gecko/gfx/layers/basic/BasicLayerManager.cpp
Ehsan Akhgari 0fd9123eac Bug 579517 - Part 1: Automated conversion of NSPR numeric types to stdint types in Gecko; r=bsmedberg
This patch was generated by a script.  Here's the source of the script for
future reference:

function convert() {
echo "Converting $1 to $2..."
find . ! -wholename "*nsprpub*" \
       ! -wholename "*security/nss*" \
       ! -wholename "*/.hg*" \
       ! -wholename "obj-ff-dbg*" \
       ! -name nsXPCOMCID.h \
       ! -name prtypes.h \
         -type f \
      \( -iname "*.cpp" \
         -o -iname "*.h" \
         -o -iname "*.c" \
         -o -iname "*.cc" \
         -o -iname "*.idl" \
         -o -iname "*.ipdl" \
         -o -iname "*.ipdlh" \
         -o -iname "*.mm" \) | \
    xargs -n 1 sed -i -e "s/\b$1\b/$2/g"
}

convert PRInt8 int8_t
convert PRUint8 uint8_t
convert PRInt16 int16_t
convert PRUint16 uint16_t
convert PRInt32 int32_t
convert PRUint32 uint32_t
convert PRInt64 int64_t
convert PRUint64 uint64_t

convert PRIntn int
convert PRUintn unsigned

convert PRSize size_t

convert PROffset32 int32_t
convert PROffset64 int64_t

convert PRPtrdiff ptrdiff_t

convert PRFloat64 double
2012-08-22 11:56:38 -04:00

1220 lines
40 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/. */
#include "mozilla/layers/PLayerChild.h"
#include "mozilla/layers/PLayersChild.h"
#include "mozilla/layers/PLayersParent.h"
#include "gfxSharedImageSurface.h"
#include "gfxImageSurface.h"
#include "gfxUtils.h"
#include "gfxPlatform.h"
#include "nsXULAppAPI.h"
#include "RenderTrace.h"
#include "sampler.h"
#define PIXMAN_DONT_DEFINE_STDINT
#include "pixman.h"
#include "BasicTiledThebesLayer.h"
#include "BasicLayersImpl.h"
#include "BasicThebesLayer.h"
#include "BasicContainerLayer.h"
#include "mozilla/Preferences.h"
#include "nsIWidget.h"
using namespace mozilla::gfx;
namespace mozilla {
namespace layers {
/**
* Clips to the smallest device-pixel-aligned rectangle containing aRect
* in user space.
* Returns true if the clip is "perfect", i.e. we actually clipped exactly to
* aRect.
*/
static bool
ClipToContain(gfxContext* aContext, const nsIntRect& aRect)
{
gfxRect userRect(aRect.x, aRect.y, aRect.width, aRect.height);
gfxRect deviceRect = aContext->UserToDevice(userRect);
deviceRect.RoundOut();
gfxMatrix currentMatrix = aContext->CurrentMatrix();
aContext->IdentityMatrix();
aContext->NewPath();
aContext->Rectangle(deviceRect);
aContext->Clip();
aContext->SetMatrix(currentMatrix);
return aContext->DeviceToUser(deviceRect).IsEqualInterior(userRect);
}
already_AddRefed<gfxContext>
BasicLayerManager::PushGroupForLayer(gfxContext* aContext, Layer* aLayer,
const nsIntRegion& aRegion,
bool* aNeedsClipToVisibleRegion)
{
// If we need to call PushGroup, we should clip to the smallest possible
// area first to minimize the size of the temporary surface.
bool didCompleteClip = ClipToContain(aContext, aRegion.GetBounds());
nsRefPtr<gfxContext> result;
if (aLayer->CanUseOpaqueSurface() &&
((didCompleteClip && aRegion.GetNumRects() == 1) ||
!aContext->CurrentMatrix().HasNonIntegerTranslation())) {
// If the layer is opaque in its visible region we can push a CONTENT_COLOR
// group. We need to make sure that only pixels inside the layer's visible
// region are copied back to the destination. Remember if we've already
// clipped precisely to the visible region.
*aNeedsClipToVisibleRegion = !didCompleteClip || aRegion.GetNumRects() > 1;
result = PushGroupWithCachedSurface(aContext, gfxASurface::CONTENT_COLOR);
} else {
*aNeedsClipToVisibleRegion = false;
result = aContext;
if (aLayer->GetContentFlags() & Layer::CONTENT_COMPONENT_ALPHA) {
aContext->PushGroupAndCopyBackground(gfxASurface::CONTENT_COLOR_ALPHA);
} else {
aContext->PushGroup(gfxASurface::CONTENT_COLOR_ALPHA);
}
}
return result.forget();
}
static nsIntRect
ToOutsideIntRect(const gfxRect &aRect)
{
gfxRect r = aRect;
r.RoundOut();
return nsIntRect(r.X(), r.Y(), r.Width(), r.Height());
}
static nsIntRect
ToInsideIntRect(const gfxRect& aRect)
{
gfxRect r = aRect;
r.RoundIn();
return nsIntRect(r.X(), r.Y(), r.Width(), r.Height());
}
BasicLayerManager::BasicLayerManager(nsIWidget* aWidget) :
#ifdef DEBUG
mPhase(PHASE_NONE),
#endif
mWidget(aWidget)
, mDoubleBuffering(BUFFER_NONE), mUsingDefaultTarget(false)
, mCachedSurfaceInUse(false)
, mTransactionIncomplete(false)
{
MOZ_COUNT_CTOR(BasicLayerManager);
NS_ASSERTION(aWidget, "Must provide a widget");
}
BasicLayerManager::BasicLayerManager() :
#ifdef DEBUG
mPhase(PHASE_NONE),
#endif
mWidget(nullptr)
, mDoubleBuffering(BUFFER_NONE), mUsingDefaultTarget(false)
, mCachedSurfaceInUse(false)
, mTransactionIncomplete(false)
{
MOZ_COUNT_CTOR(BasicLayerManager);
}
BasicLayerManager::~BasicLayerManager()
{
NS_ASSERTION(!InTransaction(), "Died during transaction?");
ClearCachedResources();
mRoot = nullptr;
MOZ_COUNT_DTOR(BasicLayerManager);
}
void
BasicLayerManager::SetDefaultTarget(gfxContext* aContext)
{
NS_ASSERTION(!InTransaction(),
"Must set default target outside transaction");
mDefaultTarget = aContext;
}
void
BasicLayerManager::SetDefaultTargetConfiguration(BufferMode aDoubleBuffering, ScreenRotation aRotation)
{
mDoubleBuffering = aDoubleBuffering;
}
void
BasicLayerManager::BeginTransaction()
{
mInTransaction = true;
mUsingDefaultTarget = true;
BeginTransactionWithTarget(mDefaultTarget);
}
already_AddRefed<gfxContext>
BasicLayerManager::PushGroupWithCachedSurface(gfxContext *aTarget,
gfxASurface::gfxContentType aContent)
{
nsRefPtr<gfxContext> ctx;
// We can't cache Azure DrawTargets at this point.
if (!mCachedSurfaceInUse && aTarget->IsCairo()) {
gfxContextMatrixAutoSaveRestore saveMatrix(aTarget);
aTarget->IdentityMatrix();
nsRefPtr<gfxASurface> currentSurf = aTarget->CurrentSurface();
gfxRect clip = aTarget->GetClipExtents();
clip.RoundOut();
ctx = mCachedSurface.Get(aContent, clip, currentSurf);
if (ctx) {
mCachedSurfaceInUse = true;
/* Align our buffer for the original surface */
ctx->SetMatrix(saveMatrix.Matrix());
return ctx.forget();
}
}
ctx = aTarget;
ctx->PushGroup(aContent);
return ctx.forget();
}
void
BasicLayerManager::PopGroupToSourceWithCachedSurface(gfxContext *aTarget, gfxContext *aPushed)
{
if (!aTarget)
return;
nsRefPtr<gfxASurface> current = aPushed->CurrentSurface();
if (aTarget->IsCairo() && mCachedSurface.IsSurface(current)) {
gfxContextMatrixAutoSaveRestore saveMatrix(aTarget);
aTarget->IdentityMatrix();
aTarget->SetSource(current);
mCachedSurfaceInUse = false;
} else {
aTarget->PopGroupToSource();
}
}
void
BasicLayerManager::BeginTransactionWithTarget(gfxContext* aTarget)
{
mInTransaction = true;
#ifdef MOZ_LAYERS_HAVE_LOG
MOZ_LAYERS_LOG(("[----- BeginTransaction"));
Log();
#endif
NS_ASSERTION(!InTransaction(), "Nested transactions not allowed");
#ifdef DEBUG
mPhase = PHASE_CONSTRUCTION;
#endif
mTarget = aTarget;
}
static void
TransformIntRect(nsIntRect& aRect, const gfxMatrix& aMatrix,
nsIntRect (*aRoundMethod)(const gfxRect&))
{
gfxRect gr = gfxRect(aRect.x, aRect.y, aRect.width, aRect.height);
gr = aMatrix.TransformBounds(gr);
aRect = (*aRoundMethod)(gr);
}
/**
* This function assumes that GetEffectiveTransform transforms
* all layers to the same coordinate system (the "root coordinate system").
* It can't be used as is by accelerated layers because of intermediate surfaces.
* This must set the hidden flag to true or false on *all* layers in the subtree.
* It also sets the operator for all layers to "OVER", and call
* SetDrawAtomically(false).
* It clears mClipToVisibleRegion on all layers.
* @param aClipRect the cliprect, in the root coordinate system. We assume
* that any layer drawing is clipped to this rect. It is therefore not
* allowed to add to the opaque region outside that rect.
* @param aDirtyRect the dirty rect that will be painted, in the root
* coordinate system. Layers outside this rect should be hidden.
* @param aOpaqueRegion the opaque region covering aLayer, in the
* root coordinate system.
*/
enum {
ALLOW_OPAQUE = 0x01,
};
static void
MarkLayersHidden(Layer* aLayer, const nsIntRect& aClipRect,
const nsIntRect& aDirtyRect,
nsIntRegion& aOpaqueRegion,
uint32_t aFlags)
{
nsIntRect newClipRect(aClipRect);
uint32_t newFlags = aFlags;
// Allow aLayer or aLayer's descendants to cover underlying layers
// only if it's opaque.
if (aLayer->GetOpacity() != 1.0f) {
newFlags &= ~ALLOW_OPAQUE;
}
{
const nsIntRect* clipRect = aLayer->GetEffectiveClipRect();
if (clipRect) {
nsIntRect cr = *clipRect;
// clipRect is in the container's coordinate system. Get it into the
// global coordinate system.
if (aLayer->GetParent()) {
gfxMatrix tr;
if (aLayer->GetParent()->GetEffectiveTransform().CanDraw2D(&tr)) {
// Clip rect is applied after aLayer's transform, i.e., in the coordinate
// system of aLayer's parent.
TransformIntRect(cr, tr, ToInsideIntRect);
} else {
cr.SetRect(0, 0, 0, 0);
}
}
newClipRect.IntersectRect(newClipRect, cr);
}
}
BasicImplData* data = ToData(aLayer);
data->SetOperator(gfxContext::OPERATOR_OVER);
data->SetClipToVisibleRegion(false);
data->SetDrawAtomically(false);
if (!aLayer->AsContainerLayer()) {
gfxMatrix transform;
if (!aLayer->GetEffectiveTransform().CanDraw2D(&transform)) {
data->SetHidden(false);
return;
}
nsIntRegion region = aLayer->GetEffectiveVisibleRegion();
nsIntRect r = region.GetBounds();
TransformIntRect(r, transform, ToOutsideIntRect);
r.IntersectRect(r, aDirtyRect);
data->SetHidden(aOpaqueRegion.Contains(r));
// Allow aLayer to cover underlying layers only if aLayer's
// content is opaque
if ((aLayer->GetContentFlags() & Layer::CONTENT_OPAQUE) &&
(newFlags & ALLOW_OPAQUE)) {
nsIntRegionRectIterator it(region);
while (const nsIntRect* sr = it.Next()) {
r = *sr;
TransformIntRect(r, transform, ToInsideIntRect);
r.IntersectRect(r, newClipRect);
aOpaqueRegion.Or(aOpaqueRegion, r);
}
}
} else {
Layer* child = aLayer->GetLastChild();
bool allHidden = true;
for (; child; child = child->GetPrevSibling()) {
MarkLayersHidden(child, newClipRect, aDirtyRect, aOpaqueRegion, newFlags);
if (!ToData(child)->IsHidden()) {
allHidden = false;
}
}
data->SetHidden(allHidden);
}
}
/**
* This function assumes that GetEffectiveTransform transforms
* all layers to the same coordinate system (the "root coordinate system").
* MarkLayersHidden must be called before calling this.
* @param aVisibleRect the rectangle of aLayer that is visible (i.e. not
* clipped and in the dirty rect), in the root coordinate system.
*/
static void
ApplyDoubleBuffering(Layer* aLayer, const nsIntRect& aVisibleRect)
{
BasicImplData* data = ToData(aLayer);
if (data->IsHidden())
return;
nsIntRect newVisibleRect(aVisibleRect);
{
const nsIntRect* clipRect = aLayer->GetEffectiveClipRect();
if (clipRect) {
nsIntRect cr = *clipRect;
// clipRect is in the container's coordinate system. Get it into the
// global coordinate system.
if (aLayer->GetParent()) {
gfxMatrix tr;
if (aLayer->GetParent()->GetEffectiveTransform().CanDraw2D(&tr)) {
NS_ASSERTION(!tr.HasNonIntegerTranslation(),
"Parent can only have an integer translation");
cr += nsIntPoint(int32_t(tr.x0), int32_t(tr.y0));
} else {
NS_ERROR("Parent can only have an integer translation");
}
}
newVisibleRect.IntersectRect(newVisibleRect, cr);
}
}
BasicContainerLayer* container =
static_cast<BasicContainerLayer*>(aLayer->AsContainerLayer());
// Layers that act as their own backbuffers should be drawn to the destination
// using OPERATOR_SOURCE to ensure that alpha values in a transparent window
// are cleared. This can also be faster than OPERATOR_OVER.
if (!container) {
data->SetOperator(gfxContext::OPERATOR_SOURCE);
data->SetDrawAtomically(true);
} else {
if (container->UseIntermediateSurface() ||
!container->ChildrenPartitionVisibleRegion(newVisibleRect)) {
// We need to double-buffer this container.
data->SetOperator(gfxContext::OPERATOR_SOURCE);
container->ForceIntermediateSurface();
} else {
// Tell the children to clip to their visible regions so our assumption
// that they don't paint outside their visible regions is valid!
for (Layer* child = aLayer->GetFirstChild(); child;
child = child->GetNextSibling()) {
ToData(child)->SetClipToVisibleRegion(true);
ApplyDoubleBuffering(child, newVisibleRect);
}
}
}
}
void
BasicLayerManager::EndTransaction(DrawThebesLayerCallback aCallback,
void* aCallbackData,
EndTransactionFlags aFlags)
{
mInTransaction = false;
EndTransactionInternal(aCallback, aCallbackData, aFlags);
}
void
BasicLayerManager::AbortTransaction()
{
NS_ASSERTION(InConstruction(), "Should be in construction phase");
#ifdef DEBUG
mPhase = PHASE_NONE;
#endif
mUsingDefaultTarget = false;
mInTransaction = false;
}
bool
BasicLayerManager::EndTransactionInternal(DrawThebesLayerCallback aCallback,
void* aCallbackData,
EndTransactionFlags aFlags)
{
SAMPLE_LABEL("BasicLayerManager", "EndTranscationInternal");
#ifdef MOZ_LAYERS_HAVE_LOG
MOZ_LAYERS_LOG((" ----- (beginning paint)"));
Log();
#endif
NS_ASSERTION(InConstruction(), "Should be in construction phase");
#ifdef DEBUG
mPhase = PHASE_DRAWING;
#endif
Layer* aLayer = GetRoot();
RenderTraceLayers(aLayer, "FF00");
mTransactionIncomplete = false;
if (aFlags & END_NO_COMPOSITE) {
// TODO: We should really just set mTarget to null and make sure we can handle that further down the call chain
nsRefPtr<gfxASurface> surf = gfxPlatform::GetPlatform()->CreateOffscreenSurface(gfxIntSize(1, 1), gfxASurface::CONTENT_COLOR);
mTarget = new gfxContext(surf);
}
if (mTarget && mRoot && !(aFlags & END_NO_IMMEDIATE_REDRAW)) {
nsIntRect clipRect;
if (HasShadowManager()) {
// If this has a shadow manager, the clip extents of mTarget are meaningless.
// So instead just use the root layer's visible region bounds.
const nsIntRect& bounds = mRoot->GetVisibleRegion().GetBounds();
gfxRect deviceRect =
mTarget->UserToDevice(gfxRect(bounds.x, bounds.y, bounds.width, bounds.height));
clipRect = ToOutsideIntRect(deviceRect);
} else {
gfxContextMatrixAutoSaveRestore save(mTarget);
mTarget->SetMatrix(gfxMatrix());
clipRect = ToOutsideIntRect(mTarget->GetClipExtents());
}
// Need to do this before we call ApplyDoubleBuffering,
// which depends on correct effective transforms
mSnapEffectiveTransforms =
!(mTarget->GetFlags() & gfxContext::FLAG_DISABLE_SNAPPING);
mRoot->ComputeEffectiveTransforms(gfx3DMatrix::From2D(mTarget->CurrentMatrix()));
if (IsRetained()) {
nsIntRegion region;
MarkLayersHidden(mRoot, clipRect, clipRect, region, ALLOW_OPAQUE);
if (mUsingDefaultTarget && mDoubleBuffering != BUFFER_NONE) {
ApplyDoubleBuffering(mRoot, clipRect);
}
}
if (aFlags & END_NO_COMPOSITE) {
if (IsRetained()) {
// Clip the destination out so that we don't draw to it, and
// only end up validating ThebesLayers.
mTarget->Clip(gfxRect(0, 0, 0, 0));
PaintLayer(mTarget, mRoot, aCallback, aCallbackData, nullptr);
}
// If we're not retained, then don't composite means do nothing at all.
} else {
PaintLayer(mTarget, mRoot, aCallback, aCallbackData, nullptr);
if (mWidget) {
FlashWidgetUpdateArea(mTarget);
}
}
if (!mTransactionIncomplete) {
// Clear out target if we have a complete transaction.
mTarget = nullptr;
}
}
#ifdef MOZ_LAYERS_HAVE_LOG
Log();
MOZ_LAYERS_LOG(("]----- EndTransaction"));
#endif
#ifdef DEBUG
// Go back to the construction phase if the transaction isn't complete.
// Layout will update the layer tree and call EndTransaction().
mPhase = mTransactionIncomplete ? PHASE_CONSTRUCTION : PHASE_NONE;
#endif
if (!mTransactionIncomplete) {
// This is still valid if the transaction was incomplete.
mUsingDefaultTarget = false;
}
NS_ASSERTION(!aCallback || !mTransactionIncomplete,
"If callback is not null, transaction must be complete");
// XXX - We should probably assert here that for an incomplete transaction
// out target is the default target.
return !mTransactionIncomplete;
}
void
BasicLayerManager::FlashWidgetUpdateArea(gfxContext *aContext)
{
static bool sWidgetFlashingEnabled;
static bool sWidgetFlashingPrefCached = false;
if (!sWidgetFlashingPrefCached) {
sWidgetFlashingPrefCached = true;
mozilla::Preferences::AddBoolVarCache(&sWidgetFlashingEnabled,
"nglayout.debug.widget_update_flashing");
}
if (sWidgetFlashingEnabled) {
float r = float(rand()) / RAND_MAX;
float g = float(rand()) / RAND_MAX;
float b = float(rand()) / RAND_MAX;
aContext->SetColor(gfxRGBA(r, g, b, 0.2));
aContext->Paint();
}
}
bool
BasicLayerManager::EndEmptyTransaction(EndTransactionFlags aFlags)
{
mInTransaction = false;
if (!mRoot) {
return false;
}
return EndTransactionInternal(nullptr, nullptr, aFlags);
}
void
BasicLayerManager::SetRoot(Layer* aLayer)
{
NS_ASSERTION(aLayer, "Root can't be null");
NS_ASSERTION(aLayer->Manager() == this, "Wrong manager");
NS_ASSERTION(InConstruction(), "Only allowed in construction phase");
mRoot = aLayer;
}
static pixman_transform
Matrix3DToPixman(const gfx3DMatrix& aMatrix)
{
pixman_f_transform transform;
transform.m[0][0] = aMatrix._11;
transform.m[0][1] = aMatrix._21;
transform.m[0][2] = aMatrix._41;
transform.m[1][0] = aMatrix._12;
transform.m[1][1] = aMatrix._22;
transform.m[1][2] = aMatrix._42;
transform.m[2][0] = aMatrix._14;
transform.m[2][1] = aMatrix._24;
transform.m[2][2] = aMatrix._44;
pixman_transform result;
pixman_transform_from_pixman_f_transform(&result, &transform);
return result;
}
static void
PixmanTransform(const gfxImageSurface *aDest,
const gfxImageSurface *aSrc,
const gfx3DMatrix& aTransform,
gfxPoint aDestOffset)
{
gfxIntSize destSize = aDest->GetSize();
pixman_image_t* dest = pixman_image_create_bits(aDest->Format() == gfxASurface::ImageFormatARGB32 ? PIXMAN_a8r8g8b8 : PIXMAN_x8r8g8b8,
destSize.width,
destSize.height,
(uint32_t*)aDest->Data(),
aDest->Stride());
gfxIntSize srcSize = aSrc->GetSize();
pixman_image_t* src = pixman_image_create_bits(aSrc->Format() == gfxASurface::ImageFormatARGB32 ? PIXMAN_a8r8g8b8 : PIXMAN_x8r8g8b8,
srcSize.width,
srcSize.height,
(uint32_t*)aSrc->Data(),
aSrc->Stride());
NS_ABORT_IF_FALSE(src && dest, "Failed to create pixman images?");
pixman_transform pixTransform = Matrix3DToPixman(aTransform);
pixman_transform pixTransformInverted;
// If the transform is singular then nothing would be drawn anyway, return here
if (!pixman_transform_invert(&pixTransformInverted, &pixTransform)) {
return;
}
pixman_image_set_transform(src, &pixTransformInverted);
pixman_image_composite32(PIXMAN_OP_SRC,
src,
nullptr,
dest,
aDestOffset.x,
aDestOffset.y,
0,
0,
0,
0,
destSize.width,
destSize.height);
pixman_image_unref(dest);
pixman_image_unref(src);
}
/**
* Transform a surface using a gfx3DMatrix and blit to the destination if
* it is efficient to do so.
*
* @param aSource Source surface.
* @param aDest Desintation context.
* @param aBounds Area represented by aSource.
* @param aTransform Transformation matrix.
* @param aDrawOffset Location to draw returned surface on aDest.
* @param aDontBlit Never draw to aDest if this is true.
* @return Transformed surface, or nullptr if it has been drawn to aDest.
*/
static already_AddRefed<gfxASurface>
Transform3D(gfxASurface* aSource, gfxContext* aDest,
const gfxRect& aBounds, const gfx3DMatrix& aTransform,
gfxPoint& aDrawOffset, bool aDontBlit)
{
nsRefPtr<gfxImageSurface> sourceImage = aSource->GetAsImageSurface();
if (!sourceImage) {
sourceImage = new gfxImageSurface(gfxIntSize(aBounds.width, aBounds.height), gfxPlatform::GetPlatform()->OptimalFormatForContent(aSource->GetContentType()));
nsRefPtr<gfxContext> ctx = new gfxContext(sourceImage);
aSource->SetDeviceOffset(gfxPoint(0, 0));
ctx->SetSource(aSource);
ctx->SetOperator(gfxContext::OPERATOR_SOURCE);
ctx->Paint();
}
// Find the transformed rectangle of our layer.
gfxRect offsetRect = aTransform.TransformBounds(aBounds);
// Intersect the transformed layer with the destination rectangle.
// This is in device space since we have an identity transform set on aTarget.
gfxRect destRect = aDest->GetClipExtents();
destRect.IntersectRect(destRect, offsetRect);
// Create a surface the size of the transformed object.
nsRefPtr<gfxASurface> dest = aDest->CurrentSurface();
nsRefPtr<gfxImageSurface> destImage;
gfxPoint offset;
bool blitComplete;
if (!destImage || aDontBlit || !aDest->ClipContainsRect(destRect)) {
destImage = new gfxImageSurface(gfxIntSize(destRect.width, destRect.height),
gfxASurface::ImageFormatARGB32);
offset = destRect.TopLeft();
blitComplete = false;
} else {
offset = -dest->GetDeviceOffset();
blitComplete = true;
}
// Include a translation to the correct origin.
gfx3DMatrix translation = gfx3DMatrix::Translation(aBounds.x, aBounds.y, 0);
// Transform the content and offset it such that the content begins at the origin.
PixmanTransform(destImage, sourceImage, translation * aTransform, offset);
if (blitComplete) {
return nullptr;
}
// If we haven't actually drawn to aDest then return our temporary image so that
// the caller can do this.
aDrawOffset = destRect.TopLeft();
return destImage.forget();
}
void
BasicLayerManager::PaintLayer(gfxContext* aTarget,
Layer* aLayer,
DrawThebesLayerCallback aCallback,
void* aCallbackData,
ReadbackProcessor* aReadback)
{
RenderTraceScope trace("BasicLayerManager::PaintLayer", "707070");
const nsIntRect* clipRect = aLayer->GetEffectiveClipRect();
const gfx3DMatrix& effectiveTransform = aLayer->GetEffectiveTransform();
// aLayer might not be a container layer, but if so we take care not to use
// the container variable
BasicContainerLayer* container = static_cast<BasicContainerLayer*>(aLayer);
bool needsGroup = aLayer->GetFirstChild() &&
container->UseIntermediateSurface();
BasicImplData* data = ToData(aLayer);
bool needsClipToVisibleRegion =
data->GetClipToVisibleRegion() && !aLayer->AsThebesLayer();
NS_ASSERTION(needsGroup || !aLayer->GetFirstChild() ||
container->GetOperator() == gfxContext::OPERATOR_OVER,
"non-OVER operator should have forced UseIntermediateSurface");
NS_ASSERTION(!aLayer->GetFirstChild() || !aLayer->GetMaskLayer() ||
container->UseIntermediateSurface(),
"ContainerLayer with mask layer should force UseIntermediateSurface");
// If needsSaveRestore is false, we should still save and restore
// the CTM
bool needsSaveRestore = needsGroup || clipRect || needsClipToVisibleRegion;
gfxMatrix savedMatrix;
if (needsSaveRestore) {
aTarget->Save();
if (clipRect) {
aTarget->NewPath();
aTarget->Rectangle(gfxRect(clipRect->x, clipRect->y, clipRect->width, clipRect->height), true);
aTarget->Clip();
}
}
savedMatrix = aTarget->CurrentMatrix();
gfxMatrix transform;
// Will return an identity matrix for 3d transforms, and is handled separately below.
bool is2D = effectiveTransform.CanDraw2D(&transform);
NS_ABORT_IF_FALSE(is2D || needsGroup || !aLayer->GetFirstChild(), "Must PushGroup for 3d transforms!");
if (is2D) {
aTarget->SetMatrix(transform);
} else {
aTarget->SetMatrix(gfxMatrix());
}
const nsIntRegion& visibleRegion = aLayer->GetEffectiveVisibleRegion();
// If needsGroup is true, we'll clip to the visible region after we've popped the group
if (needsClipToVisibleRegion && !needsGroup) {
gfxUtils::ClipToRegion(aTarget, visibleRegion);
// Don't need to clip to visible region again
needsClipToVisibleRegion = false;
}
bool pushedTargetOpaqueRect = false;
nsRefPtr<gfxASurface> currentSurface = aTarget->CurrentSurface();
DrawTarget *dt = aTarget->GetDrawTarget();
const nsIntRect& bounds = visibleRegion.GetBounds();
if (is2D) {
if (aTarget->IsCairo()) {
const gfxRect& targetOpaqueRect = currentSurface->GetOpaqueRect();
// Try to annotate currentSurface with a region of pixels that have been
// (or will be) painted opaque, if no such region is currently set.
if (targetOpaqueRect.IsEmpty() && visibleRegion.GetNumRects() == 1 &&
(aLayer->GetContentFlags() & Layer::CONTENT_OPAQUE) &&
!transform.HasNonAxisAlignedTransform()) {
currentSurface->SetOpaqueRect(
aTarget->UserToDevice(gfxRect(bounds.x, bounds.y, bounds.width, bounds.height)));
pushedTargetOpaqueRect = true;
}
} else {
const IntRect& targetOpaqueRect = dt->GetOpaqueRect();
// Try to annotate currentSurface with a region of pixels that have been
// (or will be) painted opaque, if no such region is currently set.
if (targetOpaqueRect.IsEmpty() && visibleRegion.GetNumRects() == 1 &&
(aLayer->GetContentFlags() & Layer::CONTENT_OPAQUE) &&
!transform.HasNonAxisAlignedTransform()) {
gfx::Rect opaqueRect = dt->GetTransform().TransformBounds(
gfx::Rect(bounds.x, bounds.y, bounds.width, bounds.height));
opaqueRect.RoundIn();
IntRect intOpaqueRect;
if (opaqueRect.ToIntRect(&intOpaqueRect)) {
aTarget->GetDrawTarget()->SetOpaqueRect(intOpaqueRect);
pushedTargetOpaqueRect = true;
}
}
}
}
nsRefPtr<gfxContext> groupTarget;
nsRefPtr<gfxASurface> untransformedSurface;
bool clipIsEmpty = !aTarget || aTarget->GetClipExtents().IsEmpty();
if (!is2D && !clipIsEmpty) {
untransformedSurface =
gfxPlatform::GetPlatform()->CreateOffscreenSurface(gfxIntSize(bounds.width, bounds.height),
gfxASurface::CONTENT_COLOR_ALPHA);
if (!untransformedSurface) {
if (pushedTargetOpaqueRect) {
if (aTarget->IsCairo()) {
currentSurface->SetOpaqueRect(gfxRect(0, 0, 0, 0));
} else {
dt->SetOpaqueRect(IntRect());
}
}
NS_ASSERTION(needsSaveRestore, "Should always need to restore with 3d transforms!");
aTarget->Restore();
return;
}
untransformedSurface->SetDeviceOffset(gfxPoint(-bounds.x, -bounds.y));
groupTarget = new gfxContext(untransformedSurface);
} else if (needsGroup && !clipIsEmpty) {
groupTarget = PushGroupForLayer(aTarget, aLayer, aLayer->GetEffectiveVisibleRegion(),
&needsClipToVisibleRegion);
} else {
groupTarget = aTarget;
}
if (aLayer->GetFirstChild() &&
aLayer->GetMaskLayer() &&
HasShadowManager()) {
// 'paint' the mask so that it gets sent to the shadow layer tree
static_cast<BasicImplData*>(aLayer->GetMaskLayer()->ImplData())
->Paint(nullptr, nullptr);
}
/* Only paint ourself, or our children - This optimization relies on this! */
Layer* child = aLayer->GetFirstChild();
if (!child) {
#ifdef MOZ_LAYERS_HAVE_LOG
MOZ_LAYERS_LOG(("%s (0x%p) is covered: %i\n", __FUNCTION__,
(void*)aLayer, data->IsHidden()));
#endif
if (aLayer->AsThebesLayer()) {
data->PaintThebes(groupTarget,
aLayer->GetMaskLayer(),
aCallback, aCallbackData,
aReadback);
} else {
data->Paint(groupTarget, aLayer->GetMaskLayer());
}
} else {
ReadbackProcessor readback;
ContainerLayer* container = static_cast<ContainerLayer*>(aLayer);
if (IsRetained()) {
readback.BuildUpdates(container);
}
nsAutoTArray<Layer*, 12> children;
container->SortChildrenBy3DZOrder(children);
for (uint32_t i = 0; i < children.Length(); i++) {
PaintLayer(groupTarget, children.ElementAt(i), aCallback, aCallbackData, &readback);
if (mTransactionIncomplete)
break;
}
}
if (needsGroup) {
bool blitComplete = false;
if (is2D) {
PopGroupToSourceWithCachedSurface(aTarget, groupTarget);
} else {
// Temporary fast fix for bug 725886
// Revert these changes when 725886 is ready
if (!clipIsEmpty) {
NS_ABORT_IF_FALSE(untransformedSurface,
"We should always allocate an untransformed surface with 3d transforms!");
gfxPoint offset;
bool dontBlit = needsClipToVisibleRegion || mTransactionIncomplete ||
aLayer->GetEffectiveOpacity() != 1.0f;
#ifdef DEBUG
if (aLayer->GetDebugColorIndex() != 0) {
gfxRGBA color((aLayer->GetDebugColorIndex() & 1) ? 1.0 : 0.0,
(aLayer->GetDebugColorIndex() & 2) ? 1.0 : 0.0,
(aLayer->GetDebugColorIndex() & 4) ? 1.0 : 0.0,
1.0);
nsRefPtr<gfxContext> temp = new gfxContext(untransformedSurface);
temp->SetColor(color);
temp->Paint();
}
#endif
nsRefPtr<gfxASurface> result =
Transform3D(untransformedSurface, aTarget, bounds,
effectiveTransform, offset, dontBlit);
blitComplete = !result;
if (result) {
aTarget->SetSource(result, offset);
}
}
}
// If we're doing our own double-buffering, we need to avoid drawing
// the results of an incomplete transaction to the destination surface ---
// that could cause flicker. Double-buffering is implemented using a
// temporary surface for one or more container layers, so we need to stop
// those temporary surfaces from being composited to aTarget.
// ApplyDoubleBuffering guarantees that this container layer can't
// intersect any other leaf layers, so if the transaction is not yet marked
// incomplete, the contents of this container layer are the final contents
// for the window.
if (!mTransactionIncomplete && !blitComplete) {
if (needsClipToVisibleRegion) {
gfxUtils::ClipToRegion(aTarget, aLayer->GetEffectiveVisibleRegion());
}
AutoSetOperator setOperator(aTarget, container->GetOperator());
PaintWithMask(aTarget, aLayer->GetEffectiveOpacity(),
HasShadowManager() ? nullptr : aLayer->GetMaskLayer());
}
}
if (pushedTargetOpaqueRect) {
if (aTarget->IsCairo()) {
currentSurface->SetOpaqueRect(gfxRect(0, 0, 0, 0));
} else {
dt->SetOpaqueRect(IntRect());
}
}
if (needsSaveRestore) {
aTarget->Restore();
} else {
aTarget->SetMatrix(savedMatrix);
}
}
void
BasicLayerManager::ClearCachedResources()
{
if (mRoot) {
ClearLayer(mRoot);
}
mCachedSurface.Expire();
}
void
BasicLayerManager::ClearLayer(Layer* aLayer)
{
ToData(aLayer)->ClearCachedResources();
for (Layer* child = aLayer->GetFirstChild(); child;
child = child->GetNextSibling()) {
ClearLayer(child);
}
}
already_AddRefed<ReadbackLayer>
BasicLayerManager::CreateReadbackLayer()
{
NS_ASSERTION(InConstruction(), "Only allowed in construction phase");
nsRefPtr<ReadbackLayer> layer = new BasicReadbackLayer(this);
return layer.forget();
}
BasicShadowLayerManager::BasicShadowLayerManager(nsIWidget* aWidget) :
BasicLayerManager(aWidget), mTargetRotation(ROTATION_0),
mRepeatTransaction(false)
{
MOZ_COUNT_CTOR(BasicShadowLayerManager);
}
BasicShadowLayerManager::~BasicShadowLayerManager()
{
MOZ_COUNT_DTOR(BasicShadowLayerManager);
}
int32_t
BasicShadowLayerManager::GetMaxTextureSize() const
{
if (HasShadowManager()) {
return ShadowLayerForwarder::GetMaxTextureSize();
}
return PR_INT32_MAX;
}
void
BasicShadowLayerManager::SetDefaultTargetConfiguration(BufferMode aDoubleBuffering, ScreenRotation aRotation)
{
BasicLayerManager::SetDefaultTargetConfiguration(aDoubleBuffering, aRotation);
mTargetRotation = aRotation;
if (mWidget) {
mTargetBounds = mWidget->GetNaturalBounds();
}
}
void
BasicShadowLayerManager::SetRoot(Layer* aLayer)
{
if (mRoot != aLayer) {
if (HasShadowManager()) {
// Have to hold the old root and its children in order to
// maintain the same view of the layer tree in this process as
// the parent sees. Otherwise layers can be destroyed
// mid-transaction and bad things can happen (v. bug 612573)
if (mRoot) {
Hold(mRoot);
}
ShadowLayerForwarder::SetRoot(Hold(aLayer));
}
BasicLayerManager::SetRoot(aLayer);
}
}
void
BasicShadowLayerManager::Mutated(Layer* aLayer)
{
BasicLayerManager::Mutated(aLayer);
NS_ASSERTION(InConstruction() || InDrawing(), "wrong phase");
if (HasShadowManager() && ShouldShadow(aLayer)) {
ShadowLayerForwarder::Mutated(Hold(aLayer));
}
}
void
BasicShadowLayerManager::BeginTransactionWithTarget(gfxContext* aTarget)
{
NS_ABORT_IF_FALSE(mKeepAlive.IsEmpty(), "uncommitted txn?");
nsRefPtr<gfxContext> targetContext = aTarget;
// If the last transaction was incomplete (a failed DoEmptyTransaction),
// don't signal a new transaction to ShadowLayerForwarder. Carry on adding
// to the previous transaction.
if (HasShadowManager()) {
ShadowLayerForwarder::BeginTransaction(mTargetBounds, mTargetRotation);
// If we have a non-default target, we need to let our shadow manager draw
// to it. This will happen at the end of the transaction.
if (aTarget && (aTarget != mDefaultTarget) &&
XRE_GetProcessType() == GeckoProcessType_Default) {
mShadowTarget = aTarget;
// Create a temporary target for ourselves, so that mShadowTarget is only
// drawn to by our shadow manager.
nsRefPtr<gfxASurface> targetSurface = gfxPlatform::GetPlatform()->
CreateOffscreenSurface(aTarget->OriginalSurface()->GetSize(),
aTarget->OriginalSurface()->GetContentType());
targetContext = new gfxContext(targetSurface);
}
}
BasicLayerManager::BeginTransactionWithTarget(aTarget);
}
void
BasicShadowLayerManager::EndTransaction(DrawThebesLayerCallback aCallback,
void* aCallbackData,
EndTransactionFlags aFlags)
{
BasicLayerManager::EndTransaction(aCallback, aCallbackData, aFlags);
ForwardTransaction();
if (mRepeatTransaction) {
mRepeatTransaction = false;
BasicLayerManager::BeginTransaction();
BasicShadowLayerManager::EndTransaction(aCallback, aCallbackData, aFlags);
} else if (mShadowTarget) {
// Draw to shadow target at the recursion tail of the repeat transactions
ShadowLayerForwarder::ShadowDrawToTarget(mShadowTarget);
mShadowTarget = nullptr;
}
}
bool
BasicShadowLayerManager::EndEmptyTransaction(EndTransactionFlags aFlags)
{
if (!BasicLayerManager::EndEmptyTransaction(aFlags)) {
// Return without calling ForwardTransaction. This leaves the
// ShadowLayerForwarder transaction open; the following
// EndTransaction will complete it.
return false;
}
ForwardTransaction();
return true;
}
void
BasicShadowLayerManager::ForwardTransaction()
{
RenderTraceScope rendertrace("Foward Transaction", "000090");
#ifdef DEBUG
mPhase = PHASE_FORWARD;
#endif
// forward this transaction's changeset to our ShadowLayerManager
AutoInfallibleTArray<EditReply, 10> replies;
if (HasShadowManager() && ShadowLayerForwarder::EndTransaction(&replies)) {
for (nsTArray<EditReply>::size_type i = 0; i < replies.Length(); ++i) {
const EditReply& reply = replies[i];
switch (reply.type()) {
case EditReply::TOpThebesBufferSwap: {
MOZ_LAYERS_LOG(("[LayersForwarder] ThebesBufferSwap"));
const OpThebesBufferSwap& obs = reply.get_OpThebesBufferSwap();
BasicShadowableThebesLayer* thebes = GetBasicShadowable(obs)->AsThebes();
thebes->SetBackBufferAndAttrs(
obs.newBackBuffer(), obs.newValidRegion(),
obs.readOnlyFrontBuffer(), obs.frontUpdatedRegion());
break;
}
case EditReply::TOpBufferSwap: {
MOZ_LAYERS_LOG(("[LayersForwarder] BufferSwap"));
const OpBufferSwap& obs = reply.get_OpBufferSwap();
const CanvasSurface& newBack = obs.newBackBuffer();
if (newBack.type() == CanvasSurface::TSurfaceDescriptor) {
GetBasicShadowable(obs)->SetBackBuffer(newBack.get_SurfaceDescriptor());
} else if (newBack.type() == CanvasSurface::Tnull_t) {
GetBasicShadowable(obs)->SetBackBuffer(SurfaceDescriptor());
} else {
NS_RUNTIMEABORT("Unknown back image type");
}
break;
}
case EditReply::TOpImageSwap: {
MOZ_LAYERS_LOG(("[LayersForwarder] YUVBufferSwap"));
const OpImageSwap& ois = reply.get_OpImageSwap();
BasicShadowableLayer* layer = GetBasicShadowable(ois);
const SharedImage& newBack = ois.newBackImage();
if (newBack.type() == SharedImage::TSurfaceDescriptor) {
layer->SetBackBuffer(newBack.get_SurfaceDescriptor());
} else if (newBack.type() == SharedImage::TYUVImage) {
const YUVImage& yuv = newBack.get_YUVImage();
layer->SetBackBufferYUVImage(yuv.Ydata(), yuv.Udata(), yuv.Vdata());
} else {
layer->SetBackBuffer(SurfaceDescriptor());
layer->SetBackBufferYUVImage(SurfaceDescriptor(),
SurfaceDescriptor(),
SurfaceDescriptor());
}
break;
}
default:
NS_RUNTIMEABORT("not reached");
}
}
} else if (HasShadowManager()) {
NS_WARNING("failed to forward Layers transaction");
}
#ifdef DEBUG
mPhase = PHASE_NONE;
#endif
// this may result in Layers being deleted, which results in
// PLayer::Send__delete__() and DeallocShmem()
mKeepAlive.Clear();
}
ShadowableLayer*
BasicShadowLayerManager::Hold(Layer* aLayer)
{
NS_ABORT_IF_FALSE(HasShadowManager(),
"top-level tree, no shadow tree to remote to");
ShadowableLayer* shadowable = ToShadowable(aLayer);
NS_ABORT_IF_FALSE(shadowable, "trying to remote an unshadowable layer");
mKeepAlive.AppendElement(aLayer);
return shadowable;
}
bool
BasicShadowLayerManager::IsCompositingCheap()
{
// Whether compositing is cheap depends on the parent backend.
return mShadowManager &&
LayerManager::IsCompositingCheap(GetParentBackendType());
}
void
BasicShadowLayerManager::SetIsFirstPaint()
{
ShadowLayerForwarder::SetIsFirstPaint();
}
already_AddRefed<ThebesLayer>
BasicShadowLayerManager::CreateThebesLayer()
{
NS_ASSERTION(InConstruction(), "Only allowed in construction phase");
#ifdef FORCE_BASICTILEDTHEBESLAYER
if (HasShadowManager() && GetParentBackendType() == LAYERS_OPENGL) {
// BasicTiledThebesLayer doesn't support main
// thread compositing so only return this layer
// type if we have a shadow manager.
nsRefPtr<BasicTiledThebesLayer> layer =
new BasicTiledThebesLayer(this);
MAYBE_CREATE_SHADOW(Thebes);
return layer.forget();
} else
#endif
{
nsRefPtr<BasicShadowableThebesLayer> layer =
new BasicShadowableThebesLayer(this);
MAYBE_CREATE_SHADOW(Thebes);
return layer.forget();
}
}
BasicShadowableLayer::~BasicShadowableLayer()
{
if (HasShadow()) {
PLayerChild::Send__delete__(GetShadow());
}
MOZ_COUNT_DTOR(BasicShadowableLayer);
}
}
}