Skip to content

Latest commit

 

History

History
250 lines (196 loc) · 8.28 KB

README.md

File metadata and controls

250 lines (196 loc) · 8.28 KB

priority-task

Helps running tasks based on priority without having to deal with implementing a priority queue from scratch. additionally, provides a utility to update the priority at runtime, as well as, pause, resume and abort task execution.

Tests Coveralls

Using priority-task you need to only create the tasks, assign them priority, and run them. priority-task will take care of running them in order.

Time Complexity

This util generally runs in O(log n) time complexity, meaning most common operations run in O(log n) time complexity, here is a breakdown of each operation and it's time complexity:

operation time complexity
create a new task O(log n)
internally run highest priority O(log n)
update priority O(log n)
pause O(1)
resume O(log n)
cancel/abort O(1)

Note to be able to have O(log n) time complexity for update priority and pause operations, a tag is used to mark invalid items in the heap, and re-insert them later. This means that the heap can have duplicates, causing increased memory consumption; however, for most practical uses this is ignorable.

Installing the package

using npm

npm i priority-task

using yarn

yarn add priority-task

Usage

Running tasks

You need to only create PTask objects; assign them a priority, a function to run, and a value to pass to the function; then call PTask.run() method. PTask.run() method returns a promise which will resolve to the output of the function passed to onRun option.

import { PTask } from "priority-task";

// Prepare tasks
const task1 = new PTask<number, number>({
    priority: 1,
    onRun: async (a: number) => a, // The function to run
    args: 1, // The value to be passed to the function
});

const task2 = new PTask<number, number>({
    priority: 2,
    onRun: async (a: number) => a,
    args: 2,
});

const task3 = new PTask<number, number>({
    priority: 3,
    onRun: async (a: number) => a,
    args: 3,
});

const res = [];
const p2 = task2.run().then((val) => res.push(val));
const p1 = task1.run().then((val) => res.push(val));
const p3 = task3.run().then((val) => res.push(val));

Promise.all([p1, p2, p3]).then(() => {
    console.log(res); // [3, 2, 1]
});

Pausing and resuming tasks

To be able to pause a task, the task needs to accept a second parameter. the second parameter will have methods to learn the current execution stage of the task, namely paused or canceled. The task also should have a mechanism to pause execution. An example would be a task that is processing some array elements, it can check the current stage of execution before processing the next element.

// The function to execute
const calculateSquares = async (nums: number[], execInfo: ExecInfo) => {
    const squares = [];
    const iter = async (i: number, num: number) => {
    if (i === nums.length) return;

    squares.push(num * num);
    await new Promise(r => setTimeout(r, 20));
    // Checking if the task was paused. If paused will stop execution
    // and return the results obtained so far.
    if (!execInfo.isPaused()) await iter(++i, nums[i]);
    };

    await iter(0, nums[0]);
    return squares;
};

const task = new PTask<number[], number[]>({
    args: [1, 2, 3, 4, 5, 6],
    priority: 1,
    onRun: calculateSquares,
    // This optional function will be called after the task was paused
    // with the currently available arguments and the results obtained
    // so far. The return of this function will be used as the argument
    // for the calculateSquares function, when execution is resumed.
    onPause: (args, resSoFar) => {
        // If no results obtained so far, return the same arguments
        if (!resSoFar) return args;

        // Based on the length of the results array,
        // remove some items from the argumets
        return args.slice(resSoFar.length);
    },
    // When resuming the execution, calculateSquares will have a subset of
    // the original argument; hence will produce a subset of final result.
    // This function is used to merge the previously obtained results with
    // the new subset
    resultsMerge: (resSoFar, newRes) => {
    if (!resSoFar) return newRes;
    return resSoFar.concat(newRes);
    }
});

task.run().then((res) => {
    console.log(res); // [1, 4, 9, 16, 25, 36]
});

setTimeout(async () => {
    await task.pause();
    task.resume();
}, 20);

Canceling tasks

A task can be canceled only if it hasn't yet started execution using PTask.cancel(). When a task is canceled, PTask.run() will throw 'Task canceled' error.

const task = new PTask<void, void>({
    args: null,
    priority: 1,
    onRun: async () => await new Promise((resolve) => setTimeout(resolve, 500))
});

task.run().catch((err) => {
    console.log(err.message); // 'Task canceled'
});

task.cancel();

Aborting running tasks

Using PTask.cancel({abort: true}), the task will be aborted even if it was running or paused. however, for running tasks, similar to pausing a task, a second parameter is needed to be able to learn the current execution stage of the task and cancel the function execution.

let p1RunCount = 0;
let p2RunCount = 0;

const ptask1 = new PTask<void, void>({
    args: null,
    priority: 2,
    onRun: async (args, execInfo) => {
    const iter = async () => {
        await new Promise((resolve) => setTimeout(resolve, 100));
        // chacking if the task execution was canceled. If so return.
        if (!execInfo.isCanceled()) {
            p1RunCount++; // Increment the counter for the first task
            await iter();
        }
    }

    await iter();
    },
});

const ptask2 = new PTask<void, void>({
    args: null,
    priority: 1,
    onRun: async (args, execInfo) => {
    const iter = async () => {
        await new Promise((resolve) => setTimeout(resolve, 100));
        // chacking if the task execution was canceled. If so return.
        if (!execInfo.isCanceled()) {
            p2RunCount++; // Increment the counter for the second task
            await iter();
        }
    }

    await iter();
    },
});

// * Start executing both tasks
// The first will run first, because of higher priority value
// and the second will start after the abortion of the first one
ptask1.run().catch((err) => null);
ptask2.run().catch((err) => null);

// * Abort the first task after 1 second
setTimeout(() => {
    ptask1.cancel({abort: true});
}, 1000);

// * Check the iterations count of both tasks after 3 seconds
setTimeout(() => {
    console.log(p1RunCount < 10); // true
    console.log(p2RunCount > 10); // true

    // abort the 2nd task so it doesn't run for ∞
    ptask2.cancel({abort: true});
}, 3000);

PTask.run() will throw an error once task abortion is successfully complete. If the function passed to onRun doesn't implement a way to stop execution abrubtly, PTask.run() will not throw the abortion error untill the function's execution is complete; however, another task will be permited to start execution in the meantime.

Update the priority of a task

The priority of any task can be updated at any time given that the task hasn't started running yet.

task.priority = 5;

Set the concurrency limit

This property limits the number of concurrently running tasks. The default value is 1. The limit can be set or changed at any time.

If queueName is not provided, it will set the limit of the default queue.

PTask.setConcurrencyLimit(limit: number, queueName?: string | undefined): void

Get the status of a task

const task = new PTask<number, number>({
    priority: 1,
    onRun: async (a: number) => a, // The function to run
    args: 1, // The value to be passed to the function
});

// Returns the current status of the task:
// 'pending', 'running', 'paused', 'canceled', 'completed'
console.log(task.status);

Get all tasks

PTask.getAllPTasks();