This specification defines an interface for web applications to access
the complete timing information for resources in a document.
Status of This Document
This is a
preview
Do not attempt to implement this version of the specification. Do not
reference this version as authoritative in any way.
Instead, see
https://w3c.github.io/resource-timing/ for the Editor's draft.
This section describes the status of this
document at the time of its publication. A list of current W3C
publications and the latest revision of this technical report can be found
in the W3C technical reports index at
https://www.w3.org/TR/.
Warning
Implementers SHOULD be aware that this document is not stable.
Implementers who are not taking part in the discussions are likely to
find the specification changing out from under them in incompatible
ways. Vendors interested in implementing this document before it
eventually reaches the Candidate Recommendation stage SHOULD join the
aforementioned mailing lists and take part in the discussions.
Publication as an Editor's Draft does not
imply endorsement by W3C and its Members.
This is a draft document and may be updated, replaced or obsoleted by other
documents at any time. It is inappropriate to cite this document as other
than work in progress.
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operating under the
W3C Patent
Policy.
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public list of any patent disclosures
made in connection with the deliverables of
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Essential Claim(s)
must disclose the information in accordance with
section 6 of the W3C Patent Policy.
User latency is an important quality benchmark for Web Applications.
While JavaScript-based mechanisms can provide comprehensive
instrumentation for user latency measurements within an application, in
many cases, they are unable to provide a complete end-to-end latency
picture. This document introduces the PerformanceResourceTiming
interface to allow JavaScript mechanisms to collect complete timing
information related to resources on a document. Navigation Timing 2
[NAVIGATION-TIMING-2] extends this specification to provide
additional timing information associated with a navigation.
For example, the following JavaScript shows a simple attempt to measure
the time it takes to fetch a resource:
<!doctype html><html><head></head><bodyonload="loadResources()"><script>functionloadResources()
{
var start = newDate().getTime();
var image1 = new Image();
var resourceTiming = function() {
var now = newDate().getTime();
var latency = now - start;
alert("End to end resource fetch: " + latency);
};
image1.onload = resourceTiming;
image1.src = 'https://www.w3.org/Icons/w3c_main.png';
}
</script><imgsrc="https://www.w3.org/Icons/w3c_home.png"></body></html>
Though this script can measure the time it takes to fetch a resource,
it cannot break down the time spent in various phases. Further, the
script cannot easily measure the time it takes to fetch resources
described in markup.
To address the need for complete information on user experience, this
document introduces the PerformanceResourceTiming interface.
This interface allows JavaScript mechanisms to provide complete
client-side latency measurements within applications. With this
interface, the previous example can be modified to measure a user's
perceived load time of a resource.
The following script calculates the amount of time it takes to fetch
every resource in the page, even those defined in markup. This example
assumes that this page is hosted on https://www.w3.org. One could
further measure the amount of time it takes in every phase of fetching
a resource with the PerformanceResourceTiming interface.
<!doctype html><html><head></head><bodyonload="loadResources()"><script>functionloadResources()
{
var image1 = new Image();
image1.onload = resourceTiming;
image1.src = 'https://www.w3.org/Icons/w3c_main.png';
}
functionresourceTiming()
{
var resourceList = window.performance.getEntriesByType("resource");
for (i = 0; i < resourceList.length; i++)
{
if (resourceList[i].initiatorType == "img")
{
alert("End to end resource fetch: " + (resourceList[i].responseEnd - resourceList[i].startTime));
}
}
}
</script><imgid="image0"src="https://www.w3.org/Icons/w3c_home.png"></body></html>
2. Conformance
As well as sections marked as non-normative, all authoring guidelines, diagrams, examples, and notes in this specification are non-normative. Everything else in this specification is normative.
The key words MAY, MUST, and SHOULD in this document
are to be interpreted as described in
BCP 14
[RFC2119] [RFC8174]
when, and only when, they appear in all capitals, as shown here.
Requirements phrased in the imperative as part of algorithms (such as
"strip any leading space characters" or "return false and abort these
steps") are to be interpreted with the meaning of the key word ("MUST",
"SHOULD", "MAY", etc) used in introducing the algorithm.
Some conformance requirements are phrased as requirements on
attributes, methods or objects. Such requirements are to be interpreted
as requirements on user agents.
Conformance requirements phrased as algorithms or specific steps may be
implemented in any manner, so long as the end result is equivalent. (In
particular, the algorithms defined in this specification are intended
to be easy to follow, and not intended to be performant.)
3.
Terminology
The construction "a Foo object", where Foo is
actually an interface, is sometimes used instead of the more accurate
"an object implementing the interface Foo.
The term DOM is used to refer to the API set made available
to scripts in Web applications, and does not necessarily imply the
existence of an actual Document object or of any other Node
objects as defined in the [DOM] specification.
A DOM attribute is said to be getting when its value is
being retrieved (such as by author script), and is said to be
setting when a new value is assigned to it.
The term JavaScript is used to refer to ECMA262, rather than
the official term ECMAScript, since the term JavaScript is more widely
known. [ECMASCRIPT]
The term resource is used to refer to elements and any other
user-initiated fetches throughout this specification. For example, a
resource could originate from XMLHttpRequest objects [XHR], HTML
elements [HTML] such as iframe, img, script, object, embed, and link
with the link type of stylesheet, and SVG elements [SVG11] such as
svg.
The term cross-origin is used to mean non same origin.
Throughout this work, all time values are measured in milliseconds
since the start of navigation of the document [HR-TIME-2]. For
example, the start
of navigation of the document occurs at time 0.
Note
This definition of time is based on the High Resolution Time
specification [HR-TIME-2] and is different from the definition of
time used in the Navigation Timing specification
[NAVIGATION-TIMING-2], where time is measured in milliseconds since
midnight of January 1, 1970 (UTC).
If the same canonical URL is used as the src
attribute of two HTML IMG elements, the fetch of the
resource initiated by the first HTML IMG element would
be included as a PerformanceResourceTiming object in the
Performance
Timeline. The user agent might not re-request the URL for the
second HTML IMG element, instead using the existing
download it initiated for the first HTML IMG element. In
this case, the fetch of the resource by the first
IMG element would be the only occurrence in the
Performance
Timeline.
If the src attribute of a HTML IMG
element is changed via script, both the fetch of the original
resource as well as the fetch of the new URL would be included as
PerformanceResourceTiming objects in the Performance
Timeline.
If an HTML IFRAME element is added via markup
without specifying a src attribute, the user agent may
load the about:blank document for the
IFRAME. If at a later time the src
attribute is changed dynamically via script, the user agent may
fetch the new URL resource for the IFRAME. In this
case, only the fetch of the new URL would be included as a
PerformanceResourceTiming object in the Performance
Timeline.
If an XMLHttpRequest is generated twice for the same
canonical URL, both fetches of the resource would be included as
a PerformanceResourceTiming object in the Performance
Timeline. This is because the fetch of the resource for the
second XMLHttpRequest cannot reuse the download issued
for the first XMLHttpRequest.
If an HTML IFRAME element is included on the page,
then only the resource requested by IFRAMEsrc attribute is included as a
PerformanceResourceTiming object in the Performance
Timeline. Sub-resources requested by the IFRAME
document will be included in the IFRAME document's
Performance
Timeline and not the parent document's Performance
Timeline.
If a resource fetch was
aborted due to a networking error (e.g. DNS, TCP, or TLS error), then
the fetch will be included as a PerformanceResourceTiming
object in the Performance
Timeline with only the startTime, fetchStart, duration and
responseEnd set.
If a resource fetch is
aborted because it failed a fetch precondition (e.g. mixed content,
CORS restriction, CSP policy, etc), then this resource will not be
included as a PerformanceResourceTiming object in the
Performance
Timeline.
The constant number added to transferSize replaces exposing the
total byte size of the HTTP headers, as that may expose the
presence of certain cookies. See this
issue.
This means that if the resourcetimingbufferfull
event handler does not add more room in the buffer than it adds
resources to it, excess entries will be dropped from the buffer.
Developers should make sure that
resourcetimingbufferfull event handlers call
clearResourceTimings or extend the buffer
sufficiently (by calling
setResourceTimingBufferSize).
Server-side applications may return the Timing-Allow-Origin
HTTP response header to allow the User Agent to fully expose, to the
document origin(s) specified, the values of attributes that would
have been zero due to the cross-origin restrictions previously
specified in this section.
4.5.1
Timing-Allow-Origin Response Header
The Timing-Allow-Origin HTTP response header field can
be used to communicate a policy indicating origin(s) that are
allowed to see values of attributes that would have been zero due
to the cross-origin restrictions. The header's value is represented
by the following ABNF [RFC5234] (using List Extension, [RFC7230]):
The sender MAY generate multiple Timing-Allow-Origin header
fields. The recipient MAY combine multiple
Timing-Allow-Origin header fields by appending each
subsequent field value to the combined field value in order,
separated by a comma.
The Timing-Allow-Origin header may arrive as part of a cached
response. In case of cache revalidation, according to RFC 7234,
the header's value may come from the revalidation response, or if
not present there, from the original cached resource.
The following graph illustrates the timing attributes defined by
the PerformanceResourceTiming interface. Attributes in parenthesis
may not be available when fetchingcross-origin
resources. User agents may perform internal processing in between
timings, which allow for non-normative intervals between timings.
Figure 1
This figure illustrates the timing attributes defined by the
PerformanceResourceTiming interface. Attributes in
parenthesis indicate that they may not be available if the
resource fails the timing
allow check algorithm.
4.5.4
Creating a resource timing entry
To mark resource timing given a fetch timing infotimingInfo, a DOMString requestedURL, a DOMString
initiatorType a global objectglobal, and a string
cacheMode, perform the following steps:
To setup the resource timing entry for
PerformanceResourceTimingentry given DOMString
initiatorType, DOMString requestedURL, fetch timing infotimingInfo, and a DOMString cacheMode, perform the following
steps:
Assert that cacheMode is the empty string or
"local".
The PerformanceResourceTiming interface exposes timing
information for a resource to any web page or worker that has
requested that resource. To limit the access to the
PerformanceResourceTiming interface, the same origin policy is enforced by default
and certain attributes are set to zero, as described in HTTP fetch. Resource providers can explicitly allow all timing
information to be collected for a resource by adding the
Timing-Allow-Origin HTTP response header, which specifies
the domains that are allowed to access the timing information.
Statistical fingerprinting is a privacy concern where a malicious
web site may determine whether a user has visited a third-party web
site by measuring the timing of cache hits and misses of resources
in the third-party web site. Though the
PerformanceResourceTiming interface gives timing information
for resources in a document, the cross-origin restrictions in in
HTTP Fetch prevent making this privacy concern any worse than
it is today using the load event on resources to measure timing to
determine cache hits and misses.
4.5.6
Acknowledgments
Thanks to Anne Van Kesteren, Annie Sullivan, Arvind Jain, Boris
Zbarsky, Darin Fisher, Jason Weber, Jonas Sicking, James Simonsen,
Karen Anderson, Kyle Scholz, Nic Jansma, Philippe Le Hegaret,
Sigbjørn Vik, Steve Souders, Todd Reifsteck, Tony Gentilcore and
William Chan for their contributions to this work.
