/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #include // for fabsf, fabs, atan2 #include // for uint32_t, uint64_t #include // for int32_t #include // for max, min #include "AsyncPanZoomController.h" // for AsyncPanZoomController, etc #include "Axis.h" // for AxisX, AxisY, Axis, etc #include "CheckerboardEvent.h" // for CheckerboardEvent #include "Compositor.h" // for Compositor #include "FrameMetrics.h" // for FrameMetrics, etc #include "GenericFlingAnimation.h" // for GenericFlingAnimation #include "GestureEventListener.h" // for GestureEventListener #include "HitTestingTreeNode.h" // for HitTestingTreeNode #include "InputData.h" // for MultiTouchInput, etc #include "InputBlockState.h" // for InputBlockState, TouchBlockState #include "InputQueue.h" // for InputQueue #include "Overscroll.h" // for OverscrollAnimation #include "OverscrollHandoffState.h" // for OverscrollHandoffState #include "Units.h" // for CSSRect, CSSPoint, etc #include "UnitTransforms.h" // for TransformTo #include "base/message_loop.h" // for MessageLoop #include "base/task.h" // for NewRunnableMethod, etc #include "gfxPrefs.h" // for gfxPrefs #include "gfxTypes.h" // for gfxFloat #include "LayersLogging.h" // for print_stderr #include "mozilla/Assertions.h" // for MOZ_ASSERT, etc #include "mozilla/BasicEvents.h" // for Modifiers, MODIFIER_* #include "mozilla/ClearOnShutdown.h" // for ClearOnShutdown #include "mozilla/ComputedTimingFunction.h" // for ComputedTimingFunction #include "mozilla/EventForwards.h" // for nsEventStatus_* #include "mozilla/EventStateManager.h" #include "mozilla/MouseEvents.h" // for WidgetWheelEvent #include "mozilla/Preferences.h" // for Preferences #include "mozilla/ReentrantMonitor.h" // for ReentrantMonitorAutoEnter, etc #include "mozilla/RefPtr.h" // for RefPtr #include "mozilla/StaticPtr.h" // for StaticAutoPtr #include "mozilla/TimeStamp.h" // for TimeDuration, TimeStamp #include "mozilla/dom/CheckerboardReportService.h" // for CheckerboardEventStorage // note: CheckerboardReportService.h actually lives in gfx/layers/apz/util/ #include "mozilla/dom/Touch.h" // for Touch #include "mozilla/gfx/BasePoint.h" // for BasePoint #include "mozilla/gfx/BaseRect.h" // for BaseRect #include "mozilla/gfx/Coord.h" #include "mozilla/gfx/Point.h" // for Point, RoundedToInt, etc #include "mozilla/gfx/Rect.h" // for RoundedIn #include "mozilla/gfx/ScaleFactor.h" // for ScaleFactor #include "mozilla/layers/APZCTreeManager.h" // for ScrollableLayerGuid #include "mozilla/layers/APZThreadUtils.h" // for AssertOnControllerThread, etc #include "mozilla/layers/AsyncCompositionManager.h" // for ViewTransform #include "mozilla/layers/AxisPhysicsModel.h" // for AxisPhysicsModel #include "mozilla/layers/AxisPhysicsMSDModel.h" // for AxisPhysicsMSDModel #include "mozilla/layers/CompositorController.h" // for CompositorController #include "mozilla/layers/LayerTransactionParent.h" // for LayerTransactionParent #include "mozilla/layers/MetricsSharingController.h" // for MetricsSharingController #include "mozilla/layers/ScrollInputMethods.h" // for ScrollInputMethod #include "mozilla/mozalloc.h" // for operator new, etc #include "mozilla/Unused.h" // for unused #include "mozilla/FloatingPoint.h" // for FuzzyEquals* #include "nsAlgorithm.h" // for clamped #include "nsCOMPtr.h" // for already_AddRefed #include "nsDebug.h" // for NS_WARNING #include "nsIDOMWindowUtils.h" // for nsIDOMWindowUtils #include "nsMathUtils.h" // for NS_hypot #include "nsPoint.h" // for nsIntPoint #include "nsStyleConsts.h" #include "nsStyleStruct.h" // for nsTimingFunction #include "nsTArray.h" // for nsTArray, nsTArray_Impl, etc #include "nsThreadUtils.h" // for NS_IsMainThread #include "nsViewportInfo.h" // for kViewportMinScale, kViewportMaxScale #include "prsystem.h" // for PR_GetPhysicalMemorySize #include "SharedMemoryBasic.h" // for SharedMemoryBasic #include "ScrollSnap.h" // for ScrollSnapUtils #include "WheelScrollAnimation.h" #define ENABLE_APZC_LOGGING 0 // #define ENABLE_APZC_LOGGING 1 #if ENABLE_APZC_LOGGING # define APZC_LOG(...) printf_stderr("APZC: " __VA_ARGS__) # define APZC_LOG_FM(fm, prefix, ...) \ { std::stringstream ss; \ ss << nsPrintfCString(prefix, __VA_ARGS__).get(); \ AppendToString(ss, fm, ":", "", true); \ APZC_LOG("%s\n", ss.str().c_str()); \ } #else # define APZC_LOG(...) # define APZC_LOG_FM(fm, prefix, ...) #endif namespace mozilla { namespace layers { typedef mozilla::layers::AllowedTouchBehavior AllowedTouchBehavior; typedef GeckoContentController::APZStateChange APZStateChange; typedef GeckoContentController::TapType TapType; typedef mozilla::gfx::Point Point; typedef mozilla::gfx::Matrix4x4 Matrix4x4; using mozilla::gfx::CoordTyped; using mozilla::gfx::IntCoordTyped; using mozilla::gfx::IntRectTyped; using mozilla::gfx::PointTyped; using mozilla::gfx::RectTyped; using mozilla::gfx::ScaleFactors2D; // Platform-specific implementations. typedef GenericOverscrollEffect OverscrollEffect; typedef PlatformSpecificStateBase PlatformSpecificState; // no extra state, just use the base class typedef GenericFlingAnimation FlingAnimation; /** * \page APZCPrefs APZ preferences * * The following prefs are used to control the behaviour of the APZC. * The default values are provided in gfxPrefs.h. * * \li\b apz.allow_checkerboarding * Pref that allows or disallows checkerboarding * * \li\b apz.allow_immediate_handoff * If set to true, scroll can be handed off from one APZC to another within * a single input block. If set to false, a single input block can only * scroll one APZC. * * \li\b apz.axis_lock.mode * The preferred axis locking style. See AxisLockMode for possible values. * * \li\b apz.axis_lock.lock_angle * Angle from axis within which we stay axis-locked.\n * Units: radians * * \li\b apz.axis_lock.breakout_threshold * Distance in inches the user must pan before axis lock can be broken.\n * Units: (real-world, i.e. screen) inches * * \li\b apz.axis_lock.breakout_angle * Angle at which axis lock can be broken.\n * Units: radians * * \li\b apz.axis_lock.direct_pan_angle * If the angle from an axis to the line drawn by a pan move is less than * this value, we can assume that panning can be done in the allowed direction * (horizontal or vertical).\n * Currently used only for touch-action css property stuff and was addded to * keep behaviour consistent with IE.\n * Units: radians * * \li\b apz.content_response_timeout * Amount of time before we timeout response from content. For example, if * content is being unruly/slow and we don't get a response back within this * time, we will just pretend that content did not preventDefault any touch * events we dispatched to it.\n * Units: milliseconds * * \li\b apz.danger_zone_x * \li\b apz.danger_zone_y * When drawing high-res tiles, we drop down to drawing low-res tiles * when we know we can't keep up with the scrolling. The way we determine * this is by checking if we are entering the "danger zone", which is the * boundary of the painted content. For example, if the painted content * goes from y=0...1000 and the visible portion is y=250...750 then * we're far from checkerboarding. If we get to y=490...990 though then we're * only 10 pixels away from showing checkerboarding so we are probably in * a state where we can't keep up with scrolling. The danger zone prefs specify * how wide this margin is; in the above example a y-axis danger zone of 10 * pixels would make us drop to low-res at y=490...990.\n * This value is in layer pixels. * * \li\b apz.disable_for_scroll_linked_effects * Setting this pref to true will disable APZ scrolling on documents where * scroll-linked effects are detected. A scroll linked effect is detected if * positioning or transform properties are updated inside a scroll event * dispatch; we assume that such an update is in response to the scroll event * and is therefore a scroll-linked effect which will be laggy with APZ * scrolling. * * \li\b apz.displayport_expiry_ms * While a scrollable frame is scrolling async, we set a displayport on it * to make sure it is layerized. However this takes up memory, so once the * scrolling stops we want to remove the displayport. This pref controls how * long after scrolling stops the displayport is removed. A value of 0 will * disable the expiry behavior entirely. * Units: milliseconds * * \li\b apz.enlarge_displayport_when_clipped * Pref that enables enlarging of the displayport along one axis when the * generated displayport's size is beyond that of the scrollable rect on the * opposite axis. * * \li\b apz.fling_accel_interval_ms * The time that determines whether a second fling will be treated as * accelerated. If two flings are started within this interval, the second one * will be accelerated. Setting an interval of 0 means that acceleration will * be disabled.\n * Units: milliseconds * * \li\b apz.fling_accel_min_velocity * The minimum velocity of the second fling for it to be considered for fling * acceleration. * Units: screen pixels per milliseconds * * \li\b apz.fling_accel_base_mult * \li\b apz.fling_accel_supplemental_mult * When applying an acceleration on a fling, the new computed velocity is * (new_fling_velocity * base_mult) + (old_velocity * supplemental_mult). * The base_mult and supplemental_mult multiplier values are controlled by * these prefs. Note that "old_velocity" here is the initial velocity of the * previous fling _after_ acceleration was applied to it (if applicable). * * \li\b apz.fling_curve_function_x1 * \li\b apz.fling_curve_function_y1 * \li\b apz.fling_curve_function_x2 * \li\b apz.fling_curve_function_y2 * \li\b apz.fling_curve_threshold_inches_per_ms * These five parameters define a Bezier curve function and threshold used to * increase the actual velocity relative to the user's finger velocity. When the * finger velocity is below the threshold (or if the threshold is not positive), * the velocity is used as-is. If the finger velocity exceeds the threshold * velocity, then the function defined by the curve is applied on the part of * the velocity that exceeds the threshold. Note that the upper bound of the * velocity is still specified by the \b apz.max_velocity_inches_per_ms pref, and * the function will smoothly curve the velocity from the threshold to the * max. In general the function parameters chosen should define an ease-out * curve in order to increase the velocity in this range, or an ease-in curve to * decrease the velocity. A straight-line curve is equivalent to disabling the * curve entirely by setting the threshold to -1. The max velocity pref must * also be set in order for the curving to take effect, as it defines the upper * bound of the velocity curve.\n * The points (x1, y1) and (x2, y2) used as the two intermediate control points * in the cubic bezier curve; the first and last points are (0,0) and (1,1).\n * Some example values for these prefs can be found at\n * https://dxr.mozilla.org/mozilla-central/rev/70e05c6832e831374604ac3ce7433971368dffe0/layout/style/nsStyleStruct.cpp#2729 * * \li\b apz.fling_friction * Amount of friction applied during flings. This is used in the following * formula: v(t1) = v(t0) * (1 - f)^(t1 - t0), where v(t1) is the velocity * for a new sample, v(t0) is the velocity at the previous sample, f is the * value of this pref, and (t1 - t0) is the amount of time, in milliseconds, * that has elapsed between the two samples.\n * * \li\b apz.fling_min_velocity_threshold * Minimum velocity for a fling to actually kick off. If the user pans and lifts * their finger such that the velocity is smaller than this amount, no fling * is initiated.\n * Units: screen pixels per millisecond * * \li\b apz.fling_stop_on_tap_threshold * When flinging, if the velocity is above this number, then a tap on the * screen will stop the fling without dispatching a tap to content. If the * velocity is below this threshold a tap will also be dispatched. * Note: when modifying this pref be sure to run the APZC gtests as some of * them depend on the value of this pref.\n * Units: screen pixels per millisecond * * \li\b apz.fling_stopped_threshold * When flinging, if the velocity goes below this number, we just stop the * animation completely. This is to prevent asymptotically approaching 0 * velocity and rerendering unnecessarily.\n * Units: screen pixels per millisecond.\n * * \li\b apz.max_velocity_inches_per_ms * Maximum velocity. Velocity will be capped at this value if a faster fling * occurs. Negative values indicate unlimited velocity.\n * Units: (real-world, i.e. screen) inches per millisecond * * \li\b apz.max_velocity_queue_size * Maximum size of velocity queue. The queue contains last N velocity records. * On touch end we calculate the average velocity in order to compensate * touch/mouse drivers misbehaviour. * * \li\b apz.min_skate_speed * Minimum amount of speed along an axis before we switch to "skate" multipliers * rather than using the "stationary" multipliers.\n * Units: CSS pixels per millisecond * * \li\b apz.overscroll.enabled * Pref that enables overscrolling. If this is disabled, excess scroll that * cannot be handed off is discarded. * * \li\b apz.overscroll.min_pan_distance_ratio * The minimum ratio of the pan distance along one axis to the pan distance * along the other axis needed to initiate overscroll along the first axis * during panning. * * \li\b apz.overscroll.stretch_factor * How much overscrolling can stretch content along an axis. * The maximum stretch along an axis is a factor of (1 + kStretchFactor). * (So if kStretchFactor is 0, you can't stretch at all; if kStretchFactor * is 1, you can stretch at most by a factor of 2). * * \li\b apz.overscroll.spring_stiffness * The stiffness of the spring used in the physics model for the overscroll * animation. * * \li\b apz.overscroll.spring_friction * The friction of the spring used in the physics model for the overscroll * animation. * Even though a realistic physics model would dictate that this be the same * as \b apz.fling_friction, we allow it to be set to be something different, * because in practice we want flings to skate smoothly (low friction), while * we want the overscroll bounce-back to oscillate few times (high friction). * * \li\b apz.overscroll.stop_distance_threshold * \li\b apz.overscroll.stop_velocity_threshold * Thresholds for stopping the overscroll animation. When both the distance * and the velocity fall below their thresholds, we stop oscillating.\n * Units: screen pixels (for distance) * screen pixels per millisecond (for velocity) * * \li\b apz.paint_skipping.enabled * When APZ is scrolling and sending repaint requests to the main thread, often * the main thread doesn't actually need to do a repaint. This pref allows the * main thread to skip doing those repaints in cases where it doesn't need to. * * \li\b apz.record_checkerboarding * Whether or not to record detailed info on checkerboarding events. * * \li\b apz.test.logging_enabled * Enable logging of APZ test data (see bug 961289). * * \li\b apz.touch_move_tolerance * See the description for apz.touch_start_tolerance below. This is a similar * threshold, except it is used to suppress touchmove events from being delivered * to content for NON-scrollable frames (or more precisely, for APZCs where * ArePointerEventsConsumable returns false).\n * Units: (real-world, i.e. screen) inches * * \li\b apz.touch_start_tolerance * Constant describing the tolerance in distance we use, multiplied by the * device DPI, before we start panning the screen. This is to prevent us from * accidentally processing taps as touch moves, and from very short/accidental * touches moving the screen. touchmove events are also not delivered to content * within this distance on scrollable frames.\n * Units: (real-world, i.e. screen) inches * * \li\b apz.velocity_bias * How much to adjust the displayport in the direction of scrolling. This value * is multiplied by the velocity and added to the displayport offset. * * \li\b apz.velocity_relevance_time_ms * When computing a fling velocity from the most recently stored velocity * information, only velocities within the most X milliseconds are used. * This pref controls the value of X.\n * Units: ms * * \li\b apz.x_skate_size_multiplier * \li\b apz.y_skate_size_multiplier * The multiplier we apply to the displayport size if it is skating (current * velocity is above \b apz.min_skate_speed). We prefer to increase the size of * the Y axis because it is more natural in the case that a user is reading a * page page that scrolls up/down. Note that one, both or neither of these may be * used at any instant.\n * In general we want \b apz.[xy]_skate_size_multiplier to be smaller than the corresponding * stationary size multiplier because when panning fast we would like to paint * less and get faster, more predictable paint times. When panning slowly we * can afford to paint more even though it's slower. * * \li\b apz.x_stationary_size_multiplier * \li\b apz.y_stationary_size_multiplier * The multiplier we apply to the displayport size if it is not skating (see * documentation for the skate size multipliers above). * * \li\b apz.x_skate_highmem_adjust * \li\b apz.y_skate_highmem_adjust * On high memory systems, we adjust the displayport during skating * to be larger so we can reduce checkerboarding. * * \li\b apz.zoom_animation_duration_ms * This controls how long the zoom-to-rect animation takes.\n * Units: ms * * \li\b apz.scale_repaint_delay_ms * How long to delay between repaint requests during a scale. * A negative number prevents repaint requests during a scale.\n * Units: ms * */ /** * Computed time function used for sampling frames of a zoom to animation. */ StaticAutoPtr gZoomAnimationFunction; /** * Computed time function used for curving up velocity when it gets high. */ StaticAutoPtr gVelocityCurveFunction; /** * The estimated duration of a paint for the purposes of calculating a new * displayport, in milliseconds. */ static const double kDefaultEstimatedPaintDurationMs = 50; /** * Returns true if this is a high memory system and we can use * extra memory for a larger displayport to reduce checkerboarding. */ static bool gIsHighMemSystem = false; static bool IsHighMemSystem() { return gIsHighMemSystem; } /** * Is aAngle within the given threshold of the horizontal axis? * @param aAngle an angle in radians in the range [0, pi] * @param aThreshold an angle in radians in the range [0, pi/2] */ static bool IsCloseToHorizontal(float aAngle, float aThreshold) { return (aAngle < aThreshold || aAngle > (M_PI - aThreshold)); } // As above, but for the vertical axis. static bool IsCloseToVertical(float aAngle, float aThreshold) { return (fabs(aAngle - (M_PI / 2)) < aThreshold); } // Counter used to give each APZC a unique id static uint32_t sAsyncPanZoomControllerCount = 0; TimeStamp AsyncPanZoomController::GetFrameTime() const { APZCTreeManager* treeManagerLocal = GetApzcTreeManager(); return treeManagerLocal ? treeManagerLocal->GetFrameTime() : TimeStamp::Now(); } class MOZ_STACK_CLASS StateChangeNotificationBlocker { public: explicit StateChangeNotificationBlocker(AsyncPanZoomController* aApzc) : mApzc(aApzc) { ReentrantMonitorAutoEnter lock(mApzc->mMonitor); mInitialState = mApzc->mState; mApzc->mNotificationBlockers++; } ~StateChangeNotificationBlocker() { AsyncPanZoomController::PanZoomState newState; { ReentrantMonitorAutoEnter lock(mApzc->mMonitor); mApzc->mNotificationBlockers--; newState = mApzc->mState; } mApzc->DispatchStateChangeNotification(mInitialState, newState); } private: AsyncPanZoomController* mApzc; AsyncPanZoomController::PanZoomState mInitialState; }; class ZoomAnimation: public AsyncPanZoomAnimation { public: ZoomAnimation(CSSPoint aStartOffset, CSSToParentLayerScale2D aStartZoom, CSSPoint aEndOffset, CSSToParentLayerScale2D aEndZoom) : mTotalDuration(TimeDuration::FromMilliseconds(gfxPrefs::APZZoomAnimationDuration())) , mStartOffset(aStartOffset) , mStartZoom(aStartZoom) , mEndOffset(aEndOffset) , mEndZoom(aEndZoom) {} virtual bool DoSample(FrameMetrics& aFrameMetrics, const TimeDuration& aDelta) override { mDuration += aDelta; double animPosition = mDuration / mTotalDuration; if (animPosition >= 1.0) { aFrameMetrics.SetZoom(mEndZoom); aFrameMetrics.SetScrollOffset(mEndOffset); return false; } // Sample the zoom at the current time point. The sampled zoom // will affect the final computed resolution. float sampledPosition = gZoomAnimationFunction->GetValue(animPosition, ComputedTimingFunction::BeforeFlag::Unset); // We scale the scrollOffset linearly with sampledPosition, so the zoom // needs to scale inversely to match. aFrameMetrics.SetZoom(CSSToParentLayerScale2D( 1 / (sampledPosition / mEndZoom.xScale + (1 - sampledPosition) / mStartZoom.xScale), 1 / (sampledPosition / mEndZoom.yScale + (1 - sampledPosition) / mStartZoom.yScale))); aFrameMetrics.SetScrollOffset(CSSPoint::FromUnknownPoint(gfx::Point( mEndOffset.x * sampledPosition + mStartOffset.x * (1 - sampledPosition), mEndOffset.y * sampledPosition + mStartOffset.y * (1 - sampledPosition) ))); return true; } virtual bool WantsRepaints() override { return false; } private: TimeDuration mDuration; const TimeDuration mTotalDuration; // Old metrics from before we started a zoom animation. This is only valid // when we are in the "ANIMATED_ZOOM" state. This is used so that we can // interpolate between the start and end frames. We only use the // |mViewportScrollOffset| and |mResolution| fields on this. CSSPoint mStartOffset; CSSToParentLayerScale2D mStartZoom; // Target metrics for a zoom to animation. This is only valid when we are in // the "ANIMATED_ZOOM" state. We only use the |mViewportScrollOffset| and // |mResolution| fields on this. CSSPoint mEndOffset; CSSToParentLayerScale2D mEndZoom; }; class SmoothScrollAnimation : public AsyncPanZoomAnimation { public: SmoothScrollAnimation(AsyncPanZoomController& aApzc, const nsPoint &aInitialPosition, const nsPoint &aInitialVelocity, const nsPoint& aDestination, double aSpringConstant, double aDampingRatio) : mApzc(aApzc) , mXAxisModel(aInitialPosition.x, aDestination.x, aInitialVelocity.x, aSpringConstant, aDampingRatio) , mYAxisModel(aInitialPosition.y, aDestination.y, aInitialVelocity.y, aSpringConstant, aDampingRatio) { } /** * Advances a smooth scroll simulation based on the time passed in |aDelta|. * This should be called whenever sampling the content transform for this * frame. Returns true if the smooth scroll should be advanced by one frame, * or false if the smooth scroll has ended. */ bool DoSample(FrameMetrics& aFrameMetrics, const TimeDuration& aDelta) override { nsPoint oneParentLayerPixel = CSSPoint::ToAppUnits(ParentLayerPoint(1, 1) / aFrameMetrics.GetZoom()); if (mXAxisModel.IsFinished(oneParentLayerPixel.x) && mYAxisModel.IsFinished(oneParentLayerPixel.y)) { // Set the scroll offset to the exact destination. If we allow the scroll // offset to end up being a bit off from the destination, we can get // artefacts like "scroll to the next snap point in this direction" // scrolling to the snap point we're already supposed to be at. aFrameMetrics.SetScrollOffset( aFrameMetrics.CalculateScrollRange().ClampPoint( CSSPoint::FromAppUnits(nsPoint(mXAxisModel.GetDestination(), mYAxisModel.GetDestination())))); return false; } mXAxisModel.Simulate(aDelta); mYAxisModel.Simulate(aDelta); CSSPoint position = CSSPoint::FromAppUnits(nsPoint(mXAxisModel.GetPosition(), mYAxisModel.GetPosition())); CSSPoint css_velocity = CSSPoint::FromAppUnits(nsPoint(mXAxisModel.GetVelocity(), mYAxisModel.GetVelocity())); // Convert from points/second to points/ms ParentLayerPoint velocity = ParentLayerPoint(css_velocity.x, css_velocity.y) / 1000.0f; // Keep the velocity updated for the Axis class so that any animations // chained off of the smooth scroll will inherit it. if (mXAxisModel.IsFinished(oneParentLayerPixel.x)) { mApzc.mX.SetVelocity(0); } else { mApzc.mX.SetVelocity(velocity.x); } if (mYAxisModel.IsFinished(oneParentLayerPixel.y)) { mApzc.mY.SetVelocity(0); } else { mApzc.mY.SetVelocity(velocity.y); } // If we overscroll, hand off to a fling animation that will complete the // spring back. CSSToParentLayerScale2D zoom = aFrameMetrics.GetZoom(); ParentLayerPoint displacement = (position - aFrameMetrics.GetScrollOffset()) * zoom; ParentLayerPoint overscroll; ParentLayerPoint adjustedOffset; mApzc.mX.AdjustDisplacement(displacement.x, adjustedOffset.x, overscroll.x); mApzc.mY.AdjustDisplacement(displacement.y, adjustedOffset.y, overscroll.y); aFrameMetrics.ScrollBy(adjustedOffset / zoom); // The smooth scroll may have caused us to reach the end of our scroll range. // This can happen if either the layout.css.scroll-behavior.damping-ratio // preference is set to less than 1 (underdamped) or if a smooth scroll // inherits velocity from a fling gesture. if (!IsZero(overscroll)) { // Hand off a fling with the remaining momentum to the next APZC in the // overscroll handoff chain. // We may have reached the end of the scroll range along one axis but // not the other. In such a case we only want to hand off the relevant // component of the fling. if (FuzzyEqualsAdditive(overscroll.x, 0.0f, COORDINATE_EPSILON)) { velocity.x = 0; } else if (FuzzyEqualsAdditive(overscroll.y, 0.0f, COORDINATE_EPSILON)) { velocity.y = 0; } // To hand off the fling, we attempt to find a target APZC and start a new // fling with the same velocity on that APZC. For simplicity, the actual // overscroll of the current sample is discarded rather than being handed // off. The compositor should sample animations sufficiently frequently // that this is not noticeable. The target APZC is chosen by seeing if // there is an APZC further in the handoff chain which is pannable; if // there isn't, we take the new fling ourselves, entering an overscrolled // state. // Note: APZC is holding mMonitor, so directly calling // HandleSmoothScrollOverscroll() (which acquires the tree lock) would violate // the lock ordering. Instead we schedule HandleSmoothScrollOverscroll() to be // called after mMonitor is released. mDeferredTasks.AppendElement( NewRunnableMethod(&mApzc, &AsyncPanZoomController::HandleSmoothScrollOverscroll, velocity)); return false; } return true; } void SetDestination(const nsPoint& aNewDestination) { mXAxisModel.SetDestination(static_cast(aNewDestination.x)); mYAxisModel.SetDestination(static_cast(aNewDestination.y)); } CSSPoint GetDestination() const { return CSSPoint::FromAppUnits( nsPoint(mXAxisModel.GetDestination(), mYAxisModel.GetDestination())); } SmoothScrollAnimation* AsSmoothScrollAnimation() override { return this; } private: AsyncPanZoomController& mApzc; AxisPhysicsMSDModel mXAxisModel, mYAxisModel; }; /*static*/ void AsyncPanZoomController::InitializeGlobalState() { static bool sInitialized = false; if (sInitialized) return; sInitialized = true; MOZ_ASSERT(NS_IsMainThread()); gZoomAnimationFunction = new ComputedTimingFunction(); gZoomAnimationFunction->Init( nsTimingFunction(NS_STYLE_TRANSITION_TIMING_FUNCTION_EASE)); ClearOnShutdown(&gZoomAnimationFunction); gVelocityCurveFunction = new ComputedTimingFunction(); gVelocityCurveFunction->Init( nsTimingFunction(gfxPrefs::APZCurveFunctionX1(), gfxPrefs::APZCurveFunctionY2(), gfxPrefs::APZCurveFunctionX2(), gfxPrefs::APZCurveFunctionY2())); ClearOnShutdown(&gVelocityCurveFunction); uint64_t sysmem = PR_GetPhysicalMemorySize(); uint64_t threshold = 1LL << 32; // 4 GB in bytes gIsHighMemSystem = sysmem >= threshold; } AsyncPanZoomController::AsyncPanZoomController(uint64_t aLayersId, APZCTreeManager* aTreeManager, const RefPtr& aInputQueue, GeckoContentController* aGeckoContentController, GestureBehavior aGestures) : mLayersId(aLayersId), mGeckoContentController(aGeckoContentController), mRefPtrMonitor("RefPtrMonitor"), // mTreeManager must be initialized before GetFrameTime() is called mTreeManager(aTreeManager), mFrameMetrics(mScrollMetadata.GetMetrics()), mMonitor("AsyncPanZoomController"), mLastContentPaintMetrics(mLastContentPaintMetadata.GetMetrics()), mX(this), mY(this), mPanDirRestricted(false), mZoomConstraints(false, false, mFrameMetrics.GetDevPixelsPerCSSPixel() * kViewportMinScale / ParentLayerToScreenScale(1), mFrameMetrics.GetDevPixelsPerCSSPixel() * kViewportMaxScale / ParentLayerToScreenScale(1)), mLastSampleTime(GetFrameTime()), mLastCheckerboardReport(GetFrameTime()), mOverscrollEffect(MakeUnique(*this)), mState(NOTHING), mNotificationBlockers(0), mInputQueue(aInputQueue), mPinchPaintTimerSet(false), mAPZCId(sAsyncPanZoomControllerCount++), mSharedLock(nullptr), mAsyncTransformAppliedToContent(false), mCheckerboardEventLock("APZCBELock") { if (aGestures == USE_GESTURE_DETECTOR) { mGestureEventListener = new GestureEventListener(this); } } AsyncPanZoomController::~AsyncPanZoomController() { MOZ_ASSERT(IsDestroyed()); } PlatformSpecificStateBase* AsyncPanZoomController::GetPlatformSpecificState() { if (!mPlatformSpecificState) { mPlatformSpecificState = MakeUnique(); } return mPlatformSpecificState.get(); } already_AddRefed AsyncPanZoomController::GetGeckoContentController() const { MonitorAutoLock lock(mRefPtrMonitor); RefPtr controller = mGeckoContentController; return controller.forget(); } already_AddRefed AsyncPanZoomController::GetGestureEventListener() const { MonitorAutoLock lock(mRefPtrMonitor); RefPtr listener = mGestureEventListener; return listener.forget(); } const RefPtr& AsyncPanZoomController::GetInputQueue() const { return mInputQueue; } void AsyncPanZoomController::Destroy() { APZThreadUtils::AssertOnCompositorThread(); CancelAnimation(CancelAnimationFlags::ScrollSnap); { // scope the lock MonitorAutoLock lock(mRefPtrMonitor); mGeckoContentController = nullptr; mGestureEventListener = nullptr; } mParent = nullptr; mTreeManager = nullptr; // Only send the release message if the SharedFrameMetrics has been created. if (mMetricsSharingController && mSharedFrameMetricsBuffer) { Unused << mMetricsSharingController->StopSharingMetrics(mFrameMetrics.GetScrollId(), mAPZCId); } { // scope the lock ReentrantMonitorAutoEnter lock(mMonitor); mSharedFrameMetricsBuffer = nullptr; delete mSharedLock; mSharedLock = nullptr; } } bool AsyncPanZoomController::IsDestroyed() const { return mTreeManager == nullptr; } /* static */ScreenCoord AsyncPanZoomController::GetTouchStartTolerance() { return (gfxPrefs::APZTouchStartTolerance() * APZCTreeManager::GetDPI()); } /* static */AsyncPanZoomController::AxisLockMode AsyncPanZoomController::GetAxisLockMode() { return static_cast(gfxPrefs::APZAxisLockMode()); } bool AsyncPanZoomController::ArePointerEventsConsumable(TouchBlockState* aBlock, uint32_t aTouchPoints) { if (aTouchPoints == 0) { // Cant' do anything with zero touch points return false; } // This logic is simplified, erring on the side of returning true // if we're not sure. It's safer to pretend that we can consume the // event and then not be able to than vice-versa. // We could probably enhance this logic to determine things like "we're // not pannable, so we can only zoom in, and the zoom is already maxed // out, so we're not zoomable either" but no need for that at this point. bool pannable = aBlock->GetOverscrollHandoffChain()->CanBePanned(this); bool zoomable = mZoomConstraints.mAllowZoom; pannable &= (aBlock->TouchActionAllowsPanningX() || aBlock->TouchActionAllowsPanningY()); zoomable &= (aBlock->TouchActionAllowsPinchZoom()); // XXX once we fix bug 1031443, consumable should be assigned // pannable || zoomable if aTouchPoints > 1. bool consumable = (aTouchPoints == 1 ? pannable : zoomable); if (!consumable) { return false; } return true; } template static CoordTyped GetAxisStart( AsyncDragMetrics::DragDirection aDir, const PointTyped& aValue) { if (aDir == AsyncDragMetrics::HORIZONTAL) { return aValue.x; } else { return aValue.y; } } template static CoordTyped GetAxisStart(AsyncDragMetrics::DragDirection aDir, const RectTyped& aValue) { if (aDir == AsyncDragMetrics::HORIZONTAL) { return aValue.x; } else { return aValue.y; } } template static IntCoordTyped GetAxisStart(AsyncDragMetrics::DragDirection aDir, const IntRectTyped& aValue) { if (aDir == AsyncDragMetrics::HORIZONTAL) { return aValue.x; } else { return aValue.y; } } template static IntCoordTyped GetAxisEnd(AsyncDragMetrics::DragDirection aDir, const IntRectTyped& aValue) { if (aDir == AsyncDragMetrics::HORIZONTAL) { return aValue.x + aValue.width; } else { return aValue.y + aValue.height; } } template static CoordTyped GetAxisSize(AsyncDragMetrics::DragDirection aDir, const RectTyped& aValue) { if (aDir == AsyncDragMetrics::HORIZONTAL) { return aValue.width; } else { return aValue.height; } } template static float GetAxisScale(AsyncDragMetrics::DragDirection aDir, const ScaleFactors2D& aValue) { if (aDir == AsyncDragMetrics::HORIZONTAL) { return aValue.xScale; } else { return aValue.yScale; } } nsEventStatus AsyncPanZoomController::HandleDragEvent(const MouseInput& aEvent, const AsyncDragMetrics& aDragMetrics) { if (!gfxPrefs::APZDragEnabled()) { return nsEventStatus_eIgnore; } if (!GetApzcTreeManager()) { return nsEventStatus_eConsumeNoDefault; } RefPtr node = GetApzcTreeManager()->FindScrollNode(aDragMetrics); if (!node) { return nsEventStatus_eConsumeNoDefault; } ReentrantMonitorAutoEnter lock(mMonitor); CSSPoint scrollFramePoint = aEvent.mLocalOrigin / GetFrameMetrics().GetZoom(); // The scrollbar can be transformed with the frame but the pres shell // resolution is only applied to the scroll frame. CSSPoint scrollbarPoint = scrollFramePoint * mFrameMetrics.GetPresShellResolution(); CSSRect cssCompositionBound = mFrameMetrics.CalculateCompositedRectInCssPixels(); CSSCoord mousePosition = GetAxisStart(aDragMetrics.mDirection, scrollbarPoint) - CSSCoord(aDragMetrics.mScrollbarDragOffset) - GetAxisStart(aDragMetrics.mDirection, cssCompositionBound) - CSSCoord(GetAxisStart(aDragMetrics.mDirection, aDragMetrics.mScrollTrack)); CSSCoord scrollMax = CSSCoord(GetAxisEnd(aDragMetrics.mDirection, aDragMetrics.mScrollTrack)); scrollMax -= node->GetScrollSize() / GetAxisScale(aDragMetrics.mDirection, mFrameMetrics.GetZoom()) * mFrameMetrics.GetPresShellResolution(); float scrollPercent = mousePosition / scrollMax; CSSCoord minScrollPosition = GetAxisStart(aDragMetrics.mDirection, mFrameMetrics.GetScrollableRect().TopLeft()); CSSCoord maxScrollPosition = GetAxisSize(aDragMetrics.mDirection, mFrameMetrics.GetScrollableRect()) - GetAxisSize(aDragMetrics.mDirection, cssCompositionBound); CSSCoord scrollPosition = scrollPercent * maxScrollPosition; scrollPosition = std::max(scrollPosition, minScrollPosition); scrollPosition = std::min(scrollPosition, maxScrollPosition); CSSPoint scrollOffset = mFrameMetrics.GetScrollOffset(); if (aDragMetrics.mDirection == AsyncDragMetrics::HORIZONTAL) { scrollOffset.x = scrollPosition; } else { scrollOffset.y = scrollPosition; } mFrameMetrics.SetScrollOffset(scrollOffset); ScheduleCompositeAndMaybeRepaint(); UpdateSharedCompositorFrameMetrics(); return nsEventStatus_eConsumeNoDefault; } nsEventStatus AsyncPanZoomController::HandleInputEvent(const InputData& aEvent, const ScreenToParentLayerMatrix4x4& aTransformToApzc) { APZThreadUtils::AssertOnControllerThread(); nsEventStatus rv = nsEventStatus_eIgnore; switch (aEvent.mInputType) { case MULTITOUCH_INPUT: { MultiTouchInput multiTouchInput = aEvent.AsMultiTouchInput(); if (!multiTouchInput.TransformToLocal(aTransformToApzc)) { return rv; } RefPtr listener = GetGestureEventListener(); if (listener) { rv = listener->HandleInputEvent(multiTouchInput); if (rv == nsEventStatus_eConsumeNoDefault) { return rv; } } switch (multiTouchInput.mType) { case MultiTouchInput::MULTITOUCH_START: rv = OnTouchStart(multiTouchInput); break; case MultiTouchInput::MULTITOUCH_MOVE: rv = OnTouchMove(multiTouchInput); break; case MultiTouchInput::MULTITOUCH_END: rv = OnTouchEnd(multiTouchInput); break; case MultiTouchInput::MULTITOUCH_CANCEL: rv = OnTouchCancel(multiTouchInput); break; default: NS_WARNING("Unhandled multitouch"); break; } break; } case PANGESTURE_INPUT: { PanGestureInput panGestureInput = aEvent.AsPanGestureInput(); if (!panGestureInput.TransformToLocal(aTransformToApzc)) { return rv; } switch (panGestureInput.mType) { case PanGestureInput::PANGESTURE_MAYSTART: rv = OnPanMayBegin(panGestureInput); break; case PanGestureInput::PANGESTURE_CANCELLED: rv = OnPanCancelled(panGestureInput); break; case PanGestureInput::PANGESTURE_START: rv = OnPanBegin(panGestureInput); break; case PanGestureInput::PANGESTURE_PAN: rv = OnPan(panGestureInput, true); break; case PanGestureInput::PANGESTURE_END: rv = OnPanEnd(panGestureInput); break; case PanGestureInput::PANGESTURE_MOMENTUMSTART: rv = OnPanMomentumStart(panGestureInput); break; case PanGestureInput::PANGESTURE_MOMENTUMPAN: rv = OnPan(panGestureInput, false); break; case PanGestureInput::PANGESTURE_MOMENTUMEND: rv = OnPanMomentumEnd(panGestureInput); break; default: NS_WARNING("Unhandled pan gesture"); break; } break; } case MOUSE_INPUT: { MouseInput mouseInput = aEvent.AsMouseInput(); if (!mouseInput.TransformToLocal(aTransformToApzc)) { return rv; } // TODO Need to implement blocks to properly handle this. //rv = HandleDragEvent(mouseInput, dragMetrics); break; } case SCROLLWHEEL_INPUT: { ScrollWheelInput scrollInput = aEvent.AsScrollWheelInput(); if (!scrollInput.TransformToLocal(aTransformToApzc)) { return rv; } rv = OnScrollWheel(scrollInput); break; } case PINCHGESTURE_INPUT: { PinchGestureInput pinchInput = aEvent.AsPinchGestureInput(); if (!pinchInput.TransformToLocal(aTransformToApzc)) { return rv; } rv = HandleGestureEvent(pinchInput); break; } case TAPGESTURE_INPUT: { TapGestureInput tapInput = aEvent.AsTapGestureInput(); if (!tapInput.TransformToLocal(aTransformToApzc)) { return rv; } rv = HandleGestureEvent(tapInput); break; } default: NS_WARNING("Unhandled input event type"); break; } return rv; } nsEventStatus AsyncPanZoomController::HandleGestureEvent(const InputData& aEvent) { APZThreadUtils::AssertOnControllerThread(); nsEventStatus rv = nsEventStatus_eIgnore; switch (aEvent.mInputType) { case PINCHGESTURE_INPUT: { const PinchGestureInput& pinchGestureInput = aEvent.AsPinchGestureInput(); switch (pinchGestureInput.mType) { case PinchGestureInput::PINCHGESTURE_START: rv = OnScaleBegin(pinchGestureInput); break; case PinchGestureInput::PINCHGESTURE_SCALE: rv = OnScale(pinchGestureInput); break; case PinchGestureInput::PINCHGESTURE_END: rv = OnScaleEnd(pinchGestureInput); break; default: NS_WARNING("Unhandled pinch gesture"); break; } break; } case TAPGESTURE_INPUT: { const TapGestureInput& tapGestureInput = aEvent.AsTapGestureInput(); switch (tapGestureInput.mType) { case TapGestureInput::TAPGESTURE_LONG: rv = OnLongPress(tapGestureInput); break; case TapGestureInput::TAPGESTURE_LONG_UP: rv = OnLongPressUp(tapGestureInput); break; case TapGestureInput::TAPGESTURE_UP: rv = OnSingleTapUp(tapGestureInput); break; case TapGestureInput::TAPGESTURE_CONFIRMED: rv = OnSingleTapConfirmed(tapGestureInput); break; case TapGestureInput::TAPGESTURE_DOUBLE: rv = OnDoubleTap(tapGestureInput); break; case TapGestureInput::TAPGESTURE_SECOND: rv = OnSecondTap(tapGestureInput); break; case TapGestureInput::TAPGESTURE_CANCEL: rv = OnCancelTap(tapGestureInput); break; default: NS_WARNING("Unhandled tap gesture"); break; } break; } default: NS_WARNING("Unhandled input event"); break; } return rv; } void AsyncPanZoomController::HandleTouchVelocity(uint32_t aTimesampMs, float aSpeedY) { mY.HandleTouchVelocity(aTimesampMs, aSpeedY); } nsEventStatus AsyncPanZoomController::OnTouchStart(const MultiTouchInput& aEvent) { APZC_LOG("%p got a touch-start in state %d\n", this, mState); mPanDirRestricted = false; ParentLayerPoint point = GetFirstTouchPoint(aEvent); switch (mState) { case FLING: case ANIMATING_ZOOM: case SMOOTH_SCROLL: case OVERSCROLL_ANIMATION: case WHEEL_SCROLL: case PAN_MOMENTUM: MOZ_ASSERT(GetCurrentTouchBlock()); GetCurrentTouchBlock()->GetOverscrollHandoffChain()->CancelAnimations(ExcludeOverscroll); MOZ_FALLTHROUGH; case NOTHING: { mX.StartTouch(point.x, aEvent.mTime); mY.StartTouch(point.y, aEvent.mTime); if (RefPtr controller = GetGeckoContentController()) { MOZ_ASSERT(GetCurrentTouchBlock()); controller->NotifyAPZStateChange( GetGuid(), APZStateChange::eStartTouch, GetCurrentTouchBlock()->GetOverscrollHandoffChain()->CanBePanned(this)); } SetState(TOUCHING); break; } case TOUCHING: case PANNING: case PANNING_LOCKED_X: case PANNING_LOCKED_Y: case PINCHING: NS_WARNING("Received impossible touch in OnTouchStart"); break; default: NS_WARNING("Unhandled case in OnTouchStart"); break; } return nsEventStatus_eConsumeNoDefault; } nsEventStatus AsyncPanZoomController::OnTouchMove(const MultiTouchInput& aEvent) { APZC_LOG("%p got a touch-move in state %d\n", this, mState); switch (mState) { case FLING: case SMOOTH_SCROLL: case NOTHING: case ANIMATING_ZOOM: // May happen if the user double-taps and drags without lifting after the // second tap. Ignore the move if this happens. return nsEventStatus_eIgnore; case TOUCHING: { ScreenCoord panThreshold = GetTouchStartTolerance(); UpdateWithTouchAtDevicePoint(aEvent); if (PanDistance() < panThreshold) { return nsEventStatus_eIgnore; } MOZ_ASSERT(GetCurrentTouchBlock()); if (gfxPrefs::TouchActionEnabled() && GetCurrentTouchBlock()->TouchActionAllowsPanningXY()) { // User tries to trigger a touch behavior. If allowed touch behavior is vertical pan // + horizontal pan (touch-action value is equal to AUTO) we can return ConsumeNoDefault // status immediately to trigger cancel event further. It should happen independent of // the parent type (whether it is scrolling or not). StartPanning(aEvent); return nsEventStatus_eConsumeNoDefault; } return StartPanning(aEvent); } case PANNING: case PANNING_LOCKED_X: case PANNING_LOCKED_Y: case PAN_MOMENTUM: TrackTouch(aEvent); return nsEventStatus_eConsumeNoDefault; case PINCHING: // The scale gesture listener should have handled this. NS_WARNING("Gesture listener should have handled pinching in OnTouchMove."); return nsEventStatus_eIgnore; case WHEEL_SCROLL: case OVERSCROLL_ANIMATION: // Should not receive a touch-move in the OVERSCROLL_ANIMATION state // as touch blocks that begin in an overscrolled state cancel the // animation. The same is true for wheel scroll animations. NS_WARNING("Received impossible touch in OnTouchMove"); break; } return nsEventStatus_eConsumeNoDefault; } nsEventStatus AsyncPanZoomController::OnTouchEnd(const MultiTouchInput& aEvent) { APZC_LOG("%p got a touch-end in state %d\n", this, mState); RefPtr controller = GetGeckoContentController(); if (controller) { controller->SetScrollingRootContent(false); } OnTouchEndOrCancel(); // In case no touch behavior triggered previously we can avoid sending // scroll events or requesting content repaint. This condition is added // to make tests consistent - in case touch-action is NONE (and therefore // no pans/zooms can be performed) we expected neither scroll or repaint // events. if (mState != NOTHING) { ReentrantMonitorAutoEnter lock(mMonitor); } switch (mState) { case FLING: // Should never happen. NS_WARNING("Received impossible touch end in OnTouchEnd."); MOZ_FALLTHROUGH; case ANIMATING_ZOOM: case SMOOTH_SCROLL: case NOTHING: // May happen if the user double-taps and drags without lifting after the // second tap. Ignore if this happens. return nsEventStatus_eIgnore; case TOUCHING: // We may have some velocity stored on the axis from move events // that were not big enough to trigger scrolling. Clear that out. mX.SetVelocity(0); mY.SetVelocity(0); MOZ_ASSERT(GetCurrentTouchBlock()); APZC_LOG("%p still has %u touch points active\n", this, GetCurrentTouchBlock()->GetActiveTouchCount()); // In cases where the user is panning, then taps the second finger without // entering a pinch, we will arrive here when the second finger is lifted. // However the first finger is still down so we want to remain in state // TOUCHING. if (GetCurrentTouchBlock()->GetActiveTouchCount() == 0) { // It's possible we may be overscrolled if the user tapped during a // previous overscroll pan. Make sure to snap back in this situation. // An ancestor APZC could be overscrolled instead of this APZC, so // walk the handoff chain as well. GetCurrentTouchBlock()->GetOverscrollHandoffChain()->SnapBackOverscrolledApzc(this); // SnapBackOverscrolledApzc() will put any APZC it causes to snap back // into the OVERSCROLL_ANIMATION state. If that's not us, since we're // done TOUCHING enter the NOTHING state. if (mState != OVERSCROLL_ANIMATION) { SetState(NOTHING); } } return nsEventStatus_eIgnore; case PANNING: case PANNING_LOCKED_X: case PANNING_LOCKED_Y: case PAN_MOMENTUM: { MOZ_ASSERT(GetCurrentTouchBlock()); GetCurrentTouchBlock()->GetOverscrollHandoffChain()->FlushRepaints(); mX.EndTouch(aEvent.mTime); mY.EndTouch(aEvent.mTime); ParentLayerPoint flingVelocity = GetVelocityVector(); // Clear our velocities; if DispatchFling() gives the fling to us, // the fling velocity gets *added* to our existing velocity in // AcceptFling(). mX.SetVelocity(0); mY.SetVelocity(0); // Clear our state so that we don't stay in the PANNING state // if DispatchFling() gives the fling to somone else. However, // don't send the state change notification until we've determined // what our final state is to avoid notification churn. StateChangeNotificationBlocker blocker(this); SetState(NOTHING); APZC_LOG("%p starting a fling animation if %f >= %f\n", this, flingVelocity.Length().value, gfxPrefs::APZFlingMinVelocityThreshold()); if (flingVelocity.Length() < gfxPrefs::APZFlingMinVelocityThreshold()) { return nsEventStatus_eConsumeNoDefault; } // Make a local copy of the tree manager pointer and check that it's not // null before calling DispatchFling(). This is necessary because Destroy(), // which nulls out mTreeManager, could be called concurrently. if (APZCTreeManager* treeManagerLocal = GetApzcTreeManager()) { FlingHandoffState handoffState{flingVelocity, GetCurrentTouchBlock()->GetOverscrollHandoffChain(), false /* not handoff */, GetCurrentTouchBlock()->GetScrolledApzc()}; treeManagerLocal->DispatchFling(this, handoffState); } return nsEventStatus_eConsumeNoDefault; } case PINCHING: SetState(NOTHING); // Scale gesture listener should have handled this. NS_WARNING("Gesture listener should have handled pinching in OnTouchEnd."); return nsEventStatus_eIgnore; case WHEEL_SCROLL: case OVERSCROLL_ANIMATION: // Should not receive a touch-end in the OVERSCROLL_ANIMATION state // as touch blocks that begin in an overscrolled state cancel the // animation. The same is true for WHEEL_SCROLL. NS_WARNING("Received impossible touch in OnTouchEnd"); break; } return nsEventStatus_eConsumeNoDefault; } nsEventStatus AsyncPanZoomController::OnTouchCancel(const MultiTouchInput& aEvent) { APZC_LOG("%p got a touch-cancel in state %d\n", this, mState); OnTouchEndOrCancel(); CancelAnimationAndGestureState(); return nsEventStatus_eConsumeNoDefault; } nsEventStatus AsyncPanZoomController::OnScaleBegin(const PinchGestureInput& aEvent) { APZC_LOG("%p got a scale-begin in state %d\n", this, mState); mPinchPaintTimerSet = false; // Note that there may not be a touch block at this point, if we received the // PinchGestureEvent directly from widget code without any touch events. if (HasReadyTouchBlock() && !GetCurrentTouchBlock()->TouchActionAllowsPinchZoom()) { return nsEventStatus_eIgnore; } // For platforms that don't support APZ zooming, dispatch a message to the // content controller, it may want to do something else with this gesture. if (!gfxPrefs::APZAllowZooming()) { if (RefPtr controller = GetGeckoContentController()) { controller->NotifyPinchGesture(aEvent.mType, GetGuid(), 0, aEvent.modifiers); } } SetState(PINCHING); mX.SetVelocity(0); mY.SetVelocity(0); mLastZoomFocus = aEvent.mLocalFocusPoint - mFrameMetrics.GetCompositionBounds().TopLeft(); return nsEventStatus_eConsumeNoDefault; } nsEventStatus AsyncPanZoomController::OnScale(const PinchGestureInput& aEvent) { APZC_LOG("%p got a scale in state %d\n", this, mState); if (HasReadyTouchBlock() && !GetCurrentTouchBlock()->TouchActionAllowsPinchZoom()) { return nsEventStatus_eIgnore; } if (mState != PINCHING) { return nsEventStatus_eConsumeNoDefault; } if (!gfxPrefs::APZAllowZooming()) { if (RefPtr controller = GetGeckoContentController()) { controller->NotifyPinchGesture(aEvent.mType, GetGuid(), ViewAs(aEvent.mCurrentSpan - aEvent.mPreviousSpan, PixelCastJustification::LayoutDeviceIsParentLayerForRCDRSF), aEvent.modifiers); } } // Only the root APZC is zoomable, and the root APZC is not allowed to have // different x and y scales. If it did, the calculations in this function // would have to be adjusted (as e.g. it would no longer be valid to take // the minimum or maximum of the ratios of the widths and heights of the // page rect and the composition bounds). MOZ_ASSERT(mFrameMetrics.IsRootContent()); MOZ_ASSERT(mFrameMetrics.GetZoom().AreScalesSame()); { ReentrantMonitorAutoEnter lock(mMonitor); CSSToParentLayerScale userZoom = mFrameMetrics.GetZoom().ToScaleFactor(); ParentLayerPoint focusPoint = aEvent.mLocalFocusPoint - mFrameMetrics.GetCompositionBounds().TopLeft(); CSSPoint cssFocusPoint = focusPoint / mFrameMetrics.GetZoom(); ParentLayerPoint focusChange = mLastZoomFocus - focusPoint; mLastZoomFocus = focusPoint; // If displacing by the change in focus point will take us off page bounds, // then reduce the displacement such that it doesn't. focusChange.x -= mX.DisplacementWillOverscrollAmount(focusChange.x); focusChange.y -= mY.DisplacementWillOverscrollAmount(focusChange.y); ScrollBy(focusChange / userZoom); // If the span is zero or close to it, we don't want to process this zoom // change because we're going to get wonky numbers for the spanRatio. So // let's bail out here. Note that we do this after the focus-change-scroll // above, so that if we have a pinch with zero span but changing focus, // such as generated by some Synaptics touchpads on Windows, we still // scroll properly. float prevSpan = aEvent.mPreviousSpan; if (fabsf(prevSpan) <= EPSILON || fabsf(aEvent.mCurrentSpan) <= EPSILON) { // We might have done a nonzero ScrollBy above, so update metrics and // repaint/recomposite ScheduleCompositeAndMaybeRepaint(); UpdateSharedCompositorFrameMetrics(); return nsEventStatus_eConsumeNoDefault; } float spanRatio = aEvent.mCurrentSpan / aEvent.mPreviousSpan; // When we zoom in with focus, we can zoom too much towards the boundaries // that we actually go over them. These are the needed displacements along // either axis such that we don't overscroll the boundaries when zooming. CSSPoint neededDisplacement; CSSToParentLayerScale realMinZoom = mZoomConstraints.mMinZoom; CSSToParentLayerScale realMaxZoom = mZoomConstraints.mMaxZoom; realMinZoom.scale = std::max(realMinZoom.scale, mFrameMetrics.GetCompositionBounds().width / mFrameMetrics.GetScrollableRect().width); realMinZoom.scale = std::max(realMinZoom.scale, mFrameMetrics.GetCompositionBounds().height / mFrameMetrics.GetScrollableRect().height); if (realMaxZoom < realMinZoom) { realMaxZoom = realMinZoom; } bool doScale = (spanRatio > 1.0 && userZoom < realMaxZoom) || (spanRatio < 1.0 && userZoom > realMinZoom); if (!mZoomConstraints.mAllowZoom) { doScale = false; } if (doScale) { spanRatio = clamped(spanRatio, realMinZoom.scale / userZoom.scale, realMaxZoom.scale / userZoom.scale); // Note that the spanRatio here should never put us into OVERSCROLL_BOTH because // up above we clamped it. neededDisplacement.x = -mX.ScaleWillOverscrollAmount(spanRatio, cssFocusPoint.x); neededDisplacement.y = -mY.ScaleWillOverscrollAmount(spanRatio, cssFocusPoint.y); ScaleWithFocus(spanRatio, cssFocusPoint); if (neededDisplacement != CSSPoint()) { ScrollBy(neededDisplacement); } // We don't want to redraw on every scale, so throttle it. if (!mPinchPaintTimerSet) { const int delay = gfxPrefs::APZScaleRepaintDelay(); if (delay >= 0) { if (RefPtr controller = GetGeckoContentController()) { mPinchPaintTimerSet = true; controller->PostDelayedTask( NewRunnableMethod(this, &AsyncPanZoomController::DoDelayedRequestContentRepaint), delay); } } } UpdateSharedCompositorFrameMetrics(); } // We did a ScrollBy call above even if we didn't do a scale, so we // should composite for that. ScheduleComposite(); } return nsEventStatus_eConsumeNoDefault; } nsEventStatus AsyncPanZoomController::OnScaleEnd(const PinchGestureInput& aEvent) { APZC_LOG("%p got a scale-end in state %d\n", this, mState); mPinchPaintTimerSet = false; if (HasReadyTouchBlock() && !GetCurrentTouchBlock()->TouchActionAllowsPinchZoom()) { return nsEventStatus_eIgnore; } if (!gfxPrefs::APZAllowZooming()) { if (RefPtr controller = GetGeckoContentController()) { controller->NotifyPinchGesture(aEvent.mType, GetGuid(), 0, aEvent.modifiers); } } SetState(NOTHING); { ReentrantMonitorAutoEnter lock(mMonitor); ScheduleComposite(); RequestContentRepaint(); UpdateSharedCompositorFrameMetrics(); } // Non-negative focus point would indicate that one finger is still down if (aEvent.mLocalFocusPoint.x != -1 && aEvent.mLocalFocusPoint.y != -1) { mPanDirRestricted = false; mX.StartTouch(aEvent.mLocalFocusPoint.x, aEvent.mTime); mY.StartTouch(aEvent.mLocalFocusPoint.y, aEvent.mTime); SetState(TOUCHING); } else { // Otherwise, handle the fingers being lifted. ReentrantMonitorAutoEnter lock(mMonitor); // We can get into a situation where we are overscrolled at the end of a // pinch if we go into overscroll with a two-finger pan, and then turn // that into a pinch by increasing the span sufficiently. In such a case, // there is no snap-back animation to get us out of overscroll, so we need // to get out of it somehow. // Moreover, in cases of scroll handoff, the overscroll can be on an APZC // further up in the handoff chain rather than on the current APZC, so // we need to clear overscroll along the entire handoff chain. if (HasReadyTouchBlock()) { GetCurrentTouchBlock()->GetOverscrollHandoffChain()->ClearOverscroll(); } else { ClearOverscroll(); } // Along with clearing the overscroll, we also want to snap to the nearest // snap point as appropriate. ScrollSnap(); } return nsEventStatus_eConsumeNoDefault; } bool AsyncPanZoomController::ConvertToGecko(const ScreenIntPoint& aPoint, LayoutDevicePoint* aOut) { if (APZCTreeManager* treeManagerLocal = GetApzcTreeManager()) { ScreenToScreenMatrix4x4 transformScreenToGecko = treeManagerLocal->GetScreenToApzcTransform(this) * treeManagerLocal->GetApzcToGeckoTransform(this); Maybe layoutPoint = UntransformBy( transformScreenToGecko, aPoint); if (!layoutPoint) { return false; } *aOut = LayoutDevicePoint(ViewAs(*layoutPoint, PixelCastJustification::LayoutDeviceIsScreenForUntransformedEvent)); return true; } return false; } static bool AllowsScrollingMoreThanOnePage(double aMultiplier) { const int32_t kMinAllowPageScroll = EventStateManager::MIN_MULTIPLIER_VALUE_ALLOWING_OVER_ONE_PAGE_SCROLL; return Abs(aMultiplier) >= kMinAllowPageScroll; } ParentLayerPoint AsyncPanZoomController::GetScrollWheelDelta(const ScrollWheelInput& aEvent) const { ParentLayerSize scrollAmount; ParentLayerSize pageScrollSize; { // Grab the lock to access the frame metrics. ReentrantMonitorAutoEnter lock(mMonitor); LayoutDeviceIntSize scrollAmountLD = mScrollMetadata.GetLineScrollAmount(); LayoutDeviceIntSize pageScrollSizeLD = mScrollMetadata.GetPageScrollAmount(); scrollAmount = scrollAmountLD / mFrameMetrics.GetDevPixelsPerCSSPixel() * mFrameMetrics.GetZoom(); pageScrollSize = pageScrollSizeLD / mFrameMetrics.GetDevPixelsPerCSSPixel() * mFrameMetrics.GetZoom(); } ParentLayerPoint delta; switch (aEvent.mDeltaType) { case ScrollWheelInput::SCROLLDELTA_LINE: { delta.x = aEvent.mDeltaX * scrollAmount.width; delta.y = aEvent.mDeltaY * scrollAmount.height; break; } case ScrollWheelInput::SCROLLDELTA_PAGE: { delta.x = aEvent.mDeltaX * pageScrollSize.width; delta.y = aEvent.mDeltaY * pageScrollSize.height; break; } case ScrollWheelInput::SCROLLDELTA_PIXEL: { delta = ToParentLayerCoordinates(ScreenPoint(aEvent.mDeltaX, aEvent.mDeltaY), aEvent.mOrigin); break; } default: MOZ_ASSERT_UNREACHABLE("unexpected scroll delta type"); } // Apply user-set multipliers. delta.x *= aEvent.mUserDeltaMultiplierX; delta.y *= aEvent.mUserDeltaMultiplierY; // For the conditions under which we allow system scroll overrides, see // EventStateManager::DeltaAccumulator::ComputeScrollAmountForDefaultAction // and WheelTransaction::OverrideSystemScrollSpeed. Note that we do *not* // restrict this to the root content, see bug 1217715 for discussion on this. if (gfxPrefs::MouseWheelHasRootScrollDeltaOverride() && !aEvent.IsCustomizedByUserPrefs() && aEvent.mDeltaType == ScrollWheelInput::SCROLLDELTA_LINE && aEvent.mAllowToOverrideSystemScrollSpeed) { delta.x = WidgetWheelEvent::ComputeOverriddenDelta(delta.x, false); delta.y = WidgetWheelEvent::ComputeOverriddenDelta(delta.y, true); } // If this is a line scroll, and this event was part of a scroll series, then // it might need extra acceleration. See WheelHandlingHelper.cpp. if (aEvent.mDeltaType == ScrollWheelInput::SCROLLDELTA_LINE && aEvent.mScrollSeriesNumber > 0) { int32_t start = gfxPrefs::MouseWheelAccelerationStart(); if (start >= 0 && aEvent.mScrollSeriesNumber >= uint32_t(start)) { int32_t factor = gfxPrefs::MouseWheelAccelerationFactor(); if (factor > 0) { delta.x = ComputeAcceleratedWheelDelta(delta.x, aEvent.mScrollSeriesNumber, factor); delta.y = ComputeAcceleratedWheelDelta(delta.y, aEvent.mScrollSeriesNumber, factor); } } } // We shouldn't scroll more than one page at once except when the // user preference is large. if (!AllowsScrollingMoreThanOnePage(aEvent.mUserDeltaMultiplierX) && Abs(delta.x) > pageScrollSize.width) { delta.x = (delta.x >= 0) ? pageScrollSize.width : -pageScrollSize.width; } if (!AllowsScrollingMoreThanOnePage(aEvent.mUserDeltaMultiplierY) && Abs(delta.y) > pageScrollSize.height) { delta.y = (delta.y >= 0) ? pageScrollSize.height : -pageScrollSize.height; } return delta; } // Return whether or not the underlying layer can be scrolled on either axis. bool AsyncPanZoomController::CanScroll(const InputData& aEvent) const { ParentLayerPoint delta; if (aEvent.mInputType == SCROLLWHEEL_INPUT) { delta = GetScrollWheelDelta(aEvent.AsScrollWheelInput()); } else if (aEvent.mInputType == PANGESTURE_INPUT) { const PanGestureInput& panInput = aEvent.AsPanGestureInput(); delta = ToParentLayerCoordinates(panInput.UserMultipliedPanDisplacement(), panInput.mPanStartPoint); } if (!delta.x && !delta.y) { return false; } return CanScrollWithWheel(delta); } bool AsyncPanZoomController::CanScrollWithWheel(const ParentLayerPoint& aDelta) const { ReentrantMonitorAutoEnter lock(mMonitor); if (mX.CanScroll(aDelta.x)) { return true; } if (mY.CanScroll(aDelta.y) && mScrollMetadata.AllowVerticalScrollWithWheel()) { return true; } return false; } bool AsyncPanZoomController::CanScroll(Layer::ScrollDirection aDirection) const { ReentrantMonitorAutoEnter lock(mMonitor); switch (aDirection) { case Layer::HORIZONTAL: return mX.CanScroll(); case Layer::VERTICAL: return mY.CanScroll(); default: MOZ_ASSERT(false); return false; } } bool AsyncPanZoomController::AllowScrollHandoffInCurrentBlock() const { bool result = mInputQueue->AllowScrollHandoff(); if (!gfxPrefs::APZAllowImmediateHandoff()) { if (InputBlockState* currentBlock = GetCurrentInputBlock()) { // Do not allow handoff beyond the first APZC to scroll. if (currentBlock->GetScrolledApzc() == this) { result = false; } } } return result; } void AsyncPanZoomController::DoDelayedRequestContentRepaint() { if (!IsDestroyed() && mPinchPaintTimerSet) { ReentrantMonitorAutoEnter lock(mMonitor); RequestContentRepaint(); } mPinchPaintTimerSet = false; } nsEventStatus AsyncPanZoomController::OnScrollWheel(const ScrollWheelInput& aEvent) { ParentLayerPoint delta = GetScrollWheelDelta(aEvent); APZC_LOG("%p got a scroll-wheel with delta %s\n", this, Stringify(delta).c_str()); if ((delta.x || delta.y) && !CanScrollWithWheel(delta)) { // We can't scroll this apz anymore, so we simply drop the event. if (mInputQueue->GetActiveWheelTransaction() && gfxPrefs::MouseScrollTestingEnabled()) { if (RefPtr controller = GetGeckoContentController()) { controller->NotifyMozMouseScrollEvent( mFrameMetrics.GetScrollId(), NS_LITERAL_STRING("MozMouseScrollFailed")); } } return nsEventStatus_eConsumeNoDefault; } if (delta.x == 0 && delta.y == 0) { // Avoid spurious state changes and unnecessary work return nsEventStatus_eIgnore; } switch (aEvent.mScrollMode) { case ScrollWheelInput::SCROLLMODE_INSTANT: { // Wheel events from "clicky" mouse wheels trigger scroll snapping to the // next snap point. Check for this, and adjust the delta to take into // account the snap point. CSSPoint startPosition = mFrameMetrics.GetScrollOffset(); MaybeAdjustDeltaForScrollSnapping(aEvent, delta, startPosition); ScreenPoint distance = ToScreenCoordinates( ParentLayerPoint(fabs(delta.x), fabs(delta.y)), aEvent.mLocalOrigin); CancelAnimation(); MOZ_ASSERT(mInputQueue->GetCurrentWheelBlock()); OverscrollHandoffState handoffState( *mInputQueue->GetCurrentWheelBlock()->GetOverscrollHandoffChain(), distance, ScrollSource::Wheel); ParentLayerPoint startPoint = aEvent.mLocalOrigin; ParentLayerPoint endPoint = aEvent.mLocalOrigin - delta; CallDispatchScroll(startPoint, endPoint, handoffState); SetState(NOTHING); // The calls above handle their own locking; moreover, // ToScreenCoordinates() and CallDispatchScroll() can grab the tree lock. ReentrantMonitorAutoEnter lock(mMonitor); RequestContentRepaint(); break; } case ScrollWheelInput::SCROLLMODE_SMOOTH: { // The lock must be held across the entire update operation, so the // compositor doesn't end the animation before we get a chance to // update it. ReentrantMonitorAutoEnter lock(mMonitor); // Perform scroll snapping if appropriate. CSSPoint startPosition = mFrameMetrics.GetScrollOffset(); // If we're already in a wheel scroll or smooth scroll animation, // the delta is applied to its destination, not to the current // scroll position. Take this into account when finding a snap point. if (mState == WHEEL_SCROLL) { startPosition = mAnimation->AsWheelScrollAnimation()->GetDestination(); } else if (mState == SMOOTH_SCROLL) { startPosition = mAnimation->AsSmoothScrollAnimation()->GetDestination(); } if (MaybeAdjustDeltaForScrollSnapping(aEvent, delta, startPosition)) { // If we're scroll snapping, use a smooth scroll animation to get // the desired physics. Note that SmoothScrollTo() will re-use an // existing smooth scroll animation if there is one. APZC_LOG("%p wheel scrolling to snap point %s\n", this, Stringify(startPosition).c_str()); SmoothScrollTo(startPosition); break; } // Otherwise, use a wheel scroll animation, also reusing one if possible. if (mState != WHEEL_SCROLL) { CancelAnimation(); SetState(WHEEL_SCROLL); nsPoint initialPosition = CSSPoint::ToAppUnits(mFrameMetrics.GetScrollOffset()); StartAnimation(new WheelScrollAnimation( *this, initialPosition, aEvent.mDeltaType)); } nsPoint deltaInAppUnits = CSSPoint::ToAppUnits(delta / mFrameMetrics.GetZoom()); // Cast velocity from ParentLayerPoints/ms to CSSPoints/ms then convert to // appunits/second nsPoint velocity = CSSPoint::ToAppUnits(CSSPoint(mX.GetVelocity(), mY.GetVelocity())) * 1000.0f; WheelScrollAnimation* animation = mAnimation->AsWheelScrollAnimation(); animation->Update(aEvent.mTimeStamp, deltaInAppUnits, nsSize(velocity.x, velocity.y)); break; } case ScrollWheelInput::SCROLLMODE_SENTINEL: { MOZ_ASSERT_UNREACHABLE("Invalid ScrollMode."); break; } } return nsEventStatus_eConsumeNoDefault; } void AsyncPanZoomController::NotifyMozMouseScrollEvent(const nsString& aString) const { RefPtr controller = GetGeckoContentController(); if (!controller) { return; } controller->NotifyMozMouseScrollEvent(mFrameMetrics.GetScrollId(), aString); } nsEventStatus AsyncPanZoomController::OnPanMayBegin(const PanGestureInput& aEvent) { APZC_LOG("%p got a pan-maybegin in state %d\n", this, mState); mX.StartTouch(aEvent.mLocalPanStartPoint.x, aEvent.mTime); mY.StartTouch(aEvent.mLocalPanStartPoint.y, aEvent.mTime); MOZ_ASSERT(GetCurrentPanGestureBlock()); GetCurrentPanGestureBlock()->GetOverscrollHandoffChain()->CancelAnimations(); return nsEventStatus_eConsumeNoDefault; } nsEventStatus AsyncPanZoomController::OnPanCancelled(const PanGestureInput& aEvent) { APZC_LOG("%p got a pan-cancelled in state %d\n", this, mState); mX.CancelGesture(); mY.CancelGesture(); return nsEventStatus_eConsumeNoDefault; } nsEventStatus AsyncPanZoomController::OnPanBegin(const PanGestureInput& aEvent) { APZC_LOG("%p got a pan-begin in state %d\n", this, mState); if (mState == SMOOTH_SCROLL) { // SMOOTH_SCROLL scrolls are cancelled by pan gestures. CancelAnimation(); } mX.StartTouch(aEvent.mLocalPanStartPoint.x, aEvent.mTime); mY.StartTouch(aEvent.mLocalPanStartPoint.y, aEvent.mTime); if (GetAxisLockMode() == FREE) { SetState(PANNING); return nsEventStatus_eConsumeNoDefault; } float dx = aEvent.mPanDisplacement.x, dy = aEvent.mPanDisplacement.y; if (dx || dy) { double angle = atan2(dy, dx); // range [-pi, pi] angle = fabs(angle); // range [0, pi] HandlePanning(angle); } else { SetState(PANNING); } // Call into OnPan in order to process any delta included in this event. OnPan(aEvent, true); return nsEventStatus_eConsumeNoDefault; } nsEventStatus AsyncPanZoomController::OnPan(const PanGestureInput& aEvent, bool aFingersOnTouchpad) { APZC_LOG("%p got a pan-pan in state %d\n", this, mState); if (mState == SMOOTH_SCROLL) { if (!aFingersOnTouchpad) { // When a SMOOTH_SCROLL scroll is being processed on a frame, mouse // wheel and trackpad momentum scroll position updates will not cancel the // SMOOTH_SCROLL scroll animations, enabling scripts that depend on // them to be responsive without forcing the user to wait for the momentum // scrolling to completely stop. return nsEventStatus_eConsumeNoDefault; } // SMOOTH_SCROLL scrolls are cancelled by pan gestures. CancelAnimation(); } if (mState == NOTHING) { // This event block was interrupted by something else. If the user's fingers // are still on on the touchpad we want to resume scrolling, otherwise we // ignore the rest of the scroll gesture. if (!aFingersOnTouchpad) { return nsEventStatus_eConsumeNoDefault; } // Resume / restart the pan. // PanBegin will call back into this function with mState == PANNING. return OnPanBegin(aEvent); } // Note that there is a multiplier that applies onto the "physical" pan // displacement (how much the user's fingers moved) that produces the "logical" // pan displacement (how much the page should move). For some of the code // below it makes more sense to use the physical displacement rather than // the logical displacement, and vice-versa. ScreenPoint physicalPanDisplacement = aEvent.mPanDisplacement; ParentLayerPoint logicalPanDisplacement = aEvent.UserMultipliedLocalPanDisplacement(); // We need to update the axis velocity in order to get a useful display port // size and position. We need to do so even if this is a momentum pan (i.e. // aFingersOnTouchpad == false); in that case the "with touch" part is not // really appropriate, so we may want to rethink this at some point. mX.UpdateWithTouchAtDevicePoint(aEvent.mLocalPanStartPoint.x, logicalPanDisplacement.x, aEvent.mTime); mY.UpdateWithTouchAtDevicePoint(aEvent.mLocalPanStartPoint.y, logicalPanDisplacement.y, aEvent.mTime); HandlePanningUpdate(physicalPanDisplacement); ScreenPoint panDistance(fabs(physicalPanDisplacement.x), fabs(physicalPanDisplacement.y)); MOZ_ASSERT(GetCurrentPanGestureBlock()); OverscrollHandoffState handoffState( *GetCurrentPanGestureBlock()->GetOverscrollHandoffChain(), panDistance, ScrollSource::Wheel); // Create fake "touch" positions that will result in the desired scroll motion. // Note that the pan displacement describes the change in scroll position: // positive displacement values mean that the scroll position increases. // However, an increase in scroll position means that the scrolled contents // are moved to the left / upwards. Since our simulated "touches" determine // the motion of the scrolled contents, not of the scroll position, they need // to move in the opposite direction of the pan displacement. ParentLayerPoint startPoint = aEvent.mLocalPanStartPoint; ParentLayerPoint endPoint = aEvent.mLocalPanStartPoint - logicalPanDisplacement; CallDispatchScroll(startPoint, endPoint, handoffState); return nsEventStatus_eConsumeNoDefault; } nsEventStatus AsyncPanZoomController::OnPanEnd(const PanGestureInput& aEvent) { APZC_LOG("%p got a pan-end in state %d\n", this, mState); // Call into OnPan in order to process any delta included in this event. OnPan(aEvent, true); mX.EndTouch(aEvent.mTime); mY.EndTouch(aEvent.mTime); // Drop any velocity on axes where we don't have room to scroll anyways // (in this APZC, or an APZC further in the handoff chain). // This ensures that we don't enlarge the display port unnecessarily. MOZ_ASSERT(GetCurrentPanGestureBlock()); RefPtr overscrollHandoffChain = GetCurrentPanGestureBlock()->GetOverscrollHandoffChain(); if (!overscrollHandoffChain->CanScrollInDirection(this, Layer::HORIZONTAL)) { mX.SetVelocity(0); } if (!overscrollHandoffChain->CanScrollInDirection(this, Layer::VERTICAL)) { mY.SetVelocity(0); } SetState(NOTHING); RequestContentRepaint(); if (!aEvent.mFollowedByMomentum) { ScrollSnap(); } return nsEventStatus_eConsumeNoDefault; } nsEventStatus AsyncPanZoomController::OnPanMomentumStart(const PanGestureInput& aEvent) { APZC_LOG("%p got a pan-momentumstart in state %d\n", this, mState); if (mState == SMOOTH_SCROLL) { // SMOOTH_SCROLL scrolls are cancelled by pan gestures. CancelAnimation(); } SetState(PAN_MOMENTUM); ScrollSnapToDestination(); // Call into OnPan in order to process any delta included in this event. OnPan(aEvent, false); return nsEventStatus_eConsumeNoDefault; } nsEventStatus AsyncPanZoomController::OnPanMomentumEnd(const PanGestureInput& aEvent) { APZC_LOG("%p got a pan-momentumend in state %d\n", this, mState); // Call into OnPan in order to process any delta included in this event. OnPan(aEvent, false); // We need to reset the velocity to zero. We don't really have a "touch" // here because the touch has already ended long before the momentum // animation started, but I guess it doesn't really matter for now. mX.CancelGesture(); mY.CancelGesture(); SetState(NOTHING); RequestContentRepaint(); return nsEventStatus_eConsumeNoDefault; } nsEventStatus AsyncPanZoomController::OnLongPress(const TapGestureInput& aEvent) { APZC_LOG("%p got a long-press in state %d\n", this, mState); RefPtr controller = GetGeckoContentController(); if (controller) { LayoutDevicePoint geckoScreenPoint; if (ConvertToGecko(aEvent.mPoint, &geckoScreenPoint)) { TouchBlockState* touch = GetCurrentTouchBlock(); if (!touch) { APZC_LOG("%p dropping long-press because some non-touch block interrupted it\n", this); return nsEventStatus_eIgnore; } if (touch->IsDuringFastFling()) { APZC_LOG("%p dropping long-press because of fast fling\n", this); return nsEventStatus_eIgnore; } uint64_t blockId = GetInputQueue()->InjectNewTouchBlock(this); controller->HandleTap(TapType::eLongTap, geckoScreenPoint, aEvent.modifiers, GetGuid(), blockId); return nsEventStatus_eConsumeNoDefault; } } return nsEventStatus_eIgnore; } nsEventStatus AsyncPanZoomController::OnLongPressUp(const TapGestureInput& aEvent) { APZC_LOG("%p got a long-tap-up in state %d\n", this, mState); return GenerateSingleTap(TapType::eLongTapUp, aEvent.mPoint, aEvent.modifiers); } nsEventStatus AsyncPanZoomController::GenerateSingleTap(TapType aType, const ScreenIntPoint& aPoint, mozilla::Modifiers aModifiers) { RefPtr controller = GetGeckoContentController(); if (controller) { LayoutDevicePoint geckoScreenPoint; if (ConvertToGecko(aPoint, &geckoScreenPoint)) { TouchBlockState* touch = GetCurrentTouchBlock(); // |touch| may be null in the case where this function is // invoked by GestureEventListener on a timeout. In that case we already // verified that the single tap is allowed so we let it through. // XXX there is a bug here that in such a case the touch block that // generated this tap will not get its mSingleTapOccurred flag set. // See https://bugzilla.mozilla.org/show_bug.cgi?id=1256344#c6 if (touch) { if (touch->IsDuringFastFling()) { APZC_LOG("%p dropping single-tap because it was during a fast-fling\n", this); return nsEventStatus_eIgnore; } touch->SetSingleTapOccurred(); } // Because this may be being running as part of APZCTreeManager::ReceiveInputEvent, // calling controller->HandleTap directly might mean that content receives // the single tap message before the corresponding touch-up. To avoid that we // schedule the singletap message to run on the next spin of the event loop. // See bug 965381 for the issue this was causing. RefPtr runnable = NewRunnableMethod(controller, &GeckoContentController::HandleTap, aType, geckoScreenPoint, aModifiers, GetGuid(), touch ? touch->GetBlockId() : 0); controller->PostDelayedTask(runnable.forget(), 0); return nsEventStatus_eConsumeNoDefault; } } return nsEventStatus_eIgnore; } void AsyncPanZoomController::OnTouchEndOrCancel() { if (RefPtr controller = GetGeckoContentController()) { MOZ_ASSERT(GetCurrentTouchBlock()); controller->NotifyAPZStateChange( GetGuid(), APZStateChange::eEndTouch, GetCurrentTouchBlock()->SingleTapOccurred()); } } nsEventStatus AsyncPanZoomController::OnSingleTapUp(const TapGestureInput& aEvent) { APZC_LOG("%p got a single-tap-up in state %d\n", this, mState); // If mZoomConstraints.mAllowDoubleTapZoom is true we wait for a call to OnSingleTapConfirmed before // sending event to content MOZ_ASSERT(GetCurrentTouchBlock()); if (!(mZoomConstraints.mAllowDoubleTapZoom && GetCurrentTouchBlock()->TouchActionAllowsDoubleTapZoom())) { return GenerateSingleTap(TapType::eSingleTap, aEvent.mPoint, aEvent.modifiers); } return nsEventStatus_eIgnore; } nsEventStatus AsyncPanZoomController::OnSingleTapConfirmed(const TapGestureInput& aEvent) { APZC_LOG("%p got a single-tap-confirmed in state %d\n", this, mState); return GenerateSingleTap(TapType::eSingleTap, aEvent.mPoint, aEvent.modifiers); } nsEventStatus AsyncPanZoomController::OnDoubleTap(const TapGestureInput& aEvent) { APZC_LOG("%p got a double-tap in state %d\n", this, mState); RefPtr controller = GetGeckoContentController(); if (controller) { MOZ_ASSERT(GetCurrentTouchBlock()); if (mZoomConstraints.mAllowDoubleTapZoom && GetCurrentTouchBlock()->TouchActionAllowsDoubleTapZoom()) { LayoutDevicePoint geckoScreenPoint; if (ConvertToGecko(aEvent.mPoint, &geckoScreenPoint)) { controller->HandleTap(TapType::eDoubleTap, geckoScreenPoint, aEvent.modifiers, GetGuid(), GetCurrentTouchBlock()->GetBlockId()); } } return nsEventStatus_eConsumeNoDefault; } return nsEventStatus_eIgnore; } nsEventStatus AsyncPanZoomController::OnSecondTap(const TapGestureInput& aEvent) { APZC_LOG("%p got a second-tap in state %d\n", this, mState); return GenerateSingleTap(TapType::eSecondTap, aEvent.mPoint, aEvent.modifiers); } nsEventStatus AsyncPanZoomController::OnCancelTap(const TapGestureInput& aEvent) { APZC_LOG("%p got a cancel-tap in state %d\n", this, mState); // XXX: Implement this. return nsEventStatus_eIgnore; } ScreenToParentLayerMatrix4x4 AsyncPanZoomController::GetTransformToThis() const { if (APZCTreeManager* treeManagerLocal = GetApzcTreeManager()) { return treeManagerLocal->GetScreenToApzcTransform(this); } return ScreenToParentLayerMatrix4x4(); } ScreenPoint AsyncPanZoomController::ToScreenCoordinates(const ParentLayerPoint& aVector, const ParentLayerPoint& aAnchor) const { return TransformVector(GetTransformToThis().Inverse(), aVector, aAnchor); } // TODO: figure out a good way to check the w-coordinate is positive and return the result ParentLayerPoint AsyncPanZoomController::ToParentLayerCoordinates(const ScreenPoint& aVector, const ScreenPoint& aAnchor) const { return TransformVector(GetTransformToThis(), aVector, aAnchor); } bool AsyncPanZoomController::Contains(const ScreenIntPoint& aPoint) const { ScreenToParentLayerMatrix4x4 transformToThis = GetTransformToThis(); Maybe point = UntransformBy(transformToThis, aPoint); if (!point) { return false; } ParentLayerIntRect cb; { ReentrantMonitorAutoEnter lock(mMonitor); GetFrameMetrics().GetCompositionBounds().ToIntRect(&cb); } return cb.Contains(*point); } ScreenCoord AsyncPanZoomController::PanDistance() const { ParentLayerPoint panVector; ParentLayerPoint panStart; { ReentrantMonitorAutoEnter lock(mMonitor); panVector = ParentLayerPoint(mX.PanDistance(), mY.PanDistance()); panStart = PanStart(); } return ToScreenCoordinates(panVector, panStart).Length(); } ParentLayerPoint AsyncPanZoomController::PanStart() const { return ParentLayerPoint(mX.PanStart(), mY.PanStart()); } const ParentLayerPoint AsyncPanZoomController::GetVelocityVector() const { return ParentLayerPoint(mX.GetVelocity(), mY.GetVelocity()); } void AsyncPanZoomController::SetVelocityVector(const ParentLayerPoint& aVelocityVector) { mX.SetVelocity(aVelocityVector.x); mY.SetVelocity(aVelocityVector.y); } void AsyncPanZoomController::HandlePanningWithTouchAction(double aAngle) { // Handling of cross sliding will need to be added in this method after touch-action released // enabled by default. MOZ_ASSERT(GetCurrentTouchBlock()); if (GetCurrentTouchBlock()->TouchActionAllowsPanningXY()) { if (mX.CanScrollNow() && mY.CanScrollNow()) { if (IsCloseToHorizontal(aAngle, gfxPrefs::APZAxisLockAngle())) { mY.SetAxisLocked(true); SetState(PANNING_LOCKED_X); } else if (IsCloseToVertical(aAngle, gfxPrefs::APZAxisLockAngle())) { mX.SetAxisLocked(true); SetState(PANNING_LOCKED_Y); } else { SetState(PANNING); } } else if (mX.CanScrollNow() || mY.CanScrollNow()) { SetState(PANNING); } else { SetState(NOTHING); } } else if (GetCurrentTouchBlock()->TouchActionAllowsPanningX()) { // Using bigger angle for panning to keep behavior consistent // with IE. if (IsCloseToHorizontal(aAngle, gfxPrefs::APZAllowedDirectPanAngle())) { mY.SetAxisLocked(true); SetState(PANNING_LOCKED_X); mPanDirRestricted = true; } else { // Don't treat these touches as pan/zoom movements since 'touch-action' value // requires it. SetState(NOTHING); } } else if (GetCurrentTouchBlock()->TouchActionAllowsPanningY()) { if (IsCloseToVertical(aAngle, gfxPrefs::APZAllowedDirectPanAngle())) { mX.SetAxisLocked(true); SetState(PANNING_LOCKED_Y); mPanDirRestricted = true; } else { SetState(NOTHING); } } else { SetState(NOTHING); } if (!IsInPanningState()) { // If we didn't enter a panning state because touch-action disallowed it, // make sure to clear any leftover velocity from the pre-threshold // touchmoves. mX.SetVelocity(0); mY.SetVelocity(0); } } void AsyncPanZoomController::HandlePanning(double aAngle) { ReentrantMonitorAutoEnter lock(mMonitor); MOZ_ASSERT(GetCurrentInputBlock()); RefPtr overscrollHandoffChain = GetCurrentInputBlock()->GetOverscrollHandoffChain(); bool canScrollHorizontal = !mX.IsAxisLocked() && overscrollHandoffChain->CanScrollInDirection(this, Layer::HORIZONTAL); bool canScrollVertical = !mY.IsAxisLocked() && overscrollHandoffChain->CanScrollInDirection(this, Layer::VERTICAL); if (!canScrollHorizontal || !canScrollVertical) { SetState(PANNING); } else if (IsCloseToHorizontal(aAngle, gfxPrefs::APZAxisLockAngle())) { mY.SetAxisLocked(true); if (canScrollHorizontal) { SetState(PANNING_LOCKED_X); } } else if (IsCloseToVertical(aAngle, gfxPrefs::APZAxisLockAngle())) { mX.SetAxisLocked(true); if (canScrollVertical) { SetState(PANNING_LOCKED_Y); } } else { SetState(PANNING); } } void AsyncPanZoomController::HandlePanningUpdate(const ScreenPoint& aPanDistance) { // If we're axis-locked, check if the user is trying to break the lock if (GetAxisLockMode() == STICKY && !mPanDirRestricted) { double angle = atan2(aPanDistance.y, aPanDistance.x); // range [-pi, pi] angle = fabs(angle); // range [0, pi] float breakThreshold = gfxPrefs::APZAxisBreakoutThreshold() * APZCTreeManager::GetDPI(); if (fabs(aPanDistance.x) > breakThreshold || fabs(aPanDistance.y) > breakThreshold) { if (mState == PANNING_LOCKED_X) { if (!IsCloseToHorizontal(angle, gfxPrefs::APZAxisBreakoutAngle())) { mY.SetAxisLocked(false); SetState(PANNING); } } else if (mState == PANNING_LOCKED_Y) { if (!IsCloseToVertical(angle, gfxPrefs::APZAxisBreakoutAngle())) { mX.SetAxisLocked(false); SetState(PANNING); } } } } } nsEventStatus AsyncPanZoomController::StartPanning(const MultiTouchInput& aEvent) { ReentrantMonitorAutoEnter lock(mMonitor); ParentLayerPoint point = GetFirstTouchPoint(aEvent); float dx = mX.PanDistance(point.x); float dy = mY.PanDistance(point.y); double angle = atan2(dy, dx); // range [-pi, pi] angle = fabs(angle); // range [0, pi] if (gfxPrefs::TouchActionEnabled()) { HandlePanningWithTouchAction(angle); } else { if (GetAxisLockMode() == FREE) { SetState(PANNING); } else { HandlePanning(angle); } } if (IsInPanningState()) { if (RefPtr controller = GetGeckoContentController()) { controller->NotifyAPZStateChange(GetGuid(), APZStateChange::eStartPanning); } return nsEventStatus_eConsumeNoDefault; } // Don't consume an event that didn't trigger a panning. return nsEventStatus_eIgnore; } void AsyncPanZoomController::UpdateWithTouchAtDevicePoint(const MultiTouchInput& aEvent) { ParentLayerPoint point = GetFirstTouchPoint(aEvent); mX.UpdateWithTouchAtDevicePoint(point.x, 0, aEvent.mTime); mY.UpdateWithTouchAtDevicePoint(point.y, 0, aEvent.mTime); } bool AsyncPanZoomController::AttemptScroll(ParentLayerPoint& aStartPoint, ParentLayerPoint& aEndPoint, OverscrollHandoffState& aOverscrollHandoffState) { // "start - end" rather than "end - start" because e.g. moving your finger // down (*positive* direction along y axis) causes the vertical scroll offset // to *decrease* as the page follows your finger. ParentLayerPoint displacement = aStartPoint - aEndPoint; ParentLayerPoint overscroll; // will be used outside monitor block // If the direction of panning is reversed within the same input block, // a later event in the block could potentially scroll an APZC earlier // in the handoff chain, than an earlier event in the block (because // the earlier APZC was scrolled to its extent in the original direction). // We want to disallow this. bool scrollThisApzc = false; if (InputBlockState* block = GetCurrentInputBlock()) { scrollThisApzc = !block->GetScrolledApzc() || block->IsDownchainOfScrolledApzc(this); } if (scrollThisApzc) { ReentrantMonitorAutoEnter lock(mMonitor); ParentLayerPoint adjustedDisplacement; bool forceVerticalOverscroll = (aOverscrollHandoffState.mScrollSource == ScrollSource::Wheel && !mScrollMetadata.AllowVerticalScrollWithWheel()); bool yChanged = mY.AdjustDisplacement(displacement.y, adjustedDisplacement.y, overscroll.y, forceVerticalOverscroll); bool xChanged = mX.AdjustDisplacement(displacement.x, adjustedDisplacement.x, overscroll.x); if (xChanged || yChanged) { ScheduleComposite(); } if (!IsZero(adjustedDisplacement)) { ScrollBy(adjustedDisplacement / mFrameMetrics.GetZoom()); if (CancelableBlockState* block = GetCurrentInputBlock()) { if (block->AsTouchBlock() && (block->GetScrolledApzc() != this)) { RefPtr controller = GetGeckoContentController(); if (controller) { controller->SetScrollingRootContent(IsRootContent()); } } block->SetScrolledApzc(this); } ScheduleCompositeAndMaybeRepaint(); UpdateSharedCompositorFrameMetrics(); } // Adjust the start point to reflect the consumed portion of the scroll. aStartPoint = aEndPoint + overscroll; } else { overscroll = displacement; } // If we consumed the entire displacement as a normal scroll, great. if (IsZero(overscroll)) { return true; } if (AllowScrollHandoffInCurrentBlock()) { // If there is overscroll, first try to hand it off to an APZC later // in the handoff chain to consume (either as a normal scroll or as // overscroll). // Note: "+ overscroll" rather than "- overscroll" because "overscroll" // is what's left of "displacement", and "displacement" is "start - end". ++aOverscrollHandoffState.mChainIndex; CallDispatchScroll(aStartPoint, aEndPoint, aOverscrollHandoffState); overscroll = aStartPoint - aEndPoint; if (IsZero(overscroll)) { return true; } } // If there is no APZC later in the handoff chain that accepted the // overscroll, try to accept it ourselves. We only accept it if we // are pannable. APZC_LOG("%p taking overscroll during panning\n", this); OverscrollForPanning(overscroll, aOverscrollHandoffState.mPanDistance); aStartPoint = aEndPoint + overscroll; return IsZero(overscroll); } void AsyncPanZoomController::OverscrollForPanning(ParentLayerPoint& aOverscroll, const ScreenPoint& aPanDistance) { // Only allow entering overscroll along an axis if the pan distance along // that axis is greater than the pan distance along the other axis by a // configurable factor. If we are already overscrolled, don't check this. if (!IsOverscrolled()) { if (aPanDistance.x < gfxPrefs::APZMinPanDistanceRatio() * aPanDistance.y) { aOverscroll.x = 0; } if (aPanDistance.y < gfxPrefs::APZMinPanDistanceRatio() * aPanDistance.x) { aOverscroll.y = 0; } } OverscrollBy(aOverscroll); } void AsyncPanZoomController::OverscrollBy(ParentLayerPoint& aOverscroll) { if (!gfxPrefs::APZOverscrollEnabled()) { return; } ReentrantMonitorAutoEnter lock(mMonitor); // Do not go into overscroll in a direction in which we have no room to // scroll to begin with. bool xCanScroll = mX.CanScroll(); bool yCanScroll = mY.CanScroll(); bool xConsumed = FuzzyEqualsAdditive(aOverscroll.x, 0.0f, COORDINATE_EPSILON); bool yConsumed = FuzzyEqualsAdditive(aOverscroll.y, 0.0f, COORDINATE_EPSILON); bool shouldOverscrollX = xCanScroll && !xConsumed; bool shouldOverscrollY = yCanScroll && !yConsumed; mOverscrollEffect->ConsumeOverscroll(aOverscroll, shouldOverscrollX, shouldOverscrollY); } RefPtr AsyncPanZoomController::BuildOverscrollHandoffChain() { if (APZCTreeManager* treeManagerLocal = GetApzcTreeManager()) { return treeManagerLocal->BuildOverscrollHandoffChain(this); } // This APZC IsDestroyed(). To avoid callers having to special-case this // scenario, just build a 1-element chain containing ourselves. OverscrollHandoffChain* result = new OverscrollHandoffChain; result->Add(this); return result; } void AsyncPanZoomController::AcceptFling(FlingHandoffState& aHandoffState) { ReentrantMonitorAutoEnter lock(mMonitor); // We may have a pre-existing velocity for whatever reason (for example, // a previously handed off fling). We don't want to clobber that. APZC_LOG("%p accepting fling with velocity %s\n", this, Stringify(aHandoffState.mVelocity).c_str()); if (mX.CanScroll()) { mX.SetVelocity(mX.GetVelocity() + aHandoffState.mVelocity.x); aHandoffState.mVelocity.x = 0; } if (mY.CanScroll()) { mY.SetVelocity(mY.GetVelocity() + aHandoffState.mVelocity.y); aHandoffState.mVelocity.y = 0; } // If there's a scroll snap point near the predicted fling destination, // scroll there using a smooth scroll animation. Otherwise, start a // fling animation. ScrollSnapToDestination(); if (mState != SMOOTH_SCROLL) { SetState(FLING); FlingAnimation *fling = new FlingAnimation(*this, GetPlatformSpecificState(), aHandoffState.mChain, aHandoffState.mIsHandoff, aHandoffState.mScrolledApzc); StartAnimation(fling); } } bool AsyncPanZoomController::AttemptFling(FlingHandoffState& aHandoffState) { // If we are pannable, take over the fling ourselves. if (IsPannable()) { AcceptFling(aHandoffState); return true; } return false; } void AsyncPanZoomController::HandleFlingOverscroll(const ParentLayerPoint& aVelocity, const RefPtr& aOverscrollHandoffChain, const RefPtr& aScrolledApzc) { APZCTreeManager* treeManagerLocal = GetApzcTreeManager(); if (treeManagerLocal) { FlingHandoffState handoffState{aVelocity, aOverscrollHandoffChain, true /* handoff */, aScrolledApzc}; treeManagerLocal->DispatchFling(this, handoffState); if (!IsZero(handoffState.mVelocity) && IsPannable() && gfxPrefs::APZOverscrollEnabled()) { mOverscrollEffect->HandleFlingOverscroll(handoffState.mVelocity); } } } void AsyncPanZoomController::HandleSmoothScrollOverscroll(const ParentLayerPoint& aVelocity) { // We must call BuildOverscrollHandoffChain from this deferred callback // function in order to avoid a deadlock when acquiring the tree lock. HandleFlingOverscroll(aVelocity, BuildOverscrollHandoffChain(), nullptr); } void AsyncPanZoomController::SmoothScrollTo(const CSSPoint& aDestination) { if (mState == SMOOTH_SCROLL && mAnimation) { APZC_LOG("%p updating destination on existing animation\n", this); RefPtr animation( static_cast(mAnimation.get())); animation->SetDestination(CSSPoint::ToAppUnits(aDestination)); } else { CancelAnimation(); SetState(SMOOTH_SCROLL); nsPoint initialPosition = CSSPoint::ToAppUnits(mFrameMetrics.GetScrollOffset()); // Cast velocity from ParentLayerPoints/ms to CSSPoints/ms then convert to // appunits/second nsPoint initialVelocity = CSSPoint::ToAppUnits(CSSPoint(mX.GetVelocity(), mY.GetVelocity())) * 1000.0f; nsPoint destination = CSSPoint::ToAppUnits(aDestination); StartAnimation(new SmoothScrollAnimation(*this, initialPosition, initialVelocity, destination, gfxPrefs::ScrollBehaviorSpringConstant(), gfxPrefs::ScrollBehaviorDampingRatio())); } } void AsyncPanZoomController::StartOverscrollAnimation(const ParentLayerPoint& aVelocity) { SetState(OVERSCROLL_ANIMATION); StartAnimation(new OverscrollAnimation(*this, aVelocity)); } void AsyncPanZoomController::CallDispatchScroll(ParentLayerPoint& aStartPoint, ParentLayerPoint& aEndPoint, OverscrollHandoffState& aOverscrollHandoffState) { // Make a local copy of the tree manager pointer and check if it's not // null before calling DispatchScroll(). This is necessary because // Destroy(), which nulls out mTreeManager, could be called concurrently. APZCTreeManager* treeManagerLocal = GetApzcTreeManager(); if (!treeManagerLocal) { return; } treeManagerLocal->DispatchScroll(this, aStartPoint, aEndPoint, aOverscrollHandoffState); } void AsyncPanZoomController::TrackTouch(const MultiTouchInput& aEvent) { ParentLayerPoint prevTouchPoint(mX.GetPos(), mY.GetPos()); ParentLayerPoint touchPoint = GetFirstTouchPoint(aEvent); ScreenPoint panDistance = ToScreenCoordinates( ParentLayerPoint(mX.PanDistance(touchPoint.x), mY.PanDistance(touchPoint.y)), PanStart()); HandlePanningUpdate(panDistance); UpdateWithTouchAtDevicePoint(aEvent); if (prevTouchPoint != touchPoint) { MOZ_ASSERT(GetCurrentTouchBlock()); OverscrollHandoffState handoffState( *GetCurrentTouchBlock()->GetOverscrollHandoffChain(), panDistance, ScrollSource::Touch); CallDispatchScroll(prevTouchPoint, touchPoint, handoffState); } } ParentLayerPoint AsyncPanZoomController::GetFirstTouchPoint(const MultiTouchInput& aEvent) { return ((SingleTouchData&)aEvent.mTouches[0]).mLocalScreenPoint; } void AsyncPanZoomController::StartAnimation(AsyncPanZoomAnimation* aAnimation) { ReentrantMonitorAutoEnter lock(mMonitor); mAnimation = aAnimation; mLastSampleTime = GetFrameTime(); ScheduleComposite(); } void AsyncPanZoomController::CancelAnimation(CancelAnimationFlags aFlags) { ReentrantMonitorAutoEnter lock(mMonitor); APZC_LOG("%p running CancelAnimation in state %d\n", this, mState); SetState(NOTHING); mAnimation = nullptr; // Since there is no animation in progress now the axes should // have no velocity either. If we are dropping the velocity from a non-zero // value we should trigger a repaint as the displayport margins are dependent // on the velocity and the last repaint request might not have good margins // any more. bool repaint = !IsZero(GetVelocityVector()); mX.SetVelocity(0); mY.SetVelocity(0); mX.SetAxisLocked(false); mY.SetAxisLocked(false); // Setting the state to nothing and cancelling the animation can // preempt normal mechanisms for relieving overscroll, so we need to clear // overscroll here. if (!(aFlags & ExcludeOverscroll) && IsOverscrolled()) { ClearOverscroll(); repaint = true; } // Similar to relieving overscroll, we also need to snap to any snap points // if appropriate. if (aFlags & CancelAnimationFlags::ScrollSnap) { ScrollSnap(); } if (repaint) { RequestContentRepaint(); ScheduleComposite(); UpdateSharedCompositorFrameMetrics(); } } void AsyncPanZoomController::ClearOverscroll() { ReentrantMonitorAutoEnter lock(mMonitor); mX.ClearOverscroll(); mY.ClearOverscroll(); } void AsyncPanZoomController::SetCompositorController(CompositorController* aCompositorController) { mCompositorController = aCompositorController; } void AsyncPanZoomController::SetMetricsSharingController(MetricsSharingController* aMetricsSharingController) { mMetricsSharingController = aMetricsSharingController; } void AsyncPanZoomController::AdjustScrollForSurfaceShift(const ScreenPoint& aShift) { ReentrantMonitorAutoEnter lock(mMonitor); CSSPoint adjustment = ViewAs(aShift, PixelCastJustification::ScreenIsParentLayerForRoot) / mFrameMetrics.GetZoom(); APZC_LOG("%p adjusting scroll position by %s for surface shift\n", this, Stringify(adjustment).c_str()); CSSPoint scrollOffset = mFrameMetrics.GetScrollOffset(); scrollOffset.y = mY.ClampOriginToScrollableRect(scrollOffset.y + adjustment.y); scrollOffset.x = mX.ClampOriginToScrollableRect(scrollOffset.x + adjustment.x); mFrameMetrics.SetScrollOffset(scrollOffset); ScheduleCompositeAndMaybeRepaint(); UpdateSharedCompositorFrameMetrics(); } void AsyncPanZoomController::ScrollBy(const CSSPoint& aOffset) { mFrameMetrics.ScrollBy(aOffset); } void AsyncPanZoomController::ScaleWithFocus(float aScale, const CSSPoint& aFocus) { mFrameMetrics.ZoomBy(aScale); // We want to adjust the scroll offset such that the CSS point represented by aFocus remains // at the same position on the screen before and after the change in zoom. The below code // accomplishes this; see https://bugzilla.mozilla.org/show_bug.cgi?id=923431#c6 for an // in-depth explanation of how. mFrameMetrics.SetScrollOffset((mFrameMetrics.GetScrollOffset() + aFocus) - (aFocus / aScale)); } /** * Enlarges the displayport along both axes based on the velocity. */ static CSSSize CalculateDisplayPortSize(const CSSSize& aCompositionSize, const CSSPoint& aVelocity) { bool xIsStationarySpeed = fabsf(aVelocity.x) < gfxPrefs::APZMinSkateSpeed(); bool yIsStationarySpeed = fabsf(aVelocity.y) < gfxPrefs::APZMinSkateSpeed(); float xMultiplier = xIsStationarySpeed ? gfxPrefs::APZXStationarySizeMultiplier() : gfxPrefs::APZXSkateSizeMultiplier(); float yMultiplier = yIsStationarySpeed ? gfxPrefs::APZYStationarySizeMultiplier() : gfxPrefs::APZYSkateSizeMultiplier(); if (IsHighMemSystem() && !xIsStationarySpeed) { xMultiplier += gfxPrefs::APZXSkateHighMemAdjust(); } if (IsHighMemSystem() && !yIsStationarySpeed) { yMultiplier += gfxPrefs::APZYSkateHighMemAdjust(); } return aCompositionSize * CSSSize(xMultiplier, yMultiplier); } /** * Ensures that the displayport is at least as large as the visible area * inflated by the danger zone. If this is not the case then the * "AboutToCheckerboard" function in TiledContentClient.cpp will return true * even in the stable state. */ static CSSSize ExpandDisplayPortToDangerZone(const CSSSize& aDisplayPortSize, const FrameMetrics& aFrameMetrics) { CSSSize dangerZone(0.0f, 0.0f); if (aFrameMetrics.LayersPixelsPerCSSPixel().xScale != 0 && aFrameMetrics.LayersPixelsPerCSSPixel().yScale != 0) { dangerZone = LayerSize( gfxPrefs::APZDangerZoneX(), gfxPrefs::APZDangerZoneY()) / aFrameMetrics.LayersPixelsPerCSSPixel(); } const CSSSize compositionSize = aFrameMetrics.CalculateBoundedCompositedSizeInCssPixels(); const float xSize = std::max(aDisplayPortSize.width, compositionSize.width + (2 * dangerZone.width)); const float ySize = std::max(aDisplayPortSize.height, compositionSize.height + (2 * dangerZone.height)); return CSSSize(xSize, ySize); } /** * Attempts to redistribute any area in the displayport that would get clipped * by the scrollable rect, or be inaccessible due to disabled scrolling, to the * other axis, while maintaining total displayport area. */ static void RedistributeDisplayPortExcess(CSSSize& aDisplayPortSize, const CSSRect& aScrollableRect) { // As aDisplayPortSize.height * aDisplayPortSize.width does not change, // we are just scaling by the ratio and its inverse. if (aDisplayPortSize.height > aScrollableRect.height) { aDisplayPortSize.width *= (aDisplayPortSize.height / aScrollableRect.height); aDisplayPortSize.height = aScrollableRect.height; } else if (aDisplayPortSize.width > aScrollableRect.width) { aDisplayPortSize.height *= (aDisplayPortSize.width / aScrollableRect.width); aDisplayPortSize.width = aScrollableRect.width; } } /* static */ const ScreenMargin AsyncPanZoomController::CalculatePendingDisplayPort( const FrameMetrics& aFrameMetrics, const ParentLayerPoint& aVelocity) { if (aFrameMetrics.IsScrollInfoLayer()) { // Don't compute margins. Since we can't asynchronously scroll this frame, // we don't want to paint anything more than the composition bounds. return ScreenMargin(); } CSSSize compositionSize = aFrameMetrics.CalculateBoundedCompositedSizeInCssPixels(); CSSPoint velocity; if (aFrameMetrics.GetZoom() != CSSToParentLayerScale2D(0, 0)) { velocity = aVelocity / aFrameMetrics.GetZoom(); // avoid division by zero } CSSRect scrollableRect = aFrameMetrics.GetExpandedScrollableRect(); // Calculate the displayport size based on how fast we're moving along each axis. CSSSize displayPortSize = CalculateDisplayPortSize(compositionSize, velocity); displayPortSize = ExpandDisplayPortToDangerZone(displayPortSize, aFrameMetrics); if (gfxPrefs::APZEnlargeDisplayPortWhenClipped()) { RedistributeDisplayPortExcess(displayPortSize, scrollableRect); } // We calculate a "displayport" here which is relative to the scroll offset. // Note that the scroll offset we have here in the APZ code may not be the // same as the base rect that gets used on the layout side when the displayport // margins are actually applied, so it is important to only consider the // displayport as margins relative to a scroll offset rather than relative to // something more unchanging like the scrollable rect origin. // Center the displayport based on its expansion over the composition size. CSSRect displayPort((compositionSize.width - displayPortSize.width) / 2.0f, (compositionSize.height - displayPortSize.height) / 2.0f, displayPortSize.width, displayPortSize.height); // Offset the displayport, depending on how fast we're moving and the // estimated time it takes to paint, to try to minimise checkerboarding. float paintFactor = kDefaultEstimatedPaintDurationMs; displayPort.MoveBy(velocity * paintFactor * gfxPrefs::APZVelocityBias()); APZC_LOG_FM(aFrameMetrics, "Calculated displayport as (%f %f %f %f) from velocity %s paint time %f metrics", displayPort.x, displayPort.y, displayPort.width, displayPort.height, ToString(aVelocity).c_str(), paintFactor); CSSMargin cssMargins; cssMargins.left = -displayPort.x; cssMargins.top = -displayPort.y; cssMargins.right = displayPort.width - compositionSize.width - cssMargins.left; cssMargins.bottom = displayPort.height - compositionSize.height - cssMargins.top; return cssMargins * aFrameMetrics.DisplayportPixelsPerCSSPixel(); } void AsyncPanZoomController::ScheduleComposite() { if (mCompositorController) { mCompositorController->ScheduleRenderOnCompositorThread(); } } void AsyncPanZoomController::ScheduleCompositeAndMaybeRepaint() { ScheduleComposite(); RequestContentRepaint(); } void AsyncPanZoomController::FlushRepaintForOverscrollHandoff() { ReentrantMonitorAutoEnter lock(mMonitor); RequestContentRepaint(); UpdateSharedCompositorFrameMetrics(); } void AsyncPanZoomController::FlushRepaintForNewInputBlock() { APZC_LOG("%p flushing repaint for new input block\n", this); ReentrantMonitorAutoEnter lock(mMonitor); RequestContentRepaint(); UpdateSharedCompositorFrameMetrics(); } bool AsyncPanZoomController::SnapBackIfOverscrolled() { ReentrantMonitorAutoEnter lock(mMonitor); // It's possible that we're already in the middle of an overscroll // animation - if so, don't start a new one. if (IsOverscrolled() && mState != OVERSCROLL_ANIMATION) { APZC_LOG("%p is overscrolled, starting snap-back\n", this); StartOverscrollAnimation(ParentLayerPoint(0, 0)); return true; } // If we don't kick off an overscroll animation, we still need to ask the // main thread to snap to any nearby snap points, assuming we haven't already // done so when we started this fling if (mState != FLING) { ScrollSnap(); } return false; } bool AsyncPanZoomController::IsFlingingFast() const { ReentrantMonitorAutoEnter lock(mMonitor); if (mState == FLING && GetVelocityVector().Length() > gfxPrefs::APZFlingStopOnTapThreshold()) { APZC_LOG("%p is moving fast\n", this); return true; } return false; } bool AsyncPanZoomController::IsPannable() const { ReentrantMonitorAutoEnter lock(mMonitor); return mX.CanScroll() || mY.CanScroll(); } int32_t AsyncPanZoomController::GetLastTouchIdentifier() const { RefPtr listener = GetGestureEventListener(); return listener ? listener->GetLastTouchIdentifier() : -1; } void AsyncPanZoomController::RequestContentRepaint(bool aUserAction) { // Reinvoke this method on the repaint thread if it's not there already. It's // important to do this before the call to CalculatePendingDisplayPort, so // that CalculatePendingDisplayPort uses the most recent available version of // mFrameMetrics, just before the paint request is dispatched to content. RefPtr controller = GetGeckoContentController(); if (!controller) { return; } if (!controller->IsRepaintThread()) { // use the local variable to resolve the function overload. auto func = static_cast (&AsyncPanZoomController::RequestContentRepaint); controller->DispatchToRepaintThread(NewRunnableMethod(this, func, aUserAction)); return; } MOZ_ASSERT(controller->IsRepaintThread()); ReentrantMonitorAutoEnter lock(mMonitor); ParentLayerPoint velocity = GetVelocityVector(); mFrameMetrics.SetDisplayPortMargins(CalculatePendingDisplayPort(mFrameMetrics, velocity)); mFrameMetrics.SetUseDisplayPortMargins(true); mFrameMetrics.SetPaintRequestTime(TimeStamp::Now()); mFrameMetrics.SetRepaintDrivenByUserAction(aUserAction); RequestContentRepaint(mFrameMetrics, velocity); } /*static*/ CSSRect GetDisplayPortRect(const FrameMetrics& aFrameMetrics) { // This computation is based on what happens in CalculatePendingDisplayPort. If that // changes then this might need to change too CSSRect baseRect(aFrameMetrics.GetScrollOffset(), aFrameMetrics.CalculateBoundedCompositedSizeInCssPixels()); baseRect.Inflate(aFrameMetrics.GetDisplayPortMargins() / aFrameMetrics.DisplayportPixelsPerCSSPixel()); return baseRect; } void AsyncPanZoomController::RequestContentRepaint(const FrameMetrics& aFrameMetrics, const ParentLayerPoint& aVelocity) { RefPtr controller = GetGeckoContentController(); if (!controller) { return; } MOZ_ASSERT(controller->IsRepaintThread()); // If we're trying to paint what we already think is painted, discard this // request since it's a pointless paint. ScreenMargin marginDelta = (mLastPaintRequestMetrics.GetDisplayPortMargins() - aFrameMetrics.GetDisplayPortMargins()); if (fabsf(marginDelta.left) < EPSILON && fabsf(marginDelta.top) < EPSILON && fabsf(marginDelta.right) < EPSILON && fabsf(marginDelta.bottom) < EPSILON && fabsf(mLastPaintRequestMetrics.GetScrollOffset().x - aFrameMetrics.GetScrollOffset().x) < EPSILON && fabsf(mLastPaintRequestMetrics.GetScrollOffset().y - aFrameMetrics.GetScrollOffset().y) < EPSILON && aFrameMetrics.GetPresShellResolution() == mLastPaintRequestMetrics.GetPresShellResolution() && aFrameMetrics.GetZoom() == mLastPaintRequestMetrics.GetZoom() && fabsf(aFrameMetrics.GetViewport().width - mLastPaintRequestMetrics.GetViewport().width) < EPSILON && fabsf(aFrameMetrics.GetViewport().height - mLastPaintRequestMetrics.GetViewport().height) < EPSILON && aFrameMetrics.GetScrollGeneration() == mLastPaintRequestMetrics.GetScrollGeneration() && aFrameMetrics.GetScrollUpdateType() == mLastPaintRequestMetrics.GetScrollUpdateType()) { return; } APZC_LOG_FM(aFrameMetrics, "%p requesting content repaint", this); { // scope lock MutexAutoLock lock(mCheckerboardEventLock); if (mCheckerboardEvent && mCheckerboardEvent->IsRecordingTrace()) { std::stringstream info; info << " velocity " << aVelocity; std::string str = info.str(); mCheckerboardEvent->UpdateRendertraceProperty( CheckerboardEvent::RequestedDisplayPort, GetDisplayPortRect(aFrameMetrics), str); } } MOZ_ASSERT(aFrameMetrics.GetScrollUpdateType() == FrameMetrics::eNone || aFrameMetrics.GetScrollUpdateType() == FrameMetrics::eUserAction); controller->RequestContentRepaint(aFrameMetrics); mExpectedGeckoMetrics = aFrameMetrics; mLastPaintRequestMetrics = aFrameMetrics; } bool AsyncPanZoomController::UpdateAnimation(const TimeStamp& aSampleTime, nsTArray>* aOutDeferredTasks) { APZThreadUtils::AssertOnCompositorThread(); // This function may get called multiple with the same sample time, because // there may be multiple layers with this APZC, and each layer invokes this // function during composition. However we only want to do one animation step // per composition so we need to deduplicate these calls first. if (mLastSampleTime == aSampleTime) { return false; } TimeDuration sampleTimeDelta = aSampleTime - mLastSampleTime; mLastSampleTime = aSampleTime; if (mAnimation) { bool continueAnimation = mAnimation->Sample(mFrameMetrics, sampleTimeDelta); bool wantsRepaints = mAnimation->WantsRepaints(); *aOutDeferredTasks = mAnimation->TakeDeferredTasks(); if (!continueAnimation) { mAnimation = nullptr; SetState(NOTHING); } // Request a repaint at the end of the animation in case something such as a // call to NotifyLayersUpdated was invoked during the animation and Gecko's // current state is some intermediate point of the animation. if (!continueAnimation || wantsRepaints) { RequestContentRepaint(); } UpdateSharedCompositorFrameMetrics(); return true; } return false; } AsyncTransformComponentMatrix AsyncPanZoomController::GetOverscrollTransform(AsyncMode aMode) const { ReentrantMonitorAutoEnter lock(mMonitor); if (aMode == RESPECT_FORCE_DISABLE && mScrollMetadata.IsApzForceDisabled()) { return AsyncTransformComponentMatrix(); } if (!IsOverscrolled()) { return AsyncTransformComponentMatrix(); } // The overscroll effect is a uniform stretch along the overscrolled axis, // with the edge of the content where we have reached the end of the // scrollable area pinned into place. // The kStretchFactor parameter determines how much overscroll can stretch the // content. const float kStretchFactor = gfxPrefs::APZOverscrollStretchFactor(); // Compute the amount of the stretch along each axis. The stretch is // proportional to the amount by which we are overscrolled along that axis. ParentLayerSize compositionSize(mX.GetCompositionLength(), mY.GetCompositionLength()); float scaleX = 1 + kStretchFactor * fabsf(mX.GetOverscroll()) / mX.GetCompositionLength(); float scaleY = 1 + kStretchFactor * fabsf(mY.GetOverscroll()) / mY.GetCompositionLength(); // The scale is applied relative to the origin of the composition bounds, i.e. // it keeps the top-left corner of the content in place. This is fine if we // are overscrolling at the top or on the left, but if we are overscrolling // at the bottom or on the right, we want the bottom or right edge of the // content to stay in place instead, so we add a translation to compensate. ParentLayerPoint translation; bool overscrolledOnRight = mX.GetOverscroll() > 0; if (overscrolledOnRight) { ParentLayerCoord overscrolledCompositionWidth = scaleX * compositionSize.width; ParentLayerCoord extraCompositionWidth = overscrolledCompositionWidth - compositionSize.width; translation.x = -extraCompositionWidth; } bool overscrolledAtBottom = mY.GetOverscroll() > 0; if (overscrolledAtBottom) { ParentLayerCoord overscrolledCompositionHeight = scaleY * compositionSize.height; ParentLayerCoord extraCompositionHeight = overscrolledCompositionHeight - compositionSize.height; translation.y = -extraCompositionHeight; } // Combine the transformations into a matrix. return AsyncTransformComponentMatrix::Scaling(scaleX, scaleY, 1) .PostTranslate(translation.x, translation.y, 0); } bool AsyncPanZoomController::AdvanceAnimations(const TimeStamp& aSampleTime) { APZThreadUtils::AssertOnCompositorThread(); // Don't send any state-change notifications until the end of the function, // because we may go through some intermediate states while we finish // animations and start new ones. StateChangeNotificationBlocker blocker(this); // The eventual return value of this function. The compositor needs to know // whether or not to advance by a frame as soon as it can. For example, if a // fling is happening, it has to keep compositing so that the animation is // smooth. If an animation frame is requested, it is the compositor's // responsibility to schedule a composite. mAsyncTransformAppliedToContent = false; bool requestAnimationFrame = false; nsTArray> deferredTasks; { ReentrantMonitorAutoEnter lock(mMonitor); requestAnimationFrame = UpdateAnimation(aSampleTime, &deferredTasks); { // scope lock MutexAutoLock lock(mCheckerboardEventLock); if (mCheckerboardEvent) { mCheckerboardEvent->UpdateRendertraceProperty( CheckerboardEvent::UserVisible, CSSRect(mFrameMetrics.GetScrollOffset(), mFrameMetrics.CalculateCompositedSizeInCssPixels())); } } } // Execute any deferred tasks queued up by mAnimation's Sample() (called by // UpdateAnimation()). This needs to be done after the monitor is released // since the tasks are allowed to call APZCTreeManager methods which can grab // the tree lock. for (uint32_t i = 0; i < deferredTasks.Length(); ++i) { deferredTasks[i]->Run(); deferredTasks[i] = nullptr; } // One of the deferred tasks may have started a new animation. In this case, // we want to ask the compositor to schedule a new composite. requestAnimationFrame |= (mAnimation != nullptr); return requestAnimationFrame; } ParentLayerPoint AsyncPanZoomController::GetCurrentAsyncScrollOffset(AsyncMode aMode) const { ReentrantMonitorAutoEnter lock(mMonitor); if (aMode == RESPECT_FORCE_DISABLE && mScrollMetadata.IsApzForceDisabled()) { return mLastContentPaintMetrics.GetScrollOffset() * mLastContentPaintMetrics.GetZoom(); } return (mFrameMetrics.GetScrollOffset() + mTestAsyncScrollOffset) * mFrameMetrics.GetZoom() * mTestAsyncZoom.scale; } AsyncTransform AsyncPanZoomController::GetCurrentAsyncTransform(AsyncMode aMode) const { ReentrantMonitorAutoEnter lock(mMonitor); if (aMode == RESPECT_FORCE_DISABLE && mScrollMetadata.IsApzForceDisabled()) { return AsyncTransform(); } CSSPoint lastPaintScrollOffset; if (mLastContentPaintMetrics.IsScrollable()) { lastPaintScrollOffset = mLastContentPaintMetrics.GetScrollOffset(); } CSSPoint currentScrollOffset = mFrameMetrics.GetScrollOffset() + mTestAsyncScrollOffset; // If checkerboarding has been disallowed, clamp the scroll position to stay // within rendered content. if (!gfxPrefs::APZAllowCheckerboarding() && !mLastContentPaintMetrics.GetDisplayPort().IsEmpty()) { CSSSize compositedSize = mLastContentPaintMetrics.CalculateCompositedSizeInCssPixels(); CSSPoint maxScrollOffset = lastPaintScrollOffset + CSSPoint(mLastContentPaintMetrics.GetDisplayPort().XMost() - compositedSize.width, mLastContentPaintMetrics.GetDisplayPort().YMost() - compositedSize.height); CSSPoint minScrollOffset = lastPaintScrollOffset + mLastContentPaintMetrics.GetDisplayPort().TopLeft(); if (minScrollOffset.x < maxScrollOffset.x) { currentScrollOffset.x = clamped(currentScrollOffset.x, minScrollOffset.x, maxScrollOffset.x); } if (minScrollOffset.y < maxScrollOffset.y) { currentScrollOffset.y = clamped(currentScrollOffset.y, minScrollOffset.y, maxScrollOffset.y); } } ParentLayerPoint translation = (currentScrollOffset - lastPaintScrollOffset) * mFrameMetrics.GetZoom() * mTestAsyncZoom.scale; return AsyncTransform( LayerToParentLayerScale(mFrameMetrics.GetAsyncZoom().scale * mTestAsyncZoom.scale), -translation); } AsyncTransformComponentMatrix AsyncPanZoomController::GetCurrentAsyncTransformWithOverscroll(AsyncMode aMode) const { return AsyncTransformComponentMatrix(GetCurrentAsyncTransform(aMode)) * GetOverscrollTransform(aMode); } Matrix4x4 AsyncPanZoomController::GetTransformToLastDispatchedPaint() const { ReentrantMonitorAutoEnter lock(mMonitor); LayerPoint scrollChange = (mLastContentPaintMetrics.GetScrollOffset() - mExpectedGeckoMetrics.GetScrollOffset()) * mLastContentPaintMetrics.GetDevPixelsPerCSSPixel() * mLastContentPaintMetrics.GetCumulativeResolution(); // We're interested in the async zoom change. Factor out the content scale // that may change when dragging the window to a monitor with a different // content scale. LayoutDeviceToParentLayerScale2D lastContentZoom = mLastContentPaintMetrics.GetZoom() / mLastContentPaintMetrics.GetDevPixelsPerCSSPixel(); LayoutDeviceToParentLayerScale2D lastDispatchedZoom = mExpectedGeckoMetrics.GetZoom() / mExpectedGeckoMetrics.GetDevPixelsPerCSSPixel(); gfxSize zoomChange = lastContentZoom / lastDispatchedZoom; return Matrix4x4::Translation(scrollChange.x, scrollChange.y, 0). PostScale(zoomChange.width, zoomChange.height, 1); } uint32_t AsyncPanZoomController::GetCheckerboardMagnitude() const { ReentrantMonitorAutoEnter lock(mMonitor); CSSPoint currentScrollOffset = mFrameMetrics.GetScrollOffset() + mTestAsyncScrollOffset; CSSRect painted = mLastContentPaintMetrics.GetDisplayPort() + mLastContentPaintMetrics.GetScrollOffset(); CSSRect visible = CSSRect(currentScrollOffset, mFrameMetrics.CalculateCompositedSizeInCssPixels()); CSSIntRegion checkerboard; // Round so as to minimize checkerboarding; if we're only showing fractional // pixels of checkerboarding it's not really worth counting checkerboard.Sub(RoundedIn(visible), RoundedOut(painted)); return checkerboard.Area(); } void AsyncPanZoomController::ReportCheckerboard(const TimeStamp& aSampleTime) { if (mLastCheckerboardReport == aSampleTime) { // This function will get called multiple times for each APZC on a single // composite (once for each layer it is attached to). Only report the // checkerboard once per composite though. return; } mLastCheckerboardReport = aSampleTime; bool recordTrace = gfxPrefs::APZRecordCheckerboarding(); uint32_t magnitude = GetCheckerboardMagnitude(); MutexAutoLock lock(mCheckerboardEventLock); if (!mCheckerboardEvent && recordTrace) { mCheckerboardEvent = MakeUnique(recordTrace); } mPotentialCheckerboardTracker.InTransform(IsTransformingState(mState)); if (magnitude) { mPotentialCheckerboardTracker.CheckerboardSeen(); } UpdateCheckerboardEvent(lock, magnitude); } void AsyncPanZoomController::UpdateCheckerboardEvent(const MutexAutoLock& aProofOfLock, uint32_t aMagnitude) { if (mCheckerboardEvent && mCheckerboardEvent->RecordFrameInfo(aMagnitude)) { // This checkerboard event is done. mPotentialCheckerboardTracker.CheckerboardDone(); if (gfxPrefs::APZRecordCheckerboarding()) { // if the pref is enabled, also send it to the storage class. it may be // chosen for public display on about:checkerboard, the hall of fame for // checkerboard events. uint32_t severity = mCheckerboardEvent->GetSeverity(); std::string log = mCheckerboardEvent->GetLog(); CheckerboardEventStorage::Report(severity, log); } mCheckerboardEvent = nullptr; } } void AsyncPanZoomController::FlushActiveCheckerboardReport() { MutexAutoLock lock(mCheckerboardEventLock); // Pretend like we got a frame with 0 pixels checkerboarded. This will // terminate the checkerboard event and flush it out UpdateCheckerboardEvent(lock, 0); } bool AsyncPanZoomController::IsCurrentlyCheckerboarding() const { ReentrantMonitorAutoEnter lock(mMonitor); if (!gfxPrefs::APZAllowCheckerboarding() || mScrollMetadata.IsApzForceDisabled()) { return false; } CSSPoint currentScrollOffset = mFrameMetrics.GetScrollOffset() + mTestAsyncScrollOffset; CSSRect painted = mLastContentPaintMetrics.GetDisplayPort() + mLastContentPaintMetrics.GetScrollOffset(); painted.Inflate(CSSMargin::FromAppUnits(nsMargin(1, 1, 1, 1))); // fuzz for rounding error CSSRect visible = CSSRect(currentScrollOffset, mFrameMetrics.CalculateCompositedSizeInCssPixels()); if (painted.Contains(visible)) { return false; } APZC_LOG_FM(mFrameMetrics, "%p is currently checkerboarding (painted %s visble %s)", this, Stringify(painted).c_str(), Stringify(visible).c_str()); return true; } void AsyncPanZoomController::NotifyLayersUpdated(const ScrollMetadata& aScrollMetadata, bool aIsFirstPaint, bool aThisLayerTreeUpdated) { APZThreadUtils::AssertOnCompositorThread(); ReentrantMonitorAutoEnter lock(mMonitor); bool isDefault = mScrollMetadata.IsDefault(); const FrameMetrics& aLayerMetrics = aScrollMetadata.GetMetrics(); if ((aScrollMetadata == mLastContentPaintMetadata) && !isDefault) { // No new information here, skip it. APZC_LOG("%p NotifyLayersUpdated short-circuit\n", this); return; } // If the mFrameMetrics scroll offset is different from the last scroll offset // that the main-thread sent us, then we know that the user has been doing // something that triggers a scroll. This check is the APZ equivalent of the // check on the main-thread at // https://hg.mozilla.org/mozilla-central/file/97a52326b06a/layout/generic/nsGfxScrollFrame.cpp#l4050 // There is code below (the use site of userScrolled) that prevents a restored- // scroll-position update from overwriting a user scroll, again equivalent to // how the main thread code does the same thing. CSSPoint lastScrollOffset = mLastContentPaintMetadata.GetMetrics().GetScrollOffset(); bool userScrolled = !FuzzyEqualsAdditive(mFrameMetrics.GetScrollOffset().x, lastScrollOffset.x) || !FuzzyEqualsAdditive(mFrameMetrics.GetScrollOffset().y, lastScrollOffset.y); if (aLayerMetrics.GetScrollUpdateType() != FrameMetrics::ScrollOffsetUpdateType::ePending) { mLastContentPaintMetadata = aScrollMetadata; } mScrollMetadata.SetScrollParentId(aScrollMetadata.GetScrollParentId()); APZC_LOG_FM(aLayerMetrics, "%p got a NotifyLayersUpdated with aIsFirstPaint=%d, aThisLayerTreeUpdated=%d", this, aIsFirstPaint, aThisLayerTreeUpdated); { // scope lock MutexAutoLock lock(mCheckerboardEventLock); if (mCheckerboardEvent && mCheckerboardEvent->IsRecordingTrace()) { std::string str; if (aThisLayerTreeUpdated) { if (!aLayerMetrics.GetPaintRequestTime().IsNull()) { // Note that we might get the paint request time as non-null, but with // aThisLayerTreeUpdated false. That can happen if we get a layer transaction // from a different process right after we get the layer transaction with // aThisLayerTreeUpdated == true. In this case we want to ignore the // paint request time because it was already dumped in the previous layer // transaction. TimeDuration paintTime = TimeStamp::Now() - aLayerMetrics.GetPaintRequestTime(); std::stringstream info; info << " painttime " << paintTime.ToMilliseconds(); str = info.str(); } else { // This might be indicative of a wasted paint particularly if it happens // during a checkerboard event. str = " (this layertree updated)"; } } mCheckerboardEvent->UpdateRendertraceProperty( CheckerboardEvent::Page, aLayerMetrics.GetScrollableRect()); mCheckerboardEvent->UpdateRendertraceProperty( CheckerboardEvent::PaintedDisplayPort, aLayerMetrics.GetDisplayPort() + aLayerMetrics.GetScrollOffset(), str); if (!aLayerMetrics.GetCriticalDisplayPort().IsEmpty()) { mCheckerboardEvent->UpdateRendertraceProperty( CheckerboardEvent::PaintedCriticalDisplayPort, aLayerMetrics.GetCriticalDisplayPort() + aLayerMetrics.GetScrollOffset()); } } } bool needContentRepaint = false; bool viewportUpdated = false; if (FuzzyEqualsAdditive(aLayerMetrics.GetCompositionBounds().width, mFrameMetrics.GetCompositionBounds().width) && FuzzyEqualsAdditive(aLayerMetrics.GetCompositionBounds().height, mFrameMetrics.GetCompositionBounds().height)) { // Remote content has sync'd up to the composition geometry // change, so we can accept the viewport it's calculated. if (mFrameMetrics.GetViewport().width != aLayerMetrics.GetViewport().width || mFrameMetrics.GetViewport().height != aLayerMetrics.GetViewport().height) { needContentRepaint = true; viewportUpdated = true; } mFrameMetrics.SetViewport(aLayerMetrics.GetViewport()); } // If the layers update was not triggered by our own repaint request, then // we want to take the new scroll offset. Check the scroll generation as well // to filter duplicate calls to NotifyLayersUpdated with the same scroll offset // update message. bool scrollOffsetUpdated = aLayerMetrics.GetScrollOffsetUpdated() && (aLayerMetrics.GetScrollGeneration() != mFrameMetrics.GetScrollGeneration()); if (scrollOffsetUpdated && userScrolled && aLayerMetrics.GetScrollUpdateType() == FrameMetrics::ScrollOffsetUpdateType::eRestore) { APZC_LOG("%p dropping scroll update of type eRestore because of user scroll\n", this); scrollOffsetUpdated = false; } bool smoothScrollRequested = aLayerMetrics.GetDoSmoothScroll() && (aLayerMetrics.GetScrollGeneration() != mFrameMetrics.GetScrollGeneration()); // TODO if we're in a drag and scrollOffsetUpdated is set then we want to // ignore it if ((aIsFirstPaint && aThisLayerTreeUpdated) || isDefault) { // Initialize our internal state to something sane when the content // that was just painted is something we knew nothing about previously CancelAnimation(); mScrollMetadata = aScrollMetadata; mExpectedGeckoMetrics = aLayerMetrics; ShareCompositorFrameMetrics(); if (mFrameMetrics.GetDisplayPortMargins() != ScreenMargin()) { // A non-zero display port margin here indicates a displayport has // been set by a previous APZC for the content at this guid. The // scrollable rect may have changed since then, making the margins // wrong, so we need to calculate a new display port. APZC_LOG("%p detected non-empty margins which probably need updating\n", this); needContentRepaint = true; } } else { // If we're not taking the aLayerMetrics wholesale we still need to pull // in some things into our local mFrameMetrics because these things are // determined by Gecko and our copy in mFrameMetrics may be stale. if (FuzzyEqualsAdditive(mFrameMetrics.GetCompositionBounds().width, aLayerMetrics.GetCompositionBounds().width) && mFrameMetrics.GetDevPixelsPerCSSPixel() == aLayerMetrics.GetDevPixelsPerCSSPixel() && !viewportUpdated) { // Any change to the pres shell resolution was requested by APZ and is // already included in our zoom; however, other components of the // cumulative resolution (a parent document's pres-shell resolution, or // the css-driven resolution) may have changed, and we need to update // our zoom to reflect that. Note that we can't just take // aLayerMetrics.mZoom because the APZ may have additional async zoom // since the repaint request. gfxSize totalResolutionChange = aLayerMetrics.GetCumulativeResolution() / mFrameMetrics.GetCumulativeResolution(); float presShellResolutionChange = aLayerMetrics.GetPresShellResolution() / mFrameMetrics.GetPresShellResolution(); if (presShellResolutionChange != 1.0f) { needContentRepaint = true; } mFrameMetrics.ZoomBy(totalResolutionChange / presShellResolutionChange); } else { // Take the new zoom as either device scale or composition width or // viewport size got changed (e.g. due to orientation change, or content // changing the meta-viewport tag). mFrameMetrics.SetZoom(aLayerMetrics.GetZoom()); mFrameMetrics.SetDevPixelsPerCSSPixel(aLayerMetrics.GetDevPixelsPerCSSPixel()); } if (!mFrameMetrics.GetScrollableRect().IsEqualEdges(aLayerMetrics.GetScrollableRect())) { mFrameMetrics.SetScrollableRect(aLayerMetrics.GetScrollableRect()); needContentRepaint = true; } mFrameMetrics.SetCompositionBounds(aLayerMetrics.GetCompositionBounds()); mFrameMetrics.SetRootCompositionSize(aLayerMetrics.GetRootCompositionSize()); mFrameMetrics.SetPresShellResolution(aLayerMetrics.GetPresShellResolution()); mFrameMetrics.SetCumulativeResolution(aLayerMetrics.GetCumulativeResolution()); mScrollMetadata.SetHasScrollgrab(aScrollMetadata.GetHasScrollgrab()); mScrollMetadata.SetLineScrollAmount(aScrollMetadata.GetLineScrollAmount()); mScrollMetadata.SetPageScrollAmount(aScrollMetadata.GetPageScrollAmount()); mScrollMetadata.SetSnapInfo(ScrollSnapInfo(aScrollMetadata.GetSnapInfo())); // The scroll clip can differ between layers associated a given scroll frame, // so APZC (which keeps a single copy of ScrollMetadata per scroll frame) // has no business using it. mScrollMetadata.SetScrollClip(Nothing()); mScrollMetadata.SetIsLayersIdRoot(aScrollMetadata.IsLayersIdRoot()); mScrollMetadata.SetUsesContainerScrolling(aScrollMetadata.UsesContainerScrolling()); mFrameMetrics.SetIsScrollInfoLayer(aLayerMetrics.IsScrollInfoLayer()); mScrollMetadata.SetForceDisableApz(aScrollMetadata.IsApzForceDisabled()); if (scrollOffsetUpdated) { APZC_LOG("%p updating scroll offset from %s to %s\n", this, ToString(mFrameMetrics.GetScrollOffset()).c_str(), ToString(aLayerMetrics.GetScrollOffset()).c_str()); // Send an acknowledgement with the new scroll generation so that any // repaint requests later in this function go through. // Because of the scroll generation update, any inflight paint requests are // going to be ignored by layout, and so mExpectedGeckoMetrics // becomes incorrect for the purposes of calculating the LD transform. To // correct this we need to update mExpectedGeckoMetrics to be the // last thing we know was painted by Gecko. mFrameMetrics.CopyScrollInfoFrom(aLayerMetrics); mExpectedGeckoMetrics = aLayerMetrics; // Cancel the animation (which might also trigger a repaint request) // after we update the scroll offset above. Otherwise we can be left // in a state where things are out of sync. CancelAnimation(); // Since the scroll offset has changed, we need to recompute the // displayport margins and send them to layout. Otherwise there might be // scenarios where for example we scroll from the top of a page (where the // top displayport margin is zero) to the bottom of a page, which will // result in a displayport that doesn't extend upwards at all. // Note that even if the CancelAnimation call above requested a repaint // this is fine because we already have repaint request deduplication. needContentRepaint = true; } } if (smoothScrollRequested) { // A smooth scroll has been requested for animation on the compositor // thread. This flag will be reset by the main thread when it receives // the scroll update acknowledgement. APZC_LOG("%p smooth scrolling from %s to %s in state %d\n", this, Stringify(mFrameMetrics.GetScrollOffset()).c_str(), Stringify(aLayerMetrics.GetSmoothScrollOffset()).c_str(), mState); // See comment on the similar code in the |if (scrollOffsetUpdated)| block // above. mFrameMetrics.CopySmoothScrollInfoFrom(aLayerMetrics); needContentRepaint = true; mExpectedGeckoMetrics = aLayerMetrics; SmoothScrollTo(mFrameMetrics.GetSmoothScrollOffset()); } if (needContentRepaint) { // This repaint request is not driven by a user action on the APZ side RequestContentRepaint(false); } UpdateSharedCompositorFrameMetrics(); } const FrameMetrics& AsyncPanZoomController::GetFrameMetrics() const { mMonitor.AssertCurrentThreadIn(); return mFrameMetrics; } APZCTreeManager* AsyncPanZoomController::GetApzcTreeManager() const { mMonitor.AssertNotCurrentThreadIn(); return mTreeManager; } void AsyncPanZoomController::ZoomToRect(CSSRect aRect, const uint32_t aFlags) { if (!aRect.IsFinite()) { NS_WARNING("ZoomToRect got called with a non-finite rect; ignoring..."); return; } else if (aRect.IsEmpty() && (aFlags & DISABLE_ZOOM_OUT)) { // Double-tap-to-zooming uses an empty rect to mean "zoom out". // If zooming out is disabled, an empty rect is nonsensical // and will produce undesirable scrolling. NS_WARNING("ZoomToRect got called with an empty rect and zoom out disabled; ignoring..."); return; } // Only the root APZC is zoomable, and the root APZC is not allowed to have // different x and y scales. If it did, the calculations in this function // would have to be adjusted (as e.g. it would no longer be valid to take // the minimum or maximum of the ratios of the widths and heights of the // page rect and the composition bounds). MOZ_ASSERT(mFrameMetrics.IsRootContent()); MOZ_ASSERT(mFrameMetrics.GetZoom().AreScalesSame()); SetState(ANIMATING_ZOOM); { ReentrantMonitorAutoEnter lock(mMonitor); ParentLayerRect compositionBounds = mFrameMetrics.GetCompositionBounds(); CSSRect cssPageRect = mFrameMetrics.GetScrollableRect(); CSSPoint scrollOffset = mFrameMetrics.GetScrollOffset(); CSSToParentLayerScale currentZoom = mFrameMetrics.GetZoom().ToScaleFactor(); CSSToParentLayerScale targetZoom; // The minimum zoom to prevent over-zoom-out. // If the zoom factor is lower than this (i.e. we are zoomed more into the page), // then the CSS content rect, in layers pixels, will be smaller than the // composition bounds. If this happens, we can't fill the target composited // area with this frame. CSSToParentLayerScale localMinZoom(std::max(mZoomConstraints.mMinZoom.scale, std::max(compositionBounds.width / cssPageRect.width, compositionBounds.height / cssPageRect.height))); CSSToParentLayerScale localMaxZoom = mZoomConstraints.mMaxZoom; if (!aRect.IsEmpty()) { // Intersect the zoom-to-rect to the CSS rect to make sure it fits. aRect = aRect.Intersect(cssPageRect); targetZoom = CSSToParentLayerScale(std::min(compositionBounds.width / aRect.width, compositionBounds.height / aRect.height)); } // 1. If the rect is empty, the content-side logic for handling a double-tap // requested that we zoom out. // 2. currentZoom is equal to mZoomConstraints.mMaxZoom and user still double-tapping it // 3. currentZoom is equal to localMinZoom and user still double-tapping it // Treat these three cases as a request to zoom out as much as possible. bool zoomOut; if (aFlags & DISABLE_ZOOM_OUT) { zoomOut = false; } else { zoomOut = aRect.IsEmpty() || (currentZoom == localMaxZoom && targetZoom >= localMaxZoom) || (currentZoom == localMinZoom && targetZoom <= localMinZoom); } if (zoomOut) { CSSSize compositedSize = mFrameMetrics.CalculateCompositedSizeInCssPixels(); float y = scrollOffset.y; float newHeight = cssPageRect.width * (compositedSize.height / compositedSize.width); float dh = compositedSize.height - newHeight; aRect = CSSRect(0.0f, y + dh/2, cssPageRect.width, newHeight); aRect = aRect.Intersect(cssPageRect); targetZoom = CSSToParentLayerScale(std::min(compositionBounds.width / aRect.width, compositionBounds.height / aRect.height)); } targetZoom.scale = clamped(targetZoom.scale, localMinZoom.scale, localMaxZoom.scale); FrameMetrics endZoomToMetrics = mFrameMetrics; if (aFlags & PAN_INTO_VIEW_ONLY) { targetZoom = currentZoom; } else if(aFlags & ONLY_ZOOM_TO_DEFAULT_SCALE) { CSSToParentLayerScale zoomAtDefaultScale = mFrameMetrics.GetDevPixelsPerCSSPixel() * LayoutDeviceToParentLayerScale(1.0); if (targetZoom.scale > zoomAtDefaultScale.scale) { // Only change the zoom if we are less than the default zoom if (currentZoom.scale < zoomAtDefaultScale.scale) { targetZoom = zoomAtDefaultScale; } else { targetZoom = currentZoom; } } } endZoomToMetrics.SetZoom(CSSToParentLayerScale2D(targetZoom)); // Adjust the zoomToRect to a sensible position to prevent overscrolling. CSSSize sizeAfterZoom = endZoomToMetrics.CalculateCompositedSizeInCssPixels(); // Vertically center the zoomed element in the screen. if (!zoomOut && (sizeAfterZoom.height > aRect.height)) { aRect.y -= (sizeAfterZoom.height - aRect.height) * 0.5f; if (aRect.y < 0.0f) { aRect.y = 0.0f; } } // If either of these conditions are met, the page will be // overscrolled after zoomed if (aRect.y + sizeAfterZoom.height > cssPageRect.height) { aRect.y = cssPageRect.height - sizeAfterZoom.height; aRect.y = aRect.y > 0 ? aRect.y : 0; } if (aRect.x + sizeAfterZoom.width > cssPageRect.width) { aRect.x = cssPageRect.width - sizeAfterZoom.width; aRect.x = aRect.x > 0 ? aRect.x : 0; } endZoomToMetrics.SetScrollOffset(aRect.TopLeft()); StartAnimation(new ZoomAnimation( mFrameMetrics.GetScrollOffset(), mFrameMetrics.GetZoom(), endZoomToMetrics.GetScrollOffset(), endZoomToMetrics.GetZoom())); // Schedule a repaint now, so the new displayport will be painted before the // animation finishes. ParentLayerPoint velocity(0, 0); endZoomToMetrics.SetDisplayPortMargins( CalculatePendingDisplayPort(endZoomToMetrics, velocity)); endZoomToMetrics.SetUseDisplayPortMargins(true); endZoomToMetrics.SetPaintRequestTime(TimeStamp::Now()); endZoomToMetrics.SetRepaintDrivenByUserAction(true); RefPtr controller = GetGeckoContentController(); if (!controller) { return; } if (controller->IsRepaintThread()) { RequestContentRepaint(endZoomToMetrics, velocity); } else { // use a local var to resolve the function overload auto func = static_cast (&AsyncPanZoomController::RequestContentRepaint); controller->DispatchToRepaintThread( NewRunnableMethod( this, func, endZoomToMetrics, velocity)); } } } CancelableBlockState* AsyncPanZoomController::GetCurrentInputBlock() const { return GetInputQueue()->GetCurrentBlock(); } TouchBlockState* AsyncPanZoomController::GetCurrentTouchBlock() const { return GetInputQueue()->GetCurrentTouchBlock(); } PanGestureBlockState* AsyncPanZoomController::GetCurrentPanGestureBlock() const { return GetInputQueue()->GetCurrentPanGestureBlock(); } void AsyncPanZoomController::ResetTouchInputState() { MultiTouchInput cancel(MultiTouchInput::MULTITOUCH_CANCEL, 0, TimeStamp::Now(), 0); RefPtr listener = GetGestureEventListener(); if (listener) { listener->HandleInputEvent(cancel); } CancelAnimationAndGestureState(); // Clear overscroll along the entire handoff chain, in case an APZC // later in the chain is overscrolled. if (TouchBlockState* block = GetCurrentTouchBlock()) { block->GetOverscrollHandoffChain()->ClearOverscroll(); } } void AsyncPanZoomController::CancelAnimationAndGestureState() { mX.CancelGesture(); mY.CancelGesture(); CancelAnimation(CancelAnimationFlags::ScrollSnap); } bool AsyncPanZoomController::HasReadyTouchBlock() const { return GetInputQueue()->HasReadyTouchBlock(); } void AsyncPanZoomController::SetState(PanZoomState aNewState) { PanZoomState oldState; // Intentional scoping for mutex { ReentrantMonitorAutoEnter lock(mMonitor); APZC_LOG("%p changing from state %d to %d\n", this, mState, aNewState); oldState = mState; mState = aNewState; } DispatchStateChangeNotification(oldState, aNewState); } void AsyncPanZoomController::DispatchStateChangeNotification(PanZoomState aOldState, PanZoomState aNewState) { { // scope the lock ReentrantMonitorAutoEnter lock(mMonitor); if (mNotificationBlockers > 0) { return; } } if (RefPtr controller = GetGeckoContentController()) { if (!IsTransformingState(aOldState) && IsTransformingState(aNewState)) { controller->NotifyAPZStateChange( GetGuid(), APZStateChange::eTransformBegin); #if defined(XP_WIN) || defined(MOZ_WIDGET_GTK) // Let the compositor know about scroll state changes so it can manage // windowed plugins. if (gfxPrefs::HidePluginsForScroll() && mCompositorController) { mCompositorController->ScheduleHideAllPluginWindows(); } #endif } else if (IsTransformingState(aOldState) && !IsTransformingState(aNewState)) { controller->NotifyAPZStateChange( GetGuid(), APZStateChange::eTransformEnd); #if defined(XP_WIN) || defined(MOZ_WIDGET_GTK) if (gfxPrefs::HidePluginsForScroll() && mCompositorController) { mCompositorController->ScheduleShowAllPluginWindows(); } #endif } } } bool AsyncPanZoomController::IsTransformingState(PanZoomState aState) { return !(aState == NOTHING || aState == TOUCHING); } bool AsyncPanZoomController::IsInPanningState() const { return (mState == PANNING || mState == PANNING_LOCKED_X || mState == PANNING_LOCKED_Y); } void AsyncPanZoomController::UpdateZoomConstraints(const ZoomConstraints& aConstraints) { APZC_LOG("%p updating zoom constraints to %d %d %f %f\n", this, aConstraints.mAllowZoom, aConstraints.mAllowDoubleTapZoom, aConstraints.mMinZoom.scale, aConstraints.mMaxZoom.scale); if (IsNaN(aConstraints.mMinZoom.scale) || IsNaN(aConstraints.mMaxZoom.scale)) { NS_WARNING("APZC received zoom constraints with NaN values; dropping..."); return; } CSSToParentLayerScale min = mFrameMetrics.GetDevPixelsPerCSSPixel() * kViewportMinScale / ParentLayerToScreenScale(1); CSSToParentLayerScale max = mFrameMetrics.GetDevPixelsPerCSSPixel() * kViewportMaxScale / ParentLayerToScreenScale(1); // inf float values and other bad cases should be sanitized by the code below. mZoomConstraints.mAllowZoom = aConstraints.mAllowZoom; mZoomConstraints.mAllowDoubleTapZoom = aConstraints.mAllowDoubleTapZoom; mZoomConstraints.mMinZoom = (min > aConstraints.mMinZoom ? min : aConstraints.mMinZoom); mZoomConstraints.mMaxZoom = (max > aConstraints.mMaxZoom ? aConstraints.mMaxZoom : max); if (mZoomConstraints.mMaxZoom < mZoomConstraints.mMinZoom) { mZoomConstraints.mMaxZoom = mZoomConstraints.mMinZoom; } } ZoomConstraints AsyncPanZoomController::GetZoomConstraints() const { return mZoomConstraints; } void AsyncPanZoomController::PostDelayedTask(already_AddRefed aTask, int aDelayMs) { APZThreadUtils::AssertOnControllerThread(); RefPtr task = aTask; RefPtr controller = GetGeckoContentController(); if (controller) { controller->PostDelayedTask(task.forget(), aDelayMs); } // If there is no controller, that means this APZC has been destroyed, and // we probably don't need to run the task. It will get destroyed when the // RefPtr goes out of scope. } bool AsyncPanZoomController::Matches(const ScrollableLayerGuid& aGuid) { return aGuid == GetGuid(); } bool AsyncPanZoomController::HasTreeManager(const APZCTreeManager* aTreeManager) const { return GetApzcTreeManager() == aTreeManager; } void AsyncPanZoomController::GetGuid(ScrollableLayerGuid* aGuidOut) const { if (aGuidOut) { *aGuidOut = GetGuid(); } } ScrollableLayerGuid AsyncPanZoomController::GetGuid() const { return ScrollableLayerGuid(mLayersId, mFrameMetrics); } void AsyncPanZoomController::UpdateSharedCompositorFrameMetrics() { mMonitor.AssertCurrentThreadIn(); FrameMetrics* frame = mSharedFrameMetricsBuffer ? static_cast(mSharedFrameMetricsBuffer->memory()) : nullptr; if (frame && mSharedLock && gfxPrefs::ProgressivePaint()) { mSharedLock->Lock(); *frame = mFrameMetrics; mSharedLock->Unlock(); } } void AsyncPanZoomController::ShareCompositorFrameMetrics() { APZThreadUtils::AssertOnCompositorThread(); // Only create the shared memory buffer if it hasn't already been created, // we are using progressive tile painting, and we have a // controller to pass the shared memory back to the content process/thread. if (!mSharedFrameMetricsBuffer && mMetricsSharingController && gfxPrefs::ProgressivePaint()) { // Create shared memory and initialize it with the current FrameMetrics value mSharedFrameMetricsBuffer = new ipc::SharedMemoryBasic; FrameMetrics* frame = nullptr; mSharedFrameMetricsBuffer->Create(sizeof(FrameMetrics)); mSharedFrameMetricsBuffer->Map(sizeof(FrameMetrics)); frame = static_cast(mSharedFrameMetricsBuffer->memory()); if (frame) { { // scope the monitor, only needed to copy the FrameMetrics. ReentrantMonitorAutoEnter lock(mMonitor); *frame = mFrameMetrics; } // Get the process id of the content process base::ProcessId otherPid = mMetricsSharingController->RemotePid(); ipc::SharedMemoryBasic::Handle mem = ipc::SharedMemoryBasic::NULLHandle(); // Get the shared memory handle to share with the content process mSharedFrameMetricsBuffer->ShareToProcess(otherPid, &mem); // Get the cross process mutex handle to share with the content process mSharedLock = new CrossProcessMutex("AsyncPanZoomControlLock"); CrossProcessMutexHandle handle = mSharedLock->ShareToProcess(otherPid); // Send the shared memory handle and cross process handle to the content // process by an asynchronous ipc call. Include the APZC unique ID // so the content process know which APZC sent this shared FrameMetrics. if (!mMetricsSharingController->StartSharingMetrics(mem, handle, mLayersId, mAPZCId)) { APZC_LOG("%p failed to share FrameMetrics with content process.", this); } } } } Maybe AsyncPanZoomController::FindSnapPointNear( const CSSPoint& aDestination, nsIScrollableFrame::ScrollUnit aUnit) { mMonitor.AssertCurrentThreadIn(); APZC_LOG("%p scroll snapping near %s\n", this, Stringify(aDestination).c_str()); CSSRect scrollRange = mFrameMetrics.CalculateScrollRange(); if (Maybe snapPoint = ScrollSnapUtils::GetSnapPointForDestination( mScrollMetadata.GetSnapInfo(), aUnit, CSSSize::ToAppUnits(mFrameMetrics.CalculateCompositedSizeInCssPixels()), CSSRect::ToAppUnits(scrollRange), CSSPoint::ToAppUnits(mFrameMetrics.GetScrollOffset()), CSSPoint::ToAppUnits(aDestination))) { CSSPoint cssSnapPoint = CSSPoint::FromAppUnits(snapPoint.ref()); // GetSnapPointForDestination() can produce a destination that's outside // of the scroll frame's scroll range. Clamp it here (this matches the // behaviour of the main-thread code path, which clamps it in // nsGfxScrollFrame::ScrollTo()). return Some(scrollRange.ClampPoint(cssSnapPoint)); } return Nothing(); } void AsyncPanZoomController::ScrollSnapNear(const CSSPoint& aDestination) { if (Maybe snapPoint = FindSnapPointNear(aDestination, nsIScrollableFrame::DEVICE_PIXELS)) { if (*snapPoint != mFrameMetrics.GetScrollOffset()) { APZC_LOG("%p smooth scrolling to snap point %s\n", this, Stringify(*snapPoint).c_str()); SmoothScrollTo(*snapPoint); } } } void AsyncPanZoomController::ScrollSnap() { ReentrantMonitorAutoEnter lock(mMonitor); ScrollSnapNear(mFrameMetrics.GetScrollOffset()); } void AsyncPanZoomController::ScrollSnapToDestination() { ReentrantMonitorAutoEnter lock(mMonitor); float friction = gfxPrefs::APZFlingFriction(); ParentLayerPoint velocity(mX.GetVelocity(), mY.GetVelocity()); ParentLayerPoint predictedDelta; // "-velocity / log(1.0 - friction)" is the integral of the deceleration // curve modeled for flings in the "Axis" class. if (velocity.x != 0.0f) { predictedDelta.x = -velocity.x / log(1.0 - friction); } if (velocity.y != 0.0f) { predictedDelta.y = -velocity.y / log(1.0 - friction); } CSSPoint predictedDestination = mFrameMetrics.GetScrollOffset() + predictedDelta / mFrameMetrics.GetZoom(); // If the fling will overscroll, don't scroll snap, because then the user // user would not see any overscroll animation. bool flingWillOverscroll = IsOverscrolled() && ((velocity.x * mX.GetOverscroll() >= 0) || (velocity.y * mY.GetOverscroll() >= 0)); if (!flingWillOverscroll) { APZC_LOG("%p fling snapping. friction: %f velocity: %f, %f " "predictedDelta: %f, %f position: %f, %f " "predictedDestination: %f, %f\n", this, friction, velocity.x, velocity.y, (float)predictedDelta.x, (float)predictedDelta.y, (float)mFrameMetrics.GetScrollOffset().x, (float)mFrameMetrics.GetScrollOffset().y, (float)predictedDestination.x, (float)predictedDestination.y); ScrollSnapNear(predictedDestination); } } bool AsyncPanZoomController::MaybeAdjustDeltaForScrollSnapping( const ScrollWheelInput& aEvent, ParentLayerPoint& aDelta, CSSPoint& aStartPosition) { // Don't scroll snap for pixel scrolls. This matches the main thread // behaviour in EventStateManager::DoScrollText(). if (aEvent.mDeltaType == ScrollWheelInput::SCROLLDELTA_PIXEL) { return false; } ReentrantMonitorAutoEnter lock(mMonitor); CSSToParentLayerScale2D zoom = mFrameMetrics.GetZoom(); CSSPoint destination = mFrameMetrics.CalculateScrollRange().ClampPoint( aStartPosition + (aDelta / zoom)); nsIScrollableFrame::ScrollUnit unit = ScrollWheelInput::ScrollUnitForDeltaType(aEvent.mDeltaType); if (Maybe snapPoint = FindSnapPointNear(destination, unit)) { aDelta = (*snapPoint - aStartPosition) * zoom; aStartPosition = *snapPoint; return true; } return false; } } // namespace layers } // namespace mozilla