source: trip-planner-front/node_modules/zone.js/dist/zone.js.d.ts@ 59329aa

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[6a3a178]1/**
2 * @license
3 * Copyright Google LLC All Rights Reserved.
4 *
5 * Use of this source code is governed by an MIT-style license that can be
6 * found in the LICENSE file at https://angular.io/license
7 */
8/// <amd-module name="angular/packages/zone.js/lib/zone" />
9/**
10 * Suppress closure compiler errors about unknown 'global' variable
11 * @fileoverview
12 * @suppress {undefinedVars}
13 */
14/**
15 * Zone is a mechanism for intercepting and keeping track of asynchronous work.
16 *
17 * A Zone is a global object which is configured with rules about how to intercept and keep track
18 * of the asynchronous callbacks. Zone has these responsibilities:
19 *
20 * 1. Intercept asynchronous task scheduling
21 * 2. Wrap callbacks for error-handling and zone tracking across async operations.
22 * 3. Provide a way to attach data to zones
23 * 4. Provide a context specific last frame error handling
24 * 5. (Intercept blocking methods)
25 *
26 * A zone by itself does not do anything, instead it relies on some other code to route existing
27 * platform API through it. (The zone library ships with code which monkey patches all of the
28 * browsers's asynchronous API and redirects them through the zone for interception.)
29 *
30 * In its simplest form a zone allows one to intercept the scheduling and calling of asynchronous
31 * operations, and execute additional code before as well as after the asynchronous task. The rules
32 * of interception are configured using [ZoneConfig]. There can be many different zone instances in
33 * a system, but only one zone is active at any given time which can be retrieved using
34 * [Zone#current].
35 *
36 *
37 *
38 * ## Callback Wrapping
39 *
40 * An important aspect of the zones is that they should persist across asynchronous operations. To
41 * achieve this, when a future work is scheduled through async API, it is necessary to capture, and
42 * subsequently restore the current zone. For example if a code is running in zone `b` and it
43 * invokes `setTimeout` to scheduleTask work later, the `setTimeout` method needs to 1) capture the
44 * current zone and 2) wrap the `wrapCallback` in code which will restore the current zone `b` once
45 * the wrapCallback executes. In this way the rules which govern the current code are preserved in
46 * all future asynchronous tasks. There could be a different zone `c` which has different rules and
47 * is associated with different asynchronous tasks. As these tasks are processed, each asynchronous
48 * wrapCallback correctly restores the correct zone, as well as preserves the zone for future
49 * asynchronous callbacks.
50 *
51 * Example: Suppose a browser page consist of application code as well as third-party
52 * advertisement code. (These two code bases are independent, developed by different mutually
53 * unaware developers.) The application code may be interested in doing global error handling and
54 * so it configures the `app` zone to send all of the errors to the server for analysis, and then
55 * executes the application in the `app` zone. The advertising code is interested in the same
56 * error processing but it needs to send the errors to a different third-party. So it creates the
57 * `ads` zone with a different error handler. Now both advertising as well as application code
58 * create many asynchronous operations, but the [Zone] will ensure that all of the asynchronous
59 * operations created from the application code will execute in `app` zone with its error
60 * handler and all of the advertisement code will execute in the `ads` zone with its error handler.
61 * This will not only work for the async operations created directly, but also for all subsequent
62 * asynchronous operations.
63 *
64 * If you think of chain of asynchronous operations as a thread of execution (bit of a stretch)
65 * then [Zone#current] will act as a thread local variable.
66 *
67 *
68 *
69 * ## Asynchronous operation scheduling
70 *
71 * In addition to wrapping the callbacks to restore the zone, all operations which cause a
72 * scheduling of work for later are routed through the current zone which is allowed to intercept
73 * them by adding work before or after the wrapCallback as well as using different means of
74 * achieving the request. (Useful for unit testing, or tracking of requests). In some instances
75 * such as `setTimeout` the wrapping of the wrapCallback and scheduling is done in the same
76 * wrapCallback, but there are other examples such as `Promises` where the `then` wrapCallback is
77 * wrapped, but the execution of `then` is triggered by `Promise` scheduling `resolve` work.
78 *
79 * Fundamentally there are three kinds of tasks which can be scheduled:
80 *
81 * 1. [MicroTask] used for doing work right after the current task. This is non-cancelable which is
82 * guaranteed to run exactly once and immediately.
83 * 2. [MacroTask] used for doing work later. Such as `setTimeout`. This is typically cancelable
84 * which is guaranteed to execute at least once after some well understood delay.
85 * 3. [EventTask] used for listening on some future event. This may execute zero or more times, with
86 * an unknown delay.
87 *
88 * Each asynchronous API is modeled and routed through one of these APIs.
89 *
90 *
91 * ### [MicroTask]
92 *
93 * [MicroTask]s represent work which will be done in current VM turn as soon as possible, before VM
94 * yielding.
95 *
96 *
97 * ### [MacroTask]
98 *
99 * [MacroTask]s represent work which will be done after some delay. (Sometimes the delay is
100 * approximate such as on next available animation frame). Typically these methods include:
101 * `setTimeout`, `setImmediate`, `setInterval`, `requestAnimationFrame`, and all browser specific
102 * variants.
103 *
104 *
105 * ### [EventTask]
106 *
107 * [EventTask]s represent a request to create a listener on an event. Unlike the other task
108 * events they may never be executed, but typically execute more than once. There is no queue of
109 * events, rather their callbacks are unpredictable both in order and time.
110 *
111 *
112 * ## Global Error Handling
113 *
114 *
115 * ## Composability
116 *
117 * Zones can be composed together through [Zone.fork()]. A child zone may create its own set of
118 * rules. A child zone is expected to either:
119 *
120 * 1. Delegate the interception to a parent zone, and optionally add before and after wrapCallback
121 * hooks.
122 * 2. Process the request itself without delegation.
123 *
124 * Composability allows zones to keep their concerns clean. For example a top most zone may choose
125 * to handle error handling, while child zones may choose to do user action tracking.
126 *
127 *
128 * ## Root Zone
129 *
130 * At the start the browser will run in a special root zone, which is configured to behave exactly
131 * like the platform, making any existing code which is not zone-aware behave as expected. All
132 * zones are children of the root zone.
133 *
134 */
135interface Zone {
136 /**
137 *
138 * @returns {Zone} The parent Zone.
139 */
140 parent: Zone | null;
141 /**
142 * @returns {string} The Zone name (useful for debugging)
143 */
144 name: string;
145 /**
146 * Returns a value associated with the `key`.
147 *
148 * If the current zone does not have a key, the request is delegated to the parent zone. Use
149 * [ZoneSpec.properties] to configure the set of properties associated with the current zone.
150 *
151 * @param key The key to retrieve.
152 * @returns {any} The value for the key, or `undefined` if not found.
153 */
154 get(key: string): any;
155 /**
156 * Returns a Zone which defines a `key`.
157 *
158 * Recursively search the parent Zone until a Zone which has a property `key` is found.
159 *
160 * @param key The key to use for identification of the returned zone.
161 * @returns {Zone} The Zone which defines the `key`, `null` if not found.
162 */
163 getZoneWith(key: string): Zone | null;
164 /**
165 * Used to create a child zone.
166 *
167 * @param zoneSpec A set of rules which the child zone should follow.
168 * @returns {Zone} A new child zone.
169 */
170 fork(zoneSpec: ZoneSpec): Zone;
171 /**
172 * Wraps a callback function in a new function which will properly restore the current zone upon
173 * invocation.
174 *
175 * The wrapped function will properly forward `this` as well as `arguments` to the `callback`.
176 *
177 * Before the function is wrapped the zone can intercept the `callback` by declaring
178 * [ZoneSpec.onIntercept].
179 *
180 * @param callback the function which will be wrapped in the zone.
181 * @param source A unique debug location of the API being wrapped.
182 * @returns {function(): *} A function which will invoke the `callback` through [Zone.runGuarded].
183 */
184 wrap<F extends Function>(callback: F, source: string): F;
185 /**
186 * Invokes a function in a given zone.
187 *
188 * The invocation of `callback` can be intercepted by declaring [ZoneSpec.onInvoke].
189 *
190 * @param callback The function to invoke.
191 * @param applyThis
192 * @param applyArgs
193 * @param source A unique debug location of the API being invoked.
194 * @returns {any} Value from the `callback` function.
195 */
196 run<T>(callback: Function, applyThis?: any, applyArgs?: any[], source?: string): T;
197 /**
198 * Invokes a function in a given zone and catches any exceptions.
199 *
200 * Any exceptions thrown will be forwarded to [Zone.HandleError].
201 *
202 * The invocation of `callback` can be intercepted by declaring [ZoneSpec.onInvoke]. The
203 * handling of exceptions can be intercepted by declaring [ZoneSpec.handleError].
204 *
205 * @param callback The function to invoke.
206 * @param applyThis
207 * @param applyArgs
208 * @param source A unique debug location of the API being invoked.
209 * @returns {any} Value from the `callback` function.
210 */
211 runGuarded<T>(callback: Function, applyThis?: any, applyArgs?: any[], source?: string): T;
212 /**
213 * Execute the Task by restoring the [Zone.currentTask] in the Task's zone.
214 *
215 * @param task to run
216 * @param applyThis
217 * @param applyArgs
218 * @returns {any} Value from the `task.callback` function.
219 */
220 runTask<T>(task: Task, applyThis?: any, applyArgs?: any): T;
221 /**
222 * Schedule a MicroTask.
223 *
224 * @param source
225 * @param callback
226 * @param data
227 * @param customSchedule
228 */
229 scheduleMicroTask(source: string, callback: Function, data?: TaskData, customSchedule?: (task: Task) => void): MicroTask;
230 /**
231 * Schedule a MacroTask.
232 *
233 * @param source
234 * @param callback
235 * @param data
236 * @param customSchedule
237 * @param customCancel
238 */
239 scheduleMacroTask(source: string, callback: Function, data?: TaskData, customSchedule?: (task: Task) => void, customCancel?: (task: Task) => void): MacroTask;
240 /**
241 * Schedule an EventTask.
242 *
243 * @param source
244 * @param callback
245 * @param data
246 * @param customSchedule
247 * @param customCancel
248 */
249 scheduleEventTask(source: string, callback: Function, data?: TaskData, customSchedule?: (task: Task) => void, customCancel?: (task: Task) => void): EventTask;
250 /**
251 * Schedule an existing Task.
252 *
253 * Useful for rescheduling a task which was already canceled.
254 *
255 * @param task
256 */
257 scheduleTask<T extends Task>(task: T): T;
258 /**
259 * Allows the zone to intercept canceling of scheduled Task.
260 *
261 * The interception is configured using [ZoneSpec.onCancelTask]. The default canceler invokes
262 * the [Task.cancelFn].
263 *
264 * @param task
265 * @returns {any}
266 */
267 cancelTask(task: Task): any;
268}
269interface ZoneType {
270 /**
271 * @returns {Zone} Returns the current [Zone]. The only way to change
272 * the current zone is by invoking a run() method, which will update the current zone for the
273 * duration of the run method callback.
274 */
275 current: Zone;
276 /**
277 * @returns {Task} The task associated with the current execution.
278 */
279 currentTask: Task | null;
280 /**
281 * Verify that Zone has been correctly patched. Specifically that Promise is zone aware.
282 */
283 assertZonePatched(): void;
284 /**
285 * Return the root zone.
286 */
287 root: Zone;
288 /**
289 * load patch for specified native module, allow user to
290 * define their own patch, user can use this API after loading zone.js
291 */
292 __load_patch(name: string, fn: _PatchFn, ignoreDuplicate?: boolean): void;
293 /**
294 * Zone symbol API to generate a string with __zone_symbol__ prefix
295 */
296 __symbol__(name: string): string;
297}
298/**
299 * Patch Function to allow user define their own monkey patch module.
300 */
301declare type _PatchFn = (global: Window, Zone: ZoneType, api: _ZonePrivate) => void;
302/**
303 * _ZonePrivate interface to provide helper method to help user implement
304 * their own monkey patch module.
305 */
306interface _ZonePrivate {
307 currentZoneFrame: () => _ZoneFrame;
308 symbol: (name: string) => string;
309 scheduleMicroTask: (task?: MicroTask) => void;
310 onUnhandledError: (error: Error) => void;
311 microtaskDrainDone: () => void;
312 showUncaughtError: () => boolean;
313 patchEventTarget: (global: any, apis: any[], options?: any) => boolean[];
314 patchOnProperties: (obj: any, properties: string[] | null, prototype?: any) => void;
315 patchThen: (ctro: Function) => void;
316 patchMethod: (target: any, name: string, patchFn: (delegate: Function, delegateName: string, name: string) => (self: any, args: any[]) => any) => Function | null;
317 bindArguments: (args: any[], source: string) => any[];
318 patchMacroTask: (obj: any, funcName: string, metaCreator: (self: any, args: any[]) => any) => void;
319 patchEventPrototype: (_global: any, api: _ZonePrivate) => void;
320 isIEOrEdge: () => boolean;
321 ObjectDefineProperty: (o: any, p: PropertyKey, attributes: PropertyDescriptor & ThisType<any>) => any;
322 ObjectGetOwnPropertyDescriptor: (o: any, p: PropertyKey) => PropertyDescriptor | undefined;
323 ObjectCreate(o: object | null, properties?: PropertyDescriptorMap & ThisType<any>): any;
324 ArraySlice(start?: number, end?: number): any[];
325 patchClass: (className: string) => void;
326 wrapWithCurrentZone: (callback: any, source: string) => any;
327 filterProperties: (target: any, onProperties: string[], ignoreProperties: any[]) => string[];
328 attachOriginToPatched: (target: any, origin: any) => void;
329 _redefineProperty: (target: any, callback: string, desc: any) => void;
330 patchCallbacks: (api: _ZonePrivate, target: any, targetName: string, method: string, callbacks: string[]) => void;
331 getGlobalObjects: () => {
332 globalSources: any;
333 zoneSymbolEventNames: any;
334 eventNames: string[];
335 isBrowser: boolean;
336 isMix: boolean;
337 isNode: boolean;
338 TRUE_STR: string;
339 FALSE_STR: string;
340 ZONE_SYMBOL_PREFIX: string;
341 ADD_EVENT_LISTENER_STR: string;
342 REMOVE_EVENT_LISTENER_STR: string;
343 } | undefined;
344}
345/**
346 * _ZoneFrame represents zone stack frame information
347 */
348interface _ZoneFrame {
349 parent: _ZoneFrame | null;
350 zone: Zone;
351}
352interface UncaughtPromiseError extends Error {
353 zone: Zone;
354 task: Task;
355 promise: Promise<any>;
356 rejection: any;
357 throwOriginal?: boolean;
358}
359/**
360 * Provides a way to configure the interception of zone events.
361 *
362 * Only the `name` property is required (all other are optional).
363 */
364interface ZoneSpec {
365 /**
366 * The name of the zone. Useful when debugging Zones.
367 */
368 name: string;
369 /**
370 * A set of properties to be associated with Zone. Use [Zone.get] to retrieve them.
371 */
372 properties?: {
373 [key: string]: any;
374 };
375 /**
376 * Allows the interception of zone forking.
377 *
378 * When the zone is being forked, the request is forwarded to this method for interception.
379 *
380 * @param parentZoneDelegate Delegate which performs the parent [ZoneSpec] operation.
381 * @param currentZone The current [Zone] where the current interceptor has been declared.
382 * @param targetZone The [Zone] which originally received the request.
383 * @param zoneSpec The argument passed into the `fork` method.
384 */
385 onFork?: (parentZoneDelegate: ZoneDelegate, currentZone: Zone, targetZone: Zone, zoneSpec: ZoneSpec) => Zone;
386 /**
387 * Allows interception of the wrapping of the callback.
388 *
389 * @param parentZoneDelegate Delegate which performs the parent [ZoneSpec] operation.
390 * @param currentZone The current [Zone] where the current interceptor has been declared.
391 * @param targetZone The [Zone] which originally received the request.
392 * @param delegate The argument passed into the `wrap` method.
393 * @param source The argument passed into the `wrap` method.
394 */
395 onIntercept?: (parentZoneDelegate: ZoneDelegate, currentZone: Zone, targetZone: Zone, delegate: Function, source: string) => Function;
396 /**
397 * Allows interception of the callback invocation.
398 *
399 * @param parentZoneDelegate Delegate which performs the parent [ZoneSpec] operation.
400 * @param currentZone The current [Zone] where the current interceptor has been declared.
401 * @param targetZone The [Zone] which originally received the request.
402 * @param delegate The argument passed into the `run` method.
403 * @param applyThis The argument passed into the `run` method.
404 * @param applyArgs The argument passed into the `run` method.
405 * @param source The argument passed into the `run` method.
406 */
407 onInvoke?: (parentZoneDelegate: ZoneDelegate, currentZone: Zone, targetZone: Zone, delegate: Function, applyThis: any, applyArgs?: any[], source?: string) => any;
408 /**
409 * Allows interception of the error handling.
410 *
411 * @param parentZoneDelegate Delegate which performs the parent [ZoneSpec] operation.
412 * @param currentZone The current [Zone] where the current interceptor has been declared.
413 * @param targetZone The [Zone] which originally received the request.
414 * @param error The argument passed into the `handleError` method.
415 */
416 onHandleError?: (parentZoneDelegate: ZoneDelegate, currentZone: Zone, targetZone: Zone, error: any) => boolean;
417 /**
418 * Allows interception of task scheduling.
419 *
420 * @param parentZoneDelegate Delegate which performs the parent [ZoneSpec] operation.
421 * @param currentZone The current [Zone] where the current interceptor has been declared.
422 * @param targetZone The [Zone] which originally received the request.
423 * @param task The argument passed into the `scheduleTask` method.
424 */
425 onScheduleTask?: (parentZoneDelegate: ZoneDelegate, currentZone: Zone, targetZone: Zone, task: Task) => Task;
426 onInvokeTask?: (parentZoneDelegate: ZoneDelegate, currentZone: Zone, targetZone: Zone, task: Task, applyThis: any, applyArgs?: any[]) => any;
427 /**
428 * Allows interception of task cancellation.
429 *
430 * @param parentZoneDelegate Delegate which performs the parent [ZoneSpec] operation.
431 * @param currentZone The current [Zone] where the current interceptor has been declared.
432 * @param targetZone The [Zone] which originally received the request.
433 * @param task The argument passed into the `cancelTask` method.
434 */
435 onCancelTask?: (parentZoneDelegate: ZoneDelegate, currentZone: Zone, targetZone: Zone, task: Task) => any;
436 /**
437 * Notifies of changes to the task queue empty status.
438 *
439 * @param parentZoneDelegate Delegate which performs the parent [ZoneSpec] operation.
440 * @param currentZone The current [Zone] where the current interceptor has been declared.
441 * @param targetZone The [Zone] which originally received the request.
442 * @param hasTaskState
443 */
444 onHasTask?: (parentZoneDelegate: ZoneDelegate, currentZone: Zone, targetZone: Zone, hasTaskState: HasTaskState) => void;
445}
446/**
447 * A delegate when intercepting zone operations.
448 *
449 * A ZoneDelegate is needed because a child zone can't simply invoke a method on a parent zone. For
450 * example a child zone wrap can't just call parent zone wrap. Doing so would create a callback
451 * which is bound to the parent zone. What we are interested in is intercepting the callback before
452 * it is bound to any zone. Furthermore, we also need to pass the targetZone (zone which received
453 * the original request) to the delegate.
454 *
455 * The ZoneDelegate methods mirror those of Zone with an addition of extra targetZone argument in
456 * the method signature. (The original Zone which received the request.) Some methods are renamed
457 * to prevent confusion, because they have slightly different semantics and arguments.
458 *
459 * - `wrap` => `intercept`: The `wrap` method delegates to `intercept`. The `wrap` method returns
460 * a callback which will run in a given zone, where as intercept allows wrapping the callback
461 * so that additional code can be run before and after, but does not associate the callback
462 * with the zone.
463 * - `run` => `invoke`: The `run` method delegates to `invoke` to perform the actual execution of
464 * the callback. The `run` method switches to new zone; saves and restores the `Zone.current`;
465 * and optionally performs error handling. The invoke is not responsible for error handling,
466 * or zone management.
467 *
468 * Not every method is usually overwritten in the child zone, for this reason the ZoneDelegate
469 * stores the closest zone which overwrites this behavior along with the closest ZoneSpec.
470 *
471 * NOTE: We have tried to make this API analogous to Event bubbling with target and current
472 * properties.
473 *
474 * Note: The ZoneDelegate treats ZoneSpec as class. This allows the ZoneSpec to use its `this` to
475 * store internal state.
476 */
477interface ZoneDelegate {
478 zone: Zone;
479 fork(targetZone: Zone, zoneSpec: ZoneSpec): Zone;
480 intercept(targetZone: Zone, callback: Function, source: string): Function;
481 invoke(targetZone: Zone, callback: Function, applyThis?: any, applyArgs?: any[], source?: string): any;
482 handleError(targetZone: Zone, error: any): boolean;
483 scheduleTask(targetZone: Zone, task: Task): Task;
484 invokeTask(targetZone: Zone, task: Task, applyThis?: any, applyArgs?: any[]): any;
485 cancelTask(targetZone: Zone, task: Task): any;
486 hasTask(targetZone: Zone, isEmpty: HasTaskState): void;
487}
488declare type HasTaskState = {
489 microTask: boolean;
490 macroTask: boolean;
491 eventTask: boolean;
492 change: TaskType;
493};
494/**
495 * Task type: `microTask`, `macroTask`, `eventTask`.
496 */
497declare type TaskType = 'microTask' | 'macroTask' | 'eventTask';
498/**
499 * Task type: `notScheduled`, `scheduling`, `scheduled`, `running`, `canceling`, 'unknown'.
500 */
501declare type TaskState = 'notScheduled' | 'scheduling' | 'scheduled' | 'running' | 'canceling' | 'unknown';
502/**
503 */
504interface TaskData {
505 /**
506 * A periodic [MacroTask] is such which get automatically rescheduled after it is executed.
507 */
508 isPeriodic?: boolean;
509 /**
510 * Delay in milliseconds when the Task will run.
511 */
512 delay?: number;
513 /**
514 * identifier returned by the native setTimeout.
515 */
516 handleId?: number;
517}
518/**
519 * Represents work which is executed with a clean stack.
520 *
521 * Tasks are used in Zones to mark work which is performed on clean stack frame. There are three
522 * kinds of task. [MicroTask], [MacroTask], and [EventTask].
523 *
524 * A JS VM can be modeled as a [MicroTask] queue, [MacroTask] queue, and [EventTask] set.
525 *
526 * - [MicroTask] queue represents a set of tasks which are executing right after the current stack
527 * frame becomes clean and before a VM yield. All [MicroTask]s execute in order of insertion
528 * before VM yield and the next [MacroTask] is executed.
529 * - [MacroTask] queue represents a set of tasks which are executed one at a time after each VM
530 * yield. The queue is ordered by time, and insertions can happen in any location.
531 * - [EventTask] is a set of tasks which can at any time be inserted to the end of the [MacroTask]
532 * queue. This happens when the event fires.
533 *
534 */
535interface Task {
536 /**
537 * Task type: `microTask`, `macroTask`, `eventTask`.
538 */
539 type: TaskType;
540 /**
541 * Task state: `notScheduled`, `scheduling`, `scheduled`, `running`, `canceling`, `unknown`.
542 */
543 state: TaskState;
544 /**
545 * Debug string representing the API which requested the scheduling of the task.
546 */
547 source: string;
548 /**
549 * The Function to be used by the VM upon entering the [Task]. This function will delegate to
550 * [Zone.runTask] and delegate to `callback`.
551 */
552 invoke: Function;
553 /**
554 * Function which needs to be executed by the Task after the [Zone.currentTask] has been set to
555 * the current task.
556 */
557 callback: Function;
558 /**
559 * Task specific options associated with the current task. This is passed to the `scheduleFn`.
560 */
561 data?: TaskData;
562 /**
563 * Represents the default work which needs to be done to schedule the Task by the VM.
564 *
565 * A zone may choose to intercept this function and perform its own scheduling.
566 */
567 scheduleFn?: (task: Task) => void;
568 /**
569 * Represents the default work which needs to be done to un-schedule the Task from the VM. Not all
570 * Tasks are cancelable, and therefore this method is optional.
571 *
572 * A zone may chose to intercept this function and perform its own un-scheduling.
573 */
574 cancelFn?: (task: Task) => void;
575 /**
576 * @type {Zone} The zone which will be used to invoke the `callback`. The Zone is captured
577 * at the time of Task creation.
578 */
579 readonly zone: Zone;
580 /**
581 * Number of times the task has been executed, or -1 if canceled.
582 */
583 runCount: number;
584 /**
585 * Cancel the scheduling request. This method can be called from `ZoneSpec.onScheduleTask` to
586 * cancel the current scheduling interception. Once canceled the task can be discarded or
587 * rescheduled using `Zone.scheduleTask` on a different zone.
588 */
589 cancelScheduleRequest(): void;
590}
591interface MicroTask extends Task {
592 type: 'microTask';
593}
594interface MacroTask extends Task {
595 type: 'macroTask';
596}
597interface EventTask extends Task {
598 type: 'eventTask';
599}
600declare const Zone: ZoneType;
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