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218e854766
We got runtime error when enabling float-cast-overflow check in this line, so let's clamp the value to pass the check. Differential Revision: https://phabricator.services.mozilla.com/D139969
347 lines
13 KiB
C++
347 lines
13 KiB
C++
/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
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/* vim: set ts=8 sts=2 et sw=2 tw=80: */
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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/AnimationEffect.h"
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#include "mozilla/dom/AnimationEffectBinding.h"
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#include "mozilla/dom/Animation.h"
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#include "mozilla/dom/KeyframeEffect.h"
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#include "mozilla/dom/MutationObservers.h"
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#include "mozilla/AnimationUtils.h"
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#include "mozilla/FloatingPoint.h"
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#include "nsDOMMutationObserver.h"
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namespace mozilla::dom {
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NS_IMPL_CYCLE_COLLECTION_CLASS(AnimationEffect)
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NS_IMPL_CYCLE_COLLECTION_UNLINK_BEGIN(AnimationEffect)
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NS_IMPL_CYCLE_COLLECTION_UNLINK(mDocument, mAnimation)
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NS_IMPL_CYCLE_COLLECTION_UNLINK_PRESERVED_WRAPPER
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NS_IMPL_CYCLE_COLLECTION_UNLINK_END
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NS_IMPL_CYCLE_COLLECTION_TRAVERSE_BEGIN(AnimationEffect)
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NS_IMPL_CYCLE_COLLECTION_TRAVERSE(mDocument, mAnimation)
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NS_IMPL_CYCLE_COLLECTION_TRAVERSE_END
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NS_IMPL_CYCLE_COLLECTION_TRACE_WRAPPERCACHE(AnimationEffect)
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NS_IMPL_CYCLE_COLLECTING_ADDREF(AnimationEffect)
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NS_IMPL_CYCLE_COLLECTING_RELEASE(AnimationEffect)
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NS_INTERFACE_MAP_BEGIN_CYCLE_COLLECTION(AnimationEffect)
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NS_WRAPPERCACHE_INTERFACE_MAP_ENTRY
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NS_INTERFACE_MAP_ENTRY(nsISupports)
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NS_INTERFACE_MAP_END
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AnimationEffect::AnimationEffect(Document* aDocument, TimingParams&& aTiming)
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: mDocument(aDocument), mTiming(std::move(aTiming)) {}
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AnimationEffect::~AnimationEffect() = default;
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nsISupports* AnimationEffect::GetParentObject() const {
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return ToSupports(mDocument);
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}
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// https://drafts.csswg.org/web-animations/#current
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bool AnimationEffect::IsCurrent() const {
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if (!mAnimation || mAnimation->PlayState() == AnimationPlayState::Finished) {
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return false;
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}
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ComputedTiming computedTiming = GetComputedTiming();
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if (computedTiming.mPhase == ComputedTiming::AnimationPhase::Active) {
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return true;
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}
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return (mAnimation->PlaybackRate() > 0 &&
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computedTiming.mPhase == ComputedTiming::AnimationPhase::Before) ||
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(mAnimation->PlaybackRate() < 0 &&
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computedTiming.mPhase == ComputedTiming::AnimationPhase::After);
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}
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// https://drafts.csswg.org/web-animations/#in-effect
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bool AnimationEffect::IsInEffect() const {
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ComputedTiming computedTiming = GetComputedTiming();
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return !computedTiming.mProgress.IsNull();
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}
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void AnimationEffect::SetSpecifiedTiming(TimingParams&& aTiming) {
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if (mTiming == aTiming) {
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return;
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}
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mTiming = aTiming;
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if (mAnimation) {
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Maybe<nsAutoAnimationMutationBatch> mb;
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if (AsKeyframeEffect() && AsKeyframeEffect()->GetAnimationTarget()) {
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mb.emplace(AsKeyframeEffect()->GetAnimationTarget().mElement->OwnerDoc());
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}
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mAnimation->NotifyEffectTimingUpdated();
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if (mAnimation->IsRelevant()) {
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MutationObservers::NotifyAnimationChanged(mAnimation);
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}
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if (AsKeyframeEffect()) {
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AsKeyframeEffect()->RequestRestyle(EffectCompositor::RestyleType::Layer);
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}
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}
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// For keyframe effects, NotifyEffectTimingUpdated above will eventually
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// cause KeyframeEffect::NotifyAnimationTimingUpdated to be called so it can
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// update its registration with the target element as necessary.
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}
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ComputedTiming AnimationEffect::GetComputedTimingAt(
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const Nullable<TimeDuration>& aLocalTime, const TimingParams& aTiming,
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double aPlaybackRate) {
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static const StickyTimeDuration zeroDuration;
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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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if (aTiming.Duration()) {
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MOZ_ASSERT(aTiming.Duration().ref() >= zeroDuration,
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"Iteration duration should be positive");
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result.mDuration = aTiming.Duration().ref();
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}
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MOZ_ASSERT(aTiming.Iterations() >= 0.0 && !IsNaN(aTiming.Iterations()),
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"mIterations should be nonnegative & finite, as ensured by "
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"ValidateIterations or CSSParser");
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result.mIterations = aTiming.Iterations();
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MOZ_ASSERT(aTiming.IterationStart() >= 0.0,
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"mIterationStart should be nonnegative, as ensured by "
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"ValidateIterationStart");
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result.mIterationStart = aTiming.IterationStart();
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result.mActiveDuration = aTiming.ActiveDuration();
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result.mEndTime = aTiming.EndTime();
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result.mFill = aTiming.Fill() == dom::FillMode::Auto ? dom::FillMode::None
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: aTiming.Fill();
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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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StickyTimeDuration beforeActiveBoundary =
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std::max(std::min(StickyTimeDuration(aTiming.Delay()), result.mEndTime),
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zeroDuration);
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StickyTimeDuration activeAfterBoundary = std::max(
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std::min(StickyTimeDuration(aTiming.Delay() + result.mActiveDuration),
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result.mEndTime),
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zeroDuration);
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if (localTime > activeAfterBoundary ||
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(aPlaybackRate >= 0 && localTime == activeAfterBoundary)) {
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result.mPhase = ComputedTiming::AnimationPhase::After;
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if (!result.FillsForwards()) {
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// The animation isn't active or filling at this time.
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return result;
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}
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result.mActiveTime =
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std::max(std::min(StickyTimeDuration(localTime - aTiming.Delay()),
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result.mActiveDuration),
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zeroDuration);
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} else if (localTime < beforeActiveBoundary ||
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(aPlaybackRate < 0 && localTime == beforeActiveBoundary)) {
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result.mPhase = ComputedTiming::AnimationPhase::Before;
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if (!result.FillsBackwards()) {
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// The animation isn't active or filling at this time.
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return result;
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}
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result.mActiveTime =
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std::max(StickyTimeDuration(localTime - aTiming.Delay()), zeroDuration);
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} else {
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MOZ_ASSERT(result.mActiveDuration,
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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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result.mActiveTime = localTime - aTiming.Delay();
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}
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// Convert active time to a multiple of iterations.
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// https://drafts.csswg.org/web-animations/#overall-progress
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double overallProgress;
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if (!result.mDuration) {
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overallProgress = result.mPhase == ComputedTiming::AnimationPhase::Before
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? 0.0
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: result.mIterations;
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} else {
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overallProgress = result.mActiveTime / result.mDuration;
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}
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// Factor in iteration start offset.
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if (IsFinite(overallProgress)) {
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overallProgress += result.mIterationStart;
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}
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// Determine the 0-based index of the current iteration.
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// https://drafts.csswg.org/web-animations/#current-iteration
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result.mCurrentIteration =
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(result.mIterations >= double(UINT64_MAX) &&
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result.mPhase == ComputedTiming::AnimationPhase::After) ||
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overallProgress >= double(UINT64_MAX)
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? UINT64_MAX // In GetComputedTimingDictionary(),
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// we will convert this into Infinity
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: static_cast<uint64_t>(std::max(overallProgress, 0.0));
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// Convert the overall progress to a fraction of a single iteration--the
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// simply iteration progress.
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// https://drafts.csswg.org/web-animations/#simple-iteration-progress
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double progress = IsFinite(overallProgress)
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? fmod(overallProgress, 1.0)
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: fmod(result.mIterationStart, 1.0);
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// When we are at the end of the active interval and the end of an iteration
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// we need to report the end of the final iteration and not the start of the
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// next iteration. We *don't* want to do this, however, when we have
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// a zero-iteration animation.
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if (progress == 0.0 &&
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(result.mPhase == ComputedTiming::AnimationPhase::After ||
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result.mPhase == ComputedTiming::AnimationPhase::Active) &&
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result.mActiveTime == result.mActiveDuration &&
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result.mIterations != 0.0) {
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// The only way we can reach the end of the active interval and have
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// a progress of zero and a current iteration of zero, is if we have a
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// zero iteration count -- something we should have detected above.
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MOZ_ASSERT(result.mCurrentIteration != 0,
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"Should not have zero current iteration");
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progress = 1.0;
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if (result.mCurrentIteration != UINT64_MAX) {
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result.mCurrentIteration--;
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}
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}
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// Factor in the direction.
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bool thisIterationReverse = false;
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switch (aTiming.Direction()) {
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case PlaybackDirection::Normal:
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thisIterationReverse = false;
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break;
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case PlaybackDirection::Reverse:
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thisIterationReverse = true;
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break;
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case PlaybackDirection::Alternate:
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thisIterationReverse = (result.mCurrentIteration & 1) == 1;
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break;
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case PlaybackDirection::Alternate_reverse:
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thisIterationReverse = (result.mCurrentIteration & 1) == 0;
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break;
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default:
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MOZ_ASSERT_UNREACHABLE("Unknown PlaybackDirection type");
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}
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if (thisIterationReverse) {
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progress = 1.0 - progress;
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}
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// Calculate the 'before flag' which we use when applying step timing
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// functions.
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if ((result.mPhase == ComputedTiming::AnimationPhase::After &&
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thisIterationReverse) ||
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(result.mPhase == ComputedTiming::AnimationPhase::Before &&
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!thisIterationReverse)) {
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result.mBeforeFlag = ComputedTimingFunction::BeforeFlag::Set;
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}
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// Apply the easing.
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if (aTiming.TimingFunction()) {
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progress = aTiming.TimingFunction()->GetValue(progress, result.mBeforeFlag);
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}
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MOZ_ASSERT(IsFinite(progress), "Progress value should be finite");
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result.mProgress.SetValue(progress);
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return result;
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}
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ComputedTiming AnimationEffect::GetComputedTiming(
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const TimingParams* aTiming) const {
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double playbackRate = mAnimation ? mAnimation->PlaybackRate() : 1;
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return GetComputedTimingAt(
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GetLocalTime(), aTiming ? *aTiming : SpecifiedTiming(), playbackRate);
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}
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// Helper function for generating an (Computed)EffectTiming dictionary
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static void GetEffectTimingDictionary(const TimingParams& aTiming,
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EffectTiming& aRetVal) {
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aRetVal.mDelay = aTiming.Delay().ToMilliseconds();
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aRetVal.mEndDelay = aTiming.EndDelay().ToMilliseconds();
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aRetVal.mFill = aTiming.Fill();
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aRetVal.mIterationStart = aTiming.IterationStart();
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aRetVal.mIterations = aTiming.Iterations();
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if (aTiming.Duration()) {
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aRetVal.mDuration.SetAsUnrestrictedDouble() =
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aTiming.Duration()->ToMilliseconds();
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}
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aRetVal.mDirection = aTiming.Direction();
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if (aTiming.TimingFunction()) {
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aRetVal.mEasing.Truncate();
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aTiming.TimingFunction()->AppendToString(aRetVal.mEasing);
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}
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}
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void AnimationEffect::GetTiming(EffectTiming& aRetVal) const {
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GetEffectTimingDictionary(SpecifiedTiming(), aRetVal);
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}
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void AnimationEffect::GetComputedTimingAsDict(
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ComputedEffectTiming& aRetVal) const {
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// Specified timing
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GetEffectTimingDictionary(SpecifiedTiming(), aRetVal);
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// Computed timing
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double playbackRate = mAnimation ? mAnimation->PlaybackRate() : 1;
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const Nullable<TimeDuration> currentTime = GetLocalTime();
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ComputedTiming computedTiming =
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GetComputedTimingAt(currentTime, SpecifiedTiming(), playbackRate);
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aRetVal.mDuration.SetAsUnrestrictedDouble() =
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computedTiming.mDuration.ToMilliseconds();
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aRetVal.mFill = computedTiming.mFill;
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aRetVal.mActiveDuration = computedTiming.mActiveDuration.ToMilliseconds();
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aRetVal.mEndTime = computedTiming.mEndTime.ToMilliseconds();
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aRetVal.mLocalTime = AnimationUtils::TimeDurationToDouble(currentTime);
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aRetVal.mProgress = computedTiming.mProgress;
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if (!aRetVal.mProgress.IsNull()) {
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// Convert the returned currentIteration into Infinity if we set
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// (uint64_t) computedTiming.mCurrentIteration to UINT64_MAX
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double iteration =
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computedTiming.mCurrentIteration == UINT64_MAX
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? PositiveInfinity<double>()
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: static_cast<double>(computedTiming.mCurrentIteration);
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aRetVal.mCurrentIteration.SetValue(iteration);
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}
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}
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void AnimationEffect::UpdateTiming(const OptionalEffectTiming& aTiming,
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ErrorResult& aRv) {
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TimingParams timing =
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TimingParams::MergeOptionalEffectTiming(mTiming, aTiming, aRv);
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if (aRv.Failed()) {
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return;
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}
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SetSpecifiedTiming(std::move(timing));
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}
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Nullable<TimeDuration> AnimationEffect::GetLocalTime() const {
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// Since the *animation* start time is currently always zero, the local
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// time is equal to the parent time.
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Nullable<TimeDuration> result;
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if (mAnimation) {
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result = mAnimation->GetCurrentTimeAsDuration();
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}
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return result;
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}
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} // namespace mozilla::dom
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