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b986ff9440
This patch extracts the logic for calculating animation styles from AnimationPlayerCollection and puts the bulk of it into the Animation objects. Some of the initial logic surrounding the animation player state (e.g. is it paused or not, etc.) is put into AnimationPlayer. In future we may shift this logic even further down to the AnimationEffect objects but currently we don't create such objects unless necessary.
352 lines
12 KiB
C++
352 lines
12 KiB
C++
/* vim: set shiftwidth=2 tabstop=8 autoindent cindent expandtab: */
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/* This Source Code Form is subject to the terms of the Mozilla Public
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* License, v. 2.0. If a copy of the MPL was not distributed with this file,
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* You can obtain one at http://mozilla.org/MPL/2.0/. */
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#include "mozilla/dom/Animation.h"
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#include "mozilla/dom/AnimationBinding.h"
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#include "mozilla/dom/AnimationEffect.h"
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#include "mozilla/FloatingPoint.h"
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#include "AnimationCommon.h"
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#include "nsCSSPropertySet.h"
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namespace mozilla {
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void
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ComputedTimingFunction::Init(const nsTimingFunction &aFunction)
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{
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mType = aFunction.mType;
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if (mType == nsTimingFunction::Function) {
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mTimingFunction.Init(aFunction.mFunc.mX1, aFunction.mFunc.mY1,
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aFunction.mFunc.mX2, aFunction.mFunc.mY2);
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} else {
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mSteps = aFunction.mSteps;
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}
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}
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static inline double
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StepEnd(uint32_t aSteps, double aPortion)
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{
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NS_ABORT_IF_FALSE(0.0 <= aPortion && aPortion <= 1.0, "out of range");
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uint32_t step = uint32_t(aPortion * aSteps); // floor
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return double(step) / double(aSteps);
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}
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double
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ComputedTimingFunction::GetValue(double aPortion) const
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{
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switch (mType) {
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case nsTimingFunction::Function:
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return mTimingFunction.GetSplineValue(aPortion);
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case nsTimingFunction::StepStart:
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// There are diagrams in the spec that seem to suggest this check
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// and the bounds point should not be symmetric with StepEnd, but
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// should actually step up at rather than immediately after the
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// fraction points. However, we rely on rounding negative values
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// up to zero, so we can't do that. And it's not clear the spec
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// really meant it.
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return 1.0 - StepEnd(mSteps, 1.0 - aPortion);
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default:
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NS_ABORT_IF_FALSE(false, "bad type");
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// fall through
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case nsTimingFunction::StepEnd:
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return StepEnd(mSteps, aPortion);
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}
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}
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// In the Web Animations model, the time fraction can be outside the range
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// [0.0, 1.0] but it shouldn't be Infinity.
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const double ComputedTiming::kNullTimeFraction = PositiveInfinity<double>();
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namespace dom {
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NS_IMPL_CYCLE_COLLECTION_WRAPPERCACHE(Animation, mDocument, mTarget)
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NS_IMPL_CYCLE_COLLECTION_ROOT_NATIVE(Animation, AddRef)
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NS_IMPL_CYCLE_COLLECTION_UNROOT_NATIVE(Animation, Release)
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JSObject*
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Animation::WrapObject(JSContext* aCx)
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{
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return AnimationBinding::Wrap(aCx, this);
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}
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already_AddRefed<AnimationEffect>
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Animation::GetEffect()
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{
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nsRefPtr<AnimationEffect> effect = new AnimationEffect(this);
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return effect.forget();
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}
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void
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Animation::SetParentTime(Nullable<TimeDuration> aParentTime)
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{
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mParentTime = aParentTime;
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}
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ComputedTiming
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Animation::GetComputedTimingAt(const Nullable<TimeDuration>& aLocalTime,
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const AnimationTiming& aTiming)
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{
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const TimeDuration zeroDuration;
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// Currently we expect negative durations to be picked up during CSS
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// parsing but when we start receiving timing parameters from other sources
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// we will need to clamp negative durations here.
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// For now, if we're hitting this it probably means we're overflowing
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// integer arithmetic in mozilla::TimeStamp.
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MOZ_ASSERT(aTiming.mIterationDuration >= zeroDuration,
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"Expecting iteration duration >= 0");
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// Always return the same object to benefit from return-value optimization.
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ComputedTiming result;
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result.mActiveDuration = ActiveDuration(aTiming);
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// The default constructor for ComputedTiming sets all other members to
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// values consistent with an animation that has not been sampled.
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if (aLocalTime.IsNull()) {
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return result;
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}
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const TimeDuration& localTime = aLocalTime.Value();
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// When we finish exactly at the end of an iteration we need to report
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// the end of the final iteration and not the start of the next iteration
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// so we set up a flag for that case.
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bool isEndOfFinalIteration = false;
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// Get the normalized time within the active interval.
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StickyTimeDuration activeTime;
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if (localTime >= aTiming.mDelay + result.mActiveDuration) {
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result.mPhase = ComputedTiming::AnimationPhase_After;
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if (!aTiming.FillsForwards()) {
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// The animation isn't active or filling at this time.
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result.mTimeFraction = ComputedTiming::kNullTimeFraction;
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return result;
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}
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activeTime = result.mActiveDuration;
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// Note that infinity == floor(infinity) so this will also be true when we
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// have finished an infinitely repeating animation of zero duration.
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isEndOfFinalIteration =
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aTiming.mIterationCount != 0.0 &&
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aTiming.mIterationCount == floor(aTiming.mIterationCount);
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} else if (localTime < aTiming.mDelay) {
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result.mPhase = ComputedTiming::AnimationPhase_Before;
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if (!aTiming.FillsBackwards()) {
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// The animation isn't active or filling at this time.
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result.mTimeFraction = ComputedTiming::kNullTimeFraction;
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return result;
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}
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// activeTime is zero
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} else {
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MOZ_ASSERT(result.mActiveDuration != zeroDuration,
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"How can we be in the middle of a zero-duration interval?");
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result.mPhase = ComputedTiming::AnimationPhase_Active;
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activeTime = localTime - aTiming.mDelay;
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}
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// Get the position within the current iteration.
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StickyTimeDuration iterationTime;
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if (aTiming.mIterationDuration != zeroDuration) {
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iterationTime = isEndOfFinalIteration
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? StickyTimeDuration(aTiming.mIterationDuration)
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: activeTime % aTiming.mIterationDuration;
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} /* else, iterationTime is zero */
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// Determine the 0-based index of the current iteration.
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if (isEndOfFinalIteration) {
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result.mCurrentIteration =
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aTiming.mIterationCount == NS_IEEEPositiveInfinity()
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? UINT64_MAX // FIXME: When we return this via the API we'll need
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// to make sure it ends up being infinity.
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: static_cast<uint64_t>(aTiming.mIterationCount) - 1;
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} else if (activeTime == zeroDuration) {
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// If the active time is zero we're either in the first iteration
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// (including filling backwards) or we have finished an animation with an
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// iteration duration of zero that is filling forwards (but we're not at
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// the exact end of an iteration since we deal with that above).
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result.mCurrentIteration =
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result.mPhase == ComputedTiming::AnimationPhase_After
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? static_cast<uint64_t>(aTiming.mIterationCount) // floor
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: 0;
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} else {
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result.mCurrentIteration =
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static_cast<uint64_t>(activeTime / aTiming.mIterationDuration); // floor
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}
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// Normalize the iteration time into a fraction of the iteration duration.
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if (result.mPhase == ComputedTiming::AnimationPhase_Before) {
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result.mTimeFraction = 0.0;
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} else if (result.mPhase == ComputedTiming::AnimationPhase_After) {
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result.mTimeFraction = isEndOfFinalIteration
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? 1.0
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: fmod(aTiming.mIterationCount, 1.0f);
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} else {
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// We are in the active phase so the iteration duration can't be zero.
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MOZ_ASSERT(aTiming.mIterationDuration != zeroDuration,
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"In the active phase of a zero-duration animation?");
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result.mTimeFraction =
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aTiming.mIterationDuration == TimeDuration::Forever()
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? 0.0
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: iterationTime / aTiming.mIterationDuration;
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}
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bool thisIterationReverse = false;
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switch (aTiming.mDirection) {
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case NS_STYLE_ANIMATION_DIRECTION_NORMAL:
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thisIterationReverse = false;
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break;
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case NS_STYLE_ANIMATION_DIRECTION_REVERSE:
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thisIterationReverse = true;
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break;
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case NS_STYLE_ANIMATION_DIRECTION_ALTERNATE:
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thisIterationReverse = (result.mCurrentIteration & 1) == 1;
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break;
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case NS_STYLE_ANIMATION_DIRECTION_ALTERNATE_REVERSE:
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thisIterationReverse = (result.mCurrentIteration & 1) == 0;
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break;
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}
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if (thisIterationReverse) {
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result.mTimeFraction = 1.0 - result.mTimeFraction;
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}
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return result;
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}
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StickyTimeDuration
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Animation::ActiveDuration(const AnimationTiming& aTiming)
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{
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if (aTiming.mIterationCount == mozilla::PositiveInfinity<float>()) {
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// An animation that repeats forever has an infinite active duration
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// unless its iteration duration is zero, in which case it has a zero
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// active duration.
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const StickyTimeDuration zeroDuration;
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return aTiming.mIterationDuration == zeroDuration
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? zeroDuration
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: StickyTimeDuration::Forever();
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}
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return StickyTimeDuration(
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aTiming.mIterationDuration.MultDouble(aTiming.mIterationCount));
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}
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bool
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Animation::IsCurrent() const
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{
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if (IsFinishedTransition()) {
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return false;
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}
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ComputedTiming computedTiming = GetComputedTiming();
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return computedTiming.mPhase == ComputedTiming::AnimationPhase_Before ||
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computedTiming.mPhase == ComputedTiming::AnimationPhase_Active;
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}
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bool
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Animation::IsInEffect() const
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{
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if (IsFinishedTransition()) {
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return false;
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}
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ComputedTiming computedTiming = GetComputedTiming();
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return computedTiming.mTimeFraction != ComputedTiming::kNullTimeFraction;
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}
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bool
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Animation::HasAnimationOfProperty(nsCSSProperty aProperty) const
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{
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for (size_t propIdx = 0, propEnd = mProperties.Length();
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propIdx != propEnd; ++propIdx) {
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if (aProperty == mProperties[propIdx].mProperty) {
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return true;
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}
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}
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return false;
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}
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void
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Animation::ComposeStyle(nsRefPtr<css::AnimValuesStyleRule>& aStyleRule,
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nsCSSPropertySet& aSetProperties)
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{
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ComputedTiming computedTiming = GetComputedTiming();
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// If the time fraction is null, we don't have fill data for the current
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// time so we shouldn't animate.
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if (computedTiming.mTimeFraction == ComputedTiming::kNullTimeFraction) {
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return;
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}
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MOZ_ASSERT(0.0 <= computedTiming.mTimeFraction &&
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computedTiming.mTimeFraction <= 1.0,
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"timing fraction should be in [0-1]");
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for (size_t propIdx = 0, propEnd = mProperties.Length();
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propIdx != propEnd; ++propIdx)
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{
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const AnimationProperty& prop = mProperties[propIdx];
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MOZ_ASSERT(prop.mSegments[0].mFromKey == 0.0, "incorrect first from key");
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MOZ_ASSERT(prop.mSegments[prop.mSegments.Length() - 1].mToKey == 1.0,
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"incorrect last to key");
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if (aSetProperties.HasProperty(prop.mProperty)) {
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// Animations are composed by AnimationPlayerCollection by iterating
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// from the last animation to first. For animations targetting the
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// same property, the later one wins. So if this property is already set,
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// we should not override it.
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return;
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}
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aSetProperties.AddProperty(prop.mProperty);
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MOZ_ASSERT(prop.mSegments.Length() > 0,
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"property should not be in animations if it has no segments");
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// FIXME: Maybe cache the current segment?
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const AnimationPropertySegment *segment = prop.mSegments.Elements(),
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*segmentEnd = segment + prop.mSegments.Length();
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while (segment->mToKey < computedTiming.mTimeFraction) {
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MOZ_ASSERT(segment->mFromKey < segment->mToKey, "incorrect keys");
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++segment;
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if (segment == segmentEnd) {
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MOZ_ASSERT_UNREACHABLE("incorrect time fraction");
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break; // in order to continue in outer loop (just below)
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}
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MOZ_ASSERT(segment->mFromKey == (segment-1)->mToKey, "incorrect keys");
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}
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if (segment == segmentEnd) {
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continue;
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}
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MOZ_ASSERT(segment->mFromKey < segment->mToKey, "incorrect keys");
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MOZ_ASSERT(segment >= prop.mSegments.Elements() &&
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size_t(segment - prop.mSegments.Elements()) <
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prop.mSegments.Length(),
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"out of array bounds");
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if (!aStyleRule) {
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// Allocate the style rule now that we know we have animation data.
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aStyleRule = new css::AnimValuesStyleRule();
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}
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double positionInSegment =
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(computedTiming.mTimeFraction - segment->mFromKey) /
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(segment->mToKey - segment->mFromKey);
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double valuePosition =
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segment->mTimingFunction.GetValue(positionInSegment);
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StyleAnimationValue *val = aStyleRule->AddEmptyValue(prop.mProperty);
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#ifdef DEBUG
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bool result =
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#endif
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StyleAnimationValue::Interpolate(prop.mProperty,
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segment->mFromValue,
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segment->mToValue,
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valuePosition, *val);
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MOZ_ASSERT(result, "interpolate must succeed now");
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}
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}
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} // namespace dom
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} // namespace mozilla
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