// Copyright (c) Microsoft, All rights reserved. See License.txt in the project root for license information. ;(function (undefined) { var objectTypes = { 'function': true, 'object': true }; function checkGlobal(value) { return (value && value.Object === Object) ? value : null; } var freeExports = (objectTypes[typeof exports] && exports && !exports.nodeType) ? exports : null; var freeModule = (objectTypes[typeof module] && module && !module.nodeType) ? module : null; var freeGlobal = checkGlobal(freeExports && freeModule && typeof global === 'object' && global); var freeSelf = checkGlobal(objectTypes[typeof self] && self); var freeWindow = checkGlobal(objectTypes[typeof window] && window); var moduleExports = (freeModule && freeModule.exports === freeExports) ? freeExports : null; var thisGlobal = checkGlobal(objectTypes[typeof this] && this); var root = freeGlobal || ((freeWindow !== (thisGlobal && thisGlobal.window)) && freeWindow) || freeSelf || thisGlobal || Function('return this')(); var Rx = { internals: {}, config: { Promise: root.Promise }, helpers: { } }; // Defaults var noop = Rx.helpers.noop = function () { }, identity = Rx.helpers.identity = function (x) { return x; }, defaultNow = Rx.helpers.defaultNow = (function () { return !!Date.now ? Date.now : function () { return +new Date; }; }()), defaultComparer = Rx.helpers.defaultComparer = function (x, y) { return isEqual(x, y); }, defaultSubComparer = Rx.helpers.defaultSubComparer = function (x, y) { return x > y ? 1 : (x < y ? -1 : 0); }, defaultKeySerializer = Rx.helpers.defaultKeySerializer = function (x) { return x.toString(); }, defaultError = Rx.helpers.defaultError = function (err) { throw err; }, isPromise = Rx.helpers.isPromise = function (p) { return !!p && typeof p.subscribe !== 'function' && typeof p.then === 'function'; }, isFunction = Rx.helpers.isFunction = (function () { var isFn = function (value) { return typeof value == 'function' || false; }; // fallback for older versions of Chrome and Safari if (isFn(/x/)) { isFn = function(value) { return typeof value == 'function' && toString.call(value) == '[object Function]'; }; } return isFn; }()); function cloneArray(arr) { var len = arr.length, a = new Array(len); for(var i = 0; i < len; i++) { a[i] = arr[i]; } return a; } var errorObj = {e: {}}; function tryCatcherGen(tryCatchTarget) { return function tryCatcher() { try { return tryCatchTarget.apply(this, arguments); } catch (e) { errorObj.e = e; return errorObj; } }; } var tryCatch = Rx.internals.tryCatch = function tryCatch(fn) { if (!isFunction(fn)) { throw new TypeError('fn must be a function'); } return tryCatcherGen(fn); }; function thrower(e) { throw e; } Rx.config.longStackSupport = false; var hasStacks = false, stacks = tryCatch(function () { throw new Error(); })(); hasStacks = !!stacks.e && !!stacks.e.stack; // All code after this point will be filtered from stack traces reported by RxJS var rStartingLine = captureLine(), rFileName; var STACK_JUMP_SEPARATOR = 'From previous event:'; function makeStackTraceLong(error, observable) { // If possible, transform the error stack trace by removing Node and RxJS // cruft, then concatenating with the stack trace of `observable`. if (hasStacks && observable.stack && typeof error === 'object' && error !== null && error.stack && error.stack.indexOf(STACK_JUMP_SEPARATOR) === -1 ) { var stacks = []; for (var o = observable; !!o; o = o.source) { if (o.stack) { stacks.unshift(o.stack); } } stacks.unshift(error.stack); var concatedStacks = stacks.join('\n' + STACK_JUMP_SEPARATOR + '\n'); error.stack = filterStackString(concatedStacks); } } function filterStackString(stackString) { var lines = stackString.split('\n'), desiredLines = []; for (var i = 0, len = lines.length; i < len; i++) { var line = lines[i]; if (!isInternalFrame(line) && !isNodeFrame(line) && line) { desiredLines.push(line); } } return desiredLines.join('\n'); } function isInternalFrame(stackLine) { var fileNameAndLineNumber = getFileNameAndLineNumber(stackLine); if (!fileNameAndLineNumber) { return false; } var fileName = fileNameAndLineNumber[0], lineNumber = fileNameAndLineNumber[1]; return fileName === rFileName && lineNumber >= rStartingLine && lineNumber <= rEndingLine; } function isNodeFrame(stackLine) { return stackLine.indexOf('(module.js:') !== -1 || stackLine.indexOf('(node.js:') !== -1; } function captureLine() { if (!hasStacks) { return; } try { throw new Error(); } catch (e) { var lines = e.stack.split('\n'); var firstLine = lines[0].indexOf('@') > 0 ? lines[1] : lines[2]; var fileNameAndLineNumber = getFileNameAndLineNumber(firstLine); if (!fileNameAndLineNumber) { return; } rFileName = fileNameAndLineNumber[0]; return fileNameAndLineNumber[1]; } } function getFileNameAndLineNumber(stackLine) { // Named functions: 'at functionName (filename:lineNumber:columnNumber)' var attempt1 = /at .+ \((.+):(\d+):(?:\d+)\)$/.exec(stackLine); if (attempt1) { return [attempt1[1], Number(attempt1[2])]; } // Anonymous functions: 'at filename:lineNumber:columnNumber' var attempt2 = /at ([^ ]+):(\d+):(?:\d+)$/.exec(stackLine); if (attempt2) { return [attempt2[1], Number(attempt2[2])]; } // Firefox style: 'function@filename:lineNumber or @filename:lineNumber' var attempt3 = /.*@(.+):(\d+)$/.exec(stackLine); if (attempt3) { return [attempt3[1], Number(attempt3[2])]; } } // Utilities var toString = Object.prototype.toString; var arrayClass = '[object Array]', funcClass = '[object Function]', stringClass = '[object String]'; if (!Array.prototype.forEach) { Array.prototype.forEach = function (callback, thisArg) { var T, k; if (this == null) { throw new TypeError(' this is null or not defined'); } var O = Object(this); var len = O.length >>> 0; if (typeof callback !== 'function') { throw new TypeError(callback + ' is not a function'); } if (arguments.length > 1) { T = thisArg; } k = 0; while (k < len) { var kValue; if (k in O) { kValue = O[k]; callback.call(T, kValue, k, O); } k++; } }; } var boxedString = Object('a'), splitString = boxedString[0] !== 'a' || !(0 in boxedString); if (!Array.prototype.every) { Array.prototype.every = function every(fun /*, thisp */) { var object = Object(this), self = splitString && toString.call(this) === stringClass ? this.split('') : object, length = self.length >>> 0, thisp = arguments[1]; if (toString.call(fun) !== funcClass) { throw new TypeError(fun + ' is not a function'); } for (var i = 0; i < length; i++) { if (i in self && !fun.call(thisp, self[i], i, object)) { return false; } } return true; }; } if (!Array.prototype.map) { Array.prototype.map = function map(fun /*, thisp*/) { var object = Object(this), self = splitString && toString.call(this) === stringClass ? this.split('') : object, length = self.length >>> 0, result = new Array(length), thisp = arguments[1]; if (toString.call(fun) !== funcClass) { throw new TypeError(fun + ' is not a function'); } for (var i = 0; i < length; i++) { if (i in self) { result[i] = fun.call(thisp, self[i], i, object); } } return result; }; } if (!Array.prototype.filter) { Array.prototype.filter = function (predicate) { var results = [], item, t = new Object(this); for (var i = 0, len = t.length >>> 0; i < len; i++) { item = t[i]; if (i in t && predicate.call(arguments[1], item, i, t)) { results.push(item); } } return results; }; } if (!Array.isArray) { Array.isArray = function (arg) { return toString.call(arg) === arrayClass; }; } if (!Array.prototype.indexOf) { Array.prototype.indexOf = function indexOf(searchElement) { var t = Object(this); var len = t.length >>> 0; if (len === 0) { return -1; } var n = 0; if (arguments.length > 1) { n = Number(arguments[1]); if (n !== n) { n = 0; } else if (n !== 0 && n !== Infinity && n !== -Infinity) { n = (n > 0 || -1) * Math.floor(Math.abs(n)); } } if (n >= len) { return -1; } var k = n >= 0 ? n : Math.max(len - Math.abs(n), 0); for (; k < len; k++) { if (k in t && t[k] === searchElement) { return k; } } return -1; }; } // Fix for Tessel if (!Object.prototype.propertyIsEnumerable) { Object.prototype.propertyIsEnumerable = function (key) { for (var k in this) { if (k === key) { return true; } } return false; }; } if (!Object.keys) { Object.keys = (function() { 'use strict'; var hasOwnProperty = Object.prototype.hasOwnProperty, hasDontEnumBug = !({ toString: null }).propertyIsEnumerable('toString'); return function(obj) { if (typeof obj !== 'object' && (typeof obj !== 'function' || obj === null)) { throw new TypeError('Object.keys called on non-object'); } var result = [], prop, i; for (prop in obj) { if (hasOwnProperty.call(obj, prop)) { result.push(prop); } } if (hasDontEnumBug) { for (i = 0; i < dontEnumsLength; i++) { if (hasOwnProperty.call(obj, dontEnums[i])) { result.push(dontEnums[i]); } } } return result; }; }()); } if (typeof Object.create !== 'function') { // Production steps of ECMA-262, Edition 5, 15.2.3.5 // Reference: http://es5.github.io/#x15.2.3.5 Object.create = (function() { function Temp() {} var hasOwn = Object.prototype.hasOwnProperty; return function (O) { if (typeof O !== 'object') { throw new TypeError('Object prototype may only be an Object or null'); } Temp.prototype = O; var obj = new Temp(); Temp.prototype = null; if (arguments.length > 1) { // Object.defineProperties does ToObject on its first argument. var Properties = Object(arguments[1]); for (var prop in Properties) { if (hasOwn.call(Properties, prop)) { obj[prop] = Properties[prop]; } } } // 5. Return obj return obj; }; })(); } root.Element && root.Element.prototype.attachEvent && !root.Element.prototype.addEventListener && (function () { function addMethod(name, fn) { Window.prototype[name] = HTMLDocument.prototype[name] = Element.prototype[name] = fn; } addMethod('addEventListener', function (type, listener) { var target = this; var listeners = target._c1_listeners = target._c1_listeners || {}; var typeListeners = listeners[type] = listeners[type] || []; target.attachEvent('on' + type, typeListeners.event = function (e) { e || (e = root.event); var documentElement = target.document && target.document.documentElement || target.documentElement || { scrollLeft: 0, scrollTop: 0 }; e.currentTarget = target; e.pageX = e.clientX + documentElement.scrollLeft; e.pageY = e.clientY + documentElement.scrollTop; e.preventDefault = function () { e.bubbledKeyCode = e.keyCode; if (e.ctrlKey) { try { e.keyCode = 0; } catch (e) { } } e.defaultPrevented = true; e.returnValue = false; e.modified = true; e.returnValue = false; }; e.stopImmediatePropagation = function () { immediatePropagation = false; e.cancelBubble = true; }; e.stopPropagation = function () { e.cancelBubble = true; }; e.relatedTarget = e.fromElement || null; e.target = e.srcElement || target; e.timeStamp = +new Date(); // Normalize key events switch(e.type) { case 'keypress': var c = ('charCode' in e ? e.charCode : e.keyCode); if (c === 10) { c = 0; e.keyCode = 13; } else if (c === 13 || c === 27) { c = 0; } else if (c === 3) { c = 99; } e.charCode = c; e.keyChar = e.charCode ? String.fromCharCode(e.charCode) : ''; break; } var copiedEvent = {}; for (var prop in e) { copiedEvent[prop] = e[prop]; } for (var i = 0, typeListenersCache = [].concat(typeListeners), typeListenerCache, immediatePropagation = true; immediatePropagation && (typeListenerCache = typeListenersCache[i]); ++i) { for (var ii = 0, typeListener; typeListener = typeListeners[ii]; ++ii) { if (typeListener === typeListenerCache) { typeListener.call(target, copiedEvent); break; } } } }); typeListeners.push(listener); }); addMethod('removeEventListener', function (type, listener) { var target = this; var listeners = target._c1_listeners = target._c1_listeners || {}; var typeListeners = listeners[type] = listeners[type] || []; for (var i = typeListeners.length - 1, typeListener; typeListener = typeListeners[i]; --i) { if (typeListener === listener) { typeListeners.splice(i, 1); break; } } !typeListeners.length && typeListeners.event && target.detachEvent('on' + type, typeListeners.event); }); addMethod('dispatchEvent', function (e) { var target = this; var type = e.type; var listeners = target._c1_listeners = target._c1_listeners || {}; var typeListeners = listeners[type] = listeners[type] || []; try { return target.fireEvent('on' + type, e); } catch (err) { return typeListeners.event && typeListeners.event(e); } }); function ready() { if (ready.interval && document.body) { ready.interval = clearInterval(ready.interval); document.dispatchEvent(new CustomEvent('DOMContentLoaded')); } } ready.interval = setInterval(ready, 1); root.addEventListener('load', ready); }()); (!root.CustomEvent || typeof root.CustomEvent === 'object') && (function() { function CustomEvent (type, params) { var event; params = params || { bubbles: false, cancelable: false, detail: undefined }; try { if (document.createEvent) { event = document.createEvent('CustomEvent'); event.initCustomEvent(type, params.bubbles, params.cancelable, params.detail); } else if (document.createEventObject) { event = document.createEventObject(); } } catch (error) { event = document.createEvent('Event'); event.initEvent(type, params.bubbles, params.cancelable); event.detail = params.detail; } return event; } root.CustomEvent && (CustomEvent.prototype = root.CustomEvent.prototype); root.CustomEvent = CustomEvent; }()); var EmptyError = Rx.EmptyError = function() { this.message = 'Sequence contains no elements.'; Error.call(this); }; EmptyError.prototype = Object.create(Error.prototype); EmptyError.prototype.name = 'EmptyError'; var ObjectDisposedError = Rx.ObjectDisposedError = function() { this.message = 'Object has been disposed'; Error.call(this); }; ObjectDisposedError.prototype = Object.create(Error.prototype); ObjectDisposedError.prototype.name = 'ObjectDisposedError'; var ArgumentOutOfRangeError = Rx.ArgumentOutOfRangeError = function () { this.message = 'Argument out of range'; Error.call(this); }; ArgumentOutOfRangeError.prototype = Object.create(Error.prototype); ArgumentOutOfRangeError.prototype.name = 'ArgumentOutOfRangeError'; var NotSupportedError = Rx.NotSupportedError = function (message) { this.message = message || 'This operation is not supported'; Error.call(this); }; NotSupportedError.prototype = Object.create(Error.prototype); NotSupportedError.prototype.name = 'NotSupportedError'; var NotImplementedError = Rx.NotImplementedError = function (message) { this.message = message || 'This operation is not implemented'; Error.call(this); }; NotImplementedError.prototype = Object.create(Error.prototype); NotImplementedError.prototype.name = 'NotImplementedError'; var notImplemented = Rx.helpers.notImplemented = function () { throw new NotImplementedError(); }; var notSupported = Rx.helpers.notSupported = function () { throw new NotSupportedError(); }; // Shim in iterator support var $iterator$ = (typeof Symbol === 'function' && Symbol.iterator) || '_es6shim_iterator_'; // Bug for mozilla version if (root.Set && typeof new root.Set()['@@iterator'] === 'function') { $iterator$ = '@@iterator'; } var doneEnumerator = Rx.doneEnumerator = { done: true, value: undefined }; var isIterable = Rx.helpers.isIterable = function (o) { return o && o[$iterator$] !== undefined; }; var isArrayLike = Rx.helpers.isArrayLike = function (o) { return o && o.length !== undefined; }; Rx.helpers.iterator = $iterator$; var bindCallback = Rx.internals.bindCallback = function (func, thisArg, argCount) { if (typeof thisArg === 'undefined') { return func; } switch(argCount) { case 0: return function() { return func.call(thisArg) }; case 1: return function(arg) { return func.call(thisArg, arg); }; case 2: return function(value, index) { return func.call(thisArg, value, index); }; case 3: return function(value, index, collection) { return func.call(thisArg, value, index, collection); }; } return function() { return func.apply(thisArg, arguments); }; }; /** Used to determine if values are of the language type Object */ var dontEnums = ['toString', 'toLocaleString', 'valueOf', 'hasOwnProperty', 'isPrototypeOf', 'propertyIsEnumerable', 'constructor'], dontEnumsLength = dontEnums.length; var argsTag = '[object Arguments]', arrayTag = '[object Array]', boolTag = '[object Boolean]', dateTag = '[object Date]', errorTag = '[object Error]', funcTag = '[object Function]', mapTag = '[object Map]', numberTag = '[object Number]', objectTag = '[object Object]', regexpTag = '[object RegExp]', setTag = '[object Set]', stringTag = '[object String]', weakMapTag = '[object WeakMap]'; var arrayBufferTag = '[object ArrayBuffer]', float32Tag = '[object Float32Array]', float64Tag = '[object Float64Array]', int8Tag = '[object Int8Array]', int16Tag = '[object Int16Array]', int32Tag = '[object Int32Array]', uint8Tag = '[object Uint8Array]', uint8ClampedTag = '[object Uint8ClampedArray]', uint16Tag = '[object Uint16Array]', uint32Tag = '[object Uint32Array]'; var typedArrayTags = {}; typedArrayTags[float32Tag] = typedArrayTags[float64Tag] = typedArrayTags[int8Tag] = typedArrayTags[int16Tag] = typedArrayTags[int32Tag] = typedArrayTags[uint8Tag] = typedArrayTags[uint8ClampedTag] = typedArrayTags[uint16Tag] = typedArrayTags[uint32Tag] = true; typedArrayTags[argsTag] = typedArrayTags[arrayTag] = typedArrayTags[arrayBufferTag] = typedArrayTags[boolTag] = typedArrayTags[dateTag] = typedArrayTags[errorTag] = typedArrayTags[funcTag] = typedArrayTags[mapTag] = typedArrayTags[numberTag] = typedArrayTags[objectTag] = typedArrayTags[regexpTag] = typedArrayTags[setTag] = typedArrayTags[stringTag] = typedArrayTags[weakMapTag] = false; var objectProto = Object.prototype, hasOwnProperty = objectProto.hasOwnProperty, objToString = objectProto.toString, MAX_SAFE_INTEGER = Math.pow(2, 53) - 1; var keys = Object.keys || (function() { var hasOwnProperty = Object.prototype.hasOwnProperty, hasDontEnumBug = !({ toString: null }).propertyIsEnumerable('toString'), dontEnums = [ 'toString', 'toLocaleString', 'valueOf', 'hasOwnProperty', 'isPrototypeOf', 'propertyIsEnumerable', 'constructor' ], dontEnumsLength = dontEnums.length; return function(obj) { if (typeof obj !== 'object' && (typeof obj !== 'function' || obj === null)) { throw new TypeError('Object.keys called on non-object'); } var result = [], prop, i; for (prop in obj) { if (hasOwnProperty.call(obj, prop)) { result.push(prop); } } if (hasDontEnumBug) { for (i = 0; i < dontEnumsLength; i++) { if (hasOwnProperty.call(obj, dontEnums[i])) { result.push(dontEnums[i]); } } } return result; }; }()); function equalObjects(object, other, equalFunc, isLoose, stackA, stackB) { var objProps = keys(object), objLength = objProps.length, othProps = keys(other), othLength = othProps.length; if (objLength !== othLength && !isLoose) { return false; } var index = objLength, key; while (index--) { key = objProps[index]; if (!(isLoose ? key in other : hasOwnProperty.call(other, key))) { return false; } } var skipCtor = isLoose; while (++index < objLength) { key = objProps[index]; var objValue = object[key], othValue = other[key], result; if (!(result === undefined ? equalFunc(objValue, othValue, isLoose, stackA, stackB) : result)) { return false; } skipCtor || (skipCtor = key === 'constructor'); } if (!skipCtor) { var objCtor = object.constructor, othCtor = other.constructor; if (objCtor !== othCtor && ('constructor' in object && 'constructor' in other) && !(typeof objCtor === 'function' && objCtor instanceof objCtor && typeof othCtor === 'function' && othCtor instanceof othCtor)) { return false; } } return true; } function equalByTag(object, other, tag) { switch (tag) { case boolTag: case dateTag: return +object === +other; case errorTag: return object.name === other.name && object.message === other.message; case numberTag: return (object !== +object) ? other !== +other : object === +other; case regexpTag: case stringTag: return object === (other + ''); } return false; } var isObject = Rx.internals.isObject = function(value) { var type = typeof value; return !!value && (type === 'object' || type === 'function'); }; function isObjectLike(value) { return !!value && typeof value === 'object'; } function isLength(value) { return typeof value === 'number' && value > -1 && value % 1 === 0 && value <= MAX_SAFE_INTEGER; } var isHostObject = (function() { try { Object({ 'toString': 0 } + ''); } catch(e) { return function() { return false; }; } return function(value) { return typeof value.toString !== 'function' && typeof (value + '') === 'string'; }; }()); function isTypedArray(value) { return isObjectLike(value) && isLength(value.length) && !!typedArrayTags[objToString.call(value)]; } var isArray = Array.isArray || function(value) { return isObjectLike(value) && isLength(value.length) && objToString.call(value) === arrayTag; }; function arraySome (array, predicate) { var index = -1, length = array.length; while (++index < length) { if (predicate(array[index], index, array)) { return true; } } return false; } function equalArrays(array, other, equalFunc, isLoose, stackA, stackB) { var index = -1, arrLength = array.length, othLength = other.length; if (arrLength !== othLength && !(isLoose && othLength > arrLength)) { return false; } // Ignore non-index properties. while (++index < arrLength) { var arrValue = array[index], othValue = other[index], result; if (result !== undefined) { if (result) { continue; } return false; } // Recursively compare arrays (susceptible to call stack limits). if (isLoose) { if (!arraySome(other, function(othValue) { return arrValue === othValue || equalFunc(arrValue, othValue, isLoose, stackA, stackB); })) { return false; } } else if (!(arrValue === othValue || equalFunc(arrValue, othValue, isLoose, stackA, stackB))) { return false; } } return true; } function baseIsEqualDeep(object, other, equalFunc, isLoose, stackA, stackB) { var objIsArr = isArray(object), othIsArr = isArray(other), objTag = arrayTag, othTag = arrayTag; if (!objIsArr) { objTag = objToString.call(object); if (objTag === argsTag) { objTag = objectTag; } else if (objTag !== objectTag) { objIsArr = isTypedArray(object); } } if (!othIsArr) { othTag = objToString.call(other); if (othTag === argsTag) { othTag = objectTag; } } var objIsObj = objTag === objectTag && !isHostObject(object), othIsObj = othTag === objectTag && !isHostObject(other), isSameTag = objTag === othTag; if (isSameTag && !(objIsArr || objIsObj)) { return equalByTag(object, other, objTag); } if (!isLoose) { var objIsWrapped = objIsObj && hasOwnProperty.call(object, '__wrapped__'), othIsWrapped = othIsObj && hasOwnProperty.call(other, '__wrapped__'); if (objIsWrapped || othIsWrapped) { return equalFunc(objIsWrapped ? object.value() : object, othIsWrapped ? other.value() : other, isLoose, stackA, stackB); } } if (!isSameTag) { return false; } // Assume cyclic values are equal. // For more information on detecting circular references see https://es5.github.io/#JO. stackA || (stackA = []); stackB || (stackB = []); var length = stackA.length; while (length--) { if (stackA[length] === object) { return stackB[length] === other; } } // Add `object` and `other` to the stack of traversed objects. stackA.push(object); stackB.push(other); var result = (objIsArr ? equalArrays : equalObjects)(object, other, equalFunc, isLoose, stackA, stackB); stackA.pop(); stackB.pop(); return result; } function baseIsEqual(value, other, isLoose, stackA, stackB) { if (value === other) { return true; } if (value == null || other == null || (!isObject(value) && !isObjectLike(other))) { return value !== value && other !== other; } return baseIsEqualDeep(value, other, baseIsEqual, isLoose, stackA, stackB); } var isEqual = Rx.internals.isEqual = function (value, other) { return baseIsEqual(value, other); }; var hasProp = {}.hasOwnProperty, slice = Array.prototype.slice; var inherits = Rx.internals.inherits = function (child, parent) { function __() { this.constructor = child; } __.prototype = parent.prototype; child.prototype = new __(); }; var addProperties = Rx.internals.addProperties = function (obj) { for(var sources = [], i = 1, len = arguments.length; i < len; i++) { sources.push(arguments[i]); } for (var idx = 0, ln = sources.length; idx < ln; idx++) { var source = sources[idx]; for (var prop in source) { obj[prop] = source[prop]; } } }; // Rx Utils var addRef = Rx.internals.addRef = function (xs, r) { return new AnonymousObservable(function (observer) { return new BinaryDisposable(r.getDisposable(), xs.subscribe(observer)); }); }; function arrayInitialize(count, factory) { var a = new Array(count); for (var i = 0; i < count; i++) { a[i] = factory(); } return a; } /** * Represents a group of disposable resources that are disposed together. * @constructor */ var CompositeDisposable = Rx.CompositeDisposable = function () { var args = [], i, len; if (Array.isArray(arguments[0])) { args = arguments[0]; } else { len = arguments.length; args = new Array(len); for(i = 0; i < len; i++) { args[i] = arguments[i]; } } this.disposables = args; this.isDisposed = false; this.length = args.length; }; var CompositeDisposablePrototype = CompositeDisposable.prototype; /** * Adds a disposable to the CompositeDisposable or disposes the disposable if the CompositeDisposable is disposed. * @param {Mixed} item Disposable to add. */ CompositeDisposablePrototype.add = function (item) { if (this.isDisposed) { item.dispose(); } else { this.disposables.push(item); this.length++; } }; /** * Removes and disposes the first occurrence of a disposable from the CompositeDisposable. * @param {Mixed} item Disposable to remove. * @returns {Boolean} true if found; false otherwise. */ CompositeDisposablePrototype.remove = function (item) { var shouldDispose = false; if (!this.isDisposed) { var idx = this.disposables.indexOf(item); if (idx !== -1) { shouldDispose = true; this.disposables.splice(idx, 1); this.length--; item.dispose(); } } return shouldDispose; }; /** * Disposes all disposables in the group and removes them from the group. */ CompositeDisposablePrototype.dispose = function () { if (!this.isDisposed) { this.isDisposed = true; var len = this.disposables.length, currentDisposables = new Array(len); for(var i = 0; i < len; i++) { currentDisposables[i] = this.disposables[i]; } this.disposables = []; this.length = 0; for (i = 0; i < len; i++) { currentDisposables[i].dispose(); } } }; /** * Provides a set of static methods for creating Disposables. * @param {Function} dispose Action to run during the first call to dispose. The action is guaranteed to be run at most once. */ var Disposable = Rx.Disposable = function (action) { this.isDisposed = false; this.action = action || noop; }; /** Performs the task of cleaning up resources. */ Disposable.prototype.dispose = function () { if (!this.isDisposed) { this.action(); this.isDisposed = true; } }; /** * Creates a disposable object that invokes the specified action when disposed. * @param {Function} dispose Action to run during the first call to dispose. The action is guaranteed to be run at most once. * @return {Disposable} The disposable object that runs the given action upon disposal. */ var disposableCreate = Disposable.create = function (action) { return new Disposable(action); }; /** * Gets the disposable that does nothing when disposed. */ var disposableEmpty = Disposable.empty = { dispose: noop }; /** * Validates whether the given object is a disposable * @param {Object} Object to test whether it has a dispose method * @returns {Boolean} true if a disposable object, else false. */ var isDisposable = Disposable.isDisposable = function (d) { return d && isFunction(d.dispose); }; var checkDisposed = Disposable.checkDisposed = function (disposable) { if (disposable.isDisposed) { throw new ObjectDisposedError(); } }; var disposableFixup = Disposable._fixup = function (result) { return isDisposable(result) ? result : disposableEmpty; }; // Single assignment var SingleAssignmentDisposable = Rx.SingleAssignmentDisposable = function () { this.isDisposed = false; this.current = null; }; SingleAssignmentDisposable.prototype.getDisposable = function () { return this.current; }; SingleAssignmentDisposable.prototype.setDisposable = function (value) { if (this.current) { throw new Error('Disposable has already been assigned'); } var shouldDispose = this.isDisposed; !shouldDispose && (this.current = value); shouldDispose && value && value.dispose(); }; SingleAssignmentDisposable.prototype.dispose = function () { if (!this.isDisposed) { this.isDisposed = true; var old = this.current; this.current = null; old && old.dispose(); } }; // Multiple assignment disposable var SerialDisposable = Rx.SerialDisposable = function () { this.isDisposed = false; this.current = null; }; SerialDisposable.prototype.getDisposable = function () { return this.current; }; SerialDisposable.prototype.setDisposable = function (value) { var shouldDispose = this.isDisposed; if (!shouldDispose) { var old = this.current; this.current = value; } old && old.dispose(); shouldDispose && value && value.dispose(); }; SerialDisposable.prototype.dispose = function () { if (!this.isDisposed) { this.isDisposed = true; var old = this.current; this.current = null; } old && old.dispose(); }; var BinaryDisposable = Rx.BinaryDisposable = function (first, second) { this._first = first; this._second = second; this.isDisposed = false; }; BinaryDisposable.prototype.dispose = function () { if (!this.isDisposed) { this.isDisposed = true; var old1 = this._first; this._first = null; old1 && old1.dispose(); var old2 = this._second; this._second = null; old2 && old2.dispose(); } }; var NAryDisposable = Rx.NAryDisposable = function (disposables) { this._disposables = disposables; this.isDisposed = false; }; NAryDisposable.prototype.dispose = function () { if (!this.isDisposed) { this.isDisposed = true; for (var i = 0, len = this._disposables.length; i < len; i++) { this._disposables[i].dispose(); } this._disposables.length = 0; } }; /** * Represents a disposable resource that only disposes its underlying disposable resource when all dependent disposable objects have been disposed. */ var RefCountDisposable = Rx.RefCountDisposable = (function () { function InnerDisposable(disposable) { this.disposable = disposable; this.disposable.count++; this.isInnerDisposed = false; } InnerDisposable.prototype.dispose = function () { if (!this.disposable.isDisposed && !this.isInnerDisposed) { this.isInnerDisposed = true; this.disposable.count--; if (this.disposable.count === 0 && this.disposable.isPrimaryDisposed) { this.disposable.isDisposed = true; this.disposable.underlyingDisposable.dispose(); } } }; /** * Initializes a new instance of the RefCountDisposable with the specified disposable. * @constructor * @param {Disposable} disposable Underlying disposable. */ function RefCountDisposable(disposable) { this.underlyingDisposable = disposable; this.isDisposed = false; this.isPrimaryDisposed = false; this.count = 0; } /** * Disposes the underlying disposable only when all dependent disposables have been disposed */ RefCountDisposable.prototype.dispose = function () { if (!this.isDisposed && !this.isPrimaryDisposed) { this.isPrimaryDisposed = true; if (this.count === 0) { this.isDisposed = true; this.underlyingDisposable.dispose(); } } }; /** * Returns a dependent disposable that when disposed decreases the refcount on the underlying disposable. * @returns {Disposable} A dependent disposable contributing to the reference count that manages the underlying disposable's lifetime. */ RefCountDisposable.prototype.getDisposable = function () { return this.isDisposed ? disposableEmpty : new InnerDisposable(this); }; return RefCountDisposable; })(); function ScheduledDisposable(scheduler, disposable) { this.scheduler = scheduler; this.disposable = disposable; this.isDisposed = false; } function scheduleItem(s, self) { if (!self.isDisposed) { self.isDisposed = true; self.disposable.dispose(); } } ScheduledDisposable.prototype.dispose = function () { this.scheduler.schedule(this, scheduleItem); }; var ScheduledItem = Rx.internals.ScheduledItem = function (scheduler, state, action, dueTime, comparer) { this.scheduler = scheduler; this.state = state; this.action = action; this.dueTime = dueTime; this.comparer = comparer || defaultSubComparer; this.disposable = new SingleAssignmentDisposable(); }; ScheduledItem.prototype.invoke = function () { this.disposable.setDisposable(this.invokeCore()); }; ScheduledItem.prototype.compareTo = function (other) { return this.comparer(this.dueTime, other.dueTime); }; ScheduledItem.prototype.isCancelled = function () { return this.disposable.isDisposed; }; ScheduledItem.prototype.invokeCore = function () { return disposableFixup(this.action(this.scheduler, this.state)); }; /** Provides a set of static properties to access commonly used schedulers. */ var Scheduler = Rx.Scheduler = (function () { function Scheduler() { } /** Determines whether the given object is a scheduler */ Scheduler.isScheduler = function (s) { return s instanceof Scheduler; }; var schedulerProto = Scheduler.prototype; /** * Schedules an action to be executed. * @param state State passed to the action to be executed. * @param {Function} action Action to be executed. * @returns {Disposable} The disposable object used to cancel the scheduled action (best effort). */ schedulerProto.schedule = function (state, action) { throw new NotImplementedError(); }; /** * Schedules an action to be executed after dueTime. * @param state State passed to the action to be executed. * @param {Function} action Action to be executed. * @param {Number} dueTime Relative time after which to execute the action. * @returns {Disposable} The disposable object used to cancel the scheduled action (best effort). */ schedulerProto.scheduleFuture = function (state, dueTime, action) { var dt = dueTime; dt instanceof Date && (dt = dt - this.now()); dt = Scheduler.normalize(dt); if (dt === 0) { return this.schedule(state, action); } return this._scheduleFuture(state, dt, action); }; schedulerProto._scheduleFuture = function (state, dueTime, action) { throw new NotImplementedError(); }; /** Gets the current time according to the local machine's system clock. */ Scheduler.now = defaultNow; /** Gets the current time according to the local machine's system clock. */ Scheduler.prototype.now = defaultNow; /** * Normalizes the specified TimeSpan value to a positive value. * @param {Number} timeSpan The time span value to normalize. * @returns {Number} The specified TimeSpan value if it is zero or positive; otherwise, 0 */ Scheduler.normalize = function (timeSpan) { timeSpan < 0 && (timeSpan = 0); return timeSpan; }; return Scheduler; }()); var normalizeTime = Scheduler.normalize, isScheduler = Scheduler.isScheduler; (function (schedulerProto) { function invokeRecImmediate(scheduler, pair) { var state = pair[0], action = pair[1], group = new CompositeDisposable(); action(state, innerAction); return group; function innerAction(state2) { var isAdded = false, isDone = false; var d = scheduler.schedule(state2, scheduleWork); if (!isDone) { group.add(d); isAdded = true; } function scheduleWork(_, state3) { if (isAdded) { group.remove(d); } else { isDone = true; } action(state3, innerAction); return disposableEmpty; } } } function invokeRecDate(scheduler, pair) { var state = pair[0], action = pair[1], group = new CompositeDisposable(); action(state, innerAction); return group; function innerAction(state2, dueTime1) { var isAdded = false, isDone = false; var d = scheduler.scheduleFuture(state2, dueTime1, scheduleWork); if (!isDone) { group.add(d); isAdded = true; } function scheduleWork(_, state3) { if (isAdded) { group.remove(d); } else { isDone = true; } action(state3, innerAction); return disposableEmpty; } } } /** * Schedules an action to be executed recursively. * @param {Mixed} state State passed to the action to be executed. * @param {Function} action Action to execute recursively. The last parameter passed to the action is used to trigger recursive scheduling of the action, passing in recursive invocation state. * @returns {Disposable} The disposable object used to cancel the scheduled action (best effort). */ schedulerProto.scheduleRecursive = function (state, action) { return this.schedule([state, action], invokeRecImmediate); }; /** * Schedules an action to be executed recursively after a specified relative or absolute due time. * @param {Mixed} state State passed to the action to be executed. * @param {Function} action Action to execute recursively. The last parameter passed to the action is used to trigger recursive scheduling of the action, passing in the recursive due time and invocation state. * @param {Number | Date} dueTime Relative or absolute time after which to execute the action for the first time. * @returns {Disposable} The disposable object used to cancel the scheduled action (best effort). */ schedulerProto.scheduleRecursiveFuture = function (state, dueTime, action) { return this.scheduleFuture([state, action], dueTime, invokeRecDate); }; }(Scheduler.prototype)); (function (schedulerProto) { /** * Schedules a periodic piece of work by dynamically discovering the scheduler's capabilities. The periodic task will be scheduled using window.setInterval for the base implementation. * @param {Mixed} state Initial state passed to the action upon the first iteration. * @param {Number} period Period for running the work periodically. * @param {Function} action Action to be executed, potentially updating the state. * @returns {Disposable} The disposable object used to cancel the scheduled recurring action (best effort). */ schedulerProto.schedulePeriodic = function(state, period, action) { if (typeof root.setInterval === 'undefined') { throw new NotSupportedError(); } period = normalizeTime(period); var s = state, id = root.setInterval(function () { s = action(s); }, period); return disposableCreate(function () { root.clearInterval(id); }); }; }(Scheduler.prototype)); (function (schedulerProto) { /** * Returns a scheduler that wraps the original scheduler, adding exception handling for scheduled actions. * @param {Function} handler Handler that's run if an exception is caught. The exception will be rethrown if the handler returns false. * @returns {Scheduler} Wrapper around the original scheduler, enforcing exception handling. */ schedulerProto.catchError = schedulerProto['catch'] = function (handler) { return new CatchScheduler(this, handler); }; }(Scheduler.prototype)); var SchedulePeriodicRecursive = Rx.internals.SchedulePeriodicRecursive = (function () { function createTick(self) { return function tick(command, recurse) { recurse(0, self._period); var state = tryCatch(self._action)(self._state); if (state === errorObj) { self._cancel.dispose(); thrower(state.e); } self._state = state; }; } function SchedulePeriodicRecursive(scheduler, state, period, action) { this._scheduler = scheduler; this._state = state; this._period = period; this._action = action; } SchedulePeriodicRecursive.prototype.start = function () { var d = new SingleAssignmentDisposable(); this._cancel = d; d.setDisposable(this._scheduler.scheduleRecursiveFuture(0, this._period, createTick(this))); return d; }; return SchedulePeriodicRecursive; }()); /** Gets a scheduler that schedules work immediately on the current thread. */ var ImmediateScheduler = (function (__super__) { inherits(ImmediateScheduler, __super__); function ImmediateScheduler() { __super__.call(this); } ImmediateScheduler.prototype.schedule = function (state, action) { return disposableFixup(action(this, state)); }; return ImmediateScheduler; }(Scheduler)); var immediateScheduler = Scheduler.immediate = new ImmediateScheduler(); /** * Gets a scheduler that schedules work as soon as possible on the current thread. */ var CurrentThreadScheduler = (function (__super__) { var queue; function runTrampoline () { while (queue.length > 0) { var item = queue.dequeue(); !item.isCancelled() && item.invoke(); } } inherits(CurrentThreadScheduler, __super__); function CurrentThreadScheduler() { __super__.call(this); } CurrentThreadScheduler.prototype.schedule = function (state, action) { var si = new ScheduledItem(this, state, action, this.now()); if (!queue) { queue = new PriorityQueue(4); queue.enqueue(si); var result = tryCatch(runTrampoline)(); queue = null; if (result === errorObj) { thrower(result.e); } } else { queue.enqueue(si); } return si.disposable; }; CurrentThreadScheduler.prototype.scheduleRequired = function () { return !queue; }; return CurrentThreadScheduler; }(Scheduler)); var currentThreadScheduler = Scheduler.currentThread = new CurrentThreadScheduler(); var scheduleMethod, clearMethod; var localTimer = (function () { var localSetTimeout, localClearTimeout = noop; if (!!root.setTimeout) { localSetTimeout = root.setTimeout; localClearTimeout = root.clearTimeout; } else if (!!root.WScript) { localSetTimeout = function (fn, time) { root.WScript.Sleep(time); fn(); }; } else { throw new NotSupportedError(); } return { setTimeout: localSetTimeout, clearTimeout: localClearTimeout }; }()); var localSetTimeout = localTimer.setTimeout, localClearTimeout = localTimer.clearTimeout; (function () { var nextHandle = 1, tasksByHandle = {}, currentlyRunning = false; clearMethod = function (handle) { delete tasksByHandle[handle]; }; function runTask(handle) { if (currentlyRunning) { localSetTimeout(function () { runTask(handle); }, 0); } else { var task = tasksByHandle[handle]; if (task) { currentlyRunning = true; var result = tryCatch(task)(); clearMethod(handle); currentlyRunning = false; if (result === errorObj) { thrower(result.e); } } } } var reNative = new RegExp('^' + String(toString) .replace(/[.*+?^${}()|[\]\\]/g, '\\$&') .replace(/toString| for [^\]]+/g, '.*?') + '$' ); var setImmediate = typeof (setImmediate = freeGlobal && moduleExports && freeGlobal.setImmediate) == 'function' && !reNative.test(setImmediate) && setImmediate; function postMessageSupported () { // Ensure not in a worker if (!root.postMessage || root.importScripts) { return false; } var isAsync = false, oldHandler = root.onmessage; // Test for async root.onmessage = function () { isAsync = true; }; root.postMessage('', '*'); root.onmessage = oldHandler; return isAsync; } // Use in order, setImmediate, nextTick, postMessage, MessageChannel, script readystatechanged, setTimeout if (isFunction(setImmediate)) { scheduleMethod = function (action) { var id = nextHandle++; tasksByHandle[id] = action; setImmediate(function () { runTask(id); }); return id; }; } else if (typeof process !== 'undefined' && {}.toString.call(process) === '[object process]') { scheduleMethod = function (action) { var id = nextHandle++; tasksByHandle[id] = action; process.nextTick(function () { runTask(id); }); return id; }; } else if (postMessageSupported()) { var MSG_PREFIX = 'ms.rx.schedule' + Math.random(); var onGlobalPostMessage = function (event) { // Only if we're a match to avoid any other global events if (typeof event.data === 'string' && event.data.substring(0, MSG_PREFIX.length) === MSG_PREFIX) { runTask(event.data.substring(MSG_PREFIX.length)); } }; root.addEventListener('message', onGlobalPostMessage, false); scheduleMethod = function (action) { var id = nextHandle++; tasksByHandle[id] = action; root.postMessage(MSG_PREFIX + id, '*'); return id; }; } else if (!!root.MessageChannel) { var channel = new root.MessageChannel(); channel.port1.onmessage = function (e) { runTask(e.data); }; scheduleMethod = function (action) { var id = nextHandle++; tasksByHandle[id] = action; channel.port2.postMessage(id); return id; }; } else if ('document' in root && 'onreadystatechange' in root.document.createElement('script')) { scheduleMethod = function (action) { var scriptElement = root.document.createElement('script'); var id = nextHandle++; tasksByHandle[id] = action; scriptElement.onreadystatechange = function () { runTask(id); scriptElement.onreadystatechange = null; scriptElement.parentNode.removeChild(scriptElement); scriptElement = null; }; root.document.documentElement.appendChild(scriptElement); return id; }; } else { scheduleMethod = function (action) { var id = nextHandle++; tasksByHandle[id] = action; localSetTimeout(function () { runTask(id); }, 0); return id; }; } }()); /** * Gets a scheduler that schedules work via a timed callback based upon platform. */ var DefaultScheduler = (function (__super__) { inherits(DefaultScheduler, __super__); function DefaultScheduler() { __super__.call(this); } function scheduleAction(disposable, action, scheduler, state) { return function schedule() { disposable.setDisposable(Disposable._fixup(action(scheduler, state))); }; } function ClearDisposable(id) { this._id = id; this.isDisposed = false; } ClearDisposable.prototype.dispose = function () { if (!this.isDisposed) { this.isDisposed = true; clearMethod(this._id); } }; function LocalClearDisposable(id) { this._id = id; this.isDisposed = false; } LocalClearDisposable.prototype.dispose = function () { if (!this.isDisposed) { this.isDisposed = true; localClearTimeout(this._id); } }; DefaultScheduler.prototype.schedule = function (state, action) { var disposable = new SingleAssignmentDisposable(), id = scheduleMethod(scheduleAction(disposable, action, this, state)); return new BinaryDisposable(disposable, new ClearDisposable(id)); }; DefaultScheduler.prototype._scheduleFuture = function (state, dueTime, action) { if (dueTime === 0) { return this.schedule(state, action); } var disposable = new SingleAssignmentDisposable(), id = localSetTimeout(scheduleAction(disposable, action, this, state), dueTime); return new BinaryDisposable(disposable, new LocalClearDisposable(id)); }; function scheduleLongRunning(state, action, disposable) { return function () { action(state, disposable); }; } DefaultScheduler.prototype.scheduleLongRunning = function (state, action) { var disposable = disposableCreate(noop); scheduleMethod(scheduleLongRunning(state, action, disposable)); return disposable; }; return DefaultScheduler; }(Scheduler)); var defaultScheduler = Scheduler['default'] = Scheduler.async = new DefaultScheduler(); var CatchScheduler = (function (__super__) { inherits(CatchScheduler, __super__); function CatchScheduler(scheduler, handler) { this._scheduler = scheduler; this._handler = handler; this._recursiveOriginal = null; this._recursiveWrapper = null; __super__.call(this); } CatchScheduler.prototype.schedule = function (state, action) { return this._scheduler.schedule(state, this._wrap(action)); }; CatchScheduler.prototype._scheduleFuture = function (state, dueTime, action) { return this._scheduler.schedule(state, dueTime, this._wrap(action)); }; CatchScheduler.prototype.now = function () { return this._scheduler.now(); }; CatchScheduler.prototype._clone = function (scheduler) { return new CatchScheduler(scheduler, this._handler); }; CatchScheduler.prototype._wrap = function (action) { var parent = this; return function (self, state) { var res = tryCatch(action)(parent._getRecursiveWrapper(self), state); if (res === errorObj) { if (!parent._handler(res.e)) { thrower(res.e); } return disposableEmpty; } return disposableFixup(res); }; }; CatchScheduler.prototype._getRecursiveWrapper = function (scheduler) { if (this._recursiveOriginal !== scheduler) { this._recursiveOriginal = scheduler; var wrapper = this._clone(scheduler); wrapper._recursiveOriginal = scheduler; wrapper._recursiveWrapper = wrapper; this._recursiveWrapper = wrapper; } return this._recursiveWrapper; }; CatchScheduler.prototype.schedulePeriodic = function (state, period, action) { var self = this, failed = false, d = new SingleAssignmentDisposable(); d.setDisposable(this._scheduler.schedulePeriodic(state, period, function (state1) { if (failed) { return null; } var res = tryCatch(action)(state1); if (res === errorObj) { failed = true; if (!self._handler(res.e)) { thrower(res.e); } d.dispose(); return null; } return res; })); return d; }; return CatchScheduler; }(Scheduler)); function IndexedItem(id, value) { this.id = id; this.value = value; } IndexedItem.prototype.compareTo = function (other) { var c = this.value.compareTo(other.value); c === 0 && (c = this.id - other.id); return c; }; var PriorityQueue = Rx.internals.PriorityQueue = function (capacity) { this.items = new Array(capacity); this.length = 0; }; var priorityProto = PriorityQueue.prototype; priorityProto.isHigherPriority = function (left, right) { return this.items[left].compareTo(this.items[right]) < 0; }; priorityProto.percolate = function (index) { if (index >= this.length || index < 0) { return; } var parent = index - 1 >> 1; if (parent < 0 || parent === index) { return; } if (this.isHigherPriority(index, parent)) { var temp = this.items[index]; this.items[index] = this.items[parent]; this.items[parent] = temp; this.percolate(parent); } }; priorityProto.heapify = function (index) { +index || (index = 0); if (index >= this.length || index < 0) { return; } var left = 2 * index + 1, right = 2 * index + 2, first = index; if (left < this.length && this.isHigherPriority(left, first)) { first = left; } if (right < this.length && this.isHigherPriority(right, first)) { first = right; } if (first !== index) { var temp = this.items[index]; this.items[index] = this.items[first]; this.items[first] = temp; this.heapify(first); } }; priorityProto.peek = function () { return this.items[0].value; }; priorityProto.removeAt = function (index) { this.items[index] = this.items[--this.length]; this.items[this.length] = undefined; this.heapify(); }; priorityProto.dequeue = function () { var result = this.peek(); this.removeAt(0); return result; }; priorityProto.enqueue = function (item) { var index = this.length++; this.items[index] = new IndexedItem(PriorityQueue.count++, item); this.percolate(index); }; priorityProto.remove = function (item) { for (var i = 0; i < this.length; i++) { if (this.items[i].value === item) { this.removeAt(i); return true; } } return false; }; PriorityQueue.count = 0; /** * Represents a notification to an observer. */ var Notification = Rx.Notification = (function () { function Notification() { } Notification.prototype._accept = function (onNext, onError, onCompleted) { throw new NotImplementedError(); }; Notification.prototype._acceptObserver = function (onNext, onError, onCompleted) { throw new NotImplementedError(); }; /** * Invokes the delegate corresponding to the notification or the observer's method corresponding to the notification and returns the produced result. * @param {Function | Observer} observerOrOnNext Function to invoke for an OnNext notification or Observer to invoke the notification on.. * @param {Function} onError Function to invoke for an OnError notification. * @param {Function} onCompleted Function to invoke for an OnCompleted notification. * @returns {Any} Result produced by the observation. */ Notification.prototype.accept = function (observerOrOnNext, onError, onCompleted) { return observerOrOnNext && typeof observerOrOnNext === 'object' ? this._acceptObserver(observerOrOnNext) : this._accept(observerOrOnNext, onError, onCompleted); }; /** * Returns an observable sequence with a single notification. * * @memberOf Notifications * @param {Scheduler} [scheduler] Scheduler to send out the notification calls on. * @returns {Observable} The observable sequence that surfaces the behavior of the notification upon subscription. */ Notification.prototype.toObservable = function (scheduler) { var self = this; isScheduler(scheduler) || (scheduler = immediateScheduler); return new AnonymousObservable(function (o) { return scheduler.schedule(self, function (_, notification) { notification._acceptObserver(o); notification.kind === 'N' && o.onCompleted(); }); }); }; return Notification; })(); var OnNextNotification = (function (__super__) { inherits(OnNextNotification, __super__); function OnNextNotification(value) { this.value = value; this.kind = 'N'; } OnNextNotification.prototype._accept = function (onNext) { return onNext(this.value); }; OnNextNotification.prototype._acceptObserver = function (o) { return o.onNext(this.value); }; OnNextNotification.prototype.toString = function () { return 'OnNext(' + this.value + ')'; }; return OnNextNotification; }(Notification)); var OnErrorNotification = (function (__super__) { inherits(OnErrorNotification, __super__); function OnErrorNotification(error) { this.error = error; this.kind = 'E'; } OnErrorNotification.prototype._accept = function (onNext, onError) { return onError(this.error); }; OnErrorNotification.prototype._acceptObserver = function (o) { return o.onError(this.error); }; OnErrorNotification.prototype.toString = function () { return 'OnError(' + this.error + ')'; }; return OnErrorNotification; }(Notification)); var OnCompletedNotification = (function (__super__) { inherits(OnCompletedNotification, __super__); function OnCompletedNotification() { this.kind = 'C'; } OnCompletedNotification.prototype._accept = function (onNext, onError, onCompleted) { return onCompleted(); }; OnCompletedNotification.prototype._acceptObserver = function (o) { return o.onCompleted(); }; OnCompletedNotification.prototype.toString = function () { return 'OnCompleted()'; }; return OnCompletedNotification; }(Notification)); /** * Creates an object that represents an OnNext notification to an observer. * @param {Any} value The value contained in the notification. * @returns {Notification} The OnNext notification containing the value. */ var notificationCreateOnNext = Notification.createOnNext = function (value) { return new OnNextNotification(value); }; /** * Creates an object that represents an OnError notification to an observer. * @param {Any} error The exception contained in the notification. * @returns {Notification} The OnError notification containing the exception. */ var notificationCreateOnError = Notification.createOnError = function (error) { return new OnErrorNotification(error); }; /** * Creates an object that represents an OnCompleted notification to an observer. * @returns {Notification} The OnCompleted notification. */ var notificationCreateOnCompleted = Notification.createOnCompleted = function () { return new OnCompletedNotification(); }; /** * Supports push-style iteration over an observable sequence. */ var Observer = Rx.Observer = function () { }; /** * Creates a notification callback from an observer. * @returns The action that forwards its input notification to the underlying observer. */ Observer.prototype.toNotifier = function () { var observer = this; return function (n) { return n.accept(observer); }; }; /** * Hides the identity of an observer. * @returns An observer that hides the identity of the specified observer. */ Observer.prototype.asObserver = function () { var self = this; return new AnonymousObserver( function (x) { self.onNext(x); }, function (err) { self.onError(err); }, function () { self.onCompleted(); }); }; /** * Checks access to the observer for grammar violations. This includes checking for multiple OnError or OnCompleted calls, as well as reentrancy in any of the observer methods. * If a violation is detected, an Error is thrown from the offending observer method call. * @returns An observer that checks callbacks invocations against the observer grammar and, if the checks pass, forwards those to the specified observer. */ Observer.prototype.checked = function () { return new CheckedObserver(this); }; /** * Creates an observer from the specified OnNext, along with optional OnError, and OnCompleted actions. * @param {Function} [onNext] Observer's OnNext action implementation. * @param {Function} [onError] Observer's OnError action implementation. * @param {Function} [onCompleted] Observer's OnCompleted action implementation. * @returns {Observer} The observer object implemented using the given actions. */ var observerCreate = Observer.create = function (onNext, onError, onCompleted) { onNext || (onNext = noop); onError || (onError = defaultError); onCompleted || (onCompleted = noop); return new AnonymousObserver(onNext, onError, onCompleted); }; /** * Creates an observer from a notification callback. * @param {Function} handler Action that handles a notification. * @returns The observer object that invokes the specified handler using a notification corresponding to each message it receives. */ Observer.fromNotifier = function (handler, thisArg) { var cb = bindCallback(handler, thisArg, 1); return new AnonymousObserver(function (x) { return cb(notificationCreateOnNext(x)); }, function (e) { return cb(notificationCreateOnError(e)); }, function () { return cb(notificationCreateOnCompleted()); }); }; /** * Schedules the invocation of observer methods on the given scheduler. * @param {Scheduler} scheduler Scheduler to schedule observer messages on. * @returns {Observer} Observer whose messages are scheduled on the given scheduler. */ Observer.prototype.notifyOn = function (scheduler) { return new ObserveOnObserver(scheduler, this); }; Observer.prototype.makeSafe = function(disposable) { return new AnonymousSafeObserver(this._onNext, this._onError, this._onCompleted, disposable); }; /** * Abstract base class for implementations of the Observer class. * This base class enforces the grammar of observers where OnError and OnCompleted are terminal messages. */ var AbstractObserver = Rx.internals.AbstractObserver = (function (__super__) { inherits(AbstractObserver, __super__); /** * Creates a new observer in a non-stopped state. */ function AbstractObserver() { this.isStopped = false; } // Must be implemented by other observers AbstractObserver.prototype.next = notImplemented; AbstractObserver.prototype.error = notImplemented; AbstractObserver.prototype.completed = notImplemented; /** * Notifies the observer of a new element in the sequence. * @param {Any} value Next element in the sequence. */ AbstractObserver.prototype.onNext = function (value) { !this.isStopped && this.next(value); }; /** * Notifies the observer that an exception has occurred. * @param {Any} error The error that has occurred. */ AbstractObserver.prototype.onError = function (error) { if (!this.isStopped) { this.isStopped = true; this.error(error); } }; /** * Notifies the observer of the end of the sequence. */ AbstractObserver.prototype.onCompleted = function () { if (!this.isStopped) { this.isStopped = true; this.completed(); } }; /** * Disposes the observer, causing it to transition to the stopped state. */ AbstractObserver.prototype.dispose = function () { this.isStopped = true; }; AbstractObserver.prototype.fail = function (e) { if (!this.isStopped) { this.isStopped = true; this.error(e); return true; } return false; }; return AbstractObserver; }(Observer)); /** * Class to create an Observer instance from delegate-based implementations of the on* methods. */ var AnonymousObserver = Rx.AnonymousObserver = (function (__super__) { inherits(AnonymousObserver, __super__); /** * Creates an observer from the specified OnNext, OnError, and OnCompleted actions. * @param {Any} onNext Observer's OnNext action implementation. * @param {Any} onError Observer's OnError action implementation. * @param {Any} onCompleted Observer's OnCompleted action implementation. */ function AnonymousObserver(onNext, onError, onCompleted) { __super__.call(this); this._onNext = onNext; this._onError = onError; this._onCompleted = onCompleted; } /** * Calls the onNext action. * @param {Any} value Next element in the sequence. */ AnonymousObserver.prototype.next = function (value) { this._onNext(value); }; /** * Calls the onError action. * @param {Any} error The error that has occurred. */ AnonymousObserver.prototype.error = function (error) { this._onError(error); }; /** * Calls the onCompleted action. */ AnonymousObserver.prototype.completed = function () { this._onCompleted(); }; return AnonymousObserver; }(AbstractObserver)); var CheckedObserver = (function (__super__) { inherits(CheckedObserver, __super__); function CheckedObserver(observer) { __super__.call(this); this._observer = observer; this._state = 0; // 0 - idle, 1 - busy, 2 - done } var CheckedObserverPrototype = CheckedObserver.prototype; CheckedObserverPrototype.onNext = function (value) { this.checkAccess(); var res = tryCatch(this._observer.onNext).call(this._observer, value); this._state = 0; res === errorObj && thrower(res.e); }; CheckedObserverPrototype.onError = function (err) { this.checkAccess(); var res = tryCatch(this._observer.onError).call(this._observer, err); this._state = 2; res === errorObj && thrower(res.e); }; CheckedObserverPrototype.onCompleted = function () { this.checkAccess(); var res = tryCatch(this._observer.onCompleted).call(this._observer); this._state = 2; res === errorObj && thrower(res.e); }; CheckedObserverPrototype.checkAccess = function () { if (this._state === 1) { throw new Error('Re-entrancy detected'); } if (this._state === 2) { throw new Error('Observer completed'); } if (this._state === 0) { this._state = 1; } }; return CheckedObserver; }(Observer)); var ScheduledObserver = Rx.internals.ScheduledObserver = (function (__super__) { inherits(ScheduledObserver, __super__); function ScheduledObserver(scheduler, observer) { __super__.call(this); this.scheduler = scheduler; this.observer = observer; this.isAcquired = false; this.hasFaulted = false; this.queue = []; this.disposable = new SerialDisposable(); } function enqueueNext(observer, x) { return function () { observer.onNext(x); }; } function enqueueError(observer, e) { return function () { observer.onError(e); }; } function enqueueCompleted(observer) { return function () { observer.onCompleted(); }; } ScheduledObserver.prototype.next = function (x) { this.queue.push(enqueueNext(this.observer, x)); }; ScheduledObserver.prototype.error = function (e) { this.queue.push(enqueueError(this.observer, e)); }; ScheduledObserver.prototype.completed = function () { this.queue.push(enqueueCompleted(this.observer)); }; function scheduleMethod(state, recurse) { var work; if (state.queue.length > 0) { work = state.queue.shift(); } else { state.isAcquired = false; return; } var res = tryCatch(work)(); if (res === errorObj) { state.queue = []; state.hasFaulted = true; return thrower(res.e); } recurse(state); } ScheduledObserver.prototype.ensureActive = function () { var isOwner = false; if (!this.hasFaulted && this.queue.length > 0) { isOwner = !this.isAcquired; this.isAcquired = true; } isOwner && this.disposable.setDisposable(this.scheduler.scheduleRecursive(this, scheduleMethod)); }; ScheduledObserver.prototype.dispose = function () { __super__.prototype.dispose.call(this); this.disposable.dispose(); }; return ScheduledObserver; }(AbstractObserver)); var ObserveOnObserver = (function (__super__) { inherits(ObserveOnObserver, __super__); function ObserveOnObserver(scheduler, observer, cancel) { __super__.call(this, scheduler, observer); this._cancel = cancel; } ObserveOnObserver.prototype.next = function (value) { __super__.prototype.next.call(this, value); this.ensureActive(); }; ObserveOnObserver.prototype.error = function (e) { __super__.prototype.error.call(this, e); this.ensureActive(); }; ObserveOnObserver.prototype.completed = function () { __super__.prototype.completed.call(this); this.ensureActive(); }; ObserveOnObserver.prototype.dispose = function () { __super__.prototype.dispose.call(this); this._cancel && this._cancel.dispose(); this._cancel = null; }; return ObserveOnObserver; })(ScheduledObserver); var observableProto; /** * Represents a push-style collection. */ var Observable = Rx.Observable = (function () { function makeSubscribe(self, subscribe) { return function (o) { var oldOnError = o.onError; o.onError = function (e) { makeStackTraceLong(e, self); oldOnError.call(o, e); }; return subscribe.call(self, o); }; } function Observable() { if (Rx.config.longStackSupport && hasStacks) { var oldSubscribe = this._subscribe; var e = tryCatch(thrower)(new Error()).e; this.stack = e.stack.substring(e.stack.indexOf('\n') + 1); this._subscribe = makeSubscribe(this, oldSubscribe); } } observableProto = Observable.prototype; /** * Determines whether the given object is an Observable * @param {Any} An object to determine whether it is an Observable * @returns {Boolean} true if an Observable, else false. */ Observable.isObservable = function (o) { return o && isFunction(o.subscribe); }; /** * Subscribes an o to the observable sequence. * @param {Mixed} [oOrOnNext] The object that is to receive notifications or an action to invoke for each element in the observable sequence. * @param {Function} [onError] Action to invoke upon exceptional termination of the observable sequence. * @param {Function} [onCompleted] Action to invoke upon graceful termination of the observable sequence. * @returns {Diposable} A disposable handling the subscriptions and unsubscriptions. */ observableProto.subscribe = observableProto.forEach = function (oOrOnNext, onError, onCompleted) { return this._subscribe(typeof oOrOnNext === 'object' ? oOrOnNext : observerCreate(oOrOnNext, onError, onCompleted)); }; /** * Subscribes to the next value in the sequence with an optional "this" argument. * @param {Function} onNext The function to invoke on each element in the observable sequence. * @param {Any} [thisArg] Object to use as this when executing callback. * @returns {Disposable} A disposable handling the subscriptions and unsubscriptions. */ observableProto.subscribeOnNext = function (onNext, thisArg) { return this._subscribe(observerCreate(typeof thisArg !== 'undefined' ? function(x) { onNext.call(thisArg, x); } : onNext)); }; /** * Subscribes to an exceptional condition in the sequence with an optional "this" argument. * @param {Function} onError The function to invoke upon exceptional termination of the observable sequence. * @param {Any} [thisArg] Object to use as this when executing callback. * @returns {Disposable} A disposable handling the subscriptions and unsubscriptions. */ observableProto.subscribeOnError = function (onError, thisArg) { return this._subscribe(observerCreate(null, typeof thisArg !== 'undefined' ? function(e) { onError.call(thisArg, e); } : onError)); }; /** * Subscribes to the next value in the sequence with an optional "this" argument. * @param {Function} onCompleted The function to invoke upon graceful termination of the observable sequence. * @param {Any} [thisArg] Object to use as this when executing callback. * @returns {Disposable} A disposable handling the subscriptions and unsubscriptions. */ observableProto.subscribeOnCompleted = function (onCompleted, thisArg) { return this._subscribe(observerCreate(null, null, typeof thisArg !== 'undefined' ? function() { onCompleted.call(thisArg); } : onCompleted)); }; return Observable; })(); var ObservableBase = Rx.ObservableBase = (function (__super__) { inherits(ObservableBase, __super__); function fixSubscriber(subscriber) { return subscriber && isFunction(subscriber.dispose) ? subscriber : isFunction(subscriber) ? disposableCreate(subscriber) : disposableEmpty; } function setDisposable(s, state) { var ado = state[0], self = state[1]; var sub = tryCatch(self.subscribeCore).call(self, ado); if (sub === errorObj && !ado.fail(errorObj.e)) { thrower(errorObj.e); } ado.setDisposable(fixSubscriber(sub)); } function ObservableBase() { __super__.call(this); } ObservableBase.prototype._subscribe = function (o) { var ado = new AutoDetachObserver(o), state = [ado, this]; if (currentThreadScheduler.scheduleRequired()) { currentThreadScheduler.schedule(state, setDisposable); } else { setDisposable(null, state); } return ado; }; ObservableBase.prototype.subscribeCore = notImplemented; return ObservableBase; }(Observable)); var FlatMapObservable = Rx.FlatMapObservable = (function(__super__) { inherits(FlatMapObservable, __super__); function FlatMapObservable(source, selector, resultSelector, thisArg) { this.resultSelector = isFunction(resultSelector) ? resultSelector : null; this.selector = bindCallback(isFunction(selector) ? selector : function() { return selector; }, thisArg, 3); this.source = source; __super__.call(this); } FlatMapObservable.prototype.subscribeCore = function(o) { return this.source.subscribe(new InnerObserver(o, this.selector, this.resultSelector, this)); }; inherits(InnerObserver, AbstractObserver); function InnerObserver(observer, selector, resultSelector, source) { this.i = 0; this.selector = selector; this.resultSelector = resultSelector; this.source = source; this.o = observer; AbstractObserver.call(this); } InnerObserver.prototype._wrapResult = function(result, x, i) { return this.resultSelector ? result.map(function(y, i2) { return this.resultSelector(x, y, i, i2); }, this) : result; }; InnerObserver.prototype.next = function(x) { var i = this.i++; var result = tryCatch(this.selector)(x, i, this.source); if (result === errorObj) { return this.o.onError(result.e); } isPromise(result) && (result = observableFromPromise(result)); (isArrayLike(result) || isIterable(result)) && (result = Observable.from(result)); this.o.onNext(this._wrapResult(result, x, i)); }; InnerObserver.prototype.error = function(e) { this.o.onError(e); }; InnerObserver.prototype.completed = function() { this.o.onCompleted(); }; return FlatMapObservable; }(ObservableBase)); var Enumerable = Rx.internals.Enumerable = function () { }; function IsDisposedDisposable(state) { this._s = state; this.isDisposed = false; } IsDisposedDisposable.prototype.dispose = function () { if (!this.isDisposed) { this.isDisposed = true; this._s.isDisposed = true; } }; var ConcatEnumerableObservable = (function(__super__) { inherits(ConcatEnumerableObservable, __super__); function ConcatEnumerableObservable(sources) { this.sources = sources; __super__.call(this); } function scheduleMethod(state, recurse) { if (state.isDisposed) { return; } var currentItem = tryCatch(state.e.next).call(state.e); if (currentItem === errorObj) { return state.o.onError(currentItem.e); } if (currentItem.done) { return state.o.onCompleted(); } // Check if promise var currentValue = currentItem.value; isPromise(currentValue) && (currentValue = observableFromPromise(currentValue)); var d = new SingleAssignmentDisposable(); state.subscription.setDisposable(d); d.setDisposable(currentValue.subscribe(new InnerObserver(state, recurse))); } ConcatEnumerableObservable.prototype.subscribeCore = function (o) { var subscription = new SerialDisposable(); var state = { isDisposed: false, o: o, subscription: subscription, e: this.sources[$iterator$]() }; var cancelable = currentThreadScheduler.scheduleRecursive(state, scheduleMethod); return new NAryDisposable([subscription, cancelable, new IsDisposedDisposable(state)]); }; function InnerObserver(state, recurse) { this._state = state; this._recurse = recurse; AbstractObserver.call(this); } inherits(InnerObserver, AbstractObserver); InnerObserver.prototype.next = function (x) { this._state.o.onNext(x); }; InnerObserver.prototype.error = function (e) { this._state.o.onError(e); }; InnerObserver.prototype.completed = function () { this._recurse(this._state); }; return ConcatEnumerableObservable; }(ObservableBase)); Enumerable.prototype.concat = function () { return new ConcatEnumerableObservable(this); }; var CatchErrorObservable = (function(__super__) { function CatchErrorObservable(sources) { this.sources = sources; __super__.call(this); } inherits(CatchErrorObservable, __super__); function scheduleMethod(state, recurse) { if (state.isDisposed) { return; } var currentItem = tryCatch(state.e.next).call(state.e); if (currentItem === errorObj) { return state.o.onError(currentItem.e); } if (currentItem.done) { return state.lastError !== null ? state.o.onError(state.lastError) : state.o.onCompleted(); } var currentValue = currentItem.value; isPromise(currentValue) && (currentValue = observableFromPromise(currentValue)); var d = new SingleAssignmentDisposable(); state.subscription.setDisposable(d); d.setDisposable(currentValue.subscribe(new InnerObserver(state, recurse))); } CatchErrorObservable.prototype.subscribeCore = function (o) { var subscription = new SerialDisposable(); var state = { isDisposed: false, e: this.sources[$iterator$](), subscription: subscription, lastError: null, o: o }; var cancelable = currentThreadScheduler.scheduleRecursive(state, scheduleMethod); return new NAryDisposable([subscription, cancelable, new IsDisposedDisposable(state)]); }; function InnerObserver(state, recurse) { this._state = state; this._recurse = recurse; AbstractObserver.call(this); } inherits(InnerObserver, AbstractObserver); InnerObserver.prototype.next = function (x) { this._state.o.onNext(x); }; InnerObserver.prototype.error = function (e) { this._state.lastError = e; this._recurse(this._state); }; InnerObserver.prototype.completed = function () { this._state.o.onCompleted(); }; return CatchErrorObservable; }(ObservableBase)); Enumerable.prototype.catchError = function () { return new CatchErrorObservable(this); }; var RepeatEnumerable = (function (__super__) { inherits(RepeatEnumerable, __super__); function RepeatEnumerable(v, c) { this.v = v; this.c = c == null ? -1 : c; } RepeatEnumerable.prototype[$iterator$] = function () { return new RepeatEnumerator(this); }; function RepeatEnumerator(p) { this.v = p.v; this.l = p.c; } RepeatEnumerator.prototype.next = function () { if (this.l === 0) { return doneEnumerator; } if (this.l > 0) { this.l--; } return { done: false, value: this.v }; }; return RepeatEnumerable; }(Enumerable)); var enumerableRepeat = Enumerable.repeat = function (value, repeatCount) { return new RepeatEnumerable(value, repeatCount); }; var OfEnumerable = (function(__super__) { inherits(OfEnumerable, __super__); function OfEnumerable(s, fn, thisArg) { this.s = s; this.fn = fn ? bindCallback(fn, thisArg, 3) : null; } OfEnumerable.prototype[$iterator$] = function () { return new OfEnumerator(this); }; function OfEnumerator(p) { this.i = -1; this.s = p.s; this.l = this.s.length; this.fn = p.fn; } OfEnumerator.prototype.next = function () { return ++this.i < this.l ? { done: false, value: !this.fn ? this.s[this.i] : this.fn(this.s[this.i], this.i, this.s) } : doneEnumerator; }; return OfEnumerable; }(Enumerable)); var enumerableOf = Enumerable.of = function (source, selector, thisArg) { return new OfEnumerable(source, selector, thisArg); }; var ObserveOnObservable = (function (__super__) { inherits(ObserveOnObservable, __super__); function ObserveOnObservable(source, s) { this.source = source; this._s = s; __super__.call(this); } ObserveOnObservable.prototype.subscribeCore = function (o) { return this.source.subscribe(new ObserveOnObserver(this._s, o)); }; return ObserveOnObservable; }(ObservableBase)); /** * Wraps the source sequence in order to run its observer callbacks on the specified scheduler. * * This only invokes observer callbacks on a scheduler. In case the subscription and/or unsubscription actions have side-effects * that require to be run on a scheduler, use subscribeOn. * * @param {Scheduler} scheduler Scheduler to notify observers on. * @returns {Observable} The source sequence whose observations happen on the specified scheduler. */ observableProto.observeOn = function (scheduler) { return new ObserveOnObservable(this, scheduler); }; var SubscribeOnObservable = (function (__super__) { inherits(SubscribeOnObservable, __super__); function SubscribeOnObservable(source, s) { this.source = source; this._s = s; __super__.call(this); } function scheduleMethod(scheduler, state) { var source = state[0], d = state[1], o = state[2]; d.setDisposable(new ScheduledDisposable(scheduler, source.subscribe(o))); } SubscribeOnObservable.prototype.subscribeCore = function (o) { var m = new SingleAssignmentDisposable(), d = new SerialDisposable(); d.setDisposable(m); m.setDisposable(this._s.schedule([this.source, d, o], scheduleMethod)); return d; }; return SubscribeOnObservable; }(ObservableBase)); /** * Wraps the source sequence in order to run its subscription and unsubscription logic on the specified scheduler. This operation is not commonly used; * see the remarks section for more information on the distinction between subscribeOn and observeOn. * This only performs the side-effects of subscription and unsubscription on the specified scheduler. In order to invoke observer * callbacks on a scheduler, use observeOn. * @param {Scheduler} scheduler Scheduler to perform subscription and unsubscription actions on. * @returns {Observable} The source sequence whose subscriptions and unsubscriptions happen on the specified scheduler. */ observableProto.subscribeOn = function (scheduler) { return new SubscribeOnObservable(this, scheduler); }; var FromPromiseObservable = (function(__super__) { inherits(FromPromiseObservable, __super__); function FromPromiseObservable(p, s) { this._p = p; this._s = s; __super__.call(this); } function scheduleNext(s, state) { var o = state[0], data = state[1]; o.onNext(data); o.onCompleted(); } function scheduleError(s, state) { var o = state[0], err = state[1]; o.onError(err); } FromPromiseObservable.prototype.subscribeCore = function(o) { var sad = new SingleAssignmentDisposable(), self = this, p = this._p; if (isFunction(p)) { p = tryCatch(p)(); if (p === errorObj) { o.onError(p.e); return sad; } } p .then(function (data) { sad.setDisposable(self._s.schedule([o, data], scheduleNext)); }, function (err) { sad.setDisposable(self._s.schedule([o, err], scheduleError)); }); return sad; }; return FromPromiseObservable; }(ObservableBase)); /** * Converts a Promise to an Observable sequence * @param {Promise} An ES6 Compliant promise. * @returns {Observable} An Observable sequence which wraps the existing promise success and failure. */ var observableFromPromise = Observable.fromPromise = function (promise, scheduler) { scheduler || (scheduler = defaultScheduler); return new FromPromiseObservable(promise, scheduler); }; /* * Converts an existing observable sequence to an ES6 Compatible Promise * @example * var promise = Rx.Observable.return(42).toPromise(RSVP.Promise); * * // With config * Rx.config.Promise = RSVP.Promise; * var promise = Rx.Observable.return(42).toPromise(); * @param {Function} [promiseCtor] The constructor of the promise. If not provided, it looks for it in Rx.config.Promise. * @returns {Promise} An ES6 compatible promise with the last value from the observable sequence. */ observableProto.toPromise = function (promiseCtor) { promiseCtor || (promiseCtor = Rx.config.Promise); if (!promiseCtor) { throw new NotSupportedError('Promise type not provided nor in Rx.config.Promise'); } var source = this; return new promiseCtor(function (resolve, reject) { // No cancellation can be done var value; source.subscribe(function (v) { value = v; }, reject, function () { resolve(value); }); }); }; var ToArrayObservable = (function(__super__) { inherits(ToArrayObservable, __super__); function ToArrayObservable(source) { this.source = source; __super__.call(this); } ToArrayObservable.prototype.subscribeCore = function(o) { return this.source.subscribe(new InnerObserver(o)); }; inherits(InnerObserver, AbstractObserver); function InnerObserver(o) { this.o = o; this.a = []; AbstractObserver.call(this); } InnerObserver.prototype.next = function (x) { this.a.push(x); }; InnerObserver.prototype.error = function (e) { this.o.onError(e); }; InnerObserver.prototype.completed = function () { this.o.onNext(this.a); this.o.onCompleted(); }; return ToArrayObservable; }(ObservableBase)); /** * Creates an array from an observable sequence. * @returns {Observable} An observable sequence containing a single element with a list containing all the elements of the source sequence. */ observableProto.toArray = function () { return new ToArrayObservable(this); }; /** * Creates an observable sequence from a specified subscribe method implementation. * @example * var res = Rx.Observable.create(function (observer) { return function () { } ); * var res = Rx.Observable.create(function (observer) { return Rx.Disposable.empty; } ); * var res = Rx.Observable.create(function (observer) { } ); * @param {Function} subscribe Implementation of the resulting observable sequence's subscribe method, returning a function that will be wrapped in a Disposable. * @returns {Observable} The observable sequence with the specified implementation for the Subscribe method. */ Observable.create = function (subscribe, parent) { return new AnonymousObservable(subscribe, parent); }; var Defer = (function(__super__) { inherits(Defer, __super__); function Defer(factory) { this._f = factory; __super__.call(this); } Defer.prototype.subscribeCore = function (o) { var result = tryCatch(this._f)(); if (result === errorObj) { return observableThrow(result.e).subscribe(o);} isPromise(result) && (result = observableFromPromise(result)); return result.subscribe(o); }; return Defer; }(ObservableBase)); /** * Returns an observable sequence that invokes the specified factory function whenever a new observer subscribes. * * @example * var res = Rx.Observable.defer(function () { return Rx.Observable.fromArray([1,2,3]); }); * @param {Function} observableFactory Observable factory function to invoke for each observer that subscribes to the resulting sequence or Promise. * @returns {Observable} An observable sequence whose observers trigger an invocation of the given observable factory function. */ var observableDefer = Observable.defer = function (observableFactory) { return new Defer(observableFactory); }; var EmptyObservable = (function(__super__) { inherits(EmptyObservable, __super__); function EmptyObservable(scheduler) { this.scheduler = scheduler; __super__.call(this); } EmptyObservable.prototype.subscribeCore = function (observer) { var sink = new EmptySink(observer, this.scheduler); return sink.run(); }; function EmptySink(observer, scheduler) { this.observer = observer; this.scheduler = scheduler; } function scheduleItem(s, state) { state.onCompleted(); return disposableEmpty; } EmptySink.prototype.run = function () { var state = this.observer; return this.scheduler === immediateScheduler ? scheduleItem(null, state) : this.scheduler.schedule(state, scheduleItem); }; return EmptyObservable; }(ObservableBase)); var EMPTY_OBSERVABLE = new EmptyObservable(immediateScheduler); /** * Returns an empty observable sequence, using the specified scheduler to send out the single OnCompleted message. * * @example * var res = Rx.Observable.empty(); * var res = Rx.Observable.empty(Rx.Scheduler.timeout); * @param {Scheduler} [scheduler] Scheduler to send the termination call on. * @returns {Observable} An observable sequence with no elements. */ var observableEmpty = Observable.empty = function (scheduler) { isScheduler(scheduler) || (scheduler = immediateScheduler); return scheduler === immediateScheduler ? EMPTY_OBSERVABLE : new EmptyObservable(scheduler); }; var FromObservable = (function(__super__) { inherits(FromObservable, __super__); function FromObservable(iterable, fn, scheduler) { this._iterable = iterable; this._fn = fn; this._scheduler = scheduler; __super__.call(this); } function createScheduleMethod(o, it, fn) { return function loopRecursive(i, recurse) { var next = tryCatch(it.next).call(it); if (next === errorObj) { return o.onError(next.e); } if (next.done) { return o.onCompleted(); } var result = next.value; if (isFunction(fn)) { result = tryCatch(fn)(result, i); if (result === errorObj) { return o.onError(result.e); } } o.onNext(result); recurse(i + 1); }; } FromObservable.prototype.subscribeCore = function (o) { var list = Object(this._iterable), it = getIterable(list); return this._scheduler.scheduleRecursive(0, createScheduleMethod(o, it, this._fn)); }; return FromObservable; }(ObservableBase)); var maxSafeInteger = Math.pow(2, 53) - 1; function StringIterable(s) { this._s = s; } StringIterable.prototype[$iterator$] = function () { return new StringIterator(this._s); }; function StringIterator(s) { this._s = s; this._l = s.length; this._i = 0; } StringIterator.prototype[$iterator$] = function () { return this; }; StringIterator.prototype.next = function () { return this._i < this._l ? { done: false, value: this._s.charAt(this._i++) } : doneEnumerator; }; function ArrayIterable(a) { this._a = a; } ArrayIterable.prototype[$iterator$] = function () { return new ArrayIterator(this._a); }; function ArrayIterator(a) { this._a = a; this._l = toLength(a); this._i = 0; } ArrayIterator.prototype[$iterator$] = function () { return this; }; ArrayIterator.prototype.next = function () { return this._i < this._l ? { done: false, value: this._a[this._i++] } : doneEnumerator; }; function numberIsFinite(value) { return typeof value === 'number' && root.isFinite(value); } function isNan(n) { return n !== n; } function getIterable(o) { var i = o[$iterator$], it; if (!i && typeof o === 'string') { it = new StringIterable(o); return it[$iterator$](); } if (!i && o.length !== undefined) { it = new ArrayIterable(o); return it[$iterator$](); } if (!i) { throw new TypeError('Object is not iterable'); } return o[$iterator$](); } function sign(value) { var number = +value; if (number === 0) { return number; } if (isNaN(number)) { return number; } return number < 0 ? -1 : 1; } function toLength(o) { var len = +o.length; if (isNaN(len)) { return 0; } if (len === 0 || !numberIsFinite(len)) { return len; } len = sign(len) * Math.floor(Math.abs(len)); if (len <= 0) { return 0; } if (len > maxSafeInteger) { return maxSafeInteger; } return len; } /** * This method creates a new Observable sequence from an array-like or iterable object. * @param {Any} arrayLike An array-like or iterable object to convert to an Observable sequence. * @param {Function} [mapFn] Map function to call on every element of the array. * @param {Any} [thisArg] The context to use calling the mapFn if provided. * @param {Scheduler} [scheduler] Optional scheduler to use for scheduling. If not provided, defaults to Scheduler.currentThread. */ var observableFrom = Observable.from = function (iterable, mapFn, thisArg, scheduler) { if (iterable == null) { throw new Error('iterable cannot be null.') } if (mapFn && !isFunction(mapFn)) { throw new Error('mapFn when provided must be a function'); } if (mapFn) { var mapper = bindCallback(mapFn, thisArg, 2); } isScheduler(scheduler) || (scheduler = currentThreadScheduler); return new FromObservable(iterable, mapper, scheduler); } var FromArrayObservable = (function(__super__) { inherits(FromArrayObservable, __super__); function FromArrayObservable(args, scheduler) { this._args = args; this._scheduler = scheduler; __super__.call(this); } function scheduleMethod(o, args) { var len = args.length; return function loopRecursive (i, recurse) { if (i < len) { o.onNext(args[i]); recurse(i + 1); } else { o.onCompleted(); } }; } FromArrayObservable.prototype.subscribeCore = function (o) { return this._scheduler.scheduleRecursive(0, scheduleMethod(o, this._args)); }; return FromArrayObservable; }(ObservableBase)); /** * Converts an array to an observable sequence, using an optional scheduler to enumerate the array. * @deprecated use Observable.from or Observable.of * @param {Scheduler} [scheduler] Scheduler to run the enumeration of the input sequence on. * @returns {Observable} The observable sequence whose elements are pulled from the given enumerable sequence. */ var observableFromArray = Observable.fromArray = function (array, scheduler) { isScheduler(scheduler) || (scheduler = currentThreadScheduler); return new FromArrayObservable(array, scheduler) }; var GenerateObservable = (function (__super__) { inherits(GenerateObservable, __super__); function GenerateObservable(state, cndFn, itrFn, resFn, s) { this._initialState = state; this._cndFn = cndFn; this._itrFn = itrFn; this._resFn = resFn; this._s = s; __super__.call(this); } function scheduleRecursive(state, recurse) { if (state.first) { state.first = false; } else { state.newState = tryCatch(state.self._itrFn)(state.newState); if (state.newState === errorObj) { return state.o.onError(state.newState.e); } } var hasResult = tryCatch(state.self._cndFn)(state.newState); if (hasResult === errorObj) { return state.o.onError(hasResult.e); } if (hasResult) { var result = tryCatch(state.self._resFn)(state.newState); if (result === errorObj) { return state.o.onError(result.e); } state.o.onNext(result); recurse(state); } else { state.o.onCompleted(); } } GenerateObservable.prototype.subscribeCore = function (o) { var state = { o: o, self: this, first: true, newState: this._initialState }; return this._s.scheduleRecursive(state, scheduleRecursive); }; return GenerateObservable; }(ObservableBase)); /** * Generates an observable sequence by running a state-driven loop producing the sequence's elements, using the specified scheduler to send out observer messages. * * @example * var res = Rx.Observable.generate(0, function (x) { return x < 10; }, function (x) { return x + 1; }, function (x) { return x; }); * var res = Rx.Observable.generate(0, function (x) { return x < 10; }, function (x) { return x + 1; }, function (x) { return x; }, Rx.Scheduler.timeout); * @param {Mixed} initialState Initial state. * @param {Function} condition Condition to terminate generation (upon returning false). * @param {Function} iterate Iteration step function. * @param {Function} resultSelector Selector function for results produced in the sequence. * @param {Scheduler} [scheduler] Scheduler on which to run the generator loop. If not provided, defaults to Scheduler.currentThread. * @returns {Observable} The generated sequence. */ Observable.generate = function (initialState, condition, iterate, resultSelector, scheduler) { isScheduler(scheduler) || (scheduler = currentThreadScheduler); return new GenerateObservable(initialState, condition, iterate, resultSelector, scheduler); }; var NeverObservable = (function(__super__) { inherits(NeverObservable, __super__); function NeverObservable() { __super__.call(this); } NeverObservable.prototype.subscribeCore = function (observer) { return disposableEmpty; }; return NeverObservable; }(ObservableBase)); var NEVER_OBSERVABLE = new NeverObservable(); /** * Returns a non-terminating observable sequence, which can be used to denote an infinite duration (e.g. when using reactive joins). * @returns {Observable} An observable sequence whose observers will never get called. */ var observableNever = Observable.never = function () { return NEVER_OBSERVABLE; }; function observableOf (scheduler, array) { isScheduler(scheduler) || (scheduler = currentThreadScheduler); return new FromArrayObservable(array, scheduler); } /** * This method creates a new Observable instance with a variable number of arguments, regardless of number or type of the arguments. * @returns {Observable} The observable sequence whose elements are pulled from the given arguments. */ Observable.of = function () { var len = arguments.length, args = new Array(len); for(var i = 0; i < len; i++) { args[i] = arguments[i]; } return new FromArrayObservable(args, currentThreadScheduler); }; /** * This method creates a new Observable instance with a variable number of arguments, regardless of number or type of the arguments. * @param {Scheduler} scheduler A scheduler to use for scheduling the arguments. * @returns {Observable} The observable sequence whose elements are pulled from the given arguments. */ Observable.ofWithScheduler = function (scheduler) { var len = arguments.length, args = new Array(len - 1); for(var i = 1; i < len; i++) { args[i - 1] = arguments[i]; } return new FromArrayObservable(args, scheduler); }; var PairsObservable = (function(__super__) { inherits(PairsObservable, __super__); function PairsObservable(o, scheduler) { this._o = o; this._keys = Object.keys(o); this._scheduler = scheduler; __super__.call(this); } function scheduleMethod(o, obj, keys) { return function loopRecursive(i, recurse) { if (i < keys.length) { var key = keys[i]; o.onNext([key, obj[key]]); recurse(i + 1); } else { o.onCompleted(); } }; } PairsObservable.prototype.subscribeCore = function (o) { return this._scheduler.scheduleRecursive(0, scheduleMethod(o, this._o, this._keys)); }; return PairsObservable; }(ObservableBase)); /** * Convert an object into an observable sequence of [key, value] pairs. * @param {Object} obj The object to inspect. * @param {Scheduler} [scheduler] Scheduler to run the enumeration of the input sequence on. * @returns {Observable} An observable sequence of [key, value] pairs from the object. */ Observable.pairs = function (obj, scheduler) { scheduler || (scheduler = currentThreadScheduler); return new PairsObservable(obj, scheduler); }; var RangeObservable = (function(__super__) { inherits(RangeObservable, __super__); function RangeObservable(start, count, scheduler) { this.start = start; this.rangeCount = count; this.scheduler = scheduler; __super__.call(this); } function loopRecursive(start, count, o) { return function loop (i, recurse) { if (i < count) { o.onNext(start + i); recurse(i + 1); } else { o.onCompleted(); } }; } RangeObservable.prototype.subscribeCore = function (o) { return this.scheduler.scheduleRecursive( 0, loopRecursive(this.start, this.rangeCount, o) ); }; return RangeObservable; }(ObservableBase)); /** * Generates an observable sequence of integral numbers within a specified range, using the specified scheduler to send out observer messages. * @param {Number} start The value of the first integer in the sequence. * @param {Number} count The number of sequential integers to generate. * @param {Scheduler} [scheduler] Scheduler to run the generator loop on. If not specified, defaults to Scheduler.currentThread. * @returns {Observable} An observable sequence that contains a range of sequential integral numbers. */ Observable.range = function (start, count, scheduler) { isScheduler(scheduler) || (scheduler = currentThreadScheduler); return new RangeObservable(start, count, scheduler); }; var RepeatObservable = (function(__super__) { inherits(RepeatObservable, __super__); function RepeatObservable(value, repeatCount, scheduler) { this.value = value; this.repeatCount = repeatCount == null ? -1 : repeatCount; this.scheduler = scheduler; __super__.call(this); } RepeatObservable.prototype.subscribeCore = function (observer) { var sink = new RepeatSink(observer, this); return sink.run(); }; return RepeatObservable; }(ObservableBase)); function RepeatSink(observer, parent) { this.observer = observer; this.parent = parent; } RepeatSink.prototype.run = function () { var observer = this.observer, value = this.parent.value; function loopRecursive(i, recurse) { if (i === -1 || i > 0) { observer.onNext(value); i > 0 && i--; } if (i === 0) { return observer.onCompleted(); } recurse(i); } return this.parent.scheduler.scheduleRecursive(this.parent.repeatCount, loopRecursive); }; /** * Generates an observable sequence that repeats the given element the specified number of times, using the specified scheduler to send out observer messages. * @param {Mixed} value Element to repeat. * @param {Number} repeatCount [Optiona] Number of times to repeat the element. If not specified, repeats indefinitely. * @param {Scheduler} scheduler Scheduler to run the producer loop on. If not specified, defaults to Scheduler.immediate. * @returns {Observable} An observable sequence that repeats the given element the specified number of times. */ Observable.repeat = function (value, repeatCount, scheduler) { isScheduler(scheduler) || (scheduler = currentThreadScheduler); return new RepeatObservable(value, repeatCount, scheduler); }; var JustObservable = (function(__super__) { inherits(JustObservable, __super__); function JustObservable(value, scheduler) { this._value = value; this._scheduler = scheduler; __super__.call(this); } JustObservable.prototype.subscribeCore = function (o) { var state = [this._value, o]; return this._scheduler === immediateScheduler ? scheduleItem(null, state) : this._scheduler.schedule(state, scheduleItem); }; function scheduleItem(s, state) { var value = state[0], observer = state[1]; observer.onNext(value); observer.onCompleted(); return disposableEmpty; } return JustObservable; }(ObservableBase)); /** * Returns an observable sequence that contains a single element, using the specified scheduler to send out observer messages. * There is an alias called 'just' or browsers 0) { this.parent.handleSubscribe(this.parent.q.shift()); } else { this.parent.activeCount--; this.parent.done && this.parent.activeCount === 0 && this.parent.o.onCompleted(); } }; return MergeObserver; }(AbstractObserver)); /** * Merges an observable sequence of observable sequences into an observable sequence, limiting the number of concurrent subscriptions to inner sequences. * Or merges two observable sequences into a single observable sequence. * @param {Mixed} [maxConcurrentOrOther] Maximum number of inner observable sequences being subscribed to concurrently or the second observable sequence. * @returns {Observable} The observable sequence that merges the elements of the inner sequences. */ observableProto.merge = function (maxConcurrentOrOther) { return typeof maxConcurrentOrOther !== 'number' ? observableMerge(this, maxConcurrentOrOther) : new MergeObservable(this, maxConcurrentOrOther); }; /** * Merges all the observable sequences into a single observable sequence. * The scheduler is optional and if not specified, the immediate scheduler is used. * @returns {Observable} The observable sequence that merges the elements of the observable sequences. */ var observableMerge = Observable.merge = function () { var scheduler, sources = [], i, len = arguments.length; if (!arguments[0]) { scheduler = immediateScheduler; for(i = 1; i < len; i++) { sources.push(arguments[i]); } } else if (isScheduler(arguments[0])) { scheduler = arguments[0]; for(i = 1; i < len; i++) { sources.push(arguments[i]); } } else { scheduler = immediateScheduler; for(i = 0; i < len; i++) { sources.push(arguments[i]); } } if (Array.isArray(sources[0])) { sources = sources[0]; } return observableOf(scheduler, sources).mergeAll(); }; var MergeAllObservable = (function (__super__) { inherits(MergeAllObservable, __super__); function MergeAllObservable(source) { this.source = source; __super__.call(this); } MergeAllObservable.prototype.subscribeCore = function (o) { var g = new CompositeDisposable(), m = new SingleAssignmentDisposable(); g.add(m); m.setDisposable(this.source.subscribe(new MergeAllObserver(o, g))); return g; }; return MergeAllObservable; }(ObservableBase)); var MergeAllObserver = (function (__super__) { function MergeAllObserver(o, g) { this.o = o; this.g = g; this.done = false; __super__.call(this); } inherits(MergeAllObserver, __super__); MergeAllObserver.prototype.next = function(innerSource) { var sad = new SingleAssignmentDisposable(); this.g.add(sad); isPromise(innerSource) && (innerSource = observableFromPromise(innerSource)); sad.setDisposable(innerSource.subscribe(new InnerObserver(this, sad))); }; MergeAllObserver.prototype.error = function (e) { this.o.onError(e); }; MergeAllObserver.prototype.completed = function () { this.done = true; this.g.length === 1 && this.o.onCompleted(); }; function InnerObserver(parent, sad) { this.parent = parent; this.sad = sad; __super__.call(this); } inherits(InnerObserver, __super__); InnerObserver.prototype.next = function (x) { this.parent.o.onNext(x); }; InnerObserver.prototype.error = function (e) { this.parent.o.onError(e); }; InnerObserver.prototype.completed = function () { this.parent.g.remove(this.sad); this.parent.done && this.parent.g.length === 1 && this.parent.o.onCompleted(); }; return MergeAllObserver; }(AbstractObserver)); /** * Merges an observable sequence of observable sequences into an observable sequence. * @returns {Observable} The observable sequence that merges the elements of the inner sequences. */ observableProto.mergeAll = function () { return new MergeAllObservable(this); }; var CompositeError = Rx.CompositeError = function(errors) { this.innerErrors = errors; this.message = 'This contains multiple errors. Check the innerErrors'; Error.call(this); }; CompositeError.prototype = Object.create(Error.prototype); CompositeError.prototype.name = 'CompositeError'; var MergeDelayErrorObservable = (function(__super__) { inherits(MergeDelayErrorObservable, __super__); function MergeDelayErrorObservable(source) { this.source = source; __super__.call(this); } MergeDelayErrorObservable.prototype.subscribeCore = function (o) { var group = new CompositeDisposable(), m = new SingleAssignmentDisposable(), state = { isStopped: false, errors: [], o: o }; group.add(m); m.setDisposable(this.source.subscribe(new MergeDelayErrorObserver(group, state))); return group; }; return MergeDelayErrorObservable; }(ObservableBase)); var MergeDelayErrorObserver = (function(__super__) { inherits(MergeDelayErrorObserver, __super__); function MergeDelayErrorObserver(group, state) { this._group = group; this._state = state; __super__.call(this); } function setCompletion(o, errors) { if (errors.length === 0) { o.onCompleted(); } else if (errors.length === 1) { o.onError(errors[0]); } else { o.onError(new CompositeError(errors)); } } MergeDelayErrorObserver.prototype.next = function (x) { var inner = new SingleAssignmentDisposable(); this._group.add(inner); // Check for promises support isPromise(x) && (x = observableFromPromise(x)); inner.setDisposable(x.subscribe(new InnerObserver(inner, this._group, this._state))); }; MergeDelayErrorObserver.prototype.error = function (e) { this._state.errors.push(e); this._state.isStopped = true; this._group.length === 1 && setCompletion(this._state.o, this._state.errors); }; MergeDelayErrorObserver.prototype.completed = function () { this._state.isStopped = true; this._group.length === 1 && setCompletion(this._state.o, this._state.errors); }; inherits(InnerObserver, __super__); function InnerObserver(inner, group, state) { this._inner = inner; this._group = group; this._state = state; __super__.call(this); } InnerObserver.prototype.next = function (x) { this._state.o.onNext(x); }; InnerObserver.prototype.error = function (e) { this._state.errors.push(e); this._group.remove(this._inner); this._state.isStopped && this._group.length === 1 && setCompletion(this._state.o, this._state.errors); }; InnerObserver.prototype.completed = function () { this._group.remove(this._inner); this._state.isStopped && this._group.length === 1 && setCompletion(this._state.o, this._state.errors); }; return MergeDelayErrorObserver; }(AbstractObserver)); /** * Flattens an Observable that emits Observables into one Observable, in a way that allows an Observer to * receive all successfully emitted items from all of the source Observables without being interrupted by * an error notification from one of them. * * This behaves like Observable.prototype.mergeAll except that if any of the merged Observables notify of an * error via the Observer's onError, mergeDelayError will refrain from propagating that * error notification until all of the merged Observables have finished emitting items. * @param {Array | Arguments} args Arguments or an array to merge. * @returns {Observable} an Observable that emits all of the items emitted by the Observables emitted by the Observable */ Observable.mergeDelayError = function() { var args; if (Array.isArray(arguments[0])) { args = arguments[0]; } else { var len = arguments.length; args = new Array(len); for(var i = 0; i < len; i++) { args[i] = arguments[i]; } } var source = observableOf(null, args); return new MergeDelayErrorObservable(source); }; /** * Continues an observable sequence that is terminated normally or by an exception with the next observable sequence. * @param {Observable} second Second observable sequence used to produce results after the first sequence terminates. * @returns {Observable} An observable sequence that concatenates the first and second sequence, even if the first sequence terminates exceptionally. */ observableProto.onErrorResumeNext = function (second) { if (!second) { throw new Error('Second observable is required'); } return onErrorResumeNext([this, second]); }; var OnErrorResumeNextObservable = (function(__super__) { inherits(OnErrorResumeNextObservable, __super__); function OnErrorResumeNextObservable(sources) { this.sources = sources; __super__.call(this); } function scheduleMethod(state, recurse) { if (state.pos < state.sources.length) { var current = state.sources[state.pos++]; isPromise(current) && (current = observableFromPromise(current)); var d = new SingleAssignmentDisposable(); state.subscription.setDisposable(d); d.setDisposable(current.subscribe(new OnErrorResumeNextObserver(state, recurse))); } else { state.o.onCompleted(); } } OnErrorResumeNextObservable.prototype.subscribeCore = function (o) { var subscription = new SerialDisposable(), state = {pos: 0, subscription: subscription, o: o, sources: this.sources }, cancellable = immediateScheduler.scheduleRecursive(state, scheduleMethod); return new BinaryDisposable(subscription, cancellable); }; return OnErrorResumeNextObservable; }(ObservableBase)); var OnErrorResumeNextObserver = (function(__super__) { inherits(OnErrorResumeNextObserver, __super__); function OnErrorResumeNextObserver(state, recurse) { this._state = state; this._recurse = recurse; __super__.call(this); } OnErrorResumeNextObserver.prototype.next = function (x) { this._state.o.onNext(x); }; OnErrorResumeNextObserver.prototype.error = function () { this._recurse(this._state); }; OnErrorResumeNextObserver.prototype.completed = function () { this._recurse(this._state); }; return OnErrorResumeNextObserver; }(AbstractObserver)); /** * Continues an observable sequence that is terminated normally or by an exception with the next observable sequence. * @returns {Observable} An observable sequence that concatenates the source sequences, even if a sequence terminates exceptionally. */ var onErrorResumeNext = Observable.onErrorResumeNext = function () { var sources = []; if (Array.isArray(arguments[0])) { sources = arguments[0]; } else { var len = arguments.length; sources = new Array(len); for(var i = 0; i < len; i++) { sources[i] = arguments[i]; } } return new OnErrorResumeNextObservable(sources); }; var SkipUntilObservable = (function(__super__) { inherits(SkipUntilObservable, __super__); function SkipUntilObservable(source, other) { this._s = source; this._o = isPromise(other) ? observableFromPromise(other) : other; this._open = false; __super__.call(this); } SkipUntilObservable.prototype.subscribeCore = function(o) { var leftSubscription = new SingleAssignmentDisposable(); leftSubscription.setDisposable(this._s.subscribe(new SkipUntilSourceObserver(o, this))); isPromise(this._o) && (this._o = observableFromPromise(this._o)); var rightSubscription = new SingleAssignmentDisposable(); rightSubscription.setDisposable(this._o.subscribe(new SkipUntilOtherObserver(o, this, rightSubscription))); return new BinaryDisposable(leftSubscription, rightSubscription); }; return SkipUntilObservable; }(ObservableBase)); var SkipUntilSourceObserver = (function(__super__) { inherits(SkipUntilSourceObserver, __super__); function SkipUntilSourceObserver(o, p) { this._o = o; this._p = p; __super__.call(this); } SkipUntilSourceObserver.prototype.next = function (x) { this._p._open && this._o.onNext(x); }; SkipUntilSourceObserver.prototype.error = function (err) { this._o.onError(err); }; SkipUntilSourceObserver.prototype.onCompleted = function () { this._p._open && this._o.onCompleted(); }; return SkipUntilSourceObserver; }(AbstractObserver)); var SkipUntilOtherObserver = (function(__super__) { inherits(SkipUntilOtherObserver, __super__); function SkipUntilOtherObserver(o, p, r) { this._o = o; this._p = p; this._r = r; __super__.call(this); } SkipUntilOtherObserver.prototype.next = function () { this._p._open = true; this._r.dispose(); }; SkipUntilOtherObserver.prototype.error = function (err) { this._o.onError(err); }; SkipUntilOtherObserver.prototype.onCompleted = function () { this._r.dispose(); }; return SkipUntilOtherObserver; }(AbstractObserver)); /** * Returns the values from the source observable sequence only after the other observable sequence produces a value. * @param {Observable | Promise} other The observable sequence or Promise that triggers propagation of elements of the source sequence. * @returns {Observable} An observable sequence containing the elements of the source sequence starting from the point the other sequence triggered propagation. */ observableProto.skipUntil = function (other) { return new SkipUntilObservable(this, other); }; var SwitchObservable = (function(__super__) { inherits(SwitchObservable, __super__); function SwitchObservable(source) { this.source = source; __super__.call(this); } SwitchObservable.prototype.subscribeCore = function (o) { var inner = new SerialDisposable(), s = this.source.subscribe(new SwitchObserver(o, inner)); return new BinaryDisposable(s, inner); }; inherits(SwitchObserver, AbstractObserver); function SwitchObserver(o, inner) { this.o = o; this.inner = inner; this.stopped = false; this.latest = 0; this.hasLatest = false; AbstractObserver.call(this); } SwitchObserver.prototype.next = function (innerSource) { var d = new SingleAssignmentDisposable(), id = ++this.latest; this.hasLatest = true; this.inner.setDisposable(d); isPromise(innerSource) && (innerSource = observableFromPromise(innerSource)); d.setDisposable(innerSource.subscribe(new InnerObserver(this, id))); }; SwitchObserver.prototype.error = function (e) { this.o.onError(e); }; SwitchObserver.prototype.completed = function () { this.stopped = true; !this.hasLatest && this.o.onCompleted(); }; inherits(InnerObserver, AbstractObserver); function InnerObserver(parent, id) { this.parent = parent; this.id = id; AbstractObserver.call(this); } InnerObserver.prototype.next = function (x) { this.parent.latest === this.id && this.parent.o.onNext(x); }; InnerObserver.prototype.error = function (e) { this.parent.latest === this.id && this.parent.o.onError(e); }; InnerObserver.prototype.completed = function () { if (this.parent.latest === this.id) { this.parent.hasLatest = false; this.parent.stopped && this.parent.o.onCompleted(); } }; return SwitchObservable; }(ObservableBase)); /** * Transforms an observable sequence of observable sequences into an observable sequence producing values only from the most recent observable sequence. * @returns {Observable} The observable sequence that at any point in time produces the elements of the most recent inner observable sequence that has been received. */ observableProto['switch'] = observableProto.switchLatest = function () { return new SwitchObservable(this); }; var TakeUntilObservable = (function(__super__) { inherits(TakeUntilObservable, __super__); function TakeUntilObservable(source, other) { this.source = source; this.other = isPromise(other) ? observableFromPromise(other) : other; __super__.call(this); } TakeUntilObservable.prototype.subscribeCore = function(o) { return new BinaryDisposable( this.source.subscribe(o), this.other.subscribe(new TakeUntilObserver(o)) ); }; return TakeUntilObservable; }(ObservableBase)); var TakeUntilObserver = (function(__super__) { inherits(TakeUntilObserver, __super__); function TakeUntilObserver(o) { this._o = o; __super__.call(this); } TakeUntilObserver.prototype.next = function () { this._o.onCompleted(); }; TakeUntilObserver.prototype.error = function (err) { this._o.onError(err); }; TakeUntilObserver.prototype.onCompleted = noop; return TakeUntilObserver; }(AbstractObserver)); /** * Returns the values from the source observable sequence until the other observable sequence produces a value. * @param {Observable | Promise} other Observable sequence or Promise that terminates propagation of elements of the source sequence. * @returns {Observable} An observable sequence containing the elements of the source sequence up to the point the other sequence interrupted further propagation. */ observableProto.takeUntil = function (other) { return new TakeUntilObservable(this, other); }; function falseFactory() { return false; } function argumentsToArray() { var len = arguments.length, args = new Array(len); for(var i = 0; i < len; i++) { args[i] = arguments[i]; } return args; } var WithLatestFromObservable = (function(__super__) { inherits(WithLatestFromObservable, __super__); function WithLatestFromObservable(source, sources, resultSelector) { this._s = source; this._ss = sources; this._cb = resultSelector; __super__.call(this); } WithLatestFromObservable.prototype.subscribeCore = function (o) { var len = this._ss.length; var state = { hasValue: arrayInitialize(len, falseFactory), hasValueAll: false, values: new Array(len) }; var n = this._ss.length, subscriptions = new Array(n + 1); for (var i = 0; i < n; i++) { var other = this._ss[i], sad = new SingleAssignmentDisposable(); isPromise(other) && (other = observableFromPromise(other)); sad.setDisposable(other.subscribe(new WithLatestFromOtherObserver(o, i, state))); subscriptions[i] = sad; } var outerSad = new SingleAssignmentDisposable(); outerSad.setDisposable(this._s.subscribe(new WithLatestFromSourceObserver(o, this._cb, state))); subscriptions[n] = outerSad; return new NAryDisposable(subscriptions); }; return WithLatestFromObservable; }(ObservableBase)); var WithLatestFromOtherObserver = (function (__super__) { inherits(WithLatestFromOtherObserver, __super__); function WithLatestFromOtherObserver(o, i, state) { this._o = o; this._i = i; this._state = state; __super__.call(this); } WithLatestFromOtherObserver.prototype.next = function (x) { this._state.values[this._i] = x; this._state.hasValue[this._i] = true; this._state.hasValueAll = this._state.hasValue.every(identity); }; WithLatestFromOtherObserver.prototype.error = function (e) { this._o.onError(e); }; WithLatestFromOtherObserver.prototype.completed = noop; return WithLatestFromOtherObserver; }(AbstractObserver)); var WithLatestFromSourceObserver = (function (__super__) { inherits(WithLatestFromSourceObserver, __super__); function WithLatestFromSourceObserver(o, cb, state) { this._o = o; this._cb = cb; this._state = state; __super__.call(this); } WithLatestFromSourceObserver.prototype.next = function (x) { var allValues = [x].concat(this._state.values); if (!this._state.hasValueAll) { return; } var res = tryCatch(this._cb).apply(null, allValues); if (res === errorObj) { return this._o.onError(res.e); } this._o.onNext(res); }; WithLatestFromSourceObserver.prototype.error = function (e) { this._o.onError(e); }; WithLatestFromSourceObserver.prototype.completed = function () { this._o.onCompleted(); }; return WithLatestFromSourceObserver; }(AbstractObserver)); /** * Merges the specified observable sequences into one observable sequence by using the selector function only when the (first) source observable sequence produces an element. * @returns {Observable} An observable sequence containing the result of combining elements of the sources using the specified result selector function. */ observableProto.withLatestFrom = function () { if (arguments.length === 0) { throw new Error('invalid arguments'); } var len = arguments.length, args = new Array(len); for(var i = 0; i < len; i++) { args[i] = arguments[i]; } var resultSelector = isFunction(args[len - 1]) ? args.pop() : argumentsToArray; Array.isArray(args[0]) && (args = args[0]); return new WithLatestFromObservable(this, args, resultSelector); }; function falseFactory() { return false; } function emptyArrayFactory() { return []; } var ZipObservable = (function(__super__) { inherits(ZipObservable, __super__); function ZipObservable(sources, resultSelector) { this._s = sources; this._cb = resultSelector; __super__.call(this); } ZipObservable.prototype.subscribeCore = function(observer) { var n = this._s.length, subscriptions = new Array(n), done = arrayInitialize(n, falseFactory), q = arrayInitialize(n, emptyArrayFactory); for (var i = 0; i < n; i++) { var source = this._s[i], sad = new SingleAssignmentDisposable(); subscriptions[i] = sad; isPromise(source) && (source = observableFromPromise(source)); sad.setDisposable(source.subscribe(new ZipObserver(observer, i, this, q, done))); } return new NAryDisposable(subscriptions); }; return ZipObservable; }(ObservableBase)); var ZipObserver = (function (__super__) { inherits(ZipObserver, __super__); function ZipObserver(o, i, p, q, d) { this._o = o; this._i = i; this._p = p; this._q = q; this._d = d; __super__.call(this); } function notEmpty(x) { return x.length > 0; } function shiftEach(x) { return x.shift(); } function notTheSame(i) { return function (x, j) { return j !== i; }; } ZipObserver.prototype.next = function (x) { this._q[this._i].push(x); if (this._q.every(notEmpty)) { var queuedValues = this._q.map(shiftEach); var res = tryCatch(this._p._cb).apply(null, queuedValues); if (res === errorObj) { return this._o.onError(res.e); } this._o.onNext(res); } else if (this._d.filter(notTheSame(this._i)).every(identity)) { this._o.onCompleted(); } }; ZipObserver.prototype.error = function (e) { this._o.onError(e); }; ZipObserver.prototype.completed = function () { this._d[this._i] = true; this._d.every(identity) && this._o.onCompleted(); }; return ZipObserver; }(AbstractObserver)); /** * Merges the specified observable sequences into one observable sequence by using the selector function whenever all of the observable sequences or an array have produced an element at a corresponding index. * The last element in the arguments must be a function to invoke for each series of elements at corresponding indexes in the args. * @returns {Observable} An observable sequence containing the result of combining elements of the args using the specified result selector function. */ observableProto.zip = function () { if (arguments.length === 0) { throw new Error('invalid arguments'); } var len = arguments.length, args = new Array(len); for(var i = 0; i < len; i++) { args[i] = arguments[i]; } var resultSelector = isFunction(args[len - 1]) ? args.pop() : argumentsToArray; Array.isArray(args[0]) && (args = args[0]); var parent = this; args.unshift(parent); return new ZipObservable(args, resultSelector); }; /** * Merges the specified observable sequences into one observable sequence by using the selector function whenever all of the observable sequences have produced an element at a corresponding index. * @param arguments Observable sources. * @param {Function} resultSelector Function to invoke for each series of elements at corresponding indexes in the sources. * @returns {Observable} An observable sequence containing the result of combining elements of the sources using the specified result selector function. */ Observable.zip = function () { var len = arguments.length, args = new Array(len); for(var i = 0; i < len; i++) { args[i] = arguments[i]; } if (Array.isArray(args[0])) { args = isFunction(args[1]) ? args[0].concat(args[1]) : args[0]; } var first = args.shift(); return first.zip.apply(first, args); }; function falseFactory() { return false; } function emptyArrayFactory() { return []; } function argumentsToArray() { var len = arguments.length, args = new Array(len); for(var i = 0; i < len; i++) { args[i] = arguments[i]; } return args; } var ZipIterableObservable = (function(__super__) { inherits(ZipIterableObservable, __super__); function ZipIterableObservable(sources, cb) { this.sources = sources; this._cb = cb; __super__.call(this); } ZipIterableObservable.prototype.subscribeCore = function (o) { var sources = this.sources, len = sources.length, subscriptions = new Array(len); var state = { q: arrayInitialize(len, emptyArrayFactory), done: arrayInitialize(len, falseFactory), cb: this._cb, o: o }; for (var i = 0; i < len; i++) { (function (i) { var source = sources[i], sad = new SingleAssignmentDisposable(); (isArrayLike(source) || isIterable(source)) && (source = observableFrom(source)); subscriptions[i] = sad; sad.setDisposable(source.subscribe(new ZipIterableObserver(state, i))); }(i)); } return new NAryDisposable(subscriptions); }; return ZipIterableObservable; }(ObservableBase)); var ZipIterableObserver = (function (__super__) { inherits(ZipIterableObserver, __super__); function ZipIterableObserver(s, i) { this._s = s; this._i = i; __super__.call(this); } function notEmpty(x) { return x.length > 0; } function shiftEach(x) { return x.shift(); } function notTheSame(i) { return function (x, j) { return j !== i; }; } ZipIterableObserver.prototype.next = function (x) { this._s.q[this._i].push(x); if (this._s.q.every(notEmpty)) { var queuedValues = this._s.q.map(shiftEach), res = tryCatch(this._s.cb).apply(null, queuedValues); if (res === errorObj) { return this._s.o.onError(res.e); } this._s.o.onNext(res); } else if (this._s.done.filter(notTheSame(this._i)).every(identity)) { this._s.o.onCompleted(); } }; ZipIterableObserver.prototype.error = function (e) { this._s.o.onError(e); }; ZipIterableObserver.prototype.completed = function () { this._s.done[this._i] = true; this._s.done.every(identity) && this._s.o.onCompleted(); }; return ZipIterableObserver; }(AbstractObserver)); /** * Merges the specified observable sequences into one observable sequence by using the selector function whenever all of the observable sequences or an array have produced an element at a corresponding index. * The last element in the arguments must be a function to invoke for each series of elements at corresponding indexes in the args. * @returns {Observable} An observable sequence containing the result of combining elements of the args using the specified result selector function. */ observableProto.zipIterable = function () { if (arguments.length === 0) { throw new Error('invalid arguments'); } var len = arguments.length, args = new Array(len); for(var i = 0; i < len; i++) { args[i] = arguments[i]; } var resultSelector = isFunction(args[len - 1]) ? args.pop() : argumentsToArray; var parent = this; args.unshift(parent); return new ZipIterableObservable(args, resultSelector); }; function asObservable(source) { return function subscribe(o) { return source.subscribe(o); }; } /** * Hides the identity of an observable sequence. * @returns {Observable} An observable sequence that hides the identity of the source sequence. */ observableProto.asObservable = function () { return new AnonymousObservable(asObservable(this), this); }; function toArray(x) { return x.toArray(); } function notEmpty(x) { return x.length > 0; } /** * Projects each element of an observable sequence into zero or more buffers which are produced based on element count information. * @param {Number} count Length of each buffer. * @param {Number} [skip] Number of elements to skip between creation of consecutive buffers. If not provided, defaults to the count. * @returns {Observable} An observable sequence of buffers. */ observableProto.bufferWithCount = observableProto.bufferCount = function (count, skip) { typeof skip !== 'number' && (skip = count); return this.windowWithCount(count, skip) .flatMap(toArray) .filter(notEmpty); }; var DematerializeObservable = (function (__super__) { inherits(DematerializeObservable, __super__); function DematerializeObservable(source) { this.source = source; __super__.call(this); } DematerializeObservable.prototype.subscribeCore = function (o) { return this.source.subscribe(new DematerializeObserver(o)); }; return DematerializeObservable; }(ObservableBase)); var DematerializeObserver = (function (__super__) { inherits(DematerializeObserver, __super__); function DematerializeObserver(o) { this._o = o; __super__.call(this); } DematerializeObserver.prototype.next = function (x) { x.accept(this._o); }; DematerializeObserver.prototype.error = function (e) { this._o.onError(e); }; DematerializeObserver.prototype.completed = function () { this._o.onCompleted(); }; return DematerializeObserver; }(AbstractObserver)); /** * Dematerializes the explicit notification values of an observable sequence as implicit notifications. * @returns {Observable} An observable sequence exhibiting the behavior corresponding to the source sequence's notification values. */ observableProto.dematerialize = function () { return new DematerializeObservable(this); }; var DistinctUntilChangedObservable = (function(__super__) { inherits(DistinctUntilChangedObservable, __super__); function DistinctUntilChangedObservable(source, keyFn, comparer) { this.source = source; this.keyFn = keyFn; this.comparer = comparer; __super__.call(this); } DistinctUntilChangedObservable.prototype.subscribeCore = function (o) { return this.source.subscribe(new DistinctUntilChangedObserver(o, this.keyFn, this.comparer)); }; return DistinctUntilChangedObservable; }(ObservableBase)); var DistinctUntilChangedObserver = (function(__super__) { inherits(DistinctUntilChangedObserver, __super__); function DistinctUntilChangedObserver(o, keyFn, comparer) { this.o = o; this.keyFn = keyFn; this.comparer = comparer; this.hasCurrentKey = false; this.currentKey = null; __super__.call(this); } DistinctUntilChangedObserver.prototype.next = function (x) { var key = x, comparerEquals; if (isFunction(this.keyFn)) { key = tryCatch(this.keyFn)(x); if (key === errorObj) { return this.o.onError(key.e); } } if (this.hasCurrentKey) { comparerEquals = tryCatch(this.comparer)(this.currentKey, key); if (comparerEquals === errorObj) { return this.o.onError(comparerEquals.e); } } if (!this.hasCurrentKey || !comparerEquals) { this.hasCurrentKey = true; this.currentKey = key; this.o.onNext(x); } }; DistinctUntilChangedObserver.prototype.error = function(e) { this.o.onError(e); }; DistinctUntilChangedObserver.prototype.completed = function () { this.o.onCompleted(); }; return DistinctUntilChangedObserver; }(AbstractObserver)); /** * Returns an observable sequence that contains only distinct contiguous elements according to the keyFn and the comparer. * @param {Function} [keyFn] A function to compute the comparison key for each element. If not provided, it projects the value. * @param {Function} [comparer] Equality comparer for computed key values. If not provided, defaults to an equality comparer function. * @returns {Observable} An observable sequence only containing the distinct contiguous elements, based on a computed key value, from the source sequence. */ observableProto.distinctUntilChanged = function (keyFn, comparer) { comparer || (comparer = defaultComparer); return new DistinctUntilChangedObservable(this, keyFn, comparer); }; var TapObservable = (function(__super__) { inherits(TapObservable,__super__); function TapObservable(source, observerOrOnNext, onError, onCompleted) { this.source = source; this._oN = observerOrOnNext; this._oE = onError; this._oC = onCompleted; __super__.call(this); } TapObservable.prototype.subscribeCore = function(o) { return this.source.subscribe(new InnerObserver(o, this)); }; inherits(InnerObserver, AbstractObserver); function InnerObserver(o, p) { this.o = o; this.t = !p._oN || isFunction(p._oN) ? observerCreate(p._oN || noop, p._oE || noop, p._oC || noop) : p._oN; this.isStopped = false; AbstractObserver.call(this); } InnerObserver.prototype.next = function(x) { var res = tryCatch(this.t.onNext).call(this.t, x); if (res === errorObj) { this.o.onError(res.e); } this.o.onNext(x); }; InnerObserver.prototype.error = function(err) { var res = tryCatch(this.t.onError).call(this.t, err); if (res === errorObj) { return this.o.onError(res.e); } this.o.onError(err); }; InnerObserver.prototype.completed = function() { var res = tryCatch(this.t.onCompleted).call(this.t); if (res === errorObj) { return this.o.onError(res.e); } this.o.onCompleted(); }; return TapObservable; }(ObservableBase)); /** * Invokes an action for each element in the observable sequence and invokes an action upon graceful or exceptional termination of the observable sequence. * This method can be used for debugging, logging, etc. of query behavior by intercepting the message stream to run arbitrary actions for messages on the pipeline. * @param {Function | Observer} observerOrOnNext Action to invoke for each element in the observable sequence or an o. * @param {Function} [onError] Action to invoke upon exceptional termination of the observable sequence. Used if only the observerOrOnNext parameter is also a function. * @param {Function} [onCompleted] Action to invoke upon graceful termination of the observable sequence. Used if only the observerOrOnNext parameter is also a function. * @returns {Observable} The source sequence with the side-effecting behavior applied. */ observableProto['do'] = observableProto.tap = observableProto.doAction = function (observerOrOnNext, onError, onCompleted) { return new TapObservable(this, observerOrOnNext, onError, onCompleted); }; /** * Invokes an action for each element in the observable sequence. * This method can be used for debugging, logging, etc. of query behavior by intercepting the message stream to run arbitrary actions for messages on the pipeline. * @param {Function} onNext Action to invoke for each element in the observable sequence. * @param {Any} [thisArg] Object to use as this when executing callback. * @returns {Observable} The source sequence with the side-effecting behavior applied. */ observableProto.doOnNext = observableProto.tapOnNext = function (onNext, thisArg) { return this.tap(typeof thisArg !== 'undefined' ? function (x) { onNext.call(thisArg, x); } : onNext); }; /** * Invokes an action upon exceptional termination of the observable sequence. * This method can be used for debugging, logging, etc. of query behavior by intercepting the message stream to run arbitrary actions for messages on the pipeline. * @param {Function} onError Action to invoke upon exceptional termination of the observable sequence. * @param {Any} [thisArg] Object to use as this when executing callback. * @returns {Observable} The source sequence with the side-effecting behavior applied. */ observableProto.doOnError = observableProto.tapOnError = function (onError, thisArg) { return this.tap(noop, typeof thisArg !== 'undefined' ? function (e) { onError.call(thisArg, e); } : onError); }; /** * Invokes an action upon graceful termination of the observable sequence. * This method can be used for debugging, logging, etc. of query behavior by intercepting the message stream to run arbitrary actions for messages on the pipeline. * @param {Function} onCompleted Action to invoke upon graceful termination of the observable sequence. * @param {Any} [thisArg] Object to use as this when executing callback. * @returns {Observable} The source sequence with the side-effecting behavior applied. */ observableProto.doOnCompleted = observableProto.tapOnCompleted = function (onCompleted, thisArg) { return this.tap(noop, null, typeof thisArg !== 'undefined' ? function () { onCompleted.call(thisArg); } : onCompleted); }; var FinallyObservable = (function (__super__) { inherits(FinallyObservable, __super__); function FinallyObservable(source, fn, thisArg) { this.source = source; this._fn = bindCallback(fn, thisArg, 0); __super__.call(this); } FinallyObservable.prototype.subscribeCore = function (o) { var d = tryCatch(this.source.subscribe).call(this.source, o); if (d === errorObj) { this._fn(); thrower(d.e); } return new FinallyDisposable(d, this._fn); }; function FinallyDisposable(s, fn) { this.isDisposed = false; this._s = s; this._fn = fn; } FinallyDisposable.prototype.dispose = function () { if (!this.isDisposed) { var res = tryCatch(this._s.dispose).call(this._s); this._fn(); res === errorObj && thrower(res.e); } }; return FinallyObservable; }(ObservableBase)); /** * Invokes a specified action after the source observable sequence terminates gracefully or exceptionally. * @param {Function} finallyAction Action to invoke after the source observable sequence terminates. * @returns {Observable} Source sequence with the action-invoking termination behavior applied. */ observableProto['finally'] = function (action, thisArg) { return new FinallyObservable(this, action, thisArg); }; var IgnoreElementsObservable = (function(__super__) { inherits(IgnoreElementsObservable, __super__); function IgnoreElementsObservable(source) { this.source = source; __super__.call(this); } IgnoreElementsObservable.prototype.subscribeCore = function (o) { return this.source.subscribe(new InnerObserver(o)); }; function InnerObserver(o) { this.o = o; this.isStopped = false; } InnerObserver.prototype.onNext = noop; InnerObserver.prototype.onError = function (err) { if(!this.isStopped) { this.isStopped = true; this.o.onError(err); } }; InnerObserver.prototype.onCompleted = function () { if(!this.isStopped) { this.isStopped = true; this.o.onCompleted(); } }; InnerObserver.prototype.dispose = function() { this.isStopped = true; }; InnerObserver.prototype.fail = function (e) { if (!this.isStopped) { this.isStopped = true; this.observer.onError(e); return true; } return false; }; return IgnoreElementsObservable; }(ObservableBase)); /** * Ignores all elements in an observable sequence leaving only the termination messages. * @returns {Observable} An empty observable sequence that signals termination, successful or exceptional, of the source sequence. */ observableProto.ignoreElements = function () { return new IgnoreElementsObservable(this); }; var MaterializeObservable = (function (__super__) { inherits(MaterializeObservable, __super__); function MaterializeObservable(source, fn) { this.source = source; __super__.call(this); } MaterializeObservable.prototype.subscribeCore = function (o) { return this.source.subscribe(new MaterializeObserver(o)); }; return MaterializeObservable; }(ObservableBase)); var MaterializeObserver = (function (__super__) { inherits(MaterializeObserver, __super__); function MaterializeObserver(o) { this._o = o; __super__.call(this); } MaterializeObserver.prototype.next = function (x) { this._o.onNext(notificationCreateOnNext(x)) }; MaterializeObserver.prototype.error = function (e) { this._o.onNext(notificationCreateOnError(e)); this._o.onCompleted(); }; MaterializeObserver.prototype.completed = function () { this._o.onNext(notificationCreateOnCompleted()); this._o.onCompleted(); }; return MaterializeObserver; }(AbstractObserver)); /** * Materializes the implicit notifications of an observable sequence as explicit notification values. * @returns {Observable} An observable sequence containing the materialized notification values from the source sequence. */ observableProto.materialize = function () { return new MaterializeObservable(this); }; /** * Repeats the observable sequence a specified number of times. If the repeat count is not specified, the sequence repeats indefinitely. * @param {Number} [repeatCount] Number of times to repeat the sequence. If not provided, repeats the sequence indefinitely. * @returns {Observable} The observable sequence producing the elements of the given sequence repeatedly. */ observableProto.repeat = function (repeatCount) { return enumerableRepeat(this, repeatCount).concat(); }; /** * Repeats the source observable sequence the specified number of times or until it successfully terminates. If the retry count is not specified, it retries indefinitely. * Note if you encounter an error and want it to retry once, then you must use .retry(2); * * @example * var res = retried = retry.repeat(); * var res = retried = retry.repeat(2); * @param {Number} [retryCount] Number of times to retry the sequence. If not provided, retry the sequence indefinitely. * @returns {Observable} An observable sequence producing the elements of the given sequence repeatedly until it terminates successfully. */ observableProto.retry = function (retryCount) { return enumerableRepeat(this, retryCount).catchError(); }; function repeat(value) { return { '@@iterator': function () { return { next: function () { return { done: false, value: value }; } }; } }; } var RetryWhenObservable = (function(__super__) { function createDisposable(state) { return { isDisposed: false, dispose: function () { if (!this.isDisposed) { this.isDisposed = true; state.isDisposed = true; } } }; } function RetryWhenObservable(source, notifier) { this.source = source; this._notifier = notifier; __super__.call(this); } inherits(RetryWhenObservable, __super__); RetryWhenObservable.prototype.subscribeCore = function (o) { var exceptions = new Subject(), notifier = new Subject(), handled = this._notifier(exceptions), notificationDisposable = handled.subscribe(notifier); var e = this.source['@@iterator'](); var state = { isDisposed: false }, lastError, subscription = new SerialDisposable(); var cancelable = currentThreadScheduler.scheduleRecursive(null, function (_, recurse) { if (state.isDisposed) { return; } var currentItem = e.next(); if (currentItem.done) { if (lastError) { o.onError(lastError); } else { o.onCompleted(); } return; } // Check if promise var currentValue = currentItem.value; isPromise(currentValue) && (currentValue = observableFromPromise(currentValue)); var outer = new SingleAssignmentDisposable(); var inner = new SingleAssignmentDisposable(); subscription.setDisposable(new BinaryDisposable(inner, outer)); outer.setDisposable(currentValue.subscribe( function(x) { o.onNext(x); }, function (exn) { inner.setDisposable(notifier.subscribe(recurse, function(ex) { o.onError(ex); }, function() { o.onCompleted(); })); exceptions.onNext(exn); outer.dispose(); }, function() { o.onCompleted(); })); }); return new NAryDisposable([notificationDisposable, subscription, cancelable, createDisposable(state)]); }; return RetryWhenObservable; }(ObservableBase)); observableProto.retryWhen = function (notifier) { return new RetryWhenObservable(repeat(this), notifier); }; function repeat(value) { return { '@@iterator': function () { return { next: function () { return { done: false, value: value }; } }; } }; } var RepeatWhenObservable = (function(__super__) { function createDisposable(state) { return { isDisposed: false, dispose: function () { if (!this.isDisposed) { this.isDisposed = true; state.isDisposed = true; } } }; } function RepeatWhenObservable(source, notifier) { this.source = source; this._notifier = notifier; __super__.call(this); } inherits(RepeatWhenObservable, __super__); RepeatWhenObservable.prototype.subscribeCore = function (o) { var completions = new Subject(), notifier = new Subject(), handled = this._notifier(completions), notificationDisposable = handled.subscribe(notifier); var e = this.source['@@iterator'](); var state = { isDisposed: false }, lastError, subscription = new SerialDisposable(); var cancelable = currentThreadScheduler.scheduleRecursive(null, function (_, recurse) { if (state.isDisposed) { return; } var currentItem = e.next(); if (currentItem.done) { if (lastError) { o.onError(lastError); } else { o.onCompleted(); } return; } // Check if promise var currentValue = currentItem.value; isPromise(currentValue) && (currentValue = observableFromPromise(currentValue)); var outer = new SingleAssignmentDisposable(); var inner = new SingleAssignmentDisposable(); subscription.setDisposable(new BinaryDisposable(inner, outer)); outer.setDisposable(currentValue.subscribe( function(x) { o.onNext(x); }, function (exn) { o.onError(exn); }, function() { inner.setDisposable(notifier.subscribe(recurse, function(ex) { o.onError(ex); }, function() { o.onCompleted(); })); completions.onNext(null); outer.dispose(); })); }); return new NAryDisposable([notificationDisposable, subscription, cancelable, createDisposable(state)]); }; return RepeatWhenObservable; }(ObservableBase)); observableProto.repeatWhen = function (notifier) { return new RepeatWhenObservable(repeat(this), notifier); }; var ScanObservable = (function(__super__) { inherits(ScanObservable, __super__); function ScanObservable(source, accumulator, hasSeed, seed) { this.source = source; this.accumulator = accumulator; this.hasSeed = hasSeed; this.seed = seed; __super__.call(this); } ScanObservable.prototype.subscribeCore = function(o) { return this.source.subscribe(new ScanObserver(o,this)); }; return ScanObservable; }(ObservableBase)); var ScanObserver = (function (__super__) { inherits(ScanObserver, __super__); function ScanObserver(o, parent) { this._o = o; this._p = parent; this._fn = parent.accumulator; this._hs = parent.hasSeed; this._s = parent.seed; this._ha = false; this._a = null; this._hv = false; this._i = 0; __super__.call(this); } ScanObserver.prototype.next = function (x) { !this._hv && (this._hv = true); if (this._ha) { this._a = tryCatch(this._fn)(this._a, x, this._i, this._p); } else { this._a = this._hs ? tryCatch(this._fn)(this._s, x, this._i, this._p) : x; this._ha = true; } if (this._a === errorObj) { return this._o.onError(this._a.e); } this._o.onNext(this._a); this._i++; }; ScanObserver.prototype.error = function (e) { this._o.onError(e); }; ScanObserver.prototype.completed = function () { !this._hv && this._hs && this._o.onNext(this._s); this._o.onCompleted(); }; return ScanObserver; }(AbstractObserver)); /** * Applies an accumulator function over an observable sequence and returns each intermediate result. The optional seed value is used as the initial accumulator value. * For aggregation behavior with no intermediate results, see Observable.aggregate. * @param {Mixed} [seed] The initial accumulator value. * @param {Function} accumulator An accumulator function to be invoked on each element. * @returns {Observable} An observable sequence containing the accumulated values. */ observableProto.scan = function () { var hasSeed = false, seed, accumulator = arguments[0]; if (arguments.length === 2) { hasSeed = true; seed = arguments[1]; } return new ScanObservable(this, accumulator, hasSeed, seed); }; var SkipLastObservable = (function (__super__) { inherits(SkipLastObservable, __super__); function SkipLastObservable(source, c) { this.source = source; this._c = c; __super__.call(this); } SkipLastObservable.prototype.subscribeCore = function (o) { return this.source.subscribe(new SkipLastObserver(o, this._c)); }; return SkipLastObservable; }(ObservableBase)); var SkipLastObserver = (function (__super__) { inherits(SkipLastObserver, __super__); function SkipLastObserver(o, c) { this._o = o; this._c = c; this._q = []; __super__.call(this); } SkipLastObserver.prototype.next = function (x) { this._q.push(x); this._q.length > this._c && this._o.onNext(this._q.shift()); }; SkipLastObserver.prototype.error = function (e) { this._o.onError(e); }; SkipLastObserver.prototype.completed = function () { this._o.onCompleted(); }; return SkipLastObserver; }(AbstractObserver)); /** * Bypasses a specified number of elements at the end of an observable sequence. * @description * This operator accumulates a queue with a length enough to store the first `count` elements. As more elements are * received, elements are taken from the front of the queue and produced on the result sequence. This causes elements to be delayed. * @param count Number of elements to bypass at the end of the source sequence. * @returns {Observable} An observable sequence containing the source sequence elements except for the bypassed ones at the end. */ observableProto.skipLast = function (count) { if (count < 0) { throw new ArgumentOutOfRangeError(); } return new SkipLastObservable(this, count); }; /** * Prepends a sequence of values to an observable sequence with an optional scheduler and an argument list of values to prepend. * @example * var res = source.startWith(1, 2, 3); * var res = source.startWith(Rx.Scheduler.timeout, 1, 2, 3); * @param {Arguments} args The specified values to prepend to the observable sequence * @returns {Observable} The source sequence prepended with the specified values. */ observableProto.startWith = function () { var values, scheduler, start = 0; if (!!arguments.length && isScheduler(arguments[0])) { scheduler = arguments[0]; start = 1; } else { scheduler = immediateScheduler; } for(var args = [], i = start, len = arguments.length; i < len; i++) { args.push(arguments[i]); } return observableConcat.apply(null, [observableFromArray(args, scheduler), this]); }; var TakeLastObserver = (function (__super__) { inherits(TakeLastObserver, __super__); function TakeLastObserver(o, c) { this._o = o; this._c = c; this._q = []; __super__.call(this); } TakeLastObserver.prototype.next = function (x) { this._q.push(x); this._q.length > this._c && this._q.shift(); }; TakeLastObserver.prototype.error = function (e) { this._o.onError(e); }; TakeLastObserver.prototype.completed = function () { while (this._q.length > 0) { this._o.onNext(this._q.shift()); } this._o.onCompleted(); }; return TakeLastObserver; }(AbstractObserver)); /** * Returns a specified number of contiguous elements from the end of an observable sequence. * @description * This operator accumulates a buffer with a length enough to store elements count elements. Upon completion of * the source sequence, this buffer is drained on the result sequence. This causes the elements to be delayed. * @param {Number} count Number of elements to take from the end of the source sequence. * @returns {Observable} An observable sequence containing the specified number of elements from the end of the source sequence. */ observableProto.takeLast = function (count) { if (count < 0) { throw new ArgumentOutOfRangeError(); } var source = this; return new AnonymousObservable(function (o) { return source.subscribe(new TakeLastObserver(o, count)); }, source); }; var TakeLastBufferObserver = (function (__super__) { inherits(TakeLastBufferObserver, __super__); function TakeLastBufferObserver(o, c) { this._o = o; this._c = c; this._q = []; __super__.call(this); } TakeLastBufferObserver.prototype.next = function (x) { this._q.push(x); this._q.length > this._c && this._q.shift(); }; TakeLastBufferObserver.prototype.error = function (e) { this._o.onError(e); }; TakeLastBufferObserver.prototype.completed = function () { this._o.onNext(this._q); this._o.onCompleted(); }; return TakeLastBufferObserver; }(AbstractObserver)); /** * Returns an array with the specified number of contiguous elements from the end of an observable sequence. * * @description * This operator accumulates a buffer with a length enough to store count elements. Upon completion of the * source sequence, this buffer is produced on the result sequence. * @param {Number} count Number of elements to take from the end of the source sequence. * @returns {Observable} An observable sequence containing a single array with the specified number of elements from the end of the source sequence. */ observableProto.takeLastBuffer = function (count) { if (count < 0) { throw new ArgumentOutOfRangeError(); } var source = this; return new AnonymousObservable(function (o) { return source.subscribe(new TakeLastBufferObserver(o, count)); }, source); }; /** * Projects each element of an observable sequence into zero or more windows which are produced based on element count information. * @param {Number} count Length of each window. * @param {Number} [skip] Number of elements to skip between creation of consecutive windows. If not specified, defaults to the count. * @returns {Observable} An observable sequence of windows. */ observableProto.windowWithCount = observableProto.windowCount = function (count, skip) { var source = this; +count || (count = 0); Math.abs(count) === Infinity && (count = 0); if (count <= 0) { throw new ArgumentOutOfRangeError(); } skip == null && (skip = count); +skip || (skip = 0); Math.abs(skip) === Infinity && (skip = 0); if (skip <= 0) { throw new ArgumentOutOfRangeError(); } return new AnonymousObservable(function (observer) { var m = new SingleAssignmentDisposable(), refCountDisposable = new RefCountDisposable(m), n = 0, q = []; function createWindow () { var s = new Subject(); q.push(s); observer.onNext(addRef(s, refCountDisposable)); } createWindow(); m.setDisposable(source.subscribe( function (x) { for (var i = 0, len = q.length; i < len; i++) { q[i].onNext(x); } var c = n - count + 1; c >= 0 && c % skip === 0 && q.shift().onCompleted(); ++n % skip === 0 && createWindow(); }, function (e) { while (q.length > 0) { q.shift().onError(e); } observer.onError(e); }, function () { while (q.length > 0) { q.shift().onCompleted(); } observer.onCompleted(); } )); return refCountDisposable; }, source); }; observableProto.flatMapConcat = observableProto.concatMap = function(selector, resultSelector, thisArg) { return new FlatMapObservable(this, selector, resultSelector, thisArg).merge(1); }; /** * Projects each notification of an observable sequence to an observable sequence and concats the resulting observable sequences into one observable sequence. * @param {Function} onNext A transform function to apply to each element; the second parameter of the function represents the index of the source element. * @param {Function} onError A transform function to apply when an error occurs in the source sequence. * @param {Function} onCompleted A transform function to apply when the end of the source sequence is reached. * @param {Any} [thisArg] An optional "this" to use to invoke each transform. * @returns {Observable} An observable sequence whose elements are the result of invoking the one-to-many transform function corresponding to each notification in the input sequence. */ observableProto.concatMapObserver = observableProto.selectConcatObserver = function(onNext, onError, onCompleted, thisArg) { var source = this, onNextFunc = bindCallback(onNext, thisArg, 2), onErrorFunc = bindCallback(onError, thisArg, 1), onCompletedFunc = bindCallback(onCompleted, thisArg, 0); return new AnonymousObservable(function (observer) { var index = 0; return source.subscribe( function (x) { var result; try { result = onNextFunc(x, index++); } catch (e) { observer.onError(e); return; } isPromise(result) && (result = observableFromPromise(result)); observer.onNext(result); }, function (err) { var result; try { result = onErrorFunc(err); } catch (e) { observer.onError(e); return; } isPromise(result) && (result = observableFromPromise(result)); observer.onNext(result); observer.onCompleted(); }, function () { var result; try { result = onCompletedFunc(); } catch (e) { observer.onError(e); return; } isPromise(result) && (result = observableFromPromise(result)); observer.onNext(result); observer.onCompleted(); }); }, this).concatAll(); }; var DefaultIfEmptyObserver = (function (__super__) { inherits(DefaultIfEmptyObserver, __super__); function DefaultIfEmptyObserver(o, d) { this._o = o; this._d = d; this._f = false; __super__.call(this); } DefaultIfEmptyObserver.prototype.next = function (x) { this._f = true; this._o.onNext(x); }; DefaultIfEmptyObserver.prototype.error = function (e) { this._o.onError(e); }; DefaultIfEmptyObserver.prototype.completed = function () { !this._f && this._o.onNext(this._d); this._o.onCompleted(); }; return DefaultIfEmptyObserver; }(AbstractObserver)); /** * Returns the elements of the specified sequence or the specified value in a singleton sequence if the sequence is empty. * * var res = obs = xs.defaultIfEmpty(); * 2 - obs = xs.defaultIfEmpty(false); * * @memberOf Observable# * @param defaultValue The value to return if the sequence is empty. If not provided, this defaults to null. * @returns {Observable} An observable sequence that contains the specified default value if the source is empty; otherwise, the elements of the source itself. */ observableProto.defaultIfEmpty = function (defaultValue) { var source = this; defaultValue === undefined && (defaultValue = null); return new AnonymousObservable(function (o) { return source.subscribe(new DefaultIfEmptyObserver(o, defaultValue)); }, source); }; // Swap out for Array.findIndex function arrayIndexOfComparer(array, item, comparer) { for (var i = 0, len = array.length; i < len; i++) { if (comparer(array[i], item)) { return i; } } return -1; } function HashSet(comparer) { this.comparer = comparer; this.set = []; } HashSet.prototype.push = function(value) { var retValue = arrayIndexOfComparer(this.set, value, this.comparer) === -1; retValue && this.set.push(value); return retValue; }; var DistinctObservable = (function (__super__) { inherits(DistinctObservable, __super__); function DistinctObservable(source, keyFn, cmpFn) { this.source = source; this._keyFn = keyFn; this._cmpFn = cmpFn; __super__.call(this); } DistinctObservable.prototype.subscribeCore = function (o) { return this.source.subscribe(new DistinctObserver(o, this._keyFn, this._cmpFn)); }; return DistinctObservable; }(ObservableBase)); var DistinctObserver = (function (__super__) { inherits(DistinctObserver, __super__); function DistinctObserver(o, keyFn, cmpFn) { this._o = o; this._keyFn = keyFn; this._h = new HashSet(cmpFn); __super__.call(this); } DistinctObserver.prototype.next = function (x) { var key = x; if (isFunction(this._keyFn)) { key = tryCatch(this._keyFn)(x); if (key === errorObj) { return this._o.onError(key.e); } } this._h.push(key) && this._o.onNext(x); }; DistinctObserver.prototype.error = function (e) { this._o.onError(e); }; DistinctObserver.prototype.completed = function () { this._o.onCompleted(); }; return DistinctObserver; }(AbstractObserver)); /** * Returns an observable sequence that contains only distinct elements according to the keySelector and the comparer. * Usage of this operator should be considered carefully due to the maintenance of an internal lookup structure which can grow large. * * @example * var res = obs = xs.distinct(); * 2 - obs = xs.distinct(function (x) { return x.id; }); * 2 - obs = xs.distinct(function (x) { return x.id; }, function (a,b) { return a === b; }); * @param {Function} [keySelector] A function to compute the comparison key for each element. * @param {Function} [comparer] Used to compare items in the collection. * @returns {Observable} An observable sequence only containing the distinct elements, based on a computed key value, from the source sequence. */ observableProto.distinct = function (keySelector, comparer) { comparer || (comparer = defaultComparer); return new DistinctObservable(this, keySelector, comparer); }; var MapObservable = (function (__super__) { inherits(MapObservable, __super__); function MapObservable(source, selector, thisArg) { this.source = source; this.selector = bindCallback(selector, thisArg, 3); __super__.call(this); } function innerMap(selector, self) { return function (x, i, o) { return selector.call(this, self.selector(x, i, o), i, o); }; } MapObservable.prototype.internalMap = function (selector, thisArg) { return new MapObservable(this.source, innerMap(selector, this), thisArg); }; MapObservable.prototype.subscribeCore = function (o) { return this.source.subscribe(new InnerObserver(o, this.selector, this)); }; inherits(InnerObserver, AbstractObserver); function InnerObserver(o, selector, source) { this.o = o; this.selector = selector; this.source = source; this.i = 0; AbstractObserver.call(this); } InnerObserver.prototype.next = function(x) { var result = tryCatch(this.selector)(x, this.i++, this.source); if (result === errorObj) { return this.o.onError(result.e); } this.o.onNext(result); }; InnerObserver.prototype.error = function (e) { this.o.onError(e); }; InnerObserver.prototype.completed = function () { this.o.onCompleted(); }; return MapObservable; }(ObservableBase)); /** * Projects each element of an observable sequence into a new form by incorporating the element's index. * @param {Function} selector A transform function to apply to each source element; the second parameter of the function represents the index of the source element. * @param {Any} [thisArg] Object to use as this when executing callback. * @returns {Observable} An observable sequence whose elements are the result of invoking the transform function on each element of source. */ observableProto.map = observableProto.select = function (selector, thisArg) { var selectorFn = typeof selector === 'function' ? selector : function () { return selector; }; return this instanceof MapObservable ? this.internalMap(selectorFn, thisArg) : new MapObservable(this, selectorFn, thisArg); }; function plucker(args, len) { return function mapper(x) { var currentProp = x; for (var i = 0; i < len; i++) { var p = currentProp[args[i]]; if (typeof p !== 'undefined') { currentProp = p; } else { return undefined; } } return currentProp; }; } /** * Retrieves the value of a specified nested property from all elements in * the Observable sequence. * @param {Arguments} arguments The nested properties to pluck. * @returns {Observable} Returns a new Observable sequence of property values. */ observableProto.pluck = function () { var len = arguments.length, args = new Array(len); if (len === 0) { throw new Error('List of properties cannot be empty.'); } for(var i = 0; i < len; i++) { args[i] = arguments[i]; } return this.map(plucker(args, len)); }; observableProto.flatMap = observableProto.selectMany = observableProto.mergeMap = function(selector, resultSelector, thisArg) { return new FlatMapObservable(this, selector, resultSelector, thisArg).mergeAll(); }; /** * Projects each notification of an observable sequence to an observable sequence and merges the resulting observable sequences into one observable sequence. * @param {Function} onNext A transform function to apply to each element; the second parameter of the function represents the index of the source element. * @param {Function} onError A transform function to apply when an error occurs in the source sequence. * @param {Function} onCompleted A transform function to apply when the end of the source sequence is reached. * @param {Any} [thisArg] An optional "this" to use to invoke each transform. * @returns {Observable} An observable sequence whose elements are the result of invoking the one-to-many transform function corresponding to each notification in the input sequence. */ observableProto.flatMapObserver = observableProto.selectManyObserver = function (onNext, onError, onCompleted, thisArg) { var source = this; return new AnonymousObservable(function (observer) { var index = 0; return source.subscribe( function (x) { var result; try { result = onNext.call(thisArg, x, index++); } catch (e) { observer.onError(e); return; } isPromise(result) && (result = observableFromPromise(result)); observer.onNext(result); }, function (err) { var result; try { result = onError.call(thisArg, err); } catch (e) { observer.onError(e); return; } isPromise(result) && (result = observableFromPromise(result)); observer.onNext(result); observer.onCompleted(); }, function () { var result; try { result = onCompleted.call(thisArg); } catch (e) { observer.onError(e); return; } isPromise(result) && (result = observableFromPromise(result)); observer.onNext(result); observer.onCompleted(); }); }, source).mergeAll(); }; observableProto.flatMapLatest = observableProto.switchMap = function(selector, resultSelector, thisArg) { return new FlatMapObservable(this, selector, resultSelector, thisArg).switchLatest(); }; var SkipObservable = (function(__super__) { inherits(SkipObservable, __super__); function SkipObservable(source, count) { this.source = source; this._count = count; __super__.call(this); } SkipObservable.prototype.subscribeCore = function (o) { return this.source.subscribe(new SkipObserver(o, this._count)); }; function SkipObserver(o, c) { this._o = o; this._r = c; AbstractObserver.call(this); } inherits(SkipObserver, AbstractObserver); SkipObserver.prototype.next = function (x) { if (this._r <= 0) { this._o.onNext(x); } else { this._r--; } }; SkipObserver.prototype.error = function(e) { this._o.onError(e); }; SkipObserver.prototype.completed = function() { this._o.onCompleted(); }; return SkipObservable; }(ObservableBase)); /** * Bypasses a specified number of elements in an observable sequence and then returns the remaining elements. * @param {Number} count The number of elements to skip before returning the remaining elements. * @returns {Observable} An observable sequence that contains the elements that occur after the specified index in the input sequence. */ observableProto.skip = function (count) { if (count < 0) { throw new ArgumentOutOfRangeError(); } return new SkipObservable(this, count); }; var SkipWhileObservable = (function (__super__) { inherits(SkipWhileObservable, __super__); function SkipWhileObservable(source, fn) { this.source = source; this._fn = fn; __super__.call(this); } SkipWhileObservable.prototype.subscribeCore = function (o) { return this.source.subscribe(new SkipWhileObserver(o, this)); }; return SkipWhileObservable; }(ObservableBase)); var SkipWhileObserver = (function (__super__) { inherits(SkipWhileObserver, __super__); function SkipWhileObserver(o, p) { this._o = o; this._p = p; this._i = 0; this._r = false; __super__.call(this); } SkipWhileObserver.prototype.next = function (x) { if (!this._r) { var res = tryCatch(this._p._fn)(x, this._i++, this._p); if (res === errorObj) { return this._o.onError(res.e); } this._r = !res; } this._r && this._o.onNext(x); }; SkipWhileObserver.prototype.error = function (e) { this._o.onError(e); }; SkipWhileObserver.prototype.completed = function () { this._o.onCompleted(); }; return SkipWhileObserver; }(AbstractObserver)); /** * Bypasses elements in an observable sequence as long as a specified condition is true and then returns the remaining elements. * The element's index is used in the logic of the predicate function. * * var res = source.skipWhile(function (value) { return value < 10; }); * var res = source.skipWhile(function (value, index) { return value < 10 || index < 10; }); * @param {Function} predicate A function to test each element for a condition; the second parameter of the function represents the index of the source element. * @param {Any} [thisArg] Object to use as this when executing callback. * @returns {Observable} An observable sequence that contains the elements from the input sequence starting at the first element in the linear series that does not pass the test specified by predicate. */ observableProto.skipWhile = function (predicate, thisArg) { var fn = bindCallback(predicate, thisArg, 3); return new SkipWhileObservable(this, fn); }; var TakeObservable = (function(__super__) { inherits(TakeObservable, __super__); function TakeObservable(source, count) { this.source = source; this._count = count; __super__.call(this); } TakeObservable.prototype.subscribeCore = function (o) { return this.source.subscribe(new TakeObserver(o, this._count)); }; function TakeObserver(o, c) { this._o = o; this._c = c; this._r = c; AbstractObserver.call(this); } inherits(TakeObserver, AbstractObserver); TakeObserver.prototype.next = function (x) { if (this._r-- > 0) { this._o.onNext(x); this._r <= 0 && this._o.onCompleted(); } }; TakeObserver.prototype.error = function (e) { this._o.onError(e); }; TakeObserver.prototype.completed = function () { this._o.onCompleted(); }; return TakeObservable; }(ObservableBase)); /** * Returns a specified number of contiguous elements from the start of an observable sequence, using the specified scheduler for the edge case of take(0). * @param {Number} count The number of elements to return. * @param {Scheduler} [scheduler] Scheduler used to produce an OnCompleted message in case