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How to Evaluate Site Speed with the Performance API

How to Evaluate Site Speed with the Performance API

Browser DevTools are great for monitoring web application performance on your local development PC. However, they’re less practical for measuring site speed on different devices, browsers, and network connections across global locations.

The Performance API records DevTool-like metrics from real users as they navigate your application. You can post collected data to a service such as OpenReplay.io, e.g.

asayer.event('load-performance', {

  'os'      : 'Ubuntu',
  'agent'   : 'Firefox 88.0',
  'location': 'US',
  'pageload': 1522.598,
  'paint'   : 5969.123,
  'ajaxinit': 1507.067

});

To help identify performance bottlenecks on specific browsers, devices, or even user sessions.

What is the Performance API?

The Performance API is a collection of APIs used to measure:

Historically, developers had to adopt the Date() function to record elapsed times, e.g.

const startTime = new Date();
doSomething();
const elapsedTime = new Date() - startTime;

console.log(`doSomething() took ${ elapsedTime }ms`);

but the Performance API is:

  1. higher resolution. Unlike Date(), it records timings in fractions of a millisecond.
  2. more reliable. Date() uses the system time so timings can become inaccurate when the OS synchronises the clock.

The API is available in client-side JavaScript in most modern browsers and is detectable with:

if ('performance' in window) {
  // use Performance APIs
}

Resource and user timing is also available in client-side Web Workers. These provide a way to run long-running or computationally-expensive scripts in the background which do not interfere with the browser’s main processing thread.

User timing APIs are also available in server-side:

  • Node.js applications with the performance_hook module, and
  • Deno applications run with the --allow-hrtime option.

The Performance API and documentation can be a little difficult to understand partly because it has evolved. I hope the information and examples in this article help illustrate its potential.

Load timing properties

The sections below describe:

  1. page navigation timings which return a PerformanceNavigationTiming object, and

  2. resource timings which returns a PerformanceResourceTiming object

Both objects provide the following identification properties:

  • name — resource URL
  • entryType — performance type ("navigation" for a page, "resource" for a page asset)
  • initiatorType — resource which initiated the performance entry ("navigation" for a page)
  • serverTiming — an array of PerformanceServerTiming objects with name, description, and duration metrics written by the server to the HTTP Server-Timing header

Both objects provide the following timing properties shown here in the chronological order you would expect them to occur. Timestamps are in milliseconds relative to the start of the page load:

  • startTime — timestamp when the fetch started (0 for a page since it’s the first asset loaded)
  • nextHopProtocol — network protocol used
  • workerStart — timestamp before starting a Progressive Web App (PWA) Service Worker (0 if the request is not intercepted by a Service Worker)
  • redirectStart — timestamp of the fetch which initiated a redirect
  • redirectEnd — timestamp after receiving the last byte of the last redirect response
  • fetchStart — timestamp before the resource fetch
  • domainLookupStart — timestamp before a DNS lookup
  • domainLookupEnd — timestamp after the DNS lookup
  • connectStart — timestamp before the browser establishes a server connection
  • connectEnd — timestamp after establishing a server connection
  • secureConnectionStart — timestamp before the browser starts the SSL handshake process
  • requestStart — timestamp before the browser requests the resource
  • responseStart — timestamp when the browser receives the first byte of data
  • responseEnd — timestamp after receiving the last byte or closing the connection
  • duration — the difference between startTime and responseEnd

Both objects provide the following download size properties:

  • transferSize — the resource size in bytes (octets), including the header and compressed body
  • encodedBodySize — the resource’s payload body in bytes (octets) before decoding/uncompressing
  • decodedBodySize — the resource’s payload body in bytes (octets) after decoding/uncompressing

Page PerformanceNavigationTiming objects provide further metrics about loading and DOM events, although these are not supported in Safari:

  • type — either "navigate", "reload", "back_forward" or "prerender"
  • redirectCount — the number of redirects
  • unloadEventStart — timestamp before the unload event of the previous document (zero if no previous document)
  • unloadEventEnd — timestamp after the unload event of the previous document (zero if no previous document)
  • domInteractive — timestamp before the browser sets the document readiness to interactive when HTML parsing and DOM construction is complete
  • domContentLoadedEventStart — timestamp before document’s DOMContentLoaded event fires
  • domContentLoadedEventEnd — timestamp after document’s DOMContentLoaded event completes
  • domComplete — timestamp before the browser sets the document readiness to complete when DOM construction and DOMContentLoaded events have completed
  • loadEventStart — timestamp before the page load event has fired
  • loadEventEnd — timestamp after the page load event and all assets are available

The Navigation Timing API collates timings for unloading the previous page, redirects, DNS lookups, page loading, file sizes, load events, and more. The information would be difficult to reliably determine in any other way.

Navigation timing is available to client-side JavaScript window and Web Worker functions. Pass a "navigation" type to the performance.getEntriesByType():

const pageTiming = performance.getEntriesByType('navigation');

or the page URL to performance.getEntriesByName():

const pageTiming = performance.getEntriesByName(window.location);

Either option returns an array with a single element containing a PerformanceNavigationTiming object (see load timing properties). It contains read-only properties about the resource load times, e.g.

{
  connectEnd: 139
  connectStart: 103
  decodedBodySize: 72325
  domComplete: 771
  domContentLoadedEventEnd: 634
  domContentLoadedEventStart: 630
  domInteractive: 421
  domainLookupEnd: 103
  domainLookupStart: 87
  duration: 771
  encodedBodySize: 13091
  entryType: "navigation"
  fetchStart: 0
  initiatorType: "navigation"
  loadEventEnd: 771
  loadEventStart: 771
  name: "https://domain.com/"
  nextHopProtocol: "h2"
  redirectCount: 0
  redirectEnd: 0
  redirectStart: 0
  requestStart: 140
  responseEnd: 154
  responseStart: 154
  secureConnectionStart: 115
  serverTiming: Array []
  startTime: 0
  transferSize: 13735
  type: "reload"
  unloadEventEnd: 171
  unloadEventStart: 169
  workerStart: 0
}

You can use it to calculate useful page loading metrics from users, e.g.

if ('performance' in window) {

  const
    pageTiming      = performance.getEntriesByName(window.location)[0],
    pageDownload    = pageTiming.duration,
    pageDomReady    = pageTiming.domContentLoadedEventStart,
    pageFullyReady  = pageTiming.loadEventEnd;

}

Resource timing

You can examine load timings for other resources such as images, stylesheets, scripts, Fetch, and XMLHttpRequest Ajax calls in a similar way to the page.

Resource timing is available to client-side JavaScript window and Web Worker functions. Pass a "resource" type to the performance.getEntriesByType() to return an array. Each element is a PerformanceResourceTiming object (see load timing properties) representing a resource loaded by the page (but not the page itself):

const resourceTiming = performance.getEntriesByType('resource');

example result:

[
  {
    name: "https://domain.com/script1.js",
    entryType: "resource",
    initiatorType: "script",
    fetchStart: 102,
    duration: 51
    ...etc...
  },
  {
    name: "https://domain.com/style1.css",
    entryType: "resource",
    initiatorType: "link",
    fetchStart: 323,
    duration: 54
    ...etc...
  },
  {
    name: "https://domain.com/service/",
    entryType: "resource",
    initiatorType: "xmlhttprequest",
    fetchStart: 598,
    duration: 30
    ...etc...
  },
  ...etc...
]

You can also fetch a resource by passing its exact URL to performance.getEntriesByName():

const resourceTiming = performance.getEntriesByName('https://domain.com/style1.css');

This returns an array with a single element:

[
  {
    name: "https://domain.com/style1.css",
    entryType: "resource",
    initiatorType: "link",
    fetchStart: 323,
    duration: 54
    ...etc...
  }
]

You could use this to report to calculate the load times and sizes of each JavaScript resource as well as the total:

if ('performance' in window) {

  // total size of all JavaScript files
  let scriptTotalSize = 0;

  // array of script names, load times, and uncompressed file sizes
  const script = performance.getEntriesByType('resource')
    .filter( r => r.initiatorType === 'script')
    .map( r => {

      let size = r.decodedBodySize;
      scriptTotalSize += size;

      return {
        name: r.name,
        load: r.duration,
        size
      };

    });

}

The Performance API records at least 150 resource metrics, but you can define a specific number with performance.setResourceTimingBufferSize(N), e.g.

// record metrics for 300 page resources
performance.setResourceTimingBufferSize(300);

You can clear existing metrics with performance.clearResourceTimings(). This may be practical when you no longer require page resource information but want to record Ajax requests:

// clear timings
performance.clearResourceTimings();

// API Fetch request
const res = await Fetch('/service1/');

// one resource returned
const resourceTiming = performance.getEntriesByType('resource');

Paint timing

The Paint Timing API is available to client-side JavaScript window functions and records two rendering operations observed during page construction.

Pass a "paint" type to the performance.getEntriesByType() to return an array containing two PerformancePaintTiming objects:

const paintTiming = performance.getEntriesByType('paint');

The result:

[
  {
    "name": "first-paint",
    "entryType": "paint",
    "startTime": 242,
    "duration": 0
  },
  {
    "name": "first-contentful-paint",
    "entryType": "paint",
    "startTime": 243,
    "duration": 0
  }
]

where:

  • first-paint: the browser has painted the first pixel on the page, and

  • first-contentful-paint: the browser has painted the first item of DOM content, such as text or an image.

Note that "duration" will always be zero.

performance.now()

performance.now() returns a high-resolution timestamp in fractions of a millisecond since the beginning of the process’s lifetime. The method is available in client-side JavaScript, Web Workers, Node.js, and Deno.

In client-side JavaScript, the performance.now() timer starts at zero when the process responsible for creating the document started. Web Worker, Node.js, and Deno timers start when the script process initially executes.

Note that Node.js scripts must load the Performance hooks (perf_hooks) module to use the Performance API. In CommonJS:

const { performance } = require('perf_hooks');

or as an ES module:

import { performance } from 'perf_hooks';

You can use performance.now() to time scripts, e.g.

const doSomethingStart = performance.now();

doSomething();

const doSomethingElapsed = performance.now() - doSomethingStart;

A further non-standard timeOrigin property returns the timestamp at which the current process began. This is measured in Unix time since 1 January 1970 and is available in Node.js and browser JavaScript (not IE or Safari):

const doSomethingStart = performance.timeOrigin;

doSomething();

const doSomethingElapsed = performance.timeOrigin - doSomethingStart;

User timing

performance.now() becomes cumbersome when taking more than a couple of timing measurements. The performance.mark() method adds a named PerformanceMark object object with a timestamp to the performance buffer. It’s available in client-side JavaScript, Web Workers, Node.js, and Deno:

// Node.js scripts require:
// CommonJS: const { performance } = require('perf_hooks');
// or ESM  : import { performance } from 'perf_hooks';

performance.mark('script:start');

performance.mark('doSomething1:start');
doSomething1();
performance.mark('doSomething1:end');

performance.mark('doSomething2:start');
doSomething2();
performance.mark('doSomething2:end');

performance.mark('script:end');

Pass a "mark" type to the performance.getEntriesByType() to return an array of marks:

const userTiming = performance.getEntriesByType('mark');

The resulting array contains objects with name and startTime properties:

[
  {
    detail: null
    duration: 0
    entryType: "mark"
    name: "script:start"
    startTime: 100
  },
  {
    detail: null
    duration: 0
    entryType: "mark"
    name: "doSomething1:start"
    startTime: 100
  },
  {
    detail: null
    duration: 0
    entryType: "mark"
    name: "doSomething1:end"
    startTime: 123
  },
  ...etc...
]

The performance.measure() method calculates the elapsed time between two marks. It’s passed the measure name, the start mark name (or a falsy value to use the page/script load time), and the end mark name (or a falsy value to use the current time), e.g.

performance.measure('doSomething1', 'doSomething1:start', 'doSomething1:end');
performance.measure('script', null, 'doSomething1:end');

This adds a PerformanceMeasure object to the performance buffer with a calculated duration. Pass a "measure" type to the performance.getEntriesByType() to return an array of measures:

const userTiming = performance.getEntriesByType('measure');

The resulting array:

[
  {
    detail: null
    duration: 211
    entryType: "measure"
    name: "doSomething1"
    startTime: 100
  },
  {
    detail: null
    duration: 551
    entryType: "measure"
    name: "script"
    startTime: 100
  }
]

You can also fetch mark and measure entries by name using performance.getEntriesByName():

performance.getEntriesByName('doSomething1');

Other useful methods include:

Open Source Session Replay

OpenReplay is an open-source, session replay suite that lets you see what users do on your web app, helping you troubleshoot issues faster. OpenReplay is self-hosted for full control over your data.

replayer.png

Start enjoying your debugging experience - start using OpenReplay for free.

PerformanceObserver

The PerformanceObserver interface can watch for changes to the performance buffer and run a function when specific objects appear. It’s most practically used for mark, measure, and resource loading events (navigation and paint timings will generally occur before a script has started).

First, define an observer function. This could log an event or post the data to a statistics endpoint:

function performanceObserver(list, observer) {

  list.getEntries().forEach(entry => {

    console.log('---');
    console.log(`name    : ${ entry.name }`);
    console.log(`type    : ${ entry.type }`);
    console.log(`start   : ${ entry.startTime }`);
    console.log(`duration: ${ entry.duration }`);

  });

}

The function has the following parameters:

  1. a list of observer entries, and

  2. the observer object so it’s possible to disconnect() if necessary.

Pass this function when creating a new PerformanceObserver object then run the observe() method with the entryTypes to observe:

let observer = new PerformanceObserver(performanceObserver);
observer.observe({ entryTypes: ['mark', 'measure'] });

Adding a new mark or measure will now run the performanceObserver() function and display details about that measurement.

Future performance options

Chrome-based browsers offer a non-standard performance.memory property which returns a single MemoryInfo object:

{
  jsHeapSizeLimit: 4294705152
  totalJSHeapSize: 5092217
  usedJSHeapSize: 3742009
}

where:

  • jsHeapSizeLimit — the maximum size of the heap in bytes
  • totalJSHeapSize — the total allocated heap size in bytes, and
  • usedJSHeapSize — The currently active segment of JS heap in bytes.

The Frame timing API is not implemented in any browser, but will record the amount of browser work in one event loop iteration. This includes processing DOM events, CSS animations, rendering, scrolling, resizing, etc. The API should be able to report potential jerkiness when a frame takes longer than 16.7 milliseconds so updates drop below 60 frames per second.

Finally, the Self-Profiling API is an experimental feature under development in Chrome. Given a sample rate, the API will help locate slow or unnecessary code in a similar way to the DevTools performance report:

// define a new profiler with 10ms sample rate
const profile = await performance.profile({ sampleInterval: 10 });

// run code
doSomething();

// stop the profiler and capture a trace
const trace = await profile.stop();

Pinpoint performance problems

It’s easy to presume your application runs well when you’re developing on a new PC connected to a fast network. The performance API offers a way to prove — or disprove — performance issues by collecting real user metrics based on their devices, connections, and locations.