{I" class:ETI"ProcessedAsset;FI"logical_path;TI"ember-data.js;FI" pathname;TI"($root/tmp/ember-rails/ember-data.js;FI"content_type;TI"application/javascript;TI" mtime;Tl+ƒ?™RI" length;TioKI" digest;TI"%fc362a00a444d6723de9523c106b5cce;FI" source;TI"oK// ========================================================================== // Project: Ember Data // Copyright: Copyright 2011-2013 Tilde Inc. and contributors. // Portions Copyright 2011 LivingSocial Inc. // License: Licensed under MIT license (see license.js) // ========================================================================== // Version: v1.0.0-beta.3-48-gb47afef // Last commit: b47afef (2013-10-08 19:07:59 -0700) (function() { var define, requireModule; (function() { var registry = {}, seen = {}; define = function(name, deps, callback) { registry[name] = { deps: deps, callback: callback }; }; requireModule = function(name) { if (seen[name]) { return seen[name]; } seen[name] = {}; var mod, deps, callback, reified , exports; mod = registry[name]; if (!mod) { throw new Error("Module '" + name + "' not found."); } deps = mod.deps; callback = mod.callback; reified = []; exports; for (var i=0, l=deps.length; i self.attributeLimit) { return false; } var desc = capitalize(underscore(name).replace('_', ' ')); columns.push({ name: name, desc: desc }); }); return columns; }, getRecords: function(type) { return this.get('store').all(type); }, getRecordColumnValues: function(record) { var self = this, count = 0, columnValues = { id: get(record, 'id') }; record.eachAttribute(function(key) { if (count++ > self.attributeLimit) { return false; } var value = get(record, key); columnValues[key] = value; }); return columnValues; }, getRecordKeywords: function(record) { var keywords = [], keys = Ember.A(['id']); record.eachAttribute(function(key) { keys.push(key); }); keys.forEach(function(key) { keywords.push(get(record, key)); }); return keywords; }, getRecordFilterValues: function(record) { return { isNew: record.get('isNew'), isModified: record.get('isDirty') && !record.get('isNew'), isClean: !record.get('isDirty') }; }, getRecordColor: function(record) { var color = 'black'; if (record.get('isNew')) { color = 'green'; } else if (record.get('isDirty')) { color = 'blue'; } return color; }, observeRecord: function(record, recordUpdated) { var releaseMethods = Ember.A(), self = this, keysToObserve = Ember.A(['id', 'isNew', 'isDirty']); record.eachAttribute(function(key) { keysToObserve.push(key); }); keysToObserve.forEach(function(key) { var handler = function() { recordUpdated(self.wrapRecord(record)); }; Ember.addObserver(record, key, handler); releaseMethods.push(function() { Ember.removeObserver(record, key, handler); }); }); var release = function() { releaseMethods.forEach(function(fn) { fn(); } ); }; return release; } }); })(); (function() { DS.Transform = Ember.Object.extend({ serialize: Ember.required(), deserialize: Ember.required() }); })(); (function() { DS.BooleanTransform = DS.Transform.extend({ deserialize: function(serialized) { var type = typeof serialized; if (type === "boolean") { return serialized; } else if (type === "string") { return serialized.match(/^true$|^t$|^1$/i) !== null; } else if (type === "number") { return serialized === 1; } else { return false; } }, serialize: function(deserialized) { return Boolean(deserialized); } }); })(); (function() { DS.DateTransform = DS.Transform.extend({ deserialize: function(serialized) { var type = typeof serialized; if (type === "string") { return new Date(Ember.Date.parse(serialized)); } else if (type === "number") { return new Date(serialized); } else if (serialized === null || serialized === undefined) { // if the value is not present in the data, // return undefined, not null. return serialized; } else { return null; } }, serialize: function(date) { if (date instanceof Date) { var days = ["Sun", "Mon", "Tue", "Wed", "Thu", "Fri", "Sat"]; var months = ["Jan", "Feb", "Mar", "Apr", "May", "Jun", "Jul", "Aug", "Sep", "Oct", "Nov", "Dec"]; var pad = function(num) { return num < 10 ? "0"+num : ""+num; }; var utcYear = date.getUTCFullYear(), utcMonth = date.getUTCMonth(), utcDayOfMonth = date.getUTCDate(), utcDay = date.getUTCDay(), utcHours = date.getUTCHours(), utcMinutes = date.getUTCMinutes(), utcSeconds = date.getUTCSeconds(); var dayOfWeek = days[utcDay]; var dayOfMonth = pad(utcDayOfMonth); var month = months[utcMonth]; return dayOfWeek + ", " + dayOfMonth + " " + month + " " + utcYear + " " + pad(utcHours) + ":" + pad(utcMinutes) + ":" + pad(utcSeconds) + " GMT"; } else { return null; } } }); })(); (function() { var empty = Ember.isEmpty; DS.NumberTransform = DS.Transform.extend({ deserialize: function(serialized) { return empty(serialized) ? null : Number(serialized); }, serialize: function(deserialized) { return empty(deserialized) ? null : Number(deserialized); } }); })(); (function() { var none = Ember.isNone; DS.StringTransform = DS.Transform.extend({ deserialize: function(serialized) { return none(serialized) ? null : String(serialized); }, serialize: function(deserialized) { return none(deserialized) ? null : String(deserialized); } }); })(); (function() { })(); (function() { /** @module ember-data */ var set = Ember.set; /* This code registers an injection for Ember.Application. If an Ember.js developer defines a subclass of DS.Store on their application, this code will automatically instantiate it and make it available on the router. Additionally, after an application's controllers have been injected, they will each have the store made available to them. For example, imagine an Ember.js application with the following classes: App.Store = DS.Store.extend({ adapter: 'custom' }); App.PostsController = Ember.ArrayController.extend({ // ... }); When the application is initialized, `App.Store` will automatically be instantiated, and the instance of `App.PostsController` will have its `store` property set to that instance. Note that this code will only be run if the `ember-application` package is loaded. If Ember Data is being used in an environment other than a typical application (e.g., node.js where only `ember-runtime` is available), this code will be ignored. */ Ember.onLoad('Ember.Application', function(Application) { Application.initializer({ name: "store", initialize: function(container, application) { application.register('store:main', application.Store || DS.Store); application.register('serializer:_default', DS.JSONSerializer); application.register('serializer:_rest', DS.RESTSerializer); application.register('adapter:_rest', DS.RESTAdapter); // Eagerly generate the store so defaultStore is populated. // TODO: Do this in a finisher hook container.lookup('store:main'); } }); Application.initializer({ name: "transforms", initialize: function(container, application) { application.register('transform:boolean', DS.BooleanTransform); application.register('transform:date', DS.DateTransform); application.register('transform:number', DS.NumberTransform); application.register('transform:string', DS.StringTransform); } }); Application.initializer({ name: "dataAdapter", initialize: function(container, application) { application.register('dataAdapter:main', DS.DebugAdapter); } }); Application.initializer({ name: "injectStore", initialize: function(container, application) { application.inject('controller', 'store', 'store:main'); application.inject('route', 'store', 'store:main'); application.inject('serializer', 'store', 'store:main'); application.inject('dataAdapter', 'store', 'store:main'); } }); }); })(); (function() { /** @module ember-data */ /** Date.parse with progressive enhancement for ISO 8601 Ā© 2011 Colin Snover Released under MIT license. @class Date @namespace Ember @static */ Ember.Date = Ember.Date || {}; var origParse = Date.parse, numericKeys = [ 1, 4, 5, 6, 7, 10, 11 ]; /** @method parse @param date */ Ember.Date.parse = function (date) { var timestamp, struct, minutesOffset = 0; // ES5 Ā§15.9.4.2 states that the string should attempt to be parsed as a Date Time String Format string // before falling back to any implementation-specific date parsing, so thatā€™s what we do, even if native // implementations could be faster // 1 YYYY 2 MM 3 DD 4 HH 5 mm 6 ss 7 msec 8 Z 9 Ā± 10 tzHH 11 tzmm if ((struct = /^(\d{4}|[+\-]\d{6})(?:-(\d{2})(?:-(\d{2}))?)?(?:T(\d{2}):(\d{2})(?::(\d{2})(?:\.(\d{3}))?)?(?:(Z)|([+\-])(\d{2})(?::(\d{2}))?)?)?$/.exec(date))) { // avoid NaN timestamps caused by ā€œundefinedā€ values being passed to Date.UTC for (var i = 0, k; (k = numericKeys[i]); ++i) { struct[k] = +struct[k] || 0; } // allow undefined days and months struct[2] = (+struct[2] || 1) - 1; struct[3] = +struct[3] || 1; if (struct[8] !== 'Z' && struct[9] !== undefined) { minutesOffset = struct[10] * 60 + struct[11]; if (struct[9] === '+') { minutesOffset = 0 - minutesOffset; } } timestamp = Date.UTC(struct[1], struct[2], struct[3], struct[4], struct[5] + minutesOffset, struct[6], struct[7]); } else { timestamp = origParse ? origParse(date) : NaN; } return timestamp; }; if (Ember.EXTEND_PROTOTYPES === true || Ember.EXTEND_PROTOTYPES.Date) { Date.parse = Ember.Date.parse; } })(); (function() { })(); (function() { /** @module ember-data */ var get = Ember.get, set = Ember.set; /** A record array is an array that contains records of a certain type. The record array materializes records as needed when they are retrieved for the first time. You should not create record arrays yourself. Instead, an instance of DS.RecordArray or its subclasses will be returned by your application's store in response to queries. @class RecordArray @namespace DS @extends Ember.ArrayProxy @uses Ember.Evented */ DS.RecordArray = Ember.ArrayProxy.extend(Ember.Evented, { /** The model type contained by this record array. @property type @type DS.Model */ type: null, // The array of client ids backing the record array. When a // record is requested from the record array, the record // for the client id at the same index is materialized, if // necessary, by the store. content: null, isLoaded: false, isUpdating: false, // The store that created this record array. store: null, objectAtContent: function(index) { var content = get(this, 'content'); return content.objectAt(index); }, update: function() { if (get(this, 'isUpdating')) { return; } var store = get(this, 'store'), type = get(this, 'type'); store.fetchAll(type, this); }, addRecord: function(record) { get(this, 'content').addObject(record); }, removeRecord: function(record) { get(this, 'content').removeObject(record); }, save: function() { var promise = Ember.RSVP.all(this.invoke("save")).then(function(array) { return Ember.A(array); }); return DS.PromiseArray.create({ promise: promise }); } }); })(); (function() { /** @module ember-data */ var get = Ember.get; /** @class FilteredRecordArray @namespace DS @extends DS.RecordArray */ DS.FilteredRecordArray = DS.RecordArray.extend({ filterFunction: null, isLoaded: true, replace: function() { var type = get(this, 'type').toString(); throw new Error("The result of a client-side filter (on " + type + ") is immutable."); }, updateFilter: Ember.observer(function() { var manager = get(this, 'manager'); manager.updateFilter(this, get(this, 'type'), get(this, 'filterFunction')); }, 'filterFunction') }); })(); (function() { /** @module ember-data */ var get = Ember.get, set = Ember.set; /** @class AdapterPopulatedRecordArray @namespace DS @extends DS.RecordArray */ DS.AdapterPopulatedRecordArray = DS.RecordArray.extend({ query: null, replace: function() { var type = get(this, 'type').toString(); throw new Error("The result of a server query (on " + type + ") is immutable."); }, load: function(data) { var store = get(this, 'store'), type = get(this, 'type'), records = store.pushMany(type, data), meta = store.metadataFor(type); this.setProperties({ content: Ember.A(records), isLoaded: true, meta: meta }); // TODO: does triggering didLoad event should be the last action of the runLoop? Ember.run.once(this, 'trigger', 'didLoad'); } }); })(); (function() { /** @module ember-data */ var get = Ember.get, set = Ember.set; var map = Ember.EnumerableUtils.map; /** A ManyArray is a RecordArray that represents the contents of a has-many relationship. The ManyArray is instantiated lazily the first time the relationship is requested. ### Inverses Often, the relationships in Ember Data applications will have an inverse. For example, imagine the following models are defined: App.Post = DS.Model.extend({ comments: DS.hasMany('comment') }); App.Comment = DS.Model.extend({ post: DS.belongsTo('post') }); If you created a new instance of `App.Post` and added a `App.Comment` record to its `comments` has-many relationship, you would expect the comment's `post` property to be set to the post that contained the has-many. We call the record to which a relationship belongs the relationship's _owner_. @class ManyArray @namespace DS @extends DS.RecordArray */ DS.ManyArray = DS.RecordArray.extend({ init: function() { this._super.apply(this, arguments); this._changesToSync = Ember.OrderedSet.create(); }, /** The record to which this relationship belongs. @property {DS.Model} @private */ owner: null, /** `true` if the relationship is polymorphic, `false` otherwise. @property {Boolean} @private */ isPolymorphic: false, // LOADING STATE isLoaded: false, loadingRecordsCount: function(count) { this.loadingRecordsCount = count; }, loadedRecord: function() { this.loadingRecordsCount--; if (this.loadingRecordsCount === 0) { set(this, 'isLoaded', true); this.trigger('didLoad'); } }, fetch: function() { var records = get(this, 'content'), store = get(this, 'store'), owner = get(this, 'owner'), resolver = Ember.RSVP.defer(); var unloadedRecords = records.filterProperty('isEmpty', true); store.fetchMany(unloadedRecords, owner, resolver); }, // Overrides Ember.Array's replace method to implement replaceContent: function(index, removed, added) { // Map the array of record objects into an array of client ids. added = map(added, function(record) { Ember.assert("You cannot add '" + record.constructor.typeKey + "' records to this relationship (only '" + this.type.typeKey + "' allowed)", !this.type || record instanceof this.type); return record; }, this); this._super(index, removed, added); }, arrangedContentDidChange: function() { Ember.run.once(this, 'fetch'); }, arrayContentWillChange: function(index, removed, added) { var owner = get(this, 'owner'), name = get(this, 'name'); if (!owner._suspendedRelationships) { // This code is the first half of code that continues inside // of arrayContentDidChange. It gets or creates a change from // the child object, adds the current owner as the old // parent if this is the first time the object was removed // from a ManyArray, and sets `newParent` to null. // // Later, if the object is added to another ManyArray, // the `arrayContentDidChange` will set `newParent` on // the change. for (var i=index; i} records @param {String} type @param {Resolver} resolver @return DS.ManyArray */ findMany: function(owner, records, type, resolver) { type = this.modelFor(type); records = Ember.A(records); var unloadedRecords = records.filterProperty('isEmpty', true), manyArray = this.recordArrayManager.createManyArray(type, records); forEach(unloadedRecords, function(record) { record.loadingData(); }); manyArray.loadingRecordsCount = unloadedRecords.length; if (unloadedRecords.length) { forEach(unloadedRecords, function(record) { this.recordArrayManager.registerWaitingRecordArray(record, manyArray); }, this); this.fetchMany(unloadedRecords, owner, resolver); } else { if (resolver) { resolver.resolve(); } manyArray.set('isLoaded', true); Ember.run.once(manyArray, 'trigger', 'didLoad'); } return manyArray; }, /** If a relationship was originally populated by the adapter as a link (as opposed to a list of IDs), this method is called when the relationship is fetched. The link (which is usually a URL) is passed through unchanged, so the adapter can make whatever request it wants. The usual use-case is for the server to register a URL as a link, and then use that URL in the future to make a request for the relationship. @method findHasMany @private @param {DS.Model} owner @param {any} link @param {String} type @param {Resolver} resolver @return DS.ManyArray */ findHasMany: function(owner, link, relationship, resolver) { var adapter = this.adapterFor(owner.constructor); Ember.assert("You tried to load a hasMany relationship but you have no adapter (for " + owner.constructor + ")", adapter); Ember.assert("You tried to load a hasMany relationship from a specified `link` in the original payload but your adapter does not implement `findHasMany`", adapter.findHasMany); var records = this.recordArrayManager.createManyArray(relationship.type, Ember.A([])); _findHasMany(adapter, this, owner, link, relationship, resolver); return records; }, findBelongsTo: function(owner, link, relationship, resolver) { var adapter = this.adapterFor(owner.constructor); Ember.assert("You tried to load a belongsTo relationship but you have no adapter (for " + owner.constructor + ")", adapter); Ember.assert("You tried to load a belongsTo relationship from a specified `link` in the original payload but your adapter does not implement `findBelongsTo`", adapter.findBelongsTo); _findBelongsTo(adapter, this, owner, link, relationship, resolver); }, /** This method delegates a query to the adapter. This is the one place where adapter-level semantics are exposed to the application. Exposing queries this way seems preferable to creating an abstract query language for all server-side queries, and then require all adapters to implement them. This method returns a promise, which is resolved with a `RecordArray` once the server returns. @method findQuery @private @param {String} type @param {any} query an opaque query to be used by the adapter @return Promise */ findQuery: function(type, query) { type = this.modelFor(type); var array = DS.AdapterPopulatedRecordArray.create({ type: type, query: query, content: Ember.A(), store: this }); var adapter = this.adapterFor(type), resolver = Ember.RSVP.defer(); Ember.assert("You tried to load a query but you have no adapter (for " + type + ")", adapter); Ember.assert("You tried to load a query but your adapter does not implement `findQuery`", adapter.findQuery); _findQuery(adapter, this, type, query, array, resolver); return promiseArray(resolver.promise); }, /** This method returns an array of all records adapter can find. It triggers the adapter's `findAll` method to give it an opportunity to populate the array with records of that type. @method findAll @private @param {Class} type @return {DS.AdapterPopulatedRecordArray} */ findAll: function(type) { type = this.modelFor(type); return this.fetchAll(type, this.all(type)); }, /** @method fetchAll @private @param type @param array @returns Promise */ fetchAll: function(type, array) { var adapter = this.adapterFor(type), sinceToken = this.typeMapFor(type).metadata.since, resolver = Ember.RSVP.defer(); set(array, 'isUpdating', true); Ember.assert("You tried to load all records but you have no adapter (for " + type + ")", adapter); Ember.assert("You tried to load all records but your adapter does not implement `findAll`", adapter.findAll); _findAll(adapter, this, type, sinceToken, resolver); return promiseArray(resolver.promise); }, /** @method didUpdateAll @param type */ didUpdateAll: function(type) { var findAllCache = this.typeMapFor(type).findAllCache; set(findAllCache, 'isUpdating', false); }, /** This method returns a filtered array that contains all of the known records for a given type. Note that because it's just a filter, it will have any locally created records of the type. Also note that multiple calls to `all` for a given type will always return the same RecordArray. @method all @param {Class} type @return {DS.RecordArray} */ all: function(type) { type = this.modelFor(type); var typeMap = this.typeMapFor(type), findAllCache = typeMap.findAllCache; if (findAllCache) { return findAllCache; } var array = DS.RecordArray.create({ type: type, content: Ember.A(), store: this, isLoaded: true }); this.recordArrayManager.registerFilteredRecordArray(array, type); typeMap.findAllCache = array; return array; }, /** This method unloads all of the known records for a given type. @method unloadAll @param {Class} type */ unloadAll: function(type) { type = this.modelFor(type); var typeMap = this.typeMapFor(type), records = typeMap.records, record; while(record = records.pop()) { record.unloadRecord(); } }, /** Takes a type and filter function, and returns a live RecordArray that remains up to date as new records are loaded into the store or created locally. The callback function takes a materialized record, and returns true if the record should be included in the filter and false if it should not. The filter function is called once on all records for the type when it is created, and then once on each newly loaded or created record. If any of a record's properties change, or if it changes state, the filter function will be invoked again to determine whether it should still be in the array. @method filter @param {Class} type @param {Function} filter @return {DS.FilteredRecordArray} */ filter: function(type, query, filter) { var promise; // allow an optional server query if (arguments.length === 3) { promise = this.findQuery(type, query); } else if (arguments.length === 2) { filter = query; } type = this.modelFor(type); var array = DS.FilteredRecordArray.create({ type: type, content: Ember.A(), store: this, manager: this.recordArrayManager, filterFunction: filter }); this.recordArrayManager.registerFilteredRecordArray(array, type, filter); if (promise) { return promise.then(function() { return array; }); } else { return array; } }, /** This method returns if a certain record is already loaded in the store. Use this function to know beforehand if a find() will result in a request or that it will be a cache hit. @method recordIsLoaded @param {Class} type @param {string} id @return {boolean} */ recordIsLoaded: function(type, id) { if (!this.hasRecordForId(type, id)) { return false; } return !get(this.recordForId(type, id), 'isEmpty'); }, /** This method returns the metadata for a specific type. @method metadataFor @param {string} type @return {object} */ metadataFor: function(type) { type = this.modelFor(type); return this.typeMapFor(type).metadata; }, // ............ // . UPDATING . // ............ /** If the adapter updates attributes or acknowledges creation or deletion, the record will notify the store to update its membership in any filters. To avoid thrashing, this method is invoked only once per run loop per record. @method dataWasUpdated @private @param {Class} type @param {Number|String} clientId @param {DS.Model} record */ dataWasUpdated: function(type, record) { // Because data updates are invoked at the end of the run loop, // it is possible that a record might be deleted after its data // has been modified and this method was scheduled to be called. // // If that's the case, the record would have already been removed // from all record arrays; calling updateRecordArrays would just // add it back. If the record is deleted, just bail. It shouldn't // give us any more trouble after this. if (get(record, 'isDeleted')) { return; } if (get(record, 'isLoaded')) { this.recordArrayManager.recordDidChange(record); } }, // .............. // . PERSISTING . // .............. /** This method is called by `record.save`, and gets passed a resolver for the promise that `record.save` returns. It schedules saving to happen at the end of the run loop. @method scheduleSave @private @param {DS.Model} record @param {Resolver} resolver */ scheduleSave: function(record, resolver) { record.adapterWillCommit(); this._pendingSave.push([record, resolver]); once(this, 'flushPendingSave'); }, /** This method is called at the end of the run loop, and flushes any records passed into `scheduleSave` @method flushPendingSave @private */ flushPendingSave: function() { var pending = this._pendingSave.slice(); this._pendingSave = []; forEach(pending, function(tuple) { var record = tuple[0], resolver = tuple[1], adapter = this.adapterFor(record.constructor), operation; if (get(record, 'isNew')) { operation = 'createRecord'; } else if (get(record, 'isDeleted')) { operation = 'deleteRecord'; } else { operation = 'updateRecord'; } _commit(adapter, this, operation, record, resolver); }, this); }, /** This method is called once the promise returned by an adapter's `createRecord`, `updateRecord` or `deleteRecord` is resolved. If the data provides a server-generated ID, it will update the record and the store's indexes. @method didSaveRecord @private @param {DS.Model} record the in-flight record @param {Object} data optional data (see above) */ didSaveRecord: function(record, data) { if (data) { // normalize relationship IDs into records data = normalizeRelationships(this, record.constructor, data, record); this.updateId(record, data); } record.adapterDidCommit(data); }, /** This method is called once the promise returned by an adapter's `createRecord`, `updateRecord` or `deleteRecord` is rejected with a `DS.InvalidError`. @method recordWasInvalid @private @param {DS.Model} record @param {Object} errors */ recordWasInvalid: function(record, errors) { record.adapterDidInvalidate(errors); }, /** This method is called once the promise returned by an adapter's `createRecord`, `updateRecord` or `deleteRecord` is rejected (with anything other than a `DS.InvalidError`). @method recordWasError @private @param {DS.Model} record */ recordWasError: function(record) { record.adapterDidError(); }, /** When an adapter's `createRecord`, `updateRecord` or `deleteRecord` resolves with data, this method extracts the ID from the supplied data. @method updateId @private @param {DS.Model} record @param {Object} data */ updateId: function(record, data) { var oldId = get(record, 'id'), id = coerceId(data.id); Ember.assert("An adapter cannot assign a new id to a record that already has an id. " + record + " had id: " + oldId + " and you tried to update it with " + id + ". This likely happened because your server returned data in response to a find or update that had a different id than the one you sent.", oldId === null || id === oldId); this.typeMapFor(record.constructor).idToRecord[id] = record; set(record, 'id', id); }, /** Returns a map of IDs to client IDs for a given type. @method typeMapFor @private @param type */ typeMapFor: function(type) { var typeMaps = get(this, 'typeMaps'), guid = Ember.guidFor(type), typeMap; typeMap = typeMaps[guid]; if (typeMap) { return typeMap; } typeMap = { idToRecord: {}, records: [], metadata: {} }; typeMaps[guid] = typeMap; return typeMap; }, // ................ // . LOADING DATA . // ................ /** This internal method is used by `push`. @method _load @private @param {DS.Model} type @param {Object} data @param {Boolean} partial the data should be merged into the existing data, not replace it. */ _load: function(type, data, partial) { var id = coerceId(data.id), record = this.recordForId(type, id); record.setupData(data, partial); this.recordArrayManager.recordDidChange(record); return record; }, /** Returns a model class for a particular key. Used by methods that take a type key (like `find`, `createRecord`, etc.) @method modelFor @param {String or subclass of DS.Model} key @returns {subclass of DS.Model} */ modelFor: function(key) { var factory; if (typeof key === 'string') { factory = this.container.lookupFactory('model:' + key); Ember.assert("No model was found for '" + key + "'", factory); factory.typeKey = key; } else { // A factory already supplied. factory = key; } factory.store = this; return factory; }, /** Push some data for a given type into the store. This method expects normalized data: * The ID is a key named `id` (an ID is mandatory) * The names of attributes are the ones you used in your model's `DS.attr`s. * Your relationships must be: * represented as IDs or Arrays of IDs * represented as model instances * represented as URLs, under the `links` key For this model: ```js App.Person = DS.Model.extend({ firstName: DS.attr(), lastName: DS.attr(), children: DS.hasMany('person') }); ``` To represent the children as IDs: ```js { id: 1, firstName: "Tom", lastName: "Dale", children: [1, 2, 3] } ``` To represent the children relationship as a URL: ```js { id: 1, firstName: "Tom", lastName: "Dale", links: { children: "/people/1/children" } } ``` If you're streaming data or implementing an adapter, make sure that you have converted the incoming data into this form. This method can be used both to push in brand new records, as well as to update existing records. @method push @param {String} type @param {Object} data @returns DS.Model the record that was created or updated. */ push: function(type, data, _partial) { // _partial is an internal param used by `update`. // If passed, it means that the data should be // merged into the existing data, not replace it. Ember.assert("You must include an `id` in a hash passed to `push`", data.id != null); type = this.modelFor(type); // normalize relationship IDs into records data = normalizeRelationships(this, type, data); this._load(type, data, _partial); return this.recordForId(type, data.id); }, /** Push some raw data into the store. The data will be automatically deserialized using the serializer for the `type` param. This method can be used both to push in brand new records, as well as to update existing records. You can push in more than one type of object at once. All objects should be in the format expected by the serializer. ```js App.ApplicationSerializer = DS.ActiveModelSerializer; var pushData = { posts: [ {id: 1, post_title: "Great post", comment_ids: [2]} ], comments: [ {id: 2, comment_body: "Insightful comment"} ] } store.pushPayload('post', pushData); ``` @method push @param {String} type @param {Object} payload */ pushPayload: function (type, payload) { var serializer = this.serializerFor(type); serializer.pushPayload(this, payload); }, update: function(type, data) { Ember.assert("You must include an `id` in a hash passed to `update`", data.id != null); return this.push(type, data, true); }, /** If you have an Array of normalized data to push, you can call `pushMany` with the Array, and it will call `push` repeatedly for you. @method pushMany @param {String} type @param {Array} datas @return {Array} */ pushMany: function(type, datas) { return map(datas, function(data) { return this.push(type, data); }, this); }, /** If you have some metadata to set for a type you can call `metaForType`. @method metaForType @param {String} type @param {Object} metadata */ metaForType: function(type, metadata) { type = this.modelFor(type); Ember.merge(this.typeMapFor(type).metadata, metadata); }, /** Build a brand new record for a given type, ID, and initial data. @method buildRecord @private @param {subclass of DS.Model} type @param {String} id @param {Object} data @returns DS.Model */ buildRecord: function(type, id, data) { var typeMap = this.typeMapFor(type), idToRecord = typeMap.idToRecord; Ember.assert('The id ' + id + ' has already been used with another record of type ' + type.toString() + '.', !id || !idToRecord[id]); // lookupFactory should really return an object that creates // instances with the injections applied var record = type._create({ id: id, store: this, container: this.container }); if (data) { record.setupData(data); } // if we're creating an item, this process will be done // later, once the object has been persisted. if (id) { idToRecord[id] = record; } typeMap.records.push(record); return record; }, // ............... // . DESTRUCTION . // ............... /** When a record is destroyed, this un-indexes it and removes it from any record arrays so it can be GCed. @method dematerializeRecord @private @param {DS.Model} record */ dematerializeRecord: function(record) { var type = record.constructor, typeMap = this.typeMapFor(type), id = get(record, 'id'); record.updateRecordArrays(); if (id) { delete typeMap.idToRecord[id]; } var loc = indexOf(typeMap.records, record); typeMap.records.splice(loc, 1); }, // ........................ // . RELATIONSHIP CHANGES . // ........................ addRelationshipChangeFor: function(childRecord, childKey, parentRecord, parentKey, change) { var clientId = childRecord.clientId, parentClientId = parentRecord ? parentRecord : parentRecord; var key = childKey + parentKey; var changes = this._relationshipChanges; if (!(clientId in changes)) { changes[clientId] = {}; } if (!(parentClientId in changes[clientId])) { changes[clientId][parentClientId] = {}; } if (!(key in changes[clientId][parentClientId])) { changes[clientId][parentClientId][key] = {}; } changes[clientId][parentClientId][key][change.changeType] = change; }, removeRelationshipChangeFor: function(clientRecord, childKey, parentRecord, parentKey, type) { var clientId = clientRecord.clientId, parentClientId = parentRecord ? parentRecord.clientId : parentRecord; var changes = this._relationshipChanges; var key = childKey + parentKey; if (!(clientId in changes) || !(parentClientId in changes[clientId]) || !(key in changes[clientId][parentClientId])){ return; } delete changes[clientId][parentClientId][key][type]; }, relationshipChangePairsFor: function(record){ var toReturn = []; if( !record ) { return toReturn; } //TODO(Igor) What about the other side var changesObject = this._relationshipChanges[record.clientId]; for (var objKey in changesObject){ if(changesObject.hasOwnProperty(objKey)){ for (var changeKey in changesObject[objKey]){ if(changesObject[objKey].hasOwnProperty(changeKey)){ toReturn.push(changesObject[objKey][changeKey]); } } } } return toReturn; }, // ...................... // . PER-TYPE ADAPTERS // ...................... /** Returns the adapter for a given type. @method adapterFor @private @param {subclass of DS.Model} type @returns DS.Adapter */ adapterFor: function(type) { var container = this.container, adapter; if (container) { adapter = container.lookup('adapter:' + type.typeKey) || container.lookup('adapter:application'); } return adapter || get(this, 'defaultAdapter'); }, // .............................. // . RECORD CHANGE NOTIFICATION . // .............................. /** Returns an instance of the serializer for a given type. For example, `serializerFor('person')` will return an instance of `App.PersonSerializer`. If no `App.PersonSerializer` is found, this method will look for an `App.ApplicationSerializer` (the default serializer for your entire application). If no `App.ApplicationSerializer` is found, it will fall back to an instance of `DS.JSONSerializer`. @method serializerFor @private @param {String} type the record to serialize */ serializerFor: function(type) { type = this.modelFor(type); var adapter = this.adapterFor(type); return serializerFor(this.container, type.typeKey, adapter && adapter.defaultSerializer); } }); function normalizeRelationships(store, type, data, record) { type.eachRelationship(function(key, relationship) { // A link (usually a URL) was already provided in // normalized form if (data.links && data.links[key]) { if (record && relationship.options.async) { record._relationships[key] = null; } return; } var kind = relationship.kind, value = data[key]; if (value == null) { return; } if (kind === 'belongsTo') { deserializeRecordId(store, data, key, relationship, value); } else if (kind === 'hasMany') { deserializeRecordIds(store, data, key, relationship, value); addUnsavedRecords(record, key, value); } }); return data; } function deserializeRecordId(store, data, key, relationship, id) { if (isNone(id) || id instanceof DS.Model) { return; } var type; if (typeof id === 'number' || typeof id === 'string') { type = typeFor(relationship, key, data); data[key] = store.recordForId(type, id); } else if (typeof id === 'object') { // polymorphic data[key] = store.recordForId(id.type, id.id); } } function typeFor(relationship, key, data) { if (relationship.options.polymorphic) { return data[key + "Type"]; } else { return relationship.type; } } function deserializeRecordIds(store, data, key, relationship, ids) { for (var i=0, l=ids.length; i "created.uncommitted" The `DS.Model` states are themselves stateless. What we mean is that, though each instance of a record also has a unique instance of a `DS.StateManager`, the hierarchical states that each of *those* points to is a shared data structure. For performance reasons, instead of each record getting its own copy of the hierarchy of states, each state manager points to this global, immutable shared instance. How does a state know which record it should be acting on? We pass a reference to the current state manager as the first parameter to every method invoked on a state. The state manager passed as the first parameter is where you should stash state about the record if needed; you should never store data on the state object itself. If you need access to the record being acted on, you can retrieve the state manager's `record` property. For example, if you had an event handler `myEvent`: myEvent: function(manager) { var record = manager.get('record'); record.doSomething(); } For more information about state managers in general, see the Ember.js documentation on `Ember.StateManager`. ### Events, Flags, and Transitions A state may implement zero or more events, flags, or transitions. #### Events Events are named functions that are invoked when sent to a record. The state manager will first look for a method with the given name on the current state. If no method is found, it will search the current state's parent, and then its grandparent, and so on until reaching the top of the hierarchy. If the root is reached without an event handler being found, an exception will be raised. This can be very helpful when debugging new features. Here's an example implementation of a state with a `myEvent` event handler: aState: DS.State.create({ myEvent: function(manager, param) { console.log("Received myEvent with "+param); } }) To trigger this event: record.send('myEvent', 'foo'); //=> "Received myEvent with foo" Note that an optional parameter can be sent to a record's `send()` method, which will be passed as the second parameter to the event handler. Events should transition to a different state if appropriate. This can be done by calling the state manager's `transitionTo()` method with a path to the desired state. The state manager will attempt to resolve the state path relative to the current state. If no state is found at that path, it will attempt to resolve it relative to the current state's parent, and then its parent, and so on until the root is reached. For example, imagine a hierarchy like this: * created * start <-- currentState * inFlight * updated * inFlight If we are currently in the `start` state, calling `transitionTo('inFlight')` would transition to the `created.inFlight` state, while calling `transitionTo('updated.inFlight')` would transition to the `updated.inFlight` state. Remember that *only events* should ever cause a state transition. You should never call `transitionTo()` from outside a state's event handler. If you are tempted to do so, create a new event and send that to the state manager. #### Flags Flags are Boolean values that can be used to introspect a record's current state in a more user-friendly way than examining its state path. For example, instead of doing this: var statePath = record.get('stateManager.currentPath'); if (statePath === 'created.inFlight') { doSomething(); } You can say: if (record.get('isNew') && record.get('isSaving')) { doSomething(); } If your state does not set a value for a given flag, the value will be inherited from its parent (or the first place in the state hierarchy where it is defined). The current set of flags are defined below. If you want to add a new flag, in addition to the area below, you will also need to declare it in the `DS.Model` class. #### Transitions Transitions are like event handlers but are called automatically upon entering or exiting a state. To implement a transition, just call a method either `enter` or `exit`: myState: DS.State.create({ // Gets called automatically when entering // this state. enter: function(manager) { console.log("Entered myState"); } }) Note that enter and exit events are called once per transition. If the current state changes, but changes to another child state of the parent, the transition event on the parent will not be triggered. */ var hasDefinedProperties = function(object) { // Ignore internal property defined by simulated `Ember.create`. var names = Ember.keys(object); var i, l, name; for (i = 0, l = names.length; i < l; i++ ) { name = names[i]; if (object.hasOwnProperty(name) && object[name]) { return true; } } return false; }; var didSetProperty = function(record, context) { if (context.value === context.originalValue) { delete record._attributes[context.name]; record.send('propertyWasReset', context.name); } else if (context.value !== context.oldValue) { record.send('becomeDirty'); } record.updateRecordArraysLater(); }; // Implementation notes: // // Each state has a boolean value for all of the following flags: // // * isLoaded: The record has a populated `data` property. When a // record is loaded via `store.find`, `isLoaded` is false // until the adapter sets it. When a record is created locally, // its `isLoaded` property is always true. // * isDirty: The record has local changes that have not yet been // saved by the adapter. This includes records that have been // created (but not yet saved) or deleted. // * isSaving: The record has been committed, but // the adapter has not yet acknowledged that the changes have // been persisted to the backend. // * isDeleted: The record was marked for deletion. When `isDeleted` // is true and `isDirty` is true, the record is deleted locally // but the deletion was not yet persisted. When `isSaving` is // true, the change is in-flight. When both `isDirty` and // `isSaving` are false, the change has persisted. // * isError: The adapter reported that it was unable to save // local changes to the backend. This may also result in the // record having its `isValid` property become false if the // adapter reported that server-side validations failed. // * isNew: The record was created on the client and the adapter // did not yet report that it was successfully saved. // * isValid: No client-side validations have failed and the // adapter did not report any server-side validation failures. // The dirty state is a abstract state whose functionality is // shared between the `created` and `updated` states. // // The deleted state shares the `isDirty` flag with the // subclasses of `DirtyState`, but with a very different // implementation. // // Dirty states have three child states: // // `uncommitted`: the store has not yet handed off the record // to be saved. // `inFlight`: the store has handed off the record to be saved, // but the adapter has not yet acknowledged success. // `invalid`: the record has invalid information and cannot be // send to the adapter yet. var DirtyState = { initialState: 'uncommitted', // FLAGS isDirty: true, // SUBSTATES // When a record first becomes dirty, it is `uncommitted`. // This means that there are local pending changes, but they // have not yet begun to be saved, and are not invalid. uncommitted: { // EVENTS didSetProperty: didSetProperty, propertyWasReset: function(record, name) { var stillDirty = false; for (var prop in record._attributes) { stillDirty = true; break; } if (!stillDirty) { record.send('rolledBack'); } }, pushedData: Ember.K, becomeDirty: Ember.K, willCommit: function(record) { record.transitionTo('inFlight'); }, reloadRecord: function(record, resolver) { get(record, 'store').reloadRecord(record, resolver); }, rolledBack: function(record) { record.transitionTo('loaded.saved'); }, becameInvalid: function(record) { record.transitionTo('invalid'); }, rollback: function(record) { record.rollback(); } }, // Once a record has been handed off to the adapter to be // saved, it is in the 'in flight' state. Changes to the // record cannot be made during this window. inFlight: { // FLAGS isSaving: true, // EVENTS didSetProperty: didSetProperty, becomeDirty: Ember.K, pushedData: Ember.K, // TODO: More robust semantics around save-while-in-flight willCommit: Ember.K, didCommit: function(record) { var dirtyType = get(this, 'dirtyType'); record.transitionTo('saved'); record.send('invokeLifecycleCallbacks', dirtyType); }, becameInvalid: function(record, errors) { set(record, 'errors', errors); record.transitionTo('invalid'); record.send('invokeLifecycleCallbacks'); }, becameError: function(record) { record.transitionTo('uncommitted'); record.triggerLater('becameError', record); } }, // A record is in the `invalid` state when its client-side // invalidations have failed, or if the adapter has indicated // the the record failed server-side invalidations. invalid: { // FLAGS isValid: false, // EVENTS deleteRecord: function(record) { record.transitionTo('deleted.uncommitted'); record.clearRelationships(); }, didSetProperty: function(record, context) { var errors = get(record, 'errors'), key = context.name; set(errors, key, null); if (!hasDefinedProperties(errors)) { record.send('becameValid'); } didSetProperty(record, context); }, becomeDirty: Ember.K, rollback: function(record) { record.send('becameValid'); record.send('rollback'); }, becameValid: function(record) { record.transitionTo('uncommitted'); }, invokeLifecycleCallbacks: function(record) { record.triggerLater('becameInvalid', record); } } }; // The created and updated states are created outside the state // chart so we can reopen their substates and add mixins as // necessary. function deepClone(object) { var clone = {}, value; for (var prop in object) { value = object[prop]; if (value && typeof value === 'object') { clone[prop] = deepClone(value); } else { clone[prop] = value; } } return clone; } function mixin(original, hash) { for (var prop in hash) { original[prop] = hash[prop]; } return original; } function dirtyState(options) { var newState = deepClone(DirtyState); return mixin(newState, options); } var createdState = dirtyState({ dirtyType: 'created', // FLAGS isNew: true }); createdState.uncommitted.rolledBack = function(record) { record.transitionTo('deleted.saved'); }; var updatedState = dirtyState({ dirtyType: 'updated' }); createdState.uncommitted.deleteRecord = function(record) { record.clearRelationships(); record.transitionTo('deleted.saved'); }; createdState.uncommitted.rollback = function(record) { DirtyState.uncommitted.rollback.apply(this, arguments); record.transitionTo('deleted.saved'); }; updatedState.uncommitted.deleteRecord = function(record) { record.transitionTo('deleted.uncommitted'); record.clearRelationships(); }; var RootState = { // FLAGS isEmpty: false, isLoading: false, isLoaded: false, isDirty: false, isSaving: false, isDeleted: false, isNew: false, isValid: true, // DEFAULT EVENTS // Trying to roll back if you're not in the dirty state // doesn't change your state. For example, if you're in the // in-flight state, rolling back the record doesn't move // you out of the in-flight state. rolledBack: Ember.K, propertyWasReset: Ember.K, // SUBSTATES // A record begins its lifecycle in the `empty` state. // If its data will come from the adapter, it will // transition into the `loading` state. Otherwise, if // the record is being created on the client, it will // transition into the `created` state. empty: { isEmpty: true, // EVENTS loadingData: function(record, promise) { record._loadingPromise = promise; record.transitionTo('loading'); }, loadedData: function(record) { record.transitionTo('loaded.created.uncommitted'); record.suspendRelationshipObservers(function() { record.notifyPropertyChange('data'); }); }, pushedData: function(record) { record.transitionTo('loaded.saved'); record.triggerLater('didLoad'); } }, // A record enters this state when the store askes // the adapter for its data. It remains in this state // until the adapter provides the requested data. // // Usually, this process is asynchronous, using an // XHR to retrieve the data. loading: { // FLAGS isLoading: true, exit: function(record) { record._loadingPromise = null; }, // EVENTS pushedData: function(record) { record.transitionTo('loaded.saved'); record.triggerLater('didLoad'); set(record, 'isError', false); }, becameError: function(record) { record.triggerLater('becameError', record); }, notFound: function(record) { record.transitionTo('empty'); } }, // A record enters this state when its data is populated. // Most of a record's lifecycle is spent inside substates // of the `loaded` state. loaded: { initialState: 'saved', // FLAGS isLoaded: true, // SUBSTATES // If there are no local changes to a record, it remains // in the `saved` state. saved: { setup: function(record) { var attrs = record._attributes, isDirty = false; for (var prop in attrs) { if (attrs.hasOwnProperty(prop)) { isDirty = true; break; } } if (isDirty) { record.adapterDidDirty(); } }, // EVENTS didSetProperty: didSetProperty, pushedData: Ember.K, becomeDirty: function(record) { record.transitionTo('updated.uncommitted'); }, willCommit: function(record) { record.transitionTo('updated.inFlight'); }, reloadRecord: function(record, resolver) { get(record, 'store').reloadRecord(record, resolver); }, deleteRecord: function(record) { record.transitionTo('deleted.uncommitted'); record.clearRelationships(); }, unloadRecord: function(record) { // clear relationships before moving to deleted state // otherwise it fails record.clearRelationships(); record.transitionTo('deleted.saved'); }, didCommit: function(record) { record.send('invokeLifecycleCallbacks', get(record, 'lastDirtyType')); } }, // A record is in this state after it has been locally // created but before the adapter has indicated that // it has been saved. created: createdState, // A record is in this state if it has already been // saved to the server, but there are new local changes // that have not yet been saved. updated: updatedState }, // A record is in this state if it was deleted from the store. deleted: { initialState: 'uncommitted', dirtyType: 'deleted', // FLAGS isDeleted: true, isLoaded: true, isDirty: true, // TRANSITIONS setup: function(record) { var store = get(record, 'store'); store.recordArrayManager.remove(record); }, // SUBSTATES // When a record is deleted, it enters the `start` // state. It will exit this state when the record // starts to commit. uncommitted: { // EVENTS willCommit: function(record) { record.transitionTo('inFlight'); }, rollback: function(record) { record.rollback(); }, becomeDirty: Ember.K, deleteRecord: Ember.K, rolledBack: function(record) { record.transitionTo('loaded.saved'); } }, // After a record starts committing, but // before the adapter indicates that the deletion // has saved to the server, a record is in the // `inFlight` substate of `deleted`. inFlight: { // FLAGS isSaving: true, // EVENTS // TODO: More robust semantics around save-while-in-flight willCommit: Ember.K, didCommit: function(record) { record.transitionTo('saved'); record.send('invokeLifecycleCallbacks'); }, becameError: function(record) { record.transitionTo('uncommitted'); record.triggerLater('becameError', record); } }, // Once the adapter indicates that the deletion has // been saved, the record enters the `saved` substate // of `deleted`. saved: { // FLAGS isDirty: false, setup: function(record) { var store = get(record, 'store'); store.dematerializeRecord(record); }, invokeLifecycleCallbacks: function(record) { record.triggerLater('didDelete', record); record.triggerLater('didCommit', record); } } }, invokeLifecycleCallbacks: function(record, dirtyType) { if (dirtyType === 'created') { record.triggerLater('didCreate', record); } else { record.triggerLater('didUpdate', record); } record.triggerLater('didCommit', record); } }; function wireState(object, parent, name) { /*jshint proto:true*/ // TODO: Use Object.create and copy instead object = mixin(parent ? Ember.create(parent) : {}, object); object.parentState = parent; object.stateName = name; for (var prop in object) { if (!object.hasOwnProperty(prop) || prop === 'parentState' || prop === 'stateName') { continue; } if (typeof object[prop] === 'object') { object[prop] = wireState(object[prop], object, name + "." + prop); } } return object; } RootState = wireState(RootState, null, "root"); DS.RootState = RootState; })(); (function() { /** @module ember-data */ var get = Ember.get, set = Ember.set, merge = Ember.merge, once = Ember.run.once; var retrieveFromCurrentState = Ember.computed(function(key, value) { return get(get(this, 'currentState'), key); }).property('currentState').readOnly(); /** The model class that all Ember Data records descend from. @class Model @namespace DS @extends Ember.Object @uses Ember.Evented */ DS.Model = Ember.Object.extend(Ember.Evented, { isEmpty: retrieveFromCurrentState, isLoading: retrieveFromCurrentState, isLoaded: retrieveFromCurrentState, isDirty: retrieveFromCurrentState, isSaving: retrieveFromCurrentState, isDeleted: retrieveFromCurrentState, isNew: retrieveFromCurrentState, isValid: retrieveFromCurrentState, dirtyType: retrieveFromCurrentState, isError: false, isReloading: false, clientId: null, id: null, transaction: null, currentState: null, errors: null, /** Create a JSON representation of the record, using the serialization strategy of the store's adapter. @method serialize @param {Object} options Available options: * `includeId`: `true` if the record's ID should be included in the JSON representation. @returns {Object} an object whose values are primitive JSON values only */ serialize: function(options) { var store = get(this, 'store'); return store.serialize(this, options); }, /** Use {{#crossLink "DS.JSONSerializer"}}DS.JSONSerializer{{/crossLink}} to get the JSON representation of a record. @method toJSON @param {Object} options Available options: * `includeId`: `true` if the record's ID should be included in the JSON representation. @returns {Object} A JSON representation of the object. */ toJSON: function(options) { // container is for lazy transform lookups var serializer = DS.JSONSerializer.create({ container: this.container }); return serializer.serialize(this, options); }, /** Fired when the record is loaded from the server. @event didLoad */ didLoad: Ember.K, /** Fired when the record is reloaded from the server. @event didReload */ didReload: Ember.K, /** Fired when the record is updated. @event didUpdate */ didUpdate: Ember.K, /** Fired when the record is created. @event didCreate */ didCreate: Ember.K, /** Fired when the record is deleted. @event didDelete */ didDelete: Ember.K, /** Fired when the record becomes invalid. @event becameInvalid */ becameInvalid: Ember.K, /** Fired when the record enters the error state. @event becameError */ becameError: Ember.K, data: Ember.computed(function() { this._data = this._data || {}; return this._data; }).property(), _data: null, init: function() { set(this, 'currentState', DS.RootState.empty); this._super(); this._setup(); }, _setup: function() { this._changesToSync = {}; this._deferredTriggers = []; this._data = {}; this._attributes = {}; this._inFlightAttributes = {}; this._relationships = {}; }, send: function(name, context) { var currentState = get(this, 'currentState'); if (!currentState[name]) { this._unhandledEvent(currentState, name, context); } return currentState[name](this, context); }, transitionTo: function(name) { // POSSIBLE TODO: Remove this code and replace with // always having direct references to state objects var pivotName = name.split(".", 1), currentState = get(this, 'currentState'), state = currentState; do { if (state.exit) { state.exit(this); } state = state.parentState; } while (!state.hasOwnProperty(pivotName)); var path = name.split("."); var setups = [], enters = [], i, l; for (i=0, l=path.length; i')` from " + this.toString(), name !== 'id'); meta.name = name; map.set(name, meta); } }); return map; }), transformedAttributes: Ember.computed(function() { var map = Ember.Map.create(); this.eachAttribute(function(key, meta) { if (meta.type) { map.set(key, meta.type); } }); return map; }), eachAttribute: function(callback, binding) { get(this, 'attributes').forEach(function(name, meta) { callback.call(binding, name, meta); }, binding); }, eachTransformedAttribute: function(callback, binding) { get(this, 'transformedAttributes').forEach(function(name, type) { callback.call(binding, name, type); }); } }); DS.Model.reopen({ eachAttribute: function(callback, binding) { this.constructor.eachAttribute(callback, binding); } }); function getDefaultValue(record, options, key) { if (typeof options.defaultValue === "function") { return options.defaultValue(); } else { return options.defaultValue; } } function hasValue(record, key) { return record._attributes.hasOwnProperty(key) || record._inFlightAttributes.hasOwnProperty(key) || record._data.hasOwnProperty(key); } function getValue(record, key) { if (record._attributes.hasOwnProperty(key)) { return record._attributes[key]; } else if (record._inFlightAttributes.hasOwnProperty(key)) { return record._inFlightAttributes[key]; } else { return record._data[key]; } } /** `DS.attr` defines an attribute on a DS.Model. By default, attributes are passed through as-is, however you can specify an optional type to have the value automatically transformed. Ember Data ships with four basic transform types: 'string', 'number', 'boolean' and 'date'. You can define your own transforms by subclassing DS.Transform. DS.attr takes an optional hash as a second parameter, currently supported options are: 'defaultValue': Pass a string or a function to be called to set the attribute to a default value if none is supplied. @method attr @param {String} type the attribute type @param {Object} options a hash of options */ DS.attr = function(type, options) { options = options || {}; var meta = { type: type, isAttribute: true, options: options }; return Ember.computed(function(key, value) { if (arguments.length > 1) { Ember.assert("You may not set `id` as an attribute on your model. Please remove any lines that look like: `id: DS.attr('')` from " + this.constructor.toString(), key !== 'id'); var oldValue = this._attributes[key] || this._inFlightAttributes[key] || this._data[key]; this.send('didSetProperty', { name: key, oldValue: oldValue, originalValue: this._data[key], value: value }); this._attributes[key] = value; return value; } else if (hasValue(this, key)) { return getValue(this, key); } else { return getDefaultValue(this, options, key); } // `data` is never set directly. However, it may be // invalidated from the state manager's setData // event. }).property('data').meta(meta); }; })(); (function() { /** @module ember-data */ })(); (function() { /** @module ember-data */ /** An AttributeChange object is created whenever a record's attribute changes value. It is used to track changes to a record between transaction commits. @class AttributeChange @namespace DS @private @constructor */ var AttributeChange = DS.AttributeChange = function(options) { this.record = options.record; this.store = options.store; this.name = options.name; this.value = options.value; this.oldValue = options.oldValue; }; AttributeChange.createChange = function(options) { return new AttributeChange(options); }; AttributeChange.prototype = { sync: function() { if (this.value !== this.oldValue) { this.record.send('becomeDirty'); this.record.updateRecordArraysLater(); } // TODO: Use this object in the commit process this.destroy(); }, /** If the AttributeChange is destroyed (either by being rolled back or being committed), remove it from the list of pending changes on the record. @method destroy */ destroy: function() { delete this.record._changesToSync[this.name]; } }; })(); (function() { /** @module ember-data */ var get = Ember.get, set = Ember.set; var forEach = Ember.EnumerableUtils.forEach; /** @class RelationshipChange @namespace DS @private @construtor */ DS.RelationshipChange = function(options) { this.parentRecord = options.parentRecord; this.childRecord = options.childRecord; this.firstRecord = options.firstRecord; this.firstRecordKind = options.firstRecordKind; this.firstRecordName = options.firstRecordName; this.secondRecord = options.secondRecord; this.secondRecordKind = options.secondRecordKind; this.secondRecordName = options.secondRecordName; this.changeType = options.changeType; this.store = options.store; this.committed = {}; }; /** @class RelationshipChangeAdd @namespace DS @private @construtor */ DS.RelationshipChangeAdd = function(options){ DS.RelationshipChange.call(this, options); }; /** @class RelationshipChangeRemove @namespace DS @private @construtor */ DS.RelationshipChangeRemove = function(options){ DS.RelationshipChange.call(this, options); }; DS.RelationshipChange.create = function(options) { return new DS.RelationshipChange(options); }; DS.RelationshipChangeAdd.create = function(options) { return new DS.RelationshipChangeAdd(options); }; DS.RelationshipChangeRemove.create = function(options) { return new DS.RelationshipChangeRemove(options); }; DS.OneToManyChange = {}; DS.OneToNoneChange = {}; DS.ManyToNoneChange = {}; DS.OneToOneChange = {}; DS.ManyToManyChange = {}; DS.RelationshipChange._createChange = function(options){ if(options.changeType === "add"){ return DS.RelationshipChangeAdd.create(options); } if(options.changeType === "remove"){ return DS.RelationshipChangeRemove.create(options); } }; DS.RelationshipChange.determineRelationshipType = function(recordType, knownSide){ var knownKey = knownSide.key, key, otherKind; var knownKind = knownSide.kind; var inverse = recordType.inverseFor(knownKey); if (inverse){ key = inverse.name; otherKind = inverse.kind; } if (!inverse){ return knownKind === "belongsTo" ? "oneToNone" : "manyToNone"; } else{ if(otherKind === "belongsTo"){ return knownKind === "belongsTo" ? "oneToOne" : "manyToOne"; } else{ return knownKind === "belongsTo" ? "oneToMany" : "manyToMany"; } } }; DS.RelationshipChange.createChange = function(firstRecord, secondRecord, store, options){ // Get the type of the child based on the child's client ID var firstRecordType = firstRecord.constructor, changeType; changeType = DS.RelationshipChange.determineRelationshipType(firstRecordType, options); if (changeType === "oneToMany"){ return DS.OneToManyChange.createChange(firstRecord, secondRecord, store, options); } else if (changeType === "manyToOne"){ return DS.OneToManyChange.createChange(secondRecord, firstRecord, store, options); } else if (changeType === "oneToNone"){ return DS.OneToNoneChange.createChange(firstRecord, secondRecord, store, options); } else if (changeType === "manyToNone"){ return DS.ManyToNoneChange.createChange(firstRecord, secondRecord, store, options); } else if (changeType === "oneToOne"){ return DS.OneToOneChange.createChange(firstRecord, secondRecord, store, options); } else if (changeType === "manyToMany"){ return DS.ManyToManyChange.createChange(firstRecord, secondRecord, store, options); } }; DS.OneToNoneChange.createChange = function(childRecord, parentRecord, store, options) { var key = options.key; var change = DS.RelationshipChange._createChange({ parentRecord: parentRecord, childRecord: childRecord, firstRecord: childRecord, store: store, changeType: options.changeType, firstRecordName: key, firstRecordKind: "belongsTo" }); store.addRelationshipChangeFor(childRecord, key, parentRecord, null, change); return change; }; DS.ManyToNoneChange.createChange = function(childRecord, parentRecord, store, options) { var key = options.key; var change = DS.RelationshipChange._createChange({ parentRecord: childRecord, childRecord: parentRecord, secondRecord: childRecord, store: store, changeType: options.changeType, secondRecordName: options.key, secondRecordKind: "hasMany" }); store.addRelationshipChangeFor(childRecord, key, parentRecord, null, change); return change; }; DS.ManyToManyChange.createChange = function(childRecord, parentRecord, store, options) { // If the name of the belongsTo side of the relationship is specified, // use that // If the type of the parent is specified, look it up on the child's type // definition. var key = options.key; var change = DS.RelationshipChange._createChange({ parentRecord: parentRecord, childRecord: childRecord, firstRecord: childRecord, secondRecord: parentRecord, firstRecordKind: "hasMany", secondRecordKind: "hasMany", store: store, changeType: options.changeType, firstRecordName: key }); store.addRelationshipChangeFor(childRecord, key, parentRecord, null, change); return change; }; DS.OneToOneChange.createChange = function(childRecord, parentRecord, store, options) { var key; // If the name of the belongsTo side of the relationship is specified, // use that // If the type of the parent is specified, look it up on the child's type // definition. if (options.parentType) { key = options.parentType.inverseFor(options.key).name; } else if (options.key) { key = options.key; } else { Ember.assert("You must pass either a parentType or belongsToName option to OneToManyChange.forChildAndParent", false); } var change = DS.RelationshipChange._createChange({ parentRecord: parentRecord, childRecord: childRecord, firstRecord: childRecord, secondRecord: parentRecord, firstRecordKind: "belongsTo", secondRecordKind: "belongsTo", store: store, changeType: options.changeType, firstRecordName: key }); store.addRelationshipChangeFor(childRecord, key, parentRecord, null, change); return change; }; DS.OneToOneChange.maintainInvariant = function(options, store, childRecord, key){ if (options.changeType === "add" && store.recordIsMaterialized(childRecord)) { var oldParent = get(childRecord, key); if (oldParent){ var correspondingChange = DS.OneToOneChange.createChange(childRecord, oldParent, store, { parentType: options.parentType, hasManyName: options.hasManyName, changeType: "remove", key: options.key }); store.addRelationshipChangeFor(childRecord, key, options.parentRecord , null, correspondingChange); correspondingChange.sync(); } } }; DS.OneToManyChange.createChange = function(childRecord, parentRecord, store, options) { var key; // If the name of the belongsTo side of the relationship is specified, // use that // If the type of the parent is specified, look it up on the child's type // definition. if (options.parentType) { key = options.parentType.inverseFor(options.key).name; DS.OneToManyChange.maintainInvariant( options, store, childRecord, key ); } else if (options.key) { key = options.key; } else { Ember.assert("You must pass either a parentType or belongsToName option to OneToManyChange.forChildAndParent", false); } var change = DS.RelationshipChange._createChange({ parentRecord: parentRecord, childRecord: childRecord, firstRecord: childRecord, secondRecord: parentRecord, firstRecordKind: "belongsTo", secondRecordKind: "hasMany", store: store, changeType: options.changeType, firstRecordName: key }); store.addRelationshipChangeFor(childRecord, key, parentRecord, change.getSecondRecordName(), change); return change; }; DS.OneToManyChange.maintainInvariant = function(options, store, childRecord, key){ if (options.changeType === "add" && childRecord) { var oldParent = get(childRecord, key); if (oldParent){ var correspondingChange = DS.OneToManyChange.createChange(childRecord, oldParent, store, { parentType: options.parentType, hasManyName: options.hasManyName, changeType: "remove", key: options.key }); store.addRelationshipChangeFor(childRecord, key, options.parentRecord, correspondingChange.getSecondRecordName(), correspondingChange); correspondingChange.sync(); } } }; /** @class RelationshipChange @namespace DS */ DS.RelationshipChange.prototype = { getSecondRecordName: function() { var name = this.secondRecordName, parent; if (!name) { parent = this.secondRecord; if (!parent) { return; } var childType = this.firstRecord.constructor; var inverse = childType.inverseFor(this.firstRecordName); this.secondRecordName = inverse.name; } return this.secondRecordName; }, /** Get the name of the relationship on the belongsTo side. @method getFirstRecordName @return {String} */ getFirstRecordName: function() { var name = this.firstRecordName; return name; }, /** @method destroy @private */ destroy: function() { var childRecord = this.childRecord, belongsToName = this.getFirstRecordName(), hasManyName = this.getSecondRecordName(), store = this.store; store.removeRelationshipChangeFor(childRecord, belongsToName, this.parentRecord, hasManyName, this.changeType); }, getSecondRecord: function(){ return this.secondRecord; }, /** @method getFirstRecord @private */ getFirstRecord: function() { return this.firstRecord; }, coalesce: function(){ var relationshipPairs = this.store.relationshipChangePairsFor(this.firstRecord); forEach(relationshipPairs, function(pair){ var addedChange = pair["add"]; var removedChange = pair["remove"]; if(addedChange && removedChange) { addedChange.destroy(); removedChange.destroy(); } }); } }; DS.RelationshipChangeAdd.prototype = Ember.create(DS.RelationshipChange.create({})); DS.RelationshipChangeRemove.prototype = Ember.create(DS.RelationshipChange.create({})); // the object is a value, and not a promise function isValue(object) { return typeof object === 'object' && (!object.then || typeof object.then !== 'function'); } DS.RelationshipChangeAdd.prototype.changeType = "add"; DS.RelationshipChangeAdd.prototype.sync = function() { var secondRecordName = this.getSecondRecordName(), firstRecordName = this.getFirstRecordName(), firstRecord = this.getFirstRecord(), secondRecord = this.getSecondRecord(); //Ember.assert("You specified a hasMany (" + hasManyName + ") on " + (!belongsToName && (newParent || oldParent || this.lastParent).constructor) + " but did not specify an inverse belongsTo on " + child.constructor, belongsToName); //Ember.assert("You specified a belongsTo (" + belongsToName + ") on " + child.constructor + " but did not specify an inverse hasMany on " + (!hasManyName && (newParent || oldParent || this.lastParentRecord).constructor), hasManyName); if (secondRecord instanceof DS.Model && firstRecord instanceof DS.Model) { if(this.secondRecordKind === "belongsTo"){ secondRecord.suspendRelationshipObservers(function(){ set(secondRecord, secondRecordName, firstRecord); }); } else if(this.secondRecordKind === "hasMany"){ secondRecord.suspendRelationshipObservers(function(){ var relationship = get(secondRecord, secondRecordName); if (isValue(relationship)) { relationship.addObject(firstRecord); } }); } } if (firstRecord instanceof DS.Model && secondRecord instanceof DS.Model && get(firstRecord, firstRecordName) !== secondRecord) { if(this.firstRecordKind === "belongsTo"){ firstRecord.suspendRelationshipObservers(function(){ set(firstRecord, firstRecordName, secondRecord); }); } else if(this.firstRecordKind === "hasMany"){ firstRecord.suspendRelationshipObservers(function(){ var relationship = get(firstRecord, firstRecordName); if (isValue(relationship)) { relationship.addObject(secondRecord); } }); } } this.coalesce(); }; DS.RelationshipChangeRemove.prototype.changeType = "remove"; DS.RelationshipChangeRemove.prototype.sync = function() { var secondRecordName = this.getSecondRecordName(), firstRecordName = this.getFirstRecordName(), firstRecord = this.getFirstRecord(), secondRecord = this.getSecondRecord(); //Ember.assert("You specified a hasMany (" + hasManyName + ") on " + (!belongsToName && (newParent || oldParent || this.lastParent).constructor) + " but did not specify an inverse belongsTo on " + child.constructor, belongsToName); //Ember.assert("You specified a belongsTo (" + belongsToName + ") on " + child.constructor + " but did not specify an inverse hasMany on " + (!hasManyName && (newParent || oldParent || this.lastParentRecord).constructor), hasManyName); if (secondRecord instanceof DS.Model && firstRecord instanceof DS.Model) { if(this.secondRecordKind === "belongsTo"){ secondRecord.suspendRelationshipObservers(function(){ set(secondRecord, secondRecordName, null); }); } else if(this.secondRecordKind === "hasMany"){ secondRecord.suspendRelationshipObservers(function(){ var relationship = get(secondRecord, secondRecordName); if (isValue(relationship)) { relationship.removeObject(firstRecord); } }); } } if (firstRecord instanceof DS.Model && get(firstRecord, firstRecordName)) { if(this.firstRecordKind === "belongsTo"){ firstRecord.suspendRelationshipObservers(function(){ set(firstRecord, firstRecordName, null); }); } else if(this.firstRecordKind === "hasMany"){ firstRecord.suspendRelationshipObservers(function(){ var relationship = get(firstRecord, firstRecordName); if (isValue(relationship)) { relationship.removeObject(secondRecord); } }); } } this.coalesce(); }; })(); (function() { /** @module ember-data */ })(); (function() { var get = Ember.get, set = Ember.set, isNone = Ember.isNone; /** @module ember-data */ function asyncBelongsTo(type, options, meta) { return Ember.computed(function(key, value) { var data = get(this, 'data'), store = get(this, 'store'); if (arguments.length === 2) { Ember.assert("You can only add a '" + type + "' record to this relationship", !value || value instanceof store.modelFor(type)); return value === undefined ? null : DS.PromiseObject.create({ promise: Ember.RSVP.resolve(value) }); } var link = data.links && data.links[key], belongsTo = data[key]; if(!isNone(belongsTo)) { var promise = store.fetchRecord(belongsTo) || Ember.RSVP.resolve(belongsTo); return DS.PromiseObject.create({promise: promise}); } else if (link) { var resolver = Ember.RSVP.defer(); store.findBelongsTo(this, link, meta, resolver); return DS.PromiseObject.create({ promise: resolver.promise }); } else { return null; } }).property('data').meta(meta); } DS.belongsTo = function(type, options) { if (typeof type === 'object') { options = type; type = undefined; } else { Ember.assert("The first argument DS.belongsTo must be a model type or string, like DS.belongsTo(App.Person)", !!type && (typeof type === 'string' || DS.Model.detect(type))); } options = options || {}; var meta = { type: type, isRelationship: true, options: options, kind: 'belongsTo' }; if (options.async) { return asyncBelongsTo(type, options, meta); } return Ember.computed(function(key, value) { var data = get(this, 'data'), store = get(this, 'store'), belongsTo, typeClass; if (typeof type === 'string') { typeClass = store.modelFor(type); } else { typeClass = type; } if (arguments.length === 2) { Ember.assert("You can only add a '" + type + "' record to this relationship", !value || value instanceof typeClass); return value === undefined ? null : value; } belongsTo = data[key]; if (isNone(belongsTo)) { return null; } store.fetchRecord(belongsTo); return belongsTo; }).property('data').meta(meta); }; /* These observers observe all `belongsTo` relationships on the record. See `relationships/ext` to see how these observers get their dependencies. @class Model @namespace DS */ DS.Model.reopen({ /** @method belongsToWillChange @private @static @param record @param key */ belongsToWillChange: Ember.beforeObserver(function(record, key) { if (get(record, 'isLoaded')) { var oldParent = get(record, key); if (oldParent) { var store = get(record, 'store'), change = DS.RelationshipChange.createChange(record, oldParent, store, { key: key, kind: "belongsTo", changeType: "remove" }); change.sync(); this._changesToSync[key] = change; } } }), /** @method belongsToDidChange @private @static @param record @param key */ belongsToDidChange: Ember.immediateObserver(function(record, key) { if (get(record, 'isLoaded')) { var newParent = get(record, key); if (newParent) { var store = get(record, 'store'), change = DS.RelationshipChange.createChange(record, newParent, store, { key: key, kind: "belongsTo", changeType: "add" }); change.sync(); } } delete this._changesToSync[key]; }) }); })(); (function() { /** @module ember-data */ var get = Ember.get, set = Ember.set, setProperties = Ember.setProperties; function asyncHasMany(type, options, meta) { return Ember.computed(function(key, value) { if (this._relationships[key]) { return this._relationships[key]; } var resolver = Ember.RSVP.defer(); var relationship = buildRelationship(this, key, options, function(store, data) { var link = data.links && data.links[key]; if (link) { return store.findHasMany(this, link, meta, resolver); } else { return store.findMany(this, data[key], meta.type, resolver); } }); var promise = resolver.promise.then(function() { return relationship; }); return DS.PromiseArray.create({ promise: promise }); }).property('data').meta(meta); } function buildRelationship(record, key, options, callback) { var rels = record._relationships; if (rels[key]) { return rels[key]; } var data = get(record, 'data'), store = get(record, 'store'); var relationship = rels[key] = callback.call(record, store, data); return setProperties(relationship, { owner: record, name: key, isPolymorphic: options.polymorphic }); } function hasRelationship(type, options) { options = options || {}; var meta = { type: type, isRelationship: true, options: options, kind: 'hasMany' }; if (options.async) { return asyncHasMany(type, options, meta); } return Ember.computed(function(key, value) { return buildRelationship(this, key, options, function(store, data) { var records = data[key]; Ember.assert("You looked up the '" + key + "' relationship on '" + this + "' but some of the associated records were not loaded. Either make sure they are all loaded together with the parent record, or specify that the relationship is async (`DS.hasMany({ async: true })`)", Ember.A(records).everyProperty('isEmpty', false)); return store.findMany(this, data[key], meta.type); }); }).property('data').meta(meta); } DS.hasMany = function(type, options) { if (typeof type === 'object') { options = type; type = undefined; } return hasRelationship(type, options); }; })(); (function() { var get = Ember.get, set = Ember.set; /** @module ember-data */ /* This file defines several extensions to the base `DS.Model` class that add support for one-to-many relationships. */ /** @class Model @namespace DS */ DS.Model.reopen({ /** This Ember.js hook allows an object to be notified when a property is defined. In this case, we use it to be notified when an Ember Data user defines a belongs-to relationship. In that case, we need to set up observers for each one, allowing us to track relationship changes and automatically reflect changes in the inverse has-many array. This hook passes the class being set up, as well as the key and value being defined. So, for example, when the user does this: DS.Model.extend({ parent: DS.belongsTo('user') }); This hook would be called with "parent" as the key and the computed property returned by `DS.belongsTo` as the value. @method didDefineProperty @param proto @param key @param value */ didDefineProperty: function(proto, key, value) { // Check if the value being set is a computed property. if (value instanceof Ember.Descriptor) { // If it is, get the metadata for the relationship. This is // populated by the `DS.belongsTo` helper when it is creating // the computed property. var meta = value.meta(); if (meta.isRelationship && meta.kind === 'belongsTo') { Ember.addObserver(proto, key, null, 'belongsToDidChange'); Ember.addBeforeObserver(proto, key, null, 'belongsToWillChange'); } meta.parentType = proto.constructor; } } }); /* These DS.Model extensions add class methods that provide relationship introspection abilities about relationships. A note about the computed properties contained here: **These properties are effectively sealed once called for the first time.** To avoid repeatedly doing expensive iteration over a model's fields, these values are computed once and then cached for the remainder of the runtime of your application. If your application needs to modify a class after its initial definition (for example, using `reopen()` to add additional attributes), make sure you do it before using your model with the store, which uses these properties extensively. */ DS.Model.reopenClass({ /** For a given relationship name, returns the model type of the relationship. For example, if you define a model like this: App.Post = DS.Model.extend({ comments: DS.hasMany('comment') }); Calling `App.Post.typeForRelationship('comments')` will return `App.Comment`. @method typeForRelationship @static @param {String} name the name of the relationship @return {subclass of DS.Model} the type of the relationship, or undefined */ typeForRelationship: function(name) { var relationship = get(this, 'relationshipsByName').get(name); return relationship && relationship.type; }, inverseFor: function(name) { var inverseType = this.typeForRelationship(name); if (!inverseType) { return null; } var options = this.metaForProperty(name).options; if (options.inverse === null) { return null; } var inverseName, inverseKind; if (options.inverse) { inverseName = options.inverse; inverseKind = Ember.get(inverseType, 'relationshipsByName').get(inverseName).kind; } else { var possibleRelationships = findPossibleInverses(this, inverseType); if (possibleRelationships.length === 0) { return null; } Ember.assert("You defined the '" + name + "' relationship on " + this + ", but multiple possible inverse relationships of type " + this + " were found on " + inverseType + ".", possibleRelationships.length === 1); inverseName = possibleRelationships[0].name; inverseKind = possibleRelationships[0].kind; } function findPossibleInverses(type, inverseType, possibleRelationships) { possibleRelationships = possibleRelationships || []; var relationshipMap = get(inverseType, 'relationships'); if (!relationshipMap) { return; } var relationships = relationshipMap.get(type); if (relationships) { possibleRelationships.push.apply(possibleRelationships, relationshipMap.get(type)); } if (type.superclass) { findPossibleInverses(type.superclass, inverseType, possibleRelationships); } return possibleRelationships; } return { type: inverseType, name: inverseName, kind: inverseKind }; }, /** The model's relationships as a map, keyed on the type of the relationship. The value of each entry is an array containing a descriptor for each relationship with that type, describing the name of the relationship as well as the type. For example, given the following model definition: App.Blog = DS.Model.extend({ users: DS.hasMany('user'), owner: DS.belongsTo('user'), posts: DS.hasMany('post') }); This computed property would return a map describing these relationships, like this: var relationships = Ember.get(App.Blog, 'relationships'); relationships.get(App.User); //=> [ { name: 'users', kind: 'hasMany' }, // { name: 'owner', kind: 'belongsTo' } ] relationships.get(App.Post); //=> [ { name: 'posts', kind: 'hasMany' } ] @property relationships @static @type Ember.Map @readOnly */ relationships: Ember.computed(function() { var map = new Ember.MapWithDefault({ defaultValue: function() { return []; } }); // Loop through each computed property on the class this.eachComputedProperty(function(name, meta) { // If the computed property is a relationship, add // it to the map. if (meta.isRelationship) { if (typeof meta.type === 'string') { meta.type = this.store.modelFor(meta.type); } var relationshipsForType = map.get(meta.type); relationshipsForType.push({ name: name, kind: meta.kind }); } }); return map; }), /** A hash containing lists of the model's relationships, grouped by the relationship kind. For example, given a model with this definition: App.Blog = DS.Model.extend({ users: DS.hasMany('user'), owner: DS.belongsTo('user'), posts: DS.hasMany('post') }); This property would contain the following: var relationshipNames = Ember.get(App.Blog, 'relationshipNames'); relationshipNames.hasMany; //=> ['users', 'posts'] relationshipNames.belongsTo; //=> ['owner'] @property relationshipNames @static @type Object @readOnly */ relationshipNames: Ember.computed(function() { var names = { hasMany: [], belongsTo: [] }; this.eachComputedProperty(function(name, meta) { if (meta.isRelationship) { names[meta.kind].push(name); } }); return names; }), /** An array of types directly related to a model. Each type will be included once, regardless of the number of relationships it has with the model. For example, given a model with this definition: App.Blog = DS.Model.extend({ users: DS.hasMany('user'), owner: DS.belongsTo('user'), posts: DS.hasMany('post') }); This property would contain the following: var relatedTypes = Ember.get(App.Blog, 'relatedTypes'); //=> [ App.User, App.Post ] @property relatedTypes @static @type Ember.Array @readOnly */ relatedTypes: Ember.computed(function() { var type, types = Ember.A(); // Loop through each computed property on the class, // and create an array of the unique types involved // in relationships this.eachComputedProperty(function(name, meta) { if (meta.isRelationship) { type = meta.type; if (typeof type === 'string') { type = get(this, type, false) || this.store.modelFor(type); } Ember.assert("You specified a hasMany (" + meta.type + ") on " + meta.parentType + " but " + meta.type + " was not found.", type); if (!types.contains(type)) { Ember.assert("Trying to sideload " + name + " on " + this.toString() + " but the type doesn't exist.", !!type); types.push(type); } } }); return types; }), /** A map whose keys are the relationships of a model and whose values are relationship descriptors. For example, given a model with this definition: App.Blog = DS.Model.extend({ users: DS.hasMany('user'), owner: DS.belongsTo('user'), posts: DS.hasMany('post') }); This property would contain the following: var relationshipsByName = Ember.get(App.Blog, 'relationshipsByName'); relationshipsByName.get('users'); //=> { key: 'users', kind: 'hasMany', type: App.User } relationshipsByName.get('owner'); //=> { key: 'owner', kind: 'belongsTo', type: App.User } @property relationshipsByName @static @type Ember.Map @readOnly */ relationshipsByName: Ember.computed(function() { var map = Ember.Map.create(), type; this.eachComputedProperty(function(name, meta) { if (meta.isRelationship) { meta.key = name; type = meta.type; if (!type && meta.kind === 'hasMany') { type = Ember.String.singularize(name); } else if (!type) { type = name; } if (typeof type === 'string') { meta.type = this.store.modelFor(type); } map.set(name, meta); } }); return map; }), /** A map whose keys are the fields of the model and whose values are strings describing the kind of the field. A model's fields are the union of all of its attributes and relationships. For example: App.Blog = DS.Model.extend({ users: DS.hasMany('user'), owner: DS.belongsTo('user'), posts: DS.hasMany('post'), title: DS.attr('string') }); var fields = Ember.get(App.Blog, 'fields'); fields.forEach(function(field, kind) { console.log(field, kind); }); // prints: // users, hasMany // owner, belongsTo // posts, hasMany // title, attribute @property fields @static @type Ember.Map @readOnly */ fields: Ember.computed(function() { var map = Ember.Map.create(); this.eachComputedProperty(function(name, meta) { if (meta.isRelationship) { map.set(name, meta.kind); } else if (meta.isAttribute) { map.set(name, 'attribute'); } }); return map; }), /** Given a callback, iterates over each of the relationships in the model, invoking the callback with the name of each relationship and its relationship descriptor. @method eachRelationship @static @param {Function} callback the callback to invoke @param {any} binding the value to which the callback's `this` should be bound */ eachRelationship: function(callback, binding) { get(this, 'relationshipsByName').forEach(function(name, relationship) { callback.call(binding, name, relationship); }); }, /** Given a callback, iterates over each of the types related to a model, invoking the callback with the related type's class. Each type will be returned just once, regardless of how many different relationships it has with a model. @method eachRelatedType @static @param {Function} callback the callback to invoke @param {any} binding the value to which the callback's `this` should be bound */ eachRelatedType: function(callback, binding) { get(this, 'relatedTypes').forEach(function(type) { callback.call(binding, type); }); } }); DS.Model.reopen({ /** Given a callback, iterates over each of the relationships in the model, invoking the callback with the name of each relationship and its relationship descriptor. @method eachRelationship @param {Function} callback the callback to invoke @param {any} binding the value to which the callback's `this` should be bound */ eachRelationship: function(callback, binding) { this.constructor.eachRelationship(callback, binding); } }); })(); (function() { /** @module ember-data */ })(); (function() { /** @module ember-data */ var get = Ember.get, set = Ember.set; var once = Ember.run.once; var forEach = Ember.EnumerableUtils.forEach; /** @class RecordArrayManager @namespace DS @private @extends Ember.Object */ DS.RecordArrayManager = Ember.Object.extend({ init: function() { this.filteredRecordArrays = Ember.MapWithDefault.create({ defaultValue: function() { return []; } }); this.changedRecords = []; }, recordDidChange: function(record) { this.changedRecords.push(record); once(this, this.updateRecordArrays); }, recordArraysForRecord: function(record) { record._recordArrays = record._recordArrays || Ember.OrderedSet.create(); return record._recordArrays; }, /** This method is invoked whenever data is loaded into the store by the adapter or updated by the adapter, or when an attribute changes on a record. It updates all filters that a record belongs to. To avoid thrashing, it only runs once per run loop per record. @method updateRecordArrays @param {Class} type @param {Number|String} clientId */ updateRecordArrays: function() { forEach(this.changedRecords, function(record) { var type = record.constructor, recordArrays = this.filteredRecordArrays.get(type), filter; forEach(recordArrays, function(array) { filter = get(array, 'filterFunction'); this.updateRecordArray(array, filter, type, record); }, this); // loop through all manyArrays containing an unloaded copy of this // clientId and notify them that the record was loaded. var manyArrays = record._loadingRecordArrays; if (manyArrays) { for (var i=0, l=manyArrays.length; i} The primary array that was returned in response to the original query. */ extractArray: function(store, primaryType, payload) { payload = this.normalizePayload(primaryType, payload); var primaryTypeName = primaryType.typeKey, primaryArray; for (var prop in payload) { var typeKey = prop, forcedSecondary = false; if (prop.charAt(0) === '_') { forcedSecondary = true; typeKey = prop.substr(1); } var typeName = this.typeForRoot(typeKey), type = store.modelFor(typeName), typeSerializer = store.serializerFor(type), isPrimary = (!forcedSecondary && (typeName === primaryTypeName)); /*jshint loopfunc:true*/ var normalizedArray = map.call(payload[prop], function(hash) { return typeSerializer.normalize(type, hash, prop); }, this); if (isPrimary) { primaryArray = normalizedArray; } else { store.pushMany(typeName, normalizedArray); } } return primaryArray; }, /** This method allows you to push a payload containing top-level collections of records organized per type. ```js { "posts": [{ "id": "1", "title": "Rails is omakase", "author", "1", "comments": [ "1" ] }], "comments": [{ "id": "1", "body": "FIRST }], "users": [{ "id": "1", "name": "@d2h" }] } ``` It will first normalize the payload, so you can use this to push in data streaming in from your server structured the same way that fetches and saves are structured. @method pushPayload @param {DS.Store} store @param {Object} payload */ pushPayload: function(store, payload) { payload = this.normalizePayload(null, payload); for (var prop in payload) { var typeName = this.typeForRoot(prop), type = store.modelFor(typeName); /*jshint loopfunc:true*/ var normalizedArray = map.call(payload[prop], function(hash) { return this.normalize(type, hash, prop); }, this); store.pushMany(typeName, normalizedArray); } }, /** You can use this method to normalize the JSON root keys returned into the model type expected by your store. For example, your server may return underscored root keys rather than the expected camelcased versions. ```js App.ApplicationSerializer = DS.RESTSerializer.extend({ typeForRoot: function(root) { var camelized = Ember.String.camelize(root); return Ember.String.singularize(camelized); } }); ``` @method typeForRoot @param {String} root @returns String the model's typeKey */ typeForRoot: function(root) { return Ember.String.singularize(root); }, // SERIALIZE /** Called when a record is saved in order to convert the record into JSON. By default, it creates a JSON object with a key for each attribute and belongsTo relationship. For example, consider this model: ```js App.Comment = DS.Model.extend({ title: DS.attr(), body: DS.attr(), author: DS.belongsTo('user') }); ``` The default serialization would create a JSON object like: ```js { "title": "Rails is unagi", "body": "Rails? Omakase? O_O", "author": 12 } ``` By default, attributes are passed through as-is, unless you specified an attribute type (`DS.attr('date')`). If you specify a transform, the JavaScript value will be serialized when inserted into the JSON hash. By default, belongs-to relationships are converted into IDs when inserted into the JSON hash. ## IDs `serialize` takes an options hash with a single option: `includeId`. If this option is `true`, `serialize` will, by default include the ID in the JSON object it builds. The adapter passes in `includeId: true` when serializing a record for `createRecord`, but not for `updateRecord`. ## Customization Your server may expect a different JSON format than the built-in serialization format. In that case, you can implement `serialize` yourself and return a JSON hash of your choosing. ```js App.PostSerializer = DS.RESTSerializer.extend({ serialize: function(post, options) { var json = { POST_TTL: post.get('title'), POST_BDY: post.get('body'), POST_CMS: post.get('comments').mapProperty('id') } if (options.includeId) { json.POST_ID_ = post.get('id'); } return json; } }); ``` ## Customizing an App-Wide Serializer If you want to define a serializer for your entire application, you'll probably want to use `eachAttribute` and `eachRelationship` on the record. ```js App.ApplicationSerializer = DS.RESTSerializer.extend({ serialize: function(record, options) { var json = {}; record.eachAttribute(function(name) { json[serverAttributeName(name)] = record.get(name); }) record.eachRelationship(function(name, relationship) { if (relationship.kind === 'hasMany') { json[serverHasManyName(name)] = record.get(name).mapBy('id'); } }); if (options.includeId) { json.ID_ = record.get('id'); } return json; } }); function serverAttributeName(attribute) { return attribute.underscore().toUpperCase(); } function serverHasManyName(name) { return serverAttributeName(name.singularize()) + "_IDS"; } ``` This serializer will generate JSON that looks like this: ```js { "TITLE": "Rails is omakase", "BODY": "Yep. Omakase.", "COMMENT_IDS": [ 1, 2, 3 ] } ``` ## Tweaking the Default JSON If you just want to do some small tweaks on the default JSON, you can call super first and make the tweaks on the returned JSON. ```js App.PostSerializer = DS.RESTSerializer.extend({ serialize: function(record, options) { var json = this._super(record, options); json.subject = json.title; delete json.title; return json; } }); ``` @method serialize @param record @param options */ serialize: function(record, options) { return this._super.apply(this, arguments); }, /** You can use this method to customize the root keys serialized into the JSON. By default the REST Serializer sends camelized root keys. For example, your server may expect underscored root objects. ```js App.ApplicationSerializer = DS.RESTSerializer.extend({ serializeIntoHash: function(data, type, record, options) { var root = Ember.String.decamelize(type.typeKey); data[root] = this.serialize(record, options); } }); ``` @method serializeIntoHash @param {Object} hash @param {subclass of DS.Model} type @param {DS.Model} record @param {Object} options */ serializeIntoHash: function(hash, type, record, options) { hash[type.typeKey] = this.serialize(record, options); }, /** You can use this method to customize how polymorphic objects are serialized. By default the JSON Serializer creates the key by appending `Type` to the attribute and value from the model's camelcased model name. @method serializePolymorphicType @param {DS.Model} record @param {Object} json @param relationship */ serializePolymorphicType: function(record, json, relationship) { var key = relationship.key, belongsTo = get(record, key); key = this.keyForAttribute ? this.keyForAttribute(key) : key; json[key + "Type"] = belongsTo.constructor.typeKey; } }); })(); (function() { /** @module ember-data */ var get = Ember.get, set = Ember.set; var forEach = Ember.ArrayPolyfills.forEach; /** The REST adapter allows your store to communicate with an HTTP server by transmitting JSON via XHR. Most Ember.js apps that consume a JSON API should use the REST adapter. This adapter is designed around the idea that the JSON exchanged with the server should be conventional. ## JSON Structure The REST adapter expects the JSON returned from your server to follow these conventions. ### Object Root The JSON payload should be an object that contains the record inside a root property. For example, in response to a `GET` request for `/posts/1`, the JSON should look like this: ```js { "post": { title: "I'm Running to Reform the W3C's Tag", author: "Yehuda Katz" } } ``` ### Conventional Names Attribute names in your JSON payload should be the camelcased versions of the attributes in your Ember.js models. For example, if you have a `Person` model: ```js App.Person = DS.Model.extend({ firstName: DS.attr('string'), lastName: DS.attr('string'), occupation: DS.attr('string') }); ``` The JSON returned should look like this: ```js { "person": { "firstName": "Barack", "lastName": "Obama", "occupation": "President" } } ``` ## Customization ### Endpoint path customization Endpoint paths can be prefixed with a `namespace` by setting the namespace property on the adapter: ```js DS.RESTAdapter.reopen({ namespace: 'api/1' }); ``` Requests for `App.Person` would now target `/api/1/people/1`. ### Host customization An adapter can target other hosts by setting the `host` property. ```js DS.RESTAdapter.reopen({ host: 'https://api.example.com' }); ``` ### Headers customization Some APIs require HTTP headers, eg to provide an API key. An array of headers can be added to the adapter which are passed with every request: ```js DS.RESTAdapter.reopen({ headers: { "API_KEY": "secret key", "ANOTHER_HEADER": "asdsada" } }); ``` @class RESTAdapter @constructor @namespace DS @extends DS.Adapter */ DS.RESTAdapter = DS.Adapter.extend({ defaultSerializer: '_rest', /** Called by the store in order to fetch the JSON for a given type and ID. It makes an Ajax request to a URL computed by `buildURL`, and returns a promise for the resulting payload. @method find @see RESTAdapter/buildURL @see RESTAdapter/ajax @param {DS.Store} store @param {subclass of DS.Model} type @param {String} id @returns Promise */ find: function(store, type, id) { return this.ajax(this.buildURL(type.typeKey, id), 'GET'); }, /** Called by the store in order to fetch a JSON array for all of the records for a given type. It makes an Ajax request to a URL computed by `buildURL`, and returns a promise for the resulting payload. @method findAll @see RESTAdapter/buildURL @see RESTAdapter/ajax @param {DS.Store} store @param {subclass of DS.Model} type @param {String} sinceToken @returns Promise */ findAll: function(store, type, sinceToken) { var query; if (sinceToken) { query = { since: sinceToken }; } return this.ajax(this.buildURL(type.typeKey), 'GET', { data: query }); }, /** Called by the store in order to fetch a JSON array for the records that match a particular query. The query is a simple JavaScript object that will be passed directly to the server as parameters. It makes an Ajax request to a URL computed by `buildURL`, and returns a promise for the resulting payload. @method findQuery @see RESTAdapter/buildURL @see RESTAdapter/ajax @param {DS.Store} store @param {subclass of DS.Model} type @param {Object} query @returns Promise */ findQuery: function(store, type, query) { return this.ajax(this.buildURL(type.typeKey), 'GET', { data: query }); }, /** Called by the store in order to fetch a JSON array for the unloaded records in a has-many relationship that were originally specified as IDs. For example, if the original payload looks like: ```js { "id": 1, "title": "Rails is omakase", "comments": [ 1, 2, 3 ] } ``` The IDs will be passed as a URL-encoded Array of IDs, in this form: ``` ids[]=1&ids[]=2&ids[]=3 ``` Many servers, such as Rails and PHP, will automatically convert this into an Array for you on the server-side. If you want to encode the IDs, differently, just override this (one-line) method. It makes an Ajax request to a URL computed by `buildURL`, and returns a promise for the resulting payload. @method findMany @see RESTAdapter/buildURL @see RESTAdapter/ajax @param {DS.Store} store @param {subclass of DS.Model} type @param {Array} ids @returns Promise */ findMany: function(store, type, ids, owner) { return this.ajax(this.buildURL(type.typeKey), 'GET', { data: { ids: ids } }); }, /** Called by the store in order to fetch a JSON array for the unloaded records in a has-many relationship that were originally specified as a URL (inside of `links`). For example, if your original payload looks like this: ```js { "post": { "id": 1, "title": "Rails is omakase", "links": { "comments": "/posts/1/comments" } } } ``` This method will be called with the parent record and `/posts/1/comments`. It will make an Ajax request to the originally specified URL. If the URL is host-relative (starting with a single slash), the request will use the host specified on the adapter (if any). @method findHasMany @see RESTAdapter/buildURL @see RESTAdapter/ajax @param {DS.Store} store @param {DS.Model} record @param {String} url @returns Promise */ findHasMany: function(store, record, url) { var host = get(this, 'host'), id = get(record, 'id'), type = record.constructor.typeKey; if (host && url.charAt(0) === '/' && url.charAt(1) !== '/') { url = host + url; } return this.ajax(this.urlPrefix(url, this.buildURL(type, id)), 'GET'); }, /** Called by the store in order to fetch a JSON array for the unloaded records in a belongs-to relationship that were originally specified as a URL (inside of `links`). For example, if your original payload looks like this: ```js { "person": { "id": 1, "name": "Tom Dale", "links": { "group": "/people/1/group" } } } ``` This method will be called with the parent record and `/people/1/group`. It will make an Ajax request to the originally specified URL. @method findBelongsTo @see RESTAdapter/buildURL @see RESTAdapter/ajax @param {DS.Store} store @param {DS.Model} record @param {String} url @returns Promise */ findBelongsTo: function(store, record, url) { var id = get(record, 'id'), type = record.constructor.typeKey; return this.ajax(this.urlPrefix(url, this.buildURL(type, id)), 'GET'); }, /** Called by the store when a newly created record is `save`d. It serializes the record, and `POST`s it to a URL generated by `buildURL`. See `serialize` for information on how to customize the serialized form of a record. @method createRecord @see RESTAdapter/buildURL @see RESTAdapter/ajax @see RESTAdapter/serialize @param {DS.Store} store @param {subclass of DS.Model} type @param {DS.Model} record @returns Promise */ createRecord: function(store, type, record) { var data = {}; var serializer = store.serializerFor(type.typeKey); serializer.serializeIntoHash(data, type, record, { includeId: true }); return this.ajax(this.buildURL(type.typeKey), "POST", { data: data }); }, /** Called by the store when an existing record is `save`d. It serializes the record, and `POST`s it to a URL generated by `buildURL`. See `serialize` for information on how to customize the serialized form of a record. @method updateRecord @see RESTAdapter/buildURL @see RESTAdapter/ajax @see RESTAdapter/serialize @param {DS.Store} store @param {subclass of DS.Model} type @param {DS.Model} record @returns Promise */ updateRecord: function(store, type, record) { var data = {}; var serializer = store.serializerFor(type.typeKey); serializer.serializeIntoHash(data, type, record); var id = get(record, 'id'); return this.ajax(this.buildURL(type.typeKey, id), "PUT", { data: data }); }, /** Called by the store when an deleted record is `save`d. It serializes the record, and `POST`s it to a URL generated by `buildURL`. @method deleteRecord @see RESTAdapter/buildURL @see RESTAdapter/ajax @see RESTAdapter/serialize @param {DS.Store} store @param {subclass of DS.Model} type @param {DS.Model} record @returns Promise */ deleteRecord: function(store, type, record) { var id = get(record, 'id'); return this.ajax(this.buildURL(type.typeKey, id), "DELETE"); }, /** Builds a URL for a given type and optional ID. By default, it pluralizes the type's name (for example, 'post' becomes 'posts' and 'person' becomes 'people'). If an ID is specified, it adds the ID to the path generated for the type, separated by a `/`. @method buildURL @param {String} type @param {String} id @returns String */ buildURL: function(type, id) { var url = [], host = get(this, 'host'), prefix = this.urlPrefix(); if (type) { url.push(this.pathForType(type)); } if (id) { url.push(id); } if (prefix) { url.unshift(prefix); } url = url.join('/'); if (!host && url) { url = '/' + url; } return url; }, urlPrefix: function(path, parentURL) { var host = get(this, 'host'), namespace = get(this, 'namespace'), url = []; if (path) { // Absolute path if (path.charAt(0) === '/') { if (host) { path = path.slice(1); url.push(host); } // Relative path } else if (!/^http(s)?:\/\//.test(path)) { url.push(parentURL); } } else { if (host) { url.push(host); } if (namespace) { url.push(namespace); } } if (path) { url.push(path); } return url.join('/'); }, /** Determines the pathname for a given type. By default, it pluralizes the type's name (for example, 'post' becomes 'posts' and 'person' becomes 'people'). ### Pathname customization For example if you have an object LineItem with an endpoint of "/line_items/". ```js DS.RESTAdapter.reopen({ pathForType: function(type) { var decamelized = Ember.String.decamelize(type); return Ember.String.pluralize(decamelized); }; }); ``` @method pathForType @param {String} type @returns String **/ pathForType: function(type) { return Ember.String.pluralize(type); }, /** Takes an ajax response, and returns a relavant error. By default, it has the following behavior: * It simply returns the ajax response. @method ajaxError @param jqXHR */ ajaxError: function(jqXHR) { if (jqXHR) { jqXHR.then = null; } return jqXHR; }, /** Takes a URL, an HTTP method and a hash of data, and makes an HTTP request. When the server responds with a payload, Ember Data will call into `extractSingle` or `extractArray` (depending on whether the original query was for one record or many records). By default, it has the following behavior: * It sets the response `dataType` to `"json"` * If the HTTP method is not `"GET"`, it sets the `Content-Type` to be `application/json; charset=utf-8` * If the HTTP method is not `"GET"`, it stringifies the data passed in. The data is the serialized record in the case of a save. * Registers success and failure handlers. @method ajax @private @param url @param type @param hash */ ajax: function(url, type, hash) { var adapter = this; return new Ember.RSVP.Promise(function(resolve, reject) { hash = adapter.ajaxOptions(url, type, hash); hash.success = function(json) { Ember.run(null, resolve, json); }; hash.error = function(jqXHR, textStatus, errorThrown) { Ember.run(null, reject, adapter.ajaxError(jqXHR)); }; Ember.$.ajax(hash); }); }, ajaxOptions: function(url, type, hash) { hash = hash || {}; hash.url = url; hash.type = type; hash.dataType = 'json'; hash.context = this; if (hash.data && type !== 'GET') { hash.contentType = 'application/json; charset=utf-8'; hash.data = JSON.stringify(hash.data); } if (this.headers !== undefined) { var headers = this.headers; hash.beforeSend = function (xhr) { forEach.call(Ember.keys(headers), function(key) { xhr.setRequestHeader(key, headers[key]); }); }; } return hash; } }); })(); (function() { /** @module ember-data */ })(); (function() { DS.Model.reopen({ /** Provides info about the model for debugging purposes by grouping the properties into more semantic groups. Meant to be used by debugging tools such as the Chrome Ember Extension. - Groups all attributes in "Attributes" group. - Groups all belongsTo relationships in "Belongs To" group. - Groups all hasMany relationships in "Has Many" group. - Groups all flags in "Flags" group. - Flags relationship CPs as expensive properties. @method _debugInfo @for DS.Model @private */ _debugInfo: function() { var attributes = ['id'], relationships = { belongsTo: [], hasMany: [] }, expensiveProperties = []; this.eachAttribute(function(name, meta) { attributes.push(name); }, this); this.eachRelationship(function(name, relationship) { relationships[relationship.kind].push(name); expensiveProperties.push(name); }); var groups = [ { name: 'Attributes', properties: attributes, expand: true }, { name: 'Belongs To', properties: relationships.belongsTo, expand: true }, { name: 'Has Many', properties: relationships.hasMany, expand: true }, { name: 'Flags', properties: ['isLoaded', 'isDirty', 'isSaving', 'isDeleted', 'isError', 'isNew', 'isValid'] } ]; return { propertyInfo: { // include all other mixins / properties (not just the grouped ones) includeOtherProperties: true, groups: groups, // don't pre-calculate unless cached expensiveProperties: expensiveProperties } }; } }); })(); (function() { /** @module ember-data */ })(); (function() { /** Ember Data @module ember-data @main ember-data */ })(); (function() { Ember.String.pluralize = function(word) { return Ember.Inflector.inflector.pluralize(word); }; Ember.String.singularize = function(word) { return Ember.Inflector.inflector.singularize(word); }; })(); (function() { var BLANK_REGEX = /^\s*$/; function loadUncountable(rules, uncountable) { for (var i = 0, length = uncountable.length; i < length; i++) { rules.uncountable[uncountable[i]] = true; } } function loadIrregular(rules, irregularPairs) { var pair; for (var i = 0, length = irregularPairs.length; i < length; i++) { pair = irregularPairs[i]; rules.irregular[pair[0]] = pair[1]; rules.irregularInverse[pair[1]] = pair[0]; } } /** Inflector.Ember provides a mechanism for supplying inflection rules for your application. Ember includes a default set of inflection rules, and provides an API for providing additional rules. Examples: Creating an inflector with no rules. ```js var inflector = new Ember.Inflector(); ``` Creating an inflector with the default ember ruleset. ```js var inflector = new Ember.Inflector(Ember.Inflector.defaultRules); inflector.pluralize('cow') //=> 'kine' inflector.singularize('kine') //=> 'cow' ``` Creating an inflector and adding rules later. ```javascript var inflector = Ember.Inflector.inflector; inflector.pluralize('advice') // => 'advices' inflector.uncountable('advice'); inflector.pluralize('advice') // => 'advice' inflector.pluralize('formula') // => 'formulas' inflector.irregular('formula', 'formulae'); inflector.pluralize('formula') // => 'formulae' // you would not need to add these as they are the default rules inflector.plural(/$/, 's'); inflector.singular(/s$/i, ''); ``` Creating an inflector with a nondefault ruleset. ```javascript var rules = { plurals: [ /$/, 's' ], singular: [ /\s$/, '' ], irregularPairs: [ [ 'cow', 'kine' ] ], uncountable: [ 'fish' ] }; var inflector = new Ember.Inflector(rules); ``` @class Inflector @namespace Ember */ function Inflector(ruleSet) { ruleSet = ruleSet || {}; ruleSet.uncountable = ruleSet.uncountable || {}; ruleSet.irregularPairs= ruleSet.irregularPairs|| {}; var rules = this.rules = { plurals: ruleSet.plurals || [], singular: ruleSet.singular || [], irregular: {}, irregularInverse: {}, uncountable: {} }; loadUncountable(rules, ruleSet.uncountable); loadIrregular(rules, ruleSet.irregularPairs); } Inflector.prototype = { /** @method plural @param {RegExp} regex @param {String} string */ plural: function(regex, string) { this.rules.plurals.push([regex, string]); }, /** @method singular @param {RegExp} regex @param {String} string */ singular: function(regex, string) { this.rules.singular.push([regex, string]); }, /** @method uncountable @param {String} regex */ uncountable: function(string) { loadUncountable(this.rules, [string]); }, /** @method irregular @param {String} singular @param {String} plural */ irregular: function (singular, plural) { loadIrregular(this.rules, [[singular, plural]]); }, /** @method pluralize @param {String} word */ pluralize: function(word) { return this.inflect(word, this.rules.plurals, this.rules.irregular); }, /** @method singularize @param {String} word */ singularize: function(word) { return this.inflect(word, this.rules.singular, this.rules.irregularInverse); }, /** @protected @method inflect @param {String} word @param {Object} typeRules @param {Object} irregular */ inflect: function(word, typeRules, irregular) { var inflection, substitution, result, lowercase, isBlank, isUncountable, isIrregular, isIrregularInverse, rule; isBlank = BLANK_REGEX.test(word); if (isBlank) { return word; } lowercase = word.toLowerCase(); isUncountable = this.rules.uncountable[lowercase]; if (isUncountable) { return word; } isIrregular = irregular && irregular[lowercase]; if (isIrregular) { return isIrregular; } for (var i = typeRules.length, min = 0; i > min; i--) { inflection = typeRules[i-1]; rule = inflection[0]; if (rule.test(word)) { break; } } inflection = inflection || []; rule = inflection[0]; substitution = inflection[1]; result = word.replace(rule, substitution); return result; } }; Ember.Inflector = Inflector; })(); (function() { Ember.Inflector.defaultRules = { plurals: [ [/$/, 's'], [/s$/i, 's'], [/^(ax|test)is$/i, '$1es'], [/(octop|vir)us$/i, '$1i'], [/(octop|vir)i$/i, '$1i'], [/(alias|status)$/i, '$1es'], [/(bu)s$/i, '$1ses'], [/(buffal|tomat)o$/i, '$1oes'], [/([ti])um$/i, '$1a'], [/([ti])a$/i, '$1a'], [/sis$/i, 'ses'], [/(?:([^f])fe|([lr])f)$/i, '$1$2ves'], [/(hive)$/i, '$1s'], [/([^aeiouy]|qu)y$/i, '$1ies'], [/(x|ch|ss|sh)$/i, '$1es'], [/(matr|vert|ind)(?:ix|ex)$/i, '$1ices'], [/^(m|l)ouse$/i, '$1ice'], [/^(m|l)ice$/i, '$1ice'], [/^(ox)$/i, '$1en'], [/^(oxen)$/i, '$1'], [/(quiz)$/i, '$1zes'] ], singular: [ [/s$/i, ''], [/(ss)$/i, '$1'], [/(n)ews$/i, '$1ews'], [/([ti])a$/i, '$1um'], [/((a)naly|(b)a|(d)iagno|(p)arenthe|(p)rogno|(s)ynop|(t)he)(sis|ses)$/i, '$1sis'], [/(^analy)(sis|ses)$/i, '$1sis'], [/([^f])ves$/i, '$1fe'], [/(hive)s$/i, '$1'], [/(tive)s$/i, '$1'], [/([lr])ves$/i, '$1f'], [/([^aeiouy]|qu)ies$/i, '$1y'], [/(s)eries$/i, '$1eries'], [/(m)ovies$/i, '$1ovie'], [/(x|ch|ss|sh)es$/i, '$1'], [/^(m|l)ice$/i, '$1ouse'], [/(bus)(es)?$/i, '$1'], [/(o)es$/i, '$1'], [/(shoe)s$/i, '$1'], [/(cris|test)(is|es)$/i, '$1is'], [/^(a)x[ie]s$/i, '$1xis'], [/(octop|vir)(us|i)$/i, '$1us'], [/(alias|status)(es)?$/i, '$1'], [/^(ox)en/i, '$1'], [/(vert|ind)ices$/i, '$1ex'], [/(matr)ices$/i, '$1ix'], [/(quiz)zes$/i, '$1'], [/(database)s$/i, '$1'] ], irregularPairs: [ ['person', 'people'], ['man', 'men'], ['child', 'children'], ['sex', 'sexes'], ['move', 'moves'], ['cow', 'kine'], ['zombie', 'zombies'] ], uncountable: [ 'equipment', 'information', 'rice', 'money', 'species', 'series', 'fish', 'sheep', 'jeans', 'police' ] }; })(); (function() { if (Ember.EXTEND_PROTOTYPES === true || Ember.EXTEND_PROTOTYPES.String) { /** See {{#crossLink "Ember.String/pluralize"}}{{/crossLink}} @method pluralize @for String */ String.prototype.pluralize = function() { return Ember.String.pluralize(this); }; /** See {{#crossLink "Ember.String/singularize"}}{{/crossLink}} @method singularize @for String */ String.prototype.singularize = function() { return Ember.String.singularize(this); }; } })(); (function() { Ember.Inflector.inflector = new Ember.Inflector(Ember.Inflector.defaultRules); })(); (function() { })(); (function() { /** @module ember-data */ var get = Ember.get; var forEach = Ember.EnumerableUtils.forEach; DS.ActiveModelSerializer = DS.RESTSerializer.extend({ // SERIALIZE /** Converts camelcased attributes to underscored when serializing. @method keyForAttribute @param {String} attribute @returns String */ keyForAttribute: function(attr) { return Ember.String.decamelize(attr); }, /** Underscores relationship names and appends "_id" or "_ids" when serializing relationship keys. @method keyForRelationship @param {String} key @param {String} kind @returns String */ keyForRelationship: function(key, kind) { key = Ember.String.decamelize(key); if (kind === "belongsTo") { return key + "_id"; } else if (kind === "hasMany") { return Ember.String.singularize(key) + "_ids"; } else { return key; } }, /** Serialize has-may relationship when it is configured as embedded objects. @method serializeHasMany */ serializeHasMany: function(record, json, relationship) { var key = relationship.key, attrs = get(this, 'attrs'), embed = attrs && attrs[key] && attrs[key].embedded === 'always'; if (embed) { json[this.keyForAttribute(key)] = get(record, key).map(function(relation) { var data = relation.serialize(), primaryKey = get(this, 'primaryKey'); data[primaryKey] = get(relation, primaryKey); return data; }, this); } }, /** Underscores the JSON root keys when serializing. @method serializeIntoHash @param {Object} hash @param {subclass of DS.Model} type @param {DS.Model} record @param {Object} options */ serializeIntoHash: function(data, type, record, options) { var root = Ember.String.decamelize(type.typeKey); data[root] = this.serialize(record, options); }, /** Serializes a polymorphic type as a fully capitalized model name. @method serializePolymorphicType @param {DS.Model} record @param {Object} json @param relationship */ serializePolymorphicType: function(record, json, relationship) { var key = relationship.key, belongsTo = get(record, key); key = this.keyForAttribute(key); json[key + "_type"] = Ember.String.capitalize(belongsTo.constructor.typeKey); }, // EXTRACT /** Extracts the model typeKey from underscored root objects. @method typeForRoot @param {String} root @returns String the model's typeKey */ typeForRoot: function(root) { var camelized = Ember.String.camelize(root); return Ember.String.singularize(camelized); }, /** Normalize the polymorphic type from the JSON. Normalize: ```js { id: "1" minion: { type: "evil_minion", id: "12"} } ``` To: ```js { id: "1" minion: { type: "evilMinion", id: "12"} } ``` @method normalizeRelationships @private */ normalizeRelationships: function(type, hash) { var payloadKey, payload; if (this.keyForRelationship) { type.eachRelationship(function(key, relationship) { if (relationship.options.polymorphic) { payloadKey = this.keyForAttribute(key); payload = hash[payloadKey]; if (payload && payload.type) { payload.type = this.typeForRoot(payload.type); } else if (payload && relationship.kind === "hasMany") { var self = this; forEach(payload, function(single) { single.type = self.typeForRoot(single.type); }); } } else { payloadKey = this.keyForRelationship(key, relationship.kind); payload = hash[payloadKey]; } hash[key] = payload; if (key !== payloadKey) { delete hash[payloadKey]; } }, this); } }, extractSingle: function(store, primaryType, payload, recordId, requestType) { var root = this.keyForAttribute(primaryType.typeKey), partial = payload[root]; updatePayloadWithEmbedded(store, this, primaryType, partial, payload); return this._super(store, primaryType, payload, recordId, requestType); }, extractArray: function(store, type, payload) { var root = this.keyForAttribute(type.typeKey), partials = payload[Ember.String.pluralize(root)]; forEach(partials, function(partial) { updatePayloadWithEmbedded(store, this, type, partial, payload); }, this); return this._super(store, type, payload); } }); function updatePayloadWithEmbedded(store, serializer, type, partial, payload) { var attrs = get(serializer, 'attrs'); if (!attrs) { return; } type.eachRelationship(function(key, relationship) { var expandedKey, embeddedTypeKey, attribute, ids, config = attrs[key], serializer = store.serializerFor(relationship.type.typeKey), primaryKey = get(serializer, "primaryKey"); if (relationship.kind !== "hasMany") { return; } if (config && (config.embedded === 'always' || config.embedded === 'load')) { // underscore forces the embedded records to be side loaded. // it is needed when main type === relationship.type embeddedTypeKey = '_' + Ember.String.pluralize(relationship.type.typeKey); expandedKey = this.keyForRelationship(key, relationship.kind); attribute = this.keyForAttribute(key); ids = []; if (!partial[attribute]) { return; } payload[embeddedTypeKey] = payload[embeddedTypeKey] || []; forEach(partial[attribute], function(data) { var embeddedType = store.modelFor(relationship.type.typeKey); updatePayloadWithEmbedded(store, serializer, embeddedType, data, payload); ids.push(data[primaryKey]); payload[embeddedTypeKey].push(data); }); partial[expandedKey] = ids; delete partial[attribute]; } }, serializer); } })(); (function() { /** @module ember-data */ var forEach = Ember.EnumerableUtils.forEach; /** The ActiveModelAdapter is a subclass of the RESTAdapter designed to integrate with a JSON API that uses an underscored naming convention instead of camelcasing. It has been designed to work out of the box with the [active_model_serializers](http://github.com/rails-api/active_model_serializers) Ruby gem. ## JSON Structure The ActiveModelAdapter expects the JSON returned from your server to follow the REST adapter conventions substituting underscored keys for camelcased ones. ### Conventional Names Attribute names in your JSON payload should be the underscored versions of the attributes in your Ember.js models. For example, if you have a `Person` model: ```js App.FamousPerson = DS.Model.extend({ firstName: DS.attr('string'), lastName: DS.attr('string'), occupation: DS.attr('string') }); ``` The JSON returned should look like this: ```js { "famous_person": { "first_name": "Barack", "last_name": "Obama", "occupation": "President" } } ``` @class ActiveModelAdapter @constructor @namespace DS @extends DS.Adapter **/ DS.ActiveModelAdapter = DS.RESTAdapter.extend({ defaultSerializer: '_ams', /** The ActiveModelAdapter overrides the `pathForType` method to build underscored URLs. ```js this.pathForType("famousPerson"); //=> "famous_people" ``` @method pathForType @param {String} type @returns String */ pathForType: function(type) { var decamelized = Ember.String.decamelize(type); return Ember.String.pluralize(decamelized); }, /** The ActiveModelAdapter overrides the `ajaxError` method to return a DS.InvalidError for all 422 Unprocessable Entity responses. @method ajaxError @param jqXHR @returns error */ ajaxError: function(jqXHR) { var error = this._super(jqXHR); if (jqXHR && jqXHR.status === 422) { var jsonErrors = Ember.$.parseJSON(jqXHR.responseText)["errors"], errors = {}; forEach(Ember.keys(jsonErrors), function(key) { errors[Ember.String.camelize(key)] = jsonErrors[key]; }); return new DS.InvalidError(errors); } else { return error; } } }); })(); (function() { })(); (function() { Ember.onLoad('Ember.Application', function(Application) { Application.initializer({ name: "activeModelAdapter", initialize: function(container, application) { application.register('serializer:_ams', DS.ActiveModelSerializer); application.register('adapter:_ams', DS.ActiveModelAdapter); } }); }); })(); (function() { })(); })(); ;TI"dependency_digest;TI"%5db016e720fe3b52257846250f3a53ee;FI"required_paths;T[I"($root/tmp/ember-rails/ember-data.js;FI"dependency_paths;T[{I" path;TI"($root/tmp/ember-rails/ember-data.js;FI" mtime;TI"2013-11-29T20:29:39-05:00;TI" digest;TI"%fc362a00a444d6723de9523c106b5cce;FI" _version;TI"%ad5851230fbdd4f8a862674697158df2;F