gecko/gfx/thebes/gfxPattern.cpp
Avi Halachmi ad77774fb9 Bug 838758: Cache GradientStops instead of gfxPattern. r=jrmuizel
Our gfxPattern cache is currently way too specific, which causes lots of
unnecessary cache misses. The only thing that we actually need to key on is the
color stops.

This switches the cache to hold GradientStops instead of gfxPatterns. This
improves our cache hit rate and is simpler. It also avoids doing caching when
not using Azure, which currently has no benefit.

Average paint times results (in ms)
(on windows 7 x64, i7-3630qm, HD4000)
-------------------------------------
m-c
open: 3.5 close: 3.3

m-c cache-key
open: 2.6 close: 2.4

ux
open: 7.3 close: 5.2

ux cache-key
open: 6.9 close: 5.3
2013-02-15 20:54:49 +02:00

443 lines
12 KiB
C++

/* -*- Mode: C++; tab-width: 20; 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 "gfxTypes.h"
#include "gfxPattern.h"
#include "gfxASurface.h"
#include "gfxPlatform.h"
#include "cairo.h"
#include <vector>
using namespace mozilla::gfx;
gfxPattern::gfxPattern(cairo_pattern_t *aPattern)
: mGfxPattern(NULL)
{
mPattern = cairo_pattern_reference(aPattern);
}
gfxPattern::gfxPattern(const gfxRGBA& aColor)
: mGfxPattern(NULL)
{
mPattern = cairo_pattern_create_rgba(aColor.r, aColor.g, aColor.b, aColor.a);
}
// from another surface
gfxPattern::gfxPattern(gfxASurface *surface)
: mGfxPattern(NULL)
{
mPattern = cairo_pattern_create_for_surface(surface->CairoSurface());
}
// linear
gfxPattern::gfxPattern(gfxFloat x0, gfxFloat y0, gfxFloat x1, gfxFloat y1)
: mGfxPattern(NULL)
{
mPattern = cairo_pattern_create_linear(x0, y0, x1, y1);
}
// radial
gfxPattern::gfxPattern(gfxFloat cx0, gfxFloat cy0, gfxFloat radius0,
gfxFloat cx1, gfxFloat cy1, gfxFloat radius1)
: mGfxPattern(NULL)
{
mPattern = cairo_pattern_create_radial(cx0, cy0, radius0,
cx1, cy1, radius1);
}
// Azure
gfxPattern::gfxPattern(SourceSurface *aSurface, const Matrix &aTransform)
: mPattern(NULL)
, mGfxPattern(NULL)
, mSourceSurface(aSurface)
, mTransform(aTransform)
{
}
gfxPattern::~gfxPattern()
{
cairo_pattern_destroy(mPattern);
if (mGfxPattern) {
mGfxPattern->~Pattern();
}
}
cairo_pattern_t *
gfxPattern::CairoPattern()
{
return mPattern;
}
void
gfxPattern::AddColorStop(gfxFloat offset, const gfxRGBA& c)
{
if (mPattern) {
mStops = NULL;
if (gfxPlatform::GetCMSMode() == eCMSMode_All) {
gfxRGBA cms;
qcms_transform *transform = gfxPlatform::GetCMSRGBTransform();
if (transform)
gfxPlatform::TransformPixel(c, cms, transform);
// Use the original alpha to avoid unnecessary float->byte->float
// conversion errors
cairo_pattern_add_color_stop_rgba(mPattern, offset,
cms.r, cms.g, cms.b, c.a);
}
else
cairo_pattern_add_color_stop_rgba(mPattern, offset, c.r, c.g, c.b, c.a);
}
}
void
gfxPattern::SetColorStops(mozilla::RefPtr<mozilla::gfx::GradientStops> aStops)
{
mStops = aStops;
}
void
gfxPattern::SetMatrix(const gfxMatrix& matrix)
{
if (mPattern) {
cairo_matrix_t mat = *reinterpret_cast<const cairo_matrix_t*>(&matrix);
cairo_pattern_set_matrix(mPattern, &mat);
} else {
mTransform = ToMatrix(matrix);
// Cairo-pattern matrices specify the conversion from DrawTarget to pattern
// space. Azure pattern matrices specify the conversion from pattern to
// DrawTarget space.
mTransform.Invert();
}
}
gfxMatrix
gfxPattern::GetMatrix() const
{
if (mPattern) {
cairo_matrix_t mat;
cairo_pattern_get_matrix(mPattern, &mat);
return gfxMatrix(*reinterpret_cast<gfxMatrix*>(&mat));
} else {
return ThebesMatrix(mTransform);
}
}
Pattern*
gfxPattern::GetPattern(DrawTarget *aTarget, Matrix *aPatternTransform)
{
if (mGfxPattern) {
mGfxPattern->~Pattern();
mGfxPattern = nullptr;
}
if (!mPattern) {
mGfxPattern = new (mSurfacePattern.addr())
SurfacePattern(mSourceSurface, EXTEND_CLAMP, mTransform);
return mGfxPattern;
}
GraphicsExtend extend = (GraphicsExtend)cairo_pattern_get_extend(mPattern);
switch (cairo_pattern_get_type(mPattern)) {
case CAIRO_PATTERN_TYPE_SOLID:
{
double r, g, b, a;
cairo_pattern_get_rgba(mPattern, &r, &g, &b, &a);
new (mColorPattern.addr()) ColorPattern(Color(r, g, b, a));
return mColorPattern.addr();
}
case CAIRO_PATTERN_TYPE_SURFACE:
{
GraphicsFilter filter = (GraphicsFilter)cairo_pattern_get_filter(mPattern);
cairo_matrix_t mat;
cairo_pattern_get_matrix(mPattern, &mat);
gfxMatrix matrix(*reinterpret_cast<gfxMatrix*>(&mat));
cairo_surface_t *surf = NULL;
cairo_pattern_get_surface(mPattern, &surf);
if (!mSourceSurface) {
nsRefPtr<gfxASurface> gfxSurf = gfxASurface::Wrap(surf);
// The underlying surface here will be kept around by the gfxPattern.
// This function is intended to be used right away.
mSourceSurface =
gfxPlatform::GetPlatform()->GetSourceSurfaceForSurface(aTarget, gfxSurf);
}
if (mSourceSurface) {
Matrix newMat = ToMatrix(matrix);
AdjustTransformForPattern(newMat, aTarget->GetTransform(), aPatternTransform);
double x, y;
cairo_surface_get_device_offset(surf, &x, &y);
newMat.Translate(-x, -y);
mGfxPattern = new (mSurfacePattern.addr())
SurfacePattern(mSourceSurface, ToExtendMode(extend), newMat, ToFilter(filter));
return mGfxPattern;
}
break;
}
case CAIRO_PATTERN_TYPE_LINEAR:
{
double x1, y1, x2, y2;
cairo_pattern_get_linear_points(mPattern, &x1, &y1, &x2, &y2);
if (!mStops) {
int count = 0;
cairo_pattern_get_color_stop_count(mPattern, &count);
std::vector<GradientStop> stops;
for (int i = 0; i < count; i++) {
GradientStop stop;
double r, g, b, a, offset;
cairo_pattern_get_color_stop_rgba(mPattern, i, &offset, &r, &g, &b, &a);
stop.offset = offset;
stop.color = Color(Float(r), Float(g), Float(b), Float(a));
stops.push_back(stop);
}
mStops = aTarget->CreateGradientStops(&stops.front(), count, ToExtendMode(extend));
}
if (mStops) {
cairo_matrix_t mat;
cairo_pattern_get_matrix(mPattern, &mat);
gfxMatrix matrix(*reinterpret_cast<gfxMatrix*>(&mat));
Matrix newMat = ToMatrix(matrix);
AdjustTransformForPattern(newMat, aTarget->GetTransform(), aPatternTransform);
mGfxPattern = new (mLinearGradientPattern.addr())
LinearGradientPattern(Point(x1, y1), Point(x2, y2), mStops, newMat);
return mGfxPattern;
}
break;
}
case CAIRO_PATTERN_TYPE_RADIAL:
{
if (!mStops) {
int count = 0;
cairo_pattern_get_color_stop_count(mPattern, &count);
std::vector<GradientStop> stops;
for (int i = 0; i < count; i++) {
GradientStop stop;
double r, g, b, a, offset;
cairo_pattern_get_color_stop_rgba(mPattern, i, &offset, &r, &g, &b, &a);
stop.offset = offset;
stop.color = Color(Float(r), Float(g), Float(b), Float(a));
stops.push_back(stop);
}
mStops = aTarget->CreateGradientStops(&stops.front(), count, ToExtendMode(extend));
}
if (mStops) {
cairo_matrix_t mat;
cairo_pattern_get_matrix(mPattern, &mat);
gfxMatrix matrix(*reinterpret_cast<gfxMatrix*>(&mat));
Matrix newMat = ToMatrix(matrix);
AdjustTransformForPattern(newMat, aTarget->GetTransform(), aPatternTransform);
double x1, y1, x2, y2, r1, r2;
cairo_pattern_get_radial_circles(mPattern, &x1, &y1, &r1, &x2, &y2, &r2);
mGfxPattern = new (mRadialGradientPattern.addr())
RadialGradientPattern(Point(x1, y1), Point(x2, y2), r1, r2, mStops, newMat);
return mGfxPattern;
}
break;
}
default:
/* Reassure the compiler we are handling all the enum values. */
break;
}
new (mColorPattern.addr()) ColorPattern(Color(0, 0, 0, 0));
return mColorPattern.addr();
}
void
gfxPattern::SetExtend(GraphicsExtend extend)
{
if (mPattern) {
mStops = NULL;
if (extend == EXTEND_PAD_EDGE) {
if (cairo_pattern_get_type(mPattern) == CAIRO_PATTERN_TYPE_SURFACE) {
cairo_surface_t *surf = NULL;
cairo_pattern_get_surface (mPattern, &surf);
if (surf) {
switch (cairo_surface_get_type(surf)) {
case CAIRO_SURFACE_TYPE_WIN32_PRINTING:
case CAIRO_SURFACE_TYPE_QUARTZ:
extend = EXTEND_NONE;
break;
case CAIRO_SURFACE_TYPE_WIN32:
case CAIRO_SURFACE_TYPE_XLIB:
default:
extend = EXTEND_PAD;
break;
}
}
}
// if something went wrong, or not a surface pattern, use PAD
if (extend == EXTEND_PAD_EDGE)
extend = EXTEND_PAD;
}
cairo_pattern_set_extend(mPattern, (cairo_extend_t)extend);
} else {
// This is always a surface pattern and will default to EXTEND_PAD
// for EXTEND_PAD_EDGE.
mExtend = ToExtendMode(extend);
}
}
bool
gfxPattern::IsOpaque()
{
if (mPattern) {
switch (cairo_pattern_get_type(mPattern)) {
case CAIRO_PATTERN_TYPE_SURFACE:
{
cairo_surface_t *surf = NULL;
cairo_pattern_get_surface(mPattern, &surf);
if (cairo_surface_get_content(surf) == CAIRO_CONTENT_COLOR) {
return true;
}
}
default:
return false;
}
}
if (mSourceSurface->GetFormat() == FORMAT_B8G8R8X8) {
return true;
}
return false;
}
gfxPattern::GraphicsExtend
gfxPattern::Extend() const
{
if (mPattern) {
return (GraphicsExtend)cairo_pattern_get_extend(mPattern);
} else {
return ThebesExtend(mExtend);
}
}
void
gfxPattern::SetFilter(GraphicsFilter filter)
{
if (mPattern) {
cairo_pattern_set_filter(mPattern, (cairo_filter_t)filter);
} else {
mFilter = ToFilter(filter);
}
}
gfxPattern::GraphicsFilter
gfxPattern::Filter() const
{
if (mPattern) {
return (GraphicsFilter)cairo_pattern_get_filter(mPattern);
} else {
return ThebesFilter(mFilter);
}
}
bool
gfxPattern::GetSolidColor(gfxRGBA& aColor)
{
return cairo_pattern_get_rgba(mPattern,
&aColor.r,
&aColor.g,
&aColor.b,
&aColor.a) == CAIRO_STATUS_SUCCESS;
}
already_AddRefed<gfxASurface>
gfxPattern::GetSurface()
{
if (mPattern) {
cairo_surface_t *surf = nullptr;
if (cairo_pattern_get_surface (mPattern, &surf) != CAIRO_STATUS_SUCCESS)
return nullptr;
return gfxASurface::Wrap(surf);
} else {
// We should never be trying to get the surface off an Azure gfx Pattern.
NS_ERROR("Attempt to get surface off an Azure gfxPattern!");
return NULL;
}
}
gfxPattern::GraphicsPatternType
gfxPattern::GetType() const
{
if (mPattern) {
return (GraphicsPatternType) cairo_pattern_get_type(mPattern);
} else {
// We should never be trying to get the type off an Azure gfx Pattern.
MOZ_ASSERT(0);
return PATTERN_SURFACE;
}
}
int
gfxPattern::CairoStatus()
{
if (mPattern) {
return cairo_pattern_status(mPattern);
} else {
// An Azure pattern as this point is never in error status.
return CAIRO_STATUS_SUCCESS;
}
}
void
gfxPattern::AdjustTransformForPattern(Matrix &aPatternTransform,
const Matrix &aCurrentTransform,
const Matrix *aOriginalTransform)
{
aPatternTransform.Invert();
if (!aOriginalTransform) {
// User space is unchanged, so to get from pattern space to user space,
// just invert the cairo matrix.
aPatternTransform.NudgeToIntegers();
return;
}
// aPatternTransform now maps from pattern space to the user space defined
// by *aOriginalTransform.
Matrix mat = aCurrentTransform;
mat.Invert();
// mat maps from device space to current user space
// First, transform from pattern space to original user space. Then transform
// from original user space to device space. Then transform from
// device space to current user space.
aPatternTransform = aPatternTransform * *aOriginalTransform * mat;
aPatternTransform.NudgeToIntegers();
}