This CSS module describes the contain property, which indicates that the element’s subtree is independent of the rest of the page. This enables heavy optimizations by user agents when used well.
CSS is a language for describing the rendering of structured documents
(such as HTML and XML)
on screen, on paper, etc.
Status of this document
This is a public copy of the editors’ draft.
It is provided for discussion only and may change at any moment.
Its publication here does not imply endorsement of its contents by W3C.
Don’t cite this document other than as work in progress.
Please send feedback
by filing issues in GitHub (preferred),
including the spec code “css-contain” in the title, like this:
“[css-contain] …summary of comment…”.
All issues and comments are archived.
Alternately, feedback can be sent to the (archived) public mailing list www-style@w3.org.
This is a diff spec over CSS Containment Level 2.
It is currently an Exploratory Working Draft:
if you are implementing anything, please use Level 2 as a reference.
We will merge the Level 2 text into this draft once it reaches CR.
1.1. Module Interactions
This document defines new features not present in earlier specifications.
In addition, it aims to replace and supersede [CSS-CONTAIN-1] once stable.
1.2. Value Definitions
This specification follows the CSS property definition conventions from [CSS2] using the value definition syntax from [CSS-VALUES-3].
Value types not defined in this specification are defined in CSS Values & Units [CSS-VALUES-3].
Combination with other CSS modules may expand the definitions of these value types.
In addition to the property-specific values listed in their definitions,
all properties defined in this specification
also accept the CSS-wide keywords as their property value.
For readability they have not been repeated explicitly.
Firefox101+Safari15.4+Chrome105+Opera?Edge105+Edge (Legacy)?IENoneFirefox for Android?iOS Safari?Chrome for Android?Android WebView?Samsung Internet?Opera Mobile?
Giving an element inline-size containment applies size containment to the inline-axis sizing of its principal box.
This means the inline-axisintrinsic sizes of the principal box are determined as if the element had no content.
However, content continues to impact the box’s block-axisintrinsic sizes as usual,
and the box is allowed to fragment normally in the block axis.
Note: In some cases,
a box’s block-axisintrinsic sizes can impact layout in the parent formatting context in ways that affect the box’s inline size (e.g. by triggering scrollbars on an ancestor element),
creating a dependency of the box’s inline size on its own content.
If this changed inline size results in a different block size,
that new block size can loop into further impacting the parent formatting context,
but not in a way that reverts it to the previously-problematic layout.
For example, if scrollbars were introduced,
they are not then removed,
even if the consequent block size is small enough to not need them;
or if a box’s logical height collides with a lower-placed float and is cleared down
to where it also has more available inline space
and thus becomes short enough to not have collided,
it is not them moved back up to its previous problematic size and position.
In general, the relationship between an element’s inline size
and it’s block size
is unpredictable and non-monotonic,
with the block size capable of shifting up and down arbitrarily
as the inline size is changed.
Infinite cycles are prevented
by ensuring that layout does not revert to a previous (known-problematic) state,
even if a naive analysis of the constraints would allow for such;
in other words, layout always “moves forward”.
We believe that current CSS layout specifications incorporate such rules,
but to the extent that they don’t,
please inform the CSSWG so that these errors can be corrected.
Consider this example,
where float placement creates a dependency of block sizes on inline sizes:
The block layout algorithm will first place the floating boxes,
with the first two sitting in the left and right corners of the container,
and the third, being too wide to fit between, being pushed below them.
The following article will then be laid out.
Because it is display: flow-root,
it cannot intersect any floats,
and thus must take them into account
when figuring out how to size and position itself.
The layout engine first attempts to place the article flush with the top of the container,
resulting a 100px width,
plenty wide enough to accommodate its min-content size.
However, due to the aspect-ratio of its child,
this would cause the article to be 100px tall as well,
which would intersect the third float 80px below,
so this layout opportunity is discarded.
It then attempts to position the article flush with the top of the third float,
in the narrow 40px-wide space to its right.
However, since the article’s min-width makes it too large
to fit in the 40px-wide space beside the third float,
it shifts below that one as well,
forming a 200px square below all the floated boxes.
Article
If the min-width is removed from the article,
or if inline-size containment is added to
either the article or header (causing min-width: min-content to resolve to zero),
then the article will fit as a 40px square
next to the final floated div (possibly with some of its content overflowing).
At this point, the width and height of the article (40px each) would fit back in the first considered space,
flush with the top of the container.
However, the box is not returned to the previous position,
because the layout engine knows already
that this position would result in an invalid layout.
While media queries provide a method to query
aspects of the user agent or device environment
that a document is being displayed in
(such as viewport dimensions or user preferences), container queries allow testing aspects of elements within the document
(such as box dimensions or computed styles).
For example, we can define the main content area and sidebar as containers,
and then describe a .media-object that changes
from vertical to horizontal layout depending on the size of its container:
main, aside {container: my-layout / inline-size;}
.media-object {display: grid;grid-template:'img' auto 'content' auto / 100%;}@container my-layout (inline-size > 45em){
.media-object {grid-template:'img content' auto / auto 1fr;}}
Media objects in the main and sidebar areas
will each respond to their own container context.
Multiple pseudo elements do not allow pseudo elements to be query
containers for other pseudo elements. E.g., the host, but not the ::part(), can be the query container for ::before in host::part()::before. Similarly, ::before can not be the query container for the ::marker in div::before::marker
::slotted() selectors can query containers inside the shadow tree,
including the slot itself
::part() selectors can query its originating host, but not internal
query containers inside the shadow tree
::placeholder and ::file-selector-button can query the input
element, but do not expose any internal containers if the input element is
implemented using a shadow tree
A ::before selector querying the size of the originating element:
The container-type property establishes the element
as a query container for the purpose of container queries that require explicit containment
(such as container size queries),
allowing style rules styling its descendants
to query various aspects of its sizing and layout,
and respond accordingly.
For example, authors can create container-responsive typography,
adjusting font-size, line-height, and other typographic concerns
based on the size of a container:
aside, main {container-type: inline-size;}
h2 {font-size:1.2em;}@container(width > 40em){
h2 {font-size:1.5em;}}
The container-name property
specifies a list of query container names.
These names can be used by @container rules
to filter which query containers are targeted.
In some cases, we want to query aspects of a specific container,
even if it’s not the nearest ancestor container.
For example, we might want to query the height of a main content area,
and the width of a more nested inline-container.
For each element,
the query container to be queried
is selected from among the element’s ancestor query containers that are established as a valid query container for all the container features in the <container-query>.
The optional <container-name> filters the set of query containers considered
to just those with a matching query container name.
Once an eligible query container has been selected for an element,
each container feature in the <container-query> is evaluated against that query container.
If no ancestor is an eligible query container,
then the container query is unknown for that element.
As with media queries,
we can string together multiple conditions in a single query list:
@container card (inline-size > 30em) and style(--responsive: true){/* styles */}
The styles above will only be applied
if there is an ancestor container named "card"
that meets both the inline-size and style conditions.
Style rules defined on an element inside multiple nested container queries apply when all of the wrapping container queries are true for that element.
Note: Nested container queries can evaluate in relation to different containers,
so it is not always possible to merge the individual <container-condition>s
into a single query.
While it is not possible to query multiple containers
in a single container query,
that can be achieved by nesting multiple queries:
The styles above will only be applied
if there is an ancestor container named "card"
that meets the inline-size condition,
as well as an ancestor container
meeting style condition.
A transition on a sibling element can indirectly affect the size of a
container, triggering style change events whenever container queries
change their evaluation as a result:
main {display: flex;width:300px;}
#container {container-type: inline-size;flex:1;}/* Resolved width is initially 200px, but changes as the transition on #sibling progresses. */
#inner {transition:1s background-color;background-color: tomato;}/* When this container query starts (or stops) applying, a transition must start on background-color on #inner. */@container(width <= 150px){
#inner {background-color: skyblue;}}
#sibling {width:100px;transition: width 1s;}
#sibling:hover {width:200px;}
A container style query allows querying
the computed values of the query container.
It is a boolean combination of
individual style features (<style-feature>)
that each query a single, specific property of the query container.
The syntax of a <style-feature> is the same as for a declaration[CSS-SYNTAX-3],
and its query is true if
the computed value of the given property on the query container matches the given value
(which is also computed with respect to the query container),
unknown if the property or its value is invalid or unsupported,
and false otherwise.
The boolean syntax and logic combining style features into a style query is the same as for CSS feature queries.
(See @supports. [CSS-CONDITIONAL-3])
6. Container Relative Lengths: the cqw, cqh, cqi, cqb, cqmin, cqmax units
Container query length units specify a length relative to the dimensions of a query container.
Style sheets that use container query length units can more easily move components
from one query container to another.
For each element, container query length units are evaluated
as container size queries on the relevant axis (or axes)
described by the unit.
The query container for each axis
is the nearest ancestor container
that accepts container size queries on that axis.
If no eligible query container is available,
then use the small viewport size for that axis.
Note: In some cases cqi and cqb units on the same element
will evaluate in relation to different query containers.
Similarly, cqmin and cqmax units represent
the larger or smaller of the cqi and cqb units,
even when those dimensions come from different query containers.
Child elements do not inherit the relative values as specified for their parent;
they inherit the computed values.
Authors can ensure that container query length units
have an appropriate query container by applying them inside a container query that relies on the same container-type.
Custom fallback values can be defined outside the container query:
/* The fallback value does not rely on containment */
h2 {font-size:1.2em;}@container(inline-size >= 0px){/* only applies when an inline-size container is available */
h2 {font-size:calc(1.2em + 1cqi);}}
The containerQuery attribute,
on getting, must return the <container-query> that was specified,
without any logical simplifications,
so that the returned query will evaluate to the same result
as the specified query
in any conformant implementation of this specification
(including implementations that implement future extensions
allowed by the <general-enclosed> extensibility mechanism in this specification).
In other words,
token stream simplifications are allowed
(such as reducing whitespace to a single space
or omitting it in cases where it is known to be optional),
but logical simplifications (such as removal of unneeded parentheses,
or simplification based on evaluating results) are not allowed.
Container Queries should have a matchContainer method.
This will be modeled on matchMedia() and the MediaQueryList interface,
but applied to Elements rather than the Window.
When measuring layout sizes, it behaves Similar to resizeObserver,
but it provides the additional Container Query syntax and features. [Issue #6205]
8. Suppressing An Element’s Contents Entirely: the content-visibility property
Comments and previous work from
Adam Argyle,
Amelia Bellamy-Royds,
Anders Hartvoll Ruud,
Brian Kardell,
Chris Coyier,
Christopher Kirk-Nielsen,
David Herron,
Elika J. Etemad (fantasai),
Eric Portis,
Ethan Marcotte,
Geoff Graham,
Gregory Wild-Smith,
Ian Kilpatrick,
Jen Simmons,
Kenneth Rohde Christiansen,
L. David Baron,
Lea Verou,
Martin Auswöger,
Martine Dowden,
Mike Riethmuller,
Morten Stenshorne,
Nicole Sullivan,
Rune Lillesveen,
Scott Jehl
Scott Kellum,
Stacy Kvernmo,
Theresa O’Connor,
Una Kravets,
and many others have contributed to this specification.
Conformance
Document conventions
Conformance requirements are expressed with a combination of
descriptive assertions and RFC 2119 terminology. The key words “MUST”,
“MUST NOT”, “REQUIRED”, “SHALL”, “SHALL NOT”, “SHOULD”, “SHOULD NOT”,
“RECOMMENDED”, “MAY”, and “OPTIONAL” in the normative parts of this
document are to be interpreted as described in RFC 2119.
However, for readability, these words do not appear in all uppercase
letters in this specification.
All of the text of this specification is normative except sections
explicitly marked as non-normative, examples, and notes. [RFC2119]
Examples in this specification are introduced with the words “for example”
or are set apart from the normative text with class="example",
like this:
This is an example of an informative example.
Informative notes begin with the word “Note” and are set apart from the
normative text with class="note", like this:
Note, this is an informative note.
Advisements are normative sections styled to evoke special attention and are
set apart from other normative text with <strong class="advisement">, like
this: UAs MUST provide an accessible alternative.
Tests
Tests relating to the content of this specification
may be documented in “Tests” blocks like this one.
Any such block is non-normative.
Conformance classes
Conformance to this specification
is defined for three conformance classes:
A style sheet is conformant to this specification
if all of its statements that use syntax defined in this module are valid
according to the generic CSS grammar and the individual grammars of each
feature defined in this module.
A renderer is conformant to this specification
if, in addition to interpreting the style sheet as defined by the
appropriate specifications, it supports all the features defined
by this specification by parsing them correctly
and rendering the document accordingly. However, the inability of a
UA to correctly render a document due to limitations of the device
does not make the UA non-conformant. (For example, a UA is not
required to render color on a monochrome monitor.)
An authoring tool is conformant to this specification
if it writes style sheets that are syntactically correct according to the
generic CSS grammar and the individual grammars of each feature in
this module, and meet all other conformance requirements of style sheets
as described in this module.
Partial implementations
So that authors can exploit the forward-compatible parsing rules to
assign fallback values, CSS renderers must treat as invalid (and ignore
as appropriate) any at-rules, properties, property values, keywords,
and other syntactic constructs for which they have no usable level of
support. In particular, user agents must not selectively
ignore unsupported component values and honor supported values in a single
multi-value property declaration: if any value is considered invalid
(as unsupported values must be), CSS requires that the entire declaration
be ignored.
Implementations of Unstable and Proprietary Features
Once a specification reaches the Candidate Recommendation stage,
non-experimental implementations are possible, and implementors should
release an unprefixed implementation of any CR-level feature they
can demonstrate to be correctly implemented according to spec.
To establish and maintain the interoperability of CSS across
implementations, the CSS Working Group requests that non-experimental
CSS renderers submit an implementation report (and, if necessary, the
testcases used for that implementation report) to the W3C before
releasing an unprefixed implementation of any CSS features. Testcases
submitted to W3C are subject to review and correction by the CSS
Working Group.
This is a diff spec over CSS Containment Level 2.
It is currently an Exploratory Working Draft:
if you are implementing anything, please use Level 2 as a reference.
We will merge the Level 2 text into this draft once it reaches CR. ↵
In general, the relationship between an element’s inline size
and it’s block size
is unpredictable and non-monotonic,
with the block size capable of shifting up and down arbitrarily
as the inline size is changed.
Infinite cycles are prevented
by ensuring that layout does not revert to a previous (known-problematic) state,
even if a naive analysis of the constraints would allow for such;
in other words, layout always “moves forward”.
We believe that current CSS layout specifications incorporate such rules,
but to the extent that they don’t,
please inform the CSSWG so that these errors can be corrected. ↵
Container Queries should have a matchContainer method.
This will be modeled on matchMedia() and the MediaQueryList interface,
but applied to Elements rather than the Window.
When measuring layout sizes, it behaves Similar to resizeObserver,
but it provides the additional Container Query syntax and features. [Issue #6205]↵