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denoland-deno/ext/web/02_timers.js
2022-09-22 10:05:24 +05:30

379 lines
11 KiB
JavaScript

// Copyright 2018-2022 the Deno authors. All rights reserved. MIT license.
"use strict";
((window) => {
const core = window.Deno.core;
const ops = core.ops;
const {
ArrayPrototypePush,
ArrayPrototypeShift,
FunctionPrototypeCall,
Map,
MapPrototypeDelete,
MapPrototypeGet,
MapPrototypeHas,
MapPrototypeSet,
Uint8Array,
Uint32Array,
// deno-lint-ignore camelcase
NumberPOSITIVE_INFINITY,
PromisePrototypeThen,
ObjectPrototypeIsPrototypeOf,
SafeArrayIterator,
SymbolFor,
TypeError,
indirectEval,
} = window.__bootstrap.primordials;
const { webidl } = window.__bootstrap;
const { reportException } = window.__bootstrap.event;
const { assert } = window.__bootstrap.infra;
const hrU8 = new Uint8Array(8);
const hr = new Uint32Array(hrU8.buffer);
function opNow() {
ops.op_now(hrU8);
return (hr[0] * 1000 + hr[1] / 1e6);
}
// ---------------------------------------------------------------------------
/**
* The task queue corresponding to the timer task source.
*
* @type { {action: () => void, nestingLevel: number}[] }
*/
const timerTasks = [];
/**
* The current task's timer nesting level, or zero if we're not currently
* running a timer task (since the minimum nesting level is 1).
*
* @type {number}
*/
let timerNestingLevel = 0;
function handleTimerMacrotask() {
if (timerTasks.length === 0) {
return true;
}
const task = ArrayPrototypeShift(timerTasks);
timerNestingLevel = task.nestingLevel;
try {
task.action();
} finally {
timerNestingLevel = 0;
}
return timerTasks.length === 0;
}
// ---------------------------------------------------------------------------
/**
* The keys in this map correspond to the key ID's in the spec's map of active
* timers. The values are the timeout's cancel rid.
*
* @type {Map<number, { cancelRid: number, isRef: boolean, promiseId: number }>}
*/
const activeTimers = new Map();
let nextId = 1;
/**
* @param {Function | string} callback
* @param {number} timeout
* @param {Array<any>} args
* @param {boolean} repeat
* @param {number | undefined} prevId
* @returns {number} The timer ID
*/
function initializeTimer(
callback,
timeout,
args,
repeat,
prevId,
) {
// 2. If previousId was given, let id be previousId; otherwise, let
// previousId be an implementation-defined integer than is greater than zero
// and does not already exist in global's map of active timers.
let id;
let timerInfo;
if (prevId !== undefined) {
// `prevId` is only passed for follow-up calls on intervals
assert(repeat);
id = prevId;
timerInfo = MapPrototypeGet(activeTimers, id);
} else {
// TODO(@andreubotella): Deal with overflow.
// https://github.com/whatwg/html/issues/7358
id = nextId++;
const cancelRid = ops.op_timer_handle();
timerInfo = { cancelRid, isRef: true, promiseId: -1 };
// Step 4 in "run steps after a timeout".
MapPrototypeSet(activeTimers, id, timerInfo);
}
// 3. If the surrounding agent's event loop's currently running task is a
// task that was created by this algorithm, then let nesting level be the
// task's timer nesting level. Otherwise, let nesting level be zero.
// 4. If timeout is less than 0, then set timeout to 0.
// 5. If nesting level is greater than 5, and timeout is less than 4, then
// set timeout to 4.
//
// The nesting level of 5 and minimum of 4 ms are spec-mandated magic
// constants.
if (timeout < 0) timeout = 0;
if (timerNestingLevel > 5 && timeout < 4) timeout = 4;
// 9. Let task be a task that runs the following steps:
const task = {
action: () => {
// 1. If id does not exist in global's map of active timers, then abort
// these steps.
//
// This is relevant if the timer has been canceled after the sleep op
// resolves but before this task runs.
if (!MapPrototypeHas(activeTimers, id)) {
return;
}
// 2.
// 3.
if (typeof callback === "function") {
try {
FunctionPrototypeCall(
callback,
globalThis,
...new SafeArrayIterator(args),
);
} catch (error) {
reportException(error);
}
} else {
indirectEval(callback);
}
if (repeat) {
if (MapPrototypeHas(activeTimers, id)) {
// 4. If id does not exist in global's map of active timers, then
// abort these steps.
// NOTE: If might have been removed via the author code in handler
// calling clearTimeout() or clearInterval().
// 5. If repeat is true, then perform the timer initialization steps
// again, given global, handler, timeout, arguments, true, and id.
initializeTimer(callback, timeout, args, true, id);
}
} else {
// 6. Otherwise, remove global's map of active timers[id].
core.tryClose(timerInfo.cancelRid);
MapPrototypeDelete(activeTimers, id);
}
},
// 10. Increment nesting level by one.
// 11. Set task's timer nesting level to nesting level.
nestingLevel: timerNestingLevel + 1,
};
// 12. Let completionStep be an algorithm step which queues a global task on
// the timer task source given global to run task.
// 13. Run steps after a timeout given global, "setTimeout/setInterval",
// timeout, completionStep, and id.
runAfterTimeout(
() => ArrayPrototypePush(timerTasks, task),
timeout,
timerInfo,
);
return id;
}
// ---------------------------------------------------------------------------
/**
* @typedef ScheduledTimer
* @property {number} millis
* @property {() => void} cb
* @property {boolean} resolved
* @property {ScheduledTimer | null} prev
* @property {ScheduledTimer | null} next
*/
/**
* A doubly linked list of timers.
* @type { { head: ScheduledTimer | null, tail: ScheduledTimer | null } }
*/
const scheduledTimers = { head: null, tail: null };
/**
* @param {() => void} cb Will be run after the timeout, if it hasn't been
* cancelled.
* @param {number} millis
* @param {{ cancelRid: number, isRef: boolean, promiseId: number }} timerInfo
*/
function runAfterTimeout(cb, millis, timerInfo) {
const cancelRid = timerInfo.cancelRid;
const sleepPromise = core.opAsync("op_sleep", millis, cancelRid);
timerInfo.promiseId =
sleepPromise[SymbolFor("Deno.core.internalPromiseId")];
if (!timerInfo.isRef) {
core.unrefOp(timerInfo.promiseId);
}
/** @type {ScheduledTimer} */
const timerObject = {
millis,
cb,
resolved: false,
prev: scheduledTimers.tail,
next: null,
};
// Add timerObject to the end of the list.
if (scheduledTimers.tail === null) {
assert(scheduledTimers.head === null);
scheduledTimers.head = scheduledTimers.tail = timerObject;
} else {
scheduledTimers.tail.next = timerObject;
scheduledTimers.tail = timerObject;
}
// 1.
PromisePrototypeThen(
sleepPromise,
() => {
// 2. Wait until any invocations of this algorithm that had the same
// global and orderingIdentifier, that started before this one, and
// whose milliseconds is equal to or less than this one's, have
// completed.
// 4. Perform completionSteps.
// IMPORTANT: Since the sleep ops aren't guaranteed to resolve in the
// right order, whenever one resolves, we run through the scheduled
// timers list (which is in the order in which they were scheduled), and
// we call the callback for every timer which both:
// a) has resolved, and
// b) its timeout is lower than the lowest unresolved timeout found so
// far in the list.
timerObject.resolved = true;
let lowestUnresolvedTimeout = NumberPOSITIVE_INFINITY;
let currentEntry = scheduledTimers.head;
while (currentEntry !== null) {
if (currentEntry.millis < lowestUnresolvedTimeout) {
if (currentEntry.resolved) {
currentEntry.cb();
removeFromScheduledTimers(currentEntry);
} else {
lowestUnresolvedTimeout = currentEntry.millis;
}
}
currentEntry = currentEntry.next;
}
},
(err) => {
if (ObjectPrototypeIsPrototypeOf(core.InterruptedPrototype, err)) {
// The timer was cancelled.
removeFromScheduledTimers(timerObject);
} else {
throw err;
}
},
);
}
/** @param {ScheduledTimer} timerObj */
function removeFromScheduledTimers(timerObj) {
if (timerObj.prev !== null) {
timerObj.prev.next = timerObj.next;
} else {
assert(scheduledTimers.head === timerObj);
scheduledTimers.head = timerObj.next;
}
if (timerObj.next !== null) {
timerObj.next.prev = timerObj.prev;
} else {
assert(scheduledTimers.tail === timerObj);
scheduledTimers.tail = timerObj.prev;
}
}
// ---------------------------------------------------------------------------
function checkThis(thisArg) {
if (thisArg !== null && thisArg !== undefined && thisArg !== globalThis) {
throw new TypeError("Illegal invocation");
}
}
function setTimeout(callback, timeout = 0, ...args) {
checkThis(this);
if (typeof callback !== "function") {
callback = webidl.converters.DOMString(callback);
}
timeout = webidl.converters.long(timeout);
return initializeTimer(callback, timeout, args, false);
}
function setInterval(callback, timeout = 0, ...args) {
checkThis(this);
if (typeof callback !== "function") {
callback = webidl.converters.DOMString(callback);
}
timeout = webidl.converters.long(timeout);
return initializeTimer(callback, timeout, args, true);
}
function clearTimeout(id = 0) {
checkThis(this);
id = webidl.converters.long(id);
const timerInfo = MapPrototypeGet(activeTimers, id);
if (timerInfo !== undefined) {
core.tryClose(timerInfo.cancelRid);
MapPrototypeDelete(activeTimers, id);
}
}
function clearInterval(id = 0) {
checkThis(this);
clearTimeout(id);
}
function refTimer(id) {
const timerInfo = MapPrototypeGet(activeTimers, id);
if (timerInfo === undefined || timerInfo.isRef) {
return;
}
timerInfo.isRef = true;
core.refOp(timerInfo.promiseId);
}
function unrefTimer(id) {
const timerInfo = MapPrototypeGet(activeTimers, id);
if (timerInfo === undefined || !timerInfo.isRef) {
return;
}
timerInfo.isRef = false;
core.unrefOp(timerInfo.promiseId);
}
window.__bootstrap.timers = {
setTimeout,
setInterval,
clearTimeout,
clearInterval,
handleTimerMacrotask,
opNow,
refTimer,
unrefTimer,
};
})(this);