vue2从数据变化到视图变化之nextTick使用详解

2024-04-02 19:04:59 452人浏览安东尼

摘要

目录引言1、Vue中nextTick的使用场景2、vue中nextTick在哪里定义3、vue中nextTick的实现原理（1）callbacks的定义（2）timerFunc的定义

引言

nextTick在vue中是一个很重要的方法，在new Vue实例化的同步过程中，将一些需要异步处理的函数推到异步队列中去，可以等new Vue所有的同步任务执行完后，再执行异步队列中的函数。

1、vue中nextTick的使用场景

借用vue.js官网中例子:

Vue.component("example", {
  template: "<span>{{ message }}</span>",
  data: function() {
    return {
      message: "未更新"
    };
  },
  methods: {
    updateMessage: function() {
      this.message = "已更新";
      console.log(this.$el.textContent); // => '未更新'
      this.$nextTick(function() {
        console.log(this.$el.textContent); // => '已更新'
      });
    }
  }
});

例子中显示数据变化后直接访问节点内容是'未更新'，当使用了this.$nextTick包裹后访问节点内容是'已更新'，可以看出如果需要拿到数据变化后的节点，则需要使用this.nextTick，这就是nextTick的使用场景。
那么，$nextTick是从哪里定义的？

2、vue中nextTick在哪里定义

在vue源码initGlobalapi(Vue)过程中:

import { nextTick } from '../util/index'
// ...
Vue.nextTick = nextTick

3、vue中nextTick的实现原理



import { noop } from 'shared/util'
import { handleError } from './error'
import { isIE, isiOS, isNative } from './env'
export let isUsingMicroTask = false
const callbacks = []
let pending = false
function flushCallbacks () {
  pending = false
  const copies = callbacks.slice(0)
  callbacks.length = 0
  for (let i = 0; i < copies.length; i++) {
    copies[i]()
  }
}
// Here we have async deferring wrappers using microtasks.
// In 2.5 we used (Macro) tasks (in combination with microtasks).
// However, it has subtle problems when state is changed right before repaint
// (e.g. #6813, out-in transitions).
// Also, using (macro) tasks in event handler would cause some weird behaviors
// that cannot be circumvented (e.g. #7109, #7153, #7546, #7834, #8109).
// So we now use microtasks everywhere, again.
// A major drawback of this tradeoff is that there are some scenarios
// where microtasks have too high a priority and fire in between supposedly
// sequential events (e.g. #4521, #6690, which have workarounds)
// or even between bubbling of the same event (#6566).
let timerFunc
// The nextTick behavior leverages the microtask queue, which can be accessed
// via either native Promise.then or MutationObserver.
// MutationObserver has wider support, however it is seriously bugged in
// UIWEBView in iOS >= 9.3.3 when triggered in touch event handlers. It
// completely stops working after triggering a few times... so, if native
// Promise is available, we will use it:

if (typeof Promise !== 'undefined' && isNative(Promise)) {
  const p = Promise.resolve()
  timerFunc = () => {
    p.then(flushCallbacks)
    // In problematic UIWebViews, Promise.then doesn't completely break, but
    // it can get stuck in a weird state where callbacks are pushed into the
    // microtask queue but the queue isn't being flushed, until the browser
    // needs to do some other work, e.g. handle a timer. Therefore we can
    // "force" the microtask queue to be flushed by adding an empty timer.
    if (isIOS) setTimeout(noop)
  }
  isUsingMicroTask = true
} else if (!isIE && typeof MutationObserver !== 'undefined' && (
  isNative(MutationObserver) ||
  // Phantomjs and iOS 7.x
  MutationObserver.toString() === '[object MutationObserverConstructor]'
)) {
  // Use MutationObserver where native Promise is not available,
  // e.g. PhantomJS, iOS7, Android 4.4
  // (#6466 MutationObserver is unreliable in IE11)
  let counter = 1
  const observer = new MutationObserver(flushCallbacks)
  const textnode = document.createTextNode(String(counter))
  observer.observe(textNode, {
    characterData: true
  })
  timerFunc = () => {
    counter = (counter + 1) % 2
    textNode.data = String(counter)
  }
  isUsingMicroTask = true
} else if (typeof setImmediate !== 'undefined' && isNative(setImmediate)) {
  // Fallback to setImmediate.
  // Technically it leverages the (macro) task queue,
  // but it is still a better choice than setTimeout.
  timerFunc = () => {
    setImmediate(flushCallbacks)
  }
} else {
  // Fallback to setTimeout.
  timerFunc = () => {
    setTimeout(flushCallbacks, 0)
  }
}
export function nextTick (cb?: Function, ctx?: Object) {
  let _resolve
  callbacks.push(() => {
    if (cb) {
      try {
        cb.call(ctx)
      } catch (e) {
        handleError(e, ctx, 'nextTick')
      }
    } else if (_resolve) {
      _resolve(ctx)
    }
  })
  if (!pending) {
    pending = true
    timerFunc()
  }
  // $flow-disable-line
  if (!cb && typeof Promise !== 'undefined') {
    return new Promise(resolve => {
      _resolve = resolve
    })
  }
}

（1）callbacks的定义

在nextTick中首先在callbacks中推入进行try {} catch (e) {}捕捉错误的回调函数。

（2）timerFunc的定义

然后，如没有在pengding状态时，将pending置为true，并执行timerFunc函数，这个函数依次根据当前浏览器执行环境中支不支持Promise、MutationObserver和setImmediate方法进行赋值，如果都不支持，则使用setTimeout。

第一步，如果浏览器支持Promise，const p = Promise.resolve()，然后timerFunc中定义p.then(flushCallbacks)，通过p.then(flushCallbacks)自执行的能力来诱发flushCallbacks;
第二步，如果浏览器不支持Promise但支持MutationObserver，则其利用DOM属性监听变化的能力，首先定义const observer = new MutationObserver(flushCallbacks)，并监听const textNode = document.createTextNode(String(counter))的变化，timerFunc的执行是通过修改textNode值来诱发flushCallbacks的执行。
第三步，以上两者都不满足，但浏览器支持立即执行函数setImmediate，则通过timerFunc = () => { setImmediate(flushCallbacks) }的方式来诱发flushCallbacks.
第四步，以上条件都不满足的时候，则通过timerFunc = () => { setTimeout(flushCallbacks, 0) }将定时器的延迟时间设置为0进行flushCallbacks的诱发。
以上四步中提到的的flushCallbacks函数，其中pending = false表示同步任务已经执行结束，开始了异步队列的执行。const copies = callbacks.slice(0)进行异步事件的浅拷贝，并将异步队列数组callbacks清空，等待下一次异步队列的推入。通过for (let i = 0; i < copies.length; i++) { copies[i]() }进行当前异步队列中函数的执行。

（3）cb未传入的处理

最后，如果没有传入cb并且环境也支持Promise，return new Promise(resolve => { _resolve = resolve })，然后在执行异步队列中的函数的时候，直接执行_resolve(ctx)，为nextTick的使用提供了又一个方法Vue.nextTick().then(function () {// DOM 更新了})。