gecko/gfx/thebes/gfxXlibNativeRenderer.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

614 lines
23 KiB
C++

/* -*- Mode: C++; tab-width: 20; indent-tabs-mode: nil; c-basic-offset: 4 -*-
* 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 "gfxXlibNativeRenderer.h"
#include "gfxXlibSurface.h"
#include "gfxImageSurface.h"
#include "gfxContext.h"
#include "gfxAlphaRecovery.h"
#include "cairo-xlib.h"
#include "cairo-xlib-xrender.h"
#if 0
#include <stdio.h>
#define NATIVE_DRAWING_NOTE(m) fprintf(stderr, m)
#else
#define NATIVE_DRAWING_NOTE(m) do {} while (0)
#endif
/* We have four basic strategies available:
1) 'direct': If the target is an xlib surface, and other conditions are met,
we can pass the underlying drawable directly to the callback.
2) 'simple': If the drawing is opaque, or we can draw to a surface with an
alpha channel, then we can create a temporary xlib surface, pass its
underlying drawable to the callback, and composite the result using
cairo.
3) 'copy-background': If the drawing is not opaque but the target is
opaque, and we can draw to a surface with format such that pixel
conversion to and from the target format is exact, we can create a
temporary xlib surface, copy the background from the target, pass the
underlying drawable to the callback, and copy back to the target.
This strategy is not used if the pixel format conversion is not exact,
because that would mean that drawing intended to be very transparent
messes with other content.
The strategy is prefered over simple for non-opaque drawing and opaque
targets on the same screen as compositing without alpha is a simpler
operation.
4) 'alpha-extraction': create a temporary xlib surface, fill with black,
pass its underlying drawable to the callback, copy the results to a
cairo image surface, repeat with a white background, update the on-black
image alpha values by comparing the two images, then paint the on-black
image using cairo.
Sure would be nice to have an X extension or GL to do this for us on the
server...
*/
static cairo_bool_t
_convert_coord_to_int (double coord, int32_t *v)
{
*v = (int32_t)coord;
/* XXX allow some tolerance here? */
return *v == coord;
}
static bool
_get_rectangular_clip (cairo_t *cr,
const nsIntRect& bounds,
bool *need_clip,
nsIntRect *rectangles, int max_rectangles,
int *num_rectangles)
{
cairo_rectangle_list_t *cliplist;
cairo_rectangle_t *clips;
int i;
bool retval = true;
cliplist = cairo_copy_clip_rectangle_list (cr);
if (cliplist->status != CAIRO_STATUS_SUCCESS) {
retval = false;
NATIVE_DRAWING_NOTE("FALLBACK: non-rectangular clip");
goto FINISH;
}
/* the clip is always in surface backend coordinates (i.e. native backend coords) */
clips = cliplist->rectangles;
for (i = 0; i < cliplist->num_rectangles; ++i) {
nsIntRect rect;
if (!_convert_coord_to_int (clips[i].x, &rect.x) ||
!_convert_coord_to_int (clips[i].y, &rect.y) ||
!_convert_coord_to_int (clips[i].width, &rect.width) ||
!_convert_coord_to_int (clips[i].height, &rect.height))
{
retval = false;
NATIVE_DRAWING_NOTE("FALLBACK: non-integer clip");
goto FINISH;
}
if (rect.IsEqualInterior(bounds)) {
/* the bounds are entirely inside the clip region so we don't need to clip. */
*need_clip = false;
goto FINISH;
}
NS_ASSERTION(bounds.Contains(rect),
"Was expecting to be clipped to bounds");
if (i >= max_rectangles) {
retval = false;
NATIVE_DRAWING_NOTE("FALLBACK: unsupported clip rectangle count");
goto FINISH;
}
rectangles[i] = rect;
}
*need_clip = true;
*num_rectangles = cliplist->num_rectangles;
FINISH:
cairo_rectangle_list_destroy (cliplist);
return retval;
}
#define MAX_STATIC_CLIP_RECTANGLES 50
/**
* Try the direct path.
* @return True if we took the direct path
*/
bool
gfxXlibNativeRenderer::DrawDirect(gfxContext *ctx, nsIntSize size,
uint32_t flags,
Screen *screen, Visual *visual)
{
cairo_t *cr = ctx->GetCairo();
/* Check that the target surface is an xlib surface. */
cairo_surface_t *target = cairo_get_group_target (cr);
if (cairo_surface_get_type (target) != CAIRO_SURFACE_TYPE_XLIB) {
NATIVE_DRAWING_NOTE("FALLBACK: non-X surface");
return false;
}
cairo_matrix_t matrix;
cairo_get_matrix (cr, &matrix);
double device_offset_x, device_offset_y;
cairo_surface_get_device_offset (target, &device_offset_x, &device_offset_y);
/* Draw() checked that the matrix contained only a very-close-to-integer
translation. Here (and in several other places and thebes) device
offsets are assumed to be integer. */
NS_ASSERTION(int32_t(device_offset_x) == device_offset_x &&
int32_t(device_offset_y) == device_offset_y,
"Expected integer device offsets");
nsIntPoint offset(NS_lroundf(matrix.x0 + device_offset_x),
NS_lroundf(matrix.y0 + device_offset_y));
int max_rectangles = 0;
if (flags & DRAW_SUPPORTS_CLIP_RECT) {
max_rectangles = 1;
}
if (flags & DRAW_SUPPORTS_CLIP_LIST) {
max_rectangles = MAX_STATIC_CLIP_RECTANGLES;
}
/* The client won't draw outside the surface so consider this when
analysing clip rectangles. */
nsIntRect bounds(offset, size);
bounds.IntersectRect(bounds,
nsIntRect(0, 0,
cairo_xlib_surface_get_width(target),
cairo_xlib_surface_get_height(target)));
bool needs_clip = true;
nsIntRect rectangles[MAX_STATIC_CLIP_RECTANGLES];
int rect_count = 0;
/* Check that the clip is rectangular and aligned on unit boundaries. */
/* Temporarily set the matrix for _get_rectangular_clip. It's basically
the identity matrix, but we must adjust for the fact that our
offset-rect is in device coordinates. */
cairo_identity_matrix (cr);
cairo_translate (cr, -device_offset_x, -device_offset_y);
bool have_rectangular_clip =
_get_rectangular_clip (cr, bounds, &needs_clip,
rectangles, max_rectangles, &rect_count);
cairo_set_matrix (cr, &matrix);
if (!have_rectangular_clip)
return false;
/* Stop now if everything is clipped out */
if (needs_clip && rect_count == 0)
return true;
/* Check that the screen is supported.
Visuals belong to screens, so, if alternate visuals are not supported,
then alternate screens cannot be supported. */
bool supports_alternate_visual =
(flags & DRAW_SUPPORTS_ALTERNATE_VISUAL) != 0;
bool supports_alternate_screen = supports_alternate_visual &&
(flags & DRAW_SUPPORTS_ALTERNATE_SCREEN);
if (!supports_alternate_screen &&
cairo_xlib_surface_get_screen (target) != screen) {
NATIVE_DRAWING_NOTE("FALLBACK: non-default screen");
return false;
}
/* Check that there is a visual */
Visual *target_visual = cairo_xlib_surface_get_visual (target);
if (!target_visual) {
NATIVE_DRAWING_NOTE("FALLBACK: no Visual for surface");
return false;
}
/* Check that the visual is supported */
if (!supports_alternate_visual && target_visual != visual) {
// Only the format of the visual is important (not the GLX properties)
// for Xlib or XRender drawing.
XRenderPictFormat *target_format =
cairo_xlib_surface_get_xrender_format (target);
if (!target_format ||
(target_format !=
XRenderFindVisualFormat (DisplayOfScreen(screen), visual))) {
NATIVE_DRAWING_NOTE("FALLBACK: unsupported Visual");
return false;
}
}
/* we're good to go! */
NATIVE_DRAWING_NOTE("TAKING FAST PATH\n");
cairo_surface_flush (target);
nsRefPtr<gfxASurface> surface = gfxASurface::Wrap(target);
nsresult rv = DrawWithXlib(static_cast<gfxXlibSurface*>(surface.get()),
offset, rectangles,
needs_clip ? rect_count : 0);
if (NS_SUCCEEDED(rv)) {
cairo_surface_mark_dirty (target);
return true;
}
return false;
}
static bool
VisualHasAlpha(Screen *screen, Visual *visual) {
// There may be some other visuals format with alpha but usually this is
// the only one we care about.
return visual->c_class == TrueColor &&
visual->bits_per_rgb == 8 &&
visual->red_mask == 0xff0000 &&
visual->green_mask == 0xff00 &&
visual->blue_mask == 0xff &&
gfxXlibSurface::DepthOfVisual(screen, visual) == 32;
}
// Returns whether pixel conversion between visual and format is exact (in
// both directions).
static bool
FormatConversionIsExact(Screen *screen, Visual *visual, XRenderPictFormat *format) {
if (!format ||
visual->c_class != TrueColor ||
format->type != PictTypeDirect ||
gfxXlibSurface::DepthOfVisual(screen, visual) != format->depth)
return false;
XRenderPictFormat *visualFormat =
XRenderFindVisualFormat(DisplayOfScreen(screen), visual);
if (visualFormat->type != PictTypeDirect )
return false;
const XRenderDirectFormat& a = visualFormat->direct;
const XRenderDirectFormat& b = format->direct;
return a.redMask == b.redMask &&
a.greenMask == b.greenMask &&
a.blueMask == b.blueMask;
}
// The 3 non-direct strategies described above.
// The surface format and strategy are inter-dependent.
enum DrawingMethod {
eSimple,
eCopyBackground,
eAlphaExtraction
};
static already_AddRefed<gfxXlibSurface>
CreateTempXlibSurface (gfxASurface *destination, nsIntSize size,
bool canDrawOverBackground,
uint32_t flags, Screen *screen, Visual *visual,
DrawingMethod *method)
{
bool drawIsOpaque = (flags & gfxXlibNativeRenderer::DRAW_IS_OPAQUE) != 0;
bool supportsAlternateVisual =
(flags & gfxXlibNativeRenderer::DRAW_SUPPORTS_ALTERNATE_VISUAL) != 0;
bool supportsAlternateScreen = supportsAlternateVisual &&
(flags & gfxXlibNativeRenderer::DRAW_SUPPORTS_ALTERNATE_SCREEN);
cairo_surface_t *target = destination->CairoSurface();
cairo_surface_type_t target_type = cairo_surface_get_type (target);
cairo_content_t target_content = cairo_surface_get_content (target);
Screen *target_screen = target_type == CAIRO_SURFACE_TYPE_XLIB ?
cairo_xlib_surface_get_screen (target) : screen;
// When the background has an alpha channel, we need to draw with an alpha
// channel anyway, so there is no need to copy the background. If
// doCopyBackground is set here, we'll also need to check below that the
// background can copied without any loss in format conversions.
bool doCopyBackground = !drawIsOpaque && canDrawOverBackground &&
target_content == CAIRO_CONTENT_COLOR;
if (supportsAlternateScreen && screen != target_screen && drawIsOpaque) {
// Prefer a visual on the target screen.
// (If !drawIsOpaque, we'll need doCopyBackground or an alpha channel.)
visual = DefaultVisualOfScreen(target_screen);
screen = target_screen;
} else if (doCopyBackground || (supportsAlternateVisual && drawIsOpaque)) {
// Analyse the pixel formats either to check whether we can
// doCopyBackground or to see if we can find a better visual for
// opaque drawing.
Visual *target_visual = NULL;
XRenderPictFormat *target_format = NULL;
switch (target_type) {
case CAIRO_SURFACE_TYPE_XLIB:
target_visual = cairo_xlib_surface_get_visual (target);
target_format = cairo_xlib_surface_get_xrender_format (target);
break;
case CAIRO_SURFACE_TYPE_IMAGE: {
gfxASurface::gfxImageFormat imageFormat =
static_cast<gfxImageSurface*>(destination)->Format();
target_visual = gfxXlibSurface::FindVisual(screen, imageFormat);
Display *dpy = DisplayOfScreen(screen);
if (target_visual) {
target_format = XRenderFindVisualFormat(dpy, target_visual);
} else {
target_format =
gfxXlibSurface::FindRenderFormat(dpy, imageFormat);
}
break;
}
default:
break;
}
if (supportsAlternateVisual &&
(supportsAlternateScreen || screen == target_screen)) {
if (target_visual) {
visual = target_visual;
screen = target_screen;
}
}
// Could try harder to match formats across screens for background
// copying when !supportsAlternateScreen, if we cared. Preferably
// we'll find a visual below with an alpha channel anyway; if so, the
// background won't need to be copied.
if (doCopyBackground && visual != target_visual &&
!FormatConversionIsExact(screen, visual, target_format)) {
doCopyBackground = false;
}
}
if (supportsAlternateVisual && !drawIsOpaque &&
(screen != target_screen ||
!(doCopyBackground || VisualHasAlpha(screen, visual)))) {
// Try to find a visual with an alpha channel.
Screen *visualScreen =
supportsAlternateScreen ? target_screen : screen;
Visual *argbVisual =
gfxXlibSurface::FindVisual(visualScreen,
gfxASurface::ImageFormatARGB32);
if (argbVisual) {
visual = argbVisual;
screen = visualScreen;
} else if (!doCopyBackground &&
gfxXlibSurface::DepthOfVisual(screen, visual) != 24) {
// Will need to do alpha extraction; prefer a 24-bit visual.
// No advantage in using the target screen.
Visual *rgb24Visual =
gfxXlibSurface::FindVisual(screen,
gfxASurface::ImageFormatRGB24);
if (rgb24Visual) {
visual = rgb24Visual;
}
}
}
Drawable drawable =
(screen == target_screen && target_type == CAIRO_SURFACE_TYPE_XLIB) ?
cairo_xlib_surface_get_drawable (target) : RootWindowOfScreen(screen);
nsRefPtr<gfxXlibSurface> surface =
gfxXlibSurface::Create(screen, visual,
gfxIntSize(size.width, size.height),
drawable);
if (drawIsOpaque ||
surface->GetContentType() == gfxASurface::CONTENT_COLOR_ALPHA) {
NATIVE_DRAWING_NOTE(drawIsOpaque ?
", SIMPLE OPAQUE\n" : ", SIMPLE WITH ALPHA");
*method = eSimple;
} else if (doCopyBackground) {
NATIVE_DRAWING_NOTE(", COPY BACKGROUND\n");
*method = eCopyBackground;
} else {
NATIVE_DRAWING_NOTE(", SLOW ALPHA EXTRACTION\n");
*method = eAlphaExtraction;
}
return surface.forget();
}
bool
gfxXlibNativeRenderer::DrawOntoTempSurface(gfxXlibSurface *tempXlibSurface,
nsIntPoint offset)
{
tempXlibSurface->Flush();
/* no clipping is needed because the callback can't draw outside the native
surface anyway */
nsresult rv = DrawWithXlib(tempXlibSurface, offset, NULL, 0);
tempXlibSurface->MarkDirty();
return NS_SUCCEEDED(rv);
}
static already_AddRefed<gfxImageSurface>
CopyXlibSurfaceToImage(gfxXlibSurface *tempXlibSurface,
gfxASurface::gfxImageFormat format)
{
nsRefPtr<gfxImageSurface> result =
new gfxImageSurface(tempXlibSurface->GetSize(), format);
gfxContext copyCtx(result);
copyCtx.SetSource(tempXlibSurface);
copyCtx.SetOperator(gfxContext::OPERATOR_SOURCE);
copyCtx.Paint();
return result.forget();
}
void
gfxXlibNativeRenderer::Draw(gfxContext* ctx, nsIntSize size,
uint32_t flags, Screen *screen, Visual *visual,
DrawOutput* result)
{
if (result) {
result->mSurface = NULL;
result->mUniformAlpha = false;
result->mUniformColor = false;
}
bool drawIsOpaque = (flags & DRAW_IS_OPAQUE) != 0;
gfxMatrix matrix = ctx->CurrentMatrix();
// We can only draw direct or onto a copied background if pixels align and
// native drawing is compatible with the current operator. (The matrix is
// actually also pixel-exact for flips and right-angle rotations, which
// would permit copying the background but not drawing direct.)
bool matrixIsIntegerTranslation = !matrix.HasNonIntegerTranslation();
bool canDrawOverBackground = matrixIsIntegerTranslation &&
ctx->CurrentOperator() == gfxContext::OPERATOR_OVER;
// The padding of 0.5 for non-pixel-exact transformations used here is
// the same as what _cairo_pattern_analyze_filter uses.
const gfxFloat filterRadius = 0.5;
gfxRect affectedRect(0.0, 0.0, size.width, size.height);
if (!matrixIsIntegerTranslation) {
// The filter footprint means that the affected rectangle is a
// little larger than the drawingRect;
affectedRect.Inflate(filterRadius);
NATIVE_DRAWING_NOTE("FALLBACK: matrix not integer translation");
} else if (!canDrawOverBackground) {
NATIVE_DRAWING_NOTE("FALLBACK: unsupported operator");
}
// Clipping to the region affected by drawing allows us to consider only
// the portions of the clip region that will be affected by drawing.
gfxRect clipExtents;
{
gfxContextAutoSaveRestore autoSR(ctx);
ctx->Clip(affectedRect);
clipExtents = ctx->GetClipExtents();
if (clipExtents.IsEmpty())
return; // nothing to do
if (canDrawOverBackground &&
DrawDirect(ctx, size, flags, screen, visual))
return;
}
nsIntRect drawingRect(nsIntPoint(0, 0), size);
// Drawing need only be performed within the clip extents
// (and padding for the filter).
if (!matrixIsIntegerTranslation) {
// The source surface may need to be a little larger than the clip
// extents due to the filter footprint.
clipExtents.Inflate(filterRadius);
}
clipExtents.RoundOut();
nsIntRect intExtents(int32_t(clipExtents.X()),
int32_t(clipExtents.Y()),
int32_t(clipExtents.Width()),
int32_t(clipExtents.Height()));
drawingRect.IntersectRect(drawingRect, intExtents);
gfxPoint offset(drawingRect.x, drawingRect.y);
DrawingMethod method;
nsRefPtr<gfxASurface> target = ctx->CurrentSurface();
nsRefPtr<gfxXlibSurface> tempXlibSurface =
CreateTempXlibSurface(target, drawingRect.Size(),
canDrawOverBackground, flags, screen, visual,
&method);
if (!tempXlibSurface)
return;
if (drawingRect.Size() != size || method == eCopyBackground) {
// Only drawing a portion, or copying background,
// so won't return a result.
result = NULL;
}
nsRefPtr<gfxContext> tmpCtx;
if (!drawIsOpaque) {
tmpCtx = new gfxContext(tempXlibSurface);
if (method == eCopyBackground) {
tmpCtx->SetOperator(gfxContext::OPERATOR_SOURCE);
tmpCtx->SetSource(target, -(offset + matrix.GetTranslation()));
// The copy from the tempXlibSurface to the target context should
// use operator SOURCE, but that would need a mask to bound the
// operation. Here we only copy opaque backgrounds so operator
// OVER will behave like SOURCE masked by the surface.
NS_ASSERTION(tempXlibSurface->GetContentType()
== gfxASurface::CONTENT_COLOR,
"Don't copy background with a transparent surface");
} else {
tmpCtx->SetOperator(gfxContext::OPERATOR_CLEAR);
}
tmpCtx->Paint();
}
if (!DrawOntoTempSurface(tempXlibSurface, -drawingRect.TopLeft())) {
return;
}
if (method != eAlphaExtraction) {
ctx->SetSource(tempXlibSurface, offset);
ctx->Paint();
if (result) {
result->mSurface = tempXlibSurface;
/* fill in the result with what we know, which is really just what our
assumption was */
result->mUniformAlpha = true;
result->mColor.a = 1.0;
}
return;
}
nsRefPtr<gfxImageSurface> blackImage =
CopyXlibSurfaceToImage(tempXlibSurface, gfxASurface::ImageFormatARGB32);
tmpCtx->SetDeviceColor(gfxRGBA(1.0, 1.0, 1.0));
tmpCtx->SetOperator(gfxContext::OPERATOR_SOURCE);
tmpCtx->Paint();
DrawOntoTempSurface(tempXlibSurface, -drawingRect.TopLeft());
nsRefPtr<gfxImageSurface> whiteImage =
CopyXlibSurfaceToImage(tempXlibSurface, gfxASurface::ImageFormatRGB24);
if (blackImage->CairoStatus() == CAIRO_STATUS_SUCCESS &&
whiteImage->CairoStatus() == CAIRO_STATUS_SUCCESS) {
gfxAlphaRecovery::Analysis analysis;
if (!gfxAlphaRecovery::RecoverAlpha(blackImage, whiteImage,
result ? &analysis : nullptr))
return;
ctx->SetSource(blackImage, offset);
/* if the caller wants to retrieve the rendered image, put it into
a 'similar' surface, and use that as the source for the drawing right
now. This means we always return a surface similar to the surface
used for 'cr', which is ideal if it's going to be cached and reused.
We do not return an image if the result has uniform color (including
alpha). */
if (result) {
if (analysis.uniformAlpha) {
result->mUniformAlpha = true;
result->mColor.a = analysis.alpha;
}
if (analysis.uniformColor) {
result->mUniformColor = true;
result->mColor.r = analysis.r;
result->mColor.g = analysis.g;
result->mColor.b = analysis.b;
} else {
result->mSurface = target->
CreateSimilarSurface(gfxASurface::CONTENT_COLOR_ALPHA,
gfxIntSize(size.width, size.height));
gfxContext copyCtx(result->mSurface);
copyCtx.SetSource(blackImage);
copyCtx.SetOperator(gfxContext::OPERATOR_SOURCE);
copyCtx.Paint();
ctx->SetSource(result->mSurface);
}
}
ctx->Paint();
}
}