gecko-dev/gfx/layers/FrameMetrics.h

719 строки
23 KiB
C++

/* -*- Mode: C++; tab-width: 2; 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/. */
#ifndef GFX_FRAMEMETRICS_H
#define GFX_FRAMEMETRICS_H
#include <stdint.h> // for uint32_t, uint64_t
#include "Units.h" // for CSSRect, CSSPixel, etc
#include "mozilla/gfx/BasePoint.h" // for BasePoint
#include "mozilla/gfx/Rect.h" // for RoundedIn
#include "mozilla/gfx/ScaleFactor.h" // for ScaleFactor
#include "mozilla/gfx/Logging.h" // for Log
#include "gfxColor.h"
#include "nsString.h"
namespace IPC {
template <typename T> struct ParamTraits;
} // namespace IPC
namespace mozilla {
// The layer coordinates of the parent layer.
// This can be arrived at in two ways:
// - Start with the CSS coordinates of the parent layer (note: NOT the
// CSS coordinates of the current layer, that will give you the wrong
// answer), multiply by the device scale and the resolutions of all
// layers from the root down to and including the parent.
// - Start with global screen coordinates and unapply all CSS and async
// transforms from the root down to and including the parent.
// It's helpful to look at https://wiki.mozilla.org/Platform/GFX/APZ#Coordinate_systems
// to get a picture of how the various coordinate systems relate to each other.
struct ParentLayerPixel {};
template<> struct IsPixel<ParentLayerPixel> : TrueType {};
typedef gfx::MarginTyped<ParentLayerPixel> ParentLayerMargin;
typedef gfx::PointTyped<ParentLayerPixel> ParentLayerPoint;
typedef gfx::RectTyped<ParentLayerPixel> ParentLayerRect;
typedef gfx::SizeTyped<ParentLayerPixel> ParentLayerSize;
typedef gfx::IntMarginTyped<ParentLayerPixel> ParentLayerIntMargin;
typedef gfx::IntPointTyped<ParentLayerPixel> ParentLayerIntPoint;
typedef gfx::IntRectTyped<ParentLayerPixel> ParentLayerIntRect;
typedef gfx::IntSizeTyped<ParentLayerPixel> ParentLayerIntSize;
typedef gfx::ScaleFactor<CSSPixel, ParentLayerPixel> CSSToParentLayerScale;
typedef gfx::ScaleFactor<LayoutDevicePixel, ParentLayerPixel> LayoutDeviceToParentLayerScale;
typedef gfx::ScaleFactor<ScreenPixel, ParentLayerPixel> ScreenToParentLayerScale;
typedef gfx::ScaleFactor<ParentLayerPixel, LayerPixel> ParentLayerToLayerScale;
typedef gfx::ScaleFactor<ParentLayerPixel, ScreenPixel> ParentLayerToScreenScale;
namespace layers {
/**
* The viewport and displayport metrics for the painted frame at the
* time of a layer-tree transaction. These metrics are especially
* useful for shadow layers, because the metrics values are updated
* atomically with new pixels.
*
* Note that the FrameMetrics struct is sometimes stored in shared
* memory and shared across processes, so it should be a "Plain Old
* Data (POD)" type with no members that use dynamic memory.
*/
struct FrameMetrics {
friend struct IPC::ParamTraits<mozilla::layers::FrameMetrics>;
public:
// We use IDs to identify frames across processes.
typedef uint64_t ViewID;
static const ViewID NULL_SCROLL_ID; // This container layer does not scroll.
static const ViewID START_SCROLL_ID = 2; // This is the ID that scrolling subframes
// will begin at.
static const FrameMetrics sNullMetrics; // We often need an empty metrics
FrameMetrics()
: mCompositionBounds(0, 0, 0, 0)
, mDisplayPort(0, 0, 0, 0)
, mCriticalDisplayPort(0, 0, 0, 0)
, mScrollableRect(0, 0, 0, 0)
, mResolution(1)
, mCumulativeResolution(1)
, mTransformScale(1)
, mDevPixelsPerCSSPixel(1)
, mMayHaveTouchListeners(false)
, mMayHaveTouchCaret(false)
, mIsRoot(false)
, mHasScrollgrab(false)
, mScrollId(NULL_SCROLL_ID)
, mScrollParentId(NULL_SCROLL_ID)
, mScrollOffset(0, 0)
, mZoom(1)
, mUpdateScrollOffset(false)
, mScrollGeneration(0)
, mRootCompositionSize(0, 0)
, mDisplayPortMargins(0, 0, 0, 0)
, mUseDisplayPortMargins(false)
, mPresShellId(-1)
, mViewport(0, 0, 0, 0)
, mBackgroundColor(0, 0, 0, 0)
{
mContentDescription[0] = '\0';
}
// Default copy ctor and operator= are fine
bool operator==(const FrameMetrics& aOther) const
{
return mCompositionBounds.IsEqualEdges(aOther.mCompositionBounds) &&
mRootCompositionSize == aOther.mRootCompositionSize &&
mDisplayPort.IsEqualEdges(aOther.mDisplayPort) &&
mDisplayPortMargins == aOther.mDisplayPortMargins &&
mUseDisplayPortMargins == aOther.mUseDisplayPortMargins &&
mCriticalDisplayPort.IsEqualEdges(aOther.mCriticalDisplayPort) &&
mViewport.IsEqualEdges(aOther.mViewport) &&
mScrollableRect.IsEqualEdges(aOther.mScrollableRect) &&
mResolution == aOther.mResolution &&
mCumulativeResolution == aOther.mCumulativeResolution &&
mDevPixelsPerCSSPixel == aOther.mDevPixelsPerCSSPixel &&
mMayHaveTouchListeners == aOther.mMayHaveTouchListeners &&
mMayHaveTouchCaret == aOther.mMayHaveTouchCaret &&
mPresShellId == aOther.mPresShellId &&
mIsRoot == aOther.mIsRoot &&
mScrollId == aOther.mScrollId &&
mScrollParentId == aOther.mScrollParentId &&
mScrollOffset == aOther.mScrollOffset &&
mHasScrollgrab == aOther.mHasScrollgrab &&
mUpdateScrollOffset == aOther.mUpdateScrollOffset &&
mBackgroundColor == aOther.mBackgroundColor &&
!strcmp(mContentDescription, aOther.mContentDescription);
}
bool operator!=(const FrameMetrics& aOther) const
{
return !operator==(aOther);
}
bool IsDefault() const
{
FrameMetrics def;
def.mPresShellId = mPresShellId;
return (def == *this);
}
bool IsRootScrollable() const
{
return mIsRoot;
}
bool IsScrollable() const
{
return mScrollId != NULL_SCROLL_ID;
}
CSSToLayerScale LayersPixelsPerCSSPixel() const
{
return mCumulativeResolution * mDevPixelsPerCSSPixel;
}
LayerPoint GetScrollOffsetInLayerPixels() const
{
return GetScrollOffset() * LayersPixelsPerCSSPixel();
}
LayoutDeviceToParentLayerScale GetParentResolution() const
{
return mCumulativeResolution / mResolution;
}
// Ensure the scrollableRect is at least as big as the compositionBounds
// because the scrollableRect can be smaller if the content is not large
// and the scrollableRect hasn't been updated yet.
// We move the scrollableRect up because we don't know if we can move it
// down. i.e. we know that scrollableRect can go back as far as zero.
// but we don't know how much further ahead it can go.
CSSRect GetExpandedScrollableRect() const
{
CSSRect scrollableRect = mScrollableRect;
CSSSize compSize = CalculateCompositedSizeInCssPixels();
if (scrollableRect.width < compSize.width) {
scrollableRect.x = std::max(0.f,
scrollableRect.x - (compSize.width - scrollableRect.width));
scrollableRect.width = compSize.width;
}
if (scrollableRect.height < compSize.height) {
scrollableRect.y = std::max(0.f,
scrollableRect.y - (compSize.height - scrollableRect.height));
scrollableRect.height = compSize.height;
}
return scrollableRect;
}
// Return the scale factor needed to fit the viewport
// into its composition bounds.
CSSToScreenScale CalculateIntrinsicScale() const
{
return CSSToScreenScale(
std::max(mCompositionBounds.width / mViewport.width,
mCompositionBounds.height / mViewport.height));
}
// Return the scale factor for converting from CSS pixels (for this layer)
// to layer pixels of our parent layer. Much as mZoom is used to interface
// between inputs we get in screen pixels and quantities in CSS pixels,
// this is used to interface between mCompositionBounds and quantities
// in CSS pixels.
CSSToParentLayerScale GetZoomToParent() const
{
return mZoom * mTransformScale;
}
CSSSize CalculateCompositedSizeInCssPixels() const
{
return mCompositionBounds.Size() / GetZoomToParent();
}
CSSRect CalculateCompositedRectInCssPixels() const
{
return mCompositionBounds / GetZoomToParent();
}
CSSSize CalculateBoundedCompositedSizeInCssPixels() const
{
CSSSize size = CalculateCompositedSizeInCssPixels();
size.width = std::min(size.width, mRootCompositionSize.width);
size.height = std::min(size.height, mRootCompositionSize.height);
return size;
}
void ScrollBy(const CSSPoint& aPoint)
{
mScrollOffset += aPoint;
}
void ZoomBy(float aFactor)
{
mZoom.scale *= aFactor;
}
void CopyScrollInfoFrom(const FrameMetrics& aOther)
{
mScrollOffset = aOther.mScrollOffset;
mScrollGeneration = aOther.mScrollGeneration;
}
// ---------------------------------------------------------------------------
// The following metrics are all in widget space/device pixels.
//
// This is the area within the widget that we're compositing to. It is relative
// to the layer tree origin.
//
// This is useful because, on mobile, the viewport and composition dimensions
// are not always the same. In this case, we calculate the displayport using
// an area bigger than the region we're compositing to. If we used the
// viewport dimensions to calculate the displayport, we'd run into situations
// where we're prerendering the wrong regions and the content may be clipped,
// or too much of it prerendered. If the composition dimensions are the same as the
// viewport dimensions, there is no need for this and we can just use the viewport
// instead.
//
// This value is valid for nested scrollable layers as well, and is still
// relative to the layer tree origin. This value is provided by Gecko at
// layout/paint time.
ParentLayerRect mCompositionBounds;
// ---------------------------------------------------------------------------
// The following metrics are all in CSS pixels. They are not in any uniform
// space, so each is explained separately.
//
// The area of a frame's contents that has been painted, relative to the
// viewport. It is in the same coordinate space as |mViewport|. For example,
// if it is at 0,0, then it's at the same place at the viewport, which is at
// the top-left in the layer, and at the same place as the scroll offset of
// the document.
//
// Note that this is structured in such a way that it doesn't depend on the
// method layout uses to scroll content.
//
// May be larger or smaller than |mScrollableRect|.
//
// To pre-render a margin of 100 CSS pixels around the window,
// { x = -100, y = - 100,
// width = window.innerWidth + 200, height = window.innerHeight + 200 }
CSSRect mDisplayPort;
// If non-empty, the area of a frame's contents that is considered critical
// to paint. Area outside of this area (i.e. area inside mDisplayPort, but
// outside of mCriticalDisplayPort) is considered low-priority, and may be
// painted with lower precision, or not painted at all.
//
// The same restrictions for mDisplayPort apply here.
CSSRect mCriticalDisplayPort;
// The scrollable bounds of a frame. This is determined by reflow.
// Ordinarily the x and y will be 0 and the width and height will be the
// size of the element being scrolled. However for RTL pages or elements
// the x value may be negative.
//
// This is relative to the document. It is in the same coordinate space as
// |mScrollOffset|, but a different coordinate space than |mViewport| and
// |mDisplayPort|. Note also that this coordinate system is understood by
// window.scrollTo().
//
// This is valid on any layer unless it has no content.
CSSRect mScrollableRect;
// ---------------------------------------------------------------------------
// The following metrics are dimensionless.
//
// The incremental resolution that the current frame has been painted at
// relative to the parent frame's resolution. This information is provided
// by Gecko at layout/paint time.
ParentLayerToLayerScale mResolution;
// The cumulative resolution that the current frame has been painted at.
// This is the product of our mResolution and the mResolutions of our parent frames.
// This information is provided by Gecko at layout/paint time.
LayoutDeviceToLayerScale mCumulativeResolution;
// The conversion factor between local screen pixels (the coordinate
// system in which APZCs receive input events) and our parent layer's
// layer pixels (the coordinate system of mCompositionBounds).
// This consists of the scale of the local CSS transform and the
// nontransient async transform.
// TODO: APZ does not currently work well if there is a CSS transform
// on the layer being scrolled that's not just a scale that's
// the same in both directions. When we fix this, mTransformScale
// will probably need to turn into a matrix.
ScreenToParentLayerScale mTransformScale;
// The conversion factor between CSS pixels and device pixels for this frame.
// This can vary based on a variety of things, such as reflowing-zoom. The
// conversion factor for device pixels to layers pixels is just the
// resolution.
CSSToLayoutDeviceScale mDevPixelsPerCSSPixel;
// Whether or not this frame may have touch listeners.
bool mMayHaveTouchListeners;
// Whether or not this frame may have touch caret.
bool mMayHaveTouchCaret;
public:
void SetIsRoot(bool aIsRoot)
{
mIsRoot = aIsRoot;
}
bool GetIsRoot() const
{
return mIsRoot;
}
void SetHasScrollgrab(bool aHasScrollgrab)
{
mHasScrollgrab = aHasScrollgrab;
}
bool GetHasScrollgrab() const
{
return mHasScrollgrab;
}
void SetScrollOffset(const CSSPoint& aScrollOffset)
{
mScrollOffset = aScrollOffset;
}
const CSSPoint& GetScrollOffset() const
{
return mScrollOffset;
}
void SetZoom(const CSSToScreenScale& aZoom)
{
mZoom = aZoom;
}
CSSToScreenScale GetZoom() const
{
return mZoom;
}
void SetScrollOffsetUpdated(uint32_t aScrollGeneration)
{
mUpdateScrollOffset = true;
mScrollGeneration = aScrollGeneration;
}
bool GetScrollOffsetUpdated() const
{
return mUpdateScrollOffset;
}
uint32_t GetScrollGeneration() const
{
return mScrollGeneration;
}
ViewID GetScrollId() const
{
return mScrollId;
}
void SetScrollId(ViewID scrollId)
{
mScrollId = scrollId;
}
ViewID GetScrollParentId() const
{
return mScrollParentId;
}
void SetScrollParentId(ViewID aParentId)
{
mScrollParentId = aParentId;
}
void SetRootCompositionSize(const CSSSize& aRootCompositionSize)
{
mRootCompositionSize = aRootCompositionSize;
}
const CSSSize& GetRootCompositionSize() const
{
return mRootCompositionSize;
}
void SetDisplayPortMargins(const LayerMargin& aDisplayPortMargins)
{
mDisplayPortMargins = aDisplayPortMargins;
}
const LayerMargin& GetDisplayPortMargins() const
{
return mDisplayPortMargins;
}
void SetUseDisplayPortMargins()
{
mUseDisplayPortMargins = true;
}
bool GetUseDisplayPortMargins() const
{
return mUseDisplayPortMargins;
}
uint32_t GetPresShellId() const
{
return mPresShellId;
}
void SetPresShellId(uint32_t aPresShellId)
{
mPresShellId = aPresShellId;
}
void SetViewport(const CSSRect& aViewport)
{
mViewport = aViewport;
}
const CSSRect& GetViewport() const
{
return mViewport;
}
const gfxRGBA& GetBackgroundColor() const
{
return mBackgroundColor;
}
void SetBackgroundColor(const gfxRGBA& aBackgroundColor)
{
mBackgroundColor = aBackgroundColor;
}
nsCString GetContentDescription() const
{
return nsCString(mContentDescription);
}
void SetContentDescription(const nsCString& aContentDescription)
{
strncpy(mContentDescription, aContentDescription.get(),
sizeof(mContentDescription));
mContentDescription[sizeof(mContentDescription) - 1] = 0;
}
private:
// New fields from now on should be made private and old fields should
// be refactored to be private.
// Whether or not this is the root scroll frame for the root content document.
bool mIsRoot;
// Whether or not this frame is for an element marked 'scrollgrab'.
bool mHasScrollgrab;
// A unique ID assigned to each scrollable frame.
ViewID mScrollId;
// The ViewID of the scrollable frame to which overscroll should be handed off.
ViewID mScrollParentId;
// The position of the top-left of the CSS viewport, relative to the document
// (or the document relative to the viewport, if that helps understand it).
//
// Thus it is relative to the document. It is in the same coordinate space as
// |mScrollableRect|, but a different coordinate space than |mViewport| and
// |mDisplayPort|.
//
// It is required that the rect:
// { x = mScrollOffset.x, y = mScrollOffset.y,
// width = mCompositionBounds.x / mResolution.scale,
// height = mCompositionBounds.y / mResolution.scale }
// Be within |mScrollableRect|.
//
// This is valid for any layer, but is always relative to this frame and
// not any parents, regardless of parent transforms.
CSSPoint mScrollOffset;
// The "user zoom". Content is painted by gecko at mResolution * mDevPixelsPerCSSPixel,
// but will be drawn to the screen at mZoom. In the steady state, the
// two will be the same, but during an async zoom action the two may
// diverge. This information is initialized in Gecko but updated in the APZC.
CSSToScreenScale mZoom;
// Whether mScrollOffset was updated by something other than the APZ code, and
// if the APZC receiving this metrics should update its local copy.
bool mUpdateScrollOffset;
// The scroll generation counter used to acknowledge the scroll offset update.
uint32_t mScrollGeneration;
// The size of the root scrollable's composition bounds, but in local CSS pixels.
CSSSize mRootCompositionSize;
// A display port expressed as layer margins that apply to the rect of what
// is drawn of the scrollable element.
LayerMargin mDisplayPortMargins;
// If this is true then we use the display port margins on this metrics,
// otherwise use the display port rect.
bool mUseDisplayPortMargins;
uint32_t mPresShellId;
// The CSS viewport, which is the dimensions we're using to constrain the
// <html> element of this frame, relative to the top-left of the layer. Note
// that its offset is structured in such a way that it doesn't depend on the
// method layout uses to scroll content.
//
// This is mainly useful on the root layer, however nested iframes can have
// their own viewport, which will just be the size of the window of the
// iframe. For layers that don't correspond to a document, this metric is
// meaningless and invalid.
CSSRect mViewport;
// The background color to use when overscrolling.
gfxRGBA mBackgroundColor;
// A description of the content element corresponding to this frame.
// This is empty unless this is a scrollable ContainerLayer and the
// apz.printtree pref is turned on.
char mContentDescription[20];
};
/**
* This class allows us to uniquely identify a scrollable layer. The
* mLayersId identifies the layer tree (corresponding to a child process
* and/or tab) that the scrollable layer belongs to. The mPresShellId
* is a temporal identifier (corresponding to the document loaded that
* contains the scrollable layer, which may change over time). The
* mScrollId corresponds to the actual frame that is scrollable.
*/
struct ScrollableLayerGuid {
uint64_t mLayersId;
uint32_t mPresShellId;
FrameMetrics::ViewID mScrollId;
ScrollableLayerGuid()
: mLayersId(0)
, mPresShellId(0)
, mScrollId(0)
{
MOZ_COUNT_CTOR(ScrollableLayerGuid);
}
ScrollableLayerGuid(uint64_t aLayersId, uint32_t aPresShellId,
FrameMetrics::ViewID aScrollId)
: mLayersId(aLayersId)
, mPresShellId(aPresShellId)
, mScrollId(aScrollId)
{
MOZ_COUNT_CTOR(ScrollableLayerGuid);
}
ScrollableLayerGuid(uint64_t aLayersId, const FrameMetrics& aMetrics)
: mLayersId(aLayersId)
, mPresShellId(aMetrics.GetPresShellId())
, mScrollId(aMetrics.GetScrollId())
{
MOZ_COUNT_CTOR(ScrollableLayerGuid);
}
ScrollableLayerGuid(const ScrollableLayerGuid& other)
: mLayersId(other.mLayersId)
, mPresShellId(other.mPresShellId)
, mScrollId(other.mScrollId)
{
MOZ_COUNT_CTOR(ScrollableLayerGuid);
}
~ScrollableLayerGuid()
{
MOZ_COUNT_DTOR(ScrollableLayerGuid);
}
bool operator==(const ScrollableLayerGuid& other) const
{
return mLayersId == other.mLayersId
&& mPresShellId == other.mPresShellId
&& mScrollId == other.mScrollId;
}
bool operator!=(const ScrollableLayerGuid& other) const
{
return !(*this == other);
}
bool operator<(const ScrollableLayerGuid& other) const
{
if (mLayersId < other.mLayersId) {
return true;
}
if (mLayersId == other.mLayersId) {
if (mPresShellId < other.mPresShellId) {
return true;
}
if (mPresShellId == other.mPresShellId) {
return mScrollId < other.mScrollId;
}
}
return false;
}
};
template <int LogLevel>
gfx::Log<LogLevel>& operator<<(gfx::Log<LogLevel>& log, const ScrollableLayerGuid& aGuid) {
return log << '(' << aGuid.mLayersId << ',' << aGuid.mPresShellId << ',' << aGuid.mScrollId << ')';
}
struct ZoomConstraints {
bool mAllowZoom;
bool mAllowDoubleTapZoom;
CSSToScreenScale mMinZoom;
CSSToScreenScale mMaxZoom;
ZoomConstraints()
: mAllowZoom(true)
, mAllowDoubleTapZoom(true)
{
MOZ_COUNT_CTOR(ZoomConstraints);
}
ZoomConstraints(bool aAllowZoom,
bool aAllowDoubleTapZoom,
const CSSToScreenScale& aMinZoom,
const CSSToScreenScale& aMaxZoom)
: mAllowZoom(aAllowZoom)
, mAllowDoubleTapZoom(aAllowDoubleTapZoom)
, mMinZoom(aMinZoom)
, mMaxZoom(aMaxZoom)
{
MOZ_COUNT_CTOR(ZoomConstraints);
}
ZoomConstraints(const ZoomConstraints& other)
: mAllowZoom(other.mAllowZoom)
, mAllowDoubleTapZoom(other.mAllowDoubleTapZoom)
, mMinZoom(other.mMinZoom)
, mMaxZoom(other.mMaxZoom)
{
MOZ_COUNT_CTOR(ZoomConstraints);
}
~ZoomConstraints()
{
MOZ_COUNT_DTOR(ZoomConstraints);
}
bool operator==(const ZoomConstraints& other) const
{
return mAllowZoom == other.mAllowZoom
&& mAllowDoubleTapZoom == other.mAllowDoubleTapZoom
&& mMinZoom == other.mMinZoom
&& mMaxZoom == other.mMaxZoom;
}
bool operator!=(const ZoomConstraints& other) const
{
return !(*this == other);
}
};
}
}
#endif /* GFX_FRAMEMETRICS_H */