W3C

SMIL Animation

W3C Recommendation 04-September-2001

This version:
http://www.w3.org/TR/2001/REC-smil-animation-20010904/
Latest version:
http://www.w3.org/TR/smil-animation
Previous version:
http://www.w3.org/TR/2001/PR-smil-animation-20010719
Editor(s)
Patrick Schmitz ([email protected]), Microsoft
Aaron Cohen ([email protected]), Intel


Abstract

This is a W3C Recommendation of a specification of animation functionality for XML documents.  It describes an animation framework as well as a set of base XML animation elements suitable for integration with XML documents. It is based upon the SMIL 1.0 timing model, with some extensions, and is a true subset of SMIL 2.0. This provides an intermediate stepping stone in terms of implementation complexity, for applications that wish to have SMIL-compatible animation but do not need or want time containers.

Status of this document

This section describes the status of this document at the time of its publication. Other documents may supersede this document. The latest status of this document series is maintained at the W3C.

This document has been reviewed by W3C Members and other interested parties and has been endorsed by the Director as a W3C Recommendation. It is a stable document and may be used as reference material or cited as a normative reference from another document. W3C's role in making the Recommendation is to draw attention to the specification and to promote its widespread deployment. This enhances the functionality and interoperability of the Web.

The SMIL Animation specification has been produced as part of the W3C Synchronized Multimedia Activity and was written by the SYMM Working Group (members only) of the W3C Interaction Domain, working with the SVG Working Group (members only) of the W3C Document Formats Domain. The goals of the SYMM Working Group are discussed in the SYMM Working Group charter (members only), (revised July 2000 from original charter version).

The SYMM Working Group (members only) considers that all features in the SMIL 2.0 specification have been implemented at least twice in an interoperable way. The SYMM Working Group Charter (members only) defines this as the implementations having been developed independently by different organizations and each test in the SMIL 2.0 test suite has at least two passing implementations. The Implementation results are publicly released and are intended solely to be used as proof of SMIL 2.0 implementability. It is only a snap shot of the actual implementation behaviors at one moment of time, as these implementations may not be immediately available to the public. The interoperability data is not intended to be used for assessing or grading the performance of any individual implementation.

There are patent disclosures and license commitments associated with the SMIL 2.0 specification (and thus with the SMIL Animation specification also), these may be found on the SYMM Patent Statement page in conformance with W3C policy.

Please report errors in this document to [email protected]. The list of known errors in this specification is available at http://www.w3.org/2001/09/REC-smil-animation-20010904-errata.

A list of current W3C Recommendations and other technical documents can be found at http://www.w3.org/TR.


Quick Table of Contents

1. Introduction
2. Overview and terminology
3. Animation model
4. Animation elements
5. Integrating SMIL Animation into a host language
6. Document Object Model support
7. Appendix: Differences from SMIL 1.0 timing model
8. References


Full Table of Contents

1. Introduction

2. Overview and terminology
    2.1. Basics of animation
    2.2. Animation function values
    2.3. Symbols used in the semantic descriptions

3. Animation model
    3.1. Specifying the animation target
    3.2. Specifying the animation function f(t)
        3.2.1. Animation function timing
        3.2.2. Animation function values
        3.2.3. Animation function calculation modes
    3.3. Specifying the animation effect F(t)
       3.3.1. Repeating animation
       3.3.2. Controlling the active duration
       3.3.3. The min and max attributes
       3.3.4. Computing the active duration
       3.3.5. Freezing animations
       3.3.6. Additive animation
       3.3.7. Restarting animations
    3.4. Handling syntax errors
    3.5. The animation sandwich model
    3.6. Timing model details
       3.6.1. Timing and real-world clock times
       3.6.2. Interval timing
       3.6.3. Unifying event-based and scheduled timing
       3.6.4. Event sensitivity
       3.6.5. Hyperlinks and timing
       3.6.6. Propagating changes to times
       3.6.7. Timing attribute value grammars
       3.6.8. Evaluation of begin and end time lists
    3.7. Animation function value details
    3.8. Common syntax DTD definitions

4. Animation elements
    4.1. The animate element
    4.2. The set element
    4.3. The animateMotion element
    4.4. The animateColor element

5. Integrating SMIL Animation into a host language
    5.1. Required host language definitions
    5.2. Required definitions and constraints on animation targets
    5.3. Constraints on manipulating animation elements
    5.4. Required definitions and constraints on element timing
    5.5. Error handling semantics
    5.6. SMIL Animation namespace

6. Document Object Model support
    6.1. Events and event model
    6.2. Supported interfaces
    6.3. IDL definition
    6.4. Java language binding
    6.5. ECMAScript language binding

7. Appendix: Differences from SMIL 1.0 timing model

8. References


1. Introduction

This document describes a framework for incorporating animation onto a time line and a mechanism for composing the effects of multiple animations.  A set of basic animation elements are also described that can be applied to any [XML]-based language. A language with which this module is integrated is referred to as a host language. A document containing animation elements is referred to as a host document.

Animation is inherently time-based. SMIL Animation is defined in terms of the SMIL timing model.  The animation capabilities are described by new elements with associated attributes and semantics, as well as the SMIL timing attributes. Animation is modeled as a function that changes the presented value of a specific attribute over time.

The timing model is based upon SMIL 1.0 [SMIL1.0], with some changes and extensions to support additional timing features. SMIL Animation uses a simplified "flat" timing model, with no time containers (like <par> or <seq>). This version of SMIL Animation may not be used with documents that otherwise contain timing. See also Required definitions and constraints on element timing.

While this document defines a base set of animation capabilities, it is assumed that host languages may build upon the support to define additional or more specialized animation elements.  In order to ensure a consistent model for document authors and runtime implementers, we introduce a framework for integrating animation with the SMIL timing model. Animation only manipulates attributes and properties of the target elements, and so does not require any specific knowledge of the target element semantics.

The examples in this document that include syntax for a host language use SMIL, SVG, XHTML and CSS. These are provided as an indication of possible integrations with various host languages.

2. Overview and terminology

2.1. Basics of animation

Animation is defined as a time-based manipulation of a target element (or more specifically of some attribute of the target element, the target attribute). The animation defines a mapping of time to values for the target attribute. This mapping accounts for all aspects of timing, as well as animation-specific semantics. 

Animations specify a begin, and a simple duration that can be repeated. Each animation defines an animation function that produces a value for the target attribute, for any time within the simple duration. The author can specify how long or how many times an animation function should repeat. The simple duration combined with any repeating behavior defines the active duration.

The target attribute is the name of a feature of a target element as defined in a host language document. This may be (e.g.) an XML attribute contained in the element or a CSS property that applies to the element.  By default, the target element of an animation will be the parent of the animation element (an animation element is typically a child of the target element). However, the target may be any element in the document, identified either by an ID reference or via an XLink [XLink] locator reference.

As a simple example, the following defines an animation of an SVG rectangle shape.  The rectangle will change from being tall and thin to being short and wide.

<rect ...>
   <animate attributeName="width"  from="10px"  to="100px" 
            begin="0s" dur="10s" />
   <animate attributeName="height" from="100px" to="10px"
            begin="0s" dur="10s" />
</rect>

The rectangle begins with a width of 10 pixels and increases to a width of 100 pixels over the course of 10 seconds. Over the same ten seconds, the height of the rectangle changes from 100 pixels to 10 pixels.

When an animation is running, it should not actually change the attribute values in the DOM [DOM-Level-2].  The animation runtime should maintain a presentation value for each animated attribute, separate from the DOM or CSS Object Model (OM). If an implementation does not support an object model, it should maintain the original value as defined by the document as well as the presentation value. The presentation value is reflected in the display form of the document. Animations thus manipulate the presentation value, and should not affect the base value exposed by DOM or CSS OM. This is detailed in The animation sandwich model.

The animation function is evaluated as needed over time by the implementation, and the resulting values are applied to the presentation value for the target attribute. Animation functions are continuous in time and can be sampled at whatever frame rate is appropriate for the rendering system. The syntactic representation of the animation function is independent of this model, and may be described in a variety of ways. The animation elements in this specification support syntax for a set of discrete or interpolated values, a path syntax for motion based upon SVG paths, keyframe based timing, evenly paced interpolation, and variants on these features. Animation functions could be defined that were purely or partially algorithmic (e.g., a random value function or a motion animation that tracks the mouse position). In all cases, the animation exposes this as a function of time.

The presentation value reflects the effect of the animation upon the base value. The effect is the change to the value of the target attribute at any given time. When an animation completes, the effect of the animation is no longer applied, and the presentation value reverts to the base value by default. The animation effect can also be extended to freeze the last value for the remainder of the document duration.

Animations can be defined to either override or add to the base value of an attribute. In this context, the base value may be the DOM value, or the result of other animations that also target the same attribute. This more general concept of a base value is termed the underlying value. Animations that add to the underlying value are described as additive animations. Animations that override the underlying value are referred to as non-additive animations.

2.2. Animation function values

Many animations specify the animation function f(t) as a sequence of values to be applied over time. For some types of attributes (e.g. numbers), it is also possible to describe an interpolation function between values.

As a simple form of describing the values, animation elements can specify a from value and a to value. If the attribute takes values that support interpolation (e.g. a number), the animation function can interpolate values in the range defined by  from and to, over the course of the simple duration. A variant on this uses a by value in place of the to value, to indicate an additive change to the attribute.

More complex forms specify a list of values, or even a path description for motion. Authors can also control the timing of the values, to describe "keyframe" animations, and even more complex functions.

2.3. Symbols used in the semantic descriptions

f(t)
The simple animation function that maps times within the simple duration to values for the target attribute (0 <= t <= simple duration). Note that while F(t) defines the mapping for the entire animation, f(t) has a simplified model that just handles the simple duration.
F(t)
The effect of an animation for any point in the animation. This maps any non-negative time to a value for the target attribute. A time value of 0 corresponds to the time at which the animation begins. Note that F(t) combines the animation function f(t) with all the other aspects of animation and timing controls.

3. Animation model

This section describes the attribute syntax and semantics for describing animations. The specific elements are not described here, but rather the common concepts and syntax that comprise the model for animation.  Document issues are described, as well as the means to target an element for animation. The animation model is then defined by building up from the simplest to the most complex concepts: first the simple duration and animation function f(t), and then the overall behavior F(t).  Finally, the model for combining animations is presented, and additional details of animation timing are described.

The time model depends upon several definitions for the host document: A host document is presented over a certain time interval. The start of the interval in which the document is presented is referred to as the document begin. The end of the interval in which the document is presented is referred to as the document end. The difference between the end and the begin is referred to as the document duration. The formal definitions of presentation and document begin and end are left to the host language designer (see also Required host language definitions).

3.1. Specifying the animation target

The animation target is defined as a specific attribute of a particular element. The means of specifying the target attribute and the target element are detailed in this section.

The target attribute

The target attribute to be animated is specified with attributeName. The value of this attribute is a string that specifies the name of the target attribute, as defined in the host language.

The attributes of an element that can be animated are often defined by different languages, and/or in different namespaces. For example, in many XML applications, the position of an element (which is a typical target attribute) is defined as a CSS property rather than as XML attributes. In some cases, the same attribute name is associated with attributes or properties in more than one language, or namespace.  To allow the author to disambiguate the name mapping, an additional attribute attributeType is provided that specifies the intended interpretation.

The attributeType attribute is optional. By default, the animation runtime will resolve the names according to the following rule: If there is a name conflict and attributeType is not specified, the list of CSS properties supported by the host language is matched first (if CSS is supported in the host language); if no CSS match is made (or CSS does not apply) the default namespace for the target element will be matched.

If a target attribute is defined in an XML Namespace other than the default namespace for the target element, the author must specify the namespace of the target attribute using the associated namespace prefix as defined in the scope of the animation element. The prefix is prepended to the value for attributeName.

For more information on XML namespaces, see [XML-NS].

attributeName = <attributeName>
Specifies the name of the target attribute. An XMLNS prefix may be used to indicate the XML namespace for the attribute. The prefix will be interpreted in the scope of the animation element.
 
attributeType = "CSS | XML | auto"
Specifies the namespace in which the target attribute and its associated values are defined. The attribute value is one of the following (values are case-sensitive):
"CSS"
This specifies that the value of "attributeName" is the name of a CSS property, as defined for the host document. This argument value is only meaningful in host language environments that support CSS.
"XML"
This specifies that the value of "attributeName" is the name of an XML attribute defined in the default XML namespace for the target element. Note that if the value for attributeName has an XMLNS prefix, the implementation must use the associated namespace as defined in the scope of the animation element.
"auto"
The implementation should match the attributeName to an attribute for the target element. The implementation must first search through the the list of CSS properties for a matching property name, and if none is found, search the default XML namespace for the element.
This is the default.

The target element

An animation element can define the target element of the animation either explicitly or implicitly. An explicit definition uses an attribute to specify the target element. The syntax for this is described below.

If no explicit target is specified, the implicit target element is the parent element of the animation element in the document tree. It is expected that the common case will be that an animation element is declared as a child of the element to be animated. In this case, no explicit target need be specified.

If an explicit target element reference cannot be resolved (e.g. if no such element can be found), the animation has no effect. In addition, if the target element (either implicit or explicit) does not support the specified target attribute, the animation has no effect. See also Handling syntax errors.

The following two attributes can be used to identify the target element explicitly:

targetElement = "<IDREF>"
This attribute specifies the target element to be animated. The attribute value must be the value of an XML identifier attribute of an element within the host document. For a formal definition of "IDREF", refer to XML 1.0 [XML]. 
href = uri-reference
This attribute specifies an XLink locator, referring to the target element to be animated.

When integrating animation elements into the host language, the language designer should avoid including both of these attributes. If however, the host language designer chooses to include both attributes in the host language, then when both are specified for a given animation element the XLink href attribute takes precedence over the targetElement attribute.

The advantage of using the targetElement attribute is the simpler syntax of the attribute value compared to the href attribute. The advantage of using the XLink href attribute is that it is extensible to a full linking mechanism in future versions of SMIL Animation, and the animation element can be processed by generic XLink processors. The XLink form is also provided for host languages that are designed to use XLink for all such references. The following two examples illustrate the two approaches.

This example uses the simpler targetElement syntax:

<animate targetElement="foo" attributeName="bar" .../>

This example uses the more flexible XLink locator syntax, with the equivalent target.

<foo xmlns:xlink="http://www.w3.org/1999/xlink">
   ...
   <animate xlink:href="#foo" attributeName="bar" .../>
   ...
</foo>

When using an XLink href attribute on an animation element, the following additional XLink attributes need to be defined in the host language. These may be defined in a DTD, or the host language may require these in the document syntax to support generic XLink processors. For more information, refer to the "XML Linking Language (XLink)" [XLink].

The following XLink attributes are required by the XLink specification. The values are fixed, and so may be specified as such in a DTD. All other XLink attributes are optional, and do not affect SMIL Animation semantics.

type = 'simple'
Identifies the type of XLink being used. To link to the target element, a simple link is used, and thus the attribute value must be "simple". 
actuate = 'onLoad'
Indicates that the link to the target element is followed automatically (i.e., without user action).
show = 'embed'
Indicates that the reference does not include additional content in the file. 

Additional details on the target element specification as relates to the host document and language are described in Required definitions and constraints on animation targets.

3.2. Specifying the animation function f(t)

Every animation function defines the value of the attribute at a particular moment in time. The time range for which the animation function is defined is the simple duration. The animation function does not produce defined results for times outside the range of 0 to the simple duration.

3.2.1. Animation function timing

The basic timing for an element is described using the begin and dur attributes. Authors can specify the begin time of an animation in a variety of ways, ranging from simple clock times to the time that an event like a mouse-click happens. The length of the simple duration is specified using the dur attribute. The attribute syntax is described below. The normative syntax rules for each attribute value variant are described in Timing attribute value grammars. A syntax summary is provided here as an aid to the reader.

This section is normative

begin
Defines when the element becomes active. 
The attribute value is a semi-colon separated list of values.
begin-value-list : begin-value (";" begin-value-list )?
A semi-colon separated list of begin values. The interpretation of a list of begin times is detailed in the section Evaluation of begin and end time lists.
begin-value : ( offset-value | syncbase-value | event-value | repeat-value | accessKey-value | media-marker-value | wallclock-sync-value | "indefinite" )
Describes the element begin.
offset-value : ( "+" | "-" )? Clock-value
Specifies the presentation time at which the animation begins. The begin is defined relative to the document begin.
syncbase-value : ( Id-value "." ( "begin" | "end" ) ) ( ( "+" | "-" ) Clock-value )?
Describes a syncbase and an offset from that syncbase. The element begin is defined relative to the begin or active end of another element.
event-value : ( Id-value "." )? ( event-ref  ) ( ( "+" | "-" ) Clock-value )?
Describes an event and an optional offset that determine the element begin. The animation begin is defined relative to the time that the event is raised. Events may be any event defined for the host language in accordance with [DOM2Events]. These may include user-interface events, event-triggers transmitted via a network, etc. Details of event-based timing are described in the section below on Unifying event-based and scheduled timing.
repeat-value : ( Id-value "." )? "repeat(" integer ")" ( ( "+" | "-" ) Clock-value )?
Describes a qualified repeat event. The element begin is defined relative to the time that the repeat event is raised with the specified iteration value.
accessKey-value : "accessKey(" character ")"
Describes an accessKey that determines the element begin. The element begin is defined relative to the time that the accessKey character is input by the user.
wallclock-sync-value : "wallclock(" wallclock-value ")"
Describes the element begin as a real-world clock time. The wallclock time syntax is based upon syntax defined in [ISO8601].
"indefinite"
The begin of the animation will be determined by a "beginElement()" method call or a hyperlink targeted to the animation element.
The SMIL Animation DOM methods are described in the Supported methods section.
Hyperlink-based timing is described in the Hyperlinks and timing section.
Begin value semantics

This section is normative

This section is informative

The begin value can specify a list of times. This can be used to specify multiple "ways" or "rules" to begin an element, e.g. if any one of several events is raised. A list of times can also define multiple begin times, allowing the element to play more than once (this behavior can be controlled, e.g. to only allow the earliest begin to actually be used - see also Restarting animations). 

In general, the earliest time in the list determines the begin time of the element. There are additional constraints upon the evaluation of the begin time list, detailed in Evaluation of begin and end time lists.

Note that while it is legal to include "indefinite" in a list of values for begin, "indefinite" is only really useful as a single value. Combining it with other values does not impact begin timing, as DOM begin methods can be called with or without specifying "indefinite" for begin.

Handling negative offsets for begin

This section is informative

The use of negative offsets to define begin times merely defines the synchronization relationship of the element. It does not in any way override the time container constraints upon the element, and it cannot override the constraints of presentation time. 

This section is normative

The computed begin time defines the scheduled synchronization relationship of the element, even if it is not possible to begin the element at the computed time. The time model uses the computed begin time, and not the observed time of the element begin. 

This section is normative

The element will actually begin at the time computed according to the following algorithm:

Let o be the offset value of a given begin value,
d be the associated simple duration, 
AD be the associated active duration.
Let rAt be the time when the begin time becomes resolved.
Let rTo be the resolved sync-base or event-base time without the offset
Let rD be rTo - rAt.  If rD < 0 then rD is set to 0.
 
If AD is indefinite, it compares greater than any value of o or ABS(o).
REM( x, y ) is defined as x - (y * floor( x/y )). 
If y is indefinite, REM( x, y ) is just x.

Let mb = REM( ABS(o), d ) - rD
If ABS(o) >= AD then the element does not begin.
Else if mb >= 0 then the media begins at mb.
Else the media begins at mb + d.

If the element repeats, the iteration value of the repeat event has the calculated value based upon the above computed begin time, and not the observed number of repeats.

This section is informative

Thus for example:

<animate begin="foo.click-8s" dur="3s" repeatCount="10" .../>

The animation begins when the user clicks on the element "foo". Its calculated begin time is actually 8 seconds earlier, and so it begins to play at 2 seconds into the 3 second simple duration, on the third repeat iteration. One second later, the fourth iteration of the element will begin, and the associated repeat event will have the iteration value set to 3 (since it is zero based). The element will end 22 seconds after the click. The beginEvent event is raised when the element begins, but has a time stamp value that corresponds to the defined begin time, 8 seconds earlier. Any time dependents are activated relative to the computed begin time, and not the observed begin time. 

Note: If script authors wish to distinguish between the computed repeat iterations and observed repeat iterations, they can count actual repeat events in the associated event handler.

dur
Specifies the simple duration.
The attribute value can be one of the following types of values:
Clock-value
Specifies the length of the simple duration in presentation time.
Value must be greater than 0.
"indefinite"
Specifies the simple duration as indefinite.

If no begin is specified, the default value is "0" - the animation begins when the document begins. If there is any error in the argument value syntax for begin, the default value for begin will be used.

If the animation does not have a dur attribute, the simple duration is indefinite. Note that interpolation will not work if the simple duration is indefinite (although this may still be useful for <set> elements). See also Interpolation and indefinite simple durations.

If there is any error in the argument value syntax for dur, the attribute will be ignored (as though it were not specified), and so the simple duration will be indefinite.

If the begin is specified to be "indefinite" or specifies an event-base, the time of the begin is not actually known until the element is activated (e.g., with a hyperlink, DOM method call or the referenced event). The time is referred to as unresolved when it is not known. At the point at which the element begin is activated, the time becomes resolved. This is described in detail in Unifying event-based and scheduled timing.

Examples

The following examples all specify a begin at midnight on January 1st 2000, UTC

begin="wallclock(2000-01-01Z)"
begin="wallclock( 2000-01-01T00:00Z )"
begin="wallclock( 2000-01-01T00:00:00Z )"
begin="wallclock( 2000-01-01T00:00:00.0Z )"
begin="wallclock( 2000-01-01T00:00:00.0Z )"
begin="wallclock( 2000-01-01T00:00:00.0-00:00 )"

The following example specifies a begin at 3:30 in the afternoon on July 28th 1990, in the Pacific US time zone:

begin="wallclock( 1990-07-28T15:30-08:00 )"

The following example specifies a begin at 8 in the morning wherever the document is presented:

begin="wallclock( 08:00 )"

3.2.2. Animation function values

In addition to the target attribute and the timing, an animation must specify how to change the value over time. An animation can be described either as a list of values, or in a simplified form using from, to and by values.

from = "<value>"
Specifies the starting value of the animation.
to = "<value>"
Specifies the ending value of the animation.
by = "<value>"
Specifies a relative offset value for the animation.
values = "<list>"
A semicolon-separated list of one or more values. Vector-valued attributes are supported using the vector syntax of the attributeType domain.

If a list of values is used, the animation will apply the values in order over the course of the animation (pacing and interpolation between these values is described in the next section). If a list of values is specified, any from, to and by attribute values are ignored.

The simpler from/to/by syntax provides for several variants. To use one of these variants, one of by or to must be specified; a from value is optional. It is not legal to specify both by and to attributes - if both are specified, only the to attribute will be used (the by will be ignored). The combinations of attributes yield the following classes of animation:

from-to animation
Specifying a from value and a to value defines a simple animation, equivalent to a values list with 2 values. The animation function is defined to start with the from value, and to finish with the to value.
from-by animation
Specifying a from value and a by value defines a simple animation in which the animation function is defined to start with the from value, and to change this over the course of the simple duration by a delta specified with the by attribute. This may only be used with attributes that support addition (e.g. most numeric attributes).
by animation
Specifying only a by value defines a simple animation in which the animation function is defined to offset the underlying value for the attribute, using a delta that varies over the course of the simple duration, starting from a delta of 0 and ending with the delta specified with the by attribute. This may only be used with attributes that support addition.
to animation
This describes an animation in which the animation function is defined to start with the underlying value for the attribute, and finish with the value specified with the to attribute. Using this form, an author can describe an animation that will start with any current value for the attribute, and will end up at the desired to value.

The last two forms "by animation" and "to animation" have additional semantic constraints when combined with other animations. The details of this are described below in the section How from, to and by attributes affect additive behavior.

The animation values specified in the animation element must be legal values for the specified attribute. See also Animation function value details

Leading and trailing white space, and white space before and after semicolon separators, will be ignored.

If any values (i.e., the argument-values for from, to, by or values attributes) are not legal, the animation will have no effect (see also Handling Syntax Errors). Similarly, if none of the from, to, by or values attributes are specified, the animation will have no effect.

Interpolation and indefinite simple durations

If the simple duration of an animation is indefinite (e.g., if no dur value is specified), interpolation is not generally meaningful. While it is possible to define an animation function that is not based upon a defined simple duration (e.g., some random number algorithm), most animations define the function in terms of the simple duration. If an animation function is defined in terms of the simple duration and the simple duration is indefinite, the first value of the animation function (i.e., f(0)) should be used (effectively as a constant) for the animation function.

Examples

The following example using the values syntax animates the width of an SVG shape over the course of 10 seconds, interpolating from a width of 40 to a width of 100 and back to 40.

<rect ...>
   <animate attributeName="width" values="40;100;40" dur="10s"/>
</rect>

The following "from-to animation" example animates the width of an SVG shape over the course of 10 seconds from a width of 50 to a width of 100.

<rect ...>
   <animate attributeName="width" from="50" to="100" dur="10s"/>
</rect>

The following "from-by animation" example animates the width of an SVG shape over the course of 10 seconds from a width of 50 to a width of 75.

<rect ...>
   <animate attributeName="width" from="50" by="25" dur="10s"/>
</rect>

The following "by animation" example animates the width of an SVG shape over the course of 10 seconds from the original width of 40 to a width of 70.

<rect width="40"...>
   <animate attributeName="width" by="30" dur="10s"/>
</rect>

The following "to animation" example animates the width of an SVG shape over the course of 10 seconds from the original width of 40 to a width of 100.

<rect width="40"...>
   <animate attributeName="width" to="100" dur="10s"/>
</rect>

3.2.3. Animation function calculation modes

By default, a simple linear interpolation is performed over the values, evenly spaced over the duration of the animation.  Additional attributes can be used for finer control over the interpolation and timing of the values. The calcMode attribute defines the method of applying values to the attribute. The keyTimes attribute provides additional control over the timing of the animation function, associating a time with each value in the values list (or the points in a path description for animateMotion - see The animateMotion element). Finally, the keySplines attribute provides a means of controlling the pacing of interpolation between the values in the values list.

calcMode = "discrete | linear | paced | spline"
Specifies the interpolation mode for the animation. This can take any of the following values.  The default mode is "linear", however if the attribute does not support linear interpolation (e.g. for strings), the calcMode attribute is ignored and discrete interpolation is used.
discrete
This specifies that the animation function will jump from one value to the next without any interpolation.
linear
Simple linear interpolation between values is used to calculate the animation function. 
This is the default calcMode.
paced
Defines interpolation to produce an even pace of change across the animation. This is only supported for values that define a linear numeric range, and for which some notion of "distance" between points can be calculated (e.g. position, width, height, etc.). If "paced" is specified, any keyTimes or keySplines will be ignored.
spline
Interpolates from one value in the values list to the next according to a time function defined by a cubic Bezier spline. The points of the spline are defined in the keyTimes attribute, and the control points for each interval are defined in the keySplines attribute.
keyTimes = "<list>"
A semicolon-separated list of time values used to control the pacing of the animation. Each time in the list corresponds to a value in the values attribute list, and defines when the value should be used in the animation function. Each time value in the keyTimes list is specified as a floating point value between 0 and 1 (inclusive), representing a proportional offset into the simple duration of the animation element.

If a list of keyTimes is specified, there must be exactly as many values in the keyTimes list as in the values list.

Each successive time value must be greater than or equal to the preceding time value.

The keyTimes list semantics depends upon the interpolation mode:

If the interpolation mode is "paced", the keyTimes attribute is ignored.

If there are any errors in the keyTimes specification (bad values, too many or too few values), the animation will have no effect.

If the simple duration is indefinite, any keyTimes specification will be ignored.

keySplines = "<list>"
A set of Bezier control points associated with the keyTimes list, defining a cubic Bezier function that controls interval pacing. The attribute value is a semicolon separated list of control point descriptions. Each control point description is a set of four floating point values: x1 y1 x2 y2, describing the Bezier control points for one time segment. The keyTimes values that define the associated segment are the Bezier "anchor points", and the keySplines values are the control points. Thus, there must be one fewer sets of control points than there are keyTimes.

The values must all be in the range 0 to 1.

This attribute is ignored unless the calcMode is set to "spline".

If there are any errors in the keySplines specification (bad values, too many or too few values), the animation will have no effect.

If calcMode is set to "discrete", "linear" or "spline", but the keyTimes attribute is not specified, the values in the values attribute are assumed to be equally spaced through the animation duration, according to the calcMode:

This semantic applies as well when the keySplines attribute is specified, but keyTimes is not. The times associated to the keySplines values are determined as described above.

The syntax for the control point sets in keySplines lists is:

control-pt-set ::= ( fpval comma-wsp fpval comma-wsp fpval comma-wsp fpval )
fpval          ::= Floating point number
comma-wsp      ::= S (spacechar|",") S

Control point values are separated by at least one white space character or a comma. Additional white space around the separator is allowed. The allowed syntax for floating point numbers must be defined in the host language.

For the shorthand forms from-to animation and from-by animation, there are only 2 values.  A discrete from-to animation will set the "from" value for the first half of the simple duration and the "to" value for the second half of the simple duration. Similarly, a discrete from-by animation will set the "from" value for the first half of the simple duration and for the second half of the simple duration will set the computed result of applying the "by" value. For the shorthand form to animation, there is only 1 value; a discrete to animation will simply set the "to" value for the simple duration.

If the  argument values for keyTimes or keySplines are not legal (including too few or too many values for either attribute), the animation will have no effect (see also Handling syntax errors).

In the calcMode, keyTimes and keySplines attribute values, leading and trailing white space and white space before and after semicolon separators will be ignored.

Interpolation modes illustrated

The three illustrations 1a, 1b and 1c below show how the same basic animation will change a value over time, given different interpolation modes. All examples use the default timing (no keyTimes or keySplines specified). All examples are based upon the following example, but with different values for calcMode:

<animate dur="30s" values="0; 1; 2; 4; 8; 15" calcMode="[as specified]" />

 

Diagram of linear interpolation
Figure 1a: Default discrete animation.

calcMode="discrete"

There are 6 segments of equal duration: 1 segment per value.

Diagram of linear interpolation
Figure 1b: Default linear animation.

calcMode="linear"

There are 5 segments of equal duration: n-1 segments for n values. Spline interpolation is a refinement of linear, and is further illustrated in Figure 2, below.

Diagram of linear interpolation
Figure 1c: Default paced animation.

calcMode="paced"

There are 5 segments of varying duration: n-1 segments for n values, computed to yield a constant rate of change in the value.

Examples

The following example describes a simple discrete animation:

<animate attributeName="foo" dur="8s" 
     values="bar; fun; far; boo" />

The value of the attribute "foo" will be set to each of the four strings for 2 seconds each. Because the string values cannot be interpolated, only discrete animation is possible; any calcMode attribute would be ignored.

Discrete animation can also be used with keyTimes, as in the following example:

<animateColor attributeName="color" dur="10s" calcMode="discrete"
     values="green; yellow; red" keyTimes="0.0; 0.5;" />

This example also shows how keyTimes values can interact with an indefinite duration. The value of the "color" attribute will be set to green for 5 seconds, and then to yellow for 5 seconds, and then will remain red for the remainder of the document, since the (unspecified) duration defaults to "indefinite".

The following example describes a simple linear animation:

<animate attributeName="x" dur="10s" values="0; 10; 100" 
     calcMode="linear"/>

The value of "x" will change from 0 to 10 in the first 5 seconds, and then from 10 to 100 in the second 5 seconds. Note that the values in the values attribute are spaced evenly in time with no keyTimes specified; in this case the result is a much larger actual change in the value during the second half of the animation. Contrast this with the same example changed to use "paced" interpolation:

<animate attributeName="x" dur="10s" values="0; 10; 100" 
     calcMode="paced"/>

To produce an even pace of change to the attribute "x", the second segment defined by the values list gets most of the simple duration: The value of "x" will change from 0 to 10 in the first second, and then from 10 to 100 in the next 9 seconds. While this example could be easily authored as a from-to animation without paced interpolation, many examples (such as motion paths) are much harder to author without the "paced" value for calcMode

The following example illustrates the use of keyTimes:

<animate attributeName="x" dur="10s" values="0; 50; 100" 
     keyTimes="0; .8; 1" calcMode="linear"/>

The keyTimes values cause the "x" attribute to have a value of "0" at the start of the animation, "50" after 8 seconds (at 80% into the simple duration) and "100" at the end of the animation. The value will change more slowly in the first half of the animation, and more quickly in the second half.

Extending this example to use keySplines:

<animate attributeName="x" dur="10s" values="0; 50; 100" 
     keyTimes="0; .8; 1" calcMode="spline" 
     keySplines=".5 0 .5 1; 0 0 1 1" />

The keyTimes still cause the "x" attribute to have a value of "0" at the start of the animation, "50" after 8 seconds and "100" at the end of the animation. However, the keySplines values define a curve for pacing the interpolation between values. In the example above, the spline causes an ease-in and ease-out effect between time 0 and 8 seconds (i.e., between keyTimes 0 and .8, and values "0" and "50"), but a strict linear interpolation between 8 seconds and the end (i.e., between keyTimes .8 and 1, and values  "50" and "100"). See Figure 2 below for an illustration of the curves that these keySplines values define.

For some attributes, the pace of change may not be easily discernable by viewers. However for animations like motion, the ability to make the speed of the motion change gradually, and not in abrupt steps, can be important. The keySplines attribute provides this control.

The following figure illustrates the interpretation of the keySplines attribute. Each diagram illustrates the effect of keySplines settings for a single interval (i.e., between the associated pairs of values in the keyTimes and values lists.). The horizontal axis can be thought of as the input value for the unit progress of interpolation within the interval - i.e., the pace with which interpolation proceeds along the given interval. The vertical axis is the resulting value for the unit progress, yielded by the keySplines function. Another way of describing this is that the horizontal axis is the input unit time for the interval, and the vertical axis is the output unit time. See also the section Timing and real-world clock times.

Example keySplines01 - keySplines of 0 0 1 1 (the default) keySplines="0 0 1 1" (the default) Example keySplines02 - keySplines of .5 0 .5 1 keySplines=".5 0 .5 1"
 
Example keySplines03 - keySplines of 0 .75 .25 1 keySplines="0 .75 .25 1" Example keySplines04 - keySplines of 1 0 .25 .25 keySplines="1 0 .25 .25"
Figure 2: Illustration of keySplines effect

To illustrate the calculations, consider the simple example:

<animate dur="4s" values="10; 20" keyTimes="0; 1"
     calcMode="spline" keySplines={as in table} />

Using the keySplines values for each of the four cases above, the approximate interpolated values as the animation proceeds are:

keySplines values  Initial value After 1s After 2s After 3s Final value
0 0 1 1 10.0 12.5 15.0 17.5 20.0
.5 0 .5 1 10.0 11.0 15.0 19.0 20.0
0 .75 .25 1 10.0 18.0 19.3 19.8 20.0
1 0 .25 .25 10.0 10.1 10.6 16.9 20.0

For a formal definition of Bezier spline calculation, see [COMP-GRAPHICS].

The keyTimes and keySplines attributes can also be used with the from/to/by shorthand forms for specifying values, as in the following example:

<animate attributeName="foo" from="10" to="20" 
     dur="10s" keyTimes="0.0; 0.7"
     calcMode="spline" keySplines=".5 0 .5 1" />

The value will change from 10 to 20, using an "ease-in/ease-out" curve specified by the keySplines values. The keyTimes values cause the value of 20 to be reached at 7 seconds, and to hold there for the remainder of the 10 second simple duration.

The following example describes a somewhat unusual usage: "from-to animation" with discrete animation. The "stroke-linecap" attribute of SVG elements takes a string, and so implies a calcMode of discrete. The animation will set the stroke-linecap property to "round" for 5 seconds (half the simple duration) and then set the stroke-linecap to "square" for 5 seconds.

<rect stroke-linecap="butt"...>
   <animate attributeName="stroke-linecap" 
      from="round" to="square" dur="10s"/>
</rect>

3.3. Specifying the animation effect F(t)

As described above, the animation function f(t) defines the animation for the simple duration. However SMIL Animation allows the author to repeat the simple duration. SMIL Animation also allows authors to specify whether the animation should simply end when the active duration completes, or whether it should be frozen at the last value.  In addition, the author can specify how each animation should be combined with other animations and the original DOM value.

This section describes the syntax and associated semantics for the additional functionality. A detailed model for combining animations is described, along with additional details of the timing model.

The period of time during which the animation is actively playing, including any repeat behavior, is described as the active duration. The active duration may be computed from the simple duration and the repeat specification, and it may be constrained with the end attribute.  The complete rules for computing the active duration are presented in the section Computing the active duration.

3.3.1. Repeating animations

Repeating an animation causes the animation function f(t) to be "played" several times in sequence.  The author can specify either how many times to repeat, using repeatCount, or how long to repeat, using repeatDur. Each repeat iteration is one instance of "playing" the animation function f(t).

If the simple duration is indefinite, the animation cannot repeat. See also the section Computing the active duration.

repeatCount
Specifies the number of iterations of the animation function. It can have the following attribute values:
numeric value
This is a (base 10) "floating point" numeric value that specifies the number of iterations. It can include partial iterations expressed as fraction values. A fractional value describes a portion of the simple duration. Values must be greater than 0.
"indefinite"
The animation is defined to repeat indefinitely (i.e., until the document ends).
repeatDur
Specifies the total duration for repeat. It can have the following attribute values:
Clock-value
Specifies the duration in presentation time to repeat the animation function f(t).
 
"indefinite"
The animation is defined to repeat indefinitely  (i.e., until the document ends).

At most one of repeatCount or repeatDur should be specified. If both are specified (and the simple duration is not indefinite), the active duration is defined as the minimum of the specified repeatDur and the simple duration multiplied by repeatCount. For the purposes of this comparison, a defined value is considered to be "less than" a value of "indefinite". If the simple duration is indefinite, and both repeatCount and repeatDur are specified, the repeatCount will be ignored, and the repeatDur will be used (refer to the examples below describing repeatDur and an indefinite simple duration). These rules are included in the section Computing the active duration.

Examples

In the following example, the 2.5 second animation function will be repeated twice; the active duration will be 5 seconds.

<animate attributeName="top" from="0" to="10" dur="2.5s"
         repeatCount="2"
/>

In the following example, the animation function will be repeated two full times and then the first half is repeated once more; the active duration will be 7.5 seconds.

<animate attributeName="top" from="0" to="10" dur="3s"
         repeatCount="2.5"
/>

In the following example, the animation function will repeat for a total of 7 seconds. It will play fully two times, followed by a fractional part of 2 seconds. This is equivalent to a repeatCount of 2.8. The last (partial) iteration will apply values in the range "0" to "8". 

<animate attributeName="top" from="0" to="10" dur="2.5s"
         repeatDur="7s" />

Note that if the simple duration is not defined (e.g. it is indefinite), repeat behavior is not defined (but repeatDur still defines the active duration). In the following example the simple duration is indefinite, and so the repeatCount is effectively ignored. Nevertheless, this is not considered an error: the active duration is also indefinite. The effect of the animation is to to just use the value for f(0), setting the fill color to red for the remainder of the document duration.

<animate attributeName="fill" from="red" to="blue" repeatCount="2" />

In the following example, the simple duration is indefinite, but the repeatDur still determines the active duration. The effect of the animation is to set the fill color to red for 10 seconds.

<animate attributeName="fill" from="red" to="blue" repeatDur="10s" />

In the following example, the simple duration is longer than the duration specified by repeatDur, and so the active duration will effectively cut short the simple duration. However, the animation function still interpolates using the specified simple duration. The effect of the animation is to interpolate the value of "top" from 10 to 17, over the course of 7 seconds.

<animate attributeName="top" from="10" to="20" 
         dur="10s" repeatDur="7s"
/>

The min attribute and restart:

The min attribute does not prevent an element from restarting before the minimum active duration is reached.

Controlling behavior of repeating animation - Cumulative animation

The author may also select whether a repeating animation should repeat the original behavior for each iteration, or whether it should build upon the previous results, accumulating with each iteration. For example, a motion path that describes an arc can repeat by moving along the same arc over and over again, or it can begin each repeat iteration where the last left off, making the animated element bounce across the window. This is called cumulative animation.

Using the path notation for a simple arc (detailed in The animateMotion element), we describe this example as:

<img ...>
   <animateMotion path="m 0 0 c 30 50 70 50 100 0 z" dur="5s"
      accumulate="sum" repeatCount="4" />
</img>

The image moves from the original position along the arc over the course of 5 seconds. As the animation repeats, it builds upon the previous value and begins the second arc where the first one ended, as illustrated in Figure 3, below. In this way, the image "bounces" across the screen. The same animation could be described as a complete path of 4 arcs, but in the general case the path description can get quite large and cumbersome to edit.

Diagram showing accumlating animation

Figure 3: Illustration of repeating animation with accumulate="sum". Each repeat iteration builds upon the previous.

Note that cumulative animation only controls how a single animation accumulates the results of the animation function as it repeats. It specifically does not control how one animation interacts with other animations to produce a presentation value. This latter behavior is described in the section Additive animation.

The cumulative behavior of repeating animations is controlled with the accumulate attribute:

accumulate = "none | sum"
Controls whether or not the animation is cumulative. 
If "sum", each repeat iteration after the first builds upon the last value of the previous iteration.
If "none", repeat iterations are not cumulative, and simply repeat the animation function f(t). This is the default.

This attribute is ignored if the target attribute value does not support addition, or if the animation element does not repeat.

Cumulative animation is not defined for "to animation". This attribute will be ignored if the animation function is specified with only the to attribute. See also Specifying function values.

Any numeric attribute that supports addition can support cumulative animation. For example, we can define a "pulsing" animation that will grow the "width" of an SVG <rect> element by 100 pixels in 50 seconds.

<rect width="20px"...>
   <animate attributeName="width" dur="5s"
      values="0; 15; 10" additive="sum"
      accumulate="sum" repeatCount="10" />
</rect>

Each simple duration causes the rectangle width to bulge by 15 pixels and end up 10 pixels larger. The shape is 20 pixels wide at the beginning, and after 5 seconds is 30 pixels wide. The animation repeats, and builds upon the previous values. The shape will bulge to 45 pixels and then end up 40 pixels wide after 10 seconds, and will eventually end up 120 (20 + 100) pixels wide after all 10 repeats.

From-to and from-by animations also support cumulative animation, as in the following example:

<rect width="20px"...>
   <animate attributeName="width" dur="5s" from="10px" to="20px"
      accumulate="sum" repeatCount="10" />
</rect>

The rectangle will grow from 10 to 20 pixels in the first 5 seconds, and then from 20 to 30 in the next 5 seconds, and so on up to 110 pixels after 10 repeats. Note that since the default value for additive is "replace", the original value is ignored. The following example makes the animation explicitly additive:

<rect width="20px"...>
   <animate attributeName="width" dur="5s" from="10px" to="20px"
      accumulate="sum" additive="sum" repeatCount="10" />
</rect>

The results are the same as before, except that all the values are shifted up by the original value of 20. The rectangle is 30 pixels wide after 5 seconds, and 130 pixels wide after 10 repeats.

Computing cumulative animation values

To produce the cumulative animation behavior, the animation function f(t) must be modified slightly. Each iteration after the first must add in the last value of the previous iteration - this is expressed as a multiple of the last value specified for the animation function. Note that cumulative animation is defined in terms of the values specified for the animation behavior, and not in terms of sampled or rendered animation values. The latter would vary from machine to machine, and could even vary between document views on the same machine.

Let fi(t) represent the cumulative animation function for a given iteration i.

The first iteration f0(t) is unaffected by accumulate, and so is the same as the original animation function definition.

f0(t) = f(t)

Let ve be the last value specified for the animation function (e.g., the "to" value, the last value in a "values" list, or the end of a "path").  Each iteration after the first adds in the computed offset:

fi(t) = (ve * i) + f(t)     ; i >= 1

3.3.2. Controlling the active duration

SMIL Animation provides an additional control over the active duration. The end attribute allows the author to constrain the active duration of the animation by specifying an end value, using a simple offset, a time base, an event-base or DOM method calls. The end attribute can constrain but not extend the active duration that is otherwise defined by dur and any repeat behavior. The rules for combining the attributes to compute the active duration are presented in the section, Computing the active duration.

end
Defines an end value for the animation that can constrain the active duration.
The attribute value is a semi-colon separated list of values.
end-value-list : end-value (";" end-value-list )?
A semi-colon separated list of end values. The interpretation of a list of end times is detailed in the section Evaluation of begin and end time lists.
end-value : ( offset-value | syncbase-value | event-value | repeat-value | accessKey-value | media-marker-value | wallclock-sync-value | "indefinite" )
Describes the end value.
offset-value : ( "+" | "-" )? Clock-value
Specifies the presentation time of the end. The end value is thus defined relative to the document begin.
syncbase-value : ( Id-value "." ( "begin" | "end" ) ) ( ( "+" | "-" ) Clock-value )?
Describes a syncbase and an offset from that syncbase. The end value is defined relative to the begin or active end of another element.
event-value : ( Id-value "." )? ( event-ref  ) ( ( "+" | "-" ) Clock-value )?
Describes an event and an optional offset that determine the element begin. The animation end value is defined relative to the time that the event is raised. Events may be any event defined for the host language in accordance with [DOM2Events]. These may include user-interface events, event-triggers transmitted via a network, etc. Details of event-based timing are described in the section below on Unifying event-based and scheduled timing.
repeat-value : ( Id-value "." )? "repeat(" integer ")" ( ( "+" | "-" ) Clock-value )?
Describes a qualified repeat event. The end value is defined relative to the time that the repeat event is raised with the specified iteration value.
accessKey-value : "accessKey(" character ")"
Describes an accessKey that determines the end value. The end value is defined relative to the time that the accessKey character is input by the user.
wallclock-sync-value : "wallclock(" wallclock-value ")"
Describes the end value as a real-world clock time. The wallclock time syntax is based upon syntax defined in [ISO8601].
"indefinite"
The end value of the animation will be determined by a "endElement()" (or equivalent) method call.
The SMIL Animation DOM methods are described in the Supported methods section.
Hyperlink-based timing is described in the Hyperlinks and timing section.

The end value can specify a list of times. This can be used to specify multiple "ways" or "rules" to end an element, e.g. if any one of several events is raised. A list of times can also define multiple end times that can correspond to multiple begin times, allowing the element to play more than once (this behavior can be controlled - see also Restarting animations). 

Examples:

In the following example, the active duration will end at the earlier of 10 seconds or the end of the "foo" element. This is particularly useful if "foo" is defined to begin or end relative to an event.

<animate dur="2s" repeatDur="10s" end="foo.end" ... />

In the following example, the animation begins when the user clicks on the target element. The active duration will end 30 seconds after the document begins. Note that if the user has not clicked on the target element before 30 seconds elapse, the animation will never begin.

<animate begin="click" dur="2s" repeatDur="indefinite"
         end="30s" ... />

Using end with an event value enables authors to end an animation based on either an interactive event or a maximum active duration. This is sometimes known as lazy interaction.

In this example, a presentation describes some factory processes. It uses animation to move an image around (e.g. against a background), demonstrating how an object moves from one part of a factory to another. Each step is a motion path, and set to repeat 3 times to make the point clear. Each animation can also be ended by clicking on some element "next" that allows the user to advance the presentation to the next step.

<img id="objectToMove" ... >
  <animateMotion id="step1" begin="0" dur="5s"
     repeatCount="3" end="next.click" path.../>
  <animateMotion id="step2" begin="step1.end" dur="5s"
     repeatCount="3" end="next.click" path.../>
  <animateMotion id="step3" begin="step2.end" dur="5s"
     repeatCount="3" end="next.click" path.../>
  <animateMotion id="step4" begin="step3.end" dur="5s"
     repeatCount="3" end="next.click" path.../>
  <animateMotion id="step5" begin="step4.end" dur="5s"
     repeatCount="3" end="next.click" path.../>
</img>

In this case, the active end of each animation is defined to be the earlier of 15 seconds after it begins, or a click on "next". This lets the viewer sit back and watch, or advance the presentation at a faster pace.

3.3.3. The min and max attributes: more control over the active duration

This section is informative

The min/max attributes provide the author with a way to control the lower and upper bound of the element active duration.

This section is normative

min
Specifies the minimum value of the active duration.
The attribute value can be either of the following:
Clock-value
Specifies the length of the minimum value of the active duration, measured in element active time.
Value must be greater than or equal to 0.
"media"
Specifies the minimum value of the active duration as the intrinsic media duration. This is only valid for elements that define media.

If there is any error in the argument value syntax for min, the attribute will be ignored (as though it were not specified). 

The default value for min is "0". This does not constrain the active duration at all. 

max
Specifies the maximum value of the active duration.
The attribute value can be either of the following:
Clock-value
Specifies the length of the maximum value of the active duration, measured in element active time.
Value must be greater than 0.
"media"
Specifies the maximum value of the active duration as the intrinsic media duration. This is only valid for elements that define media.
"indefinite"
The maximum value of the duration is indefinite, and so is not constrained.

If there is any error in the argument value syntax for max, the attribute will be ignored (as though it were not specified).

The default value for max is "indefinite". This does not constrain the active duration at all. 

If the "media" argument value is specified for either min or max on an element that does not define media, the respective attribute will be ignored (as though it were not specified).

If both min and max attributes are specified then the max value must be greater than or equal to the min value. If this requirement is not fulfilled then both attributes are ignored.

The rule to apply to compute the active duration of an element with min or max specified is the following: Each time the active duration of an element is computed (i.e. for each interval of the element if it begins more than once), this computation is made without taking into account the min and max attributes (by applying the algorithm described in Computing the active duration). The result of this step is checked against the min and max bounds. If the result is within the bounds, this first computed value is correct. Otherwise two situations may occur:

The min attribute and negative begin times

If an element is defined to begin before its parent (e.g. with a simple negative offset value), the min duration is measured from the calculated begin time not the observed begin (see example 1 below). This means that the min value may have no observed effect.

See also the section The min attribute and restart.

3.3.4. Computing the active duration

The table in Figure 4 shows the semantics of all possible combinations of simple duration, repeatCount and repeatDur, and end. The following conventions are used in the table:

Additionally, the following rules must be followed in computing values:

Some of the rules and results that are implicit in the table, and that should be noted in particular are:

The following symbols are used in the table:

B
The begin of an animation.
d
The simple duration of an animation.
Simple
duration d
repeatCount repeatDur end Active Duration
defined       d
defined defined     repeatCount*d
defined   defined   repeatDur
defined     defined MIN( d, end-B )
defined defined defined   MIN( repeatCount*d, repeatDur )
defined defined   defined MIN( repeatCount*d, ( end-B ))
defined   defined defined MIN( repeatDur, ( end-B ))
defined defined defined defined MIN( repeatCount*d, repeatDur, ( end-B ))
indefinite *     indefinite
indefinite * defined   repeatDur
indefinite *   defined end-B
indefinite * defined defined MIN( repeatDur, ( end-B ))
* indefinite     indefinite
*   indefinite   indefinite
* indefinite indefinite   indefinite
* indefinite   defined end-B
*   indefinite defined end-B
* indefinite indefinite defined end-B
Figure 4: Computing the active duration for different combinations of simple duration, repeatCount and repeatDur, and end.

3.3.5. Freezing animations

By default when an animation element ends, its effect is no longer applied to the presentation value for the target attribute. For example, if an animation moves an image and the animation element ends, the image will "jump back" to its original position.

<img top="3" ...>
   <animate begin="5s" dur="10s" attributeName="top" by="100"/>
</img>

The image will appear stationary at the top value of "3" for 5 seconds, then move 100 pixels down in 10 seconds. 15 seconds after the document begin, the animation ends, the effect is no longer applied, and the image jumps back from 103 to 3 where it started (i.e., to the underlying value of the top attribute).

The fill attribute can be used to maintain the value of the animation after the active duration of the animation element ends:

<img top="3" ...>
   <animate begin= "5s" dur="10s" attributeName="top" by="100"
          fill="freeze" />
</img>

The animation ends 15 seconds after the document begin, but the image remains at the top value of 103. The attribute freezes the last value of the animation for the remainder of the document duration.

The freeze behavior of an animation is controlled using the "fill "attribute:

fill = "freeze | remove"
This attribute can have the following values:
freeze
The animation effect F(t) is defined to freeze the effect value at the last value of the active duration. The animation effect is "frozen" for the remainder of the document duration (or until the animation is restarted - see Restarting animations). 
remove
The animation effect is removed (no longer applied) when the active duration of the animation is over. After the active end of the animation, the animation no longer affects the target (unless the animation is restarted - see Restarting animations).
This is the default value.

If the active duration cuts short the simple duration (including the case of partial repeats), the effect value of a frozen animation is defined by the shortened simple duration. In the following example, the animation function repeats two full times and then again for one-half of the simple duration. In this case, the value while frozen will be 15: 

<animate from="10" to="20" dur="4s" 
         repeatCount="2.5" fill="freeze" .../> 

In the following example, the dur attribute is missing, and so the simple duration is indefinite. The active duration is constrained by end to be 10 seconds. Since interpolation is not defined, the value while frozen will be 10:

<animate from="10" to="20" end="10s" fill="freeze" .../> 
Comparison to SMIL timing

SMIL Animation specifies that fill="freeze" remains in effect for the remainder of the document, or until the element is restarted. In the more general SMIL timing model that allows time containers, the duration of the freeze effect is controlled by the time container, and never extends past the end of the time container simple duration. While this may appear to conflict, the SMIL Animation definition of fill="freeze" is consistent with the SMIL timing model. It is simply the case that in SMIL Animation, the document is the only "time container", and so the effect is as described above.

3.3.6. Additive animation

It is frequently useful to define animation as an offset or delta to an attribute's value, rather than as absolute values. A simple "grow" animation can increase the width of an object by 10 pixels:

<rect width="20px" ...>
   <animate attributeName="width" from="0px" to="10px" dur="10s"
      additive="sum"/>
</rect>

The width begins at 20 pixels, and increases to 30 pixels over the course of 10 seconds.  If the animation were declared to be non-additive, the same from and to values would make the width go from 0 to 10 pixels over 10 seconds.

In addition, many complex animations are best expressed as combinations of simpler animations. A "vibrating" path, for example, can be described as a repeating up and down motion added to any other motion:

<img ...>
   <animateMotion from="0,0" to="100,0" dur="10s" />
   <animateMotion values="0,0; 0,5; 0,0" dur="1s"
                  repeatDur="10s" additive="sum"/>
</img>

When there are multiple animations defined for a given attribute that overlap at any moment, the two either add together or one overrides the other. Animations overlap when they are both either active or frozen at the same moment. The ordering of animations (e.g. which animation overrides which) is determined by a priority associated with each animation. The animations are prioritized according to when each begins. The animation first begun has lowest priority and the most recently begun animation has highest priority.

Higher priority animations that are not additive will override all earlier (lower priority) animations, and simply set the attribute value.  Animations that are additive apply (i.e. add to) to the result of the earlier-activated animations. For details on how animations are combined, see The animation sandwich model.

The additive behavior of an animation is controlled by the additive attribute:

additive = "replace | sum"
Controls whether or not the animation is additive. 
sum
Specifies that the animation will add to the underlying value of the attribute and other lower priority animations.
replace
Specifies that the animation will override the underlying value of the attribute and other lower priority animations. This is the default, however the behavior is also affected by the animation value attributes by and to, as described below.

Additive animation is defined for numeric attributes and other data types for which some addition function is defined. This includes numeric attributes for concepts such as position, widths and heights, sizes, etc. This also includes color (refer to The animateColor element), and may include other data types as specified by the host language.

It is often useful to combine additive animations and fill behavior, for example when a series of motions are defined that should build upon one another:

<img ...>
   <animateMotion begin="0" dur="5s" path="[some path]"
           additive="sum" fill="freeze" />
   <animateMotion begin="5s" dur="5s" path="[some path]"
           additive="sum" fill="freeze" />
   <animateMotion begin="10s" dur="5s" path="[some path]"
           additive="sum" fill="freeze" />
</img>

The image moves along the first path, and then starts the second path from the end of the first, then follows the third path from the end of the second, and stays at the final point.

While many animations of numerical attributes will be additive, this is not always the case. As an example of an animation that is defined to be non-additive, consider a hypothetical extension animation "mouseFollow" that causes an object to track the mouse. 

<img ...>
   <animateMotion dur=10s repeatDur="indefinite"
           path="[some nice path]" />
   <mouseFollow begin="mouseover" dur="5s"
           additive="replace" fill="remove" />
</img>

The mouse-tracking animation runs for 5 seconds every time the user mouses over the image. It cannot be additive, or it will just offset the motion path in some odd way. The mouseFollow needs to override the animateMotion while it is active. When the mouseFollow completes, its effect is no longer applied and the animateMotion again controls the presentation value for position.

In addition, some numeric attributes (e.g., a telephone number attribute) may not sensibly support addition - it is left to the host language to specify which attributes support additive animation. Attribute types such as strings and Booleans for which addition is not defined, cannot support additive animation.

How from, to and by attributes affect additive behavior.

The attribute values to and by, used to describe the animation function, can override the additive attribute in certain cases:

For the hybrid case of a to-animation, the animation function f(t) is defined in terms of the underlying value, the specified to value, and the current value of t (i.e. time) relative to the simple duration d.

d
is the simple duration
t
is a time within the simple duration (0 <= t <= d)
vcur
is the current base value (at time t)
vto
is the defined "to" value

f(t) = vcur + ((vto - vcur) * (t/d))

Note that if no other (lower priority) animations are active or frozen, this defines simple interpolation. However if another animation is manipulating the base value, the to-animation will add to the effect of the lower priority, but will dominate it as it nears the end of the simple duration, eventually overriding it completely. The value for F(t) when a to-animation is frozen (at the end of the simple duration) is just the to value. If a to-animation is frozen anywhere within the simple duration (e.g., using a repeatCount of "2.5"), the value for F(t) when the animation is frozen is the value computed for the end of the active duration. Even if other, lower priority animations are active while a to-animation is frozen, the value for F(t) does not change.

Multiple to-animations will also combine according to these semantics. The higher-priority animation will "win", and the end result will be to set the attribute to the final value of the higher-priority to-animation.

Multiple by-animations combine according to the general rules for additive animation and the animation sandwich model.

The use of from values does not imply either additive no non-additive animation, and both are possible. The from value for an additive animation is simply added to the underlying value, just as for the initial value is in animations specified with a values list. Additive behavior for from-to and from-by animations is controlled by the additive attribute, as in the general case.

For an example of additive to-animation, consider the following two additive animations. The first, a by-animation applies a delta to attribute "x" from 0 to -10. The second, a to-animation animates to a final value of 10.

 <foo x="0" .../>
    <animate id="A1" attributeName="x" 
        by="-10" dur="10s" fill="freeze" />
    <animate id="A2" attributeName="x" 
        to="10"  dur="10s" fill="freeze" />
 </foo>

The presentation value for "x" in the example above, over the course of the 10 seconds is presented in Figure 5 below. These values are simply computed using the formula described above. Note that the value for F(t) for A2 is the presentation value for "x".

 

Time F(t) for A1 F(t) for A2
 0 0 0
 1 -1 0.1
 2 -2 0.4
 3 -3 0.9
 4 -4 1.6
 5 -5 2.5
 6 -6 3.6
 7 -7 4.9
 8 -8 6.4
 9 -9 8.1
10 -10 10
Figure 5:  Effect of Additive to-animation example
Additive and Cumulative animation

The accumulate attribute should not be confused with the  additive attribute. The additive attribute defines how an animation is combined with other animations and the base value of the attribute.  The accumulate attribute defines only how the animation function interacts with itself, across repeat iterations.

Typically, authors expect cumulative animations to be additive (as in the examples described for accumulate above), but this is not required. The following example is cumulative but not additive.

<img ...>
   <animate dur="10s" repeatDur="indefinite"
            attributeName="top" from="20" by="10"
            additive="replace" accumulate="sum" />
</img>

The animation overrides whatever original value was set for "top", and begins at the value 20. It moves down by 10 pixels to 30, then repeats. It is cumulative, so the second iteration starts at 30 and moves down by another 10 to 40. Etc.

When a cumulative animation is also defined to be additive, the two features function normally. The accumulated effect for F(t) is used as the value for the animation, and is added to the underlying value for the target attribute. Refer also to The animation sandwich model.

3.3.7. Restarting animation

When an animation is defined to begin at a simple offset (e.g. begin="5s" ), there is an unequivocal time when the element begins. However, if an animation is defined to begin relative to an event (e.g. begin="foo.click" ), the event can happen at any time, and moreover can happen more than once (e.g., if the user clicks on "foo" several times). In some cases, it is desirable to restart an animation if a second begin event is received. In other cases, an author may want to preclude this behavior. The restart attribute controls the circumstances under which an animation is restarted:

restart = "always | whenNotActive | never"
always
The animation can be restarted at any time. 
This is the default value.
whenNotActive
The animation can only be restarted when it is not active (i.e., it can be restarted after the active end). Attempts to restart the animation during its active duration are ignored.
never
The animation cannot be restarted for the remainder of the document duration.

Note that there are several ways that an animation may be restarted. The behavior (i.e. to restart or not) in all cases is controlled by the restart attribute. The different restart cases are:

When an animation restarts, the defining semantic is that it behaves as though this were the first time the animation had begun, independent of any earlier behavior. The animation effect F(t) is defined independent of the restart behavior. Any effect of an animation playing earlier is no longer applied, and only the current animation effect F(t) is applied.

If an additive animation is restarted while it is active or frozen, the previous effect of the animation (i.e. before the restart) is no longer applied to the attribute. Note in particular that cumulative animation is defined only within the active duration of an animation. When an animation restarts, all accumulated context is discarded, and the animation effect F(t) begins accumulating again from the first iteration of the restarted active duration.

When an active element restarts, the element first ends the active duration, propagates this to time dependents and raises an endEvent in the normal manner (see also Evaluation of begin and end time lists).

For details on when and how the restart attribute is evaluated, see Evaluation of begin and end time lists

Note that using restart can also allow the author to define a single UI event to both begin and end an element, as follows:

<img ...>
   <animate id="foo" begin="click" dur="2s"
       repeatDur="indefinite" end="click"
       restart="whenNotActive" ... />
</img>

If "foo" were defined with the default restart behavior "always", a second click on the image would simply restart the animation. However, since the second click cannot restart the animation when restart is set to "whenNotActive", the click will just end the active duration and stop the animation. This is sometimes described as "toggle" activation. See also Event sensitivity and Unifying event-based and scheduled timing.

Resetting element state

This section is normative

When an element restarts, certain state is "reset":

Comparison to SMIL timing

SMIL Animation specifies that restart="never" precludes restart for the remainder of the document duration. In the more general SMIL 2.0 [SMIL20] timing model that allows time containers, the duration of the restart="never" semantic is defined by the time container, and only extends to the end of the time container simple duration. While this may appear to conflict, the SMIL Animation definition of restart="never" is consistent with the SMIL timing model. It is simply the case that in SMIL Animation, the document is the only "time container", and so the effect is as described above.

3.4. Handling syntax errors

The specific error handling mechanisms for each attribute are described with the individual syntax descriptions.  Some of these specifications describe the behavior of an animation with syntax errors as "having no effect".  This means that the animation will continue to behave normally with respect to timing, but will not manipulate any presentation value, and so will have no visible impact upon the presentation. 

In particular, this means that if other animation elements are defined to begin or end relative to an animation that "has no effect", the other animation elements will begin and end as though there were no syntax errors. The presentation runtime may indicate an error, but need not halt presentation or animation of the document. 

Some host languages and/or runtimes may choose to impose stricter error handling (see also Error handling semantics for a discussion of host language issues with error handling). Authoring environments may also choose to be more intrusive when errors are detected.

3.5. The animation sandwich model

When an animation is running, it does not actually change the attribute values in the DOM.  The animation runtime should ideally maintain a presentation value for any target attribute, separate from the DOM, CSS, or other object model (OM) in which the target attribute is defined. The presentation value is reflected in the display form of the document. The effect of animations is to manipulate this presentation value, and not to affect the underlying DOM or CSS OM values.

The remainder of this discussion uses the generic term OM for both the XML DOM [DOM-Level-2] as well as the CSS-OM. If an implementation does not support an object model, it should ideally maintain the original value as defined by the document as well as the presentation value; for the purposes of this section, we will consider this original value to be equivalent to the value in the OM.

In some implementations of DOM, it may be difficult or impractical to main a presentation value as described. CSS values should always be supported as described, as the CSS-OM provides a mechanism to do so. In implementations that do not support separate presentation values for general XML DOM properties, the implementation must at least restore the original value when animations no longer have an effect. 

The rest of this discussion assumes the recommended approach using a separate presentation value.

The model accounting for the OM and concurrently active or frozen animations for a given attribute is described as a "sandwich", a loose analogy to the layers of meat and cheeses in a "submarine sandwich" (a long sandwich made with many pieces of meats and cheese layered along the length of the bread). In the analogy, time is associated with the length of the sandwich, and each animation has its duration represented by the length of bread that the layer covers. On the bottom of the sandwich is the base value taken from the OM. Each active (or frozen) animation is a layer above this. The layers (i.e. the animations) are placed on the sandwich both in time along the length of the bread, as well as in order according to priority, with higher priority animations placed above (i.e. on top of) lower priority animations. At any given point in time, you can take a slice of the sandwich and see how the animation layers stack up.

Note that animations manipulate the presentation value coming out of the OM in which the attribute is defined, and pass the resulting value on to the next layer of document processing. This does not replace or override any of the normal document OM processing cascade. 

Specifically, animating an attribute defined in XML will modify the presentation value before it is passed through the style sheet cascade, using the XML DOM value as its base. Animating an attribute defined in a style sheet language will modify the presentation value passed through the remainder of the cascade. 

In CSS2 and the DOM 2 CSS-OM, the terms "specified", "computed" and "actual" are used to describe the results of evaluating the syntax, the cascade and the presentation rendering. When animation is applied to CSS properties of a particular element, the base value to be animated is read using the (readonly) getComputedStyle() method on that element. The values produced by the animation are written into an override stylesheet for that element, which may be obtained using the getOverrideStyle() method. These new values then affect the cascade and are reflected in a new computed value (and thus, modified presentation). This means that the effect of animation overrides all style sheet rules, except for user rules with the !important property. This enables !important user style settings to have priority over animations, an important requirement for accessibility. Note that the animation may have side effects upon the document layout. See also the [CSS2] specification (the terms are defined in section 6.1), and the [DOM2CSS] specification (section 5.2.1).

Within an OM, animations are prioritized according to when each begins. The animation first begun has lowest priority and the most recently begun animation has highest priority. When two animations start at the same moment in time, the activation order is resolved as follows:

Note that if an animation is restarted (see also Restarting animations), it will always move to the top of the priority list, as it becomes the most recently activated animation. That is, when an animation restarts, its layer is pulled out of the sandwich, and added back on the very top.  In contrast, when an element repeats the priority is not affected (repeat behavior is not defined as restarting).

Each additive animation adds its effect to the result of all sandwich layers below. A non-additive animation simply overrides the result of all lower sandwich layers. The end result at the top of the sandwich is the presentation value that must be reflected in the document view.

Some attributes that support additive animation have a defined legal range for values (e.g., an opacity attribute may allow values between 0 and 1). In some cases, an animation function may yield out of range values. It is recommended that implementations clamp the results to the legal range as late as possible, before applying them to the presentation value. Ideally, the effect of all the animations active or frozen at a given point should be combined, before any clamping is performed. Although individual animation functions may yield out of range values, the combination of additive animations may still be legal. Clamping only the final result and not the effect of the individual animation functions provides support for these cases. Intermediate results may be clamped when necessary although this is not optimal. The host language must define the clamping semantics for each attribute that can be animated.  As an example, this is defined for The animateColor element

Initially, before any animations for a given attribute are active, the presentation value will be identical to the original value specified in the document (the OM value).

When all animations for a given attribute have completed and the associated animation effects are no longer applied, the presentation value will again be equal to the OM value. Note that if any animation is defined with fill="freeze", the effect of the animation will be applied as long as the document is displayed, and so the presentation value will reflect the animation effect until the document end. Refer also to the section "Freezing animations".

Some animations (e.g. animateMotion) will implicitly target an attribute, or possibly several attributes (e.g. the "posX" and "posY" attributes of some layout model). These animations must be combined with any other animations for each attribute that is affected. Thus for example, an animateMotion animation may be in more than one animation sandwich (depending upon the layout model of the host language). For animation elements that implicitly target attributes, the host language designer must specify which attributes are implicitly targeted, and the runtime must accordingly combine animations for the respective attributes. 

Note that any queries (via DOM interfaces) on the target attribute will reflect the OM value, and will not reflect the effect of animations. Note also that the OM value may still be changed via the OM interfaces (e.g. using script). While it may be useful or desired to provide access to the final presentation value after all animation effects have been applied, such an interface is not provided as part of SMIL Animation. A future version may address this.

Although animation does not manipulate the OM values, the document display must reflect changes to the OM values. Host languages can support script languages that can manipulate attribute values directly in the OM. If an animation is active or frozen while a change to the OM value is made, the behavior is dependent upon whether the animation is defined to be additive or not, as follows: (see also the section Additive animation). 

3.6. Timing model details

3.6.1. Timing and real-world clock times

Throughout this specification, animation is described as a function of "time". In particular, the animation function is described as producing a value for any "time" in the range of the simple duration. However, the simple duration can be repeated, and the animation can begin and restart in many ways.  As such, there is no direct relationship between the "time" that an animation function uses, and the real world concept of time as reflected on a clock.

When a keySplines attribute is used to adjust the pacing between values in an animation, the semantics can be thought of as changing the pace of time in the given interval. An equivalent model is that keySplines simply changes the pace at which interpolation progresses through the given interval. The two interpretations are equivalent mathematically, and the significant point is that the notion of "time" as defined for the animation function f(t) should not be construed as real world clock time. For the purposes of animation, "time" can behave quite differently from real world clock time.

3.6.2. Interval timing

SMIL Animation assumes the most common model for interval timing. This describes intervals of time (i.e. durations) in which the begin time of the interval is included in the interval, but the end time is excluded from the interval. This is also referred to as end-point exclusive timing. This model makes arithmetic for intervals work correctly, and provides sensible models for sequences of intervals.

Background rationale

In the real world, this is equivalent to the way that seconds add up to minutes, and minutes add up to hours.  Although a minute is described as 60 seconds, a digital clock never shows more than 59 seconds. Adding one more second to "00:59" does not yield "00:60" but rather "01:00", or 1 minute and 0 seconds. The theoretical end time of 60 seconds that describes a minute interval is excluded from the actual interval.

In the world of media and timelines, the same applies: Let A be a video, a clip of audio, or an animation. Assume "A" begins at 10 and runs until 15 (in any units - it does not matter). If "B" is defined to follow "A", then it begins at 15 (and not at 15 plus some minimum interval). When an animation runtime engine actually renders out frames (or samples for audio), and must render the time "15", it should not show both a frame of "A" and a frame of "B", but rather should only show the new element "B". This is the same for audio, or for any interval on a timeline. If the model does not use endpoint-exclusive timing, it will draw overlapping frames, or have overlapping samples of audio, of sequenced animations, etc.

Note that transitions from "A" to "B" also adhere to the interval timing model. They do require that "A" not actually end at 15, and that both elements actually overlap. Nevertheless, the "A" duration is simply extended by the transition duration (e.g. 1 second). This new duration for "A" is also endpoint exclusive - at the end of this new duration, the transition will be complete, and only "B" should be rendered - "A" is no longer needed.

Implications for animation

For animation, several results of this are important: the definition of repeat, and the value sampled during the "frozen" state.

When repeating an animation, the arithmetic follows the end-point exclusive model. Consider the example:

  <animation dur="4s" repeatCount="4" .../>

At time 0, the simple duration is sampled at 0, and the first value is applied.  This is the inclusive begin of the interval. The simple duration is sampled normally up to 4 seconds. However, the appropriate way to map time on the active duration to time on the simple duration is to use the remainder of division by the simple duration:

  simpleTime = REMAINDER( activeTime, d ) 

or

  F(t) = f( REMAINDER( t, d ) )  where t is within the active duration

Note: REMAINDER( t, d ) is defined as t - d*floor(t/d)

Using this, a time of 4 (or 8 or 12) maps to the time of 0 on the simple duration. The endpoint of the simple duration is excluded from (i.e. not actually sampled on) the simple duration.

This implies that the last value of an animation function f(t) may never actually be applied (e.g. for a linear interpolation).  This may be true in the case of an animation that does not repeat and does not specify fill="freeze". However, in the following example, the appropriate value for the frozen state is clearly the "to" value:

  <animation from="0" to="5" dur="4s" fill=freeze .../>

This does not break the interval timing model, but does require an additional qualification for the animation function F(t) while in the frozen state:

The definition of accumulate also aligns to this model. The arithmetic is effectively inverted and values accumulate by adding in a multiple of the last value defined for the animation function f(t).

3.6.3. Unifying interactive and scheduled timing

SMIL Animation describes extensions to SMIL 1.0 to support interactive timing of animation elements. These extensions allow the author to specify that an animation should begin or end in response to an event (such as a user-input event like "click"), or to a hyperlink activation, or to a DOM method call.

The syntax to describe this uses event-value specifications and the special argument value "indefinite" for the begin and end attribute values. Event values describe user interface and other events. DOM method calls to begin or end an animation require that the associated attribute use the special value "indefinite". A hyperlink can also be targeted at an animation element that specifies begin="indefinite". The animation will begin when the hyperlink is activated (usually by the user clicking on the anchor). It is not possible to directly control the active end of an animation using hyperlinks.

Background

The current model represents an evolution from earlier multimedia runtimes. These were typically either pure, static schedulers or pure event-based systems.  Scheduler models present a linear timeline that integrates both discrete and continuous media.   Scheduler models tend to be good for storytelling, but have limited support for user-interaction. Event-based systems, on the other hand, model multimedia as a graph of event bindings.  Event-based systems provide flexible support for user-interaction, but generally have poor scheduling facilities; they are best applied to highly interactive and experiential multimedia.

The SMIL 1.0 model is primarily a scheduling model, but with some flexibility to support continuous media with unknown duration. User interaction is supported in the form of timed hyperlinking semantics, but there was no support for activating individual elements via interaction.

Modeling interactive, event-based content in SMIL

To integrate interactive content into SMIL timing, the SMIL 1.0 scheduler model is extended to support several new concepts: indeterminate timing, and activation of the element.

With indeterminate timing, an element has an undefined begin or end time.  The element still exists within the constraints of the document, but the begin or end time is determined by some external activation. Activation may be event-based (such as by a user-input event), hyperlink based (with a hyperlink targeted at the element), or DOM based (e.g., by a call to the beginElement() method).  From a scheduling perspective, the time is described as unresolved before the activation. Once the element begin or end has been activated, the time is resolved.

The event-activation support provides a means of associating an event with the begin or active end time for an element.  When the event is raised (e.g., when the user clicks on something), the associated time is resolved to a determinate time.  For event-based begin times, the element becomes active (begins to play) at the time that the event is raised (plus any specified offset). The element plays from the beginning of the animation function.  For event-based active end times, the element becomes inactive (stops playing) when the associated event is raised.

Note that an event based end will not be activated until the element has already begun. Any specified end event is ignored before the element begins. See also Event sensitivity.

Note that when an element restarts, any event-based end time that was resolved in the previous instance of play, will be reset to the unresolved state.

Related to event-activation is link-activation.  Hyperlinking has defined semantics in SMIL 1.0 to seek a document to a point in time. When combined with indeterminate timing, hyperlinking yields a variant on interactive content. A hyperlink can be targeted at an element that does not have a scheduled begin time. When the link is traversed, the element begins. The details of when hyperlinks activate an element, and when they seek the document timeline are presented in the next section. 

Note that hyperlink activation only applies to an element begin time, and not to the element end. Event and DOM based activation can apply to both begin and end times.

Note that elements can define the begin or end relative to another element, using a syncbase-value (the begin or end of another element). If the syncbase element is in turn defined with, for example, event-based times, the syncbase value is not resolved, and so the begin or end of the current element is also unresolved. For a begin or end time to be resolved, any referenced syncbase value must also be resolved.

3.6.4. Event sensitivity

This section is informative

The timing model supports synchronization based upon unpredictable events such as DOM events or user interface generated events. The model for handling events is that the notification of the event is delivered to the timing element, and the timing element uses a set of rules to resolve any synchronization dependent upon the event.

This section is normative

The semantics of element sensitivity to events are described by the following set of rules:

  1. If an element is not active, then events are only handled for begin specifications. Thus if an event is raised and begin specifies the event, the element begins. While the element is not active, any end specification of the event is ignored.
  2. If an element is (already) active when an event is raised, and begin specifies the event, then the behavior depends upon the value of restart:
    1. If restart="always", then a new begin time is resolved for the element based on the event time. Any specification of the event in end is ignored for this event instance.
    2. If restart="never" or restart="whenNotActive", then any begin specification of the event is ignored for this instance of the event. If end specifies the event, an end value is resolved based upon the event time, and the active duration is re-evaluated (according to the rules in Computing the active duration).

It is important to notice that in no case is a single event occurrence used to resolve both a begin and end time on the same element.

User event sensitivity and timing

The timing model and the user event model are largely orthogonal. While the timing model does reference user events, it does not define how these events are generated, and in particular does not define semantics of keyboard focus, mouse containment, "clickability", and related issues. Because timing can affect the presentation of elements, it may impact the rules for user event processing, however it only has an effect to the extent that the presentation of the element is affected.

3.6.5. Hyperlinks and timing

Hyperlinking semantics must be specifically defined for animation in order to ensure predictable behavior. Earlier hyperlinking semantics, such as those defined by SMIL 1.0 are insufficient because they do not handle indeterminate and interactive timing. Here we extend SMIL 1.0 semantics for use in presentations that include animations with indeterminate and interactive timing.

Hyperlinking behavior is described as seeking the document. To seek in this sense means to advance the document timeline to the specified time. 

A hyperlink may be targeted at an animation element by specifying the value of the id attribute of an animation element in the fragment part of the link locator. Traversing a hyperlink that refers to an animation will behave according to the following rules:

  1. If the target element is active, seek the document time back to the (current) begin time of the element. If there are multiple begin times, use the begin time that corresponds to the current "begin instance".
  2. Else if the target element begin time is resolved (i.e., there is any resolved time in the list of begin times, or if the begin time was forced by an earlier hyperlink or a beginElement() method call), seek the document time (forward or back, as needed) to the earliest resolved begin time of the target element. Note that the begin time may be resolved as a result of an earlier hyperlink, DOM or event activation. Once the begin time is resolved, hyperlink traversal always seeks.
  3. Else (animation begin time is unresolved) just resolve the target animation begin time at current document time. Disregard the sync-base or event base of the animation, and do not "back-propagate" any timing logic to resolve the child, but rather treat it as though it were defined with begin="indefinite" and just resolve begin time to the current document time.

Note that hyperlink activation does not introduce any restart behavior, and is not subject to the restart attribute semantics.

If a seek of the document presentation time is required, it may be necessary to seek either forward or backward, depending upon the resolved begin time of the element and the current time at the moment of hyperlink traversal. 

After seeking a document forward, the document should be in the same state as if the user had allowed the presentation to run normally from the current time until reaching the animation element begin time (but had otherwise not interacted with the document). In particular, seeking the presentation time forward should also cause any other animation elements that have resolved begin times between the current time and the seeked-to time to begin. These elements may have ended, or may still be active or frozen at the seeked-to time, depending upon their begin times and active durations. Also any animation elements currently active at the time of hyperlinking should "fast-forward" over the seek interval. These may end or may be still active or frozen at the seeked-to time, depending upon their active durations. The net effect is that seeking forward to a presentation time puts the document into a state identical to that as if the document presentation time advanced undisturbed to reach the seek time.

If the resolved begin time for an animation element that is the target of a hyperlink is before the current presentation time, the presentation must seek backwards. Seeking backwards will rewind any animations active during the seek interval and will turn off any animations that are resolved to begin at a time after the seeked-to time. Note that resolved begin times (e.g. a begin associated with an event) are not cleared or lost by seeking to an earlier time. Subject to the rules above for hyperlinks that target animation elements, hyperlinking to elements with resolved begin times will function normally, advancing the presentation time forward to the previously resolved time.

These hyperlinking semantics assume that a record is kept of the resolved begin time for all animation elements, and this record is available to be used for determining the correct presentation time to seek to. Once resolved, begin times are not cleared. However, they can be overwritten by subsequent resolutions driven by multiple occurrences of an event (i.e. by restarting). For example: 

<animate id="A" begin="10s" .../>
<animate id="B" begin="A.begin+5s" .../>
<animate id="C" begin="click" .../>
<animate id="D" begin="C.begin+5s" .../>
...
<a href="#D">Start the last animation</a>

The begin time of elements "A" and "B" can be immediately resolved to be at 10 and 15 seconds respectively. The begin of elements "C" and "D" are unresolved when the document starts. Therefore activating the hyperlink will have no effect upon the presentation time or upon elements "C" and "D". Now, assume that "C" is clicked at 25 seconds into the presentation. The click on "C" in turn resolves "D" to begin at 30 seconds. From this point on, traversing the hyperlink will cause the presentation time to be seeked to 30 seconds.

If at 60 seconds into the presentation, the user again clicks on "C", "D" will become re-resolved to a presentation time of 65 seconds. Subsequent activation of the hyperlink will result in the seeking the presentation to 65 seconds.

3.6.6. Propagating changes to times

There are several cases in which times may change as the document is presented. In particular, when an animation time is defined relative to an event, the time (i.e. the animation begin or active end) is resolved when the event occurs. Another case arises with restart behavior - both the begin and active end time of an animation can change when it restarts. Since the begin and active end times of one animation can be defined relative to the begin or active end of other animations, any changes to times must be propagated throughout the document.

When an animation "foo" has a begin or active end time that specifies a syncbase element (e.g. "bar" as below):

<rect ...>
   <animate id="bar" end="click" .../>
   <animate id="foo" begin="bar.end" .../>
</rect>

we say that "foo" is a time-dependent of "bar" - that is, the "foo" begin time depends upon the active end of "bar". 

An element A is a time dependent of another element B if A specifies B as a syncbase element. In addition, if element A is a time dependent of element B, and if element B is a time dependent of element C (i.e., element B defines element C as a syncbase element), then element A is an indirect time dependent of element C.

When an element begins or ends, the time dependents of the element are effectively notified of the action, and the schedule for the time dependents may be affected. Note than an element must actually begin before any of the time dependents (dependent on the begin) are affected, and that an element must actually end before any of the time dependents (dependent on the end) are affected. This impacts the definition of the priority ordering of animation elements, as discussed in The animation sandwich model.

In the example above, any changes to the active end time of "bar" must be propagated to the begin of "foo". The effect of the changes depends upon the state of "foo" when the change happens, as detailed below.

If the begin time of an element is dependent upon another element (as for "foo" in the example), the resulting behavior when the syncbase element ("bar") propagates changes is determined as follows:

Note that the semantic is directly analogous to event-base timing and the restart attribute.

If the end time of an element is dependent upon another element, the semantic is much simpler:

Another way to think of this is that the end time is always recalculated, but it will not affect the presentation unless the element is currently active, or unless the element begins (or restarts) after the change happens.

3.6.7. Timing attribute value grammars

This section is normative

The syntax specifications are defined using EBNF notation as defined in [XML10]

In the syntax specifications that follow, allowed white space is indicated as "S", defined as follows (taken from the [XML10] definition for "S"):

S ::= (#x20 | #x9 | #xD | #xA)*
Begin values

This section is normative

A begin-value-list is a semi-colon separated list of timing specifiers:

begin-value-list ::= begin-value (S ";" S begin-value-list )?
begin-value      ::= (offset-value | syncbase-value 
                      | event-value
                      | repeat-value | accessKey-value
                      | wallclock-sync-value | "indefinite" )
End values

This section is normative

An end-value-list is a semi-colon separated list of timing specifiers:

end-value-list ::= end-value (S ";" S end-value-list )?
end-value      ::= (offset-value | syncbase-value 
                      | event-value
                      | repeat-value | accessKey-value
                      | wallclock-sync-value | "indefinite" )
Parsing timing specifiers

Several of the timing specification values have a similar syntax. In addition, XML ID attributes are allowed to contain the dot '.' separator character. The backslash character '\' can be used to escape the dot separator within identifier and event-name references. To parse an individual item in a value-list, the following approach defines the correct interpretation. 

  1. Strip any leading, trailing, or intervening white space characters.
  2. If the value begins with a number or numeric sign indicator (i.e. '+' or '-'), the value should be parsed as an offset value.
  3. Else if the value begins with the token "wallclock", it should be parsed as a wallclock-sync-value.
  4. Else if the value is the token "indefinite", it should be parsed as the value "indefinite".
  5. Else: Build a token substring up to but not including any sign indicator (i.e. strip off any offset). In the following, ignore any '.' separator characters preceded by a backslash '\' escape character. In addition, strip any leading backslash '\' escape character. 
    1. If the token contains no '.' separator character, then the value should be parsed as an event-value with an unspecified (i.e. default) eventbase-element.
    2. Else if the token ends with the string ".begin" or ".end", then the value should be parsed as a syncbase-value.
    3. Else, the value should be parsed as an event-value (with a specified eventbase-element). Before parsing the event value, any backslash '\' escape character after the '.' separator character should be removed.

This approach allows implementations to treat the tokens wallclock and indefinite as reserved element IDs, and begin, end and marker as reserved event names, while retaining an escape mechanism so that elements and events with those names may be referenced.

Clock values

Clock values have the following syntax:

Clock-value         ::= ( Full-clock-value | Partial-clock-value 
                          | Timecount-value )
Full-clock-value    ::= Hours ":" Minutes ":" Seconds ("." Fraction)?
Partial-clock-value ::= Minutes ":" Seconds ("." Fraction)?
Timecount-value     ::= Timecount ("." Fraction)? (Metric)?
Metric              ::= "h" | "min" | "s" | "ms"
Hours               ::= DIGIT+; any positive number
Minutes             ::= 2DIGIT; range from 00 to 59
Seconds             ::= 2DIGIT; range from 00 to 59
Fraction            ::= DIGIT+
Timecount           ::= DIGIT+
2DIGIT              ::= DIGIT DIGIT
DIGIT               ::= [0-9]

For Timecount values, the default metric suffix is "s" (for seconds). No embedded white space is allowed in clock values, although leading and trailing white space characters will be ignored.

The following are examples of legal clock values:

Fractional values are just (base 10) floating point definitions of seconds. The number of digits allowed is unlimited (although actual precision may vary among implementations). 
For example:

00.5s = 500 milliseconds
00:00.005 = 5 milliseconds
Offset values

Offset values are used to specify when an element should begin or end relative to its syncbase.

This section is normative

An offset value has the following syntax:

offset-value   ::= (( S "+" | "-" S )? ( Clock-value )

The implicit syncbase for an offset value is the document begin.

ID-Reference values

This section is normative

ID reference values are references to the value of an "id" attribute of another element in the document. 

Id-value   ::= IDREF
Syncbase values

A syncbase value starts with a Syncbase-element term defining the value of an "id" attribute of another element referred to as the syncbase element.

This section is normative

A syncbase value has the following syntax:

 Syncbase-value   ::= ( Syncbase-element "." Time-symbol )
                      ( S ("+"|"-") S Clock-value )? 
 Syncbase-element ::= Id-value
 Time-symbol      ::= "begin" | "end"

The syncbase element is qualified with one of the following time symbols:

begin
Specifies the begin time of the syncbase element.
end
Specifies the Active End of the syncbase element.

Examples:

  begin="x.end-5s"      : Begin 5 seconds before "x" ends
  begin=" x.begin "     : Begin when "x" begins
  begin="x.begin + 1m"  : End 1 minute after "x" begins

Event values

This section is informative

An Event value starts with an Eventbase-element term that specifies the event-base element. The event-base element is the element on which the event is observed. Given DOM event bubbling, the event-base element may be either the element that raised the event, or it may be an ancestor element on which the bubbled event can be observed. Refer to [DOM2Events] for details.

This section is normative

An event value has the following syntax:

  Event-value       ::= ( Eventbase-element "." )? Event-symbol 
                        ( S ("+"|"-") S Clock-value )? 
  Eventbase-element ::= ID

The eventbase-element must be another element contained in the host document.

If the Eventbase-element term is missing, the event-base element is defined to be the target element of the animation,

The event value must specify an Event-symbol. This term specifies the name of the event that is raised on the Event-base element. The host language designer must specify which events can be specified.

The last term specifies an optional offset-value that is an offset from the time of the event.

This section is informative

This module defines several events that may be included in the supported set for a host language, including beginEvent and endEvent. These should not be confused with the syncbase time values. See the section on Events and event model.

The semantics of event-based timing are detailed in Unifying Scheduling and Interactive Timing.

Examples:

 begin=" x.load "        : Begin when "load" is observed on "x"
 begin="x.focus+3s"      : Begin 3 seconds after an "focus" event on "x"
 begin="x.endEvent+1.5s" : Begin 1 and a half seconds after an "endEvent" event on "x"
 begin="x.repeat"        : Begin each time a repeat event is observed on "x"

Repeat values

Repeat values are a variant on event values that support a qualified repeat event. The repeat event defined in Events and event model allows an additional suffix to qualify the event based upon an iteration value.

A repeat value has the following syntax:

Repeat-value       ::= ( Eventbase-element "." )? "repeat(" iteration ")"
                        ( S ("+"|"-") S Clock-value )? 
iteration          ::= DIGIT+ 

If this qualified form is used, the eventbase value will only be resolved when a repeat is observed that has a iteration value that matches the specified iteration.  

The qualified repeat event syntax allows an author to respond only to an individual repeat of an element.

The following example describes a qualified repeat eventbase value:

<animate id="foo" repeatCount="10" end="endAnim.click" ... />
<img id="endAnim" begin="foo.repeat(2)" .../>

The "endAnim" image will appear when the animate element "foo" repeats the second time. This example allows the user to stop the animation after it has played though at least twice.

AccessKey values

AccessKey values allow an author to tie a begin or end time to a particular keypress, independent of focus issues. It is modeled on the HTML accessKey support. Unlike with HTML, user agents should not require that a modifier key (such as "ALT") be required to activate an access key.

An access key value has the following syntax:

  AccessKey-value  ::= "accessKey(" character ")"
                       ( S ("+"|"-") S Clock-value )? 

The character is a single character from [ISO10646].

The time value is defined as the time that the access key character is input by the user.

Wallclock-sync values

This section is informative

Wallclock-sync values have the following syntax. The values allowed are based upon several of the "profiles" described in [DATETIME], which is based upon [ISO8601].

This section is normative

wallclock-val  ::= "wallclock(" S (DateTime | WallTime)  S ")"
DateTime       ::= Date "T" WallTime
Date           ::= Years "-" Months "-" Days
WallTime       ::= (HHMM-Time | HHMMSS-Time)(TZD)?
HHMM-Time      ::= Hours24 ":" Minutes
HHMMSS-Time    ::= Hours24 ":" Minutes ":" Seconds ("." Fraction)?
Years          ::= 4DIGIT;
Months         ::= 2DIGIT; range from 01 to 12
Days           ::= 2DIGIT; range from 01 to 31
Hours24        ::= 2DIGIT; range from 00 to 23
4DIGIT         ::= DIGIT DIGIT DIGIT DIGIT
TZD            ::= "Z" | (("+" | "-") Hours24 ":" Minutes )

This section is informative

Complete date plus hours and minutes:

   YYYY-MM-DDThh:mmTZD (e.g. 1997-07-16T19:20+01:00)

Complete date plus hours, minutes and seconds:

   YYYY-MM-DDThh:mm:ssTZD (e.g. 1997-07-16T19:20:30+01:00)

Complete date plus hours, minutes, seconds and a decimal fraction of a second

   YYYY-MM-DDThh:mm:ss.sTZD (e.g. 1997-07-16T19:20:30.45+01:00)

Note that the Minutes, Seconds, Fraction, 2DIGIT and DIGIT syntax is as defined for Clock-values. Note that white space is not allowed within the date and time specification.

This section is normative

There are three ways of handling time zone offsets:

  1. Times are expressed in UTC (Coordinated Universal Time), with a special UTC designator ("Z").
  2. Times are expressed in local time, together with a time zone offset in hours and minutes. A time zone offset of "+hh:mm" indicates that the date/time uses a local time zone which is "hh" hours and "mm" minutes ahead of UTC. A time zone offset of "-hh:mm" indicates that the date/time uses a local time zone which is "hh" hours and "mm" minutes behind UTC.
  3. Times are expressed in local time, as defined for the presentation location. The local time zone of the end-user platform is used.

The presentation engine must be able to convert wallclock-values to a time within the document.

This section is informative

Note that the resulting begin or end time may be before the begin, or after end of the parent time container. This is not an error, but the time container constraints still apply. In any case, the semantics of the begin and end attribute govern the interpretation of the wallclock value.

3.6.8. Evaluation of begin and end time lists

This section is informative

Animation elements can have multiple begin and end values. We need to specify the semantics associated with multiple begin and end times, and how a dynamic timegraph model works with these multiple times.

The model is based around the idea of intervals for each element. An interval is defined by a begin and an end time. As the timegraph is played, more than one interval may be created for an element with multiple begin and end times. At any given moment, there is one current interval associated with each element. Intervals are created by evaluating a list of begin times and a list of end times, each of which is based upon the conditions described in the begin and end attributes for the element.

The list of begin times and the list of end times used to calculate new intervals are referred to as lists of "instance times". Each instance time in one of the lists is associated with the specification of a begin or end condition defined in the attribute syntax. Some conditions - for example offset-values - only have a single instance in the list. Other conditions may have multiple instances if the condition can happen more than once. For example a syncbase-value can have multiple instance times if the syncbase element has played several intervals, and an event-value may have multiple instance times if the event has happened more than once. 

The instance times lists for each element are initialized when the timegraph is initialized, and exist for the entire life of the timegraph. In this version of the time model without time containers, instance times remain in the lists forever, once they have been added. For example, times associated with event-values are only added when the associated event happens, but remain in the lists thereafter. Similarly, Instance times for syncbase-values are added to the list each time a new interval is created for the syncbase element, and remain in the list.

When the timegraph is initialized, each element creates a first current interval. The begin time will generally be resolved, but the end time may often be unresolved. If the element can restart while active, the current interval can end (early) at the next begin time. This interval will play, and then when it ends, the element will review the lists of begin and end instance times. If the element should play again, another interval will be created and this new interval becomes the current interval. The history of an element can be thought of as a set of intervals. 

Because the begin and end times may depend on other times that can change, the current interval is subject to change, over time. For example, if any of the instance times for the end changes while the current interval is playing, the current interval end will be recomputed and may change. Nevertheless, once a time has happened, it is fixed. That is, once the current interval has begun, its begin time can no longer change, and once the current interval has ended, its end time can no longer change. For an element to restart, it must end the current interval and then create a new current interval to effect the restart.

When a begin or end condition defines a time dependency to another element (e.g. with a syncbase-value), the time dependency is generally thought of as a relationship between the two elements. This level of dependency is important to the model when an element creates a new current interval. However, for the purposes of propagating changes to individual times, time dependencies are more specifically a dependency from a given interval of the syncbase element to a particular instance time in one of the dependent element's instance time lists. Since only the current interval's begin and end times can change, only the current interval will generate time-change notices and propagate these to the dependent instance times.

When this section refers to the begin and end times for an element, the times are described as being in document time (relative to the document begin). All sync-arcs, event arcs, wallclock values, etc. must be converted to this time space for easy comparison. 

Cycles in the timegraph must be detected and broken to ensure reasonable functioning of the implementation. A model for how to do this in the general case is described. A mechanism to support certain useful cyclic dependencies falls out of the model.

The rest of this section details the semantics of the instance times lists, the element life cycle, and the mechanisms for handling dependency relationships and cycles.

The instance times lists

Instance lists are associated with each element, and exist for the duration of the document (i.e., there is no life cycle for instance lists). Instance lists may change, and some times may be added and removed, but  the begin and end instance times lists are persistent.

Each element can have a begin attribute that defines one or more conditions that can begin the element. In addition, the timing model describes a set of rules for determining the end of the element, including the effects of an end attribute that can have multiple conditions. In order to calculate the times that should be used for a given interval of the element, we must convert the begin times and the end times into parent simple time, sort each list of times (independently), and then find an appropriate pair of times to define an interval.

The instance times can be resolved or unresolved. In the case of the end list, an additional special value "indefinite" is allowed. The lists are maintained in sorted order, with "indefinite" sorting after all other resolved times, and unresolved times sorting to the end.

For begin, the list interpretation is straightforward, since begin times are based only upon the conditions in the attribute or upon the default begin value if there is no attribute.  However, when a begin condition is a syncbase-value, the syncbase element may have multiple intervals, and we must account for this in the list of begin times associated with the conditions.

For end, the case is somewhat more complex, since the end conditions are only one part of the calculation of the end of the active duration. The instance times list for end are used together with the other SMIL Timing semantics to calculate the actual end time for an interval. 

If an instance time was defined as syncbase-values, the instance time will maintain a time dependency relationship to the associated interval for the syncbase element. This means that if the associated begin or end time of the syncbase current interval changes, then the dependent instance time for this element will change as well.

When an element creates a new interval, it notifies time dependents and provides the begin and end times that were calculated according to the semantics described in "Computing the active duration". Each dependent element will create a new instance time tied to (i.e., with a dependency relationship to) the new syncbase current interval. 

Building the instance times lists

The translation of begin or end conditions to instance times depends upon the type of condition:

If no attribute is present, the default begin value (an offset-value of 0) must be evaluated.

If a DOM method call is made to begin or end the element (beginElement(), beginElementAt(), endElement() or endElementAt()), each method call creates a single instance time (in the appropriate instance times list). These time instances are cleared upon reset just as for event times. See Resetting element state.

When a new time instance is added to the begin list, the current interval will evaluate restart semantics and may ignore the new time or it may end the current interval (this is detailed in Interaction with restart semantics). In contrast, when an instance time in the begin list changes because the syncbase (current interval) time moves, this does not invoke restart semantics, but may change the current begin time: If the current interval has not yet begun, a change to an instance time in the begin list will cause a re-evaluation of the begin instance lists, which may cause the interval begin time to change. If the interval begin time changes, a time-change notice must be propagated to all dependents, and the current interval end must also be re-evaluated.

When a new instance time is added to the end list, or when an instance time in the end list changes, the current interval will re-evaluate its end time. If it changes, it must notify dependents.

If an element has already played all intervals, there may be no current interval. In this case, additions to either list of instance times, as well as changes to any instance time in either list cause the element to re-evaluate the lists just as it would at the end of each interval (as described in End of an interval below). This may or may not lead to the creation of a new interval for the element.

When times are added to the instance times lists, they may or may not be resolved. If they are resolved, they will be converted to document time. If an instance time changes from unresolved to resolved, it will be similarly converted.

There is a difference between an unresolved instance time, and a begin or end condition that has no associated instance. If, for example, an event value condition is specified in the end attribute, but no such event has happened, there will be no associated instance time in the end list. However, if a syncbase value condition is specified for end, and if the syncbase element has a current interval, there will be an associated instance time in the end list. Since the syncbase value condition can be relative to the end of the syncbase element, and since the end of the syncbase current interval may not be resolved, the associated instance time in the end list can be unresolved. Once the syncbase current interval actually ends, the dependent instance time in the end list will get a time-change notification for the resolved syncbase interval end. The dependent instance time will convert the newly resolved syncbase time to a resolved time in document time. If the instance lists did not include the unresolved instance times, some additional mechanism would have to be defined to add the end instance time when the syncbase element's current interval actually ended, and resolved its end time. 

The list of resolved times includes historical times defined relative to sync base elements, and so can grow over time if the sync base has many intervals. Implementations may filter the list of times as an optimization, so long as it does not affect the semantics defined herein.

Element life-cycle

The life cycle of an element can be thought of as the following basic steps:

  1. Startup - getting the first interval
  2. Waiting to begin the current interval
  3. Active time - playing an interval
  4. End of an interval - compute the next one and notify dependents
  5. Post active - perform any fill and wait for any next interval

Steps 2 to 5 can loop for as many intervals as are defined before the end of the parent simple duration. At any time during step 2, the begin time for the current interval can change, and at any time during steps 2 or 3, the end time for the current interval can change. When either happens, the changes are propagated to time dependents.

When the document and the associated timegraph are initialized, the instance lists are empty. The simple offset values and any "indefinite" value in an end attribute can be added to the respective lists as part of initialization.

When an element has played all allowed instances, it can be thought of as stuck in step 5. However any changes to the instance lists during this period cause the element to jump back to step 4 and consider the creation of a new current interval. 

Startup - getting the first interval

An element life cycle begins with the beginning of the document. The cycle begins by computing the first current interval. This requires some special consideration of the lists of times, but is relatively straight-forward. It is similar to, but not the same as the action that applies when the element ends (this is described in End of an interval). The basic idea is to find the first interval for the element, and make that the current interval. However, the model should handle two edge cases:

  1. The element can begin before the document begins, and so appears to begin part way into the local timeline. The model must handle begin times before the document begin (i.e. before 0).
  2. The element has one or more intervals defined that begin and end before the document begins (before 0). These are filtered out of the model.

Thus the strict definition of the first acceptable interval for the element is the first interval that ends after the document begins. Here is some pseudo-code to get the first interval for an element. It assumes an abstract type "Time" that supports a compare function. It can be a resolved numeric value, the special value INDEFINITE (only used with end), and it can be the special value UNRESOLVED.  Indefinite compares "greater than" all resolved values, and UNRESOLVED is "greater than" both resolved values and INDEFINITE. The code uses the instance times lists associated with the begin and end attributes, as described in the previous section.

// Utility function that returns true if the end attribute specification
// includes conditions that describe event-values, repeat-values or accessKey-values.
boolean endHasEventConditions();
// Calculates the first acceptable interval for an element
// Returns:
//    Interval if there is such an interval
//    FAILURE if there is no such interval
Interval getFirstInterval()
{
Time beginAfter=-INFINITY;

while( TRUE ) // loop till return
{
   Set tempBegin = the first value in the begin list that is >= beginAfter.
   If there is no such value  // No interval
      return FAILURE;

   If there was no end attribute specified
      // this calculates the active end with no end constraint
      tempEnd = calcActiveEnd( tempBegin );
   else
   {
      // We have a begin value - get an end
      Set tempEnd = the first value in the end list that is >= tempBegin.
      // Allow for non-0-duration interval that begins immediately
      // after a 0-duration interval.
      If tempEnd == tempBegin && tempEnd has already been used in 
        an interval calculated in this method call
      {
         set tempEnd to the next value in the end list that is > tempEnd
      }         
      If there is no such value
      {
         // Events leave the end open-ended. If there are other conditions
         // that have not yet generated instances, they must be unresolved.
         if endHasEventConditions()
            OR if the instance list is empty
            tempEnd = UNRESOLVED;
         // if all ends are before the begin, bad interval
         else
            return FAILURE;
      }
      // this calculates the active dur with an end constraint
      tempEnd = calcActiveEnd( tempBegin, tempEnd );
   }

   // We have an end - is it after the parent simple begin?
   if( tempEnd > 0 )
      return( Interval( tempBegin, tempEnd ) );

   // interval is too early 
   else if( restart == never )
      // if can't restart, no good interval
      return FAILURE;

   else
      // Change beginAfter to find next interval, and loop
      beginAfter = tempEnd;

} // close while loop

} // close getFirstInterval

Note that while we might consider the case of restart=always separately from restart=whenNotActive, it would just be busy work since we need to find an interval that begins after tempEnd.

If the model yields no first interval for the element, it will never begin, and so there is nothing more to do at this point. However if there is a valid interval, the element must notify all time dependents that there is a new interval of the element. This is a notice from this element to all elements that are direct time dependents. This is distinct from the propagation of a changed time.

When a dependent element gets a "new interval" notice, this includes a reference to the new interval. The new interval will generally have a resolved begin time and may have a resolved end time. An associated instance time will be added to the begin or end instance time list for the dependent element, and this new instance time will maintain a time dependency relationship to the syncbase interval.

Waiting to begin the interval

This period only occurs if the current interval does not begin immediately when (or before) it is created. While an interval is waiting to begin, any changes to syncbase element current interval times will be propagated to the instance lists and may result in a change to the current interval.

If the element receives a "new interval" notice while it is waiting to begin, it will add the associated time (i.e., the begin or end time of the syncbase interval) to the appropriate list of resolved times.

When an instance time changes, or when a new instance time is added to one of the lists, the element will re-evaluate the begin or end time of the current interval (using the same algorithm described in the previous section).  If this re-evaluation yields a changed interval, time change notice(s) will be sent to the associated dependents.

It is possible during this stage that the begin and end times could change such that the interval would never begin (i.e., the interval end is before the interval begin). In this case, the interval must be deleted and all dependent instance times must be removed from the respective instance lists of dependent elements. These changes to the instance lists will cause re-evaluation of the dependent element current intervals, in the same manner as a changed instance time does.

Active time - playing an interval

This period occurs when the current interval is active (i.e., once it has begun, and until it has ended).  During this period, the end time of the interval can change, but the begin time cannot. If any of the instance times in the begin list change after the current interval has begun, the change will not affect the current interval. This is different from the case of adding a new instance time to the begin list, which can cause a restart.

If the element receives a "new interval" notice while it is active, it will add the associated time (i.e., the begin or end time of the syncbase interval) to the appropriate list of resolved times. If the new interval adds a time to the begin list, restart semantics are considered, and this may end the current interval.

If restart  is set to "always", then the current interval will end early if there is an instance time in the begin list that is before (i.e. earlier than) the defined end for the current interval. Ending in this manner will also send a changed  time notice to all time dependents for the current interval end. See also Interaction with restart semantics.

End of an interval

When an element ends the current interval, the element must reconsider the lists of resolved begin and end times.  If there is another legal interval defined to begin at or after the just completed end time, a new interval will be created. When a new interval is created it becomes the current interval and a new interval notice is sent to all time dependents.

The algorithm  used is very similar to that used in step 1, except that we are interested in finding an interval that begins after the most recent end.

// Calculates the next acceptable interval for an element
// Returns:
//    Interval if there is such an interval
//    FAILURE if there is no such interval
Interval getNextInterval()
{
// Note that at this point, the just ended interval is still the "current interval"
Time beginAfter=currentInterval.end;

   Set tempBegin = the first value in the begin list that is >= beginAfter.
   If there is no such value  // No interval
      return FAILURE;

   If there was no end attribute specified
      // this calculates the active end with no end constraint
      tempEnd = calcActiveEnd( tempBegin );
   else
   {
      // We have a begin value - get an end
      Set tempEnd = the first value in the end list that is >= tempBegin.
      // Allow for non-0-duration interval that begins immediately
      // after a 0-duration interval.
      If tempEnd == currentInterval.end
      {
         set tempEnd to the next value in the end list that is > tempEnd
      }         
      If there is no such value
      {
         // Events leave the end open-ended. If there are other conditions
         // that have not yet generated instances, they must be unresolved.
         if endHasEventConditions()
            OR if the instance list is empty
            tempEnd = UNRESOLVED;
         // if all ends are before the begin, bad interval
         else
            return FAILURE;
      }
      // this calculates the active dur with an end constraint
      tempEnd = calcActiveEnd( tempBegin, tempEnd );
   }

   return( Interval( tempBegin, tempEnd ) );

} // close getNextInterval
Post active

This period can extend from the end of an interval until the beginning of the next interval, or until the end of the document duration (whichever comes first). During this period, any fill behavior is applied to the element. The times for this interval can no longer change. Implementations may as an optimization choose to break the time dependency relationships since they can no longer produce changes.

Interaction with restart semantics

There are two cases in which restart semantics must be considered:

  1. When the current interval is playing, if restart="always" then any instance time (call it T) in the begin list that is after (i.e. later than) the current interval begin but earlier than the current interval end will cause the current interval to end at time T. This is the first step in restarting the element: when the current interval ends, that in turn will create any following interval.
  2. When a new instance time is added to the begin list of instance times, restart rules can apply. The new instance times may result from a begin condition that specifies one of the syncbase value conditions, for which a new instance notice is received. It may also result from a begin condition that specifies one of the event value conditions, for which the associated event happens.
    In either case, the restart setting and the state of the current interval controls the resulting behavior. The new instance time is computed (e.g., from the syncbase current interval time or from the event time, and including any offset), and added to the begin list. Then:
Cyclic dependencies in the timegraph

There are two types of cycles that can be created with SMIL timing, closed cycles and open or propagating cycles. A closed cycle results when a set of elements has mutually dependent time conditions, and no other conditions on the affected elements can affect  or change this dependency relationship, as in examples 1 and 2 below. An open or propagating cycle results when a set of elements has mutually dependent time conditions, but at least one of the conditions involved has more than one resolved condition. If any one of the elements in the cycle can generate more than one interval, the cycle can propagate. In some cases such as that illustrated in example 3, this can be very useful.

Times defined in a closed cycle are unresolved, unless some external mechanism resolves one of the element time values (for example a DOM method call or the traversal of a hyperlink that targets one of the elements). If this happens, the resolved time will propagate through the cycle, resolving all the associated time values.

Closed cycles are an error, and may cause the entire document to fail. In some implementations, the elements in the cycle may just not begin or end correctly. Examples 1 and 2 describe the most forgiving behavior, but implementations may simply reject a document with a closed cycle.

Detecting Cycles

Implementations can detect cycles in the timegraph using a visited flag on each element as part of the processing that propagates changes to time dependents. As a changed time notice is propagated, each dependent element is marked as having been visited. If the change to a dependent instance time results in a change to the current interval for that element, this change will propagate in turn to its dependents. This second chained notice happens in the context of the first time-change notice that caused it. The effect is like a stack that builds as changes propagate throughout the graph, and then unwinds when all changes have propagated. If there is a dependency cycle, The propagation path will traverse an element twice during a given propagation chain. This is a common technique use in graph traversals.

A similar approach can be used when building dependency chains during initialization of the timegraph, and when propagating new interval notices - variations on the theme will be specific to individual implementations.

When a cycle is detected, the change propagation is ignored. The element that detected the second visit ignores the second change notice, and so breaks the cycle.

Examples

Example 1: In the following example, the 2 animations define begin times that are mutually dependent. There is no way to resolve these, and so the animations will never begin.

<animate id="foo" begin="bar.begin" .../>
<animate id="bar" begin="foo.begin" .../>

Example 2: In the following example, the 3 animations define a less obvious cycle of begin and end times that are mutually dependent. There is no way to resolve these. The animation "joe" will begin but will never end, and the animations "foo" and "bar" will never begin.

<animate id="foo" begin="joe.end" .../>
<animate id="bar" begin="foo.begin" dur="3s" .../>
<animate id="joe" begin="0" end="bar.end" .../>

Example 3: In the following example, the 2 animations define begin times that are mutually dependent, but the first has multiple begin conditions that allow the cycle to propagate forwards. The animation "foo" will first be active from 0 to 3 seconds, with the second animation "bar" active from 2 to 5 seconds. As each new current interval of "foo" and "bar" are created, they will add a new instance time to the other element's begin list, and so the cycle keeps going forward. As this overlapping "ping-pong" behavior is not otherwise easy to author, these types of cycles are not precluded. Moreover, the correct behavior will fall out of the model described above.

<animate id="foo" begin="0; bar.begin+2s" dur="3s" .../>
<animate id="bar" begin="foo.begin+2s" dur="3s" .../>

Example 4: In the following example, an open cycle is described that propagates backwards. The intended behavior does not fall out of the model, and is not supported.

<par dur="10s" repeatCount="11" >
   <video id="foo" begin="0; bar.begin-1s" dur="10s" .../>
   <video id="bar" begin="foo.begin-1s" dur="10s" .../>
</par>

 

3.7. Animation function value details

Animation function values must be legal values for the specified attribute. Three classes of values are described:

  1. Unitless scalar values. These are simple scalar values that can be parsed and set without semantic constraints. This class includes integers (base 10) and floating point (format specified by the host language).
  2. String values. These are simple strings.
  3. Language abstract values. These are values like CSS-length and CSS-angle values that have more complex parsing, but that can yield numbers that may be interpolated.

The animate element can interpolate unitless scalar values, and both animate and set elements can handle String values without any semantic knowledge of the target element or attribute. The animate and set elements must support unitless scalar values and string values. The host language must define which language abstract values should be handled by these elements. Note that the animateColor element implicitly handles the abstract values for color values, and that the animateMotion element implicitly handles position and path values. 

In order to support interpolation on attributes that define numeric values with some sort of units or qualifiers (e.g. "10px", "2.3feet", "$2.99"), some additional support is required to parse and interpolate these values. One possibility is to require that the animation framework have built-in knowledge of the unit-qualified value types. However, this violates the principle of encapsulation and does not scale beyond CSS to XML languages that define new attribute value types of this form.

The recommended approach is for the animation implementation for a given host environment to support two interfaces that abstract the handling of the language abstract values. These interfaces are not formally specified, but are simply described as follows:

  1. The first interface converts a string (the animation function value) to a unitless, canonical number (either an integer or a floating point value). This allows animation elements to interpolate between values without requiring specific knowledge of data types like CSS-length. The interface will likely require a reference to the target attribute, to determine the legal abstract values. If the passed string cannot be converted to a unitless scalar, the animation element will treat the animation function values as strings, and the calcMode will default to "discrete".
  2. The second interface converts a unitless canonical number to a legal string value for the target attribute. This may, for example, simply convert the number to a string and append a suffix for the canonical units. The animation element uses the result of this to actually set the presentation value.

Support for these two interfaces ensures that an animation engine need not replicate the parser and any additional semantic logic associated with language abstract values. 

This is not an attempt to specify how an implementation provides this support, but rather a requirement for how values are interpreted. Animation behaviors should not have to understand and be able to convert among all the CSS-length units, for example. In addition, this mechanism allows for application of animation to new XML languages, if the implementation for a language can provide parsing and conversion support for attribute values.

The above recommendations notwithstanding, it is sometimes useful to interpolate values in a specific unit-space, and to apply the result using the specified units rather than canonical units. This is especially true for certain relative units such as those defined by CSS (e.g. em units). If an animation specifies all the values in the same units, an implementation may use knowledge of the associated syntax to interpolate in the unit space, and apply the result within the animation sandwich, in terms of the specified units rather than canonical units. As noted above, this solution does not scale well to the general case. Nevertheless, in certain applications (such as CSS properties), it may be desirable to take this approach.

3.8. Common syntax DTD definitions

Timing attributes

<!ENTITY % timingAttrs
  begin          CDATA  #IMPLIED 
  dur            CDATA  #IMPLIED
  end            CDATA  #IMPLIED
  restart        (always | never | 
                   whenNotActive)  "always"
  repeatCount    CDATA  #IMPLIED 
  repeatDur      CDATA  #IMPLIED
  fill           (remove | freeze) "remove"
>

Animation attributes

<!ENTITY % animAttrs
  attributeName  CDATA  #REQUIRED
  attributeType  CDATA  #IMPLIED
  additive       (replace | sum) "replace"
  accumulate     (none | sum) "none"
>
<!ENTITY % animTargetAttr
  targetElement  IDREF  #IMPLIED
>
<!ENTITY % animLinkAttrs
  type     (simple | extended | locator | arc) #FIXED "simple"
  show     (new | embed | replace) #FIXED 'embed'
  actuate  (user | auto) #FIXED 'auto'
  href     CDATA  #IMPLIED
>

4. Animation elements

4.1. The animate element

The <animate> element introduces a generic attribute animation that requires little or no semantic understanding of the attribute being animated.  It can animate numeric scalars as well as numeric vectors. It can also animate a single non-numeric attribute through a discrete set of values. The <animate> element is an empty element - it cannot have child elements.

This element supports from/to/by and values descriptions for the animation function, as well as all of the calculation modes. It supports all the described timing attributes. These are all described in respective sections above.

<!ELEMENT animate EMPTY>
<!ATTLIST animate
  %timingAttrs
  %animAttrs
  calcMode       (discrete | linear | paced | spline ) "linear"
  values         CDATA  #IMPLIED
  keyTimes       CDATA  #IMPLIED
  keySplines     CDATA  #IMPLIED
  from           CDATA  #IMPLIED
  to             CDATA  #IMPLIED
  by             CDATA  #IMPLIED
>

Numerous examples are provided above.

4.2. The set element

The <set> element provides a simple means of just setting the value of an attribute for a specified duration. As with all animation elements, this only manipulates the presentation value, and when the animation completes, the effect is no longer applied. That is, <set> does not permanently set the value of the attribute. 

The <set> element supports all attribute types, including those that cannot reasonably be interpolated and that more sensibly support semantics of simply setting a value (e.g. strings and Boolean values). The set element is non-additive. The additive and accumulate attributes are not allowed, and will be ignored if specified.

The <set> element supports all the timing attributes to specify the simple and active durations. However, the repeatCount and repeatDur attributes will just affect the active duration of the <set>, extending the effect of the <set> (since it is not really meaningful to "repeat" a static operation). Note that using fill="freeze" with <set> will have the same effect as defining the timing so that the active duration is "indefinite".

The <set> element supports a more restricted set of attributes than the  <animate> element (in particular, only one value is specified, and no interpolation control is supported):

<!ELEMENT set EMPTY>
<!ATTLIST set
  %timingAttrs
  attributeName  CDATA  #REQUIRED
  attributeType  CDATA  #IMPLIED
  to             CDATA  #IMPLIED
>
to = "<value>"
Specifies the value for the attribute during the duration of the <set> element. The argument value must match the attribute type. 

Examples

The following changes the stroke-width of an SVG rectangle from the original value to 5 pixels wide. The effect begins at 5 seconds and lasts for 10 seconds, after which the original value is again used.

<rect ...>
   <set attributeName="stroke-width" to="5px" 
            begin="5s" dur="10s" fill="remove" />
</rect>

The following example sets the class attribute of the text element to the string "highlight" when the mouse moves over the element, and removes the effect when the mouse moves off the element. 

<text>This will highlight if you mouse over it...
   <set attributeName="class" to="highlight" 
            begin="mouseover" end="mouseout" />
</text>

4.3. The animateMotion element

The <animateMotion> element will move an element along a path. The element abstracts the notion of motion and position across a variety of layout mechanisms - the host language defines the layout model and must specify the precise semantics of position and motion. The path can be described in several ways:

All values must be x, y value pairs. Each x and y value may specify any units supported for element positioning by the host language. The host language defines the default units. In addition, the host language defines the reference point for positioning an element. This is the point within the element that is aligned to the position described by the motion animation. The reference point defaults in some languages to the upper left corner of the element bounding box; in other languages the reference point may be implicit, or may be specified for an element.

The syntax for the x, y value pairs is:

coordinate-pair ::= ( coordinate comma-wsp coordinate )
coordinate      ::= Number

Coordinate values are separated by at least one white space character or a comma. Additional white space around the separator is allowed. The values of coordinate must be defined as some sort of number in the host language.

The attributeName and attributeType attributes are not used with animateMotion, as the manipulated position attribute(s) are defined by the host language. If the position is exposed as an attribute or attributes that can also be animated (e.g., as "top" and "left", or "posX" and "posY"), implementations must combine <animateMotion> animations with other animations that manipulate individual position attributes. See also The animation sandwich model.

The <animateMotion> element adds an additional syntax alternative for specifying the animation, the "path" attribute. This allows the description of a path using a subset of the SVG path syntax. Note that if a path is specified, it will override any specified values for values or from/to/by attributes. 

As noted in Animation function values, if any values (i.e., the argument-values for from, to, by or values attributes, or for the path attribute) are not legal, the animation will have no effect (see also Handling Syntax Errors). The same is true if none of the from, to, by, values or path attributes are specified.

The default calculation mode (calcMode) for animateMotion is "paced". This will produce constant velocity motion along the specified path. Note that while animateMotion elements can be additive, authors should note that the addition of two or more "paced" (constant velocity) animations may not result in a combined motion animation with constant velocity.

<!ELEMENT animateMotion EMPTY>
<!ATTLIST animateMotion
  %timingAttrs
  additive       (replace | sum) "replace"
  accumulate     (none | sum) "none"
  calcMode       (discrete | linear | paced | spline) "paced"
  values         CDATA  #IMPLIED
  from           CDATA  #IMPLIED
  to             CDATA  #IMPLIED
  by             CDATA  #IMPLIED
  keyTimes       CDATA  #IMPLIED
  keySplines     CDATA  #IMPLIED
  path           CDATA  #IMPLIED
  origin         (default) "default"
/>
path = "<path-description>"
Specifies the curve that describes the attribute value as a function of time. The supported syntax is a subset of the SVG path syntax. Support includes commands to describes lines ("MmLlHhVvZz") and Bezier curves ("Cc"). For details refer to the path specification in SVG [SVG].

Note that SVG provides two forms of path commands - "absolute" and "relative". These terms may appear to be related to the definition of additive animation and/or to the "origin" attribute, but they are orthogonal. The terms "absolute" and "relative" apply only to the definition of the path itself, and not to the operation of the animation. The "relative" commands define a path point relative to the previously specified point. The terms "absolute" and "relative" are unrelated to the definitions of both "additive" animation and any specification of "origin".

A path data segment must begin with either one of the "moveto" commands.

Move To commands - "M <x> <y>" or "m <dx> <dy>"
Start a new sub-path at the given (x,y) coordinate. If a moveto is followed by multiple pairs of coordinates, the subsequent pairs are treated as implicit lineto commands.
Line To commands - "L <x> <y>" or "l <dx> <dy>"
Draw a line from the current point to the given (x,y) coordinate which becomes the new current point. A number of coordinate pairs may be specified to draw a polyline.
Horizontal Line To commands - "H <x>" or "h <dx>"
Draws a horizontal line from the current point (cpx, cpy) to (x, cpy). Multiple x values can be provided.
Vertical Line To commands - "V <y>" or "v <dy>"
Draws a vertical line from the current point (cpx, cpy) to (cpx, y). Multiple y values can be provided.
Closepath commands - "Z" or "z"
The "closepath" causes an automatic straight line to be drawn from the current point to the initial point of the current subpath.
Cubic Bezier Curve To commands - 
  "C <x1> <y1> <x2> <y2> <x> <y>" or 
  "c <dx1> <dy1> <dx2> <dy2> <dx> <dy>"
Draws a cubic Bezier curve from the current point to (x,y) using (x1,y1) as the control point at the beginning of the curve and (x2,y2) as the control point at the end of the curve. Multiple sets of coordinates may be specified to draw a polybezier.

When a path is combined with "discrete", "linear" or "spline" calcMode settings, the number of values is defined to be the number of points defined by the path, unless there are "move to" commands within the path.  A "move to" command does not define an additional "segment" for the purposes of timing or interpolation. A "move to" command does not count as an additional point when dividing up the duration, or when associating keyTimes and keySplines values. When a path is combined with a "paced" calcMode setting, all "move to" commands are considered to have 0 length (i.e., they always happen instantaneously), and should not be considered in computing the pacing.

calcMode 
Defined as above in Animation function calculation modes, but note that the default calcMode for animateMotion is "paced". This will produce constant velocity motion across the path.

The use of "discrete" for the calcMode together with a "path" specification is allowed, but will simply jump the target element from point to point. If the keyTimes attribute is not specified, the times are derived from the points in the path specification (as described in Animation function calculation modes).

The use of "linear" for the calcMode with more than 2 points described in "values", "path" or "keyTimes" may result in motion with varying velocity. The "linear" calcMode specifies that time is evenly divided among the segments defined by the "values" or "path" (note: any "keyTimes" list defines the same number of segments). The use of "linear" does not specify that time is divided evenly according to the distance described by each segment. 

For motion with constant velocity, calcMode should be set to "paced".

For complete velocity control, calcMode can be set to "spline" and the author can specify a velocity control spline with "keyTimes" and "keySplines".

origin = "default"
Specifies the origin of motion for the animation. The values and semantics of this attribute are dependent upon the layout and positioning model of the host language. In some languages, there may be only one option (i.e. "default"). However, in CSS positioning for example, it is possible to specify a motion path relative to the container block, or to the layout position of the element. It is often useful to describe motion relative to the position of the element as it is laid out (e.g., from off screen left to the layout position, specified as from="(-100, 0)" and to="(0, 0)". Authors must be able to describe motion both in this manner, as well as relative to the container block. The origin attribute supports this distinction. Nevertheless, because the host language defines the layout model, the host language must also specify the "default" behavior, as well as any additional attribute values that are supported.

Note that the definition of the layout model in the host language specifies whether containers have bounds, and the behavior when an element is moved outside the bounds of the layout container. In CSS2 [CSS2], for example, this can be controlled with the "clip" property.

Note that for additive animation, the "origin" distinction is not meaningful.  This attribute only applies when additive is set to "replace".

4.4. The animateColor element

The <animateColor> element specifies an animation of a color attribute. The host language must specify those attributes that describe color values and can support color animation. 

All values must represent [sRGB] color values. Legal value syntax for attribute values is defined by the host language. 

Interpolation is defined on a per-color-channel basis.

<!ELEMENT animateColor EMPTY>
<!ATTLIST animateColor
  %animAttrs
  %timingAttrs
  calcMode       (discrete | linear
                  | paced | spline ) "linear"
  values         CDATA  #IMPLIED
  from           CDATA  #IMPLIED
  to             CDATA  #IMPLIED
  by             CDATA  #IMPLIED
  keyTimes       CDATA  #IMPLIED
  keySplines     CDATA  #IMPLIED
>

The values in the from/to/by and values attributes may specify negative and out of gamut values for colors.  The function defined by an individual animateColor may yield negative or out of gamut values.  The implementation must correct the resulting presentation value, to be legal for the destination (display) colorspace. However, as described in The animation sandwich model, the implementation should only correct the final combined result of all animations for a given attribute, and should not correct the effect of individual animations.

Values are corrected by "clamping" the values to the correct range. Values less than the minimum allowed value are clamped to the minimum value (commonly 0, but not necessarily so for some color profiles). Values greater than the defined maximum are clamped to the maximum value (defined by the host language) .

Note that color values are corrected by clamping them to the gamut of the destination (display) colorspace. Some implementations may be unable to process values which are outside the source (sRGB) colorspace and must thus perform clamping to the source colorspace, then convert to the destination colorspace and clamp to its gamut. The point is to distinguish between the source and destination gamuts; to clamp as late as possible, and to realize that some devices, such as inkjet printers which appear to be RGB devices, have non-cubical gamuts.

Note to implementers: When animateColor is specified as a "to animation", the animation function should assume Euclidean RGB-cube distance where deltas must be computed. See also Specifying function values and How from, to and by attributes affect additive behavior. Similarly, when the calcMode attribute for animateColor is set to "paced", the animation function should assume Euclidean RGB-cube distance to compute the distance and pacing.

5. Integrating SMIL Animation into a host language

This section describes what a language designer must actually do to specify the integration of SMIL Animation into a host language. This includes basic definitions, constraints upon animation, and allowed events and supported events.

5.1. Required host language definitions

The host language designer must define some basic concepts in the context of the particular host language.  These provide the basis for timing and presentation semantics.

The host language designer must define what "presenting a document" means. A typical example is that the document is displayed on a screen.

The host language designer must define the document begin. Possible definitions are that the document begins when the complete document has been received by a client over a network, or that the document begins when certain document parts have been received.

The host language designer must define the document end. This is typically when the associated application exits or switches context to another document.

A host language should provide a means of uniquely identifying each animation element within a document. The facility provided should be the same as for the other elements in the language. For example, since SMIL 1.0 identifies each element with an "id" attribute that contains an XML ID value for that element, animation elements added to SMIL 1.0 should also have an "id" attribute.

5.2. Required definitions and constraints on animation targets

Specifying the target element

The host language designer must choose whether to support the targetElement attribute, or the XLink attributes for specifying the target element. Note that if the XLink syntax is used, the host language designer must decide how to denote the XLink namespace for the associated attributes. The namespace can be fixed in a DTD, or the language designer can require colonized attribute names (qnames) to denote the XLink namespace for the attributes. The required XLink attributes have fixed values, and so may also be specified in a DTD, or can be required on the animation elements. Host language designers may require that the optional XLink attributes be specified. These decisions are left to the host language designer - the syntax details for XLink attributes do not affect the semantics of SMIL Animation.

In general, target elements may be any element in the document. Host language designers must specify any exceptions to this. Host language designers are discouraged from allowing animation elements to target elements outside of the document in which the animation element is defined. The XLink syntax for the target element could allow this, but the SMIL timing and animation semantics of this are not defined in this version of SMIL Animation.

Target attribute issues

The definitions in this module can be used to animate any attribute of any element in a host document. However, it is expected that host language designers integrating SMIL Animation may choose to constrain which elements and attributes can support animation. For example, a host language may choose not to support animation of the language attribute of a script element. A host language which included a specification for DOM functionality might limit animation to the attributes which may legally be modified through the DOM.

Any attribute of any element not specifically excluded from animation by the host language may be animated, as long as the underlying data type (as defined by the host language for the attribute) supports discrete values (for discrete animation) and/or addition (for interpolated and additive animation).

All constraints upon animation must be described in the host language specification or in an appropriate schema, as the DTD alone cannot reasonably express this.

The host language must define which language abstract values should be handled for animated attributes. For example, a host language that incorporates CSS may require that CSS length values be supported. This is further detailed in Animation function value details.

The host language must specify the interpretation of relative values. For example, if a value is specified as a percentage of the size of a container, the host language must specify whether this value will be dynamically interpreted as the container size is animated.

The host language must specify the semantics of clamping values for attributes. The language must specify any defined ranges for values, and how out of range values will be handled.

The host language must specify the formats supported for numeric attribute values. This includes integer values and especially floating point values for attributes such as keyTimes and keySplines. As a reasonable minimum, host language designers are encouraged to support the format described in [CSS2]. The specific reference within the CSS specification for these data types is 4.3.1 Integers and real numbers.

Integrating animateMotion functionality

The host language specification must define which elements can be the target of animateMotion. In addition, the host language specification must describe the positioning model for elements, and must describe the model for animateMotion in this context (i.e., the semantics of the "default" value for the origin attribute must be defined). If there are different ways to describe position, additional attribute values for the origin attribute should be defined to allow authors control over the positioning model.

Language integration example: SVG

As an example, SVG [SVG] integrates SMIL Animation. It specifies which of the elements, attributes and CSS properties may be animated.  Some attributes (e.g. "viewbox" and "fill-rule") support only discrete animation, and others (e.g. "width", "opacity" and "stroke") support interpolated and additive animation. An example of an attribute that does not support any animation is the xlink:actuate attribute on the <use> element.

SVG details the format of numeric values, describing the legal ranges and allowing "scientific" (exponential) notation for floating point values.

5.3. Constraints on manipulating animation elements

Language designers integrating SMIL Animation are encouraged to disallow manipulation of attributes of the animation elements, after the document has begun. This includes both the attributes specifying targets and values, as well as the timing attributes. In particular, the id attribute (of type ID) on all animation elements must not be mutable (i.e. should be read-only). Requiring animation runtimes to track changes to id values introduces considerable complexity, for what is at best a questionable feature.

It is recommended that language specifications disallow manipulation of animation element attributes through DOM interfaces after the document has begun.  It is also recommended that language specifications disallow the use of animation elements to target other animation elements.

Note in particular that if the attributeName attribute can be changed (either by animation or script), problems may arise if the target attribute has a namespace qualified name. Current DOM specifications do not include a mechanism to handle this binding.

Dynamically changing the attribute values of animation elements introduces semantic complications to the model that are not yet sufficiently resolved. This constraint may be lifted in a future version of SMIL Animation.

5.4. Required definitions and constraints on element timing

This specification assumes that animation elements are the only elements in the host language that have timing semantics (this restriction may be removed in a future version of SMIL Animation). This specification cannot be used for host languages that contain elements with timing semantics. For example, the following integration of animation with SMIL 1.0 is illegal with this version of SMIL animation:

<par id="illegalExample">
  <img begin="2s" dur="1m" src="foo.png" alt="Sad face for bad example" />
    <anchor id="anc" href="#bar" coords="0%,0%,50%,50%" dur="30s" />
    <set targetElement="anc" attributeName="coords" 
         begin="10s" dur="20s" fill="freeze"
         to="50%,50%,100%,100%" />
  </img>
</par>

The set of "animation elements" that may have timing includes both the elements defined in this specification, as well as extension animation elements defined in host languages. Extension animation elements must conform to the animation framework described in this document.  In particular, extension animation elements may not be defined to contain other animation elements in a way that would introduce hierarchic timing as supported by the par and seq elements in SMIL 1.0 [SMIL].

Supported events for event-base timing

The host language must specify which event names are legal in event base values. If the host language defines no allowed event names, event-based timing is effectively precluded for the host language. 

Host languages may specify that dynamically created events (as per the [DOM2Events] specification) are legal as event names, and not explicitly list the allowed names.

5.5. Error handling semantics

The host language designer may impose stricter constraints upon the error handling semantics. That is, in the case of syntax errors, the host language may specify additional or stricter mechanisms to be used to indicate an error. An example would be to stop all processing of the document, or to halt all animation.

Host language designers may not relax the error handling specifications, or the error handling response (as described in Handling syntax errors). For example, host language designers may not define error recovery semantics for missing or erroneous values in the values or keyTimes attribute values.

5.6. SMIL Animation namespace

Language designers can choose to integrate SMIL Animation as an independent namespace, or can integrate SMIL Animation names into a new namespace defined as part of the host language. Language designers that wish to put the SMIL Animation functionality in an isolated namespace should use the following namespace:

http://www.w3.org/2001/smil-animation

6. Document Object Model support

Any XML-based language that integrates SMIL Animation will inherit the basic interfaces defined in DOM [DOM-Level-2] (although not all languages may require a DOM implementation). SMIL Animation specifies the interaction of animation and DOM. SMIL Animation also defines constraints upon the basic DOM interfaces, and specific DOM interfaces to support SMIL Animation.

Note that the language designer integrating SMIL Animation must specify any constraints upon SMIL Animation with respect to the DOM. This includes the specification of language attributes that can or cannot be animated, as well as the definition of addition for any attributes that support additive animation.

6.1. Events and event model

This section is informative

SMIL event-timing assumes that the host language supports events, and that the events can be bound in a declarative manner. DOM Level 2 Events [DOM2Events] describes functionality to support this.

This section is normative

The specific events supported are defined by the host language. If no events are defined by a host language, event-timing is effectively omitted.

This module defines a set of events that may be included by a host language. These include:

beginEvent
This event is raised when the element local timeline begins to play. It will be raised each time the element begins the active duration (i.e., when it restarts, but not when it repeats). It may be raised both in the course of normal (i.e. scheduled or interactive) timeline play, as well as in the case that the element was begun with a DOM method.
endEvent
This event is raised at the active end of the element. Note that this event is not raised at the simple end of each repeat. This event may be raised both in the course of normal (i.e. scheduled or interactive) timeline play, as well as in the case that the element was ended with a DOM method.
repeat
This event is raised when the element local timeline repeats. It will be raised each time the element repeats, after the first iteration. Associated with the repeat  event is an integer that indicates which repeat iteration is beginning. The value is a 0-based integer, but the repeat event is not raised for the first iteration and so the observed values will be >= 1.

If an element is restarted while it is currently playing, the element will raise an endEvent and then a beginEvent, as the element restarts.

The beginEvent may not be raised at the time that is calculated as the begin for an element. For example the element can specify a begin time before the beginning of the document (either with a negative offset value, or with a syncbase time that resolves to a time before the document begin). In this case, a time dependent of the begin syncbase time will be defined relative to the calculated begin time. The beginEvent will be raise when the element actually begins - in the example case when the document begins. Similarly, the endEvent is raised when the element actually ends, which may differ from the calculated end time (e.g., when the end is specified as a negative offset from a user event). See also the discussion Propagating changes to times.

6.2. Supported interfaces

SMIL Animation supports several methods for controlling the behavior of animation: beginElement(), beginElementAt(), endElement(), and endElementAt(). These methods are used to begin and end the active duration of an element. Authors can (but are not required to) declare the timing to respond to the DOM using the following syntax:

<animate begin="indefinite" end="indefinite" .../>

If a DOM method call is made to begin or end the element (using beginElement(), beginElementAt(), endElement() or endElementAt()), each method call creates a single instance time (in the appropriate instance times list). These times are then interpreted as part of the semantics of lists of times, as described in Evaluation of begin and end time lists.

The expectation of the following interface is that an instance of the ElementTimeControl interface can be obtained by using binding-specific casting methods on an instance of an animate element. A DOM application can use the hasFeature method of the DOMImplementation interface to determine whether the ElementTimeControl interface is supported or not. The feature string for this interface is "TimeControl".

Interface ElementTimeControl

IDL Definition
interface ElementTimeControl {
  boolean            beginElement();
  boolean            beginElementAt(in float offset));
  boolean            endElement();
  boolean            endElementAt(in float offset);
};


Methods
beginElement
Creates a begin instance time for the current time.
Return Value
void
No Parameters
beginElementAt
Creates a begin instance time for the current time plus or minus the passed offset.
Parameters
float offset The offset in seconds at which to begin the element.
Return Value
void
endElement
Creates an end instance time for the current time.
Return Value
void
No Parameters
endElementAt
Creates an end instance time for the current time plus or minus the passed offset.
Parameters
float offset The offset in seconds at which to end the element. Must be >= 0.
Return Value
void
Interface TimeEvent
The TimeEvent interface provides specific contextual information associated with Time events.

IDL Definition
interface TimeEvent : events::Event {
  readonly attribute views::AbstractView  view;
  readonly attribute long             detail;
  void               initTimeEvent(in DOMString typeArg, 
                                   in views::AbstractView viewArg, 
                                   in long detailArg);
};


Attributes
view of type views::AbstractView, readonly
The view attribute identifies the AbstractView from which the event was generated.

 

detail of type long, readonly
Specifies some detail information about the Event, depending on the type of event.

 

Methods
initTimeEvent
The initTimeEvent method is used to initialize the value of a TimeEvent created through the DocumentEvent interface. This method may only be called before the TimeEvent has been dispatched via the dispatchEvent method, though it may be called multiple times during that phase if necessary. If called multiple times, the final invocation takes precedence.
Parameters
DOMString typeArg Specifies the event type.
views::AbstractView viewArg Specifies the Event's AbstractView.
long detailArg Specifies the Event's detail.
No Return Value
No Exceptions

 

The different types of events that can occur are:

begin
Raised when the element begins. See also Events and event model.
  • Bubbles: No
  • Cancelable: No
  • Context Info: None
end
Raised when the element ends its active duration. See also Events and event model.
  • Bubbles: No
  • Cancelable: No
  • Context Info: None
repeat
Raised when the element repeats. See also Events and event model.
  • Bubbles: No
  • Cancelable: No
  • Context Info: detail (current iteration)

6.3. IDL definition

smil.idl:

// File: smil.idl
#ifndef _SMIL_IDL_
#define _SMIL_IDL_

#include "dom.idl"

#pragma prefix "dom.w3c.org"
module smil
{
  typedef dom::DOMString DOMString;

  interface ElementTimeControl {
    void            beginElement();
    void            beginElementAt(in float offset);
    void            endElement();
    void            endElementAt(in float offset);
  };

  interface TimeEvent : events::Event {
    readonly attribute views::AbstractView  view;
    readonly attribute long             detail;
    void               initTimeEvent(in DOMString typeArg, 
                                     in views::AbstractView viewArg, 
                                     in long detailArg);
  };
};

#endif // _SMIL_IDL_

6.4. Java language binding

org/w3c/dom/smil/ElementTimeControl.java:

package org.w3c.dom.smil;

import org.w3c.dom.DOMException;

public interface ElementTimeControl {
    public void  beginElement();

    public void  beginElementAt(float offset);

    public void endElement();

    public void endElementAt(float offset);

}

org/w3c/dom/smil/TimeEvent.java:

package org.w3c.dom.smil;

import org.w3c.dom.events.Event;
import org.w3c.dom.views.AbstractView;

public interface TimeEvent extends Event {
    public AbstractView getView();

    public int getDetail();

    public void initTimeEvent(String typeArg, 
                              AbstractView viewArg, 
                              int detailArg);

}

6.5. ECMAScript language binding

Object ElementTimeControl
The ElementTimeControl object has the following methods:
beginElement()
This method returns a void.
beginElementAt(offset)
This method returns a void. The offset parameter is of type float.
endElement()
This method returns a void.
endElementAt(offset)
This method returns a void. The offset parameter is of type float.
Object TimeEvent
TimeEvent has all the properties and methods of Event as well as the properties and methods defined below.
The TimeEvent object has the following properties:
view
This property is of type AbstractView.
detail
This property is of type long.
The TimeEvent object has the following methods:
initTimeEvent(typeArg, viewArg, detailArg)
This method returns a void. The typeArg parameter is of type DOMString. The viewArg parameter is of type views::AbstractView. The detailArg parameter is of type long.


 

7. Appendix: Differences from SMIL 1.0 timing model

8. References

[CSS2]
"Cascading Style Sheets, level 2", B. Bos, H. W. Lie, C. Lilley, I. Jacobs, 12 May 1998.
Available at http://www.w3.org/TR/REC-CSS2.
[COMP-GRAPHICS]
"Computer Graphics : Principles and Practice, Second Edition", James D. Foley, Andries van Dam, Steven K. Feiner, John F. Hughes, Richard L. Phillips, Addison-Wesley, pp. 488-491.
[DATETIME]
"Date and Time Formats", M. Wolf, C. Wicksteed. W3C Note 27 August 1998,
Available at: http://www.w3.org/TR/NOTE-datetime
[DOM-Level-2]
"Document Object Model (DOM) Level 2 Core Specification"
Available at http://www.w3.org/TR/DOM-Level-2/.
[DOM2CSS]
"Document Object Model CSS"
Available at http://www.w3.org/TR/DOM-Level-2-Style/css.html.
[DOM2Events]
"Document Object Model Events", T. Pixley
Available at http://www.w3.org/TR/DOM-Level-2-Events/events.html.
[HTML]
"HTML 4.01 Specification", D. Raggett, A. Le Hors, I. Jacobs, 24 December 1999.
Available at http://www.w3.org/TR/REC-html40.
[ISO8601]
"Data elements and interchange formats - Information interchange - Representation of dates and times", International Organization for Standardization, 1998.
[ISO10646]
""Information Technology -- Universal Multiple-Octet Coded Character Set (UCS) -- Part 1: Architecture and Basic Multilingual Plane", ISO/IEC 10646-1:1993. This reference refers to a set of codepoints that may evolve as new characters are assigned to them. This reference therefore includes future amendments as long as they do not change character assignments up to and including the first five amendments to ISO/IEC 10646-1:1993. Also, this reference assumes that the character sets defined by ISO 10646 and Unicode remain character-by-character equivalent. This reference also includes future publications of other parts of 10646 (i.e., other than Part 1) that define characters in planes 1-16. "
[SMIL1.0]
"Synchronized Multimedia Integration Language (SMIL) 1.0 Specification W3C Recommendation 15-June-1998 ".
Available at: http://www.w3.org/TR/REC-smil.
[SMIL20]
"Synchronized Multimedia Integration Language (SMIL 2.0) Specification", 
W3C SYMM (Proposed Recommendation).
Available at http://www.w3.org/TR/smil20/
[SMIL-MOD]
"Synchronized Multimedia Modules based upon SMIL 1.0", Patrick Schmitz, Ted Wugofski, Warner ten Kate.
Available at http://www.w3.org/TR/NOTE-SYMM-modules.
[sRGB]
IEC 61966-2-1 (1999-10) - "Multimedia systems and equipment - Colour measurement and management - Part 2-1: Colour management - Default RGB colour space - sRGB", ISBN: 2-8318-4989-6 ­ ICS codes: 33.160.60, 37.080 ­ TC 100 ­ 51 pp. 
Available at: http://www.iec.ch/nr1899.htm.
[SVG]
"Scalable Vector Graphics (SVG) 1.0 Specification", W3C Proposed Recommendation, 19 July 2001.
Available at http://www.w3.org/TR/SVG/.
[XLink]
"XML Linking Language (XLink)", S. DeRose, E. Maler, D. Orchard, editors, 27 June 2001.
Available at http://www.w3.org/TR/xlink
[XML]
"Extensible Markup Language (XML) 1.0", T. Bray, J. Paoli, C.M. Sperberg-McQueen, Eve Maler, editors, 6 October 2000.
Available at http://www.w3.org/TR/REC-xml
[XML-NS]
"Namespaces in XML" T. Bray, D. Hollander, A. Layman, editors, 14 January 1999.
Available at http://www.w3.org/TR/REC-xml-names/.