'use strict'; /** * @license Angular v12.0.0-next.0 * (c) 2010-2020 Google LLC. https://angular.io/ * License: MIT */ /** * @license * Copyright Google LLC All Rights Reserved. * * Use of this source code is governed by an MIT-style license that can be * found in the LICENSE file at https://angular.io/license */ (function (global) { const OriginalDate = global.Date; // Since when we compile this file to `es2015`, and if we define // this `FakeDate` as `class FakeDate`, and then set `FakeDate.prototype` // there will be an error which is `Cannot assign to read only property 'prototype'` // so we need to use function implementation here. function FakeDate() { if (arguments.length === 0) { const d = new OriginalDate(); d.setTime(FakeDate.now()); return d; } else { const args = Array.prototype.slice.call(arguments); return new OriginalDate(...args); } } FakeDate.now = function () { const fakeAsyncTestZoneSpec = Zone.current.get('FakeAsyncTestZoneSpec'); if (fakeAsyncTestZoneSpec) { return fakeAsyncTestZoneSpec.getFakeSystemTime(); } return OriginalDate.now.apply(this, arguments); }; FakeDate.UTC = OriginalDate.UTC; FakeDate.parse = OriginalDate.parse; // keep a reference for zone patched timer function const timers = { setTimeout: global.setTimeout, setInterval: global.setInterval, clearTimeout: global.clearTimeout, clearInterval: global.clearInterval }; class Scheduler { constructor() { // Scheduler queue with the tuple of end time and callback function - sorted by end time. this._schedulerQueue = []; // Current simulated time in millis. this._currentTickTime = 0; // Current fake system base time in millis. this._currentFakeBaseSystemTime = OriginalDate.now(); // track requeuePeriodicTimer this._currentTickRequeuePeriodicEntries = []; } getCurrentTickTime() { return this._currentTickTime; } getFakeSystemTime() { return this._currentFakeBaseSystemTime + this._currentTickTime; } setFakeBaseSystemTime(fakeBaseSystemTime) { this._currentFakeBaseSystemTime = fakeBaseSystemTime; } getRealSystemTime() { return OriginalDate.now(); } scheduleFunction(cb, delay, options) { options = Object.assign({ args: [], isPeriodic: false, isRequestAnimationFrame: false, id: -1, isRequeuePeriodic: false }, options); let currentId = options.id < 0 ? Scheduler.nextId++ : options.id; let endTime = this._currentTickTime + delay; // Insert so that scheduler queue remains sorted by end time. let newEntry = { endTime: endTime, id: currentId, func: cb, args: options.args, delay: delay, isPeriodic: options.isPeriodic, isRequestAnimationFrame: options.isRequestAnimationFrame }; if (options.isRequeuePeriodic) { this._currentTickRequeuePeriodicEntries.push(newEntry); } let i = 0; for (; i < this._schedulerQueue.length; i++) { let currentEntry = this._schedulerQueue[i]; if (newEntry.endTime < currentEntry.endTime) { break; } } this._schedulerQueue.splice(i, 0, newEntry); return currentId; } removeScheduledFunctionWithId(id) { for (let i = 0; i < this._schedulerQueue.length; i++) { if (this._schedulerQueue[i].id == id) { this._schedulerQueue.splice(i, 1); break; } } } removeAll() { this._schedulerQueue = []; } getTimerCount() { return this._schedulerQueue.length; } tickToNext(step = 1, doTick, tickOptions) { if (this._schedulerQueue.length < step) { return; } // Find the last task currently queued in the scheduler queue and tick // till that time. const startTime = this._currentTickTime; const targetTask = this._schedulerQueue[step - 1]; this.tick(targetTask.endTime - startTime, doTick, tickOptions); } tick(millis = 0, doTick, tickOptions) { let finalTime = this._currentTickTime + millis; let lastCurrentTime = 0; tickOptions = Object.assign({ processNewMacroTasksSynchronously: true }, tickOptions); // we need to copy the schedulerQueue so nested timeout // will not be wrongly called in the current tick // https://github.com/angular/angular/issues/33799 const schedulerQueue = tickOptions.processNewMacroTasksSynchronously ? this._schedulerQueue : this._schedulerQueue.slice(); if (schedulerQueue.length === 0 && doTick) { doTick(millis); return; } while (schedulerQueue.length > 0) { // clear requeueEntries before each loop this._currentTickRequeuePeriodicEntries = []; let current = schedulerQueue[0]; if (finalTime < current.endTime) { // Done processing the queue since it's sorted by endTime. break; } else { // Time to run scheduled function. Remove it from the head of queue. let current = schedulerQueue.shift(); if (!tickOptions.processNewMacroTasksSynchronously) { const idx = this._schedulerQueue.indexOf(current); if (idx >= 0) { this._schedulerQueue.splice(idx, 1); } } lastCurrentTime = this._currentTickTime; this._currentTickTime = current.endTime; if (doTick) { doTick(this._currentTickTime - lastCurrentTime); } let retval = current.func.apply(global, current.isRequestAnimationFrame ? [this._currentTickTime] : current.args); if (!retval) { // Uncaught exception in the current scheduled function. Stop processing the queue. break; } // check is there any requeue periodic entry is added in // current loop, if there is, we need to add to current loop if (!tickOptions.processNewMacroTasksSynchronously) { this._currentTickRequeuePeriodicEntries.forEach(newEntry => { let i = 0; for (; i < schedulerQueue.length; i++) { const currentEntry = schedulerQueue[i]; if (newEntry.endTime < currentEntry.endTime) { break; } } schedulerQueue.splice(i, 0, newEntry); }); } } } lastCurrentTime = this._currentTickTime; this._currentTickTime = finalTime; if (doTick) { doTick(this._currentTickTime - lastCurrentTime); } } flushOnlyPendingTimers(doTick) { if (this._schedulerQueue.length === 0) { return 0; } // Find the last task currently queued in the scheduler queue and tick // till that time. const startTime = this._currentTickTime; const lastTask = this._schedulerQueue[this._schedulerQueue.length - 1]; this.tick(lastTask.endTime - startTime, doTick, { processNewMacroTasksSynchronously: false }); return this._currentTickTime - startTime; } flush(limit = 20, flushPeriodic = false, doTick) { if (flushPeriodic) { return this.flushPeriodic(doTick); } else { return this.flushNonPeriodic(limit, doTick); } } flushPeriodic(doTick) { if (this._schedulerQueue.length === 0) { return 0; } // Find the last task currently queued in the scheduler queue and tick // till that time. const startTime = this._currentTickTime; const lastTask = this._schedulerQueue[this._schedulerQueue.length - 1]; this.tick(lastTask.endTime - startTime, doTick); return this._currentTickTime - startTime; } flushNonPeriodic(limit, doTick) { const startTime = this._currentTickTime; let lastCurrentTime = 0; let count = 0; while (this._schedulerQueue.length > 0) { count++; if (count > limit) { throw new Error('flush failed after reaching the limit of ' + limit + ' tasks. Does your code use a polling timeout?'); } // flush only non-periodic timers. // If the only remaining tasks are periodic(or requestAnimationFrame), finish flushing. if (this._schedulerQueue.filter(task => !task.isPeriodic && !task.isRequestAnimationFrame) .length === 0) { break; } const current = this._schedulerQueue.shift(); lastCurrentTime = this._currentTickTime; this._currentTickTime = current.endTime; if (doTick) { // Update any secondary schedulers like Jasmine mock Date. doTick(this._currentTickTime - lastCurrentTime); } const retval = current.func.apply(global, current.args); if (!retval) { // Uncaught exception in the current scheduled function. Stop processing the queue. break; } } return this._currentTickTime - startTime; } } // Next scheduler id. Scheduler.nextId = 1; class FakeAsyncTestZoneSpec { constructor(namePrefix, trackPendingRequestAnimationFrame = false, macroTaskOptions) { this.trackPendingRequestAnimationFrame = trackPendingRequestAnimationFrame; this.macroTaskOptions = macroTaskOptions; this._scheduler = new Scheduler(); this._microtasks = []; this._lastError = null; this._uncaughtPromiseErrors = Promise[Zone.__symbol__('uncaughtPromiseErrors')]; this.pendingPeriodicTimers = []; this.pendingTimers = []; this.patchDateLocked = false; this.properties = { 'FakeAsyncTestZoneSpec': this }; this.name = 'fakeAsyncTestZone for ' + namePrefix; // in case user can't access the construction of FakeAsyncTestSpec // user can also define macroTaskOptions by define a global variable. if (!this.macroTaskOptions) { this.macroTaskOptions = global[Zone.__symbol__('FakeAsyncTestMacroTask')]; } } static assertInZone() { if (Zone.current.get('FakeAsyncTestZoneSpec') == null) { throw new Error('The code should be running in the fakeAsync zone to call this function'); } } _fnAndFlush(fn, completers) { return (...args) => { fn.apply(global, args); if (this._lastError === null) { // Success if (completers.onSuccess != null) { completers.onSuccess.apply(global); } // Flush microtasks only on success. this.flushMicrotasks(); } else { // Failure if (completers.onError != null) { completers.onError.apply(global); } } // Return true if there were no errors, false otherwise. return this._lastError === null; }; } static _removeTimer(timers, id) { let index = timers.indexOf(id); if (index > -1) { timers.splice(index, 1); } } _dequeueTimer(id) { return () => { FakeAsyncTestZoneSpec._removeTimer(this.pendingTimers, id); }; } _requeuePeriodicTimer(fn, interval, args, id) { return () => { // Requeue the timer callback if it's not been canceled. if (this.pendingPeriodicTimers.indexOf(id) !== -1) { this._scheduler.scheduleFunction(fn, interval, { args, isPeriodic: true, id, isRequeuePeriodic: true }); } }; } _dequeuePeriodicTimer(id) { return () => { FakeAsyncTestZoneSpec._removeTimer(this.pendingPeriodicTimers, id); }; } _setTimeout(fn, delay, args, isTimer = true) { let removeTimerFn = this._dequeueTimer(Scheduler.nextId); // Queue the callback and dequeue the timer on success and error. let cb = this._fnAndFlush(fn, { onSuccess: removeTimerFn, onError: removeTimerFn }); let id = this._scheduler.scheduleFunction(cb, delay, { args, isRequestAnimationFrame: !isTimer }); if (isTimer) { this.pendingTimers.push(id); } return id; } _clearTimeout(id) { FakeAsyncTestZoneSpec._removeTimer(this.pendingTimers, id); this._scheduler.removeScheduledFunctionWithId(id); } _setInterval(fn, interval, args) { let id = Scheduler.nextId; let completers = { onSuccess: null, onError: this._dequeuePeriodicTimer(id) }; let cb = this._fnAndFlush(fn, completers); // Use the callback created above to requeue on success. completers.onSuccess = this._requeuePeriodicTimer(cb, interval, args, id); // Queue the callback and dequeue the periodic timer only on error. this._scheduler.scheduleFunction(cb, interval, { args, isPeriodic: true }); this.pendingPeriodicTimers.push(id); return id; } _clearInterval(id) { FakeAsyncTestZoneSpec._removeTimer(this.pendingPeriodicTimers, id); this._scheduler.removeScheduledFunctionWithId(id); } _resetLastErrorAndThrow() { let error = this._lastError || this._uncaughtPromiseErrors[0]; this._uncaughtPromiseErrors.length = 0; this._lastError = null; throw error; } getCurrentTickTime() { return this._scheduler.getCurrentTickTime(); } getFakeSystemTime() { return this._scheduler.getFakeSystemTime(); } setFakeBaseSystemTime(realTime) { this._scheduler.setFakeBaseSystemTime(realTime); } getRealSystemTime() { return this._scheduler.getRealSystemTime(); } static patchDate() { if (!!global[Zone.__symbol__('disableDatePatching')]) { // we don't want to patch global Date // because in some case, global Date // is already being patched, we need to provide // an option to let user still use their // own version of Date. return; } if (global['Date'] === FakeDate) { // already patched return; } global['Date'] = FakeDate; FakeDate.prototype = OriginalDate.prototype; // try check and reset timers // because jasmine.clock().install() may // have replaced the global timer FakeAsyncTestZoneSpec.checkTimerPatch(); } static resetDate() { if (global['Date'] === FakeDate) { global['Date'] = OriginalDate; } } static checkTimerPatch() { if (global.setTimeout !== timers.setTimeout) { global.setTimeout = timers.setTimeout; global.clearTimeout = timers.clearTimeout; } if (global.setInterval !== timers.setInterval) { global.setInterval = timers.setInterval; global.clearInterval = timers.clearInterval; } } lockDatePatch() { this.patchDateLocked = true; FakeAsyncTestZoneSpec.patchDate(); } unlockDatePatch() { this.patchDateLocked = false; FakeAsyncTestZoneSpec.resetDate(); } tickToNext(steps = 1, doTick, tickOptions = { processNewMacroTasksSynchronously: true }) { if (steps <= 0) { return; } FakeAsyncTestZoneSpec.assertInZone(); this.flushMicrotasks(); this._scheduler.tickToNext(steps, doTick, tickOptions); if (this._lastError !== null) { this._resetLastErrorAndThrow(); } } tick(millis = 0, doTick, tickOptions = { processNewMacroTasksSynchronously: true }) { FakeAsyncTestZoneSpec.assertInZone(); this.flushMicrotasks(); this._scheduler.tick(millis, doTick, tickOptions); if (this._lastError !== null) { this._resetLastErrorAndThrow(); } } flushMicrotasks() { FakeAsyncTestZoneSpec.assertInZone(); const flushErrors = () => { if (this._lastError !== null || this._uncaughtPromiseErrors.length) { // If there is an error stop processing the microtask queue and rethrow the error. this._resetLastErrorAndThrow(); } }; while (this._microtasks.length > 0) { let microtask = this._microtasks.shift(); microtask.func.apply(microtask.target, microtask.args); } flushErrors(); } flush(limit, flushPeriodic, doTick) { FakeAsyncTestZoneSpec.assertInZone(); this.flushMicrotasks(); const elapsed = this._scheduler.flush(limit, flushPeriodic, doTick); if (this._lastError !== null) { this._resetLastErrorAndThrow(); } return elapsed; } flushOnlyPendingTimers(doTick) { FakeAsyncTestZoneSpec.assertInZone(); this.flushMicrotasks(); const elapsed = this._scheduler.flushOnlyPendingTimers(doTick); if (this._lastError !== null) { this._resetLastErrorAndThrow(); } return elapsed; } removeAllTimers() { FakeAsyncTestZoneSpec.assertInZone(); this._scheduler.removeAll(); this.pendingPeriodicTimers = []; this.pendingTimers = []; } getTimerCount() { return this._scheduler.getTimerCount() + this._microtasks.length; } onScheduleTask(delegate, current, target, task) { switch (task.type) { case 'microTask': let args = task.data && task.data.args; // should pass additional arguments to callback if have any // currently we know process.nextTick will have such additional // arguments let additionalArgs; if (args) { let callbackIndex = task.data.cbIdx; if (typeof args.length === 'number' && args.length > callbackIndex + 1) { additionalArgs = Array.prototype.slice.call(args, callbackIndex + 1); } } this._microtasks.push({ func: task.invoke, args: additionalArgs, target: task.data && task.data.target }); break; case 'macroTask': switch (task.source) { case 'setTimeout': task.data['handleId'] = this._setTimeout(task.invoke, task.data['delay'], Array.prototype.slice.call(task.data['args'], 2)); break; case 'setImmediate': task.data['handleId'] = this._setTimeout(task.invoke, 0, Array.prototype.slice.call(task.data['args'], 1)); break; case 'setInterval': task.data['handleId'] = this._setInterval(task.invoke, task.data['delay'], Array.prototype.slice.call(task.data['args'], 2)); break; case 'XMLHttpRequest.send': throw new Error('Cannot make XHRs from within a fake async test. Request URL: ' + task.data['url']); case 'requestAnimationFrame': case 'webkitRequestAnimationFrame': case 'mozRequestAnimationFrame': // Simulate a requestAnimationFrame by using a setTimeout with 16 ms. // (60 frames per second) task.data['handleId'] = this._setTimeout(task.invoke, 16, task.data['args'], this.trackPendingRequestAnimationFrame); break; default: // user can define which macroTask they want to support by passing // macroTaskOptions const macroTaskOption = this.findMacroTaskOption(task); if (macroTaskOption) { const args = task.data && task.data['args']; const delay = args && args.length > 1 ? args[1] : 0; let callbackArgs = macroTaskOption.callbackArgs ? macroTaskOption.callbackArgs : args; if (!!macroTaskOption.isPeriodic) { // periodic macroTask, use setInterval to simulate task.data['handleId'] = this._setInterval(task.invoke, delay, callbackArgs); task.data.isPeriodic = true; } else { // not periodic, use setTimeout to simulate task.data['handleId'] = this._setTimeout(task.invoke, delay, callbackArgs); } break; } throw new Error('Unknown macroTask scheduled in fake async test: ' + task.source); } break; case 'eventTask': task = delegate.scheduleTask(target, task); break; } return task; } onCancelTask(delegate, current, target, task) { switch (task.source) { case 'setTimeout': case 'requestAnimationFrame': case 'webkitRequestAnimationFrame': case 'mozRequestAnimationFrame': return this._clearTimeout(task.data['handleId']); case 'setInterval': return this._clearInterval(task.data['handleId']); default: // user can define which macroTask they want to support by passing // macroTaskOptions const macroTaskOption = this.findMacroTaskOption(task); if (macroTaskOption) { const handleId = task.data['handleId']; return macroTaskOption.isPeriodic ? this._clearInterval(handleId) : this._clearTimeout(handleId); } return delegate.cancelTask(target, task); } } onInvoke(delegate, current, target, callback, applyThis, applyArgs, source) { try { FakeAsyncTestZoneSpec.patchDate(); return delegate.invoke(target, callback, applyThis, applyArgs, source); } finally { if (!this.patchDateLocked) { FakeAsyncTestZoneSpec.resetDate(); } } } findMacroTaskOption(task) { if (!this.macroTaskOptions) { return null; } for (let i = 0; i < this.macroTaskOptions.length; i++) { const macroTaskOption = this.macroTaskOptions[i]; if (macroTaskOption.source === task.source) { return macroTaskOption; } } return null; } onHandleError(parentZoneDelegate, currentZone, targetZone, error) { this._lastError = error; return false; // Don't propagate error to parent zone. } } // Export the class so that new instances can be created with proper // constructor params. Zone['FakeAsyncTestZoneSpec'] = FakeAsyncTestZoneSpec; })(typeof window === 'object' && window || typeof self === 'object' && self || global); Zone.__load_patch('fakeasync', (global, Zone, api) => { const FakeAsyncTestZoneSpec = Zone && Zone['FakeAsyncTestZoneSpec']; function getProxyZoneSpec() { return Zone && Zone['ProxyZoneSpec']; } let _fakeAsyncTestZoneSpec = null; /** * Clears out the shared fake async zone for a test. * To be called in a global `beforeEach`. * * @experimental */ function resetFakeAsyncZone() { if (_fakeAsyncTestZoneSpec) { _fakeAsyncTestZoneSpec.unlockDatePatch(); } _fakeAsyncTestZoneSpec = null; // in node.js testing we may not have ProxyZoneSpec in which case there is nothing to reset. getProxyZoneSpec() && getProxyZoneSpec().assertPresent().resetDelegate(); } /** * Wraps a function to be executed in the fakeAsync zone: * - microtasks are manually executed by calling `flushMicrotasks()`, * - timers are synchronous, `tick()` simulates the asynchronous passage of time. * * If there are any pending timers at the end of the function, an exception will be thrown. * * Can be used to wrap inject() calls. * * ## Example * * {@example core/testing/ts/fake_async.ts region='basic'} * * @param fn * @returns The function wrapped to be executed in the fakeAsync zone * * @experimental */ function fakeAsync(fn) { // Not using an arrow function to preserve context passed from call site const fakeAsyncFn = function (...args) { const ProxyZoneSpec = getProxyZoneSpec(); if (!ProxyZoneSpec) { throw new Error('ProxyZoneSpec is needed for the async() test helper but could not be found. ' + 'Please make sure that your environment includes zone.js/dist/proxy.js'); } const proxyZoneSpec = ProxyZoneSpec.assertPresent(); if (Zone.current.get('FakeAsyncTestZoneSpec')) { throw new Error('fakeAsync() calls can not be nested'); } try { // in case jasmine.clock init a fakeAsyncTestZoneSpec if (!_fakeAsyncTestZoneSpec) { if (proxyZoneSpec.getDelegate() instanceof FakeAsyncTestZoneSpec) { throw new Error('fakeAsync() calls can not be nested'); } _fakeAsyncTestZoneSpec = new FakeAsyncTestZoneSpec(); } let res; const lastProxyZoneSpec = proxyZoneSpec.getDelegate(); proxyZoneSpec.setDelegate(_fakeAsyncTestZoneSpec); _fakeAsyncTestZoneSpec.lockDatePatch(); try { res = fn.apply(this, args); flushMicrotasks(); } finally { proxyZoneSpec.setDelegate(lastProxyZoneSpec); } if (_fakeAsyncTestZoneSpec.pendingPeriodicTimers.length > 0) { throw new Error(`${_fakeAsyncTestZoneSpec.pendingPeriodicTimers.length} ` + `periodic timer(s) still in the queue.`); } if (_fakeAsyncTestZoneSpec.pendingTimers.length > 0) { throw new Error(`${_fakeAsyncTestZoneSpec.pendingTimers.length} timer(s) still in the queue.`); } return res; } finally { resetFakeAsyncZone(); } }; fakeAsyncFn.isFakeAsync = true; return fakeAsyncFn; } function _getFakeAsyncZoneSpec() { if (_fakeAsyncTestZoneSpec == null) { _fakeAsyncTestZoneSpec = Zone.current.get('FakeAsyncTestZoneSpec'); if (_fakeAsyncTestZoneSpec == null) { throw new Error('The code should be running in the fakeAsync zone to call this function'); } } return _fakeAsyncTestZoneSpec; } /** * Simulates the asynchronous passage of time for the timers in the fakeAsync zone. * * The microtasks queue is drained at the very start of this function and after any timer callback * has been executed. * * ## Example * * {@example core/testing/ts/fake_async.ts region='basic'} * * @experimental */ function tick(millis = 0, ignoreNestedTimeout = false) { _getFakeAsyncZoneSpec().tick(millis, null, ignoreNestedTimeout); } /** * Simulates the asynchronous passage of time for the timers in the fakeAsync zone by * draining the macrotask queue until it is empty. The returned value is the milliseconds * of time that would have been elapsed. * * @param maxTurns * @returns The simulated time elapsed, in millis. * * @experimental */ function flush(maxTurns) { return _getFakeAsyncZoneSpec().flush(maxTurns); } /** * Discard all remaining periodic tasks. * * @experimental */ function discardPeriodicTasks() { const zoneSpec = _getFakeAsyncZoneSpec(); const pendingTimers = zoneSpec.pendingPeriodicTimers; zoneSpec.pendingPeriodicTimers.length = 0; } /** * Flush any pending microtasks. * * @experimental */ function flushMicrotasks() { _getFakeAsyncZoneSpec().flushMicrotasks(); } Zone[api.symbol('fakeAsyncTest')] = { resetFakeAsyncZone, flushMicrotasks, discardPeriodicTasks, tick, flush, fakeAsync }; }, true);