': var comp = v.localeCompare(w); if (comp < 0) { return -1; } if (comp > 0) { return 1; } return 0; case 'array': var vLen = v.length; var wLen = w.length; var l = Math.min(vLen, wLen); var r = 0; var i = 0; while (r === 0 && i < l) { r = compare(v[i],w[i]); i++; } if (r !== 0) { return r; } // all elements are equal now // shorter array should be ordered first if (vLen < wLen) { return -1; } if (vLen > wLen) { return 1; } // arrays are equal now return 0; case 'instance': if (Ember.Comparable && Ember.Comparable.detect(v)) { return v.compare(v, w); } return 0; case 'date': var vNum = v.getTime(); var wNum = w.getTime(); if (vNum < wNum) { return -1; } if (vNum > wNum) { return 1; } return 0; default: return 0; } }; function _copy(obj, deep, seen, copies) { var ret, loc, key; // primitive data types are immutable, just return them. if ('object' !== typeof obj || obj===null) return obj; // avoid cyclical loops if (deep && (loc=indexOf(seen, obj))>=0) return copies[loc]; // IMPORTANT: this specific test will detect a native array only. Any other // object will need to implement Copyable. if (Ember.typeOf(obj) === 'array') { ret = obj.slice(); if (deep) { loc = ret.length; while(--loc>=0) ret[loc] = _copy(ret[loc], deep, seen, copies); } } else if (Ember.Copyable && Ember.Copyable.detect(obj)) { ret = obj.copy(deep, seen, copies); } else { ret = {}; for(key in obj) { if (!obj.hasOwnProperty(key)) continue; // Prevents browsers that don't respect non-enumerability from // copying internal Ember properties if (key.substring(0,2) === '__') continue; ret[key] = deep ? _copy(obj[key], deep, seen, copies) : obj[key]; } } if (deep) { seen.push(obj); copies.push(ret); } return ret; } /** Creates a clone of the passed object. This function can take just about any type of object and create a clone of it, including primitive values (which are not actually cloned because they are immutable). If the passed object implements the `clone()` method, then this function will simply call that method and return the result. @method copy @for Ember @param {Object} obj The object to clone @param {Boolean} deep If true, a deep copy of the object is made @return {Object} The cloned object */ Ember.copy = function(obj, deep) { // fast paths if ('object' !== typeof obj || obj===null) return obj; // can't copy primitives if (Ember.Copyable && Ember.Copyable.detect(obj)) return obj.copy(deep); return _copy(obj, deep, deep ? [] : null, deep ? [] : null); }; /** Compares two objects, returning true if they are logically equal. This is a deeper comparison than a simple triple equal. For sets it will compare the internal objects. For any other object that implements `isEqual()` it will respect that method. ```javascript Ember.isEqual('hello', 'hello'); // true Ember.isEqual(1, 2); // false Ember.isEqual([4,2], [4,2]); // false ``` @method isEqual @for Ember @param {Object} a first object to compare @param {Object} b second object to compare @return {Boolean} */ Ember.isEqual = function(a, b) { if (a && 'function'===typeof a.isEqual) return a.isEqual(b); return a === b; }; // Used by Ember.compare Ember.ORDER_DEFINITION = Ember.ENV.ORDER_DEFINITION || [ 'undefined', 'null', 'boolean', 'number', 'string', 'array', 'object', 'instance', 'function', 'class', 'date' ]; /** Returns all of the keys defined on an object or hash. This is useful when inspecting objects for debugging. On browsers that support it, this uses the native `Object.keys` implementation. @method keys @for Ember @param {Object} obj @return {Array} Array containing keys of obj */ Ember.keys = Object.keys; if (!Ember.keys || Ember.create.isSimulated) { var prototypeProperties = [ 'constructor', 'hasOwnProperty', 'isPrototypeOf', 'propertyIsEnumerable', 'valueOf', 'toLocaleString', 'toString' ], pushPropertyName = function(obj, array, key) { // Prevents browsers that don't respect non-enumerability from // copying internal Ember properties if (key.substring(0,2) === '__') return; if (key === '_super') return; if (indexOf(array, key) >= 0) return; if (!obj.hasOwnProperty(key)) return; array.push(key); }; Ember.keys = function(obj) { var ret = [], key; for (key in obj) { pushPropertyName(obj, ret, key); } // IE8 doesn't enumerate property that named the same as prototype properties. for (var i = 0, l = prototypeProperties.length; i < l; i++) { key = prototypeProperties[i]; pushPropertyName(obj, ret, key); } return ret; }; } })(); (function() { /** @module ember @submodule ember-runtime */ var STRING_DASHERIZE_REGEXP = (/[ _]/g); var STRING_DASHERIZE_CACHE = {}; var STRING_DECAMELIZE_REGEXP = (/([a-z\d])([A-Z])/g); var STRING_CAMELIZE_REGEXP = (/(\-|_|\.|\s)+(.)?/g); var STRING_UNDERSCORE_REGEXP_1 = (/([a-z\d])([A-Z]+)/g); var STRING_UNDERSCORE_REGEXP_2 = (/\-|\s+/g); var STRING_PARAMETERIZE_REGEXP_1 = (/[_|\/|\s]+/g); var STRING_PARAMETERIZE_REGEXP_2 = (/[^a-z0-9\-]+/gi); var STRING_PARAMETERIZE_REGEXP_3 = (/[\-]+/g); var STRING_PARAMETERIZE_REGEXP_4 = (/^-+|-+$/g); /** Defines the hash of localized strings for the current language. Used by the `Ember.String.loc()` helper. To localize, add string values to this hash. @property STRINGS @for Ember @type Hash */ Ember.STRINGS = {}; /** Defines string helper methods including string formatting and localization. Unless `Ember.EXTEND_PROTOTYPES.String` is `false` these methods will also be added to the `String.prototype` as well. @class String @namespace Ember @static */ Ember.String = { /** Apply formatting options to the string. This will look for occurrences of "%@" in your string and substitute them with the arguments you pass into this method. If you want to control the specific order of replacement, you can add a number after the key as well to indicate which argument you want to insert. Ordered insertions are most useful when building loc strings where values you need to insert may appear in different orders. ```javascript "Hello %@ %@".fmt('John', 'Doe'); // "Hello John Doe" "Hello %@2, %@1".fmt('John', 'Doe'); // "Hello Doe, John" ``` @method fmt @param {String} str The string to format @param {Array} formats An array of parameters to interpolate into string. @return {String} formatted string */ fmt: function(str, formats) { // first, replace any ORDERED replacements. var idx = 0; // the current index for non-numerical replacements return str.replace(/%@([0-9]+)?/g, function(s, argIndex) { argIndex = (argIndex) ? parseInt(argIndex, 10) - 1 : idx++; s = formats[argIndex]; return (s === null) ? '(null)' : (s === undefined) ? '' : Ember.inspect(s); }) ; }, /** Formats the passed string, but first looks up the string in the localized strings hash. This is a convenient way to localize text. See `Ember.String.fmt()` for more information on formatting. Note that it is traditional but not required to prefix localized string keys with an underscore or other character so you can easily identify localized strings. ```javascript Ember.STRINGS = { '_Hello World': 'Bonjour le monde', '_Hello %@ %@': 'Bonjour %@ %@' }; Ember.String.loc("_Hello World"); // 'Bonjour le monde'; Ember.String.loc("_Hello %@ %@", ["John", "Smith"]); // "Bonjour John Smith"; ``` @method loc @param {String} str The string to format @param {Array} formats Optional array of parameters to interpolate into string. @return {String} formatted string */ loc: function(str, formats) { str = Ember.STRINGS[str] || str; return Ember.String.fmt(str, formats) ; }, /** Splits a string into separate units separated by spaces, eliminating any empty strings in the process. This is a convenience method for split that is mostly useful when applied to the `String.prototype`. ```javascript Ember.String.w("alpha beta gamma").forEach(function(key) { console.log(key); }); // > alpha // > beta // > gamma ``` @method w @param {String} str The string to split @return {String} split string */ w: function(str) { return str.split(/\s+/); }, /** Converts a camelized string into all lower case separated by underscores. ```javascript 'innerHTML'.decamelize(); // 'inner_html' 'action_name'.decamelize(); // 'action_name' 'css-class-name'.decamelize(); // 'css-class-name' 'my favorite items'.decamelize(); // 'my favorite items' ``` @method decamelize @param {String} str The string to decamelize. @return {String} the decamelized string. */ decamelize: function(str) { return str.replace(STRING_DECAMELIZE_REGEXP, '$1_$2').toLowerCase(); }, /** Replaces underscores, spaces, or camelCase with dashes. ```javascript 'innerHTML'.dasherize(); // 'inner-html' 'action_name'.dasherize(); // 'action-name' 'css-class-name'.dasherize(); // 'css-class-name' 'my favorite items'.dasherize(); // 'my-favorite-items' ``` @method dasherize @param {String} str The string to dasherize. @return {String} the dasherized string. */ dasherize: function(str) { var cache = STRING_DASHERIZE_CACHE, hit = cache.hasOwnProperty(str), ret; if (hit) { return cache[str]; } else { ret = Ember.String.decamelize(str).replace(STRING_DASHERIZE_REGEXP,'-'); cache[str] = ret; } return ret; }, /** Returns the lowerCamelCase form of a string. ```javascript 'innerHTML'.camelize(); // 'innerHTML' 'action_name'.camelize(); // 'actionName' 'css-class-name'.camelize(); // 'cssClassName' 'my favorite items'.camelize(); // 'myFavoriteItems' 'My Favorite Items'.camelize(); // 'myFavoriteItems' ``` @method camelize @param {String} str The string to camelize. @return {String} the camelized string. */ camelize: function(str) { return str.replace(STRING_CAMELIZE_REGEXP, function(match, separator, chr) { return chr ? chr.toUpperCase() : ''; }).replace(/^([A-Z])/, function(match, separator, chr) { return match.toLowerCase(); }); }, /** Returns the UpperCamelCase form of a string. ```javascript 'innerHTML'.classify(); // 'InnerHTML' 'action_name'.classify(); // 'ActionName' 'css-class-name'.classify(); // 'CssClassName' 'my favorite items'.classify(); // 'MyFavoriteItems' ``` @method classify @param {String} str the string to classify @return {String} the classified string */ classify: function(str) { var parts = str.split("."), out = []; for (var i=0, l=parts.length; i= 0) { var baseValue = this[keyName]; if (baseValue) { if ('function' === typeof baseValue.concat) { value = baseValue.concat(value); } else { value = Ember.makeArray(baseValue).concat(value); } } else { value = Ember.makeArray(value); } } if (desc) { desc.set(this, keyName, value); } else { if (typeof this.setUnknownProperty === 'function' && !(keyName in this)) { this.setUnknownProperty(keyName, value); } else if (MANDATORY_SETTER) { Ember.defineProperty(this, keyName, null, value); // setup mandatory setter } else { this[keyName] = value; } } } } } finishPartial(this, m); this.init.apply(this, arguments); m.proto = proto; finishChains(this); sendEvent(this, "init"); }; Class.toString = Mixin.prototype.toString; Class.willReopen = function() { if (wasApplied) { Class.PrototypeMixin = Mixin.create(Class.PrototypeMixin); } wasApplied = false; }; Class._initMixins = function(args) { initMixins = args; }; Class._initProperties = function(args) { initProperties = args; }; Class.proto = function() { var superclass = Class.superclass; if (superclass) { superclass.proto(); } if (!wasApplied) { wasApplied = true; Class.PrototypeMixin.applyPartial(Class.prototype); rewatch(Class.prototype); } return this.prototype; }; return Class; } /** @class CoreObject @namespace Ember */ var CoreObject = makeCtor(); CoreObject.toString = function() { return "Ember.CoreObject"; }; CoreObject.PrototypeMixin = Mixin.create({ reopen: function() { applyMixin(this, arguments, true); return this; }, /** An overridable method called when objects are instantiated. By default, does nothing unless it is overridden during class definition. Example: ```javascript App.Person = Ember.Object.extend({ init: function() { alert('Name is ' + this.get('name')); } }); var steve = App.Person.create({ name: "Steve" }); // alerts 'Name is Steve'. ``` NOTE: If you do override `init` for a framework class like `Ember.View` or `Ember.ArrayController`, be sure to call `this._super()` in your `init` declaration! If you don't, Ember may not have an opportunity to do important setup work, and you'll see strange behavior in your application. @method init */ init: function() {}, /** Defines the properties that will be concatenated from the superclass (instead of overridden). By default, when you extend an Ember class a property defined in the subclass overrides a property with the same name that is defined in the superclass. However, there are some cases where it is preferable to build up a property's value by combining the superclass' property value with the subclass' value. An example of this in use within Ember is the `classNames` property of `Ember.View`. Here is some sample code showing the difference between a concatenated property and a normal one: ```javascript App.BarView = Ember.View.extend({ someNonConcatenatedProperty: ['bar'], classNames: ['bar'] }); App.FooBarView = App.BarView.extend({ someNonConcatenatedProperty: ['foo'], classNames: ['foo'], }); var fooBarView = App.FooBarView.create(); fooBarView.get('someNonConcatenatedProperty'); // ['foo'] fooBarView.get('classNames'); // ['ember-view', 'bar', 'foo'] ``` This behavior extends to object creation as well. Continuing the above example: ```javascript var view = App.FooBarView.create({ someNonConcatenatedProperty: ['baz'], classNames: ['baz'] }) view.get('someNonConcatenatedProperty'); // ['baz'] view.get('classNames'); // ['ember-view', 'bar', 'foo', 'baz'] ``` Adding a single property that is not an array will just add it in the array: ```javascript var view = App.FooBarView.create({ classNames: 'baz' }) view.get('classNames'); // ['ember-view', 'bar', 'foo', 'baz'] ``` Using the `concatenatedProperties` property, we can tell to Ember that mix the content of the properties. In `Ember.View` the `classNameBindings` and `attributeBindings` properties are also concatenated, in addition to `classNames`. This feature is available for you to use throughout the Ember object model, although typical app developers are likely to use it infrequently. Since it changes expectations about behavior of properties, you should properly document its usage in each individual concatenated property (to not mislead your users to think they can override the property in a subclass). @property concatenatedProperties @type Array @default null */ concatenatedProperties: null, /** Destroyed object property flag. if this property is `true` the observers and bindings were already removed by the effect of calling the `destroy()` method. @property isDestroyed @default false */ isDestroyed: false, /** Destruction scheduled flag. The `destroy()` method has been called. The object stays intact until the end of the run loop at which point the `isDestroyed` flag is set. @property isDestroying @default false */ isDestroying: false, /** Destroys an object by setting the `isDestroyed` flag and removing its metadata, which effectively destroys observers and bindings. If you try to set a property on a destroyed object, an exception will be raised. Note that destruction is scheduled for the end of the run loop and does not happen immediately. It will set an isDestroying flag immediately. @method destroy @return {Ember.Object} receiver */ destroy: function() { if (this.isDestroying) { return; } this.isDestroying = true; schedule('actions', this, this.willDestroy); schedule('destroy', this, this._scheduledDestroy); return this; }, /** Override to implement teardown. @method willDestroy */ willDestroy: Ember.K, /** Invoked by the run loop to actually destroy the object. This is scheduled for execution by the `destroy` method. @private @method _scheduledDestroy */ _scheduledDestroy: function() { if (this.isDestroyed) { return; } destroy(this); this.isDestroyed = true; }, bind: function(to, from) { if (!(from instanceof Ember.Binding)) { from = Ember.Binding.from(from); } from.to(to).connect(this); return from; }, /** Returns a string representation which attempts to provide more information than Javascript's `toString` typically does, in a generic way for all Ember objects. ```javascript App.Person = Em.Object.extend() person = App.Person.create() person.toString() //=> "" ``` If the object's class is not defined on an Ember namespace, it will indicate it is a subclass of the registered superclass: ```javascript Student = App.Person.extend() student = Student.create() student.toString() //=> "<(subclass of App.Person):ember1025>" ``` If the method `toStringExtension` is defined, its return value will be included in the output. ```javascript App.Teacher = App.Person.extend({ toStringExtension: function() { return this.get('fullName'); } }); teacher = App.Teacher.create() teacher.toString(); //=> "" ``` @method toString @return {String} string representation */ toString: function toString() { var hasToStringExtension = typeof this.toStringExtension === 'function', extension = hasToStringExtension ? ":" + this.toStringExtension() : ''; var ret = '<'+this.constructor.toString()+':'+guidFor(this)+extension+'>'; this.toString = makeToString(ret); return ret; } }); CoreObject.PrototypeMixin.ownerConstructor = CoreObject; function makeToString(ret) { return function() { return ret; }; } if (Ember.config.overridePrototypeMixin) { Ember.config.overridePrototypeMixin(CoreObject.PrototypeMixin); } CoreObject.__super__ = null; var ClassMixin = Mixin.create({ ClassMixin: Ember.required(), PrototypeMixin: Ember.required(), isClass: true, isMethod: false, /** Creates a new subclass. ```javascript App.Person = Ember.Object.extend({ say: function(thing) { alert(thing); } }); ``` This defines a new subclass of Ember.Object: `App.Person`. It contains one method: `say()`. You can also create a subclass from any existing class by calling its `extend()` method. For example, you might want to create a subclass of Ember's built-in `Ember.View` class: ```javascript App.PersonView = Ember.View.extend({ tagName: 'li', classNameBindings: ['isAdministrator'] }); ``` When defining a subclass, you can override methods but still access the implementation of your parent class by calling the special `_super()` method: ```javascript App.Person = Ember.Object.extend({ say: function(thing) { var name = this.get('name'); alert(name + ' says: ' + thing); } }); App.Soldier = App.Person.extend({ say: function(thing) { this._super(thing + ", sir!"); }, march: function(numberOfHours) { alert(this.get('name') + ' marches for ' + numberOfHours + ' hours.') } }); var yehuda = App.Soldier.create({ name: "Yehuda Katz" }); yehuda.say("Yes"); // alerts "Yehuda Katz says: Yes, sir!" ``` The `create()` on line #17 creates an *instance* of the `App.Soldier` class. The `extend()` on line #8 creates a *subclass* of `App.Person`. Any instance of the `App.Person` class will *not* have the `march()` method. You can also pass `Ember.Mixin` classes to add additional properties to the subclass. ```javascript App.Person = Ember.Object.extend({ say: function(thing) { alert(this.get('name') + ' says: ' + thing); } }); App.SingingMixin = Ember.Mixin.create({ sing: function(thing){ alert(this.get('name') + ' sings: la la la ' + thing); } }); App.BroadwayStar = App.Person.extend(App.SingingMixin, { dance: function() { alert(this.get('name') + ' dances: tap tap tap tap '); } }); ``` The `App.BroadwayStar` class contains three methods: `say()`, `sing()`, and `dance()`. @method extend @static @param {Ember.Mixin} [mixins]* One or more Ember.Mixin classes @param {Object} [arguments]* Object containing values to use within the new class */ extend: function() { var Class = makeCtor(), proto; Class.ClassMixin = Mixin.create(this.ClassMixin); Class.PrototypeMixin = Mixin.create(this.PrototypeMixin); Class.ClassMixin.ownerConstructor = Class; Class.PrototypeMixin.ownerConstructor = Class; reopen.apply(Class.PrototypeMixin, arguments); Class.superclass = this; Class.__super__ = this.prototype; proto = Class.prototype = o_create(this.prototype); proto.constructor = Class; generateGuid(proto); meta(proto).proto = proto; // this will disable observers on prototype Class.ClassMixin.apply(Class); return Class; }, /** Equivalent to doing `extend(arguments).create()`. If possible use the normal `create` method instead. @method createWithMixins @static @param [arguments]* */ createWithMixins: function() { var C = this; if (arguments.length>0) { this._initMixins(arguments); } return new C(); }, /** Creates an instance of a class. Accepts either no arguments, or an object containing values to initialize the newly instantiated object with. ```javascript App.Person = Ember.Object.extend({ helloWorld: function() { alert("Hi, my name is " + this.get('name')); } }); var tom = App.Person.create({ name: 'Tom Dale' }); tom.helloWorld(); // alerts "Hi, my name is Tom Dale". ``` `create` will call the `init` function if defined during `Ember.AnyObject.extend` If no arguments are passed to `create`, it will not set values to the new instance during initialization: ```javascript var noName = App.Person.create(); noName.helloWorld(); // alerts undefined ``` NOTE: For performance reasons, you cannot declare methods or computed properties during `create`. You should instead declare methods and computed properties when using `extend` or use the `createWithMixins` shorthand. @method create @static @param [arguments]* */ create: function() { var C = this; if (arguments.length>0) { this._initProperties(arguments); } return new C(); }, /** Augments a constructor's prototype with additional properties and functions: ```javascript MyObject = Ember.Object.extend({ name: 'an object' }); o = MyObject.create(); o.get('name'); // 'an object' MyObject.reopen({ say: function(msg){ console.log(msg); } }) o2 = MyObject.create(); o2.say("hello"); // logs "hello" o.say("goodbye"); // logs "goodbye" ``` To add functions and properties to the constructor itself, see `reopenClass` @method reopen */ reopen: function() { this.willReopen(); reopen.apply(this.PrototypeMixin, arguments); return this; }, /** Augments a constructor's own properties and functions: ```javascript MyObject = Ember.Object.extend({ name: 'an object' }); MyObject.reopenClass({ canBuild: false }); MyObject.canBuild; // false o = MyObject.create(); ``` In other words, this creates static properties and functions for the class. These are only available on the class and not on any instance of that class. ```javascript App.Person = Ember.Object.extend({ name : "", sayHello : function(){ alert("Hello. My name is " + this.get('name')); } }); App.Person.reopenClass({ species : "Homo sapiens", createPerson: function(newPersonsName){ return App.Person.create({ name:newPersonsName }); } }); var tom = App.Person.create({ name : "Tom Dale" }); var yehuda = App.Person.createPerson("Yehuda Katz"); tom.sayHello(); // "Hello. My name is Tom Dale" yehuda.sayHello(); // "Hello. My name is Yehuda Katz" alert(App.Person.species); // "Homo sapiens" ``` Note that `species` and `createPerson` are *not* valid on the `tom` and `yehuda` variables. They are only valid on `App.Person`. To add functions and properties to instances of a constructor by extending the constructor's prototype see `reopen` @method reopenClass */ reopenClass: function() { reopen.apply(this.ClassMixin, arguments); applyMixin(this, arguments, false); return this; }, detect: function(obj) { if ('function' !== typeof obj) { return false; } while(obj) { if (obj===this) { return true; } obj = obj.superclass; } return false; }, detectInstance: function(obj) { return obj instanceof this; }, /** In some cases, you may want to annotate computed properties with additional metadata about how they function or what values they operate on. For example, computed property functions may close over variables that are then no longer available for introspection. You can pass a hash of these values to a computed property like this: ```javascript person: function() { var personId = this.get('personId'); return App.Person.create({ id: personId }); }.property().meta({ type: App.Person }) ``` Once you've done this, you can retrieve the values saved to the computed property from your class like this: ```javascript MyClass.metaForProperty('person'); ``` This will return the original hash that was passed to `meta()`. @method metaForProperty @param key {String} property name */ metaForProperty: function(key) { var meta = this.proto()[META_KEY], desc = meta && meta.descs[key]; return desc._meta || {}; }, /** Iterate over each computed property for the class, passing its name and any associated metadata (see `metaForProperty`) to the callback. @method eachComputedProperty @param {Function} callback @param {Object} binding */ eachComputedProperty: function(callback, binding) { var proto = this.proto(), descs = meta(proto).descs, empty = {}, property; for (var name in descs) { property = descs[name]; if (property instanceof Ember.ComputedProperty) { callback.call(binding || this, name, property._meta || empty); } } } }); ClassMixin.ownerConstructor = CoreObject; if (Ember.config.overrideClassMixin) { Ember.config.overrideClassMixin(ClassMixin); } CoreObject.ClassMixin = ClassMixin; ClassMixin.apply(CoreObject); Ember.CoreObject = CoreObject; })(); (function() { /** @module ember @submodule ember-runtime */ /** `Ember.Object` is the main base class for all Ember objects. It is a subclass of `Ember.CoreObject` with the `Ember.Observable` mixin applied. For details, see the documentation for each of these. @class Object @namespace Ember @extends Ember.CoreObject @uses Ember.Observable */ Ember.Object = Ember.CoreObject.extend(Ember.Observable); Ember.Object.toString = function() { return "Ember.Object"; }; })(); (function() { /** @module ember @submodule ember-runtime */ var get = Ember.get, indexOf = Ember.ArrayPolyfills.indexOf; /** A Namespace is an object usually used to contain other objects or methods such as an application or framework. Create a namespace anytime you want to define one of these new containers. # Example Usage ```javascript MyFramework = Ember.Namespace.create({ VERSION: '1.0.0' }); ``` @class Namespace @namespace Ember @extends Ember.Object */ var Namespace = Ember.Namespace = Ember.Object.extend({ isNamespace: true, init: function() { Ember.Namespace.NAMESPACES.push(this); Ember.Namespace.PROCESSED = false; }, toString: function() { var name = get(this, 'name'); if (name) { return name; } findNamespaces(); return this[Ember.GUID_KEY+'_name']; }, nameClasses: function() { processNamespace([this.toString()], this, {}); }, destroy: function() { var namespaces = Ember.Namespace.NAMESPACES; Ember.lookup[this.toString()] = undefined; namespaces.splice(indexOf.call(namespaces, this), 1); this._super(); } }); Namespace.reopenClass({ NAMESPACES: [Ember], NAMESPACES_BY_ID: {}, PROCESSED: false, processAll: processAllNamespaces, byName: function(name) { if (!Ember.BOOTED) { processAllNamespaces(); } return NAMESPACES_BY_ID[name]; } }); var NAMESPACES_BY_ID = Namespace.NAMESPACES_BY_ID; var hasOwnProp = ({}).hasOwnProperty, guidFor = Ember.guidFor; function processNamespace(paths, root, seen) { var idx = paths.length; NAMESPACES_BY_ID[paths.join('.')] = root; // Loop over all of the keys in the namespace, looking for classes for(var key in root) { if (!hasOwnProp.call(root, key)) { continue; } var obj = root[key]; // If we are processing the `Ember` namespace, for example, the // `paths` will start with `["Ember"]`. Every iteration through // the loop will update the **second** element of this list with // the key, so processing `Ember.View` will make the Array // `['Ember', 'View']`. paths[idx] = key; // If we have found an unprocessed class if (obj && obj.toString === classToString) { // Replace the class' `toString` with the dot-separated path // and set its `NAME_KEY` obj.toString = makeToString(paths.join('.')); obj[NAME_KEY] = paths.join('.'); // Support nested namespaces } else if (obj && obj.isNamespace) { // Skip aliased namespaces if (seen[guidFor(obj)]) { continue; } seen[guidFor(obj)] = true; // Process the child namespace processNamespace(paths, obj, seen); } } paths.length = idx; // cut out last item } function findNamespaces() { var Namespace = Ember.Namespace, lookup = Ember.lookup, obj, isNamespace; if (Namespace.PROCESSED) { return; } for (var prop in lookup) { // These don't raise exceptions but can cause warnings if (prop === "parent" || prop === "top" || prop === "frameElement" || prop === "webkitStorageInfo") { continue; } // get(window.globalStorage, 'isNamespace') would try to read the storage for domain isNamespace and cause exception in Firefox. // globalStorage is a storage obsoleted by the WhatWG storage specification. See https://developer.mozilla.org/en/DOM/Storage#globalStorage if (prop === "globalStorage" && lookup.StorageList && lookup.globalStorage instanceof lookup.StorageList) { continue; } // Unfortunately, some versions of IE don't support window.hasOwnProperty if (lookup.hasOwnProperty && !lookup.hasOwnProperty(prop)) { continue; } // At times we are not allowed to access certain properties for security reasons. // There are also times where even if we can access them, we are not allowed to access their properties. try { obj = Ember.lookup[prop]; isNamespace = obj && obj.isNamespace; } catch (e) { continue; } if (isNamespace) { obj[NAME_KEY] = prop; } } } var NAME_KEY = Ember.NAME_KEY = Ember.GUID_KEY + '_name'; function superClassString(mixin) { var superclass = mixin.superclass; if (superclass) { if (superclass[NAME_KEY]) { return superclass[NAME_KEY]; } else { return superClassString(superclass); } } else { return; } } function classToString() { if (!Ember.BOOTED && !this[NAME_KEY]) { processAllNamespaces(); } var ret; if (this[NAME_KEY]) { ret = this[NAME_KEY]; } else if (this._toString) { ret = this._toString; } else { var str = superClassString(this); if (str) { ret = "(subclass of " + str + ")"; } else { ret = "(unknown mixin)"; } this.toString = makeToString(ret); } return ret; } function processAllNamespaces() { var unprocessedNamespaces = !Namespace.PROCESSED, unprocessedMixins = Ember.anyUnprocessedMixins; if (unprocessedNamespaces) { findNamespaces(); Namespace.PROCESSED = true; } if (unprocessedNamespaces || unprocessedMixins) { var namespaces = Namespace.NAMESPACES, namespace; for (var i=0, l=namespaces.length; i1) args = a_slice.call(arguments, 1); this.forEach(function(x, idx) { var method = x && x[methodName]; if ('function' === typeof method) { ret[idx] = args ? method.apply(x, args) : x[methodName](); } }, this); return ret; }, /** Simply converts the enumerable into a genuine array. The order is not guaranteed. Corresponds to the method implemented by Prototype. @method toArray @return {Array} the enumerable as an array. */ toArray: function() { var ret = Ember.A(); this.forEach(function(o, idx) { ret[idx] = o; }); return ret ; }, /** Returns a copy of the array with all null and undefined elements removed. ```javascript var arr = ["a", null, "c", undefined]; arr.compact(); // ["a", "c"] ``` @method compact @return {Array} the array without null and undefined elements. */ compact: function() { return this.filter(function(value) { return value != null; }); }, /** Returns a new enumerable that excludes the passed value. The default implementation returns an array regardless of the receiver type unless the receiver does not contain the value. ```javascript var arr = ["a", "b", "a", "c"]; arr.without("a"); // ["b", "c"] ``` @method without @param {Object} value @return {Ember.Enumerable} */ without: function(value) { if (!this.contains(value)) return this; // nothing to do var ret = Ember.A(); this.forEach(function(k) { if (k !== value) ret[ret.length] = k; }) ; return ret ; }, /** Returns a new enumerable that contains only unique values. The default implementation returns an array regardless of the receiver type. ```javascript var arr = ["a", "a", "b", "b"]; arr.uniq(); // ["a", "b"] ``` @method uniq @return {Ember.Enumerable} */ uniq: function() { var ret = Ember.A(); this.forEach(function(k) { if (a_indexOf(ret, k)<0) ret.push(k); }); return ret; }, /** This property will trigger anytime the enumerable's content changes. You can observe this property to be notified of changes to the enumerables content. For plain enumerables, this property is read only. `Ember.Array` overrides this method. @property [] @type Ember.Array @return this */ '[]': Ember.computed(function(key, value) { return this; }), // .......................................................... // ENUMERABLE OBSERVERS // /** Registers an enumerable observer. Must implement `Ember.EnumerableObserver` mixin. @method addEnumerableObserver @param {Object} target @param {Hash} [opts] @return this */ addEnumerableObserver: function(target, opts) { var willChange = (opts && opts.willChange) || 'enumerableWillChange', didChange = (opts && opts.didChange) || 'enumerableDidChange'; var hasObservers = get(this, 'hasEnumerableObservers'); if (!hasObservers) Ember.propertyWillChange(this, 'hasEnumerableObservers'); Ember.addListener(this, '@enumerable:before', target, willChange); Ember.addListener(this, '@enumerable:change', target, didChange); if (!hasObservers) Ember.propertyDidChange(this, 'hasEnumerableObservers'); return this; }, /** Removes a registered enumerable observer. @method removeEnumerableObserver @param {Object} target @param {Hash} [opts] @return this */ removeEnumerableObserver: function(target, opts) { var willChange = (opts && opts.willChange) || 'enumerableWillChange', didChange = (opts && opts.didChange) || 'enumerableDidChange'; var hasObservers = get(this, 'hasEnumerableObservers'); if (hasObservers) Ember.propertyWillChange(this, 'hasEnumerableObservers'); Ember.removeListener(this, '@enumerable:before', target, willChange); Ember.removeListener(this, '@enumerable:change', target, didChange); if (hasObservers) Ember.propertyDidChange(this, 'hasEnumerableObservers'); return this; }, /** Becomes true whenever the array currently has observers watching changes on the array. @property hasEnumerableObservers @type Boolean */ hasEnumerableObservers: Ember.computed(function() { return Ember.hasListeners(this, '@enumerable:change') || Ember.hasListeners(this, '@enumerable:before'); }), /** Invoke this method just before the contents of your enumerable will change. You can either omit the parameters completely or pass the objects to be removed or added if available or just a count. @method enumerableContentWillChange @param {Ember.Enumerable|Number} removing An enumerable of the objects to be removed or the number of items to be removed. @param {Ember.Enumerable|Number} adding An enumerable of the objects to be added or the number of items to be added. @chainable */ enumerableContentWillChange: function(removing, adding) { var removeCnt, addCnt, hasDelta; if ('number' === typeof removing) removeCnt = removing; else if (removing) removeCnt = get(removing, 'length'); else removeCnt = removing = -1; if ('number' === typeof adding) addCnt = adding; else if (adding) addCnt = get(adding,'length'); else addCnt = adding = -1; hasDelta = addCnt<0 || removeCnt<0 || addCnt-removeCnt!==0; if (removing === -1) removing = null; if (adding === -1) adding = null; Ember.propertyWillChange(this, '[]'); if (hasDelta) Ember.propertyWillChange(this, 'length'); Ember.sendEvent(this, '@enumerable:before', [this, removing, adding]); return this; }, /** Invoke this method when the contents of your enumerable has changed. This will notify any observers watching for content changes. If your are implementing an ordered enumerable (such as an array), also pass the start and end values where the content changed so that it can be used to notify range observers. @method enumerableContentDidChange @param {Ember.Enumerable|Number} removing An enumerable of the objects to be removed or the number of items to be removed. @param {Ember.Enumerable|Number} adding An enumerable of the objects to be added or the number of items to be added. @chainable */ enumerableContentDidChange: function(removing, adding) { var removeCnt, addCnt, hasDelta; if ('number' === typeof removing) removeCnt = removing; else if (removing) removeCnt = get(removing, 'length'); else removeCnt = removing = -1; if ('number' === typeof adding) addCnt = adding; else if (adding) addCnt = get(adding, 'length'); else addCnt = adding = -1; hasDelta = addCnt<0 || removeCnt<0 || addCnt-removeCnt!==0; if (removing === -1) removing = null; if (adding === -1) adding = null; Ember.sendEvent(this, '@enumerable:change', [this, removing, adding]); if (hasDelta) Ember.propertyDidChange(this, 'length'); Ember.propertyDidChange(this, '[]'); return this ; }, /** Converts the enumerable into an array and sorts by the keys specified in the argument. You may provide multiple arguments to sort by multiple properties. @method sortBy @param {String} property name(s) to sort on @return {Array} The sorted array. */ sortBy: function() { var sortKeys = arguments; return this.toArray().sort(function(a, b){ for(var i = 0; i < sortKeys.length; i++) { var key = sortKeys[i], propA = get(a, key), propB = get(b, key); // return 1 or -1 else continue to the next sortKey var compareValue = Ember.compare(propA, propB); if (compareValue) { return compareValue; } } return 0; }); } }); })(); (function() { /** @module ember @submodule ember-runtime */ // .......................................................... // HELPERS // var get = Ember.get, set = Ember.set, isNone = Ember.isNone, map = Ember.EnumerableUtils.map, cacheFor = Ember.cacheFor; // .......................................................... // ARRAY // /** This module implements Observer-friendly Array-like behavior. This mixin is picked up by the Array class as well as other controllers, etc. that want to appear to be arrays. Unlike `Ember.Enumerable,` this mixin defines methods specifically for collections that provide index-ordered access to their contents. When you are designing code that needs to accept any kind of Array-like object, you should use these methods instead of Array primitives because these will properly notify observers of changes to the array. Although these methods are efficient, they do add a layer of indirection to your application so it is a good idea to use them only when you need the flexibility of using both true JavaScript arrays and "virtual" arrays such as controllers and collections. You can use the methods defined in this module to access and modify array contents in a KVO-friendly way. You can also be notified whenever the membership of an array changes by changing the syntax of the property to `.observes('*myProperty.[]')`. To support `Ember.Array` in your own class, you must override two primitives to use it: `replace()` and `objectAt()`. Note that the Ember.Array mixin also incorporates the `Ember.Enumerable` mixin. All `Ember.Array`-like objects are also enumerable. @class Array @namespace Ember @uses Ember.Enumerable @since Ember 0.9.0 */ Ember.Array = Ember.Mixin.create(Ember.Enumerable, { /** Your array must support the `length` property. Your replace methods should set this property whenever it changes. @property {Number} length */ length: Ember.required(), /** Returns the object at the given `index`. If the given `index` is negative or is greater or equal than the array length, returns `undefined`. This is one of the primitives you must implement to support `Ember.Array`. If your object supports retrieving the value of an array item using `get()` (i.e. `myArray.get(0)`), then you do not need to implement this method yourself. ```javascript var arr = ['a', 'b', 'c', 'd']; arr.objectAt(0); // "a" arr.objectAt(3); // "d" arr.objectAt(-1); // undefined arr.objectAt(4); // undefined arr.objectAt(5); // undefined ``` @method objectAt @param {Number} idx The index of the item to return. @return {*} item at index or undefined */ objectAt: function(idx) { if ((idx < 0) || (idx>=get(this, 'length'))) return undefined ; return get(this, idx); }, /** This returns the objects at the specified indexes, using `objectAt`. ```javascript var arr = ['a', 'b', 'c', 'd']; arr.objectsAt([0, 1, 2]); // ["a", "b", "c"] arr.objectsAt([2, 3, 4]); // ["c", "d", undefined] ``` @method objectsAt @param {Array} indexes An array of indexes of items to return. @return {Array} */ objectsAt: function(indexes) { var self = this; return map(indexes, function(idx) { return self.objectAt(idx); }); }, // overrides Ember.Enumerable version nextObject: function(idx) { return this.objectAt(idx); }, /** This is the handler for the special array content property. If you get this property, it will return this. If you set this property it a new array, it will replace the current content. This property overrides the default property defined in `Ember.Enumerable`. @property [] @return this */ '[]': Ember.computed(function(key, value) { if (value !== undefined) this.replace(0, get(this, 'length'), value) ; return this ; }), firstObject: Ember.computed(function() { return this.objectAt(0); }), lastObject: Ember.computed(function() { return this.objectAt(get(this, 'length')-1); }), // optimized version from Enumerable contains: function(obj) { return this.indexOf(obj) >= 0; }, // Add any extra methods to Ember.Array that are native to the built-in Array. /** Returns a new array that is a slice of the receiver. This implementation uses the observable array methods to retrieve the objects for the new slice. ```javascript var arr = ['red', 'green', 'blue']; arr.slice(0); // ['red', 'green', 'blue'] arr.slice(0, 2); // ['red', 'green'] arr.slice(1, 100); // ['green', 'blue'] ``` @method slice @param {Integer} beginIndex (Optional) index to begin slicing from. @param {Integer} endIndex (Optional) index to end the slice at (but not included). @return {Array} New array with specified slice */ slice: function(beginIndex, endIndex) { var ret = Ember.A(); var length = get(this, 'length') ; if (isNone(beginIndex)) beginIndex = 0 ; if (isNone(endIndex) || (endIndex > length)) endIndex = length ; if (beginIndex < 0) beginIndex = length + beginIndex; if (endIndex < 0) endIndex = length + endIndex; while(beginIndex < endIndex) { ret[ret.length] = this.objectAt(beginIndex++) ; } return ret ; }, /** Returns the index of the given object's first occurrence. If no `startAt` argument is given, the starting location to search is 0. If it's negative, will count backward from the end of the array. Returns -1 if no match is found. ```javascript var arr = ["a", "b", "c", "d", "a"]; arr.indexOf("a"); // 0 arr.indexOf("z"); // -1 arr.indexOf("a", 2); // 4 arr.indexOf("a", -1); // 4 arr.indexOf("b", 3); // -1 arr.indexOf("a", 100); // -1 ``` @method indexOf @param {Object} object the item to search for @param {Number} startAt optional starting location to search, default 0 @return {Number} index or -1 if not found */ indexOf: function(object, startAt) { var idx, len = get(this, 'length'); if (startAt === undefined) startAt = 0; if (startAt < 0) startAt += len; for(idx=startAt;idx= len) startAt = len-1; if (startAt < 0) startAt += len; for(idx=startAt;idx>=0;idx--) { if (this.objectAt(idx) === object) return idx ; } return -1; }, // .......................................................... // ARRAY OBSERVERS // /** Adds an array observer to the receiving array. The array observer object normally must implement two methods: * `arrayWillChange(observedObj, start, removeCount, addCount)` - This method will be called just before the array is modified. * `arrayDidChange(observedObj, start, removeCount, addCount)` - This method will be called just after the array is modified. Both callbacks will be passed the observed object, starting index of the change as well a a count of the items to be removed and added. You can use these callbacks to optionally inspect the array during the change, clear caches, or do any other bookkeeping necessary. In addition to passing a target, you can also include an options hash which you can use to override the method names that will be invoked on the target. @method addArrayObserver @param {Object} target The observer object. @param {Hash} opts Optional hash of configuration options including `willChange` and `didChange` option. @return {Ember.Array} receiver */ addArrayObserver: function(target, opts) { var willChange = (opts && opts.willChange) || 'arrayWillChange', didChange = (opts && opts.didChange) || 'arrayDidChange'; var hasObservers = get(this, 'hasArrayObservers'); if (!hasObservers) Ember.propertyWillChange(this, 'hasArrayObservers'); Ember.addListener(this, '@array:before', target, willChange); Ember.addListener(this, '@array:change', target, didChange); if (!hasObservers) Ember.propertyDidChange(this, 'hasArrayObservers'); return this; }, /** Removes an array observer from the object if the observer is current registered. Calling this method multiple times with the same object will have no effect. @method removeArrayObserver @param {Object} target The object observing the array. @param {Hash} opts Optional hash of configuration options including `willChange` and `didChange` option. @return {Ember.Array} receiver */ removeArrayObserver: function(target, opts) { var willChange = (opts && opts.willChange) || 'arrayWillChange', didChange = (opts && opts.didChange) || 'arrayDidChange'; var hasObservers = get(this, 'hasArrayObservers'); if (hasObservers) Ember.propertyWillChange(this, 'hasArrayObservers'); Ember.removeListener(this, '@array:before', target, willChange); Ember.removeListener(this, '@array:change', target, didChange); if (hasObservers) Ember.propertyDidChange(this, 'hasArrayObservers'); return this; }, /** Becomes true whenever the array currently has observers watching changes on the array. @property {Boolean} hasArrayObservers */ hasArrayObservers: Ember.computed(function() { return Ember.hasListeners(this, '@array:change') || Ember.hasListeners(this, '@array:before'); }), /** If you are implementing an object that supports `Ember.Array`, call this method just before the array content changes to notify any observers and invalidate any related properties. Pass the starting index of the change as well as a delta of the amounts to change. @method arrayContentWillChange @param {Number} startIdx The starting index in the array that will change. @param {Number} removeAmt The number of items that will be removed. If you pass `null` assumes 0 @param {Number} addAmt The number of items that will be added. If you pass `null` assumes 0. @return {Ember.Array} receiver */ arrayContentWillChange: function(startIdx, removeAmt, addAmt) { // if no args are passed assume everything changes if (startIdx===undefined) { startIdx = 0; removeAmt = addAmt = -1; } else { if (removeAmt === undefined) removeAmt=-1; if (addAmt === undefined) addAmt=-1; } // Make sure the @each proxy is set up if anyone is observing @each if (Ember.isWatching(this, '@each')) { get(this, '@each'); } Ember.sendEvent(this, '@array:before', [this, startIdx, removeAmt, addAmt]); var removing, lim; if (startIdx>=0 && removeAmt>=0 && get(this, 'hasEnumerableObservers')) { removing = []; lim = startIdx+removeAmt; for(var idx=startIdx;idx=0 && addAmt>=0 && get(this, 'hasEnumerableObservers')) { adding = []; lim = startIdx+addAmt; for(var idx=startIdx;idx Ember.TrackedArray instances. We use // this to lazily recompute indexes for item property observers. this.trackedArraysByGuid = {}; // We suspend observers to ignore replacements from `reset` when totally // recomputing. Unfortunately we cannot properly suspend the observers // because we only have the key; instead we make the observers no-ops this.suspended = false; // This is used to coalesce item changes from property observers. this.changedItems = {}; } function ItemPropertyObserverContext (dependentArray, index, trackedArray) { this.dependentArray = dependentArray; this.index = index; this.item = dependentArray.objectAt(index); this.trackedArray = trackedArray; this.beforeObserver = null; this.observer = null; this.destroyed = false; } DependentArraysObserver.prototype = { setValue: function (newValue) { this.instanceMeta.setValue(newValue, true); }, getValue: function () { return this.instanceMeta.getValue(); }, setupObservers: function (dependentArray, dependentKey) { this.dependentKeysByGuid[guidFor(dependentArray)] = dependentKey; dependentArray.addArrayObserver(this, { willChange: 'dependentArrayWillChange', didChange: 'dependentArrayDidChange' }); if (this.cp._itemPropertyKeys[dependentKey]) { this.setupPropertyObservers(dependentKey, this.cp._itemPropertyKeys[dependentKey]); } }, teardownObservers: function (dependentArray, dependentKey) { var itemPropertyKeys = this.cp._itemPropertyKeys[dependentKey] || []; delete this.dependentKeysByGuid[guidFor(dependentArray)]; this.teardownPropertyObservers(dependentKey, itemPropertyKeys); dependentArray.removeArrayObserver(this, { willChange: 'dependentArrayWillChange', didChange: 'dependentArrayDidChange' }); }, suspendArrayObservers: function (callback, binding) { var oldSuspended = this.suspended; this.suspended = true; callback.call(binding); this.suspended = oldSuspended; }, setupPropertyObservers: function (dependentKey, itemPropertyKeys) { var dependentArray = get(this.instanceMeta.context, dependentKey), length = get(dependentArray, 'length'), observerContexts = new Array(length); this.resetTransformations(dependentKey, observerContexts); forEach(dependentArray, function (item, index) { var observerContext = this.createPropertyObserverContext(dependentArray, index, this.trackedArraysByGuid[dependentKey]); observerContexts[index] = observerContext; forEach(itemPropertyKeys, function (propertyKey) { addBeforeObserver(item, propertyKey, this, observerContext.beforeObserver); addObserver(item, propertyKey, this, observerContext.observer); }, this); }, this); }, teardownPropertyObservers: function (dependentKey, itemPropertyKeys) { var dependentArrayObserver = this, trackedArray = this.trackedArraysByGuid[dependentKey], beforeObserver, observer, item; if (!trackedArray) { return; } trackedArray.apply(function (observerContexts, offset, operation) { if (operation === Ember.TrackedArray.DELETE) { return; } forEach(observerContexts, function (observerContext) { observerContext.destroyed = true; beforeObserver = observerContext.beforeObserver; observer = observerContext.observer; item = observerContext.item; forEach(itemPropertyKeys, function (propertyKey) { removeBeforeObserver(item, propertyKey, dependentArrayObserver, beforeObserver); removeObserver(item, propertyKey, dependentArrayObserver, observer); }); }); }); }, createPropertyObserverContext: function (dependentArray, index, trackedArray) { var observerContext = new ItemPropertyObserverContext(dependentArray, index, trackedArray); this.createPropertyObserver(observerContext); return observerContext; }, createPropertyObserver: function (observerContext) { var dependentArrayObserver = this; observerContext.beforeObserver = function (obj, keyName) { return dependentArrayObserver.itemPropertyWillChange(obj, keyName, observerContext.dependentArray, observerContext); }; observerContext.observer = function (obj, keyName) { return dependentArrayObserver.itemPropertyDidChange(obj, keyName, observerContext.dependentArray, observerContext); }; }, resetTransformations: function (dependentKey, observerContexts) { this.trackedArraysByGuid[dependentKey] = new Ember.TrackedArray(observerContexts); }, trackAdd: function (dependentKey, index, newItems) { var trackedArray = this.trackedArraysByGuid[dependentKey]; if (trackedArray) { trackedArray.addItems(index, newItems); } }, trackRemove: function (dependentKey, index, removedCount) { var trackedArray = this.trackedArraysByGuid[dependentKey]; if (trackedArray) { return trackedArray.removeItems(index, removedCount); } return []; }, updateIndexes: function (trackedArray, array) { var length = get(array, 'length'); // OPTIMIZE: we could stop updating once we hit the object whose observer // fired; ie partially apply the transformations trackedArray.apply(function (observerContexts, offset, operation) { // we don't even have observer contexts for removed items, even if we did, // they no longer have any index in the array if (operation === Ember.TrackedArray.DELETE) { return; } if (operation === Ember.TrackedArray.RETAIN && observerContexts.length === length && offset === 0) { // If we update many items we don't want to walk the array each time: we // only need to update the indexes at most once per run loop. return; } forEach(observerContexts, function (context, index) { context.index = index + offset; }); }); }, dependentArrayWillChange: function (dependentArray, index, removedCount, addedCount) { if (this.suspended) { return; } var removedItem = this.callbacks.removedItem, changeMeta, guid = guidFor(dependentArray), dependentKey = this.dependentKeysByGuid[guid], itemPropertyKeys = this.cp._itemPropertyKeys[dependentKey] || [], length = get(dependentArray, 'length'), normalizedIndex = normalizeIndex(index, length, 0), normalizedRemoveCount = normalizeRemoveCount(normalizedIndex, length, removedCount), item, itemIndex, sliceIndex, observerContexts; observerContexts = this.trackRemove(dependentKey, normalizedIndex, normalizedRemoveCount); function removeObservers(propertyKey) { observerContexts[sliceIndex].destroyed = true; removeBeforeObserver(item, propertyKey, this, observerContexts[sliceIndex].beforeObserver); removeObserver(item, propertyKey, this, observerContexts[sliceIndex].observer); } for (sliceIndex = normalizedRemoveCount - 1; sliceIndex >= 0; --sliceIndex) { itemIndex = normalizedIndex + sliceIndex; if (itemIndex >= length) { break; } item = dependentArray.objectAt(itemIndex); forEach(itemPropertyKeys, removeObservers, this); changeMeta = createChangeMeta(dependentArray, item, itemIndex, this.instanceMeta.propertyName, this.cp); this.setValue( removedItem.call( this.instanceMeta.context, this.getValue(), item, changeMeta, this.instanceMeta.sugarMeta)); } }, dependentArrayDidChange: function (dependentArray, index, removedCount, addedCount) { if (this.suspended) { return; } var addedItem = this.callbacks.addedItem, guid = guidFor(dependentArray), dependentKey = this.dependentKeysByGuid[guid], observerContexts = new Array(addedCount), itemPropertyKeys = this.cp._itemPropertyKeys[dependentKey], length = get(dependentArray, 'length'), normalizedIndex = normalizeIndex(index, length, addedCount), changeMeta, observerContext; forEach(dependentArray.slice(normalizedIndex, normalizedIndex + addedCount), function (item, sliceIndex) { if (itemPropertyKeys) { observerContext = observerContexts[sliceIndex] = this.createPropertyObserverContext(dependentArray, normalizedIndex + sliceIndex, this.trackedArraysByGuid[dependentKey]); forEach(itemPropertyKeys, function (propertyKey) { addBeforeObserver(item, propertyKey, this, observerContext.beforeObserver); addObserver(item, propertyKey, this, observerContext.observer); }, this); } changeMeta = createChangeMeta(dependentArray, item, normalizedIndex + sliceIndex, this.instanceMeta.propertyName, this.cp); this.setValue( addedItem.call( this.instanceMeta.context, this.getValue(), item, changeMeta, this.instanceMeta.sugarMeta)); }, this); this.trackAdd(dependentKey, normalizedIndex, observerContexts); }, itemPropertyWillChange: function (obj, keyName, array, observerContext) { var guid = guidFor(obj); if (!this.changedItems[guid]) { this.changedItems[guid] = { array: array, observerContext: observerContext, obj: obj, previousValues: {} }; } this.changedItems[guid].previousValues[keyName] = get(obj, keyName); }, itemPropertyDidChange: function(obj, keyName, array, observerContext) { this.flushChanges(); }, flushChanges: function() { var changedItems = this.changedItems, key, c, changeMeta; for (key in changedItems) { c = changedItems[key]; if (c.observerContext.destroyed) { continue; } this.updateIndexes(c.observerContext.trackedArray, c.observerContext.dependentArray); changeMeta = createChangeMeta(c.array, c.obj, c.observerContext.index, this.instanceMeta.propertyName, this.cp, c.previousValues); this.setValue( this.callbacks.removedItem.call(this.instanceMeta.context, this.getValue(), c.obj, changeMeta, this.instanceMeta.sugarMeta)); this.setValue( this.callbacks.addedItem.call(this.instanceMeta.context, this.getValue(), c.obj, changeMeta, this.instanceMeta.sugarMeta)); } this.changedItems = {}; } }; function normalizeIndex(index, length, newItemsOffset) { if (index < 0) { return Math.max(0, length + index); } else if (index < length) { return index; } else /* index > length */ { return Math.min(length - newItemsOffset, index); } } function normalizeRemoveCount(index, length, removedCount) { return Math.min(removedCount, length - index); } function createChangeMeta(dependentArray, item, index, propertyName, property, previousValues) { var meta = { arrayChanged: dependentArray, index: index, item: item, propertyName: propertyName, property: property }; if (previousValues) { // previous values only available for item property changes meta.previousValues = previousValues; } return meta; } function addItems (dependentArray, callbacks, cp, propertyName, meta) { forEach(dependentArray, function (item, index) { meta.setValue( callbacks.addedItem.call( this, meta.getValue(), item, createChangeMeta(dependentArray, item, index, propertyName, cp), meta.sugarMeta)); }, this); } function reset(cp, propertyName) { var callbacks = cp._callbacks(), meta; if (cp._hasInstanceMeta(this, propertyName)) { meta = cp._instanceMeta(this, propertyName); meta.setValue(cp.resetValue(meta.getValue())); } else { meta = cp._instanceMeta(this, propertyName); } if (cp.options.initialize) { cp.options.initialize.call(this, meta.getValue(), { property: cp, propertyName: propertyName }, meta.sugarMeta); } } function partiallyRecomputeFor(obj, dependentKey) { if (arrayBracketPattern.test(dependentKey)) { return false; } var value = get(obj, dependentKey); return Ember.Array.detect(value); } function ReduceComputedPropertyInstanceMeta(context, propertyName, initialValue) { this.context = context; this.propertyName = propertyName; this.cache = metaFor(context).cache; this.dependentArrays = {}; this.sugarMeta = {}; this.initialValue = initialValue; } ReduceComputedPropertyInstanceMeta.prototype = { getValue: function () { if (this.propertyName in this.cache) { return this.cache[this.propertyName]; } else { return this.initialValue; } }, setValue: function(newValue, triggerObservers) { // This lets sugars force a recomputation, handy for very simple // implementations of eg max. if (newValue !== undefined) { var fireObservers = triggerObservers && (newValue !== this.cache[this.propertyName]); if (fireObservers) { propertyWillChange(this.context, this.propertyName); } this.cache[this.propertyName] = newValue; if (fireObservers) { propertyDidChange(this.context, this.propertyName); } } else { delete this.cache[this.propertyName]; } } }; /** A computed property whose dependent keys are arrays and which is updated with "one at a time" semantics. @class ReduceComputedProperty @namespace Ember @extends Ember.ComputedProperty @constructor */ function ReduceComputedProperty(options) { var cp = this; this.options = options; this._instanceMetas = {}; this._dependentKeys = null; // A map of dependentKey -> [itemProperty, ...] that tracks what properties of // items in the array we must track to update this property. this._itemPropertyKeys = {}; this._previousItemPropertyKeys = {}; this.readOnly(); this.cacheable(); this.recomputeOnce = function(propertyName) { // What we really want to do is coalesce by . // We need a form of `scheduleOnce` that accepts an arbitrary token to // coalesce by, in addition to the target and method. Ember.run.once(this, recompute, propertyName); }; var recompute = function(propertyName) { var dependentKeys = cp._dependentKeys, meta = cp._instanceMeta(this, propertyName), callbacks = cp._callbacks(); reset.call(this, cp, propertyName); meta.dependentArraysObserver.suspendArrayObservers(function () { forEach(cp._dependentKeys, function (dependentKey) { if (!partiallyRecomputeFor(this, dependentKey)) { return; } var dependentArray = get(this, dependentKey), previousDependentArray = meta.dependentArrays[dependentKey]; if (dependentArray === previousDependentArray) { // The array may be the same, but our item property keys may have // changed, so we set them up again. We can't easily tell if they've // changed: the array may be the same object, but with different // contents. if (cp._previousItemPropertyKeys[dependentKey]) { delete cp._previousItemPropertyKeys[dependentKey]; meta.dependentArraysObserver.setupPropertyObservers(dependentKey, cp._itemPropertyKeys[dependentKey]); } } else { meta.dependentArrays[dependentKey] = dependentArray; if (previousDependentArray) { meta.dependentArraysObserver.teardownObservers(previousDependentArray, dependentKey); } if (dependentArray) { meta.dependentArraysObserver.setupObservers(dependentArray, dependentKey); } } }, this); }, this); forEach(cp._dependentKeys, function(dependentKey) { if (!partiallyRecomputeFor(this, dependentKey)) { return; } var dependentArray = get(this, dependentKey); if (dependentArray) { addItems.call(this, dependentArray, callbacks, cp, propertyName, meta); } }, this); }; this.func = function (propertyName) { recompute.call(this, propertyName); return cp._instanceMeta(this, propertyName).getValue(); }; } Ember.ReduceComputedProperty = ReduceComputedProperty; ReduceComputedProperty.prototype = o_create(ComputedProperty.prototype); function defaultCallback(computedValue) { return computedValue; } ReduceComputedProperty.prototype._callbacks = function () { if (!this.callbacks) { var options = this.options; this.callbacks = { removedItem: options.removedItem || defaultCallback, addedItem: options.addedItem || defaultCallback }; } return this.callbacks; }; ReduceComputedProperty.prototype._hasInstanceMeta = function (context, propertyName) { var guid = guidFor(context), key = guid + ':' + propertyName; return !!this._instanceMetas[key]; }; ReduceComputedProperty.prototype._instanceMeta = function (context, propertyName) { var guid = guidFor(context), key = guid + ':' + propertyName, meta = this._instanceMetas[key]; if (!meta) { meta = this._instanceMetas[key] = new ReduceComputedPropertyInstanceMeta(context, propertyName, this.initialValue()); meta.dependentArraysObserver = new DependentArraysObserver(this._callbacks(), this, meta, context, propertyName, meta.sugarMeta); } return meta; }; ReduceComputedProperty.prototype.initialValue = function () { if (typeof this.options.initialValue === 'function') { return this.options.initialValue(); } else { return this.options.initialValue; } }; ReduceComputedProperty.prototype.resetValue = function (value) { return this.initialValue(); }; ReduceComputedProperty.prototype.itemPropertyKey = function (dependentArrayKey, itemPropertyKey) { this._itemPropertyKeys[dependentArrayKey] = this._itemPropertyKeys[dependentArrayKey] || []; this._itemPropertyKeys[dependentArrayKey].push(itemPropertyKey); }; ReduceComputedProperty.prototype.clearItemPropertyKeys = function (dependentArrayKey) { if (this._itemPropertyKeys[dependentArrayKey]) { this._previousItemPropertyKeys[dependentArrayKey] = this._itemPropertyKeys[dependentArrayKey]; this._itemPropertyKeys[dependentArrayKey] = []; } }; ReduceComputedProperty.prototype.property = function () { var cp = this, args = a_slice.call(arguments), propertyArgs = new Ember.Set(), match, dependentArrayKey, itemPropertyKey; forEach(a_slice.call(arguments), function (dependentKey) { if (doubleEachPropertyPattern.test(dependentKey)) { throw new Ember.Error("Nested @each properties not supported: " + dependentKey); } else if (match = eachPropertyPattern.exec(dependentKey)) { dependentArrayKey = match[1]; var itemPropertyKeyPattern = match[2], addItemPropertyKey = function (itemPropertyKey) { cp.itemPropertyKey(dependentArrayKey, itemPropertyKey); }; expandProperties(itemPropertyKeyPattern, addItemPropertyKey); propertyArgs.add(dependentArrayKey); } else { propertyArgs.add(dependentKey); } }); return ComputedProperty.prototype.property.apply(this, propertyArgs.toArray()); }; /** Creates a computed property which operates on dependent arrays and is updated with "one at a time" semantics. When items are added or removed from the dependent array(s) a reduce computed only operates on the change instead of re-evaluating the entire array. If there are more than one arguments the first arguments are considered to be dependent property keys. The last argument is required to be an options object. The options object can have the following four properties: `initialValue` - A value or function that will be used as the initial value for the computed. If this property is a function the result of calling the function will be used as the initial value. This property is required. `initialize` - An optional initialize function. Typically this will be used to set up state on the instanceMeta object. `removedItem` - A function that is called each time an element is removed from the array. `addedItem` - A function that is called each time an element is added to the array. The `initialize` function has the following signature: ```javascript function (initialValue, changeMeta, instanceMeta) ``` `initialValue` - The value of the `initialValue` property from the options object. `changeMeta` - An object which contains meta information about the computed. It contains the following properties: - `property` the computed property - `propertyName` the name of the property on the object `instanceMeta` - An object that can be used to store meta information needed for calculating your computed. For example a unique computed might use this to store the number of times a given element is found in the dependent array. The `removedItem` and `addedItem` functions both have the following signature: ```javascript function (accumulatedValue, item, changeMeta, instanceMeta) ``` `accumulatedValue` - The value returned from the last time `removedItem` or `addedItem` was called or `initialValue`. `item` - the element added or removed from the array `changeMeta` - An object which contains meta information about the change. It contains the following properties: - `property` the computed property - `propertyName` the name of the property on the object - `index` the index of the added or removed item - `item` the added or removed item: this is exactly the same as the second arg - `arrayChanged` the array that triggered the change. Can be useful when depending on multiple arrays. For property changes triggered on an item property change (when depKey is something like `someArray.@each.someProperty`), `changeMeta` will also contain the following property: - `previousValues` an object whose keys are the properties that changed on the item, and whose values are the item's previous values. `previousValues` is important Ember coalesces item property changes via Ember.run.once. This means that by the time removedItem gets called, item has the new values, but you may need the previous value (eg for sorting & filtering). `instanceMeta` - An object that can be used to store meta information needed for calculating your computed. For example a unique computed might use this to store the number of times a given element is found in the dependent array. The `removedItem` and `addedItem` functions should return the accumulated value. It is acceptable to not return anything (ie return undefined) to invalidate the computation. This is generally not a good idea for arrayComputed but it's used in eg max and min. Note that observers will be fired if either of these functions return a value that differs from the accumulated value. When returning an object that mutates in response to array changes, for example an array that maps everything from some other array (see `Ember.computed.map`), it is usually important that the *same* array be returned to avoid accidentally triggering observers. Example ```javascript Ember.computed.max = function (dependentKey) { return Ember.reduceComputed(dependentKey, { initialValue: -Infinity, addedItem: function (accumulatedValue, item, changeMeta, instanceMeta) { return Math.max(accumulatedValue, item); }, removedItem: function (accumulatedValue, item, changeMeta, instanceMeta) { if (item < accumulatedValue) { return accumulatedValue; } } }); }; ``` Dependent keys may refer to `@this` to observe changes to the object itself, which must be array-like, rather than a property of the object. This is mostly useful for array proxies, to ensure objects are retrieved via `objectAtContent`. This is how you could sort items by properties defined on an item controller. Example ```javascript App.PeopleController = Ember.ArrayController.extend({ itemController: 'person', sortedPeople: Ember.computed.sort('@this.@each.reversedName', function(personA, personB) { // `reversedName` isn't defined on Person, but we have access to it via // the item controller App.PersonController. If we'd used // `content.@each.reversedName` above, we would be getting the objects // directly and not have access to `reversedName`. // var reversedNameA = get(personA, 'reversedName'), reversedNameB = get(personB, 'reversedName'); return Ember.compare(reversedNameA, reversedNameB); }) }); App.PersonController = Ember.ObjectController.extend({ reversedName: function () { return reverse(get(this, 'name')); }.property('name') }) ``` Dependent keys whose values are not arrays are treated as regular dependencies: when they change, the computed property is completely recalculated. It is sometimes useful to have dependent arrays with similar semantics. Dependent keys which end in `.[]` do not use "one at a time" semantics. When an item is added or removed from such a dependency, the computed property is completely recomputed. Example ```javascript Ember.Object.extend({ // When `string` is changed, `computed` is completely recomputed. string: 'a string', // When an item is added to `array`, `addedItem` is called. array: [], // When an item is added to `anotherArray`, `computed` is completely // recomputed. anotherArray: [], computed: Ember.reduceComputed('string', 'array', 'anotherArray.[]', { addedItem: addedItemCallback, removedItem: removedItemCallback }) }); ``` @method reduceComputed @for Ember @param {String} [dependentKeys*] @param {Object} options @return {Ember.ComputedProperty} */ Ember.reduceComputed = function (options) { var args; if (arguments.length > 1) { args = a_slice.call(arguments, 0, -1); options = a_slice.call(arguments, -1)[0]; } if (typeof options !== "object") { throw new Ember.Error("Reduce Computed Property declared without an options hash"); } if (!('initialValue' in options)) { throw new Ember.Error("Reduce Computed Property declared without an initial value"); } var cp = new ReduceComputedProperty(options); if (args) { cp.property.apply(cp, args); } return cp; }; })(); (function() { var ReduceComputedProperty = Ember.ReduceComputedProperty, a_slice = [].slice, o_create = Ember.create, forEach = Ember.EnumerableUtils.forEach; function ArrayComputedProperty() { var cp = this; ReduceComputedProperty.apply(this, arguments); this.func = (function(reduceFunc) { return function (propertyName) { if (!cp._hasInstanceMeta(this, propertyName)) { // When we recompute an array computed property, we need already // retrieved arrays to be updated; we can't simply empty the cache and // hope the array is re-retrieved. forEach(cp._dependentKeys, function(dependentKey) { Ember.addObserver(this, dependentKey, function() { cp.recomputeOnce.call(this, propertyName); }); }, this); } return reduceFunc.apply(this, arguments); }; })(this.func); return this; } Ember.ArrayComputedProperty = ArrayComputedProperty; ArrayComputedProperty.prototype = o_create(ReduceComputedProperty.prototype); ArrayComputedProperty.prototype.initialValue = function () { return Ember.A(); }; ArrayComputedProperty.prototype.resetValue = function (array) { array.clear(); return array; }; // This is a stopgap to keep the reference counts correct with lazy CPs. ArrayComputedProperty.prototype.didChange = function (obj, keyName) { return; }; /** Creates a computed property which operates on dependent arrays and is updated with "one at a time" semantics. When items are added or removed from the dependent array(s) an array computed only operates on the change instead of re-evaluating the entire array. This should return an array, if you'd like to use "one at a time" semantics and compute some value other then an array look at `Ember.reduceComputed`. If there are more than one arguments the first arguments are considered to be dependent property keys. The last argument is required to be an options object. The options object can have the following three properties. `initialize` - An optional initialize function. Typically this will be used to set up state on the instanceMeta object. `removedItem` - A function that is called each time an element is removed from the array. `addedItem` - A function that is called each time an element is added to the array. The `initialize` function has the following signature: ```javascript function (array, changeMeta, instanceMeta) ``` `array` - The initial value of the arrayComputed, an empty array. `changeMeta` - An object which contains meta information about the computed. It contains the following properties: - `property` the computed property - `propertyName` the name of the property on the object `instanceMeta` - An object that can be used to store meta information needed for calculating your computed. For example a unique computed might use this to store the number of times a given element is found in the dependent array. The `removedItem` and `addedItem` functions both have the following signature: ```javascript function (accumulatedValue, item, changeMeta, instanceMeta) ``` `accumulatedValue` - The value returned from the last time `removedItem` or `addedItem` was called or an empty array. `item` - the element added or removed from the array `changeMeta` - An object which contains meta information about the change. It contains the following properties: - `property` the computed property - `propertyName` the name of the property on the object - `index` the index of the added or removed item - `item` the added or removed item: this is exactly the same as the second arg - `arrayChanged` the array that triggered the change. Can be useful when depending on multiple arrays. For property changes triggered on an item property change (when depKey is something like `someArray.@each.someProperty`), `changeMeta` will also contain the following property: - `previousValues` an object whose keys are the properties that changed on the item, and whose values are the item's previous values. `previousValues` is important Ember coalesces item property changes via Ember.run.once. This means that by the time removedItem gets called, item has the new values, but you may need the previous value (eg for sorting & filtering). `instanceMeta` - An object that can be used to store meta information needed for calculating your computed. For example a unique computed might use this to store the number of times a given element is found in the dependent array. The `removedItem` and `addedItem` functions should return the accumulated value. It is acceptable to not return anything (ie return undefined) to invalidate the computation. This is generally not a good idea for arrayComputed but it's used in eg max and min. Example ```javascript Ember.computed.map = function(dependentKey, callback) { var options = { addedItem: function(array, item, changeMeta, instanceMeta) { var mapped = callback(item); array.insertAt(changeMeta.index, mapped); return array; }, removedItem: function(array, item, changeMeta, instanceMeta) { array.removeAt(changeMeta.index, 1); return array; } }; return Ember.arrayComputed(dependentKey, options); }; ``` @method arrayComputed @for Ember @param {String} [dependentKeys*] @param {Object} options @return {Ember.ComputedProperty} */ Ember.arrayComputed = function (options) { var args; if (arguments.length > 1) { args = a_slice.call(arguments, 0, -1); options = a_slice.call(arguments, -1)[0]; } if (typeof options !== "object") { throw new Ember.Error("Array Computed Property declared without an options hash"); } var cp = new ArrayComputedProperty(options); if (args) { cp.property.apply(cp, args); } return cp; }; })(); (function() { /** @module ember @submodule ember-runtime */ var get = Ember.get, set = Ember.set, guidFor = Ember.guidFor, merge = Ember.merge, a_slice = [].slice, forEach = Ember.EnumerableUtils.forEach, map = Ember.EnumerableUtils.map, SearchProxy; /** A computed property that returns the sum of the value in the dependent array. @method computed.sum @for Ember @param {String} dependentKey @return {Ember.ComputedProperty} computes the sum of all values in the dependentKey's array */ Ember.computed.sum = function(dependentKey){ return Ember.reduceComputed(dependentKey, { initialValue: 0, addedItem: function(accumulatedValue, item, changeMeta, instanceMeta){ return accumulatedValue + item; }, removedItem: function(accumulatedValue, item, changeMeta, instanceMeta){ return accumulatedValue - item; } }); }; /** A computed property that calculates the maximum value in the dependent array. This will return `-Infinity` when the dependent array is empty. ```javascript App.Person = Ember.Object.extend({ childAges: Ember.computed.mapBy('children', 'age'), maxChildAge: Ember.computed.max('childAges') }); var lordByron = App.Person.create({children: []}); lordByron.get('maxChildAge'); // -Infinity lordByron.get('children').pushObject({ name: 'Augusta Ada Byron', age: 7 }); lordByron.get('maxChildAge'); // 7 lordByron.get('children').pushObjects([{ name: 'Allegra Byron', age: 5 }, { name: 'Elizabeth Medora Leigh', age: 8 }]); lordByron.get('maxChildAge'); // 8 ``` @method computed.max @for Ember @param {String} dependentKey @return {Ember.ComputedProperty} computes the largest value in the dependentKey's array */ Ember.computed.max = function (dependentKey) { return Ember.reduceComputed(dependentKey, { initialValue: -Infinity, addedItem: function (accumulatedValue, item, changeMeta, instanceMeta) { return Math.max(accumulatedValue, item); }, removedItem: function (accumulatedValue, item, changeMeta, instanceMeta) { if (item < accumulatedValue) { return accumulatedValue; } } }); }; /** A computed property that calculates the minimum value in the dependent array. This will return `Infinity` when the dependent array is empty. ```javascript App.Person = Ember.Object.extend({ childAges: Ember.computed.mapBy('children', 'age'), minChildAge: Ember.computed.min('childAges') }); var lordByron = App.Person.create({children: []}); lordByron.get('minChildAge'); // Infinity lordByron.get('children').pushObject({ name: 'Augusta Ada Byron', age: 7 }); lordByron.get('minChildAge'); // 7 lordByron.get('children').pushObjects([{ name: 'Allegra Byron', age: 5 }, { name: 'Elizabeth Medora Leigh', age: 8 }]); lordByron.get('minChildAge'); // 5 ``` @method computed.min @for Ember @param {String} dependentKey @return {Ember.ComputedProperty} computes the smallest value in the dependentKey's array */ Ember.computed.min = function (dependentKey) { return Ember.reduceComputed(dependentKey, { initialValue: Infinity, addedItem: function (accumulatedValue, item, changeMeta, instanceMeta) { return Math.min(accumulatedValue, item); }, removedItem: function (accumulatedValue, item, changeMeta, instanceMeta) { if (item > accumulatedValue) { return accumulatedValue; } } }); }; /** Returns an array mapped via the callback The callback method you provide should have the following signature. `item` is the current item in the iteration. ```javascript function(item); ``` Example ```javascript App.Hamster = Ember.Object.extend({ excitingChores: Ember.computed.map('chores', function(chore) { return chore.toUpperCase() + '!'; }) }); var hamster = App.Hamster.create({ chores: ['clean', 'write more unit tests'] }); hamster.get('excitingChores'); // ['CLEAN!', 'WRITE MORE UNIT TESTS!'] ``` @method computed.map @for Ember @param {String} dependentKey @param {Function} callback @return {Ember.ComputedProperty} an array mapped via the callback */ Ember.computed.map = function(dependentKey, callback) { var options = { addedItem: function(array, item, changeMeta, instanceMeta) { var mapped = callback.call(this, item); array.insertAt(changeMeta.index, mapped); return array; }, removedItem: function(array, item, changeMeta, instanceMeta) { array.removeAt(changeMeta.index, 1); return array; } }; return Ember.arrayComputed(dependentKey, options); }; /** Returns an array mapped to the specified key. ```javascript App.Person = Ember.Object.extend({ childAges: Ember.computed.mapBy('children', 'age') }); var lordByron = App.Person.create({children: []}); lordByron.get('childAges'); // [] lordByron.get('children').pushObject({name: 'Augusta Ada Byron', age: 7}); lordByron.get('childAges'); // [7] lordByron.get('children').pushObjects([{ name: 'Allegra Byron', age: 5 }, { name: 'Elizabeth Medora Leigh', age: 8 }]); lordByron.get('childAges'); // [7, 5, 8] ``` @method computed.mapBy @for Ember @param {String} dependentKey @param {String} propertyKey @return {Ember.ComputedProperty} an array mapped to the specified key */ Ember.computed.mapBy = function(dependentKey, propertyKey) { var callback = function(item) { return get(item, propertyKey); }; return Ember.computed.map(dependentKey + '.@each.' + propertyKey, callback); }; /** @method computed.mapProperty @for Ember @deprecated Use `Ember.computed.mapBy` instead @param dependentKey @param propertyKey */ Ember.computed.mapProperty = Ember.computed.mapBy; /** Filters the array by the callback. The callback method you provide should have the following signature. `item` is the current item in the iteration. ```javascript function(item); ``` ```javascript App.Hamster = Ember.Object.extend({ remainingChores: Ember.computed.filter('chores', function(chore) { return !chore.done; }) }); var hamster = App.Hamster.create({chores: [ {name: 'cook', done: true}, {name: 'clean', done: true}, {name: 'write more unit tests', done: false} ]}); hamster.get('remainingChores'); // [{name: 'write more unit tests', done: false}] ``` @method computed.filter @for Ember @param {String} dependentKey @param {Function} callback @return {Ember.ComputedProperty} the filtered array */ Ember.computed.filter = function(dependentKey, callback) { var options = { initialize: function (array, changeMeta, instanceMeta) { instanceMeta.filteredArrayIndexes = new Ember.SubArray(); }, addedItem: function(array, item, changeMeta, instanceMeta) { var match = !!callback.call(this, item), filterIndex = instanceMeta.filteredArrayIndexes.addItem(changeMeta.index, match); if (match) { array.insertAt(filterIndex, item); } return array; }, removedItem: function(array, item, changeMeta, instanceMeta) { var filterIndex = instanceMeta.filteredArrayIndexes.removeItem(changeMeta.index); if (filterIndex > -1) { array.removeAt(filterIndex); } return array; } }; return Ember.arrayComputed(dependentKey, options); }; /** Filters the array by the property and value ```javascript App.Hamster = Ember.Object.extend({ remainingChores: Ember.computed.filterBy('chores', 'done', false) }); var hamster = App.Hamster.create({chores: [ {name: 'cook', done: true}, {name: 'clean', done: true}, {name: 'write more unit tests', done: false} ]}); hamster.get('remainingChores'); // [{name: 'write more unit tests', done: false}] ``` @method computed.filterBy @for Ember @param {String} dependentKey @param {String} propertyKey @param {String} value @return {Ember.ComputedProperty} the filtered array */ Ember.computed.filterBy = function(dependentKey, propertyKey, value) { var callback; if (arguments.length === 2) { callback = function(item) { return get(item, propertyKey); }; } else { callback = function(item) { return get(item, propertyKey) === value; }; } return Ember.computed.filter(dependentKey + '.@each.' + propertyKey, callback); }; /** @method computed.filterProperty @for Ember @param dependentKey @param propertyKey @param value @deprecated Use `Ember.computed.filterBy` instead */ Ember.computed.filterProperty = Ember.computed.filterBy; /** A computed property which returns a new array with all the unique elements from one or more dependent arrays. Example ```javascript App.Hamster = Ember.Object.extend({ uniqueFruits: Ember.computed.uniq('fruits') }); var hamster = App.Hamster.create({fruits: [ 'banana', 'grape', 'kale', 'banana' ]}); hamster.get('uniqueFruits'); // ['banana', 'grape', 'kale'] ``` @method computed.uniq @for Ember @param {String} propertyKey* @return {Ember.ComputedProperty} computes a new array with all the unique elements from the dependent array */ Ember.computed.uniq = function() { var args = a_slice.call(arguments); args.push({ initialize: function(array, changeMeta, instanceMeta) { instanceMeta.itemCounts = {}; }, addedItem: function(array, item, changeMeta, instanceMeta) { var guid = guidFor(item); if (!instanceMeta.itemCounts[guid]) { instanceMeta.itemCounts[guid] = 1; } else { ++instanceMeta.itemCounts[guid]; } array.addObject(item); return array; }, removedItem: function(array, item, _, instanceMeta) { var guid = guidFor(item), itemCounts = instanceMeta.itemCounts; if (--itemCounts[guid] === 0) { array.removeObject(item); } return array; } }); return Ember.arrayComputed.apply(null, args); }; /** Alias for [Ember.computed.uniq](/api/#method_computed_uniq). @method computed.union @for Ember @param {String} propertyKey* @return {Ember.ComputedProperty} computes a new array with all the unique elements from the dependent array */ Ember.computed.union = Ember.computed.uniq; /** A computed property which returns a new array with all the duplicated elements from two or more dependent arrays. Example ```javascript var obj = Ember.Object.createWithMixins({ adaFriends: ['Charles Babbage', 'John Hobhouse', 'William King', 'Mary Somerville'], charlesFriends: ['William King', 'Mary Somerville', 'Ada Lovelace', 'George Peacock'], friendsInCommon: Ember.computed.intersect('adaFriends', 'charlesFriends') }); obj.get('friendsInCommon'); // ['William King', 'Mary Somerville'] ``` @method computed.intersect @for Ember @param {String} propertyKey* @return {Ember.ComputedProperty} computes a new array with all the duplicated elements from the dependent arrays */ Ember.computed.intersect = function () { var getDependentKeyGuids = function (changeMeta) { return map(changeMeta.property._dependentKeys, function (dependentKey) { return guidFor(dependentKey); }); }; var args = a_slice.call(arguments); args.push({ initialize: function (array, changeMeta, instanceMeta) { instanceMeta.itemCounts = {}; }, addedItem: function(array, item, changeMeta, instanceMeta) { var itemGuid = guidFor(item), dependentGuids = getDependentKeyGuids(changeMeta), dependentGuid = guidFor(changeMeta.arrayChanged), numberOfDependentArrays = changeMeta.property._dependentKeys.length, itemCounts = instanceMeta.itemCounts; if (!itemCounts[itemGuid]) { itemCounts[itemGuid] = {}; } if (itemCounts[itemGuid][dependentGuid] === undefined) { itemCounts[itemGuid][dependentGuid] = 0; } if (++itemCounts[itemGuid][dependentGuid] === 1 && numberOfDependentArrays === Ember.keys(itemCounts[itemGuid]).length) { array.addObject(item); } return array; }, removedItem: function(array, item, changeMeta, instanceMeta) { var itemGuid = guidFor(item), dependentGuids = getDependentKeyGuids(changeMeta), dependentGuid = guidFor(changeMeta.arrayChanged), numberOfDependentArrays = changeMeta.property._dependentKeys.length, numberOfArraysItemAppearsIn, itemCounts = instanceMeta.itemCounts; if (itemCounts[itemGuid][dependentGuid] === undefined) { itemCounts[itemGuid][dependentGuid] = 0; } if (--itemCounts[itemGuid][dependentGuid] === 0) { delete itemCounts[itemGuid][dependentGuid]; numberOfArraysItemAppearsIn = Ember.keys(itemCounts[itemGuid]).length; if (numberOfArraysItemAppearsIn === 0) { delete itemCounts[itemGuid]; } array.removeObject(item); } return array; } }); return Ember.arrayComputed.apply(null, args); }; /** A computed property which returns a new array with all the properties from the first dependent array that are not in the second dependent array. Example ```javascript App.Hamster = Ember.Object.extend({ likes: ['banana', 'grape', 'kale'], wants: Ember.computed.setDiff('likes', 'fruits') }); var hamster = App.Hamster.create({fruits: [ 'grape', 'kale', ]}); hamster.get('wants'); // ['banana'] ``` @method computed.setDiff @for Ember @param {String} setAProperty @param {String} setBProperty @return {Ember.ComputedProperty} computes a new array with all the items from the first dependent array that are not in the second dependent array */ Ember.computed.setDiff = function (setAProperty, setBProperty) { if (arguments.length !== 2) { throw new Ember.Error("setDiff requires exactly two dependent arrays."); } return Ember.arrayComputed(setAProperty, setBProperty, { addedItem: function (array, item, changeMeta, instanceMeta) { var setA = get(this, setAProperty), setB = get(this, setBProperty); if (changeMeta.arrayChanged === setA) { if (!setB.contains(item)) { array.addObject(item); } } else { array.removeObject(item); } return array; }, removedItem: function (array, item, changeMeta, instanceMeta) { var setA = get(this, setAProperty), setB = get(this, setBProperty); if (changeMeta.arrayChanged === setB) { if (setA.contains(item)) { array.addObject(item); } } else { array.removeObject(item); } return array; } }); }; function binarySearch(array, item, low, high) { var mid, midItem, res, guidMid, guidItem; if (arguments.length < 4) { high = get(array, 'length'); } if (arguments.length < 3) { low = 0; } if (low === high) { return low; } mid = low + Math.floor((high - low) / 2); midItem = array.objectAt(mid); guidMid = _guidFor(midItem); guidItem = _guidFor(item); if (guidMid === guidItem) { return mid; } res = this.order(midItem, item); if (res === 0) { res = guidMid < guidItem ? -1 : 1; } if (res < 0) { return this.binarySearch(array, item, mid+1, high); } else if (res > 0) { return this.binarySearch(array, item, low, mid); } return mid; function _guidFor(item) { if (SearchProxy.detectInstance(item)) { return guidFor(get(item, 'content')); } return guidFor(item); } } SearchProxy = Ember.ObjectProxy.extend(); /** A computed property which returns a new array with all the properties from the first dependent array sorted based on a property or sort function. The callback method you provide should have the following signature: ```javascript function(itemA, itemB); ``` - `itemA` the first item to compare. - `itemB` the second item to compare. This function should return `-1` when `itemA` should come before `itemB`. It should return `1` when `itemA` should come after `itemB`. If the `itemA` and `itemB` are equal this function should return `0`. Example ```javascript var ToDoList = Ember.Object.extend({ todosSorting: ['name'], sortedTodos: Ember.computed.sort('todos', 'todosSorting'), priorityTodos: Ember.computed.sort('todos', function(a, b){ if (a.priority > b.priority) { return 1; } else if (a.priority < b.priority) { return -1; } return 0; }), }); var todoList = ToDoList.create({todos: [ {name: 'Unit Test', priority: 2}, {name: 'Documentation', priority: 3}, {name: 'Release', priority: 1} ]}); todoList.get('sortedTodos'); // [{name:'Documentation', priority:3}, {name:'Release', priority:1}, {name:'Unit Test', priority:2}] todoList.get('priorityTodos'); // [{name:'Release', priority:1}, {name:'Unit Test', priority:2}, {name:'Documentation', priority:3}] ``` @method computed.sort @for Ember @param {String} dependentKey @param {String or Function} sortDefinition a dependent key to an array of sort properties or a function to use when sorting @return {Ember.ComputedProperty} computes a new sorted array based on the sort property array or callback function */ Ember.computed.sort = function (itemsKey, sortDefinition) { var initFn, sortPropertiesKey; if (typeof sortDefinition === 'function') { initFn = function (array, changeMeta, instanceMeta) { instanceMeta.order = sortDefinition; instanceMeta.binarySearch = binarySearch; }; } else { sortPropertiesKey = sortDefinition; initFn = function (array, changeMeta, instanceMeta) { function setupSortProperties() { var sortPropertyDefinitions = get(this, sortPropertiesKey), sortProperty, sortProperties = instanceMeta.sortProperties = [], sortPropertyAscending = instanceMeta.sortPropertyAscending = {}, idx, asc; changeMeta.property.clearItemPropertyKeys(itemsKey); forEach(sortPropertyDefinitions, function (sortPropertyDefinition) { if ((idx = sortPropertyDefinition.indexOf(':')) !== -1) { sortProperty = sortPropertyDefinition.substring(0, idx); asc = sortPropertyDefinition.substring(idx+1).toLowerCase() !== 'desc'; } else { sortProperty = sortPropertyDefinition; asc = true; } sortProperties.push(sortProperty); sortPropertyAscending[sortProperty] = asc; changeMeta.property.itemPropertyKey(itemsKey, sortProperty); }); sortPropertyDefinitions.addObserver('@each', this, updateSortPropertiesOnce); } function updateSortPropertiesOnce() { Ember.run.once(this, updateSortProperties, changeMeta.propertyName); } function updateSortProperties(propertyName) { setupSortProperties.call(this); changeMeta.property.recomputeOnce.call(this, propertyName); } Ember.addObserver(this, sortPropertiesKey, updateSortPropertiesOnce); setupSortProperties.call(this); instanceMeta.order = function (itemA, itemB) { var sortProperty, result, asc; for (var i = 0; i < this.sortProperties.length; ++i) { sortProperty = this.sortProperties[i]; result = Ember.compare(get(itemA, sortProperty), get(itemB, sortProperty)); if (result !== 0) { asc = this.sortPropertyAscending[sortProperty]; return asc ? result : (-1 * result); } } return 0; }; instanceMeta.binarySearch = binarySearch; }; } return Ember.arrayComputed(itemsKey, { initialize: initFn, addedItem: function (array, item, changeMeta, instanceMeta) { var index = instanceMeta.binarySearch(array, item); array.insertAt(index, item); return array; }, removedItem: function (array, item, changeMeta, instanceMeta) { var proxyProperties, index, searchItem; if (changeMeta.previousValues) { proxyProperties = merge({ content: item }, changeMeta.previousValues); searchItem = SearchProxy.create(proxyProperties); } else { searchItem = item; } index = instanceMeta.binarySearch(array, searchItem); array.removeAt(index); return array; } }); }; })(); (function() { Ember.RSVP = requireModule('rsvp'); Ember.RSVP.onerrorDefault = function(error) { if (error instanceof Error) { if (Ember.testing) { if (Ember.Test && Ember.Test.adapter) { Ember.Test.adapter.exception(error); } else { throw error; } } else { Ember.Logger.error(error.stack); } } }; Ember.RSVP.on('error', Ember.RSVP.onerrorDefault); })(); (function() { /** @module ember @submodule ember-runtime */ var a_slice = Array.prototype.slice; var expandProperties = Ember.expandProperties; if (Ember.EXTEND_PROTOTYPES === true || Ember.EXTEND_PROTOTYPES.Function) { /** The `property` extension of Javascript's Function prototype is available when `Ember.EXTEND_PROTOTYPES` or `Ember.EXTEND_PROTOTYPES.Function` is `true`, which is the default. Computed properties allow you to treat a function like a property: ```javascript MyApp.President = Ember.Object.extend({ firstName: '', lastName: '', fullName: function() { return this.get('firstName') + ' ' + this.get('lastName'); // Call this flag to mark the function as a property }.property() }); var president = MyApp.President.create({ firstName: "Barack", lastName: "Obama" }); president.get('fullName'); // "Barack Obama" ``` Treating a function like a property is useful because they can work with bindings, just like any other property. Many computed properties have dependencies on other properties. For example, in the above example, the `fullName` property depends on `firstName` and `lastName` to determine its value. You can tell Ember about these dependencies like this: ```javascript MyApp.President = Ember.Object.extend({ firstName: '', lastName: '', fullName: function() { return this.get('firstName') + ' ' + this.get('lastName'); // Tell Ember.js that this computed property depends on firstName // and lastName }.property('firstName', 'lastName') }); ``` Make sure you list these dependencies so Ember knows when to update bindings that connect to a computed property. Changing a dependency will not immediately trigger an update of the computed property, but will instead clear the cache so that it is updated when the next `get` is called on the property. See [Ember.ComputedProperty](/api/classes/Ember.ComputedProperty.html), [Ember.computed](/api/#method_computed). @method property @for Function */ Function.prototype.property = function() { var ret = Ember.computed(this); // ComputedProperty.prototype.property expands properties; no need for us to // do so here. return ret.property.apply(ret, arguments); }; /** The `observes` extension of Javascript's Function prototype is available when `Ember.EXTEND_PROTOTYPES` or `Ember.EXTEND_PROTOTYPES.Function` is true, which is the default. You can observe property changes simply by adding the `observes` call to the end of your method declarations in classes that you write. For example: ```javascript Ember.Object.extend({ valueObserver: function() { // Executes whenever the "value" property changes }.observes('value') }); ``` In the future this method may become asynchronous. If you want to ensure synchronous behavior, use `observesImmediately`. See `Ember.observer`. @method observes @for Function */ Function.prototype.observes = function() { var addWatchedProperty = function (obs) { watched.push(obs); }; var watched = []; for (var i=0; i b` Default implementation raises an exception. @method compare @param a {Object} the first object to compare @param b {Object} the second object to compare @return {Integer} the result of the comparison */ compare: Ember.required(Function) }); })(); (function() { /** @module ember @submodule ember-runtime */ var get = Ember.get, set = Ember.set; /** Implements some standard methods for copying an object. Add this mixin to any object you create that can create a copy of itself. This mixin is added automatically to the built-in array. You should generally implement the `copy()` method to return a copy of the receiver. Note that `frozenCopy()` will only work if you also implement `Ember.Freezable`. @class Copyable @namespace Ember @since Ember 0.9 */ Ember.Copyable = Ember.Mixin.create({ /** Override to return a copy of the receiver. Default implementation raises an exception. @method copy @param {Boolean} deep if `true`, a deep copy of the object should be made @return {Object} copy of receiver */ copy: Ember.required(Function), /** If the object implements `Ember.Freezable`, then this will return a new copy if the object is not frozen and the receiver if the object is frozen. Raises an exception if you try to call this method on a object that does not support freezing. You should use this method whenever you want a copy of a freezable object since a freezable object can simply return itself without actually consuming more memory. @method frozenCopy @return {Object} copy of receiver or receiver */ frozenCopy: function() { if (Ember.Freezable && Ember.Freezable.detect(this)) { return get(this, 'isFrozen') ? this : this.copy().freeze(); } else { throw new Ember.Error(Ember.String.fmt("%@ does not support freezing", [this])); } } }); })(); (function() { /** @module ember @submodule ember-runtime */ var get = Ember.get, set = Ember.set; /** The `Ember.Freezable` mixin implements some basic methods for marking an object as frozen. Once an object is frozen it should be read only. No changes may be made the internal state of the object. ## Enforcement To fully support freezing in your subclass, you must include this mixin and override any method that might alter any property on the object to instead raise an exception. You can check the state of an object by checking the `isFrozen` property. Although future versions of JavaScript may support language-level freezing object objects, that is not the case today. Even if an object is freezable, it is still technically possible to modify the object, even though it could break other parts of your application that do not expect a frozen object to change. It is, therefore, very important that you always respect the `isFrozen` property on all freezable objects. ## Example Usage The example below shows a simple object that implement the `Ember.Freezable` protocol. ```javascript Contact = Ember.Object.extend(Ember.Freezable, { firstName: null, lastName: null, // swaps the names swapNames: function() { if (this.get('isFrozen')) throw Ember.FROZEN_ERROR; var tmp = this.get('firstName'); this.set('firstName', this.get('lastName')); this.set('lastName', tmp); return this; } }); c = Contact.create({ firstName: "John", lastName: "Doe" }); c.swapNames(); // returns c c.freeze(); c.swapNames(); // EXCEPTION ``` ## Copying Usually the `Ember.Freezable` protocol is implemented in cooperation with the `Ember.Copyable` protocol, which defines a `frozenCopy()` method that will return a frozen object, if the object implements this method as well. @class Freezable @namespace Ember @since Ember 0.9 */ Ember.Freezable = Ember.Mixin.create({ /** Set to `true` when the object is frozen. Use this property to detect whether your object is frozen or not. @property isFrozen @type Boolean */ isFrozen: false, /** Freezes the object. Once this method has been called the object should no longer allow any properties to be edited. @method freeze @return {Object} receiver */ freeze: function() { if (get(this, 'isFrozen')) return this; set(this, 'isFrozen', true); return this; } }); Ember.FROZEN_ERROR = "Frozen object cannot be modified."; })(); (function() { /** @module ember @submodule ember-runtime */ var forEach = Ember.EnumerableUtils.forEach; /** This mixin defines the API for modifying generic enumerables. These methods can be applied to an object regardless of whether it is ordered or unordered. Note that an Enumerable can change even if it does not implement this mixin. For example, a MappedEnumerable cannot be directly modified but if its underlying enumerable changes, it will change also. ## Adding Objects To add an object to an enumerable, use the `addObject()` method. This method will only add the object to the enumerable if the object is not already present and is of a type supported by the enumerable. ```javascript set.addObject(contact); ``` ## Removing Objects To remove an object from an enumerable, use the `removeObject()` method. This will only remove the object if it is present in the enumerable, otherwise this method has no effect. ```javascript set.removeObject(contact); ``` ## Implementing In Your Own Code If you are implementing an object and want to support this API, just include this mixin in your class and implement the required methods. In your unit tests, be sure to apply the Ember.MutableEnumerableTests to your object. @class MutableEnumerable @namespace Ember @uses Ember.Enumerable */ Ember.MutableEnumerable = Ember.Mixin.create(Ember.Enumerable, { /** __Required.__ You must implement this method to apply this mixin. Attempts to add the passed object to the receiver if the object is not already present in the collection. If the object is present, this method has no effect. If the passed object is of a type not supported by the receiver, then this method should raise an exception. @method addObject @param {Object} object The object to add to the enumerable. @return {Object} the passed object */ addObject: Ember.required(Function), /** Adds each object in the passed enumerable to the receiver. @method addObjects @param {Ember.Enumerable} objects the objects to add. @return {Object} receiver */ addObjects: function(objects) { Ember.beginPropertyChanges(this); forEach(objects, function(obj) { this.addObject(obj); }, this); Ember.endPropertyChanges(this); return this; }, /** __Required.__ You must implement this method to apply this mixin. Attempts to remove the passed object from the receiver collection if the object is present in the collection. If the object is not present, this method has no effect. If the passed object is of a type not supported by the receiver, then this method should raise an exception. @method removeObject @param {Object} object The object to remove from the enumerable. @return {Object} the passed object */ removeObject: Ember.required(Function), /** Removes each object in the passed enumerable from the receiver. @method removeObjects @param {Ember.Enumerable} objects the objects to remove @return {Object} receiver */ removeObjects: function(objects) { Ember.beginPropertyChanges(this); forEach(objects, function(obj) { this.removeObject(obj); }, this); Ember.endPropertyChanges(this); return this; } }); })(); (function() { /** @module ember @submodule ember-runtime */ // .......................................................... // CONSTANTS // var OUT_OF_RANGE_EXCEPTION = "Index out of range" ; var EMPTY = []; // .......................................................... // HELPERS // var get = Ember.get, set = Ember.set; /** This mixin defines the API for modifying array-like objects. These methods can be applied only to a collection that keeps its items in an ordered set. Note that an Array can change even if it does not implement this mixin. For example, one might implement a SparseArray that cannot be directly modified, but if its underlying enumerable changes, it will change also. @class MutableArray @namespace Ember @uses Ember.Array @uses Ember.MutableEnumerable */ Ember.MutableArray = Ember.Mixin.create(Ember.Array, Ember.MutableEnumerable, { /** __Required.__ You must implement this method to apply this mixin. This is one of the primitives you must implement to support `Ember.Array`. You should replace amt objects started at idx with the objects in the passed array. You should also call `this.enumerableContentDidChange()` @method replace @param {Number} idx Starting index in the array to replace. If idx >= length, then append to the end of the array. @param {Number} amt Number of elements that should be removed from the array, starting at *idx*. @param {Array} objects An array of zero or more objects that should be inserted into the array at *idx* */ replace: Ember.required(), /** Remove all elements from self. This is useful if you want to reuse an existing array without having to recreate it. ```javascript var colors = ["red", "green", "blue"]; color.length(); // 3 colors.clear(); // [] colors.length(); // 0 ``` @method clear @return {Ember.Array} An empty Array. */ clear: function () { var len = get(this, 'length'); if (len === 0) return this; this.replace(0, len, EMPTY); return this; }, /** This will use the primitive `replace()` method to insert an object at the specified index. ```javascript var colors = ["red", "green", "blue"]; colors.insertAt(2, "yellow"); // ["red", "green", "yellow", "blue"] colors.insertAt(5, "orange"); // Error: Index out of range ``` @method insertAt @param {Number} idx index of insert the object at. @param {Object} object object to insert @return this */ insertAt: function(idx, object) { if (idx > get(this, 'length')) throw new Ember.Error(OUT_OF_RANGE_EXCEPTION) ; this.replace(idx, 0, [object]) ; return this ; }, /** Remove an object at the specified index using the `replace()` primitive method. You can pass either a single index, or a start and a length. If you pass a start and length that is beyond the length this method will throw an `OUT_OF_RANGE_EXCEPTION`. ```javascript var colors = ["red", "green", "blue", "yellow", "orange"]; colors.removeAt(0); // ["green", "blue", "yellow", "orange"] colors.removeAt(2, 2); // ["green", "blue"] colors.removeAt(4, 2); // Error: Index out of range ``` @method removeAt @param {Number} start index, start of range @param {Number} len length of passing range @return {Object} receiver */ removeAt: function(start, len) { if ('number' === typeof start) { if ((start < 0) || (start >= get(this, 'length'))) { throw new Ember.Error(OUT_OF_RANGE_EXCEPTION); } // fast case if (len === undefined) len = 1; this.replace(start, len, EMPTY); } return this ; }, /** Push the object onto the end of the array. Works just like `push()` but it is KVO-compliant. ```javascript var colors = ["red", "green"]; colors.pushObject("black"); // ["red", "green", "black"] colors.pushObject(["yellow"]); // ["red", "green", ["yellow"]] ``` @method pushObject @param {*} obj object to push @return The same obj passed as param */ pushObject: function(obj) { this.insertAt(get(this, 'length'), obj) ; return obj; }, /** Add the objects in the passed numerable to the end of the array. Defers notifying observers of the change until all objects are added. ```javascript var colors = ["red"]; colors.pushObjects(["yellow", "orange"]); // ["red", "yellow", "orange"] ``` @method pushObjects @param {Ember.Enumerable} objects the objects to add @return {Ember.Array} receiver */ pushObjects: function(objects) { if (!(Ember.Enumerable.detect(objects) || Ember.isArray(objects))) { throw new TypeError("Must pass Ember.Enumerable to Ember.MutableArray#pushObjects"); } this.replace(get(this, 'length'), 0, objects); return this; }, /** Pop object from array or nil if none are left. Works just like `pop()` but it is KVO-compliant. ```javascript var colors = ["red", "green", "blue"]; colors.popObject(); // "blue" console.log(colors); // ["red", "green"] ``` @method popObject @return object */ popObject: function() { var len = get(this, 'length') ; if (len === 0) return null ; var ret = this.objectAt(len-1) ; this.removeAt(len-1, 1) ; return ret ; }, /** Shift an object from start of array or nil if none are left. Works just like `shift()` but it is KVO-compliant. ```javascript var colors = ["red", "green", "blue"]; colors.shiftObject(); // "red" console.log(colors); // ["green", "blue"] ``` @method shiftObject @return object */ shiftObject: function() { if (get(this, 'length') === 0) return null ; var ret = this.objectAt(0) ; this.removeAt(0) ; return ret ; }, /** Unshift an object to start of array. Works just like `unshift()` but it is KVO-compliant. ```javascript var colors = ["red"]; colors.unshiftObject("yellow"); // ["yellow", "red"] colors.unshiftObject(["black"]); // [["black"], "yellow", "red"] ``` @method unshiftObject @param {*} obj object to unshift @return The same obj passed as param */ unshiftObject: function(obj) { this.insertAt(0, obj) ; return obj ; }, /** Adds the named objects to the beginning of the array. Defers notifying observers until all objects have been added. ```javascript var colors = ["red"]; colors.unshiftObjects(["black", "white"]); // ["black", "white", "red"] colors.unshiftObjects("yellow"); // Type Error: 'undefined' is not a function ``` @method unshiftObjects @param {Ember.Enumerable} objects the objects to add @return {Ember.Array} receiver */ unshiftObjects: function(objects) { this.replace(0, 0, objects); return this; }, /** Reverse objects in the array. Works just like `reverse()` but it is KVO-compliant. @method reverseObjects @return {Ember.Array} receiver */ reverseObjects: function() { var len = get(this, 'length'); if (len === 0) return this; var objects = this.toArray().reverse(); this.replace(0, len, objects); return this; }, /** Replace all the the receiver's content with content of the argument. If argument is an empty array receiver will be cleared. ```javascript var colors = ["red", "green", "blue"]; colors.setObjects(["black", "white"]); // ["black", "white"] colors.setObjects([]); // [] ``` @method setObjects @param {Ember.Array} objects array whose content will be used for replacing the content of the receiver @return {Ember.Array} receiver with the new content */ setObjects: function(objects) { if (objects.length === 0) return this.clear(); var len = get(this, 'length'); this.replace(0, len, objects); return this; }, // .......................................................... // IMPLEMENT Ember.MutableEnumerable // removeObject: function(obj) { var loc = get(this, 'length') || 0; while(--loc >= 0) { var curObject = this.objectAt(loc) ; if (curObject === obj) this.removeAt(loc) ; } return this ; }, addObject: function(obj) { if (!this.contains(obj)) this.pushObject(obj); return this ; } }); })(); (function() { /** @module ember @submodule ember-runtime */ var get = Ember.get, set = Ember.set; /** `Ember.TargetActionSupport` is a mixin that can be included in a class to add a `triggerAction` method with semantics similar to the Handlebars `{{action}}` helper. In normal Ember usage, the `{{action}}` helper is usually the best choice. This mixin is most often useful when you are doing more complex event handling in View objects. See also `Ember.ViewTargetActionSupport`, which has view-aware defaults for target and actionContext. @class TargetActionSupport @namespace Ember @extends Ember.Mixin */ Ember.TargetActionSupport = Ember.Mixin.create({ target: null, action: null, actionContext: null, targetObject: Ember.computed(function() { var target = get(this, 'target'); if (Ember.typeOf(target) === "string") { var value = get(this, target); if (value === undefined) { value = get(Ember.lookup, target); } return value; } else { return target; } }).property('target'), actionContextObject: Ember.computed(function() { var actionContext = get(this, 'actionContext'); if (Ember.typeOf(actionContext) === "string") { var value = get(this, actionContext); if (value === undefined) { value = get(Ember.lookup, actionContext); } return value; } else { return actionContext; } }).property('actionContext'), /** Send an "action" with an "actionContext" to a "target". The action, actionContext and target will be retrieved from properties of the object. For example: ```javascript App.SaveButtonView = Ember.View.extend(Ember.TargetActionSupport, { target: Ember.computed.alias('controller'), action: 'save', actionContext: Ember.computed.alias('context'), click: function() { this.triggerAction(); // Sends the `save` action, along with the current context // to the current controller } }); ``` The `target`, `action`, and `actionContext` can be provided as properties of an optional object argument to `triggerAction` as well. ```javascript App.SaveButtonView = Ember.View.extend(Ember.TargetActionSupport, { click: function() { this.triggerAction({ action: 'save', target: this.get('controller'), actionContext: this.get('context'), }); // Sends the `save` action, along with the current context // to the current controller } }); ``` The `actionContext` defaults to the object you mixing `TargetActionSupport` into. But `target` and `action` must be specified either as properties or with the argument to `triggerAction`, or a combination: ```javascript App.SaveButtonView = Ember.View.extend(Ember.TargetActionSupport, { target: Ember.computed.alias('controller'), click: function() { this.triggerAction({ action: 'save' }); // Sends the `save` action, along with a reference to `this`, // to the current controller } }); ``` @method triggerAction @param opts {Hash} (optional, with the optional keys action, target and/or actionContext) @return {Boolean} true if the action was sent successfully and did not return false */ triggerAction: function(opts) { opts = opts || {}; var action = opts.action || get(this, 'action'), target = opts.target || get(this, 'targetObject'), actionContext = opts.actionContext; function args(options, actionName) { var ret = []; if (actionName) { ret.push(actionName); } return ret.concat(options); } if (typeof actionContext === 'undefined') { actionContext = get(this, 'actionContextObject') || this; } if (target && action) { var ret; if (target.send) { ret = target.send.apply(target, args(actionContext, action)); } else { ret = target[action].apply(target, args(actionContext)); } if (ret !== false) ret = true; return ret; } else { return false; } } }); })(); (function() { /** @module ember @submodule ember-runtime */ /** This mixin allows for Ember objects to subscribe to and emit events. ```javascript App.Person = Ember.Object.extend(Ember.Evented, { greet: function() { // ... this.trigger('greet'); } }); var person = App.Person.create(); person.on('greet', function() { console.log('Our person has greeted'); }); person.greet(); // outputs: 'Our person has greeted' ``` You can also chain multiple event subscriptions: ```javascript person.on('greet', function() { console.log('Our person has greeted'); }).one('greet', function() { console.log('Offer one-time special'); }).off('event', this, forgetThis); ``` @class Evented @namespace Ember */ Ember.Evented = Ember.Mixin.create({ /** Subscribes to a named event with given function. ```javascript person.on('didLoad', function() { // fired once the person has loaded }); ``` An optional target can be passed in as the 2nd argument that will be set as the "this" for the callback. This is a good way to give your function access to the object triggering the event. When the target parameter is used the callback becomes the third argument. @method on @param {String} name The name of the event @param {Object} [target] The "this" binding for the callback @param {Function} method The callback to execute @return this */ on: function(name, target, method) { Ember.addListener(this, name, target, method); return this; }, /** Subscribes a function to a named event and then cancels the subscription after the first time the event is triggered. It is good to use ``one`` when you only care about the first time an event has taken place. This function takes an optional 2nd argument that will become the "this" value for the callback. If this argument is passed then the 3rd argument becomes the function. @method one @param {String} name The name of the event @param {Object} [target] The "this" binding for the callback @param {Function} method The callback to execute @return this */ one: function(name, target, method) { if (!method) { method = target; target = null; } Ember.addListener(this, name, target, method, true); return this; }, /** Triggers a named event for the object. Any additional arguments will be passed as parameters to the functions that are subscribed to the event. ```javascript person.on('didEat', function(food) { console.log('person ate some ' + food); }); person.trigger('didEat', 'broccoli'); // outputs: person ate some broccoli ``` @method trigger @param {String} name The name of the event @param {Object...} args Optional arguments to pass on */ trigger: function(name) { var args = [], i, l; for (i = 1, l = arguments.length; i < l; i++) { args.push(arguments[i]); } Ember.sendEvent(this, name, args); }, /** Cancels subscription for given name, target, and method. @method off @param {String} name The name of the event @param {Object} target The target of the subscription @param {Function} method The function of the subscription @return this */ off: function(name, target, method) { Ember.removeListener(this, name, target, method); return this; }, /** Checks to see if object has any subscriptions for named event. @method has @param {String} name The name of the event @return {Boolean} does the object have a subscription for event */ has: function(name) { return Ember.hasListeners(this, name); } }); })(); (function() { var RSVP = requireModule("rsvp"); RSVP.configure('async', function(callback, promise) { Ember.run.schedule('actions', promise, callback, promise); }); RSVP.Promise.prototype.fail = function(callback, label){ return this['catch'](callback, label); }; /** @module ember @submodule ember-runtime */ var get = Ember.get; /** @class Deferred @namespace Ember */ Ember.DeferredMixin = Ember.Mixin.create({ /** Add handlers to be called when the Deferred object is resolved or rejected. @method then @param {Function} resolve a callback function to be called when done @param {Function} reject a callback function to be called when failed */ then: function(resolve, reject, label) { var deferred, promise, entity; entity = this; deferred = get(this, '_deferred'); promise = deferred.promise; function fulfillmentHandler(fulfillment) { if (fulfillment === promise) { return resolve(entity); } else { return resolve(fulfillment); } } return promise.then(resolve && fulfillmentHandler, reject, label); }, /** Resolve a Deferred object and call any `doneCallbacks` with the given args. @method resolve */ resolve: function(value) { var deferred, promise; deferred = get(this, '_deferred'); promise = deferred.promise; if (value === this) { deferred.resolve(promise); } else { deferred.resolve(value); } }, /** Reject a Deferred object and call any `failCallbacks` with the given args. @method reject */ reject: function(value) { get(this, '_deferred').reject(value); }, _deferred: Ember.computed(function() { return RSVP.defer('Ember: DeferredMixin - ' + this); }) }); })(); (function() { /** @module ember @submodule ember-runtime */ var get = Ember.get, typeOf = Ember.typeOf; /** The `Ember.ActionHandler` mixin implements support for moving an `actions` property to an `_actions` property at extend time, and adding `_actions` to the object's mergedProperties list. `Ember.ActionHandler` is used internally by Ember in `Ember.View`, `Ember.Controller`, and `Ember.Route`. @class ActionHandler @namespace Ember */ Ember.ActionHandler = Ember.Mixin.create({ mergedProperties: ['_actions'], /** The collection of functions, keyed by name, available on this `ActionHandler` as action targets. These functions will be invoked when a matching `{{action}}` is triggered from within a template and the application's current route is this route. Actions can also be invoked from other parts of your application via `ActionHandler#send`. The `actions` hash will inherit action handlers from the `actions` hash defined on extended parent classes or mixins rather than just replace the entire hash, e.g.: ```js App.CanDisplayBanner = Ember.Mixin.create({ actions: { displayBanner: function(msg) { // ... } } }); App.WelcomeRoute = Ember.Route.extend(App.CanDisplayBanner, { actions: { playMusic: function() { // ... } } }); // `WelcomeRoute`, when active, will be able to respond // to both actions, since the actions hash is merged rather // then replaced when extending mixins / parent classes. this.send('displayBanner'); this.send('playMusic'); ``` Within a Controller, Route, View or Component's action handler, the value of the `this` context is the Controller, Route, View or Component object: ```js App.SongRoute = Ember.Route.extend({ actions: { myAction: function() { this.controllerFor("song"); this.transitionTo("other.route"); ... } } }); ``` It is also possible to call `this._super()` from within an action handler if it overrides a handler defined on a parent class or mixin: Take for example the following routes: ```js App.DebugRoute = Ember.Mixin.create({ actions: { debugRouteInformation: function() { console.debug("trololo"); } } }); App.AnnoyingDebugRoute = Ember.Route.extend(App.DebugRoute, { actions: { debugRouteInformation: function() { // also call the debugRouteInformation of mixed in App.DebugRoute this._super(); // show additional annoyance window.alert(...); } } }); ``` ## Bubbling By default, an action will stop bubbling once a handler defined on the `actions` hash handles it. To continue bubbling the action, you must return `true` from the handler: ```js App.Router.map(function() { this.resource("album", function() { this.route("song"); }); }); App.AlbumRoute = Ember.Route.extend({ actions: { startPlaying: function() { } } }); App.AlbumSongRoute = Ember.Route.extend({ actions: { startPlaying: function() { // ... if (actionShouldAlsoBeTriggeredOnParentRoute) { return true; } } } }); ``` @property actions @type Hash @default null */ /** Moves `actions` to `_actions` at extend time. Note that this currently modifies the mixin themselves, which is technically dubious but is practically of little consequence. This may change in the future. @private @method willMergeMixin */ willMergeMixin: function(props) { var hashName; if (!props._actions) { if (typeOf(props.actions) === 'object') { hashName = 'actions'; } else if (typeOf(props.events) === 'object') { hashName = 'events'; } if (hashName) { props._actions = Ember.merge(props._actions || {}, props[hashName]); } delete props[hashName]; } }, send: function(actionName) { var args = [].slice.call(arguments, 1), target; if (this._actions && this._actions[actionName]) { if (this._actions[actionName].apply(this, args) === true) { // handler returned true, so this action will bubble } else { return; } } else if (this.deprecatedSend && this.deprecatedSendHandles && this.deprecatedSendHandles(actionName)) { if (this.deprecatedSend.apply(this, [].slice.call(arguments)) === true) { // handler return true, so this action will bubble } else { return; } } if (target = get(this, 'target')) { target.send.apply(target, arguments); } } }); })(); (function() { var set = Ember.set, get = Ember.get, not = Ember.computed.not, or = Ember.computed.or; /** @module ember @submodule ember-runtime */ function tap(proxy, promise) { return promise.then(function(value) { set(proxy, 'isFulfilled', true); set(proxy, 'content', value); return value; }, function(reason) { set(proxy, 'isRejected', true); set(proxy, 'reason', reason); throw reason; }, "Ember: PromiseProxy"); } /** A low level mixin making ObjectProxy, ObjectController or ArrayController's promise aware. ```javascript var ObjectPromiseController = Ember.ObjectController.extend(Ember.PromiseProxyMixin); var controller = ObjectPromiseController.create({ promise: $.getJSON('/some/remote/data.json') }); controller.then(function(json){ // the json }, function(reason) { // the reason why you have no json }); ``` the controller has bindable attributes which track the promises life cycle ```javascript controller.get('isPending') //=> true controller.get('isSettled') //=> false controller.get('isRejected') //=> false controller.get('isFulfilled') //=> false ``` When the the $.getJSON completes, and the promise is fulfilled with json, the life cycle attributes will update accordingly. ```javascript controller.get('isPending') //=> false controller.get('isSettled') //=> true controller.get('isRejected') //=> false controller.get('isFulfilled') //=> true ``` As the controller is an ObjectController, and the json now its content, all the json properties will be available directly from the controller. ```javascript // Assuming the following json: { firstName: 'Stefan', lastName: 'Penner' } // both properties will accessible on the controller controller.get('firstName') //=> 'Stefan' controller.get('lastName') //=> 'Penner' ``` If the controller is backing a template, the attributes are bindable from within that template ```handlebars {{#if isPending}} loading... {{else}} firstName: {{firstName}} lastName: {{lastName}} {{/if}} ``` @class Ember.PromiseProxyMixin */ Ember.PromiseProxyMixin = Ember.Mixin.create({ /** If the proxied promise is rejected this will contain the reason provided. @property reason @default null */ reason: null, /** Once the proxied promise has settled this will become `false`. @property isPending @default true */ isPending: not('isSettled').readOnly(), /** Once the proxied promise has settled this will become `true`. @property isSettled @default false */ isSettled: or('isRejected', 'isFulfilled').readOnly(), /** Will become `true` if the proxied promise is rejected. @property isRejected @default false */ isRejected: false, /** Will become `true` if the proxied promise is fulfilled. @property isFullfilled @default false */ isFulfilled: false, /** The promise whose fulfillment value is being proxied by this object. This property must be specified upon creation, and should not be changed once created. Example: ```javascript Ember.ObjectController.extend(Ember.PromiseProxyMixin).create({ promise: }); ``` @property promise */ promise: Ember.computed(function(key, promise) { if (arguments.length === 2) { return tap(this, promise); } else { throw new Ember.Error("PromiseProxy's promise must be set"); } }), /** An alias to the proxied promise's `then`. See RSVP.Promise.then. @method then @param {Function} callback @return {RSVP.Promise} */ then: promiseAlias('then'), /** An alias to the proxied promise's `catch`. See RSVP.Promise.catch. @method catch @param {Function} callback @return {RSVP.Promise} */ 'catch': promiseAlias('catch'), /** An alias to the proxied promise's `finally`. See RSVP.Promise.finally. @method finally @param {Function} callback @return {RSVP.Promise} */ 'finally': promiseAlias('finally') }); function promiseAlias(name) { return function () { var promise = get(this, 'promise'); return promise[name].apply(promise, arguments); }; } })(); (function() { })(); (function() { var get = Ember.get, forEach = Ember.EnumerableUtils.forEach, RETAIN = 'r', INSERT = 'i', DELETE = 'd'; /** An `Ember.TrackedArray` tracks array operations. It's useful when you want to lazily compute the indexes of items in an array after they've been shifted by subsequent operations. @class TrackedArray @namespace Ember @param {array} [items=[]] The array to be tracked. This is used just to get the initial items for the starting state of retain:n. */ Ember.TrackedArray = function (items) { if (arguments.length < 1) { items = []; } var length = get(items, 'length'); if (length) { this._operations = [new ArrayOperation(RETAIN, length, items)]; } else { this._operations = []; } }; Ember.TrackedArray.RETAIN = RETAIN; Ember.TrackedArray.INSERT = INSERT; Ember.TrackedArray.DELETE = DELETE; Ember.TrackedArray.prototype = { /** Track that `newItems` were added to the tracked array at `index`. @method addItems @param index @param newItems */ addItems: function (index, newItems) { var count = get(newItems, 'length'); if (count < 1) { return; } var match = this._findArrayOperation(index), arrayOperation = match.operation, arrayOperationIndex = match.index, arrayOperationRangeStart = match.rangeStart, composeIndex, splitIndex, splitItems, splitArrayOperation, newArrayOperation; newArrayOperation = new ArrayOperation(INSERT, count, newItems); if (arrayOperation) { if (!match.split) { // insert left of arrayOperation this._operations.splice(arrayOperationIndex, 0, newArrayOperation); composeIndex = arrayOperationIndex; } else { this._split(arrayOperationIndex, index - arrayOperationRangeStart, newArrayOperation); composeIndex = arrayOperationIndex + 1; } } else { // insert at end this._operations.push(newArrayOperation); composeIndex = arrayOperationIndex; } this._composeInsert(composeIndex); }, /** Track that `count` items were removed at `index`. @method removeItems @param index @param count */ removeItems: function (index, count) { if (count < 1) { return; } var match = this._findArrayOperation(index), arrayOperation = match.operation, arrayOperationIndex = match.index, arrayOperationRangeStart = match.rangeStart, newArrayOperation, composeIndex; newArrayOperation = new ArrayOperation(DELETE, count); if (!match.split) { // insert left of arrayOperation this._operations.splice(arrayOperationIndex, 0, newArrayOperation); composeIndex = arrayOperationIndex; } else { this._split(arrayOperationIndex, index - arrayOperationRangeStart, newArrayOperation); composeIndex = arrayOperationIndex + 1; } return this._composeDelete(composeIndex); }, /** Apply all operations, reducing them to retain:n, for `n`, the number of items in the array. `callback` will be called for each operation and will be passed the following arguments: * {array} items The items for the given operation * {number} offset The computed offset of the items, ie the index in the array of the first item for this operation. * {string} operation The type of the operation. One of `Ember.TrackedArray.{RETAIN, DELETE, INSERT}` @method apply @param {function} callback */ apply: function (callback) { var items = [], offset = 0; forEach(this._operations, function (arrayOperation) { callback(arrayOperation.items, offset, arrayOperation.type); if (arrayOperation.type !== DELETE) { offset += arrayOperation.count; items = items.concat(arrayOperation.items); } }); this._operations = [new ArrayOperation(RETAIN, items.length, items)]; }, /** Return an `ArrayOperationMatch` for the operation that contains the item at `index`. @method _findArrayOperation @param {number} index the index of the item whose operation information should be returned. @private */ _findArrayOperation: function (index) { var arrayOperationIndex, len, split = false, arrayOperation, arrayOperationRangeStart, arrayOperationRangeEnd; // OPTIMIZE: we could search these faster if we kept a balanced tree. // find leftmost arrayOperation to the right of `index` for (arrayOperationIndex = arrayOperationRangeStart = 0, len = this._operations.length; arrayOperationIndex < len; ++arrayOperationIndex) { arrayOperation = this._operations[arrayOperationIndex]; if (arrayOperation.type === DELETE) { continue; } arrayOperationRangeEnd = arrayOperationRangeStart + arrayOperation.count - 1; if (index === arrayOperationRangeStart) { break; } else if (index > arrayOperationRangeStart && index <= arrayOperationRangeEnd) { split = true; break; } else { arrayOperationRangeStart = arrayOperationRangeEnd + 1; } } return new ArrayOperationMatch(arrayOperation, arrayOperationIndex, split, arrayOperationRangeStart); }, _split: function (arrayOperationIndex, splitIndex, newArrayOperation) { var arrayOperation = this._operations[arrayOperationIndex], splitItems = arrayOperation.items.slice(splitIndex), splitArrayOperation = new ArrayOperation(arrayOperation.type, splitItems.length, splitItems); // truncate LHS arrayOperation.count = splitIndex; arrayOperation.items = arrayOperation.items.slice(0, splitIndex); this._operations.splice(arrayOperationIndex + 1, 0, newArrayOperation, splitArrayOperation); }, // see SubArray for a better implementation. _composeInsert: function (index) { var newArrayOperation = this._operations[index], leftArrayOperation = this._operations[index-1], // may be undefined rightArrayOperation = this._operations[index+1], // may be undefined leftOp = leftArrayOperation && leftArrayOperation.type, rightOp = rightArrayOperation && rightArrayOperation.type; if (leftOp === INSERT) { // merge left leftArrayOperation.count += newArrayOperation.count; leftArrayOperation.items = leftArrayOperation.items.concat(newArrayOperation.items); if (rightOp === INSERT) { // also merge right (we have split an insert with an insert) leftArrayOperation.count += rightArrayOperation.count; leftArrayOperation.items = leftArrayOperation.items.concat(rightArrayOperation.items); this._operations.splice(index, 2); } else { // only merge left this._operations.splice(index, 1); } } else if (rightOp === INSERT) { // merge right newArrayOperation.count += rightArrayOperation.count; newArrayOperation.items = newArrayOperation.items.concat(rightArrayOperation.items); this._operations.splice(index + 1, 1); } }, _composeDelete: function (index) { var arrayOperation = this._operations[index], deletesToGo = arrayOperation.count, leftArrayOperation = this._operations[index-1], // may be undefined leftOp = leftArrayOperation && leftArrayOperation.type, nextArrayOperation, nextOp, nextCount, removeNewAndNextOp = false, removedItems = []; if (leftOp === DELETE) { arrayOperation = leftArrayOperation; index -= 1; } for (var i = index + 1; deletesToGo > 0; ++i) { nextArrayOperation = this._operations[i]; nextOp = nextArrayOperation.type; nextCount = nextArrayOperation.count; if (nextOp === DELETE) { arrayOperation.count += nextCount; continue; } if (nextCount > deletesToGo) { // d:2 {r,i}:5 we reduce the retain or insert, but it stays removedItems = removedItems.concat(nextArrayOperation.items.splice(0, deletesToGo)); nextArrayOperation.count -= deletesToGo; // In the case where we truncate the last arrayOperation, we don't need to // remove it; also the deletesToGo reduction is not the entirety of // nextCount i -= 1; nextCount = deletesToGo; deletesToGo = 0; } else { if (nextCount === deletesToGo) { // Handle edge case of d:2 i:2 in which case both operations go away // during composition. removeNewAndNextOp = true; } removedItems = removedItems.concat(nextArrayOperation.items); deletesToGo -= nextCount; } if (nextOp === INSERT) { // d:2 i:3 will result in delete going away arrayOperation.count -= nextCount; } } if (arrayOperation.count > 0) { // compose our new delete with possibly several operations to the right of // disparate types this._operations.splice(index+1, i-1-index); } else { // The delete operation can go away; it has merely reduced some other // operation, as in d:3 i:4; it may also have eliminated that operation, // as in d:3 i:3. this._operations.splice(index, removeNewAndNextOp ? 2 : 1); } return removedItems; }, toString: function () { var str = ""; forEach(this._operations, function (operation) { str += " " + operation.type + ":" + operation.count; }); return str.substring(1); } }; /** Internal data structure to represent an array operation. @method ArrayOperation @private @param {string} type The type of the operation. One of `Ember.TrackedArray.{RETAIN, INSERT, DELETE}` @param {number} count The number of items in this operation. @param {array} items The items of the operation, if included. RETAIN and INSERT include their items, DELETE does not. */ function ArrayOperation (operation, count, items) { this.type = operation; // RETAIN | INSERT | DELETE this.count = count; this.items = items; } /** Internal data structure used to include information when looking up operations by item index. @method ArrayOperationMatch @private @param {ArrayOperation} operation @param {number} index The index of `operation` in the array of operations. @param {boolean} split Whether or not the item index searched for would require a split for a new operation type. @param {number} rangeStart The index of the first item in the operation, with respect to the tracked array. The index of the last item can be computed from `rangeStart` and `operation.count`. */ function ArrayOperationMatch(operation, index, split, rangeStart) { this.operation = operation; this.index = index; this.split = split; this.rangeStart = rangeStart; } })(); (function() { var get = Ember.get, forEach = Ember.EnumerableUtils.forEach, RETAIN = 'r', FILTER = 'f'; function Operation (type, count) { this.type = type; this.count = count; } /** An `Ember.SubArray` tracks an array in a way similar to, but more specialized than, `Ember.TrackedArray`. It is useful for keeping track of the indexes of items within a filtered array. @class SubArray @namespace Ember */ Ember.SubArray = function (length) { if (arguments.length < 1) { length = 0; } if (length > 0) { this._operations = [new Operation(RETAIN, length)]; } else { this._operations = []; } }; Ember.SubArray.prototype = { /** Track that an item was added to the tracked array. @method addItem @param {number} index The index of the item in the tracked array. @param {boolean} match `true` iff the item is included in the subarray. @return {number} The index of the item in the subarray. */ addItem: function(index, match) { var returnValue = -1, itemType = match ? RETAIN : FILTER, self = this; this._findOperation(index, function(operation, operationIndex, rangeStart, rangeEnd, seenInSubArray) { var newOperation, splitOperation; if (itemType === operation.type) { ++operation.count; } else if (index === rangeStart) { // insert to the left of `operation` self._operations.splice(operationIndex, 0, new Operation(itemType, 1)); } else { newOperation = new Operation(itemType, 1); splitOperation = new Operation(operation.type, rangeEnd - index + 1); operation.count = index - rangeStart; self._operations.splice(operationIndex + 1, 0, newOperation, splitOperation); } if (match) { if (operation.type === RETAIN) { returnValue = seenInSubArray + (index - rangeStart); } else { returnValue = seenInSubArray; } } self._composeAt(operationIndex); }, function(seenInSubArray) { self._operations.push(new Operation(itemType, 1)); if (match) { returnValue = seenInSubArray; } self._composeAt(self._operations.length-1); }); return returnValue; }, /** Track that an item was removed from the tracked array. @method removeItem @param {number} index The index of the item in the tracked array. @return {number} The index of the item in the subarray, or `-1` if the item was not in the subarray. */ removeItem: function(index) { var returnValue = -1, self = this; this._findOperation(index, function (operation, operationIndex, rangeStart, rangeEnd, seenInSubArray) { if (operation.type === RETAIN) { returnValue = seenInSubArray + (index - rangeStart); } if (operation.count > 1) { --operation.count; } else { self._operations.splice(operationIndex, 1); self._composeAt(operationIndex); } }, function() { throw new Ember.Error("Can't remove an item that has never been added."); }); return returnValue; }, _findOperation: function (index, foundCallback, notFoundCallback) { var operationIndex, len, operation, rangeStart, rangeEnd, seenInSubArray = 0; // OPTIMIZE: change to balanced tree // find leftmost operation to the right of `index` for (operationIndex = rangeStart = 0, len = this._operations.length; operationIndex < len; rangeStart = rangeEnd + 1, ++operationIndex) { operation = this._operations[operationIndex]; rangeEnd = rangeStart + operation.count - 1; if (index >= rangeStart && index <= rangeEnd) { foundCallback(operation, operationIndex, rangeStart, rangeEnd, seenInSubArray); return; } else if (operation.type === RETAIN) { seenInSubArray += operation.count; } } notFoundCallback(seenInSubArray); }, _composeAt: function(index) { var op = this._operations[index], otherOp; if (!op) { // Composing out of bounds is a no-op, as when removing the last operation // in the list. return; } if (index > 0) { otherOp = this._operations[index-1]; if (otherOp.type === op.type) { op.count += otherOp.count; this._operations.splice(index-1, 1); --index; } } if (index < this._operations.length-1) { otherOp = this._operations[index+1]; if (otherOp.type === op.type) { op.count += otherOp.count; this._operations.splice(index+1, 1); } } }, toString: function () { var str = ""; forEach(this._operations, function (operation) { str += " " + operation.type + ":" + operation.count; }); return str.substring(1); } }; })(); (function() { Ember.Container = requireModule('container'); Ember.Container.set = Ember.set; })(); (function() { Ember.Application = Ember.Namespace.extend(); })(); (function() { /** @module ember @submodule ember-runtime */ var OUT_OF_RANGE_EXCEPTION = "Index out of range"; var EMPTY = []; var get = Ember.get, set = Ember.set; /** An ArrayProxy wraps any other object that implements `Ember.Array` and/or `Ember.MutableArray,` forwarding all requests. This makes it very useful for a number of binding use cases or other cases where being able to swap out the underlying array is useful. A simple example of usage: ```javascript var pets = ['dog', 'cat', 'fish']; var ap = Ember.ArrayProxy.create({ content: Ember.A(pets) }); ap.get('firstObject'); // 'dog' ap.set('content', ['amoeba', 'paramecium']); ap.get('firstObject'); // 'amoeba' ``` This class can also be useful as a layer to transform the contents of an array, as they are accessed. This can be done by overriding `objectAtContent`: ```javascript var pets = ['dog', 'cat', 'fish']; var ap = Ember.ArrayProxy.create({ content: Ember.A(pets), objectAtContent: function(idx) { return this.get('content').objectAt(idx).toUpperCase(); } }); ap.get('firstObject'); // . 'DOG' ``` @class ArrayProxy @namespace Ember @extends Ember.Object @uses Ember.MutableArray */ Ember.ArrayProxy = Ember.Object.extend(Ember.MutableArray, { /** The content array. Must be an object that implements `Ember.Array` and/or `Ember.MutableArray.` @property content @type Ember.Array */ content: null, /** The array that the proxy pretends to be. In the default `ArrayProxy` implementation, this and `content` are the same. Subclasses of `ArrayProxy` can override this property to provide things like sorting and filtering. @property arrangedContent */ arrangedContent: Ember.computed.alias('content'), /** Should actually retrieve the object at the specified index from the content. You can override this method in subclasses to transform the content item to something new. This method will only be called if content is non-`null`. @method objectAtContent @param {Number} idx The index to retrieve. @return {Object} the value or undefined if none found */ objectAtContent: function(idx) { return get(this, 'arrangedContent').objectAt(idx); }, /** Should actually replace the specified objects on the content array. You can override this method in subclasses to transform the content item into something new. This method will only be called if content is non-`null`. @method replaceContent @param {Number} idx The starting index @param {Number} amt The number of items to remove from the content. @param {Array} objects Optional array of objects to insert or null if no objects. @return {void} */ replaceContent: function(idx, amt, objects) { get(this, 'content').replace(idx, amt, objects); }, /** Invoked when the content property is about to change. Notifies observers that the entire array content will change. @private @method _contentWillChange */ _contentWillChange: Ember.beforeObserver('content', function() { this._teardownContent(); }), _teardownContent: function() { var content = get(this, 'content'); if (content) { content.removeArrayObserver(this, { willChange: 'contentArrayWillChange', didChange: 'contentArrayDidChange' }); } }, contentArrayWillChange: Ember.K, contentArrayDidChange: Ember.K, /** Invoked when the content property changes. Notifies observers that the entire array content has changed. @private @method _contentDidChange */ _contentDidChange: Ember.observer('content', function() { var content = get(this, 'content'); this._setupContent(); }), _setupContent: function() { var content = get(this, 'content'); if (content) { content.addArrayObserver(this, { willChange: 'contentArrayWillChange', didChange: 'contentArrayDidChange' }); } }, _arrangedContentWillChange: Ember.beforeObserver('arrangedContent', function() { var arrangedContent = get(this, 'arrangedContent'), len = arrangedContent ? get(arrangedContent, 'length') : 0; this.arrangedContentArrayWillChange(this, 0, len, undefined); this.arrangedContentWillChange(this); this._teardownArrangedContent(arrangedContent); }), _arrangedContentDidChange: Ember.observer('arrangedContent', function() { var arrangedContent = get(this, 'arrangedContent'), len = arrangedContent ? get(arrangedContent, 'length') : 0; this._setupArrangedContent(); this.arrangedContentDidChange(this); this.arrangedContentArrayDidChange(this, 0, undefined, len); }), _setupArrangedContent: function() { var arrangedContent = get(this, 'arrangedContent'); if (arrangedContent) { arrangedContent.addArrayObserver(this, { willChange: 'arrangedContentArrayWillChange', didChange: 'arrangedContentArrayDidChange' }); } }, _teardownArrangedContent: function() { var arrangedContent = get(this, 'arrangedContent'); if (arrangedContent) { arrangedContent.removeArrayObserver(this, { willChange: 'arrangedContentArrayWillChange', didChange: 'arrangedContentArrayDidChange' }); } }, arrangedContentWillChange: Ember.K, arrangedContentDidChange: Ember.K, objectAt: function(idx) { return get(this, 'content') && this.objectAtContent(idx); }, length: Ember.computed(function() { var arrangedContent = get(this, 'arrangedContent'); return arrangedContent ? get(arrangedContent, 'length') : 0; // No dependencies since Enumerable notifies length of change }), _replace: function(idx, amt, objects) { var content = get(this, 'content'); if (content) this.replaceContent(idx, amt, objects); return this; }, replace: function() { if (get(this, 'arrangedContent') === get(this, 'content')) { this._replace.apply(this, arguments); } else { throw new Ember.Error("Using replace on an arranged ArrayProxy is not allowed."); } }, _insertAt: function(idx, object) { if (idx > get(this, 'content.length')) throw new Ember.Error(OUT_OF_RANGE_EXCEPTION); this._replace(idx, 0, [object]); return this; }, insertAt: function(idx, object) { if (get(this, 'arrangedContent') === get(this, 'content')) { return this._insertAt(idx, object); } else { throw new Ember.Error("Using insertAt on an arranged ArrayProxy is not allowed."); } }, removeAt: function(start, len) { if ('number' === typeof start) { var content = get(this, 'content'), arrangedContent = get(this, 'arrangedContent'), indices = [], i; if ((start < 0) || (start >= get(this, 'length'))) { throw new Ember.Error(OUT_OF_RANGE_EXCEPTION); } if (len === undefined) len = 1; // Get a list of indices in original content to remove for (i=start; i=idx) { var item = content.objectAt(loc); if (item) { Ember.addBeforeObserver(item, keyName, proxy, 'contentKeyWillChange'); Ember.addObserver(item, keyName, proxy, 'contentKeyDidChange'); // keep track of the index each item was found at so we can map // it back when the obj changes. guid = guidFor(item); if (!objects[guid]) objects[guid] = []; objects[guid].push(loc); } } } function removeObserverForContentKey(content, keyName, proxy, idx, loc) { var objects = proxy._objects; if (!objects) objects = proxy._objects = {}; var indicies, guid; while(--loc>=idx) { var item = content.objectAt(loc); if (item) { Ember.removeBeforeObserver(item, keyName, proxy, 'contentKeyWillChange'); Ember.removeObserver(item, keyName, proxy, 'contentKeyDidChange'); guid = guidFor(item); indicies = objects[guid]; indicies[indexOf.call(indicies, loc)] = null; } } } /** This is the object instance returned when you get the `@each` property on an array. It uses the unknownProperty handler to automatically create EachArray instances for property names. @private @class EachProxy @namespace Ember @extends Ember.Object */ Ember.EachProxy = Ember.Object.extend({ init: function(content) { this._super(); this._content = content; content.addArrayObserver(this); // in case someone is already observing some keys make sure they are // added forEach(Ember.watchedEvents(this), function(eventName) { this.didAddListener(eventName); }, this); }, /** You can directly access mapped properties by simply requesting them. The `unknownProperty` handler will generate an EachArray of each item. @method unknownProperty @param keyName {String} @param value {*} */ unknownProperty: function(keyName, value) { var ret; ret = new EachArray(this._content, keyName, this); Ember.defineProperty(this, keyName, null, ret); this.beginObservingContentKey(keyName); return ret; }, // .......................................................... // ARRAY CHANGES // Invokes whenever the content array itself changes. arrayWillChange: function(content, idx, removedCnt, addedCnt) { var keys = this._keys, key, lim; lim = removedCnt>0 ? idx+removedCnt : -1; Ember.beginPropertyChanges(this); for(key in keys) { if (!keys.hasOwnProperty(key)) { continue; } if (lim>0) { removeObserverForContentKey(content, key, this, idx, lim); } Ember.propertyWillChange(this, key); } Ember.propertyWillChange(this._content, '@each'); Ember.endPropertyChanges(this); }, arrayDidChange: function(content, idx, removedCnt, addedCnt) { var keys = this._keys, lim; lim = addedCnt>0 ? idx+addedCnt : -1; Ember.changeProperties(function() { for(var key in keys) { if (!keys.hasOwnProperty(key)) { continue; } if (lim>0) { addObserverForContentKey(content, key, this, idx, lim); } Ember.propertyDidChange(this, key); } Ember.propertyDidChange(this._content, '@each'); }, this); }, // .......................................................... // LISTEN FOR NEW OBSERVERS AND OTHER EVENT LISTENERS // Start monitoring keys based on who is listening... didAddListener: function(eventName) { if (IS_OBSERVER.test(eventName)) { this.beginObservingContentKey(eventName.slice(0, -7)); } }, didRemoveListener: function(eventName) { if (IS_OBSERVER.test(eventName)) { this.stopObservingContentKey(eventName.slice(0, -7)); } }, // .......................................................... // CONTENT KEY OBSERVING // Actual watch keys on the source content. beginObservingContentKey: function(keyName) { var keys = this._keys; if (!keys) keys = this._keys = {}; if (!keys[keyName]) { keys[keyName] = 1; var content = this._content, len = get(content, 'length'); addObserverForContentKey(content, keyName, this, 0, len); } else { keys[keyName]++; } }, stopObservingContentKey: function(keyName) { var keys = this._keys; if (keys && (keys[keyName]>0) && (--keys[keyName]<=0)) { var content = this._content, len = get(content, 'length'); removeObserverForContentKey(content, keyName, this, 0, len); } }, contentKeyWillChange: function(obj, keyName) { Ember.propertyWillChange(this, keyName); }, contentKeyDidChange: function(obj, keyName) { Ember.propertyDidChange(this, keyName); } }); })(); (function() { /** @module ember @submodule ember-runtime */ var get = Ember.get, set = Ember.set, replace = Ember.EnumerableUtils._replace; // Add Ember.Array to Array.prototype. Remove methods with native // implementations and supply some more optimized versions of generic methods // because they are so common. var NativeArray = Ember.Mixin.create(Ember.MutableArray, Ember.Observable, Ember.Copyable, { // because length is a built-in property we need to know to just get the // original property. get: function(key) { if (key==='length') return this.length; else if ('number' === typeof key) return this[key]; else return this._super(key); }, objectAt: function(idx) { return this[idx]; }, // primitive for array support. replace: function(idx, amt, objects) { if (this.isFrozen) throw Ember.FROZEN_ERROR; // if we replaced exactly the same number of items, then pass only the // replaced range. Otherwise, pass the full remaining array length // since everything has shifted var len = objects ? get(objects, 'length') : 0; this.arrayContentWillChange(idx, amt, len); if (len === 0) { this.splice(idx, amt); } else { replace(this, idx, amt, objects); } this.arrayContentDidChange(idx, amt, len); return this; }, // If you ask for an unknown property, then try to collect the value // from member items. unknownProperty: function(key, value) { var ret;// = this.reducedProperty(key, value) ; if ((value !== undefined) && ret === undefined) { ret = this[key] = value; } return ret ; }, // If browser did not implement indexOf natively, then override with // specialized version indexOf: function(object, startAt) { var idx, len = this.length; if (startAt === undefined) startAt = 0; else startAt = (startAt < 0) ? Math.ceil(startAt) : Math.floor(startAt); if (startAt < 0) startAt += len; for(idx=startAt;idx=0;idx--) { if (this[idx] === object) return idx ; } return -1; }, copy: function(deep) { if (deep) { return this.map(function(item) { return Ember.copy(item, true); }); } return this.slice(); } }); // Remove any methods implemented natively so we don't override them var ignore = ['length']; Ember.EnumerableUtils.forEach(NativeArray.keys(), function(methodName) { if (Array.prototype[methodName]) ignore.push(methodName); }); if (ignore.length>0) { NativeArray = NativeArray.without.apply(NativeArray, ignore); } /** The NativeArray mixin contains the properties needed to to make the native Array support Ember.MutableArray and all of its dependent APIs. Unless you have `Ember.EXTEND_PROTOTYPES` or `Ember.EXTEND_PROTOTYPES.Array` set to false, this will be applied automatically. Otherwise you can apply the mixin at anytime by calling `Ember.NativeArray.activate`. @class NativeArray @namespace Ember @uses Ember.MutableArray @uses Ember.Observable @uses Ember.Copyable */ Ember.NativeArray = NativeArray; /** Creates an `Ember.NativeArray` from an Array like object. Does not modify the original object. Ember.A is not needed if `Ember.EXTEND_PROTOTYPES` is `true` (the default value). However, it is recommended that you use Ember.A when creating addons for ember or when you can not guarantee that `Ember.EXTEND_PROTOTYPES` will be `true`. Example ```js var Pagination = Ember.CollectionView.extend({ tagName: 'ul', classNames: ['pagination'], init: function() { this._super(); if (!this.get('content')) { this.set('content', Ember.A([])); } } }); ``` @method A @for Ember @return {Ember.NativeArray} */ Ember.A = function(arr) { if (arr === undefined) { arr = []; } return Ember.Array.detect(arr) ? arr : Ember.NativeArray.apply(arr); }; /** Activates the mixin on the Array.prototype if not already applied. Calling this method more than once is safe. This will be called when ember is loaded unless you have `Ember.EXTEND_PROTOTYPES` or `Ember.EXTEND_PROTOTYPES.Array` set to `false`. Example ```js if (Ember.EXTEND_PROTOTYPES === true || Ember.EXTEND_PROTOTYPES.Array) { Ember.NativeArray.activate(); } ``` @method activate @for Ember.NativeArray @static @return {void} */ Ember.NativeArray.activate = function() { NativeArray.apply(Array.prototype); Ember.A = function(arr) { return arr || []; }; }; if (Ember.EXTEND_PROTOTYPES === true || Ember.EXTEND_PROTOTYPES.Array) { Ember.NativeArray.activate(); } })(); (function() { /** @module ember @submodule ember-runtime */ var get = Ember.get, set = Ember.set, guidFor = Ember.guidFor, isNone = Ember.isNone, fmt = Ember.String.fmt; /** An unordered collection of objects. A Set works a bit like an array except that its items are not ordered. You can create a set to efficiently test for membership for an object. You can also iterate through a set just like an array, even accessing objects by index, however there is no guarantee as to their order. All Sets are observable via the Enumerable Observer API - which works on any enumerable object including both Sets and Arrays. ## Creating a Set You can create a set like you would most objects using `new Ember.Set()`. Most new sets you create will be empty, but you can also initialize the set with some content by passing an array or other enumerable of objects to the constructor. Finally, you can pass in an existing set and the set will be copied. You can also create a copy of a set by calling `Ember.Set#copy()`. ```javascript // creates a new empty set var foundNames = new Ember.Set(); // creates a set with four names in it. var names = new Ember.Set(["Charles", "Tom", "Juan", "Alex"]); // :P // creates a copy of the names set. var namesCopy = new Ember.Set(names); // same as above. var anotherNamesCopy = names.copy(); ``` ## Adding/Removing Objects You generally add or remove objects from a set using `add()` or `remove()`. You can add any type of object including primitives such as numbers, strings, and booleans. Unlike arrays, objects can only exist one time in a set. If you call `add()` on a set with the same object multiple times, the object will only be added once. Likewise, calling `remove()` with the same object multiple times will remove the object the first time and have no effect on future calls until you add the object to the set again. NOTE: You cannot add/remove `null` or `undefined` to a set. Any attempt to do so will be ignored. In addition to add/remove you can also call `push()`/`pop()`. Push behaves just like `add()` but `pop()`, unlike `remove()` will pick an arbitrary object, remove it and return it. This is a good way to use a set as a job queue when you don't care which order the jobs are executed in. ## Testing for an Object To test for an object's presence in a set you simply call `Ember.Set#contains()`. ## Observing changes When using `Ember.Set`, you can observe the `"[]"` property to be alerted whenever the content changes. You can also add an enumerable observer to the set to be notified of specific objects that are added and removed from the set. See [Ember.Enumerable](/api/classes/Ember.Enumerable.html) for more information on enumerables. This is often unhelpful. If you are filtering sets of objects, for instance, it is very inefficient to re-filter all of the items each time the set changes. It would be better if you could just adjust the filtered set based on what was changed on the original set. The same issue applies to merging sets, as well. ## Other Methods `Ember.Set` primary implements other mixin APIs. For a complete reference on the methods you will use with `Ember.Set`, please consult these mixins. The most useful ones will be `Ember.Enumerable` and `Ember.MutableEnumerable` which implement most of the common iterator methods you are used to on Array. Note that you can also use the `Ember.Copyable` and `Ember.Freezable` APIs on `Ember.Set` as well. Once a set is frozen it can no longer be modified. The benefit of this is that when you call `frozenCopy()` on it, Ember will avoid making copies of the set. This allows you to write code that can know with certainty when the underlying set data will or will not be modified. @class Set @namespace Ember @extends Ember.CoreObject @uses Ember.MutableEnumerable @uses Ember.Copyable @uses Ember.Freezable @since Ember 0.9 */ Ember.Set = Ember.CoreObject.extend(Ember.MutableEnumerable, Ember.Copyable, Ember.Freezable, { // .......................................................... // IMPLEMENT ENUMERABLE APIS // /** This property will change as the number of objects in the set changes. @property length @type number @default 0 */ length: 0, /** Clears the set. This is useful if you want to reuse an existing set without having to recreate it. ```javascript var colors = new Ember.Set(["red", "green", "blue"]); colors.length; // 3 colors.clear(); colors.length; // 0 ``` @method clear @return {Ember.Set} An empty Set */ clear: function() { if (this.isFrozen) { throw new Ember.Error(Ember.FROZEN_ERROR); } var len = get(this, 'length'); if (len === 0) { return this; } var guid; this.enumerableContentWillChange(len, 0); Ember.propertyWillChange(this, 'firstObject'); Ember.propertyWillChange(this, 'lastObject'); for (var i=0; i < len; i++) { guid = guidFor(this[i]); delete this[guid]; delete this[i]; } set(this, 'length', 0); Ember.propertyDidChange(this, 'firstObject'); Ember.propertyDidChange(this, 'lastObject'); this.enumerableContentDidChange(len, 0); return this; }, /** Returns true if the passed object is also an enumerable that contains the same objects as the receiver. ```javascript var colors = ["red", "green", "blue"], same_colors = new Ember.Set(colors); same_colors.isEqual(colors); // true same_colors.isEqual(["purple", "brown"]); // false ``` @method isEqual @param {Ember.Set} obj the other object. @return {Boolean} */ isEqual: function(obj) { // fail fast if (!Ember.Enumerable.detect(obj)) return false; var loc = get(this, 'length'); if (get(obj, 'length') !== loc) return false; while(--loc >= 0) { if (!obj.contains(this[loc])) return false; } return true; }, /** Adds an object to the set. Only non-`null` objects can be added to a set and those can only be added once. If the object is already in the set or the passed value is null this method will have no effect. This is an alias for `Ember.MutableEnumerable.addObject()`. ```javascript var colors = new Ember.Set(); colors.add("blue"); // ["blue"] colors.add("blue"); // ["blue"] colors.add("red"); // ["blue", "red"] colors.add(null); // ["blue", "red"] colors.add(undefined); // ["blue", "red"] ``` @method add @param {Object} obj The object to add. @return {Ember.Set} The set itself. */ add: Ember.aliasMethod('addObject'), /** Removes the object from the set if it is found. If you pass a `null` value or an object that is already not in the set, this method will have no effect. This is an alias for `Ember.MutableEnumerable.removeObject()`. ```javascript var colors = new Ember.Set(["red", "green", "blue"]); colors.remove("red"); // ["blue", "green"] colors.remove("purple"); // ["blue", "green"] colors.remove(null); // ["blue", "green"] ``` @method remove @param {Object} obj The object to remove @return {Ember.Set} The set itself. */ remove: Ember.aliasMethod('removeObject'), /** Removes the last element from the set and returns it, or `null` if it's empty. ```javascript var colors = new Ember.Set(["green", "blue"]); colors.pop(); // "blue" colors.pop(); // "green" colors.pop(); // null ``` @method pop @return {Object} The removed object from the set or null. */ pop: function() { if (get(this, 'isFrozen')) throw new Ember.Error(Ember.FROZEN_ERROR); var obj = this.length > 0 ? this[this.length-1] : null; this.remove(obj); return obj; }, /** Inserts the given object on to the end of the set. It returns the set itself. This is an alias for `Ember.MutableEnumerable.addObject()`. ```javascript var colors = new Ember.Set(); colors.push("red"); // ["red"] colors.push("green"); // ["red", "green"] colors.push("blue"); // ["red", "green", "blue"] ``` @method push @return {Ember.Set} The set itself. */ push: Ember.aliasMethod('addObject'), /** Removes the last element from the set and returns it, or `null` if it's empty. This is an alias for `Ember.Set.pop()`. ```javascript var colors = new Ember.Set(["green", "blue"]); colors.shift(); // "blue" colors.shift(); // "green" colors.shift(); // null ``` @method shift @return {Object} The removed object from the set or null. */ shift: Ember.aliasMethod('pop'), /** Inserts the given object on to the end of the set. It returns the set itself. This is an alias of `Ember.Set.push()` ```javascript var colors = new Ember.Set(); colors.unshift("red"); // ["red"] colors.unshift("green"); // ["red", "green"] colors.unshift("blue"); // ["red", "green", "blue"] ``` @method unshift @return {Ember.Set} The set itself. */ unshift: Ember.aliasMethod('push'), /** Adds each object in the passed enumerable to the set. This is an alias of `Ember.MutableEnumerable.addObjects()` ```javascript var colors = new Ember.Set(); colors.addEach(["red", "green", "blue"]); // ["red", "green", "blue"] ``` @method addEach @param {Ember.Enumerable} objects the objects to add. @return {Ember.Set} The set itself. */ addEach: Ember.aliasMethod('addObjects'), /** Removes each object in the passed enumerable to the set. This is an alias of `Ember.MutableEnumerable.removeObjects()` ```javascript var colors = new Ember.Set(["red", "green", "blue"]); colors.removeEach(["red", "blue"]); // ["green"] ``` @method removeEach @param {Ember.Enumerable} objects the objects to remove. @return {Ember.Set} The set itself. */ removeEach: Ember.aliasMethod('removeObjects'), // .......................................................... // PRIVATE ENUMERABLE SUPPORT // init: function(items) { this._super(); if (items) this.addObjects(items); }, // implement Ember.Enumerable nextObject: function(idx) { return this[idx]; }, // more optimized version firstObject: Ember.computed(function() { return this.length > 0 ? this[0] : undefined; }), // more optimized version lastObject: Ember.computed(function() { return this.length > 0 ? this[this.length-1] : undefined; }), // implements Ember.MutableEnumerable addObject: function(obj) { if (get(this, 'isFrozen')) throw new Ember.Error(Ember.FROZEN_ERROR); if (isNone(obj)) return this; // nothing to do var guid = guidFor(obj), idx = this[guid], len = get(this, 'length'), added ; if (idx>=0 && idx=0 && idx=0; }, copy: function() { var C = this.constructor, ret = new C(), loc = get(this, 'length'); set(ret, 'length', loc); while(--loc>=0) { ret[loc] = this[loc]; ret[guidFor(this[loc])] = loc; } return ret; }, toString: function() { var len = this.length, idx, array = []; for(idx = 0; idx < len; idx++) { array[idx] = this[idx]; } return fmt("Ember.Set<%@>", [array.join(',')]); } }); })(); (function() { var DeferredMixin = Ember.DeferredMixin, // mixins/deferred get = Ember.get; var Deferred = Ember.Object.extend(DeferredMixin); Deferred.reopenClass({ promise: function(callback, binding) { var deferred = Deferred.create(); callback.call(binding, deferred); return deferred; } }); Ember.Deferred = Deferred; })(); (function() { var forEach = Ember.ArrayPolyfills.forEach; /** @module ember @submodule ember-runtime */ var loadHooks = Ember.ENV.EMBER_LOAD_HOOKS || {}; var loaded = {}; /** Detects when a specific package of Ember (e.g. 'Ember.Handlebars') has fully loaded and is available for extension. The provided `callback` will be called with the `name` passed resolved from a string into the object: ``` javascript Ember.onLoad('Ember.Handlebars' function(hbars){ hbars.registerHelper(...); }); ``` @method onLoad @for Ember @param name {String} name of hook @param callback {Function} callback to be called */ Ember.onLoad = function(name, callback) { var object; loadHooks[name] = loadHooks[name] || Ember.A(); loadHooks[name].pushObject(callback); if (object = loaded[name]) { callback(object); } }; /** Called when an Ember.js package (e.g Ember.Handlebars) has finished loading. Triggers any callbacks registered for this event. @method runLoadHooks @for Ember @param name {String} name of hook @param object {Object} object to pass to callbacks */ Ember.runLoadHooks = function(name, object) { loaded[name] = object; if (loadHooks[name]) { forEach.call(loadHooks[name], function(callback) { callback(object); }); } }; })(); (function() { })(); (function() { var get = Ember.get; /** @module ember @submodule ember-runtime */ /** `Ember.ControllerMixin` provides a standard interface for all classes that compose Ember's controller layer: `Ember.Controller`, `Ember.ArrayController`, and `Ember.ObjectController`. @class ControllerMixin @namespace Ember @uses Ember.ActionHandler */ Ember.ControllerMixin = Ember.Mixin.create(Ember.ActionHandler, { /* ducktype as a controller */ isController: true, /** The object to which actions from the view should be sent. For example, when a Handlebars template uses the `{{action}}` helper, it will attempt to send the action to the view's controller's `target`. By default, a controller's `target` is set to the router after it is instantiated by `Ember.Application#initialize`. @property target @default null */ target: null, container: null, parentController: null, store: null, model: Ember.computed.alias('content'), deprecatedSendHandles: function(actionName) { return !!this[actionName]; }, deprecatedSend: function(actionName) { var args = [].slice.call(arguments, 1); this[actionName].apply(this, args); return; } }); /** @class Controller @namespace Ember @extends Ember.Object @uses Ember.ControllerMixin */ Ember.Controller = Ember.Object.extend(Ember.ControllerMixin); })(); (function() { /** @module ember @submodule ember-runtime */ var get = Ember.get, set = Ember.set, forEach = Ember.EnumerableUtils.forEach; /** `Ember.SortableMixin` provides a standard interface for array proxies to specify a sort order and maintain this sorting when objects are added, removed, or updated without changing the implicit order of their underlying content array: ```javascript songs = [ {trackNumber: 4, title: 'Ob-La-Di, Ob-La-Da'}, {trackNumber: 2, title: 'Back in the U.S.S.R.'}, {trackNumber: 3, title: 'Glass Onion'}, ]; songsController = Ember.ArrayController.create({ content: songs, sortProperties: ['trackNumber'], sortAscending: true }); songsController.get('firstObject'); // {trackNumber: 2, title: 'Back in the U.S.S.R.'} songsController.addObject({trackNumber: 1, title: 'Dear Prudence'}); songsController.get('firstObject'); // {trackNumber: 1, title: 'Dear Prudence'} ``` If you add or remove the properties to sort by or change the sort direction the content sort order will be automatically updated. ```javascript songsController.set('sortProperties', ['title']); songsController.get('firstObject'); // {trackNumber: 2, title: 'Back in the U.S.S.R.'} songsController.toggleProperty('sortAscending'); songsController.get('firstObject'); // {trackNumber: 4, title: 'Ob-La-Di, Ob-La-Da'} ``` SortableMixin works by sorting the arrangedContent array, which is the array that arrayProxy displays. Due to the fact that the underlying 'content' array is not changed, that array will not display the sorted list: ```javascript songsController.get('content').get('firstObject'); // Returns the unsorted original content songsController.get('firstObject'); // Returns the sorted content. ``` Although the sorted content can also be accessed through the arrangedContent property, it is preferable to use the proxied class and not the arrangedContent array directly. @class SortableMixin @namespace Ember @uses Ember.MutableEnumerable */ Ember.SortableMixin = Ember.Mixin.create(Ember.MutableEnumerable, { /** Specifies which properties dictate the arrangedContent's sort order. When specifying multiple properties the sorting will use properties from the `sortProperties` array prioritized from first to last. @property {Array} sortProperties */ sortProperties: null, /** Specifies the arrangedContent's sort direction @property {Boolean} sortAscending */ sortAscending: true, /** The function used to compare two values. You can override this if you want to do custom comparisons. Functions must be of the type expected by Array#sort, i.e. return 0 if the two parameters are equal, return a negative value if the first parameter is smaller than the second or return a positive value otherwise: ```javascript function(x,y) { // These are assumed to be integers if (x === y) return 0; return x < y ? -1 : 1; } ``` @property sortFunction @type {Function} @default Ember.compare */ sortFunction: Ember.compare, orderBy: function(item1, item2) { var result = 0, sortProperties = get(this, 'sortProperties'), sortAscending = get(this, 'sortAscending'), sortFunction = get(this, 'sortFunction'); forEach(sortProperties, function(propertyName) { if (result === 0) { result = sortFunction(get(item1, propertyName), get(item2, propertyName)); if ((result !== 0) && !sortAscending) { result = (-1) * result; } } }); return result; }, destroy: function() { var content = get(this, 'content'), sortProperties = get(this, 'sortProperties'); if (content && sortProperties) { forEach(content, function(item) { forEach(sortProperties, function(sortProperty) { Ember.removeObserver(item, sortProperty, this, 'contentItemSortPropertyDidChange'); }, this); }, this); } return this._super(); }, isSorted: Ember.computed.bool('sortProperties'), /** Overrides the default arrangedContent from arrayProxy in order to sort by sortFunction. Also sets up observers for each sortProperty on each item in the content Array. @property arrangedContent */ arrangedContent: Ember.computed('content', 'sortProperties.@each', function(key, value) { var content = get(this, 'content'), isSorted = get(this, 'isSorted'), sortProperties = get(this, 'sortProperties'), self = this; if (content && isSorted) { content = content.slice(); content.sort(function(item1, item2) { return self.orderBy(item1, item2); }); forEach(content, function(item) { forEach(sortProperties, function(sortProperty) { Ember.addObserver(item, sortProperty, this, 'contentItemSortPropertyDidChange'); }, this); }, this); return Ember.A(content); } return content; }), _contentWillChange: Ember.beforeObserver('content', function() { var content = get(this, 'content'), sortProperties = get(this, 'sortProperties'); if (content && sortProperties) { forEach(content, function(item) { forEach(sortProperties, function(sortProperty) { Ember.removeObserver(item, sortProperty, this, 'contentItemSortPropertyDidChange'); }, this); }, this); } this._super(); }), sortAscendingWillChange: Ember.beforeObserver('sortAscending', function() { this._lastSortAscending = get(this, 'sortAscending'); }), sortAscendingDidChange: Ember.observer('sortAscending', function() { if (get(this, 'sortAscending') !== this._lastSortAscending) { var arrangedContent = get(this, 'arrangedContent'); arrangedContent.reverseObjects(); } }), contentArrayWillChange: function(array, idx, removedCount, addedCount) { var isSorted = get(this, 'isSorted'); if (isSorted) { var arrangedContent = get(this, 'arrangedContent'); var removedObjects = array.slice(idx, idx+removedCount); var sortProperties = get(this, 'sortProperties'); forEach(removedObjects, function(item) { arrangedContent.removeObject(item); forEach(sortProperties, function(sortProperty) { Ember.removeObserver(item, sortProperty, this, 'contentItemSortPropertyDidChange'); }, this); }, this); } return this._super(array, idx, removedCount, addedCount); }, contentArrayDidChange: function(array, idx, removedCount, addedCount) { var isSorted = get(this, 'isSorted'), sortProperties = get(this, 'sortProperties'); if (isSorted) { var addedObjects = array.slice(idx, idx+addedCount); forEach(addedObjects, function(item) { this.insertItemSorted(item); forEach(sortProperties, function(sortProperty) { Ember.addObserver(item, sortProperty, this, 'contentItemSortPropertyDidChange'); }, this); }, this); } return this._super(array, idx, removedCount, addedCount); }, insertItemSorted: function(item) { var arrangedContent = get(this, 'arrangedContent'); var length = get(arrangedContent, 'length'); var idx = this._binarySearch(item, 0, length); arrangedContent.insertAt(idx, item); }, contentItemSortPropertyDidChange: function(item) { var arrangedContent = get(this, 'arrangedContent'), oldIndex = arrangedContent.indexOf(item), leftItem = arrangedContent.objectAt(oldIndex - 1), rightItem = arrangedContent.objectAt(oldIndex + 1), leftResult = leftItem && this.orderBy(item, leftItem), rightResult = rightItem && this.orderBy(item, rightItem); if (leftResult < 0 || rightResult > 0) { arrangedContent.removeObject(item); this.insertItemSorted(item); } }, _binarySearch: function(item, low, high) { var mid, midItem, res, arrangedContent; if (low === high) { return low; } arrangedContent = get(this, 'arrangedContent'); mid = low + Math.floor((high - low) / 2); midItem = arrangedContent.objectAt(mid); res = this.orderBy(midItem, item); if (res < 0) { return this._binarySearch(item, mid+1, high); } else if (res > 0) { return this._binarySearch(item, low, mid); } return mid; } }); })(); (function() { /** @module ember @submodule ember-runtime */ var get = Ember.get, set = Ember.set, forEach = Ember.EnumerableUtils.forEach, replace = Ember.EnumerableUtils.replace; /** `Ember.ArrayController` provides a way for you to publish a collection of objects so that you can easily bind to the collection from a Handlebars `#each` helper, an `Ember.CollectionView`, or other controllers. The advantage of using an `ArrayController` is that you only have to set up your view bindings once; to change what's displayed, simply swap out the `content` property on the controller. For example, imagine you wanted to display a list of items fetched via an XHR request. Create an `Ember.ArrayController` and set its `content` property: ```javascript MyApp.listController = Ember.ArrayController.create(); $.get('people.json', function(data) { MyApp.listController.set('content', data); }); ``` Then, create a view that binds to your new controller: ```handlebars {{#each MyApp.listController}} {{firstName}} {{lastName}} {{/each}} ``` Although you are binding to the controller, the behavior of this controller is to pass through any methods or properties to the underlying array. This capability comes from `Ember.ArrayProxy`, which this class inherits from. Sometimes you want to display computed properties within the body of an `#each` helper that depend on the underlying items in `content`, but are not present on those items. To do this, set `itemController` to the name of a controller (probably an `ObjectController`) that will wrap each individual item. For example: ```handlebars {{#each post in controller}}
  • {{title}} ({{titleLength}} characters)
    • {{/each}} ``` ```javascript App.PostsController = Ember.ArrayController.extend({ itemController: 'post' }); App.PostController = Ember.ObjectController.extend({ // the `title` property will be proxied to the underlying post. titleLength: function() { return this.get('title').length; }.property('title') }); ``` In some cases it is helpful to return a different `itemController` depending on the particular item. Subclasses can do this by overriding `lookupItemController`. For example: ```javascript App.MyArrayController = Ember.ArrayController.extend({ lookupItemController: function( object ) { if (object.get('isSpecial')) { return "special"; // use App.SpecialController } else { return "regular"; // use App.RegularController } } }); ``` The itemController instances will have a `parentController` property set to either the the `parentController` property of the `ArrayController` or to the `ArrayController` instance itself. @class ArrayController @namespace Ember @extends Ember.ArrayProxy @uses Ember.SortableMixin @uses Ember.ControllerMixin */ Ember.ArrayController = Ember.ArrayProxy.extend(Ember.ControllerMixin, Ember.SortableMixin, { /** The controller used to wrap items, if any. @property itemController @type String @default null */ itemController: null, /** Return the name of the controller to wrap items, or `null` if items should be returned directly. The default implementation simply returns the `itemController` property, but subclasses can override this method to return different controllers for different objects. For example: ```javascript App.MyArrayController = Ember.ArrayController.extend({ lookupItemController: function( object ) { if (object.get('isSpecial')) { return "special"; // use App.SpecialController } else { return "regular"; // use App.RegularController } } }); ``` @method lookupItemController @param {Object} object @return {String} */ lookupItemController: function(object) { return get(this, 'itemController'); }, objectAtContent: function(idx) { var length = get(this, 'length'), arrangedContent = get(this,'arrangedContent'), object = arrangedContent && arrangedContent.objectAt(idx); if (idx >= 0 && idx < length) { var controllerClass = this.lookupItemController(object); if (controllerClass) { return this.controllerAt(idx, object, controllerClass); } } // When `controllerClass` is falsy, we have not opted in to using item // controllers, so return the object directly. // When the index is out of range, we want to return the "out of range" // value, whatever that might be. Rather than make assumptions // (e.g. guessing `null` or `undefined`) we defer this to `arrangedContent`. return object; }, arrangedContentDidChange: function() { this._super(); this._resetSubControllers(); }, arrayContentDidChange: function(idx, removedCnt, addedCnt) { var subControllers = get(this, '_subControllers'), subControllersToRemove = subControllers.slice(idx, idx+removedCnt); forEach(subControllersToRemove, function(subController) { if (subController) { subController.destroy(); } }); replace(subControllers, idx, removedCnt, new Array(addedCnt)); // The shadow array of subcontrollers must be updated before we trigger // observers, otherwise observers will get the wrong subcontainer when // calling `objectAt` this._super(idx, removedCnt, addedCnt); }, init: function() { this._super(); this.set('_subControllers', Ember.A()); }, content: Ember.computed(function () { return Ember.A(); }), controllerAt: function(idx, object, controllerClass) { var container = get(this, 'container'), subControllers = get(this, '_subControllers'), subController = subControllers[idx], factory, fullName; if (subController) { return subController; } fullName = "controller:" + controllerClass; if (!container.has(fullName)) { throw new Ember.Error('Could not resolve itemController: "' + controllerClass + '"'); } subController = container.lookupFactory(fullName).create({ target: this, parentController: get(this, 'parentController') || this, content: object }); subControllers[idx] = subController; return subController; }, _subControllers: null, _resetSubControllers: function() { var subControllers = get(this, '_subControllers'); if (subControllers) { forEach(subControllers, function(subController) { if (subController) { subController.destroy(); } }); } this.set('_subControllers', Ember.A()); } }); })(); (function() { /** @module ember @submodule ember-runtime */ /** `Ember.ObjectController` is part of Ember's Controller layer. It is intended to wrap a single object, proxying unhandled attempts to `get` and `set` to the underlying content object, and to forward unhandled action attempts to its `target`. `Ember.ObjectController` derives this functionality from its superclass `Ember.ObjectProxy` and the `Ember.ControllerMixin` mixin. @class ObjectController @namespace Ember @extends Ember.ObjectProxy @uses Ember.ControllerMixin **/ Ember.ObjectController = Ember.ObjectProxy.extend(Ember.ControllerMixin); })(); (function() { })(); (function() { /** Ember Runtime @module ember @submodule ember-runtime @requires ember-metal */ })(); })(); if (typeof location !== 'undefined' && (location.hostname === 'localhost' || location.hostname === '127.0.0.1')) { Ember.Logger.warn("You are running a production build of Ember on localhost and won't receive detailed error messages. "+ "If you want full error messages please use the non-minified build provided on the Ember website."); }