/****************************************************************************
**
** Copyright (C) 2010 Nokia Corporation and/or its subsidiary(-ies).
** All rights reserved.
** Contact: Nokia Corporation (qt-info@nokia.com)
**
** This file is part of the QtGui module of the Qt Toolkit.
**
** $QT_BEGIN_LICENSE:LGPL$
** No Commercial Usage
** This file contains pre-release code and may not be distributed.
** You may use this file in accordance with the terms and conditions
** contained in the Technology Preview License Agreement accompanying
** this package.
**
** GNU Lesser General Public License Usage
** Alternatively, this file may be used under the terms of the GNU Lesser
** General Public License version 2.1 as published by the Free Software
** Foundation and appearing in the file LICENSE.LGPL included in the
** packaging of this file. Please review the following information to
** ensure the GNU Lesser General Public License version 2.1 requirements
** will be met: http://www.gnu.org/licenses/old-licenses/lgpl-2.1.html.
**
** In addition, as a special exception, Nokia gives you certain additional
** rights. These rights are described in the Nokia Qt LGPL Exception
** version 1.1, included in the file LGPL_EXCEPTION.txt in this package.
**
** If you have questions regarding the use of this file, please contact
** Nokia at qt-info@nokia.com.
**
**
**
**
**
**
**
**
** $QT_END_LICENSE$
**
****************************************************************************/
#include <private/qdrawhelper_p.h>
#include <private/qpaintengine_raster_p.h>
#include <private/qpainter_p.h>
#include <private/qdrawhelper_x86_p.h>
#include <private/qdrawhelper_armv6_p.h>
#include <private/qdrawhelper_neon_p.h>
#include <private/qmath_p.h>
#include <qmath.h>
QT_BEGIN_NAMESPACE
#define MASK(src, a) src = BYTE_MUL(src, a)
#if defined(Q_OS_IRIX) && defined(Q_CC_GNU) && __GNUC__ == 3 && __GNUC__ < 4 && QT_POINTER_SIZE == 8
#define Q_IRIX_GCC3_3_WORKAROUND
//
// work around http://gcc.gnu.org/bugzilla/show_bug.cgi?id=14484
//
static uint gccBug(uint value) __attribute__((noinline));
static uint gccBug(uint value)
{
return value;
}
#endif
/*
constants and structures
*/
static const int fixed_scale = 1 << 16;
static const int half_point = 1 << 15;
static const int buffer_size = 2048;
struct LinearGradientValues
{
qreal dx;
qreal dy;
qreal l;
qreal off;
};
struct RadialGradientValues
{
qreal dx;
qreal dy;
qreal a;
};
struct Operator;
typedef uint* (QT_FASTCALL *DestFetchProc)(uint *buffer, QRasterBuffer *rasterBuffer, int x, int y, int length);
typedef void (QT_FASTCALL *DestStoreProc)(QRasterBuffer *rasterBuffer, int x, int y, const uint *buffer, int length);
typedef const uint* (QT_FASTCALL *SourceFetchProc)(uint *buffer, const Operator *o, const QSpanData *data, int y, int x, int length);
struct Operator
{
QPainter::CompositionMode mode;
DestFetchProc dest_fetch;
DestStoreProc dest_store;
SourceFetchProc src_fetch;
CompositionFunctionSolid funcSolid;
CompositionFunction func;
union {
LinearGradientValues linear;
RadialGradientValues radial;
// TextureValues texture;
};
};
/*
Destination fetch. This is simple as we don't have to do bounds checks or
transformations
*/
static uint * QT_FASTCALL destFetchMono(uint *buffer, QRasterBuffer *rasterBuffer, int x, int y, int length)
{
uchar *data = (uchar *)rasterBuffer->scanLine(y);
uint *start = buffer;
const uint *end = buffer + length;
while (buffer < end) {
*buffer = data[x>>3] & (0x80 >> (x & 7)) ? rasterBuffer->destColor1 : rasterBuffer->destColor0;
++buffer;
++x;
}
return start;
}
static uint * QT_FASTCALL destFetchMonoLsb(uint *buffer, QRasterBuffer *rasterBuffer, int x, int y, int length)
{
uchar *data = (uchar *)rasterBuffer->scanLine(y);
uint *start = buffer;
const uint *end = buffer + length;
while (buffer < end) {
*buffer = data[x>>3] & (0x1 << (x & 7)) ? rasterBuffer->destColor1 : rasterBuffer->destColor0;
++buffer;
++x;
}
return start;
}
static uint * QT_FASTCALL destFetchARGB32(uint *buffer, QRasterBuffer *rasterBuffer, int x, int y, int length)
{
const uint *data = (const uint *)rasterBuffer->scanLine(y) + x;
for (int i = 0; i < length; ++i)
buffer[i] = PREMUL(data[i]);
return buffer;
}
static uint * QT_FASTCALL destFetchARGB32P(uint *, QRasterBuffer *rasterBuffer, int x, int y, int)
{
return (uint *)rasterBuffer->scanLine(y) + x;
}
static uint * QT_FASTCALL destFetchRGB16(uint *buffer, QRasterBuffer *rasterBuffer, int x, int y, int length)
{
const ushort *data = (const ushort *)rasterBuffer->scanLine(y) + x;
for (int i = 0; i < length; ++i)
buffer[i] = qConvertRgb16To32(data[i]);
return buffer;
}
template <class DST>
Q_STATIC_TEMPLATE_FUNCTION uint * QT_FASTCALL destFetch(uint *buffer, QRasterBuffer *rasterBuffer,
int x, int y, int length)
{
const DST *src = reinterpret_cast<DST*>(rasterBuffer->scanLine(y)) + x;
quint32 *dest = reinterpret_cast<quint32*>(buffer);
while (length--)
*dest++ = *src++;
return buffer;
}
# define SPANFUNC_POINTER_DESTFETCH(Arg) destFetch<Arg>
static const DestFetchProc destFetchProc[QImage::NImageFormats] =
{
0, // Format_Invalid
destFetchMono, // Format_Mono,
destFetchMonoLsb, // Format_MonoLSB
0, // Format_Indexed8
destFetchARGB32P, // Format_RGB32
destFetchARGB32, // Format_ARGB32,
destFetchARGB32P, // Format_ARGB32_Premultiplied
destFetchRGB16, // Format_RGB16
SPANFUNC_POINTER_DESTFETCH(qargb8565), // Format_ARGB8565_Premultiplied
SPANFUNC_POINTER_DESTFETCH(qrgb666), // Format_RGB666
SPANFUNC_POINTER_DESTFETCH(qargb6666), // Format_ARGB6666_Premultiplied
SPANFUNC_POINTER_DESTFETCH(qrgb555), // Format_RGB555
SPANFUNC_POINTER_DESTFETCH(qargb8555), // Format_ARGB8555_Premultiplied
SPANFUNC_POINTER_DESTFETCH(qrgb888), // Format_RGB888
SPANFUNC_POINTER_DESTFETCH(qrgb444), // Format_RGB444
SPANFUNC_POINTER_DESTFETCH(qargb4444) // Format_ARGB4444_Premultiplied
};
/*
Returns the color in the mono destination color table
that is the "nearest" to /color/.
*/
static inline QRgb findNearestColor(QRgb color, QRasterBuffer *rbuf)
{
QRgb color_0 = PREMUL(rbuf->destColor0);
QRgb color_1 = PREMUL(rbuf->destColor1);
color = PREMUL(color);
int r = qRed(color);
int g = qGreen(color);
int b = qBlue(color);
int rx, gx, bx;
int dist_0, dist_1;
rx = r - qRed(color_0);
gx = g - qGreen(color_0);
bx = b - qBlue(color_0);
dist_0 = rx*rx + gx*gx + bx*bx;
rx = r - qRed(color_1);
gx = g - qGreen(color_1);
bx = b - qBlue(color_1);
dist_1 = rx*rx + gx*gx + bx*bx;
if (dist_0 < dist_1)
return color_0;
return color_1;
}
/*
Destination store.
*/
static void QT_FASTCALL destStoreMono(QRasterBuffer *rasterBuffer, int x, int y, const uint *buffer, int length)
{
uchar *data = (uchar *)rasterBuffer->scanLine(y);
if (rasterBuffer->monoDestinationWithClut) {
for (int i = 0; i < length; ++i) {
if (buffer[i] == rasterBuffer->destColor0) {
data[x >> 3] &= ~(0x80 >> (x & 7));
} else if (buffer[i] == rasterBuffer->destColor1) {
data[x >> 3] |= 0x80 >> (x & 7);
} else if (findNearestColor(buffer[i], rasterBuffer) == rasterBuffer->destColor0) {
data[x >> 3] &= ~(0x80 >> (x & 7));
} else {
data[x >> 3] |= 0x80 >> (x & 7);
}
++x;
}
} else {
for (int i = 0; i < length; ++i) {
if (qGray(buffer[i]) < int(qt_bayer_matrix[y & 15][x & 15]))
data[x >> 3] |= 0x80 >> (x & 7);
else
data[x >> 3] &= ~(0x80 >> (x & 7));
++x;
}
}
}
static void QT_FASTCALL destStoreMonoLsb(QRasterBuffer *rasterBuffer, int x, int y, const uint *buffer, int length)
{
uchar *data = (uchar *)rasterBuffer->scanLine(y);
if (rasterBuffer->monoDestinationWithClut) {
for (int i = 0; i < length; ++i) {
if (buffer[i] == rasterBuffer->destColor0) {
data[x >> 3] &= ~(1 << (x & 7));
} else if (buffer[i] == rasterBuffer->destColor1) {
data[x >> 3] |= 1 << (x & 7);
} else if (findNearestColor(buffer[i], rasterBuffer) == rasterBuffer->destColor0) {
data[x >> 3] &= ~(1 << (x & 7));
} else {
data[x >> 3] |= 1 << (x & 7);
}
++x;
}
} else {
for (int i = 0; i < length; ++i) {
if (qGray(buffer[i]) < int(qt_bayer_matrix[y & 15][x & 15]))
data[x >> 3] |= 1 << (x & 7);
else
data[x >> 3] &= ~(1 << (x & 7));
++x;
}
}
}
static void QT_FASTCALL destStoreARGB32(QRasterBuffer *rasterBuffer, int x, int y, const uint *buffer, int length)
{
uint *data = (uint *)rasterBuffer->scanLine(y) + x;
for (int i = 0; i < length; ++i) {
int p = buffer[i];
int alpha = qAlpha(p);
if (alpha == 255)
data[i] = p;
else if (alpha == 0)
data[i] = 0;
else {
int inv_alpha = 0xff0000/qAlpha(buffer[i]);
data[i] = (p & 0xff000000)
| ((qRed(p)*inv_alpha) & 0xff0000)
| (((qGreen(p)*inv_alpha) >> 8) & 0xff00)
| ((qBlue(p)*inv_alpha) >> 16);
}
}
}
static void QT_FASTCALL destStoreRGB16(QRasterBuffer *rasterBuffer, int x, int y, const uint *buffer, int length)
{
quint16 *data = (quint16*)rasterBuffer->scanLine(y) + x;
qt_memconvert<quint16, quint32>(data, buffer, length);
}
template <class DST>
Q_STATIC_TEMPLATE_FUNCTION void QT_FASTCALL destStore(QRasterBuffer *rasterBuffer,
int x, int y,
const uint *buffer, int length)
{
DST *dest = reinterpret_cast<DST*>(rasterBuffer->scanLine(y)) + x;
const quint32p *src = reinterpret_cast<const quint32p*>(buffer);
while (length--)
*dest++ = DST(*src++);
}
# define SPANFUNC_POINTER_DESTSTORE(DEST) destStore<DEST>
static const DestStoreProc destStoreProc[QImage::NImageFormats] =
{
0, // Format_Invalid
destStoreMono, // Format_Mono,
destStoreMonoLsb, // Format_MonoLSB
0, // Format_Indexed8
0, // Format_RGB32
destStoreARGB32, // Format_ARGB32,
0, // Format_ARGB32_Premultiplied
destStoreRGB16, // Format_RGB16
SPANFUNC_POINTER_DESTSTORE(qargb8565), // Format_ARGB8565_Premultiplied
SPANFUNC_POINTER_DESTSTORE(qrgb666), // Format_RGB666
SPANFUNC_POINTER_DESTSTORE(qargb6666), // Format_ARGB6666_Premultiplied
SPANFUNC_POINTER_DESTSTORE(qrgb555), // Format_RGB555
SPANFUNC_POINTER_DESTSTORE(qargb8555), // Format_ARGB8555_Premultiplied
SPANFUNC_POINTER_DESTSTORE(qrgb888), // Format_RGB888
SPANFUNC_POINTER_DESTSTORE(qrgb444), // Format_RGB444
SPANFUNC_POINTER_DESTSTORE(qargb4444) // Format_ARGB4444_Premultiplied
};
/*
Source fetches
This is a bit more complicated, as we need several fetch routines for every surface type
We need 5 fetch methods per surface type:
untransformed
transformed (tiled and not tiled)
transformed bilinear (tiled and not tiled)
We don't need bounds checks for untransformed, but we need them for the other ones.
The generic implementation does pixel by pixel fetches
*/
template <QImage::Format format>
Q_STATIC_TEMPLATE_FUNCTION uint QT_FASTCALL qt_fetchPixel(const uchar *scanLine, int x, const QVector<QRgb> *rgb);
template<>
Q_STATIC_TEMPLATE_SPECIALIZATION
uint QT_FASTCALL qt_fetchPixel<QImage::Format_Mono>(const uchar *scanLine,
int x, const QVector<QRgb> *rgb)
{
bool pixel = scanLine[x>>3] & (0x80 >> (x & 7));
if (rgb) return PREMUL(rgb->at(pixel ? 1 : 0));
return pixel ? 0xff000000 : 0xffffffff;
}
template<>
Q_STATIC_TEMPLATE_SPECIALIZATION
uint QT_FASTCALL qt_fetchPixel<QImage::Format_MonoLSB>(const uchar *scanLine,
int x, const QVector<QRgb> *rgb)
{
bool pixel = scanLine[x>>3] & (0x1 << (x & 7));
if (rgb) return PREMUL(rgb->at(pixel ? 1 : 0));
return pixel ? 0xff000000 : 0xffffffff;
}
template<>
Q_STATIC_TEMPLATE_SPECIALIZATION
uint QT_FASTCALL qt_fetchPixel<QImage::Format_Indexed8>(const uchar *scanLine,
int x, const QVector<QRgb> *rgb)
{
return PREMUL(rgb->at(scanLine[x]));
}
template<>
Q_STATIC_TEMPLATE_SPECIALIZATION
uint QT_FASTCALL qt_fetchPixel<QImage::Format_ARGB32>(const uchar *scanLine,
int x, const QVector<QRgb> *)
{
return PREMUL(((const uint *)scanLine)[x]);
}
template<>
Q_STATIC_TEMPLATE_SPECIALIZATION
uint QT_FASTCALL qt_fetchPixel<QImage::Format_ARGB32_Premultiplied>(const uchar *scanLine,
int x, const QVector<QRgb> *)
{
return ((const uint *)scanLine)[x];
}
template<>
Q_STATIC_TEMPLATE_SPECIALIZATION
uint QT_FASTCALL qt_fetchPixel<QImage::Format_RGB16>(const uchar *scanLine,
int x, const QVector<QRgb> *)
{
return qConvertRgb16To32(((const ushort *)scanLine)[x]);
}
template<>
Q_STATIC_TEMPLATE_SPECIALIZATION
uint QT_FASTCALL qt_fetchPixel<QImage::Format_ARGB8565_Premultiplied>(const uchar *scanLine,
int x,
const QVector<QRgb> *)
{
const qargb8565 color = reinterpret_cast<const qargb8565*>(scanLine)[x];
return qt_colorConvert<quint32, qargb8565>(color, 0);
}
template<>
Q_STATIC_TEMPLATE_SPECIALIZATION
uint QT_FASTCALL qt_fetchPixel<QImage::Format_RGB666>(const uchar *scanLine,
int x,
const QVector<QRgb> *)
{
const qrgb666 color = reinterpret_cast<const qrgb666*>(scanLine)[x];
return qt_colorConvert<quint32, qrgb666>(color, 0);
}
template<>
Q_STATIC_TEMPLATE_SPECIALIZATION
uint QT_FASTCALL qt_fetchPixel<QImage::Format_ARGB6666_Premultiplied>(const uchar *scanLine,
int x,
const QVector<QRgb> *)
{
const qargb6666 color = reinterpret_cast<const qargb6666*>(scanLine)[x];
return qt_colorConvert<quint32, qargb6666>(color, 0);
}
template<>
Q_STATIC_TEMPLATE_SPECIALIZATION
uint QT_FASTCALL qt_fetchPixel<QImage::Format_RGB555>(const uchar *scanLine,
int x,
const QVector<QRgb> *)
{
const qrgb555 color = reinterpret_cast<const qrgb555*>(scanLine)[x];
return qt_colorConvert<quint32, qrgb555>(color, 0);
}
template<>
Q_STATIC_TEMPLATE_SPECIALIZATION
uint QT_FASTCALL qt_fetchPixel<QImage::Format_ARGB8555_Premultiplied>(const uchar *scanLine,
int x,
const QVector<QRgb> *)
{
const qargb8555 color = reinterpret_cast<const qargb8555*>(scanLine)[x];
return qt_colorConvert<quint32, qargb8555>(color, 0);
}
template<>
Q_STATIC_TEMPLATE_SPECIALIZATION
uint QT_FASTCALL qt_fetchPixel<QImage::Format_RGB888>(const uchar *scanLine,
int x,
const QVector<QRgb> *)
{
const qrgb888 color = reinterpret_cast<const qrgb888*>(scanLine)[x];
return qt_colorConvert<quint32, qrgb888>(color, 0);
}
template<>
Q_STATIC_TEMPLATE_SPECIALIZATION
uint QT_FASTCALL qt_fetchPixel<QImage::Format_RGB444>(const uchar *scanLine,
int x,
const QVector<QRgb> *)
{
const qrgb444 color = reinterpret_cast<const qrgb444*>(scanLine)[x];
return qt_colorConvert<quint32, qrgb444>(color, 0);
}
template<>
Q_STATIC_TEMPLATE_SPECIALIZATION
uint QT_FASTCALL qt_fetchPixel<QImage::Format_ARGB4444_Premultiplied>(const uchar *scanLine,
int x,
const QVector<QRgb> *)
{
const qargb4444 color = reinterpret_cast<const qargb4444*>(scanLine)[x];
return qt_colorConvert<quint32, qargb4444>(color, 0);
}
template<>
Q_STATIC_TEMPLATE_SPECIALIZATION
uint QT_FASTCALL qt_fetchPixel<QImage::Format_Invalid>(const uchar *,
int ,
const QVector<QRgb> *)
{
return 0;
}
typedef uint (QT_FASTCALL *FetchPixelProc)(const uchar *scanLine, int x, const QVector<QRgb> *);
#define SPANFUNC_POINTER_FETCHPIXEL(Arg) qt_fetchPixel<QImage::Arg>
static const FetchPixelProc fetchPixelProc[QImage::NImageFormats] =
{
0,
SPANFUNC_POINTER_FETCHPIXEL(Format_Mono),
SPANFUNC_POINTER_FETCHPIXEL(Format_MonoLSB),
SPANFUNC_POINTER_FETCHPIXEL(Format_Indexed8),
SPANFUNC_POINTER_FETCHPIXEL(Format_ARGB32_Premultiplied),
SPANFUNC_POINTER_FETCHPIXEL(Format_ARGB32),
SPANFUNC_POINTER_FETCHPIXEL(Format_ARGB32_Premultiplied),
SPANFUNC_POINTER_FETCHPIXEL(Format_RGB16),
SPANFUNC_POINTER_FETCHPIXEL(Format_ARGB8565_Premultiplied),
SPANFUNC_POINTER_FETCHPIXEL(Format_RGB666),
SPANFUNC_POINTER_FETCHPIXEL(Format_ARGB6666_Premultiplied),
SPANFUNC_POINTER_FETCHPIXEL(Format_RGB555),
SPANFUNC_POINTER_FETCHPIXEL(Format_ARGB8555_Premultiplied),
SPANFUNC_POINTER_FETCHPIXEL(Format_RGB888),
SPANFUNC_POINTER_FETCHPIXEL(Format_RGB444),
SPANFUNC_POINTER_FETCHPIXEL(Format_ARGB4444_Premultiplied)
};
enum TextureBlendType {
BlendUntransformed,
BlendTiled,
BlendTransformed,
BlendTransformedTiled,
BlendTransformedBilinear,
BlendTransformedBilinearTiled,
NBlendTypes
};
template <QImage::Format format>
Q_STATIC_TEMPLATE_FUNCTION const uint * QT_FASTCALL qt_fetchUntransformed(uint *buffer, const Operator *, const QSpanData *data,
int y, int x, int length)
{
const uchar *scanLine = data->texture.scanLine(y);
for (int i = 0; i < length; ++i)
buffer[i] = qt_fetchPixel<format>(scanLine, x + i, data->texture.colorTable);
return buffer;
}
template <>
Q_STATIC_TEMPLATE_SPECIALIZATION const uint * QT_FASTCALL
qt_fetchUntransformed<QImage::Format_ARGB32_Premultiplied>(uint *, const Operator *,
const QSpanData *data,
int y, int x, int)
{
const uchar *scanLine = data->texture.scanLine(y);
return ((const uint *)scanLine) + x;
}
template<TextureBlendType blendType> /* either BlendTransformed or BlendTransformedTiled */
Q_STATIC_TEMPLATE_FUNCTION
const uint * QT_FASTCALL fetchTransformed(uint *buffer, const Operator *, const QSpanData *data,
int y, int x, int length)
{
FetchPixelProc fetch = fetchPixelProc[data->texture.format];
int image_width = data->texture.width;
int image_height = data->texture.height;
const qreal cx = x + 0.5;
const qreal cy = y + 0.5;
const uint *end = buffer + length;
uint *b = buffer;
if (data->fast_matrix) {
// The increment pr x in the scanline
int fdx = (int)(data->m11 * fixed_scale);
int fdy = (int)(data->m12 * fixed_scale);
int fx = int((data->m21 * cy
+ data->m11 * cx + data->dx) * fixed_scale);
int fy = int((data->m22 * cy
+ data->m12 * cx + data->dy) * fixed_scale);
while (b < end) {
int px = fx >> 16;
int py = fy >> 16;
if (blendType == BlendTransformedTiled) {
px %= image_width;
py %= image_height;
if (px < 0) px += image_width;
if (py < 0) py += image_height;
const uchar *scanLine = data->texture.scanLine(py);
*b = fetch(scanLine, px, data->texture.colorTable);
} else {
if ((px < 0) || (px >= image_width)
|| (py < 0) || (py >= image_height)) {
*b = uint(0);
} else {
const uchar *scanLine = data->texture.scanLine(py);
*b = fetch(scanLine, px, data->texture.colorTable);
}
}
fx += fdx;
fy += fdy;
++b;
}
} else {
const qreal fdx = data->m11;
const qreal fdy = data->m12;
const qreal fdw = data->m13;
qreal fx = data->m21 * cy + data->m11 * cx + data->dx;
qreal fy = data->m22 * cy + data->m12 * cx + data->dy;
qreal fw = data->m23 * cy + data->m13 * cx + data->m33;
while (b < end) {
const qreal iw = fw == 0 ? 1 : 1 / fw;
const qreal tx = fx * iw;
const qreal ty = fy * iw;
int px = int(tx) - (tx < 0);
int py = int(ty) - (ty < 0);
if (blendType == BlendTransformedTiled) {
px %= image_width;
py %= image_height;
if (px < 0) px += image_width;
if (py < 0) py += image_height;
const uchar *scanLine = data->texture.scanLine(py);
*b = fetch(scanLine, px, data->texture.colorTable);
} else {
if ((px < 0) || (px >= image_width)
|| (py < 0) || (py >= image_height)) {
*b = uint(0);
} else {
const uchar *scanLine = data->texture.scanLine(py);
*b = fetch(scanLine, px, data->texture.colorTable);
}
}
fx += fdx;
fy += fdy;
fw += fdw;
//force increment to avoid /0
if (!fw) {
fw += fdw;
}
++b;
}
}
return buffer;
}
template<TextureBlendType blendType, QImage::Format format> /* blendType = BlendTransformedBilinear or BlendTransformedBilinearTiled */
Q_STATIC_TEMPLATE_FUNCTION
const uint * QT_FASTCALL fetchTransformedBilinear(uint *buffer, const Operator *, const QSpanData *data,
int y, int x, int length)
{
#ifdef Q_CC_RVCT // needed to avoid compiler crash in RVCT 2.2
FetchPixelProc fetch;
if (format != QImage::Format_Invalid)
fetch = qt_fetchPixel<format>;
else
fetch = fetchPixelProc[data->texture.format];
#else
FetchPixelProc fetch = (format != QImage::Format_Invalid) ? FetchPixelProc(qt_fetchPixel<format>) : fetchPixelProc[data->texture.format];
#endif
int image_width = data->texture.width;
int image_height = data->texture.height;
const qreal cx = x + 0.5;
const qreal cy = y + 0.5;
const uint *end = buffer + length;
uint *b = buffer;
if (data->fast_matrix) {
// The increment pr x in the scanline
int fdx = (int)(data->m11 * fixed_scale);
int fdy = (int)(data->m12 * fixed_scale);
int fx = int((data->m21 * cy
+ data->m11 * cx + data->dx) * fixed_scale);
int fy = int((data->m22 * cy
+ data->m12 * cx + data->dy) * fixed_scale);
fx -= half_point;
fy -= half_point;
while (b < end) {
int x1 = (fx >> 16);
int x2 = x1 + 1;
int y1 = (fy >> 16);
int y2 = y1 + 1;
int distx = ((fx - (x1 << 16)) >> 8);
int disty = ((fy - (y1 << 16)) >> 8);
int idistx = 256 - distx;
int idisty = 256 - disty;
if (blendType == BlendTransformedBilinearTiled) {
x1 %= image_width;
x2 %= image_width;
y1 %= image_height;
y2 %= image_height;
if (x1 < 0) x1 += image_width;
if (x2 < 0) x2 += image_width;
if (y1 < 0) y1 += image_height;
if (y2 < 0) y2 += image_height;
Q_ASSERT(x1 >= 0 && x1 < image_width);
Q_ASSERT(x2 >= 0 && x2 < image_width);
Q_ASSERT(y1 >= 0 && y1 < image_height);
Q_ASSERT(y2 >= 0 && y2 < image_height);
} else {
x1 = qBound(0, x1, image_width - 1);
x2 = qBound(0, x2, image_width - 1);
y1 = qBound(0, y1, image_height - 1);
y2 = qBound(0, y2, image_height - 1);
}
const uchar *s1 = data->texture.scanLine(y1);
const uchar *s2 = data->texture.scanLine(y2);
uint tl = fetch(s1, x1, data->texture.colorTable);
uint tr = fetch(s1, x2, data->texture.colorTable);
uint bl = fetch(s2, x1, data->texture.colorTable);
uint br = fetch(s2, x2, data->texture.colorTable);
uint xtop = INTERPOLATE_PIXEL_256(tl, idistx, tr, distx);
uint xbot = INTERPOLATE_PIXEL_256(bl, idistx, br, distx);
*b = INTERPOLATE_PIXEL_256(xtop, idisty, xbot, disty);
fx += fdx;
fy += fdy;
++b;
}
} else {
const qreal fdx = data->m11;
const qreal fdy = data->m12;
const qreal fdw = data->m13;
qreal fx = data->m21 * cy + data->m11 * cx + data->dx;
qreal fy = data->m22 * cy + data->m12 * cx + data->dy;
qreal fw = data->m23 * cy + data->m13 * cx + data->m33;
while (b < end) {
const qreal iw = fw == 0 ? 1 : 1 / fw;
const qreal px = fx * iw - 0.5;
const qreal py = fy * iw - 0.5;
int x1 = int(px) - (px < 0);
int x2 = x1 + 1;
int y1 = int(py) - (py < 0);
int y2 = y1 + 1;
int distx = int((px - x1) * 256);
int disty = int((py - y1) * 256);
int idistx = 256 - distx;
int idisty = 256 - disty;
if (blendType == BlendTransformedBilinearTiled) {
x1 %= image_width;
x2 %= image_width;
y1 %= image_height;
y2 %= image_height;
if (x1 < 0) x1 += image_width;
if (x2 < 0) x2 += image_width;
if (y1 < 0) y1 += image_height;
if (y2 < 0) y2 += image_height;
Q_ASSERT(x1 >= 0 && x1 < image_width);
Q_ASSERT(x2 >= 0 && x2 < image_width);
Q_ASSERT(y1 >= 0 && y1 < image_height);
Q_ASSERT(y2 >= 0 && y2 < image_height);
} else {
x1 = qBound(0, x1, image_width - 1);
x2 = qBound(0, x2, image_width - 1);
y1 = qBound(0, y1, image_height - 1);
y2 = qBound(0, y2, image_height - 1);
}
const uchar *s1 = data->texture.scanLine(y1);
const uchar *s2 = data->texture.scanLine(y2);
uint tl = fetch(s1, x1, data->texture.colorTable);
uint tr = fetch(s1, x2, data->texture.colorTable);
uint bl = fetch(s2, x1, data->texture.colorTable);
uint br = fetch(s2, x2, data->texture.colorTable);
uint xtop = INTERPOLATE_PIXEL_256(tl, idistx, tr, distx);
uint xbot = INTERPOLATE_PIXEL_256(bl, idistx, br, distx);
*b = INTERPOLATE_PIXEL_256(xtop, idisty, xbot, disty);
fx += fdx;
fy += fdy;
fw += fdw;
//force increment to avoid /0
if (!fw) {
fw += fdw;
}
++b;
}
}
return buffer;
}
#define SPANFUNC_POINTER_FETCHHUNTRANSFORMED(Arg) qt_fetchUntransformed<QImage::Arg>
static const SourceFetchProc sourceFetch[NBlendTypes][QImage::NImageFormats] = {
// Untransformed
{
0, // Invalid
SPANFUNC_POINTER_FETCHHUNTRANSFORMED(Format_Mono), // Mono
SPANFUNC_POINTER_FETCHHUNTRANSFORMED(Format_MonoLSB), // MonoLsb
SPANFUNC_POINTER_FETCHHUNTRANSFORMED(Format_Indexed8), // Indexed8
SPANFUNC_POINTER_FETCHHUNTRANSFORMED(Format_ARGB32_Premultiplied), // RGB32
SPANFUNC_POINTER_FETCHHUNTRANSFORMED(Format_ARGB32), // ARGB32
SPANFUNC_POINTER_FETCHHUNTRANSFORMED(Format_ARGB32_Premultiplied), // ARGB32_Premultiplied
SPANFUNC_POINTER_FETCHHUNTRANSFORMED(Format_RGB16), // RGB16
SPANFUNC_POINTER_FETCHHUNTRANSFORMED(Format_ARGB8565_Premultiplied),// ARGB8565_Premultiplied
SPANFUNC_POINTER_FETCHHUNTRANSFORMED(Format_RGB666), // RGB666
SPANFUNC_POINTER_FETCHHUNTRANSFORMED(Format_ARGB6666_Premultiplied),// ARGB6666_Premultiplied
SPANFUNC_POINTER_FETCHHUNTRANSFORMED(Format_RGB555), // RGB555
SPANFUNC_POINTER_FETCHHUNTRANSFORMED(Format_ARGB8555_Premultiplied),// ARGB8555_Premultiplied
SPANFUNC_POINTER_FETCHHUNTRANSFORMED(Format_RGB888), // RGB888
SPANFUNC_POINTER_FETCHHUNTRANSFORMED(Format_RGB444), // RGB444
SPANFUNC_POINTER_FETCHHUNTRANSFORMED(Format_ARGB4444_Premultiplied) // ARGB4444_Premultiplied
},
// Tiled
{
0, // Invalid
SPANFUNC_POINTER_FETCHHUNTRANSFORMED(Format_Mono), // Mono
SPANFUNC_POINTER_FETCHHUNTRANSFORMED(Format_MonoLSB), // MonoLsb
SPANFUNC_POINTER_FETCHHUNTRANSFORMED(Format_Indexed8), // Indexed8
SPANFUNC_POINTER_FETCHHUNTRANSFORMED(Format_ARGB32_Premultiplied), // RGB32
SPANFUNC_POINTER_FETCHHUNTRANSFORMED(Format_ARGB32), // ARGB32
SPANFUNC_POINTER_FETCHHUNTRANSFORMED(Format_ARGB32_Premultiplied), // ARGB32_Premultiplied
SPANFUNC_POINTER_FETCHHUNTRANSFORMED(Format_RGB16), // RGB16
SPANFUNC_POINTER_FETCHHUNTRANSFORMED(Format_ARGB8565_Premultiplied),// ARGB8565_Premultiplied
SPANFUNC_POINTER_FETCHHUNTRANSFORMED(Format_RGB666), // RGB666
SPANFUNC_POINTER_FETCHHUNTRANSFORMED(Format_ARGB6666_Premultiplied),// ARGB6666_Premultiplied
SPANFUNC_POINTER_FETCHHUNTRANSFORMED(Format_RGB555), // RGB555
SPANFUNC_POINTER_FETCHHUNTRANSFORMED(Format_ARGB8555_Premultiplied),// ARGB8555_Premultiplied
SPANFUNC_POINTER_FETCHHUNTRANSFORMED(Format_RGB888), // RGB888
SPANFUNC_POINTER_FETCHHUNTRANSFORMED(Format_RGB444), // RGB444
SPANFUNC_POINTER_FETCHHUNTRANSFORMED(Format_ARGB4444_Premultiplied) // ARGB4444_Premultiplied
},
// Transformed
{
0, // Invalid
fetchTransformed<BlendTransformed>, // Mono
fetchTransformed<BlendTransformed>, // MonoLsb
fetchTransformed<BlendTransformed>, // Indexed8
fetchTransformed<BlendTransformed>, // RGB32
fetchTransformed<BlendTransformed>, // ARGB32
fetchTransformed<BlendTransformed>, // ARGB32_Premultiplied
fetchTransformed<BlendTransformed>, // RGB16
fetchTransformed<BlendTransformed>, // ARGB8565_Premultiplied
fetchTransformed<BlendTransformed>, // RGB666
fetchTransformed<BlendTransformed>, // ARGB6666_Premultiplied
fetchTransformed<BlendTransformed>, // RGB555
fetchTransformed<BlendTransformed>, // ARGB8555_Premultiplied
fetchTransformed<BlendTransformed>, // RGB888
fetchTransformed<BlendTransformed>, // RGB444
fetchTransformed<BlendTransformed>, // ARGB4444_Premultiplied
},
{
0, // TransformedTiled
fetchTransformed<BlendTransformedTiled>, // Mono
fetchTransformed<BlendTransformedTiled>, // MonoLsb
fetchTransformed<BlendTransformedTiled>, // Indexed8
fetchTransformed<BlendTransformedTiled>, // RGB32
fetchTransformed<BlendTransformedTiled>, // ARGB32
fetchTransformed<BlendTransformedTiled>, // ARGB32_Premultiplied
fetchTransformed<BlendTransformedTiled>, // RGB16
fetchTransformed<BlendTransformedTiled>, // ARGB8565_Premultiplied
fetchTransformed<BlendTransformedTiled>, // RGB666
fetchTransformed<BlendTransformedTiled>, // ARGB6666_Premultiplied
fetchTransformed<BlendTransformedTiled>, // RGB555
fetchTransformed<BlendTransformedTiled>, // ARGB8555_Premultiplied
fetchTransformed<BlendTransformedTiled>, // RGB888
fetchTransformed<BlendTransformedTiled>, // RGB444
fetchTransformed<BlendTransformedTiled>, // ARGB4444_Premultiplied
},
{
0, // Bilinear
fetchTransformedBilinear<BlendTransformedBilinear, QImage::Format_Invalid>, // Mono
fetchTransformedBilinear<BlendTransformedBilinear, QImage::Format_Invalid>, // MonoLsb
fetchTransformedBilinear<BlendTransformedBilinear, QImage::Format_Invalid>, // Indexed8
fetchTransformedBilinear<BlendTransformedBilinear, QImage::Format_ARGB32_Premultiplied>, // RGB32
fetchTransformedBilinear<BlendTransformedBilinear, QImage::Format_ARGB32>, // ARGB32
fetchTransformedBilinear<BlendTransformedBilinear, QImage::Format_ARGB32_Premultiplied>, // ARGB32_Premultiplied
fetchTransformedBilinear<BlendTransformedBilinear, QImage::Format_Invalid>, // RGB16
fetchTransformedBilinear<BlendTransformedBilinear, QImage::Format_Invalid>, // ARGB8565_Premultiplied
fetchTransformedBilinear<BlendTransformedBilinear, QImage::Format_Invalid>, // RGB666
fetchTransformedBilinear<BlendTransformedBilinear, QImage::Format_Invalid>, // ARGB6666_Premultiplied
fetchTransformedBilinear<BlendTransformedBilinear, QImage::Format_Invalid>, // RGB555
fetchTransformedBilinear<BlendTransformedBilinear, QImage::Format_Invalid>, // ARGB8555_Premultiplied
fetchTransformedBilinear<BlendTransformedBilinear, QImage::Format_Invalid>, // RGB888
fetchTransformedBilinear<BlendTransformedBilinear, QImage::Format_Invalid>, // RGB444
fetchTransformedBilinear<BlendTransformedBilinear, QImage::Format_Invalid> // ARGB4444_Premultiplied
},
{
0, // BilinearTiled
fetchTransformedBilinear<BlendTransformedBilinearTiled, QImage::Format_Invalid>, // Mono
fetchTransformedBilinear<BlendTransformedBilinearTiled, QImage::Format_Invalid>, // MonoLsb
fetchTransformedBilinear<BlendTransformedBilinearTiled, QImage::Format_Invalid>, // Indexed8
fetchTransformedBilinear<BlendTransformedBilinearTiled, QImage::Format_ARGB32_Premultiplied>, // RGB32
fetchTransformedBilinear<BlendTransformedBilinearTiled, QImage::Format_ARGB32>, // ARGB32
fetchTransformedBilinear<BlendTransformedBilinearTiled, QImage::Format_ARGB32_Premultiplied>, // ARGB32_Premultiplied
fetchTransformedBilinear<BlendTransformedBilinearTiled, QImage::Format_Invalid>, // RGB16
fetchTransformedBilinear<BlendTransformedBilinearTiled, QImage::Format_Invalid>, // ARGB8565_Premultiplied
fetchTransformedBilinear<BlendTransformedBilinearTiled, QImage::Format_Invalid>, // RGB666
fetchTransformedBilinear<BlendTransformedBilinearTiled, QImage::Format_Invalid>, // ARGB6666_Premultiplied
fetchTransformedBilinear<BlendTransformedBilinearTiled, QImage::Format_Invalid>, // RGB555
fetchTransformedBilinear<BlendTransformedBilinearTiled, QImage::Format_Invalid>, // ARGB8555_Premultiplied
fetchTransformedBilinear<BlendTransformedBilinearTiled, QImage::Format_Invalid>, // RGB888
fetchTransformedBilinear<BlendTransformedBilinearTiled, QImage::Format_Invalid>, // RGB444
fetchTransformedBilinear<BlendTransformedBilinearTiled, QImage::Format_Invalid> // ARGB4444_Premultiplied
},
};
static inline uint qt_gradient_pixel(const QGradientData *data, qreal pos)
{
int ipos = int(pos * (GRADIENT_STOPTABLE_SIZE - 1) + 0.5);
// calculate the actual offset.
if (ipos < 0 || ipos >= GRADIENT_STOPTABLE_SIZE) {
if (data->spread == QGradient::RepeatSpread) {
ipos = ipos % GRADIENT_STOPTABLE_SIZE;
ipos = ipos < 0 ? GRADIENT_STOPTABLE_SIZE + ipos : ipos;
} else if (data->spread == QGradient::ReflectSpread) {
const int limit = GRADIENT_STOPTABLE_SIZE * 2 - 1;
ipos = ipos % limit;
ipos = ipos < 0 ? limit + ipos : ipos;
ipos = ipos >= GRADIENT_STOPTABLE_SIZE ? limit - ipos : ipos;
} else {
if (ipos < 0) ipos = 0;
else if (ipos >= GRADIENT_STOPTABLE_SIZE) ipos = GRADIENT_STOPTABLE_SIZE-1;
}
}
Q_ASSERT(ipos >= 0);
Q_ASSERT(ipos < GRADIENT_STOPTABLE_SIZE);
return data->colorTable[ipos];
}
#define FIXPT_BITS 8
#define FIXPT_SIZE (1<<FIXPT_BITS)
static uint qt_gradient_pixel_fixed(const QGradientData *data, int fixed_pos)
{
int ipos = (fixed_pos + (FIXPT_SIZE / 2)) >> FIXPT_BITS;
// calculate the actual offset.
if (ipos < 0 || ipos >= GRADIENT_STOPTABLE_SIZE) {
if (data->spread == QGradient::RepeatSpread) {
ipos = ipos % GRADIENT_STOPTABLE_SIZE;
ipos = ipos < 0 ? GRADIENT_STOPTABLE_SIZE + ipos : ipos;
} else if (data->spread == QGradient::ReflectSpread) {
const int limit = GRADIENT_STOPTABLE_SIZE * 2 - 1;
ipos = ipos % limit;
ipos = ipos < 0 ? limit + ipos : ipos;
ipos = ipos >= GRADIENT_STOPTABLE_SIZE ? limit - ipos : ipos;
} else {
if (ipos < 0) ipos = 0;
else if (ipos >= GRADIENT_STOPTABLE_SIZE) ipos = GRADIENT_STOPTABLE_SIZE-1;
}
}
Q_ASSERT(ipos >= 0);
Q_ASSERT(ipos < GRADIENT_STOPTABLE_SIZE);
return data->colorTable[ipos];
}
static void QT_FASTCALL getLinearGradientValues(LinearGradientValues *v, const QSpanData *data)
{
v->dx = data->gradient.linear.end.x - data->gradient.linear.origin.x;
v->dy = data->gradient.linear.end.y - data->gradient.linear.origin.y;
v->l = v->dx * v->dx + v->dy * v->dy;
v->off = 0;
if (v->l != 0) {
v->dx /= v->l;
v->dy /= v->l;
v->off = -v->dx * data->gradient.linear.origin.x - v->dy * data->gradient.linear.origin.y;
}
}
static const uint * QT_FASTCALL fetchLinearGradient(uint *buffer, const Operator *op, const QSpanData *data,
int y, int x, int length)
{
const uint *b = buffer;
qreal t, inc;
bool affine = true;
qreal rx=0, ry=0;
if (op->linear.l == 0) {
t = inc = 0;
} else {
rx = data->m21 * (y + 0.5) + data->m11 * (x + 0.5) + data->dx;
ry = data->m22 * (y + 0.5) + data->m12 * (x + 0.5) + data->dy;
t = op->linear.dx*rx + op->linear.dy*ry + op->linear.off;
inc = op->linear.dx * data->m11 + op->linear.dy * data->m12;
affine = !data->m13 && !data->m23;
if (affine) {
t *= (GRADIENT_STOPTABLE_SIZE - 1);
inc *= (GRADIENT_STOPTABLE_SIZE - 1);
}
}
const uint *end = buffer + length;
if (affine) {
if (inc > -1e-5 && inc < 1e-5) {
QT_MEMFILL_UINT(buffer, length, qt_gradient_pixel_fixed(&data->gradient, int(t * FIXPT_SIZE)));
} else {
if (t+inc*length < qreal(INT_MAX >> (FIXPT_BITS + 1)) &&
t+inc*length > qreal(INT_MIN >> (FIXPT_BITS + 1))) {
// we can use fixed point math
int t_fixed = int(t * FIXPT_SIZE);
int inc_fixed = int(inc * FIXPT_SIZE);
while (buffer < end) {
*buffer = qt_gradient_pixel_fixed(&data->gradient, t_fixed);
t_fixed += inc_fixed;
++buffer;
}
} else {
// we have to fall back to float math
while (buffer < end) {
*buffer = qt_gradient_pixel(&data->gradient, t/GRADIENT_STOPTABLE_SIZE);
t += inc;
++buffer;
}
}
}
} else { // fall back to float math here as well
qreal rw = data->m23 * (y + 0.5) + data->m13 * (x + 0.5) + data->m33;
while (buffer < end) {
qreal x = rx/rw;
qreal y = ry/rw;
t = (op->linear.dx*x + op->linear.dy *y) + op->linear.off;
*buffer = qt_gradient_pixel(&data->gradient, t);
rx += data->m11;
ry += data->m12;
rw += data->m13;
if (!rw) {
rw += data->m13;
}
++buffer;
}
}
return b;
}
static inline qreal determinant(qreal a, qreal b, qreal c)
{
return (b * b) - (4 * a * c);
}
// function to evaluate real roots
static inline qreal realRoots(qreal a, qreal b, qreal detSqrt)
{
return (-b + detSqrt)/(2 * a);
}
static inline qreal qSafeSqrt(qreal x)
{
return x > 0 ? qSqrt(x) : 0;
}
static void QT_FASTCALL getRadialGradientValues(RadialGradientValues *v, const QSpanData *data)
{
v->dx = data->gradient.radial.center.x - data->gradient.radial.focal.x;
v->dy = data->gradient.radial.center.y - data->gradient.radial.focal.y;
v->a = data->gradient.radial.radius*data->gradient.radial.radius - v->dx*v->dx - v->dy*v->dy;
}
static const uint * QT_FASTCALL fetchRadialGradient(uint *buffer, const Operator *op, const QSpanData *data,
int y, int x, int length)
{
const uint *b = buffer;
qreal rx = data->m21 * (y + 0.5)
+ data->dx + data->m11 * (x + 0.5);
qreal ry = data->m22 * (y + 0.5)
+ data->dy + data->m12 * (x + 0.5);
bool affine = !data->m13 && !data->m23;
//qreal r = data->gradient.radial.radius;
const uint *end = buffer + length;
if (affine) {
rx -= data->gradient.radial.focal.x;
ry -= data->gradient.radial.focal.y;
qreal inv_a = 1 / qreal(2 * op->radial.a);
const qreal delta_rx = data->m11;
const qreal delta_ry = data->m12;
qreal b = 2*(rx * op->radial.dx + ry * op->radial.dy);
qreal delta_b = 2*(delta_rx * op->radial.dx + delta_ry * op->radial.dy);
const qreal b_delta_b = 2 * b * delta_b;
const qreal delta_b_delta_b = 2 * delta_b * delta_b;
const qreal bb = b * b;
const qreal delta_bb = delta_b * delta_b;
b *= inv_a;
delta_b *= inv_a;
const qreal rxrxryry = rx * rx + ry * ry;
const qreal delta_rxrxryry = delta_rx * delta_rx + delta_ry * delta_ry;
const qreal rx_plus_ry = 2*(rx * delta_rx + ry * delta_ry);
const qreal delta_rx_plus_ry = 2 * delta_rxrxryry;
inv_a *= inv_a;
qreal det = (bb + 4 * op->radial.a * rxrxryry) * inv_a;
qreal delta_det = (b_delta_b + delta_bb + 4 * op->radial.a * (rx_plus_ry + delta_rxrxryry)) * inv_a;
const qreal delta_delta_det = (delta_b_delta_b + 4 * op->radial.a * delta_rx_plus_ry) * inv_a;
while (buffer < end) {
*buffer = qt_gradient_pixel(&data->gradient, qSafeSqrt(det) - b);
det += delta_det;
delta_det += delta_delta_det;
b += delta_b;
++buffer;
}
} else {
qreal rw = data->m23 * (y + 0.5)
+ data->m33 + data->m13 * (x + 0.5);
if (!rw)
rw = 1;
while (buffer < end) {
qreal gx = rx/rw - data->gradient.radial.focal.x;
qreal gy = ry/rw - data->gradient.radial.focal.y;
qreal b = 2*(gx*op->radial.dx + gy*op->radial.dy);
qreal det = determinant(op->radial.a, b , -(gx*gx + gy*gy));
qreal s = realRoots(op->radial.a, b, qSafeSqrt(det));
*buffer = qt_gradient_pixel(&data->gradient, s);
rx += data->m11;
ry += data->m12;
rw += data->m13;
if (!rw) {
rw += data->m13;
}
++buffer;
}
}
return b;
}
static const uint * QT_FASTCALL fetchConicalGradient(uint *buffer, const Operator *, const QSpanData *data,
int y, int x, int length)
{
const uint *b = buffer;
qreal rx = data->m21 * (y + 0.5)
+ data->dx + data->m11 * (x + 0.5);
qreal ry = data->m22 * (y + 0.5)
+ data->dy + data->m12 * (x + 0.5);
bool affine = !data->m13 && !data->m23;
const uint *end = buffer + length;
if (affine) {
rx -= data->gradient.conical.center.x;
ry -= data->gradient.conical.center.y;
while (buffer < end) {
qreal angle = qAtan2(ry, rx) + data->gradient.conical.angle;
*buffer = qt_gradient_pixel(&data->gradient, 1 - angle / (2*Q_PI));
rx += data->m11;
ry += data->m12;
++buffer;
}
} else {
qreal rw = data->m23 * (y + 0.5)
+ data->m33 + data->m13 * (x + 0.5);
if (!rw)
rw = 1;
while (buffer < end) {
qreal angle = qAtan2(ry/rw - data->gradient.conical.center.x,
rx/rw - data->gradient.conical.center.y)
+ data->gradient.conical.angle;
*buffer = qt_gradient_pixel(&data->gradient, 1. - angle / (2*Q_PI));
rx += data->m11;
ry += data->m12;
rw += data->m13;
if (!rw) {
rw += data->m13;
}
++buffer;
}
}
return b;
}
#if defined(Q_CC_RVCT)
// Force ARM code generation for comp_func_* -methods
# pragma push
# pragma arm
# if defined(QT_HAVE_ARMV6)
static __forceinline void preload(const uint *start)
{
asm( "pld [start]" );
}
static const uint L2CacheLineLength = 32;
static const uint L2CacheLineLengthInInts = L2CacheLineLength/sizeof(uint);
# define PRELOAD_INIT(x) preload(x);
# define PRELOAD_INIT2(x,y) PRELOAD_INIT(x) PRELOAD_INIT(y)
# define PRELOAD_COND(x) if (((uint)&x[i])%L2CacheLineLength == 0) preload(&x[i] + L2CacheLineLengthInInts);
// Two consecutive preloads stall, so space them out a bit by using different modulus.
# define PRELOAD_COND2(x,y) if (((uint)&x[i])%L2CacheLineLength == 0) preload(&x[i] + L2CacheLineLengthInInts); \
if (((uint)&y[i])%L2CacheLineLength == 16) preload(&y[i] + L2CacheLineLengthInInts);
# endif // QT_HAVE_ARMV6
#endif // Q_CC_RVCT
#if !defined(Q_CC_RVCT) || !defined(QT_HAVE_ARMV6)
# define PRELOAD_INIT(x)
# define PRELOAD_INIT2(x,y)
# define PRELOAD_COND(x)
# define PRELOAD_COND2(x,y)
#endif
/* The constant alpha factor describes an alpha factor that gets applied
to the result of the composition operation combining it with the destination.
The intent is that if const_alpha == 0. we get back dest, and if const_alpha == 1.
we get the unmodified operation
result = src op dest
dest = result * const_alpha + dest * (1. - const_alpha)
This means that in the comments below, the first line is the const_alpha==255 case, the
second line the general one.
In the lines below:
s == src, sa == alpha(src), sia = 1 - alpha(src)
d == dest, da == alpha(dest), dia = 1 - alpha(dest)
ca = const_alpha, cia = 1 - const_alpha
The methods exist in two variants. One where we have a constant source, the other
where the source is an array of pixels.
*/
/*
result = 0
d = d * cia
*/
static void QT_FASTCALL comp_func_solid_Clear(uint *dest, int length, uint, uint const_alpha)
{
if (const_alpha == 255) {
QT_MEMFILL_UINT(dest, length, 0);
} else {
int ialpha = 255 - const_alpha;
PRELOAD_INIT(dest)
for (int i = 0; i < length; ++i) {
PRELOAD_COND(dest)
dest[i] = BYTE_MUL(dest[i], ialpha);
}
}
}
static void QT_FASTCALL comp_func_Clear(uint *dest, const uint *, int length, uint const_alpha)
{
if (const_alpha == 255) {
QT_MEMFILL_UINT(dest, length, 0);
} else {
int ialpha = 255 - const_alpha;
PRELOAD_INIT(dest)
for (int i = 0; i < length; ++i) {
PRELOAD_COND(dest)
dest[i] = BYTE_MUL(dest[i], ialpha);
}
}
}
/*
result = s
dest = s * ca + d * cia
*/
static void QT_FASTCALL comp_func_solid_Source(uint *dest, int length, uint color, uint const_alpha)
{
if (const_alpha == 255) {
QT_MEMFILL_UINT(dest, length, color);
} else {
int ialpha = 255 - const_alpha;
color = BYTE_MUL(color, const_alpha);
PRELOAD_INIT(dest)
for (int i = 0; i < length; ++i) {
PRELOAD_COND(dest)
dest[i] = color + BYTE_MUL(dest[i], ialpha);
}
}
}
static void QT_FASTCALL comp_func_Source(uint *dest, const uint *src, int length, uint const_alpha)
{
if (const_alpha == 255) {
::memcpy(dest, src, length * sizeof(uint));
} else {
int ialpha = 255 - const_alpha;
PRELOAD_INIT2(dest, src)
for (int i = 0; i < length; ++i) {
PRELOAD_COND2(dest, src)
dest[i] = INTERPOLATE_PIXEL_255(src[i], const_alpha, dest[i], ialpha);
}
}
}
static void QT_FASTCALL comp_func_solid_Destination(uint *, int, uint, uint)
{
}
static void QT_FASTCALL comp_func_Destination(uint *, const uint *, int, uint)
{
}
/*
result = s + d * sia
dest = (s + d * sia) * ca + d * cia
= s * ca + d * (sia * ca + cia)
= s * ca + d * (1 - sa*ca)
*/
static void QT_FASTCALL comp_func_solid_SourceOver(uint *dest, int length, uint color, uint const_alpha)
{
if ((const_alpha & qAlpha(color)) == 255) {
QT_MEMFILL_UINT(dest, length, color);
} else {
if (const_alpha != 255)
color = BYTE_MUL(color, const_alpha);
PRELOAD_INIT(dest)
for (int i = 0; i < length; ++i) {
PRELOAD_COND(dest)
dest[i] = color + BYTE_MUL(dest[i], qAlpha(~color));
}
}
}
static void QT_FASTCALL comp_func_SourceOver(uint *dest, const uint *src, int length, uint const_alpha)
{
PRELOAD_INIT2(dest, src)
if (const_alpha == 255) {
for (int i = 0; i < length; ++i) {
PRELOAD_COND2(dest, src)
uint s = src[i];
if (s >= 0xff000000)
dest[i] = s;
else if (s != 0)
dest[i] = s + BYTE_MUL(dest[i], qAlpha(~s));
}
} else {
for (int i = 0; i < length; ++i) {
PRELOAD_COND2(dest, src)
uint s = BYTE_MUL(src[i], const_alpha);
dest[i] = s + BYTE_MUL(dest[i], qAlpha(~s));
}
}
}
/*
result = d + s * dia
dest = (d + s * dia) * ca + d * cia
= d + s * dia * ca
*/
static void QT_FASTCALL comp_func_solid_DestinationOver(uint *dest, int length, uint color, uint const_alpha)
{
if (const_alpha != 255)
color = BYTE_MUL(color, const_alpha);
PRELOAD_INIT(dest)
for (int i = 0; i < length; ++i) {
PRELOAD_COND(dest)
uint d = dest[i];
dest[i] = d + BYTE_MUL(color, qAlpha(~d));
}
}
static void QT_FASTCALL comp_func_DestinationOver(uint *dest, const uint *src, int length, uint const_alpha)
{
PRELOAD_INIT2(dest, src)
if (const_alpha == 255) {
for (int i = 0; i < length; ++i) {
PRELOAD_COND2(dest, src)
uint d = dest[i];
dest[i] = d + BYTE_MUL(src[i], qAlpha(~d));
}
} else {
for (int i = 0; i < length; ++i) {
PRELOAD_COND2(dest, src)
uint d = dest[i];
uint s = BYTE_MUL(src[i], const_alpha);
dest[i] = d + BYTE_MUL(s, qAlpha(~d));
}
}
}
/*
result = s * da
dest = s * da * ca + d * cia
*/
static void QT_FASTCALL comp_func_solid_SourceIn(uint *dest, int length, uint color, uint const_alpha)
{
PRELOAD_INIT(dest)
if (const_alpha == 255) {
for (int i = 0; i < length; ++i) {
PRELOAD_COND(dest)
dest[i] = BYTE_MUL(color, qAlpha(dest[i]));
}
} else {
color = BYTE_MUL(color, const_alpha);
uint cia = 255 - const_alpha;
for (int i = 0; i < length; ++i) {
PRELOAD_COND(dest)
uint d = dest[i];
dest[i] = INTERPOLATE_PIXEL_255(color, qAlpha(d), d, cia);
}
}
}
static void QT_FASTCALL comp_func_SourceIn(uint *dest, const uint *src, int length, uint const_alpha)
{
PRELOAD_INIT2(dest, src)
if (const_alpha == 255) {
for (int i = 0; i < length; ++i) {
PRELOAD_COND2(dest, src)
dest[i] = BYTE_MUL(src[i], qAlpha(dest[i]));
}
} else {
uint cia = 255 - const_alpha;
for (int i = 0; i < length; ++i) {
PRELOAD_COND2(dest, src)
uint d = dest[i];
uint s = BYTE_MUL(src[i], const_alpha);
dest[i] = INTERPOLATE_PIXEL_255(s, qAlpha(d), d, cia);
}
}
}
/*
result = d * sa
dest = d * sa * ca + d * cia
= d * (sa * ca + cia)
*/
static void QT_FASTCALL comp_func_solid_DestinationIn(uint *dest, int length, uint color, uint const_alpha)
{
uint a = qAlpha(color);
if (const_alpha != 255) {
a = BYTE_MUL(a, const_alpha) + 255 - const_alpha;
}
PRELOAD_INIT(dest)
for (int i = 0; i < length; ++i) {
PRELOAD_COND(dest)
dest[i] = BYTE_MUL(dest[i], a);
}
}
static void QT_FASTCALL comp_func_DestinationIn(uint *dest, const uint *src, int length, uint const_alpha)
{
PRELOAD_INIT2(dest, src)
if (const_alpha == 255) {
for (int i = 0; i < length; ++i) {
PRELOAD_COND2(dest, src)
dest[i] = BYTE_MUL(dest[i], qAlpha(src[i]));
}
} else {
int cia = 255 - const_alpha;
for (int i = 0; i < length; ++i) {
PRELOAD_COND2(dest, src)
uint a = BYTE_MUL(qAlpha(src[i]), const_alpha) + cia;
dest[i] = BYTE_MUL(dest[i], a);
}
}
}
/*
result = s * dia
dest = s * dia * ca + d * cia
*/
static void QT_FASTCALL comp_func_solid_SourceOut(uint *dest, int length, uint color, uint const_alpha)
{
PRELOAD_INIT(dest)
if (const_alpha == 255) {
for (int i = 0; i < length; ++i) {
PRELOAD_COND(dest)
dest[i] = BYTE_MUL(color, qAlpha(~dest[i]));
}
} else {
color = BYTE_MUL(color, const_alpha);
int cia = 255 - const_alpha;
for (int i = 0; i < length; ++i) {
PRELOAD_COND(dest)
uint d = dest[i];
dest[i] = INTERPOLATE_PIXEL_255(color, qAlpha(~d), d, cia);
}
}
}
static void QT_FASTCALL comp_func_SourceOut(uint *dest, const uint *src, int length, uint const_alpha)
{
PRELOAD_INIT2(dest, src)
if (const_alpha == 255) {
for (int i = 0; i < length; ++i) {
PRELOAD_COND2(dest, src)
dest[i] = BYTE_MUL(src[i], qAlpha(~dest[i]));
}
} else {
int cia = 255 - const_alpha;
for (int i = 0; i < length; ++i) {
PRELOAD_COND2(dest, src)
uint s = BYTE_MUL(src[i], const_alpha);
uint d = dest[i];
dest[i] = INTERPOLATE_PIXEL_255(s, qAlpha(~d), d, cia);
}
}
}
/*
result = d * sia
dest = d * sia * ca + d * cia
= d * (sia * ca + cia)
*/
static void QT_FASTCALL comp_func_solid_DestinationOut(uint *dest, int length, uint color, uint const_alpha)
{
uint a = qAlpha(~color);
if (const_alpha != 255)
a = BYTE_MUL(a, const_alpha) + 255 - const_alpha;
PRELOAD_INIT(dest)
for (int i = 0; i < length; ++i) {
PRELOAD_COND(dest)
dest[i] = BYTE_MUL(dest[i], a);
}
}
static void QT_FASTCALL comp_func_DestinationOut(uint *dest, const uint *src, int length, uint const_alpha)
{
PRELOAD_INIT2(dest, src)
if (const_alpha == 255) {
for (int i = 0; i < length; ++i) {
PRELOAD_COND2(dest, src)
dest[i] = BYTE_MUL(dest[i], qAlpha(~src[i]));
}
} else {
int cia = 255 - const_alpha;
for (int i = 0; i < length; ++i) {
PRELOAD_COND2(dest, src)
uint sia = BYTE_MUL(qAlpha(~src[i]), const_alpha) + cia;
dest[i] = BYTE_MUL(dest[i], sia);
}
}
}
/*
result = s*da + d*sia
dest = s*da*ca + d*sia*ca + d *cia
= s*ca * da + d * (sia*ca + cia)
= s*ca * da + d * (1 - sa*ca)
*/
static void QT_FASTCALL comp_func_solid_SourceAtop(uint *dest, int length, uint color, uint const_alpha)
{
if (const_alpha != 255) {
color = BYTE_MUL(color, const_alpha);
}
uint sia = qAlpha(~color);
PRELOAD_INIT(dest)
for (int i = 0; i < length; ++i) {
PRELOAD_COND(dest)
dest[i] = INTERPOLATE_PIXEL_255(color, qAlpha(dest[i]), dest[i], sia);
}
}
static void QT_FASTCALL comp_func_SourceAtop(uint *dest, const uint *src, int length, uint const_alpha)
{
PRELOAD_INIT2(dest, src)
if (const_alpha == 255) {
for (int i = 0; i < length; ++i) {
PRELOAD_COND2(dest, src)
uint s = src[i];
uint d = dest[i];
dest[i] = INTERPOLATE_PIXEL_255(s, qAlpha(d), d, qAlpha(~s));
}
} else {
for (int i = 0; i < length; ++i) {
PRELOAD_COND2(dest, src)
uint s = BYTE_MUL(src[i], const_alpha);
uint d = dest[i];
dest[i] = INTERPOLATE_PIXEL_255(s, qAlpha(d), d, qAlpha(~s));
}
}
}
/*
result = d*sa + s*dia
dest = d*sa*ca + s*dia*ca + d *cia
= s*ca * dia + d * (sa*ca + cia)
*/
static void QT_FASTCALL comp_func_solid_DestinationAtop(uint *dest, int length, uint color, uint const_alpha)
{
uint a = qAlpha(color);
if (const_alpha != 255) {
color = BYTE_MUL(color, const_alpha);
a = qAlpha(color) + 255 - const_alpha;
}
PRELOAD_INIT(dest)
for (int i = 0; i < length; ++i) {
PRELOAD_COND(dest)
uint d = dest[i];
dest[i] = INTERPOLATE_PIXEL_255(d, a, color, qAlpha(~d));
}
}
static void QT_FASTCALL comp_func_DestinationAtop(uint *dest, const uint *src, int length, uint const_alpha)
{
PRELOAD_INIT2(dest, src)
if (const_alpha == 255) {
for (int i = 0; i < length; ++i) {
PRELOAD_COND2(dest, src)
uint s = src[i];
uint d = dest[i];
dest[i] = INTERPOLATE_PIXEL_255(d, qAlpha(s), s, qAlpha(~d));
}
} else {
int cia = 255 - const_alpha;
for (int i = 0; i < length; ++i) {
PRELOAD_COND2(dest, src)
uint s = BYTE_MUL(src[i], const_alpha);
uint d = dest[i];
uint a = qAlpha(s) + cia;
dest[i] = INTERPOLATE_PIXEL_255(d, a, s, qAlpha(~d));
}
}
}
/*
result = d*sia + s*dia
dest = d*sia*ca + s*dia*ca + d *cia
= s*ca * dia + d * (sia*ca + cia)
= s*ca * dia + d * (1 - sa*ca)
*/
static void QT_FASTCALL comp_func_solid_XOR(uint *dest, int length, uint color, uint const_alpha)
{
if (const_alpha != 255)
color = BYTE_MUL(color, const_alpha);
uint sia = qAlpha(~color);
PRELOAD_INIT(dest)
for (int i = 0; i < length; ++i) {
PRELOAD_COND(dest)
uint d = dest[i];
dest[i] = INTERPOLATE_PIXEL_255(color, qAlpha(~d), d, sia);
}
}
static void QT_FASTCALL comp_func_XOR(uint *dest, const uint *src, int length, uint const_alpha)
{
PRELOAD_INIT2(dest, src)
if (const_alpha == 255) {
for (int i = 0; i < length; ++i) {
PRELOAD_COND2(dest, src)
uint d = dest[i];
uint s = src[i];
dest[i] = INTERPOLATE_PIXEL_255(s, qAlpha(~d), d, qAlpha(~s));
}
} else {
for (int i = 0; i < length; ++i) {
PRELOAD_COND2(dest, src)
uint d = dest[i];
uint s = BYTE_MUL(src[i], const_alpha);
dest[i] = INTERPOLATE_PIXEL_255(s, qAlpha(~d), d, qAlpha(~s));
}
}
}
static const uint AMASK = 0xff000000;
static const uint RMASK = 0x00ff0000;
static const uint GMASK = 0x0000ff00;
static const uint BMASK = 0x000000ff;
struct QFullCoverage {
inline void store(uint *dest, const uint src) const
{
*dest = src;
}
};
struct QPartialCoverage {
inline QPartialCoverage(uint const_alpha)
: ca(const_alpha)
, ica(255 - const_alpha)
{
}
inline void store(uint *dest, const uint src) const
{
*dest = INTERPOLATE_PIXEL_255(src, ca, *dest, ica);
}
private:
const uint ca;
const uint ica;
};
static inline int mix_alpha(int da, int sa)
{
return 255 - ((255 - sa) * (255 - da) >> 8);
}
/*
Dca' = Sca.Da + Dca.Sa + Sca.(1 - Da) + Dca.(1 - Sa)
= Sca + Dca
*/
template <typename T>
Q_STATIC_TEMPLATE_FUNCTION inline void comp_func_solid_Plus_impl(uint *dest, int length, uint color, const T &coverage)
{
uint s = color;
PRELOAD_INIT(dest)
for (int i = 0; i < length; ++i) {
PRELOAD_COND(dest)
uint d = dest[i];
#define MIX(mask) (qMin(((qint64(s)&mask) + (qint64(d)&mask)), qint64(mask)))
d = (MIX(AMASK) | MIX(RMASK) | MIX(GMASK) | MIX(BMASK));
#undef MIX
coverage.store(&dest[i], d);
}
}
static void QT_FASTCALL comp_func_solid_Plus(uint *dest, int length, uint color, uint const_alpha)
{
if (const_alpha == 255)
comp_func_solid_Plus_impl(dest, length, color, QFullCoverage());
else
comp_func_solid_Plus_impl(dest, length, color, QPartialCoverage(const_alpha));
}
template <typename T>
Q_STATIC_TEMPLATE_FUNCTION inline void comp_func_Plus_impl(uint *dest, const uint *src, int length, const T &coverage)
{
PRELOAD_INIT2(dest, src)
for (int i = 0; i < length; ++i) {
PRELOAD_COND2(dest, src)
uint d = dest[i];
uint s = src[i];
#define MIX(mask) (qMin(((qint64(s)&mask) + (qint64(d)&mask)), qint64(mask)))
d = (MIX(AMASK) | MIX(RMASK) | MIX(GMASK) | MIX(BMASK));
#undef MIX
coverage.store(&dest[i], d);
}
}
static void QT_FASTCALL comp_func_Plus(uint *dest, const uint *src, int length, uint const_alpha)
{
if (const_alpha == 255)
comp_func_Plus_impl(dest, src, length, QFullCoverage());
else
comp_func_Plus_impl(dest, src, length, QPartialCoverage(const_alpha));
}
/*
Dca' = Sca.Dca + Sca.(1 - Da) + Dca.(1 - Sa)
*/
static inline int multiply_op(int dst, int src, int da, int sa)
{
return qt_div_255(src * dst + src * (255 - da) + dst * (255 - sa));
}
template <typename T>
Q_STATIC_TEMPLATE_FUNCTION inline void comp_func_solid_Multiply_impl(uint *dest, int length, uint color, const T &coverage)
{
int sa = qAlpha(color);
int sr = qRed(color);
int sg = qGreen(color);
int sb = qBlue(color);
PRELOAD_INIT(dest)
for (int i = 0; i < length; ++i) {
PRELOAD_COND(dest)
uint d = dest[i];
int da = qAlpha(d);
#define OP(a, b) multiply_op(a, b, da, sa)
int r = OP( qRed(d), sr);
int b = OP( qBlue(d), sb);
int g = OP(qGreen(d), sg);
int a = mix_alpha(da, sa);
#undef OP
coverage.store(&dest[i], qRgba(r, g, b, a));
}
}
static void QT_FASTCALL comp_func_solid_Multiply(uint *dest, int length, uint color, uint const_alpha)
{
if (const_alpha == 255)
comp_func_solid_Multiply_impl(dest, length, color, QFullCoverage());
else
comp_func_solid_Multiply_impl(dest, length, color, QPartialCoverage(const_alpha));
}
template <typename T>
Q_STATIC_TEMPLATE_FUNCTION inline void comp_func_Multiply_impl(uint *dest, const uint *src, int length, const T &coverage)
{
PRELOAD_INIT2(dest, src)
for (int i = 0; i < length; ++i) {
PRELOAD_COND2(dest, src)
uint d = dest[i];
uint s = src[i];
int da = qAlpha(d);
int sa = qAlpha(s);
#define OP(a, b) multiply_op(a, b, da, sa)
int r = OP( qRed(d), qRed(s));
int b = OP( qBlue(d), qBlue(s));
int g = OP(qGreen(d), qGreen(s));
int a = mix_alpha(da, sa);
#undef OP
coverage.store(&dest[i], qRgba(r, g, b, a));
}
}
static void QT_FASTCALL comp_func_Multiply(uint *dest, const uint *src, int length, uint const_alpha)
{
if (const_alpha == 255)
comp_func_Multiply_impl(dest, src, length, QFullCoverage());
else
comp_func_Multiply_impl(dest, src, length, QPartialCoverage(const_alpha));
}
/*
Dca' = (Sca.Da + Dca.Sa - Sca.Dca) + Sca.(1 - Da) + Dca.(1 - Sa)
= Sca + Dca - Sca.Dca
*/
template <typename T>
Q_STATIC_TEMPLATE_FUNCTION inline void comp_func_solid_Screen_impl(uint *dest, int length, uint color, const T &coverage)
{
int sa = qAlpha(color);
int sr = qRed(color);
int sg = qGreen(color);
int sb = qBlue(color);
PRELOAD_INIT(dest)
for (int i = 0; i < length; ++i) {
PRELOAD_COND(dest)
uint d = dest[i];
int da = qAlpha(d);
#define OP(a, b) 255 - qt_div_255((255-a) * (255-b))
int r = OP( qRed(d), sr);
int b = OP( qBlue(d), sb);
int g = OP(qGreen(d), sg);
int a = mix_alpha(da, sa);
#undef OP
coverage.store(&dest[i], qRgba(r, g, b, a));
}
}
static void QT_FASTCALL comp_func_solid_Screen(uint *dest, int length, uint color, uint const_alpha)
{
if (const_alpha == 255)
comp_func_solid_Screen_impl(dest, length, color, QFullCoverage());
else
comp_func_solid_Screen_impl(dest, length, color, QPartialCoverage(const_alpha));
}
template <typename T>
Q_STATIC_TEMPLATE_FUNCTION inline void comp_func_Screen_impl(uint *dest, const uint *src, int length, const T &coverage)
{
PRELOAD_INIT2(dest, src)
for (int i = 0; i < length; ++i) {
PRELOAD_COND2(dest, src)
uint d = dest[i];
uint s = src[i];
int da = qAlpha(d);
int sa = qAlpha(s);
#define OP(a, b) 255 - (((255-a) * (255-b)) >> 8)
int r = OP( qRed(d), qRed(s));
int b = OP( qBlue(d), qBlue(s));
int g = OP(qGreen(d), qGreen(s));
int a = mix_alpha(da, sa);
#undef OP
coverage.store(&dest[i], qRgba(r, g, b, a));
}
}
static void QT_FASTCALL comp_func_Screen(uint *dest, const uint *src, int length, uint const_alpha)
{
if (const_alpha == 255)
comp_func_Screen_impl(dest, src, length, QFullCoverage());
else
comp_func_Screen_impl(dest, src, length, QPartialCoverage(const_alpha));
}
/*
if 2.Dca < Da
Dca' = 2.Sca.Dca + Sca.(1 - Da) + Dca.(1 - Sa)
otherwise
Dca' = Sa.Da - 2.(Da - Dca).(Sa - Sca) + Sca.(1 - Da) + Dca.(1 - Sa)
*/
static inline int overlay_op(int dst, int src, int da, int sa)
{
const int temp = src * (255 - da) + dst * (255 - sa);
if (2 * dst < da)
return qt_div_255(2 * src * dst + temp);
else
return qt_div_255(sa * da - 2 * (da - dst) * (sa - src) + temp);
}
template <typename T>
Q_STATIC_TEMPLATE_FUNCTION inline void comp_func_solid_Overlay_impl(uint *dest, int length, uint color, const T &coverage)
{
int sa = qAlpha(color);
int sr = qRed(color);
int sg = qGreen(color);
int sb = qBlue(color);
PRELOAD_INIT(dest)
for (int i = 0; i < length; ++i) {
PRELOAD_COND(dest)
uint d = dest[i];
int da = qAlpha(d);
#define OP(a, b) overlay_op(a, b, da, sa)
int r = OP( qRed(d), sr);
int b = OP( qBlue(d), sb);
int g = OP(qGreen(d), sg);
int a = mix_alpha(da, sa);
#undef OP
coverage.store(&dest[i], qRgba(r, g, b, a));
}
}
static void QT_FASTCALL comp_func_solid_Overlay(uint *dest, int length, uint color, uint const_alpha)
{
if (const_alpha == 255)
comp_func_solid_Overlay_impl(dest, length, color, QFullCoverage());
else
comp_func_solid_Overlay_impl(dest, length, color, QPartialCoverage(const_alpha));
}
template <typename T>
Q_STATIC_TEMPLATE_FUNCTION inline void comp_func_Overlay_impl(uint *dest, const uint *src, int length, const T &coverage)
{
PRELOAD_INIT2(dest, src)
for (int i = 0; i < length; ++i) {
PRELOAD_COND2(dest, src)
uint d = dest[i];
uint s = src[i];
int da = qAlpha(d);
int sa = qAlpha(s);
#define OP(a, b) overlay_op(a, b, da, sa)
int r = OP( qRed(d), qRed(s));
int b = OP( qBlue(d), qBlue(s));
int g = OP(qGreen(d), qGreen(s));
int a = mix_alpha(da, sa);
#undef OP
coverage.store(&dest[i], qRgba(r, g, b, a));
}
}
static void QT_FASTCALL comp_func_Overlay(uint *dest, const uint *src, int length, uint const_alpha)
{
if (const_alpha == 255)
comp_func_Overlay_impl(dest, src, length, QFullCoverage());
else
comp_func_Overlay_impl(dest, src, length, QPartialCoverage(const_alpha));
}
/*
Dca' = min(Sca.Da, Dca.Sa) + Sca.(1 - Da) + Dca.(1 - Sa)
Da' = Sa + Da - Sa.Da
*/
static inline int darken_op(int dst, int src, int da, int sa)
{
return qt_div_255(qMin(src * da, dst * sa) + src * (255 - da) + dst * (255 - sa));
}
template <typename T>
Q_STATIC_TEMPLATE_FUNCTION inline void comp_func_solid_Darken_impl(uint *dest, int length, uint color, const T &coverage)
{
int sa = qAlpha(color);
int sr = qRed(color);
int sg = qGreen(color);
int sb = qBlue(color);
PRELOAD_INIT(dest)
for (int i = 0; i < length; ++i) {
PRELOAD_COND(dest)
uint d = dest[i];
int da = qAlpha(d);
#define OP(a, b) darken_op(a, b, da, sa)
int r = OP( qRed(d), sr);
int b = OP( qBlue(d), sb);
int g = OP(qGreen(d), sg);
int a = mix_alpha(da, sa);
#undef OP
coverage.store(&dest[i], qRgba(r, g, b, a));
}
}
static void QT_FASTCALL comp_func_solid_Darken(uint *dest, int length, uint color, uint const_alpha)
{
if (const_alpha == 255)
comp_func_solid_Darken_impl(dest, length, color, QFullCoverage());
else
comp_func_solid_Darken_impl(dest, length, color, QPartialCoverage(const_alpha));
}
template <typename T>
Q_STATIC_TEMPLATE_FUNCTION inline void comp_func_Darken_impl(uint *dest, const uint *src, int length, const T &coverage)
{
PRELOAD_INIT2(dest, src)
for (int i = 0; i < length; ++i) {
PRELOAD_COND2(dest, src)
uint d = dest[i];
uint s = src[i];
int da = qAlpha(d);
int sa = qAlpha(s);
#define OP(a, b) darken_op(a, b, da, sa)
int r = OP( qRed(d), qRed(s));
int b = OP( qBlue(d), qBlue(s));
int g = OP(qGreen(d), qGreen(s));
int a = mix_alpha(da, sa);
#undef OP
coverage.store(&dest[i], qRgba(r, g, b, a));
}
}
static void QT_FASTCALL comp_func_Darken(uint *dest, const uint *src, int length, uint const_alpha)
{
if (const_alpha == 255)
comp_func_Darken_impl(dest, src, length, QFullCoverage());
else
comp_func_Darken_impl(dest, src, length, QPartialCoverage(const_alpha));
}
/*
Dca' = max(Sca.Da, Dca.Sa) + Sca.(1 - Da) + Dca.(1 - Sa)
Da' = Sa + Da - Sa.Da
*/
static inline int lighten_op(int dst, int src, int da, int sa)
{
return qt_div_255(qMax(src * da, dst * sa) + src * (255 - da) + dst * (255 - sa));
}
template <typename T>
Q_STATIC_TEMPLATE_FUNCTION inline void comp_func_solid_Lighten_impl(uint *dest, int length, uint color, const T &coverage)
{
int sa = qAlpha(color);
int sr = qRed(color);
int sg = qGreen(color);
int sb = qBlue(color);
PRELOAD_INIT(dest)
for (int i = 0; i < length; ++i) {
PRELOAD_COND(dest)
uint d = dest[i];
int da = qAlpha(d);
#define OP(a, b) lighten_op(a, b, da, sa)
int r = OP( qRed(d), sr);
int b = OP( qBlue(d), sb);
int g = OP(qGreen(d), sg);
int a = mix_alpha(da, sa);
#undef OP
coverage.store(&dest[i], qRgba(r, g, b, a));
}
}
static void QT_FASTCALL comp_func_solid_Lighten(uint *dest, int length, uint color, uint const_alpha)
{
if (const_alpha == 255)
comp_func_solid_Lighten_impl(dest, length, color, QFullCoverage());
else
comp_func_solid_Lighten_impl(dest, length, color, QPartialCoverage(const_alpha));
}
template <typename T>
Q_STATIC_TEMPLATE_FUNCTION inline void comp_func_Lighten_impl(uint *dest, const uint *src, int length, const T &coverage)
{
PRELOAD_INIT2(dest, src)
for (int i = 0; i < length; ++i) {
PRELOAD_COND2(dest, src)
uint d = dest[i];
uint s = src[i];
int da = qAlpha(d);
int sa = qAlpha(s);
#define OP(a, b) lighten_op(a, b, da, sa)
int r = OP( qRed(d), qRed(s));
int b = OP( qBlue(d), qBlue(s));
int g = OP(qGreen(d), qGreen(s));
int a = mix_alpha(da, sa);
#undef OP
coverage.store(&dest[i], qRgba(r, g, b, a));
}
}
static void QT_FASTCALL comp_func_Lighten(uint *dest, const uint *src, int length, uint const_alpha)
{
if (const_alpha == 255)
comp_func_Lighten_impl(dest, src, length, QFullCoverage());
else
comp_func_Lighten_impl(dest, src, length, QPartialCoverage(const_alpha));
}
/*
if Sca.Da + Dca.Sa >= Sa.Da
Dca' = Sa.Da + Sca.(1 - Da) + Dca.(1 - Sa)
otherwise
Dca' = Dca.Sa/(1-Sca/Sa) + Sca.(1 - Da) + Dca.(1 - Sa)
*/
static inline int color_dodge_op(int dst, int src, int da, int sa)
{
const int sa_da = sa * da;
const int dst_sa = dst * sa;
const int src_da = src * da;
const int temp = src * (255 - da) + dst * (255 - sa);
if (src_da + dst_sa >= sa_da)
return qt_div_255(sa_da + temp);
else
return qt_div_255(255 * dst_sa / (255 - 255 * src / sa) + temp);
}
template <typename T>
Q_STATIC_TEMPLATE_FUNCTION inline void comp_func_solid_ColorDodge_impl(uint *dest, int length, uint color, const T &coverage)
{
int sa = qAlpha(color);
int sr = qRed(color);
int sg = qGreen(color);
int sb = qBlue(color);
PRELOAD_INIT(dest)
for (int i = 0; i < length; ++i) {
PRELOAD_COND(dest)
uint d = dest[i];
int da = qAlpha(d);
#define OP(a,b) color_dodge_op(a, b, da, sa)
int r = OP( qRed(d), sr);
int b = OP( qBlue(d), sb);
int g = OP(qGreen(d), sg);
int a = mix_alpha(da, sa);
#undef OP
coverage.store(&dest[i], qRgba(r, g, b, a));
}
}
static void QT_FASTCALL comp_func_solid_ColorDodge(uint *dest, int length, uint color, uint const_alpha)
{
if (const_alpha == 255)
comp_func_solid_ColorDodge_impl(dest, length, color, QFullCoverage());
else
comp_func_solid_ColorDodge_impl(dest, length, color, QPartialCoverage(const_alpha));
}
template <typename T>
Q_STATIC_TEMPLATE_FUNCTION inline void comp_func_ColorDodge_impl(uint *dest, const uint *src, int length, const T &coverage)
{
PRELOAD_INIT2(dest, src)
for (int i = 0; i < length; ++i) {
PRELOAD_COND2(dest, src)
uint d = dest[i];
uint s = src[i];
int da = qAlpha(d);
int sa = qAlpha(s);
#define OP(a, b) color_dodge_op(a, b, da, sa)
int r = OP( qRed(d), qRed(s));
int b = OP( qBlue(d), qBlue(s));
int g = OP(qGreen(d), qGreen(s));
int a = mix_alpha(da, sa);
#undef OP
coverage.store(&dest[i], qRgba(r, g, b, a));
}
}
static void QT_FASTCALL comp_func_ColorDodge(uint *dest, const uint *src, int length, uint const_alpha)
{
if (const_alpha == 255)
comp_func_ColorDodge_impl(dest, src, length, QFullCoverage());
else
comp_func_ColorDodge_impl(dest, src, length, QPartialCoverage(const_alpha));
}
/*
if Sca.Da + Dca.Sa <= Sa.Da
Dca' = Sca.(1 - Da) + Dca.(1 - Sa)
otherwise
Dca' = Sa.(Sca.Da + Dca.Sa - Sa.Da)/Sca + Sca.(1 - Da) + Dca.(1 - Sa)
*/
static inline int color_burn_op(int dst, int src, int da, int sa)
{
const int src_da = src * da;
const int dst_sa = dst * sa;
const int sa_da = sa * da;
const int temp = src * (255 - da) + dst * (255 - sa);
if (src == 0 || src_da + dst_sa <= sa_da)
return qt_div_255(temp);
return qt_div_255(sa * (src_da + dst_sa - sa_da) / src + temp);
}
template <typename T>
Q_STATIC_TEMPLATE_FUNCTION inline void comp_func_solid_ColorBurn_impl(uint *dest, int length, uint color, const T &coverage)
{
int sa = qAlpha(color);
int sr = qRed(color);
int sg = qGreen(color);
int sb = qBlue(color);
PRELOAD_INIT(dest)
for (int i = 0; i < length; ++i) {
PRELOAD_COND(dest)
uint d = dest[i];
int da = qAlpha(d);
#define OP(a, b) color_burn_op(a, b, da, sa)
int r = OP( qRed(d), sr);
int b = OP( qBlue(d), sb);
int g = OP(qGreen(d), sg);
int a = mix_alpha(da, sa);
#undef OP
coverage.store(&dest[i], qRgba(r, g, b, a));
}
}
static void QT_FASTCALL comp_func_solid_ColorBurn(uint *dest, int length, uint color, uint const_alpha)
{
if (const_alpha == 255)
comp_func_solid_ColorBurn_impl(dest, length, color, QFullCoverage());
else
comp_func_solid_ColorBurn_impl(dest, length, color, QPartialCoverage(const_alpha));
}
template <typename T>
Q_STATIC_TEMPLATE_FUNCTION inline void comp_func_ColorBurn_impl(uint *dest, const uint *src, int length, const T &coverage)
{
PRELOAD_INIT2(dest, src)
for (int i = 0; i < length; ++i) {
PRELOAD_COND2(dest, src)
uint d = dest[i];
uint s = src[i];
int da = qAlpha(d);
int sa = qAlpha(s);
#define OP(a, b) color_burn_op(a, b, da, sa)
int r = OP( qRed(d), qRed(s));
int b = OP( qBlue(d), qBlue(s));
int g = OP(qGreen(d), qGreen(s));
int a = mix_alpha(da, sa);
#undef OP
coverage.store(&dest[i], qRgba(r, g, b, a));
}
}
static void QT_FASTCALL comp_func_ColorBurn(uint *dest, const uint *src, int length, uint const_alpha)
{
if (const_alpha == 255)
comp_func_ColorBurn_impl(dest, src, length, QFullCoverage());
else
comp_func_ColorBurn_impl(dest, src, length, QPartialCoverage(const_alpha));
}
/*
if 2.Sca < Sa
Dca' = 2.Sca.Dca + Sca.(1 - Da) + Dca.(1 - Sa)
otherwise
Dca' = Sa.Da - 2.(Da - Dca).(Sa - Sca) + Sca.(1 - Da) + Dca.(1 - Sa)
*/
static inline uint hardlight_op(int dst, int src, int da, int sa)
{
const uint temp = src * (255 - da) + dst * (255 - sa);
if (2 * src < sa)
return qt_div_255(2 * src * dst + temp);
else
return qt_div_255(sa * da - 2 * (da - dst) * (sa - src) + temp);
}
template <typename T>
Q_STATIC_TEMPLATE_FUNCTION inline void comp_func_solid_HardLight_impl(uint *dest, int length, uint color, const T &coverage)
{
int sa = qAlpha(color);
int sr = qRed(color);
int sg = qGreen(color);
int sb = qBlue(color);
PRELOAD_INIT(dest)
for (int i = 0; i < length; ++i) {
PRELOAD_COND(dest)
uint d = dest[i];
int da = qAlpha(d);
#define OP(a, b) hardlight_op(a, b, da, sa)
int r = OP( qRed(d), sr);
int b = OP( qBlue(d), sb);
int g = OP(qGreen(d), sg);
int a = mix_alpha(da, sa);
#undef OP
coverage.store(&dest[i], qRgba(r, g, b, a));
}
}
static void QT_FASTCALL comp_func_solid_HardLight(uint *dest, int length, uint color, uint const_alpha)
{
if (const_alpha == 255)
comp_func_solid_HardLight_impl(dest, length, color, QFullCoverage());
else
comp_func_solid_HardLight_impl(dest, length, color, QPartialCoverage(const_alpha));
}
template <typename T>
Q_STATIC_TEMPLATE_FUNCTION inline void comp_func_HardLight_impl(uint *dest, const uint *src, int length, const T &coverage)
{
PRELOAD_INIT2(dest, src)
for (int i = 0; i < length; ++i) {
PRELOAD_COND2(dest, src)
uint d = dest[i];
uint s = src[i];
int da = qAlpha(d);
int sa = qAlpha(s);
#define OP(a, b) hardlight_op(a, b, da, sa)
int r = OP( qRed(d), qRed(s));
int b = OP( qBlue(d), qBlue(s));
int g = OP(qGreen(d), qGreen(s));
int a = mix_alpha(da, sa);
#undef OP
coverage.store(&dest[i], qRgba(r, g, b, a));
}
}
static void QT_FASTCALL comp_func_HardLight(uint *dest, const uint *src, int length, uint const_alpha)
{
if (const_alpha == 255)
comp_func_HardLight_impl(dest, src, length, QFullCoverage());
else
comp_func_HardLight_impl(dest, src, length, QPartialCoverage(const_alpha));
}
/*
if 2.Sca <= Sa
Dca' = Dca.(Sa + (2.Sca - Sa).(1 - Dca/Da)) + Sca.(1 - Da) + Dca.(1 - Sa)
otherwise if 2.Sca > Sa and 4.Dca <= Da
Dca' = Dca.Sa + Da.(2.Sca - Sa).(4.Dca/Da.(4.Dca/Da + 1).(Dca/Da - 1) + 7.Dca/Da) + Sca.(1 - Da) + Dca.(1 - Sa)
otherwise if 2.Sca > Sa and 4.Dca > Da
Dca' = Dca.Sa + Da.(2.Sca - Sa).((Dca/Da)^0.5 - Dca/Da) + Sca.(1 - Da) + Dca.(1 - Sa)
*/
static inline int soft_light_op(int dst, int src, int da, int sa)
{
const int src2 = src << 1;
const int dst_np = da != 0 ? (255 * dst) / da : 0;
const int temp = (src * (255 - da) + dst * (255 - sa)) * 255;
if (src2 < sa)
return (dst * (sa * 255 + (src2 - sa) * (255 - dst_np)) + temp) / 65025;
else if (4 * dst <= da)
return (dst * sa * 255 + da * (src2 - sa) * ((((16 * dst_np - 12 * 255) * dst_np + 3 * 65025) * dst_np) / 65025) + temp) / 65025;
else {
return (dst * sa * 255 + da * (src2 - sa) * (int(sqrt(qreal(dst_np * 255))) - dst_np) + temp) / 65025;
}
}
template <typename T>
Q_STATIC_TEMPLATE_FUNCTION inline void comp_func_solid_SoftLight_impl(uint *dest, int length, uint color, const T &coverage)
{
int sa = qAlpha(color);
int sr = qRed(color);
int sg = qGreen(color);
int sb = qBlue(color);
PRELOAD_INIT(dest)
for (int i = 0; i < length; ++i) {
PRELOAD_COND(dest)
uint d = dest[i];
int da = qAlpha(d);
#define OP(a, b) soft_light_op(a, b, da, sa)
int r = OP( qRed(d), sr);
int b = OP( qBlue(d), sb);
int g = OP(qGreen(d), sg);
int a = mix_alpha(da, sa);
#undef OP
coverage.store(&dest[i], qRgba(r, g, b, a));
}
}
static void QT_FASTCALL comp_func_solid_SoftLight(uint *dest, int length, uint color, uint const_alpha)
{
if (const_alpha == 255)
comp_func_solid_SoftLight_impl(dest, length, color, QFullCoverage());
else
comp_func_solid_SoftLight_impl(dest, length, color, QPartialCoverage(const_alpha));
}
template <typename T>
Q_STATIC_TEMPLATE_FUNCTION inline void comp_func_SoftLight_impl(uint *dest, const uint *src, int length, const T &coverage)
{
PRELOAD_INIT2(dest, src)
for (int i = 0; i < length; ++i) {
PRELOAD_COND2(dest, src)
uint d = dest[i];
uint s = src[i];
int da = qAlpha(d);
int sa = qAlpha(s);
#define OP(a, b) soft_light_op(a, b, da, sa)
int r = OP( qRed(d), qRed(s));
int b = OP( qBlue(d), qBlue(s));
int g = OP(qGreen(d), qGreen(s));
int a = mix_alpha(da, sa);
#undef OP
coverage.store(&dest[i], qRgba(r, g, b, a));
}
}
static void QT_FASTCALL comp_func_SoftLight(uint *dest, const uint *src, int length, uint const_alpha)
{
if (const_alpha == 255)
comp_func_SoftLight_impl(dest, src, length, QFullCoverage());
else
comp_func_SoftLight_impl(dest, src, length, QPartialCoverage(const_alpha));
}
/*
Dca' = abs(Dca.Sa - Sca.Da) + Sca.(1 - Da) + Dca.(1 - Sa)
= Sca + Dca - 2.min(Sca.Da, Dca.Sa)
*/
static inline int difference_op(int dst, int src, int da, int sa)
{
return src + dst - qt_div_255(2 * qMin(src * da, dst * sa));
}
template <typename T>
Q_STATIC_TEMPLATE_FUNCTION inline void comp_func_solid_Difference_impl(uint *dest, int length, uint color, const T &coverage)
{
int sa = qAlpha(color);
int sr = qRed(color);
int sg = qGreen(color);
int sb = qBlue(color);
PRELOAD_INIT(dest)
for (int i = 0; i < length; ++i) {
PRELOAD_COND(dest)
uint d = dest[i];
int da = qAlpha(d);
#define OP(a, b) difference_op(a, b, da, sa)
int r = OP( qRed(d), sr);
int b = OP( qBlue(d), sb);
int g = OP(qGreen(d), sg);
int a = mix_alpha(da, sa);
#undef OP
coverage.store(&dest[i], qRgba(r, g, b, a));
}
}
static void QT_FASTCALL comp_func_solid_Difference(uint *dest, int length, uint color, uint const_alpha)
{
if (const_alpha == 255)
comp_func_solid_Difference_impl(dest, length, color, QFullCoverage());
else
comp_func_solid_Difference_impl(dest, length, color, QPartialCoverage(const_alpha));
}
template <typename T>
Q_STATIC_TEMPLATE_FUNCTION inline void comp_func_Difference_impl(uint *dest, const uint *src, int length, const T &coverage)
{
PRELOAD_INIT2(dest, src)
for (int i = 0; i < length; ++i) {
PRELOAD_COND2(dest, src)
uint d = dest[i];
uint s = src[i];
int da = qAlpha(d);
int sa = qAlpha(s);
#define OP(a, b) difference_op(a, b, da, sa)
int r = OP( qRed(d), qRed(s));
int b = OP( qBlue(d), qBlue(s));
int g = OP(qGreen(d), qGreen(s));
int a = mix_alpha(da, sa);
#undef OP
coverage.store(&dest[i], qRgba(r, g, b, a));
}
}
static void QT_FASTCALL comp_func_Difference(uint *dest, const uint *src, int length, uint const_alpha)
{
if (const_alpha == 255)
comp_func_Difference_impl(dest, src, length, QFullCoverage());
else
comp_func_Difference_impl(dest, src, length, QPartialCoverage(const_alpha));
}
/*
Dca' = (Sca.Da + Dca.Sa - 2.Sca.Dca) + Sca.(1 - Da) + Dca.(1 - Sa)
*/
template <typename T>
Q_STATIC_TEMPLATE_FUNCTION inline void QT_FASTCALL comp_func_solid_Exclusion_impl(uint *dest, int length, uint color, const T &coverage)
{
int sa = qAlpha(color);
int sr = qRed(color);
int sg = qGreen(color);
int sb = qBlue(color);
PRELOAD_INIT(dest)
for (int i = 0; i < length; ++i) {
PRELOAD_COND(dest)
uint d = dest[i];
int da = qAlpha(d);
#define OP(a, b) (a + b - qt_div_255(2*(a*b)))
int r = OP( qRed(d), sr);
int b = OP( qBlue(d), sb);
int g = OP(qGreen(d), sg);
int a = mix_alpha(da, sa);
#undef OP
coverage.store(&dest[i], qRgba(r, g, b, a));
}
}
static void QT_FASTCALL comp_func_solid_Exclusion(uint *dest, int length, uint color, uint const_alpha)
{
if (const_alpha == 255)
comp_func_solid_Exclusion_impl(dest, length, color, QFullCoverage());
else
comp_func_solid_Exclusion_impl(dest, length, color, QPartialCoverage(const_alpha));
}
template <typename T>
Q_STATIC_TEMPLATE_FUNCTION inline void comp_func_Exclusion_impl(uint *dest, const uint *src, int length, const T &coverage)
{
PRELOAD_INIT2(dest, src)
for (int i = 0; i < length; ++i) {
PRELOAD_COND2(dest, src)
uint d = dest[i];
uint s = src[i];
int da = qAlpha(d);
int sa = qAlpha(s);
#define OP(a, b) (a + b - ((a*b) >> 7))
int r = OP( qRed(d), qRed(s));
int b = OP( qBlue(d), qBlue(s));
int g = OP(qGreen(d), qGreen(s));
int a = mix_alpha(da, sa);
#undef OP
coverage.store(&dest[i], qRgba(r, g, b, a));
}
}
static void QT_FASTCALL comp_func_Exclusion(uint *dest, const uint *src, int length, uint const_alpha)
{
if (const_alpha == 255)
comp_func_Exclusion_impl(dest, src, length, QFullCoverage());
else
comp_func_Exclusion_impl(dest, src, length, QPartialCoverage(const_alpha));
}
#if defined(Q_CC_RVCT)
// Restore pragma state from previous #pragma arm
# pragma pop
#endif
static void QT_FASTCALL rasterop_solid_SourceOrDestination(uint *dest,
int length,
uint color,
uint const_alpha)
{
Q_UNUSED(const_alpha);
while (length--)
*dest++ |= color;
}
static void QT_FASTCALL rasterop_SourceOrDestination(uint *dest,
const uint *src,
int length,
uint const_alpha)
{
Q_UNUSED(const_alpha);
while (length--)
*dest++ |= *src++;
}
static void QT_FASTCALL rasterop_solid_SourceAndDestination(uint *dest,
int length,
uint color,
uint const_alpha)
{
Q_UNUSED(const_alpha);
color |= 0xff000000;
while (length--)
*dest++ &= color;
}
static void QT_FASTCALL rasterop_SourceAndDestination(uint *dest,
const uint *src,
int length,
uint const_alpha)
{
Q_UNUSED(const_alpha);
while (length--) {
*dest = (*src & *dest) | 0xff000000;
++dest; ++src;
}
}
static void QT_FASTCALL rasterop_solid_SourceXorDestination(uint *dest,
int length,
uint color,
uint const_alpha)
{
Q_UNUSED(const_alpha);
color &= 0x00ffffff;
while (length--)
*dest++ ^= color;
}
static void QT_FASTCALL rasterop_SourceXorDestination(uint *dest,
const uint *src,
int length,
uint const_alpha)
{
Q_UNUSED(const_alpha);
while (length--) {
*dest = (*src ^ *dest) | 0xff000000;
++dest; ++src;
}
}
static void QT_FASTCALL rasterop_solid_NotSourceAndNotDestination(uint *dest,
int length,
uint color,
uint const_alpha)
{
Q_UNUSED(const_alpha);
color = ~color;
while (length--) {
*dest = (color & ~(*dest)) | 0xff000000;
++dest;
}
}
static void QT_FASTCALL rasterop_NotSourceAndNotDestination(uint *dest,
const uint *src,
int length,
uint const_alpha)
{
Q_UNUSED(const_alpha);
while (length--) {
*dest = (~(*src) & ~(*dest)) | 0xff000000;
++dest; ++src;
}
}
static void QT_FASTCALL rasterop_solid_NotSourceOrNotDestination(uint *dest,
int length,
uint color,
uint const_alpha)
{
Q_UNUSED(const_alpha);
color = ~color | 0xff000000;
while (length--) {
*dest = color | ~(*dest);
++dest;
}
}
static void QT_FASTCALL rasterop_NotSourceOrNotDestination(uint *dest,
const uint *src,
int length,
uint const_alpha)
{
Q_UNUSED(const_alpha);
while (length--) {
*dest = ~(*src) | ~(*dest) | 0xff000000;
++dest; ++src;
}
}
static void QT_FASTCALL rasterop_solid_NotSourceXorDestination(uint *dest,
int length,
uint color,
uint const_alpha)
{
Q_UNUSED(const_alpha);
color = ~color & 0x00ffffff;
while (length--) {
*dest = color ^ (*dest);
++dest;
}
}
static void QT_FASTCALL rasterop_NotSourceXorDestination(uint *dest,
const uint *src,
int length,
uint const_alpha)
{
Q_UNUSED(const_alpha);
while (length--) {
*dest = ((~(*src)) ^ (*dest)) | 0xff000000;
++dest; ++src;
}
}
static void QT_FASTCALL rasterop_solid_NotSource(uint *dest, int length,
uint color, uint const_alpha)
{
Q_UNUSED(const_alpha);
qt_memfill(dest, ~color | 0xff000000, length);
}
static void QT_FASTCALL rasterop_NotSource(uint *dest, const uint *src,
int length, uint const_alpha)
{
Q_UNUSED(const_alpha);
while (length--)
*dest++ = ~(*src++) | 0xff000000;
}
static void QT_FASTCALL rasterop_solid_NotSourceAndDestination(uint *dest,
int length,
uint color,
uint const_alpha)
{
Q_UNUSED(const_alpha);
color = ~color | 0xff000000;
while (length--) {
*dest = color & *dest;
++dest;
}
}
static void QT_FASTCALL rasterop_NotSourceAndDestination(uint *dest,
const uint *src,
int length,
uint const_alpha)
{
Q_UNUSED(const_alpha);
while (length--) {
*dest = (~(*src) & *dest) | 0xff000000;
++dest; ++src;
}
}
static void QT_FASTCALL rasterop_solid_SourceAndNotDestination(uint *dest,
int length,
uint color,
uint const_alpha)
{
Q_UNUSED(const_alpha);
while (length--) {
*dest = (color & ~(*dest)) | 0xff000000;
++dest;
}
}
static void QT_FASTCALL rasterop_SourceAndNotDestination(uint *dest,
const uint *src,
int length,
uint const_alpha)
{
Q_UNUSED(const_alpha);
while (length--) {
*dest = (*src & ~(*dest)) | 0xff000000;
++dest; ++src;
}
}
static const CompositionFunctionSolid functionForModeSolid_C[] = {
comp_func_solid_SourceOver,
comp_func_solid_DestinationOver,
comp_func_solid_Clear,
comp_func_solid_Source,
comp_func_solid_Destination,
comp_func_solid_SourceIn,
comp_func_solid_DestinationIn,
comp_func_solid_SourceOut,
comp_func_solid_DestinationOut,
comp_func_solid_SourceAtop,
comp_func_solid_DestinationAtop,
comp_func_solid_XOR,
comp_func_solid_Plus,
comp_func_solid_Multiply,
comp_func_solid_Screen,
comp_func_solid_Overlay,
comp_func_solid_Darken,
comp_func_solid_Lighten,
comp_func_solid_ColorDodge,
comp_func_solid_ColorBurn,
comp_func_solid_HardLight,
comp_func_solid_SoftLight,
comp_func_solid_Difference,
comp_func_solid_Exclusion,
rasterop_solid_SourceOrDestination,
rasterop_solid_SourceAndDestination,
rasterop_solid_SourceXorDestination,
rasterop_solid_NotSourceAndNotDestination,
rasterop_solid_NotSourceOrNotDestination,
rasterop_solid_NotSourceXorDestination,
rasterop_solid_NotSource,
rasterop_solid_NotSourceAndDestination,
rasterop_solid_SourceAndNotDestination
};
static const CompositionFunctionSolid *functionForModeSolid = functionForModeSolid_C;
static const CompositionFunction functionForMode_C[] = {
comp_func_SourceOver,
comp_func_DestinationOver,
comp_func_Clear,
comp_func_Source,
comp_func_Destination,
comp_func_SourceIn,
comp_func_DestinationIn,
comp_func_SourceOut,
comp_func_DestinationOut,
comp_func_SourceAtop,
comp_func_DestinationAtop,
comp_func_XOR,
comp_func_Plus,
comp_func_Multiply,
comp_func_Screen,
comp_func_Overlay,
comp_func_Darken,
comp_func_Lighten,
comp_func_ColorDodge,
comp_func_ColorBurn,
comp_func_HardLight,
comp_func_SoftLight,
comp_func_Difference,
comp_func_Exclusion,
rasterop_SourceOrDestination,
rasterop_SourceAndDestination,
rasterop_SourceXorDestination,
rasterop_NotSourceAndNotDestination,
rasterop_NotSourceOrNotDestination,
rasterop_NotSourceXorDestination,
rasterop_NotSource,
rasterop_NotSourceAndDestination,
rasterop_SourceAndNotDestination
};
static const CompositionFunction *functionForMode = functionForMode_C;
static TextureBlendType getBlendType(const QSpanData *data)
{
TextureBlendType ft;
if (data->txop <= QTransform::TxTranslate)
if (data->texture.type == QTextureData::Tiled)
ft = BlendTiled;
else
ft = BlendUntransformed;
else if (data->bilinear)
if (data->texture.type == QTextureData::Tiled)
ft = BlendTransformedBilinearTiled;
else
ft = BlendTransformedBilinear;
else
if (data->texture.type == QTextureData::Tiled)
ft = BlendTransformedTiled;
else
ft = BlendTransformed;
return ft;
}
static inline Operator getOperator(const QSpanData *data, const QSpan *spans, int spanCount)
{
Operator op;
bool solidSource = false;
switch(data->type) {
case QSpanData::Solid:
solidSource = (qAlpha(data->solid.color) == 255);
break;
case QSpanData::LinearGradient:
solidSource = !data->gradient.alphaColor;
getLinearGradientValues(&op.linear, data);
op.src_fetch = fetchLinearGradient;
break;
case QSpanData::RadialGradient:
solidSource = !data->gradient.alphaColor;
getRadialGradientValues(&op.radial, data);
op.src_fetch = fetchRadialGradient;
break;
case QSpanData::ConicalGradient:
solidSource = !data->gradient.alphaColor;
op.src_fetch = fetchConicalGradient;
break;
case QSpanData::Texture:
op.src_fetch = sourceFetch[getBlendType(data)][data->texture.format];
solidSource = !data->texture.hasAlpha;
default:
break;
}
op.mode = data->rasterBuffer->compositionMode;
if (op.mode == QPainter::CompositionMode_SourceOver && solidSource)
op.mode = QPainter::CompositionMode_Source;
op.dest_fetch = destFetchProc[data->rasterBuffer->format];
if (op.mode == QPainter::CompositionMode_Source) {
switch (data->rasterBuffer->format) {
case QImage::Format_RGB32:
case QImage::Format_ARGB32_Premultiplied:
// don't clear dest_fetch as it sets up the pointer correctly to save one copy
break;
default: {
const QSpan *lastSpan = spans + spanCount;
bool alphaSpans = false;
while (spans < lastSpan) {
if (spans->coverage != 255) {
alphaSpans = true;
break;
}
++spans;
}
if (!alphaSpans)
op.dest_fetch = 0;
}
}
}
op.dest_store = destStoreProc[data->rasterBuffer->format];
op.funcSolid = functionForModeSolid[op.mode];
op.func = functionForMode[op.mode];
return op;
}
// -------------------- blend methods ---------------------
enum SpanMethod {
RegularSpans,
CallbackSpans
};
#if !defined(Q_CC_SUN)
static
#endif
void drawBufferSpan(QSpanData *data, const uint *buffer, int bufsize,
int x, int y, int length, uint const_alpha)
{
#if defined (Q_WS_QWS) && !defined(QT_NO_RASTERCALLBACKS)
data->rasterEngine->drawBufferSpan(buffer, bufsize, x, y, length, const_alpha);
#else
Q_UNUSED(data);
Q_UNUSED(buffer);
Q_UNUSED(bufsize);
Q_UNUSED(x);
Q_UNUSED(y);
Q_UNUSED(length);
Q_UNUSED(const_alpha);
#endif
}
#if !defined(Q_CC_SUN)
static
#endif
void blend_color_generic(int count, const QSpan *spans, void *userData)
{
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
uint buffer[buffer_size];
Operator op = getOperator(data, spans, count);
while (count--) {
int x = spans->x;
int length = spans->len;
while (length) {
int l = qMin(buffer_size, length);
uint *dest = op.dest_fetch ? op.dest_fetch(buffer, data->rasterBuffer, x, spans->y, l) : buffer;
op.funcSolid(dest, l, data->solid.color, spans->coverage);
if (op.dest_store)
op.dest_store(data->rasterBuffer, x, spans->y, dest, l);
length -= l;
x += l;
}
++spans;
}
}
#if defined (Q_WS_QWS) && !defined(QT_NO_RASTERCALLBACKS)
static void blend_color_generic_callback(int count, const QSpan *spans, void *userData)
{
// ### Falcon
Q_UNUSED(count);
Q_UNUSED(spans);
Q_UNUSED(userData);
// QSpanData *data = reinterpret_cast<QSpanData*>(userData);
// data->rasterEngine->drawColorSpans(spans, count, data->solid.color);
}
#endif // QT_NO_RASTERCALLBACKS
static void blend_color_argb(int count, const QSpan *spans, void *userData)
{
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
Operator op = getOperator(data, spans, count);
if (op.mode == QPainter::CompositionMode_Source) {
// inline for performance
while (count--) {
uint *target = ((uint *)data->rasterBuffer->scanLine(spans->y)) + spans->x;
if (spans->coverage == 255) {
QT_MEMFILL_UINT(target, spans->len, data->solid.color);
} else {
uint c = BYTE_MUL(data->solid.color, spans->coverage);
int ialpha = 255 - spans->coverage;
for (int i = 0; i < spans->len; ++i)
target[i] = c + BYTE_MUL(target[i], ialpha);
}
++spans;
}
return;
}
while (count--) {
uint *target = ((uint *)data->rasterBuffer->scanLine(spans->y)) + spans->x;
op.funcSolid(target, spans->len, data->solid.color, spans->coverage);
++spans;
}
}
template <class T>
Q_STATIC_TEMPLATE_FUNCTION void blendColor(int count, const QSpan *spans, void *userData)
{
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
Operator op = getOperator(data, spans, count);
if (op.mode == QPainter::CompositionMode_Source) {
const T c = qt_colorConvert<T, quint32p>(quint32p::fromRawData(data->solid.color), 0);
while (count--) {
T *target = ((T*)data->rasterBuffer->scanLine(spans->y))
+ spans->x;
if (spans->coverage == 255) {
qt_memfill(target, c, spans->len);
} else {
const quint8 alpha = T::alpha(spans->coverage);
const T color = c.byte_mul(alpha);
const int ialpha = T::ialpha(spans->coverage);
const T *end = target + spans->len;
while (target < end) {
*target = color + target->byte_mul(ialpha);
++target;
}
}
++spans;
}
return;
}
if (op.mode == QPainter::CompositionMode_SourceOver) {
while (count--) {
const quint32 color = BYTE_MUL(data->solid.color, spans->coverage);
const T c = qt_colorConvert<T, quint32p>(quint32p::fromRawData(color), 0);
const quint8 ialpha = T::alpha(qAlpha(~color));
T *target = ((T*)data->rasterBuffer->scanLine(spans->y)) + spans->x;
const T *end = target + spans->len;
while (target != end) {
*target = c + target->byte_mul(ialpha);
++target;
}
++spans;
}
return;
}
blend_color_generic(count, spans, userData);
}
#define SPANFUNC_POINTER_BLENDCOLOR(DST) blendColor<DST>
static void blend_color_rgb16(int count, const QSpan *spans, void *userData)
{
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
/*
We duplicate a little logic from getOperator() and calculate the
composition mode directly. This allows blend_color_rgb16 to be used
from qt_gradient_quint16 with minimal overhead.
*/
QPainter::CompositionMode mode = data->rasterBuffer->compositionMode;
if (mode == QPainter::CompositionMode_SourceOver &&
qAlpha(data->solid.color) == 255)
mode = QPainter::CompositionMode_Source;
if (mode == QPainter::CompositionMode_Source) {
// inline for performance
ushort c = qConvertRgb32To16(data->solid.color);
while (count--) {
ushort *target = ((ushort *)data->rasterBuffer->scanLine(spans->y)) + spans->x;
if (spans->coverage == 255) {
QT_MEMFILL_USHORT(target, spans->len, c);
} else {
ushort color = BYTE_MUL_RGB16(c, spans->coverage);
int ialpha = 255 - spans->coverage;
const ushort *end = target + spans->len;
while (target < end) {
*target = color + BYTE_MUL_RGB16(*target, ialpha);
++target;
}
}
++spans;
}
return;
}
if (mode == QPainter::CompositionMode_SourceOver) {
while (count--) {
uint color = BYTE_MUL(data->solid.color, spans->coverage);
int ialpha = qAlpha(~color);
ushort c = qConvertRgb32To16(color);
ushort *target = ((ushort *)data->rasterBuffer->scanLine(spans->y)) + spans->x;
int len = spans->len;
bool pre = (((quintptr)target) & 0x3) != 0;
bool post = false;
if (pre) {
// skip to word boundary
*target = c + BYTE_MUL_RGB16(*target, ialpha);
++target;
--len;
}
if (len & 0x1) {
post = true;
--len;
}
uint *target32 = (uint*)target;
uint c32 = c | (c<<16);
len >>= 1;
uint salpha = (ialpha+1) >> 3; // calculate here rather than in loop
while (len--) {
// blend full words
*target32 = c32 + BYTE_MUL_RGB16_32(*target32, salpha);
++target32;
target += 2;
}
if (post) {
// one last pixel beyond a full word
*target = c + BYTE_MUL_RGB16(*target, ialpha);
}
++spans;
}
return;
}
blend_color_generic(count, spans, userData);
}
template <typename T>
void handleSpans(int count, const QSpan *spans, const QSpanData *data, T &handler)
{
uint const_alpha = 256;
if (data->type == QSpanData::Texture)
const_alpha = data->texture.const_alpha;
int coverage = 0;
while (count) {
int x = spans->x;
const int y = spans->y;
int right = x + spans->len;
// compute length of adjacent spans
for (int i = 1; i < count && spans[i].y == y && spans[i].x == right; ++i)
right += spans[i].len;
int length = right - x;
while (length) {
int l = qMin(buffer_size, length);
length -= l;
int process_length = l;
int process_x = x;
const uint *src = handler.fetch(process_x, y, process_length);
int offset = 0;
while (l > 0) {
if (x == spans->x) // new span?
coverage = (spans->coverage * const_alpha) >> 8;
int right = spans->x + spans->len;
int len = qMin(l, right - x);
handler.process(x, y, len, coverage, src, offset);
l -= len;
x += len;
offset += len;
if (x == right) { // done with current span?
++spans;
--count;
}
}
handler.store(process_x, y, process_length);
}
}
}
struct QBlendBase
{
QBlendBase(QSpanData *d, Operator o)
: data(d)
, op(o)
, dest(0)
{
}
QSpanData *data;
Operator op;
uint *dest;
uint buffer[buffer_size];
uint src_buffer[buffer_size];
};
template <SpanMethod spanMethod>
class BlendSrcGeneric : public QBlendBase
{
public:
BlendSrcGeneric(QSpanData *d, Operator o)
: QBlendBase(d, o)
{
}
const uint *fetch(int x, int y, int len)
{
if (spanMethod == RegularSpans)
dest = op.dest_fetch ? op.dest_fetch(buffer, data->rasterBuffer, x, y, len) : buffer;
return op.src_fetch(src_buffer, &op, data, y, x, len);
}
void process(int x, int y, int len, int coverage, const uint *src, int offset)
{
if (spanMethod == RegularSpans)
op.func(dest + offset, src + offset, len, coverage);
else
drawBufferSpan(data, src + offset, len, x, y, len, coverage);
}
void store(int x, int y, int len)
{
if (spanMethod == RegularSpans && op.dest_store) {
op.dest_store(data->rasterBuffer, x, y, dest, len);
}
}
};
template <SpanMethod spanMethod>
Q_STATIC_TEMPLATE_FUNCTION void blend_src_generic(int count, const QSpan *spans, void *userData)
{
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
BlendSrcGeneric<spanMethod> blend(data, getOperator(data, spans, count));
handleSpans(count, spans, data, blend);
}
template <SpanMethod spanMethod>
Q_STATIC_TEMPLATE_FUNCTION void blend_untransformed_generic(int count, const QSpan *spans, void *userData)
{
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
uint buffer[buffer_size];
uint src_buffer[buffer_size];
Operator op = getOperator(data, spans, count);
const int image_width = data->texture.width;
const int image_height = data->texture.height;
int xoff = -qRound(-data->dx);
int yoff = -qRound(-data->dy);
while (count--) {
int x = spans->x;
int length = spans->len;
int sx = xoff + x;
int sy = yoff + spans->y;
if (sy >= 0 && sy < image_height && sx < image_width) {
if (sx < 0) {
x -= sx;
length += sx;
sx = 0;
}
if (sx + length > image_width)
length = image_width - sx;
if (length > 0) {
const int coverage = (spans->coverage * data->texture.const_alpha) >> 8;
while (length) {
int l = qMin(buffer_size, length);
const uint *src = op.src_fetch(src_buffer, &op, data, sy, sx, l);
if (spanMethod == RegularSpans) {
uint *dest = op.dest_fetch ? op.dest_fetch(buffer, data->rasterBuffer, x, spans->y, l) : buffer;
op.func(dest, src, l, coverage);
if (op.dest_store)
op.dest_store(data->rasterBuffer, x, spans->y, dest, l);
} else {
drawBufferSpan(data, src, l, x, spans->y,
l, coverage);
}
x += l;
sx += l;
length -= l;
}
}
}
++spans;
}
}
template <SpanMethod spanMethod>
Q_STATIC_TEMPLATE_FUNCTION void blend_untransformed_argb(int count, const QSpan *spans, void *userData)
{
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format != QImage::Format_ARGB32_Premultiplied
&& data->texture.format != QImage::Format_RGB32) {
blend_untransformed_generic<spanMethod>(count, spans, userData);
return;
}
Operator op = getOperator(data, spans, count);
const int image_width = data->texture.width;
const int image_height = data->texture.height;
int xoff = -qRound(-data->dx);
int yoff = -qRound(-data->dy);
while (count--) {
int x = spans->x;
int length = spans->len;
int sx = xoff + x;
int sy = yoff + spans->y;
if (sy >= 0 && sy < image_height && sx < image_width) {
if (sx < 0) {
x -= sx;
length += sx;
sx = 0;
}
if (sx + length > image_width)
length = image_width - sx;
if (length > 0) {
const int coverage = (spans->coverage * data->texture.const_alpha) >> 8;
const uint *src = (uint *)data->texture.scanLine(sy) + sx;
if (spanMethod == RegularSpans) {
uint *dest = ((uint *)data->rasterBuffer->scanLine(spans->y)) + x;
op.func(dest, src, length, coverage);
} else {
drawBufferSpan(data, src, length, x,
spans->y, length, coverage);
}
}
}
++spans;
}
}
static inline quint16 interpolate_pixel_rgb16_255(quint16 x, quint8 a,
quint16 y, quint8 b)
{
quint16 t = ((((x & 0x07e0) * a) + ((y & 0x07e0) * b)) >> 5) & 0x07e0;
t |= ((((x & 0xf81f) * a) + ((y & 0xf81f) * b)) >> 5) & 0xf81f;
return t;
}
static inline quint32 interpolate_pixel_rgb16x2_255(quint32 x, quint8 a,
quint32 y, quint8 b)
{
uint t;
t = ((((x & 0xf81f07e0) >> 5) * a) + (((y & 0xf81f07e0) >> 5) * b)) & 0xf81f07e0;
t |= ((((x & 0x07e0f81f) * a) + ((y & 0x07e0f81f) * b)) >> 5) & 0x07e0f81f;
return t;
}
static inline void blend_sourceOver_rgb16_rgb16(quint16 *dest,
const quint16 *src,
int length,
const quint8 alpha,
const quint8 ialpha)
{
const int dstAlign = ((quintptr)dest) & 0x3;
if (dstAlign) {
*dest = interpolate_pixel_rgb16_255(*src, alpha, *dest, ialpha);
++dest;
++src;
--length;
}
const int srcAlign = ((quintptr)src) & 0x3;
int length32 = length >> 1;
if (length32 && srcAlign == 0) {
while (length32--) {
const quint32 *src32 = reinterpret_cast<const quint32*>(src);
quint32 *dest32 = reinterpret_cast<quint32*>(dest);
*dest32 = interpolate_pixel_rgb16x2_255(*src32, alpha,
*dest32, ialpha);
dest += 2;
src += 2;
}
length &= 0x1;
}
while (length--) {
*dest = interpolate_pixel_rgb16_255(*src, alpha, *dest, ialpha);
++dest;
++src;
}
}
template <class DST, class SRC>
Q_STATIC_TEMPLATE_SPECIALIZATION
inline void madd_2(DST *dest, const quint16 alpha, const SRC *src)
{
Q_ASSERT((quintptr(dest) & 0x3) == 0);
Q_ASSERT((quintptr(src) & 0x3) == 0);
dest[0] = dest[0].byte_mul(alpha >> 8) + DST(src[0]);
dest[1] = dest[1].byte_mul(alpha & 0xff) + DST(src[1]);
}
template <class DST, class SRC>
Q_STATIC_TEMPLATE_SPECIALIZATION
inline void madd_4(DST *dest, const quint32 alpha, const SRC *src)
{
Q_ASSERT((quintptr(dest) & 0x3) == 0);
Q_ASSERT((quintptr(src) & 0x3) == 0);
dest[0] = dest[0].byte_mul(alpha >> 24) + DST(src[0]);
dest[1] = dest[1].byte_mul((alpha >> 16) & 0xff) + DST(src[1]);
dest[2] = dest[2].byte_mul((alpha >> 8) & 0xff) + DST(src[2]);
dest[3] = dest[3].byte_mul(alpha & 0xff) + DST(src[3]);
}
#if Q_BYTE_ORDER == Q_LITTLE_ENDIAN
template <>
Q_STATIC_TEMPLATE_SPECIALIZATION
inline void madd_4(qargb8565 *dest, const quint32 a, const qargb8565 *src)
{
Q_ASSERT((quintptr(dest) & 0x3) == 0);
Q_ASSERT((quintptr(src) & 0x3) == 0);
const quint32 *src32 = reinterpret_cast<const quint32*>(src);
quint32 *dest32 = reinterpret_cast<quint32*>(dest);
quint32 x, y, t;
quint8 a8;
{
x = dest32[0];
y = src32[0];
a8 = a >> 24;
// a0,g0
t = ((((x & 0x0007e0ff) * a8) >> 5) & 0x0007e0ff) + (y & 0x0007c0f8);
// r0,b0
t |= ((((x & 0x00f81f00) * a8) >> 5) & 0x00f81f00) + (y & 0x00f81f00);
a8 = (a >> 16) & 0xff;
// a1
t |= ((((x & 0xff000000) >> 5) * a8) & 0xff000000) + (y & 0xf8000000);
dest32[0] = t;
}
{
x = dest32[1];
y = src32[1];
// r1,b1
t = ((((x & 0x0000f81f) * a8) >> 5) & 0x0000f81f) + (y & 0x0000f81f);
// g1
t |= ((((x & 0x000007e0) * a8) >> 5) & 0x000007e0) + (y & 0x000007c0);
a8 = (a >> 8) & 0xff;
// a2
t |= ((((x & 0x00ff0000) * a8) >> 5) & 0x00ff0000) + (y & 0x00f80000);
{
// rgb2
quint16 x16 = (x >> 24) | ((dest32[2] & 0x000000ff) << 8);
quint16 y16 = (y >> 24) | ((src32[2] & 0x000000ff) << 8);
quint16 t16;
t16 = ((((x16 & 0xf81f) * a8) >> 5) & 0xf81f) + (y16 & 0xf81f);
t16 |= ((((x16 & 0x07e0) * a8) >> 5) & 0x07e0) + (y16 & 0x07c0);
// rg2
t |= ((t16 & 0x00ff) << 24);
dest32[1] = t;
x = dest32[2];
y = src32[2];
// gb2
t = (t16 >> 8);
}
}
{
a8 = a & 0xff;
// g3,a3
t |= ((((x & 0x07e0ff00) * a8) >> 5) & 0x07e0ff00) + (y & 0x07c0f800);
// r3,b3
t |= ((((x & 0xf81f0000) >> 5) * a8) & 0xf81f0000)+ (y & 0xf81f0000);
dest32[2] = t;
}
}
#endif
#if Q_BYTE_ORDER == Q_LITTLE_ENDIAN
template <>
Q_STATIC_TEMPLATE_SPECIALIZATION
inline void madd_4(qargb8555 *dest, const quint32 a, const qargb8555 *src)
{
Q_ASSERT((quintptr(dest) & 0x3) == 0);
Q_ASSERT((quintptr(src) & 0x3) == 0);
const quint32 *src32 = reinterpret_cast<const quint32*>(src);
quint32 *dest32 = reinterpret_cast<quint32*>(dest);
quint32 x, y, t;
quint8 a8;
{
x = dest32[0];
y = src32[0];
a8 = a >> 24;
// a0,g0
t = ((((x & 0x0003e0ff) * a8) >> 5) & 0x0003e0ff) + (y & 0x0003e0f8);
// r0,b0
t |= ((((x & 0x007c1f00) * a8) >> 5) & 0x007c1f00) + (y & 0x007c1f00);
a8 = (a >> 16) & 0xff;
// a1
t |= ((((x & 0xff000000) >> 5) * a8) & 0xff000000) + (y & 0xf8000000);
dest32[0] = t;
}
{
x = dest32[1];
y = src32[1];
// r1,b1
t = ((((x & 0x00007c1f) * a8) >> 5) & 0x00007c1f) + (y & 0x00007c1f);
// g1
t |= ((((x & 0x000003e0) * a8) >> 5) & 0x000003e0) + (y & 0x000003e0);
a8 = (a >> 8) & 0xff;
// a2
t |= ((((x & 0x00ff0000) * a8) >> 5) & 0x00ff0000) + (y & 0x00f80000);
{
// rgb2
quint16 x16 = (x >> 24) | ((dest32[2] & 0x000000ff) << 8);
quint16 y16 = (y >> 24) | ((src32[2] & 0x000000ff) << 8);
quint16 t16;
t16 = ((((x16 & 0x7c1f) * a8) >> 5) & 0x7c1f) + (y16 & 0x7c1f);
t16 |= ((((x16 & 0x03e0) * a8) >> 5) & 0x03e0) + (y16 & 0x03e0);
// rg2
t |= ((t16 & 0x00ff) << 24);
dest32[1] = t;
x = dest32[2];
y = src32[2];
// gb2
t = (t16 >> 8);
}
}
{
a8 = a & 0xff;
// g3,a3
t |= ((((x & 0x03e0ff00) * a8) >> 5) & 0x03e0ff00) + (y & 0x03e0f800);
// r3,b3
t |= ((((x & 0x7c1f0000) >> 5) * a8) & 0x7c1f0000)+ (y & 0x7c1f0000);
dest32[2] = t;
}
}
#endif
template <class T>
Q_STATIC_TEMPLATE_SPECIALIZATION
inline quint16 alpha_2(const T *src)
{
Q_ASSERT((quintptr(src) & 0x3) == 0);
if (T::hasAlpha())
return (src[0].alpha() << 8) | src[1].alpha();
else
return 0xffff;
}
template <class T>
Q_STATIC_TEMPLATE_SPECIALIZATION
inline quint32 alpha_4(const T *src)
{
Q_ASSERT((quintptr(src) & 0x3) == 0);
if (T::hasAlpha()) {
return (src[0].alpha() << 24) | (src[1].alpha() << 16)
| (src[2].alpha() << 8) | src[3].alpha();
} else {
return 0xffffffff;
}
}
template <>
Q_STATIC_TEMPLATE_SPECIALIZATION
inline quint32 alpha_4(const qargb8565 *src)
{
const quint8 *src8 = reinterpret_cast<const quint8*>(src);
return src8[0] << 24 | src8[3] << 16 | src8[6] << 8 | src8[9];
}
template <>
Q_STATIC_TEMPLATE_SPECIALIZATION
inline quint32 alpha_4(const qargb6666 *src)
{
const quint8 *src8 = reinterpret_cast<const quint8*>(src);
return ((src8[2] & 0xfc) | (src8[2] >> 6)) << 24
| ((src8[5] & 0xfc) | (src8[5] >> 6)) << 16
| ((src8[8] & 0xfc) | (src8[8] >> 6)) << 8
| ((src8[11] & 0xfc) | (src8[11] >> 6));
}
template <>
Q_STATIC_TEMPLATE_SPECIALIZATION
inline quint32 alpha_4(const qargb8555 *src)
{
Q_ASSERT((long(src) & 0x3) == 0);
const quint8 *src8 = reinterpret_cast<const quint8*>(src);
return src8[0] << 24 | src8[3] << 16 | src8[6] << 8 | src8[9];
}
template <>
Q_STATIC_TEMPLATE_SPECIALIZATION
inline quint16 alpha_2(const qargb4444 *src)
{
const quint32 *src32 = reinterpret_cast<const quint32*>(src);
const quint32 t = (*src32 & 0xf000f000) |
((*src32 & 0xf000f000) >> 4);
return (t >> 24) | (t & 0xff00);
}
template <class T>
Q_STATIC_TEMPLATE_SPECIALIZATION
inline quint16 eff_alpha_2(quint16 alpha, const T*)
{
return (T::alpha((alpha >> 8) & 0xff) << 8)
| T::alpha(alpha & 0xff);
}
template <>
Q_STATIC_TEMPLATE_SPECIALIZATION
inline quint16 eff_alpha_2(quint16 a, const qrgb565*)
{
return ((((a & 0xff00) + 0x0100) >> 3) & 0xff00)
| ((((a & 0x00ff) + 0x0001) >> 3) & 0x00ff);
}
template <>
Q_STATIC_TEMPLATE_SPECIALIZATION
inline quint16 eff_alpha_2(quint16 a, const qrgb444*)
{
return (((a & 0x00ff) + 0x0001) >> 4)
| ((((a & 0xff00) + 0x0100) >> 4) & 0xff00);
}
template <>
Q_STATIC_TEMPLATE_SPECIALIZATION
inline quint16 eff_alpha_2(quint16 a, const qargb4444*)
{
return (((a & 0x00ff) + 0x0001) >> 4)
| ((((a & 0xff00) + 0x0100) >> 4) & 0xff00);
}
template <class T>
Q_STATIC_TEMPLATE_SPECIALIZATION
inline quint16 eff_ialpha_2(quint16 alpha, const T*)
{
return (T::ialpha((alpha >> 8) & 0xff) << 8)
| T::ialpha(alpha & 0xff);
}
template <>
Q_STATIC_TEMPLATE_SPECIALIZATION
inline quint16 eff_ialpha_2(quint16 a, const qrgb565 *dummy)
{
return 0x2020 - eff_alpha_2(a, dummy);
}
template <>
Q_STATIC_TEMPLATE_SPECIALIZATION
inline quint16 eff_ialpha_2(quint16 a, const qargb4444 *dummy)
{
return 0x1010 - eff_alpha_2(a, dummy);
}
template <>
Q_STATIC_TEMPLATE_SPECIALIZATION
inline quint16 eff_ialpha_2(quint16 a, const qrgb444 *dummy)
{
return 0x1010 - eff_alpha_2(a, dummy);
}
template <class T>
Q_STATIC_TEMPLATE_SPECIALIZATION
inline quint32 eff_alpha_4(quint32 alpha, const T*)
{
return (T::alpha(alpha >> 24) << 24)
| (T::alpha((alpha >> 16) & 0xff) << 16)
| (T::alpha((alpha >> 8) & 0xff) << 8)
| T::alpha(alpha & 0xff);
}
template <>
Q_STATIC_TEMPLATE_SPECIALIZATION
inline quint32 eff_alpha_4(quint32 a, const qrgb888*)
{
return a;
}
template <>
Q_STATIC_TEMPLATE_SPECIALIZATION
inline quint32 eff_alpha_4(quint32 a, const qargb8565*)
{
return ((((a & 0xff00ff00) + 0x01000100) >> 3) & 0xff00ff00)
| ((((a & 0x00ff00ff) + 0x00010001) >> 3) & 0x00ff00ff);
}
template <>
Q_STATIC_TEMPLATE_SPECIALIZATION
inline quint32 eff_alpha_4(quint32 a, const qargb6666*)
{
return ((((a & 0xff00ff00) >> 2) + 0x00400040) & 0xff00ff00)
| ((((a & 0x00ff00ff) + 0x00010001) >> 2) & 0x00ff00ff);
}
template <>
Q_STATIC_TEMPLATE_SPECIALIZATION
inline quint32 eff_alpha_4(quint32 a, const qrgb666*)
{
return ((((a & 0xff00ff00) >> 2) + 0x00400040) & 0xff00ff00)
| ((((a & 0x00ff00ff) + 0x00010001) >> 2) & 0x00ff00ff);
}
template <>
Q_STATIC_TEMPLATE_SPECIALIZATION
inline quint32 eff_alpha_4(quint32 a, const qargb8555*)
{
return ((((a & 0xff00ff00) + 0x01000100) >> 3) & 0xff00ff00)
| ((((a & 0x00ff00ff) + 0x00010001) >> 3) & 0x00ff00ff);
}
template <class T>
Q_STATIC_TEMPLATE_SPECIALIZATION
inline quint32 eff_ialpha_4(quint32 alpha, const T*)
{
return (T::ialpha(alpha >> 24) << 24)
| (T::ialpha((alpha >> 16) & 0xff) << 16)
| (T::ialpha((alpha >> 8) & 0xff) << 8)
| T::ialpha(alpha & 0xff);
}
template <>
Q_STATIC_TEMPLATE_SPECIALIZATION
inline quint32 eff_ialpha_4(quint32 a, const qrgb888*)
{
return ~a;
}
template <>
Q_STATIC_TEMPLATE_SPECIALIZATION
inline quint32 eff_ialpha_4(quint32 a, const qargb8565 *dummy)
{
return 0x20202020 - eff_alpha_4(a, dummy);
}
template <>
Q_STATIC_TEMPLATE_SPECIALIZATION
inline quint32 eff_ialpha_4(quint32 a, const qargb6666 *dummy)
{
return 0x40404040 - eff_alpha_4(a, dummy);
}
template <>
Q_STATIC_TEMPLATE_SPECIALIZATION
inline quint32 eff_ialpha_4(quint32 a, const qrgb666 *dummy)
{
return 0x40404040 - eff_alpha_4(a, dummy);
}
template <>
Q_STATIC_TEMPLATE_SPECIALIZATION
inline quint32 eff_ialpha_4(quint32 a, const qargb8555 *dummy)
{
return 0x20202020 - eff_alpha_4(a, dummy);
}
template <class DST, class SRC>
inline void interpolate_pixel_unaligned_2(DST *dest, const SRC *src,
quint16 alpha)
{
const quint16 a = eff_alpha_2(alpha, dest);
const quint16 ia = eff_ialpha_2(alpha, dest);
dest[0] = DST(src[0]).byte_mul(a >> 8) + dest[0].byte_mul(ia >> 8);
dest[1] = DST(src[1]).byte_mul(a & 0xff) + dest[1].byte_mul(ia & 0xff);
}
template <class DST, class SRC>
inline void interpolate_pixel_2(DST *dest, const SRC *src, quint16 alpha)
{
Q_ASSERT((long(dest) & 0x3) == 0);
Q_ASSERT((long(src) & 0x3) == 0);
const quint16 a = eff_alpha_2(alpha, dest);
const quint16 ia = eff_ialpha_2(alpha, dest);
dest[0] = DST(src[0]).byte_mul(a >> 8) + dest[0].byte_mul(ia >> 8);
dest[1] = DST(src[1]).byte_mul(a & 0xff) + dest[1].byte_mul(ia & 0xff);
}
template <class DST, class SRC>
inline void interpolate_pixel(DST &dest, quint8 a, const SRC &src, quint8 b)
{
if (SRC::hasAlpha() && !DST::hasAlpha())
interpolate_pixel(dest, a, DST(src), b);
else
dest = dest.byte_mul(a) + DST(src).byte_mul(b);
}
template <>
inline void interpolate_pixel(qargb8565 &dest, quint8 a,
const qargb8565 &src, quint8 b)
{
quint8 *d = reinterpret_cast<quint8*>(&dest);
const quint8 *s = reinterpret_cast<const quint8*>(&src);
d[0] = (d[0] * a + s[0] * b) >> 5;
const quint16 x = (d[2] << 8) | d[1];
const quint16 y = (s[2] << 8) | s[1];
quint16 t = (((x & 0x07e0) * a + (y & 0x07e0) * b) >> 5) & 0x07e0;
t |= (((x & 0xf81f) * a + (y & 0xf81f) * b) >> 5) & 0xf81f;
d[1] = t & 0xff;
d[2] = t >> 8;
}
template <>
inline void interpolate_pixel(qrgb565 &dest, quint8 a,
const qrgb565 &src, quint8 b)
{
const quint16 x = dest.rawValue();
const quint16 y = src.rawValue();
quint16 t = (((x & 0x07e0) * a + (y & 0x07e0) * b) >> 5) & 0x07e0;
t |= (((x & 0xf81f) * a + (y & 0xf81f) * b) >> 5) & 0xf81f;
dest = t;
}
template <>
inline void interpolate_pixel(qrgb555 &dest, quint8 a,
const qrgb555 &src, quint8 b)
{
const quint16 x = dest.rawValue();
const quint16 y = src.rawValue();
quint16 t = (((x & 0x03e0) * a + (y & 0x03e0) * b) >> 5) & 0x03e0;
t |= ((((x & 0x7c1f) * a) + ((y & 0x7c1f) * b)) >> 5) & 0x7c1f;
dest = t;
}
template <>
inline void interpolate_pixel(qrgb444 &dest, quint8 a,
const qrgb444 &src, quint8 b)
{
const quint16 x = dest.rawValue();
const quint16 y = src.rawValue();
quint16 t = ((x & 0x00f0) * a + (y & 0x00f0) * b) & 0x0f00;
t |= ((x & 0x0f0f) * a + (y & 0x0f0f) * b) & 0xf0f0;
quint16 *d = reinterpret_cast<quint16*>(&dest);
*d = (t >> 4);
}
template <class DST, class SRC>
inline void interpolate_pixel_2(DST *dest, quint8 a,
const SRC *src, quint8 b)
{
Q_ASSERT((long(dest) & 0x3) == 0);
Q_ASSERT((long(src) & 0x3) == 0);
Q_ASSERT(!SRC::hasAlpha());
dest[0] = dest[0].byte_mul(a) + DST(src[0]).byte_mul(b);
dest[1] = dest[1].byte_mul(a) + DST(src[1]).byte_mul(b);
}
template <>
inline void interpolate_pixel_2(qrgb565 *dest, quint8 a,
const qrgb565 *src, quint8 b)
{
quint32 *x = reinterpret_cast<quint32*>(dest);
const quint32 *y = reinterpret_cast<const quint32*>(src);
quint32 t = (((*x & 0xf81f07e0) >> 5) * a +
((*y & 0xf81f07e0) >> 5) * b) & 0xf81f07e0;
t |= (((*x & 0x07e0f81f) * a
+ (*y & 0x07e0f81f) * b) >> 5) & 0x07e0f81f;
*x = t;
}
template <>
inline void interpolate_pixel_2(qrgb555 *dest, quint8 a,
const qrgb555 *src, quint8 b)
{
quint32 *x = reinterpret_cast<quint32*>(dest);
const quint32 *y = reinterpret_cast<const quint32*>(src);
quint32 t = (((*x & 0x7c1f03e0) >> 5) * a +
((*y & 0x7c1f03e0) >> 5) * b) & 0x7c1f03e0;
t |= (((*x & 0x03e07c1f) * a
+ (*y & 0x03e07c1f) * b) >> 5) & 0x03e07c1f;
*x = t;
}
template <>
inline void interpolate_pixel_2(qrgb444 *dest, quint8 a,
const qrgb444 *src, quint8 b)
{
quint32 *x = reinterpret_cast<quint32*>(dest);
const quint32 *y = reinterpret_cast<const quint32*>(src);
quint32 t = ((*x & 0x0f0f0f0f) * a + (*y & 0x0f0f0f0f) * b) & 0xf0f0f0f0;
t |= ((*x & 0x00f000f0) * a + (*y & 0x00f000f0) * b) & 0x0f000f00;
*x = t >> 4;
}
template <class DST, class SRC>
inline void interpolate_pixel_4(DST *dest, const SRC *src, quint32 alpha)
{
Q_ASSERT((long(dest) & 0x3) == 0);
Q_ASSERT((long(src) & 0x3) == 0);
const quint32 a = eff_alpha_4(alpha, dest);
const quint32 ia = eff_ialpha_4(alpha, dest);
dest[0] = DST(src[0]).byte_mul(a >> 24)
+ dest[0].byte_mul(ia >> 24);
dest[1] = DST(src[1]).byte_mul((a >> 16) & 0xff)
+ dest[1].byte_mul((ia >> 16) & 0xff);
dest[2] = DST(src[2]).byte_mul((a >> 8) & 0xff)
+ dest[2].byte_mul((ia >> 8) & 0xff);
dest[3] = DST(src[3]).byte_mul(a & 0xff)
+ dest[3].byte_mul(ia & 0xff);
}
#if Q_BYTE_ORDER == Q_LITTLE_ENDIAN
template <>
inline void interpolate_pixel_4(qargb8565 *dest, const qargb8565 *src,
quint32 alpha)
{
Q_ASSERT((long(dest) & 0x3) == 0);
Q_ASSERT((long(src) & 0x3) == 0);
const quint32 a = eff_alpha_4(alpha, dest);
const quint32 ia = eff_ialpha_4(alpha, dest);
const quint32 *src32 = reinterpret_cast<const quint32*>(src);
quint32 *dest32 = reinterpret_cast<quint32*>(dest);
quint32 x, y, t;
quint8 a8, ia8;
{
x = src32[0];
y = dest32[0];
a8 = a >> 24;
ia8 = ia >> 24;
// a0,g0
t = (((x & 0x0007e0ff) * a8 + (y & 0x0007e0ff) * ia8) >> 5)
& 0x0007e0ff;
// r0,b0
t |= (((x & 0x00f81f00) * a8 + (y & 0x00f81f00) * ia8) >> 5)
& 0x00f81f00;
a8 = (a >> 16) & 0xff;
ia8 = (ia >> 16) & 0xff;
// a1
t |= (((x & 0xff000000) >> 5) * a8 + ((y & 0xff000000) >> 5) * ia8)
& 0xff000000;
dest32[0] = t;
}
{
x = src32[1];
y = dest32[1];
// r1,b1
t = (((x & 0x0000f81f) * a8 + (y & 0x0000f81f) * ia8) >> 5)
& 0x0000f81f;
// g1
t |= (((x & 0x000007e0) * a8 + (y & 0x000007e0) * ia8) >> 5)
& 0x000007e0;
a8 = (a >> 8) & 0xff;
ia8 = (ia >> 8) & 0xff;
// a2
t |= (((x & 0x00ff0000) * a8 + (y & 0x00ff0000) * ia8) >> 5)
& 0x00ff0000;
{
// rgb2
quint16 x16 = (x >> 24) | ((src32[2] & 0x000000ff) << 8);
quint16 y16 = (y >> 24) | ((dest32[2] & 0x000000ff) << 8);
quint16 t16;
t16 = (((x16 & 0xf81f) * a8 + (y16 & 0xf81f) * ia8) >> 5) & 0xf81f;
t16 |= (((x16 & 0x07e0) * a8 + (y16 & 0x07e0) * ia8) >> 5) & 0x07e0;
// rg2
t |= ((t16 & 0x00ff) << 24);
dest32[1] = t;
x = src32[2];
y = dest32[2];
// gb2
t = (t16 >> 8);
}
}
{
a8 = a & 0xff;
ia8 = ia & 0xff;
// g3,a3
t |= (((x & 0x07e0ff00) * a8 + (y & 0x07e0ff00) * ia8) >> 5)
& 0x07e0ff00;
// r3,b3
t |= (((x & 0xf81f0000) >> 5) * a8 + ((y & 0xf81f0000) >> 5) * ia8)
& 0xf81f0000;
dest32[2] = t;
}
}
#endif
#if Q_BYTE_ORDER == Q_LITTLE_ENDIAN
template <>
inline void interpolate_pixel_4(qargb8555 *dest, const qargb8555 *src,
quint32 alpha)
{
Q_ASSERT((long(dest) & 0x3) == 0);
Q_ASSERT((long(src) & 0x3) == 0);
const quint32 a = eff_alpha_4(alpha, dest);
const quint32 ia = eff_ialpha_4(alpha, dest);
const quint32 *src32 = reinterpret_cast<const quint32*>(src);
quint32 *dest32 = reinterpret_cast<quint32*>(dest);
quint32 x, y, t;
quint8 a8, ia8;
{
x = src32[0];
y = dest32[0];
a8 = a >> 24;
ia8 = ia >> 24;
// a0,g0
t = (((x & 0x0003e0ff) * a8 + (y & 0x0003e0ff) * ia8) >> 5)
& 0x0003e0ff;
// r0,b0
t |= (((x & 0x007c1f00) * a8 + (y & 0x007c1f00) * ia8) >> 5)
& 0x007c1f00;
a8 = (a >> 16) & 0xff;
ia8 = (ia >> 16) & 0xff;
// a1
t |= (((x & 0xff000000) >> 5) * a8 + ((y & 0xff000000) >> 5) * ia8)
& 0xff000000;
dest32[0] = t;
}
{
x = src32[1];
y = dest32[1];
// r1,b1
t = (((x & 0x00007c1f) * a8 + (y & 0x00007c1f) * ia8) >> 5)
& 0x00007c1f;
// g1
t |= (((x & 0x000003e0) * a8 + (y & 0x000003e0) * ia8) >> 5)
& 0x000003e0;
a8 = (a >> 8) & 0xff;
ia8 = (ia >> 8) & 0xff;
// a2
t |= (((x & 0x00ff0000) * a8 + (y & 0x00ff0000) * ia8) >> 5)
& 0x00ff0000;
{
// rgb2
quint16 x16 = (x >> 24) | ((src32[2] & 0x000000ff) << 8);
quint16 y16 = (y >> 24) | ((dest32[2] & 0x000000ff) << 8);
quint16 t16;
t16 = (((x16 & 0x7c1f) * a8 + (y16 & 0x7c1f) * ia8) >> 5) & 0x7c1f;
t16 |= (((x16 & 0x03e0) * a8 + (y16 & 0x03e0) * ia8) >> 5) & 0x03e0;
// rg2
t |= ((t16 & 0x00ff) << 24);
dest32[1] = t;
x = src32[2];
y = dest32[2];
// gb2
t = (t16 >> 8);
}
}
{
a8 = a & 0xff;
ia8 = ia & 0xff;
// g3,a3
t |= (((x & 0x03e0ff00) * a8 + (y & 0x03e0ff00) * ia8) >> 5)
& 0x03e0ff00;
// r3,b3
t |= (((x & 0x7c1f0000) >> 5) * a8 + ((y & 0x7c1f0000) >> 5) * ia8)
& 0x7c1f0000;
dest32[2] = t;
}
}
#endif
template <>
inline void interpolate_pixel_4(qrgb888 *dest, const qrgb888 *src,
quint32 alpha)
{
Q_ASSERT((long(dest) & 0x3) == 0);
Q_ASSERT((long(src) & 0x3) == 0);
const quint32 a = eff_alpha_4(alpha, dest);
const quint32 ia = eff_ialpha_4(alpha, dest);
const quint32 *src32 = reinterpret_cast<const quint32*>(src);
quint32 *dest32 = reinterpret_cast<quint32*>(dest);
{
quint32 x = src32[0];
quint32 y = dest32[0];
quint32 t;
t = ((x >> 8) & 0xff00ff) * (a >> 24)
+ ((y >> 8) & 0xff00ff) * (ia >> 24);
t = (t + ((t >> 8) & 0xff00ff) + 0x800080);
t &= 0xff00ff00;
x = (x & 0xff0000) * (a >> 24)
+ (x & 0x0000ff) * ((a >> 16) & 0xff)
+ (y & 0xff0000) * (ia >> 24)
+ (y & 0x0000ff) * ((ia >> 16) & 0xff);
x = (x + ((x >> 8) & 0xff00ff) + 0x800080) >> 8;
x &= 0x00ff00ff;
dest32[0] = x | t;
}
{
quint32 x = src32[1];
quint32 y = dest32[1];
quint32 t;
t = ((x >> 8) & 0xff0000) * ((a >> 16) & 0xff)
+ ((x >> 8) & 0x0000ff) * ((a >> 8) & 0xff)
+ ((y >> 8) & 0xff0000) * ((ia >> 16) & 0xff)
+ ((y >> 8) & 0x0000ff) * ((ia >> 8) & 0xff);
t = (t + ((t >> 8) & 0xff00ff) + 0x800080);
t &= 0xff00ff00;
x = (x & 0xff0000) * ((a >> 16) & 0xff)
+ (x & 0x0000ff) * ((a >> 8) & 0xff)
+ (y & 0xff0000) * ((ia >> 16) & 0xff)
+ (y & 0x0000ff) * ((ia >> 8) & 0xff);
x = (x + ((x >> 8) & 0xff00ff) + 0x800080) >> 8;
x &= 0x00ff00ff;
dest32[1] = x | t;
}
{
quint32 x = src32[2];
quint32 y = dest32[2];
quint32 t;
t = ((x >> 8) & 0xff0000) * ((a >> 8) & 0xff)
+ ((x >> 8) & 0x0000ff) * (a & 0xff)
+ ((y >> 8) & 0xff0000) * ((ia >> 8) & 0xff)
+ ((y >> 8) & 0x0000ff) * (ia & 0xff);
t = (t + ((t >> 8) & 0xff00ff) + 0x800080);
t &= 0xff00ff00;
x = (x & 0xff00ff) * (a & 0xff)
+ (y & 0xff00ff) * (ia & 0xff);
x = (x + ((x >> 8) & 0xff00ff) + 0x800080) >> 8;
x &= 0x00ff00ff;
dest32[2] = x | t;
}
}
template <class DST, class SRC>
inline void interpolate_pixel_4(DST *dest, quint8 a,
const SRC *src, quint8 b)
{
Q_ASSERT((long(dest) & 0x3) == 0);
Q_ASSERT((long(src) & 0x3) == 0);
dest[0] = dest[0].byte_mul(a) + DST(src[0]).byte_mul(b);
dest[1] = dest[1].byte_mul(a) + DST(src[1]).byte_mul(b);
dest[2] = dest[2].byte_mul(a) + DST(src[2]).byte_mul(b);
dest[3] = dest[3].byte_mul(a) + DST(src[3]).byte_mul(b);
}
template <class DST, class SRC>
inline void blend_sourceOver_4(DST *dest, const SRC *src)
{
Q_ASSERT((long(dest) & 0x3) == 0);
Q_ASSERT((long(src) & 0x3) == 0);
const quint32 a = alpha_4(src);
if (a == 0xffffffff) {
qt_memconvert(dest, src, 4);
} else if (a > 0) {
quint32 buf[3]; // array of quint32 to get correct alignment
qt_memconvert((DST*)(void*)buf, src, 4);
madd_4(dest, eff_ialpha_4(a, dest), (DST*)(void*)buf);
}
}
template <>
inline void blend_sourceOver_4(qargb8565 *dest, const qargb8565 *src)
{
Q_ASSERT((long(dest) & 0x3) == 0);
Q_ASSERT((long(src) & 0x3) == 0);
const quint32 a = alpha_4(src);
if (a == 0xffffffff) {
qt_memconvert(dest, src, 4);
} else if (a > 0) {
madd_4(dest, eff_ialpha_4(a, dest), src);
}
}
template <>
inline void blend_sourceOver_4(qargb8555 *dest, const qargb8555 *src)
{
Q_ASSERT((long(dest) & 0x3) == 0);
Q_ASSERT((long(src) & 0x3) == 0);
const quint32 a = alpha_4(src);
if (a == 0xffffffff) {
qt_memconvert(dest, src, 4);
} else if (a > 0) {
madd_4(dest, eff_ialpha_4(a, dest), src);
}
}
template <>
inline void blend_sourceOver_4(qargb6666 *dest, const qargb6666 *src)
{
Q_ASSERT((long(dest) & 0x3) == 0);
Q_ASSERT((long(src) & 0x3) == 0);
const quint32 a = alpha_4(src);
if (a == 0xffffffff) {
qt_memconvert(dest, src, 4);
} else if (a > 0) {
madd_4(dest, eff_ialpha_4(a, dest), src);
}
}
template <class DST, class SRC>
void QT_FASTCALL blendUntransformed_unaligned(DST *dest, const SRC *src,
quint8 coverage, int length)
{
Q_ASSERT(coverage > 0);
if (coverage < 255) {
if (SRC::hasAlpha()) {
for (int i = 0; i < length; ++i) {
if (src[i].alpha()) {
const quint8 alpha = qt_div_255(int(src[i].alpha()) * int(coverage));
interpolate_pixel(dest[i], DST::ialpha(alpha),
src[i], DST::alpha(alpha));
}
}
} else {
const quint8 alpha = DST::alpha(coverage);
const quint8 ialpha = DST::ialpha(coverage);
if (alpha) {
for (int i = 0; i < length; ++i)
interpolate_pixel(dest[i], ialpha, src[i], alpha);
}
}
return;
}
Q_ASSERT(coverage == 0xff);
Q_ASSERT(SRC::hasAlpha());
if (SRC::hasAlpha()) {
for (int i = 0; i < length; ++i) {
const quint8 a = src->alpha();
if (a == 0xff)
*dest = DST(*src);
else if (a > 0) {
if (DST::hasAlpha())
*dest = DST(*src).truncedAlpha() + dest->byte_mul(DST::ialpha(a));
else
*dest = DST(SRC(*src).truncedAlpha()) + dest->byte_mul(DST::ialpha(a));
}
++src;
++dest;
}
}
}
template <class DST, class SRC>
void QT_FASTCALL blendUntransformed_dest16(DST *dest, const SRC *src,
quint8 coverage, int length)
{
Q_ASSERT(sizeof(DST) == 2);
Q_ASSERT(sizeof(SRC) == 2);
Q_ASSERT((long(dest) & 0x3) == (long(src) & 0x3));
Q_ASSERT(coverage > 0);
const int align = quintptr(dest) & 0x3;
if (coverage < 255) {
// align
if (align) {
const quint8 alpha = SRC::hasAlpha()
? qt_div_255(int(src->alpha()) * int(coverage))
: coverage;
if (alpha) {
interpolate_pixel(*dest, DST::ialpha(alpha),
*src, DST::alpha(alpha));
}
++dest;
++src;
--length;
}
if (SRC::hasAlpha()) {
while (length >= 2) {
const quint16 alpha16 = BYTE_MUL(uint(alpha_2(src)), uint(coverage));
interpolate_pixel_2(dest, src, alpha16);
length -= 2;
src += 2;
dest += 2;
}
} else {
const quint8 alpha = DST::alpha(coverage);
const quint8 ialpha = DST::ialpha(coverage);
while (length >= 2) {
interpolate_pixel_2(dest, ialpha, src, alpha);
length -= 2;
src += 2;
dest += 2;
}
}
// tail
if (length) {
const quint8 alpha = SRC::hasAlpha()
? qt_div_255(int(src->alpha()) * int(coverage))
: coverage;
if (alpha) {
interpolate_pixel(*dest, DST::ialpha(alpha),
*src, DST::alpha(alpha));
}
}
return;
}
Q_ASSERT(SRC::hasAlpha());
if (SRC::hasAlpha()) {
if (align) {
const quint8 alpha = src->alpha();
if (alpha == 0xff)
*dest = DST(*src);
else if (alpha > 0)
*dest = DST(*src).truncedAlpha() + dest->byte_mul(DST::ialpha(alpha));
++dest;
++src;
--length;
}
while (length >= 2) {
Q_ASSERT((long(dest) & 3) == 0);
Q_ASSERT((long(src) & 3) == 0);
const quint16 a = alpha_2(src);
if (a == 0xffff) {
qt_memconvert(dest, src, 2);
} else if (a > 0) {
quint32 buf;
if (sizeof(DST) == 2)
qt_memconvert((DST*)(void*)&buf, src, 2);
madd_2(dest, eff_ialpha_2(a, dest), (DST*)(void*)&buf);
}
length -= 2;
src += 2;
dest += 2;
}
if (length) {
const quint8 alpha = src->alpha();
if (alpha == 0xff)
*dest = DST(*src);
else if (alpha > 0)
*dest = DST(*src).truncedAlpha() + dest->byte_mul(DST::ialpha(alpha));
}
}
}
template <class DST, class SRC>
void QT_FASTCALL blendUntransformed_dest24(DST *dest, const SRC *src,
quint8 coverage, int length)
{
Q_ASSERT((long(dest) & 0x3) == (long(src) & 0x3));
Q_ASSERT(sizeof(DST) == 3);
Q_ASSERT(coverage > 0);
const int align = quintptr(dest) & 0x3;
if (coverage < 255) {
// align
for (int i = 0; i < align; ++i) {
if (SRC::hasAlpha()) {
const quint8 alpha = qt_div_255(int(src->alpha()) * int(coverage));
if (alpha)
interpolate_pixel(*dest, DST::ialpha(alpha),
*src, DST::alpha(alpha));
} else {
interpolate_pixel(*dest, DST::ialpha(coverage),
*src, DST::alpha(coverage));
}
++dest;
++src;
--length;
}
if (SRC::hasAlpha()) {
while (length >= 4) {
const quint32 alpha = BYTE_MUL(uint(alpha_4(src)), uint(coverage));
if (alpha)
interpolate_pixel_4(dest, src, alpha);
length -= 4;
src += 4;
dest += 4;
}
} else {
const quint8 alpha = DST::alpha(coverage);
const quint8 ialpha = DST::ialpha(coverage);
while (length >= 4) {
interpolate_pixel_4(dest, ialpha, src, alpha);
length -= 4;
src += 4;
dest += 4;
}
}
// tail
while (length--) {
if (SRC::hasAlpha()) {
const quint8 alpha = qt_div_255(int(src->alpha()) * int(coverage));
if (alpha)
interpolate_pixel(*dest, DST::ialpha(alpha),
*src, DST::alpha(alpha));
} else {
interpolate_pixel(*dest, DST::ialpha(coverage),
*src, DST::alpha(coverage));
}
++dest;
++src;
}
return;
}
Q_ASSERT(coverage == 255);
Q_ASSERT(SRC::hasAlpha());
if (SRC::hasAlpha()) {
// align
for (int i = 0; i < align; ++i) {
const quint8 a = src->alpha();
if (a == 0xff) {
*dest = DST(*src);
} else if (a > 0) {
*dest = DST(*src).truncedAlpha() + dest->byte_mul(DST::ialpha(a));
}
++dest;
++src;
--length;
}
while (length >= 4) {
blend_sourceOver_4(dest, src);
length -= 4;
src += 4;
dest += 4;
}
// tail
while (length--) {
const quint8 a = src->alpha();
if (a == 0xff) {
*dest = DST(*src);
} else if (a > 0) {
*dest = DST(*src).truncedAlpha() + dest->byte_mul(DST::ialpha(a));
}
++dest;
++src;
}
}
}
template <class DST, class SRC>
Q_STATIC_TEMPLATE_SPECIALIZATION
void QT_FASTCALL blendUntransformed(int count, const QSpan *spans, void *userData)
{
QSpanData *data = reinterpret_cast<QSpanData*>(userData);
QPainter::CompositionMode mode = data->rasterBuffer->compositionMode;
if (mode != QPainter::CompositionMode_SourceOver &&
mode != QPainter::CompositionMode_Source)
{
blend_src_generic<RegularSpans>(count, spans, userData);
return;
}
const bool modeSource = !SRC::hasAlpha() ||
mode == QPainter::CompositionMode_Source;
const int image_width = data->texture.width;
const int image_height = data->texture.height;
int xoff = -qRound(-data->dx);
int yoff = -qRound(-data->dy);
while (count--) {
const quint8 coverage = (data->texture.const_alpha * spans->coverage) >> 8;
if (coverage == 0) {
++spans;
continue;
}
int x = spans->x;
int length = spans->len;
int sx = xoff + x;
int sy = yoff + spans->y;
if (sy >= 0 && sy < image_height && sx < image_width) {
if (sx < 0) {
x -= sx;
length += sx;
sx = 0;
}
if (sx + length > image_width)
length = image_width - sx;
if (length > 0) {
DST *dest = ((DST*)data->rasterBuffer->scanLine(spans->y)) + x;
const SRC *src = (SRC*)data->texture.scanLine(sy) + sx;
if (modeSource && coverage == 255) {
qt_memconvert<DST, SRC>(dest, src, length);
} else if (sizeof(DST) == 3 && sizeof(SRC) == 3 && length >= 3 &&
(quintptr(dest) & 3) == (quintptr(src) & 3))
{
blendUntransformed_dest24(dest, src, coverage, length);
} else if (sizeof(DST) == 2 && sizeof(SRC) == 2 && length >= 3 &&
(quintptr(dest) & 3) == (quintptr(src) & 3))
{
blendUntransformed_dest16(dest, src, coverage, length);
} else {
blendUntransformed_unaligned(dest, src, coverage, length);
}
}
}
++spans;
}
}
static void blend_untransformed_rgb888(int count, const QSpan *spans,
void *userData)
{
#if defined(QT_QWS_DEPTH_24)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_RGB888)
blendUntransformed<qrgb888, qrgb888>(count, spans, userData);
else
#endif
blend_untransformed_generic<RegularSpans>(count, spans, userData);
}
static void blend_untransformed_argb6666(int count, const QSpan *spans,
void *userData)
{
#if defined(QT_QWS_DEPTH_18)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB6666_Premultiplied)
blendUntransformed<qargb6666, qargb6666>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB666)
blendUntransformed<qargb6666, qrgb666>(count, spans, userData);
else
#endif
blend_untransformed_generic<RegularSpans>(count, spans, userData);
}
static void blend_untransformed_rgb666(int count, const QSpan *spans,
void *userData)
{
#if defined(QT_QWS_DEPTH_18)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB6666_Premultiplied)
blendUntransformed<qrgb666, qargb6666>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB666)
blendUntransformed<qrgb666, qrgb666>(count, spans, userData);
else
#endif
blend_untransformed_generic<RegularSpans>(count, spans, userData);
}
static void blend_untransformed_argb8565(int count, const QSpan *spans,
void *userData)
{
#if defined(QT_QWS_DEPTH_16)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB8565_Premultiplied)
blendUntransformed<qargb8565, qargb8565>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB16)
blendUntransformed<qargb8565, qrgb565>(count, spans, userData);
else
#endif
blend_untransformed_generic<RegularSpans>(count, spans, userData);
}
static void blend_untransformed_rgb565(int count, const QSpan *spans,
void *userData)
{
#if defined(QT_QWS_DEPTH_16)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB8565_Premultiplied)
blendUntransformed<qrgb565, qargb8565>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB16)
blendUntransformed<qrgb565, qrgb565>(count, spans, userData);
else
#endif
blend_untransformed_generic<RegularSpans>(count, spans, userData);
}
static void blend_untransformed_argb8555(int count, const QSpan *spans,
void *userData)
{
#if defined(QT_QWS_DEPTH_15)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB8555_Premultiplied)
blendUntransformed<qargb8555, qargb8555>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB555)
blendUntransformed<qargb8555, qrgb555>(count, spans, userData);
else
#endif
blend_untransformed_generic<RegularSpans>(count, spans, userData);
}
static void blend_untransformed_rgb555(int count, const QSpan *spans,
void *userData)
{
#if defined(QT_QWS_DEPTH_15)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB8555_Premultiplied)
blendUntransformed<qrgb555, qargb8555>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB555)
blendUntransformed<qrgb555, qrgb555>(count, spans, userData);
else
#endif
blend_untransformed_generic<RegularSpans>(count, spans, userData);
}
static void blend_untransformed_argb4444(int count, const QSpan *spans,
void *userData)
{
#if defined(QT_QWS_DEPTH_12)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB4444_Premultiplied)
blendUntransformed<qargb4444, qargb4444>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB444)
blendUntransformed<qargb4444, qrgb444>(count, spans, userData);
else
#endif
blend_untransformed_generic<RegularSpans>(count, spans, userData);
}
static void blend_untransformed_rgb444(int count, const QSpan *spans,
void *userData)
{
#if defined(QT_QWS_DEPTH_12)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB4444_Premultiplied)
blendUntransformed<qrgb444, qargb4444>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB444)
blendUntransformed<qrgb444, qrgb444>(count, spans, userData);
else
#endif
blend_untransformed_generic<RegularSpans>(count, spans, userData);
}
template <SpanMethod spanMethod>
Q_STATIC_TEMPLATE_FUNCTION void blend_tiled_generic(int count, const QSpan *spans, void *userData)
{
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
uint buffer[buffer_size];
uint src_buffer[buffer_size];
Operator op = getOperator(data, spans, count);
const int image_width = data->texture.width;
const int image_height = data->texture.height;
int xoff = -qRound(-data->dx) % image_width;
int yoff = -qRound(-data->dy) % image_height;
if (xoff < 0)
xoff += image_width;
if (yoff < 0)
yoff += image_height;
while (count--) {
int x = spans->x;
int length = spans->len;
int sx = (xoff + spans->x) % image_width;
int sy = (spans->y + yoff) % image_height;
if (sx < 0)
sx += image_width;
if (sy < 0)
sy += image_height;
const int coverage = (spans->coverage * data->texture.const_alpha) >> 8;
while (length) {
int l = qMin(image_width - sx, length);
if (buffer_size < l)
l = buffer_size;
const uint *src = op.src_fetch(src_buffer, &op, data, sy, sx, l);
if (spanMethod == RegularSpans) {
uint *dest = op.dest_fetch ? op.dest_fetch(buffer, data->rasterBuffer, x, spans->y, l) : buffer;
op.func(dest, src, l, coverage);
if (op.dest_store)
op.dest_store(data->rasterBuffer, x, spans->y, dest, l);
} else {
drawBufferSpan(data, src, l, x, spans->y, l,
coverage);
}
x += l;
sx += l;
length -= l;
if (sx >= image_width)
sx = 0;
}
++spans;
}
}
template <SpanMethod spanMethod>
Q_STATIC_TEMPLATE_FUNCTION void blend_tiled_argb(int count, const QSpan *spans, void *userData)
{
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format != QImage::Format_ARGB32_Premultiplied
&& data->texture.format != QImage::Format_RGB32) {
blend_tiled_generic<spanMethod>(count, spans, userData);
return;
}
Operator op = getOperator(data, spans, count);
int image_width = data->texture.width;
int image_height = data->texture.height;
int xoff = -qRound(-data->dx) % image_width;
int yoff = -qRound(-data->dy) % image_height;
if (xoff < 0)
xoff += image_width;
if (yoff < 0)
yoff += image_height;
while (count--) {
int x = spans->x;
int length = spans->len;
int sx = (xoff + spans->x) % image_width;
int sy = (spans->y + yoff) % image_height;
if (sx < 0)
sx += image_width;
if (sy < 0)
sy += image_height;
const int coverage = (spans->coverage * data->texture.const_alpha) >> 8;
while (length) {
int l = qMin(image_width - sx, length);
if (buffer_size < l)
l = buffer_size;
const uint *src = (uint *)data->texture.scanLine(sy) + sx;
if (spanMethod == RegularSpans) {
uint *dest = ((uint *)data->rasterBuffer->scanLine(spans->y)) + x;
op.func(dest, src, l, coverage);
} else {
drawBufferSpan(data, src, buffer_size,
x, spans->y, l, coverage);
}
x += l;
length -= l;
sx = 0;
}
++spans;
}
}
template <class DST, class SRC>
Q_STATIC_TEMPLATE_FUNCTION void blendTiled(int count, const QSpan *spans, void *userData)
{
QSpanData *data = reinterpret_cast<QSpanData*>(userData);
QPainter::CompositionMode mode = data->rasterBuffer->compositionMode;
if (mode != QPainter::CompositionMode_SourceOver &&
mode != QPainter::CompositionMode_Source)
{
blend_src_generic<RegularSpans>(count, spans, userData);
return;
}
const bool modeSource = !SRC::hasAlpha() ||
mode == QPainter::CompositionMode_Source;
const int image_width = data->texture.width;
const int image_height = data->texture.height;
int xoff = -qRound(-data->dx) % image_width;
int yoff = -qRound(-data->dy) % image_height;
if (xoff < 0)
xoff += image_width;
if (yoff < 0)
yoff += image_height;
while (count--) {
const quint8 coverage = (data->texture.const_alpha * spans->coverage) >> 8;
if (coverage == 0) {
++spans;
continue;
}
int x = spans->x;
int length = spans->len;
int sx = (xoff + spans->x) % image_width;
int sy = (spans->y + yoff) % image_height;
if (sx < 0)
sx += image_width;
if (sy < 0)
sy += image_height;
if (modeSource && coverage == 255) {
// Copy the first texture block
length = qMin(image_width,length);
int tx = x;
while (length) {
int l = qMin(image_width - sx, length);
if (buffer_size < l)
l = buffer_size;
DST *dest = ((DST*)data->rasterBuffer->scanLine(spans->y)) + tx;
const SRC *src = (SRC*)data->texture.scanLine(sy) + sx;
qt_memconvert<DST, SRC>(dest, src, l);
length -= l;
tx += l;
sx = 0;
}
// Now use the rasterBuffer as the source of the texture,
// We can now progressively copy larger blocks
// - Less cpu time in code figuring out what to copy
// We are dealing with one block of data
// - More likely to fit in the cache
// - can use memcpy
int copy_image_width = qMin(image_width, int(spans->len));
length = spans->len - copy_image_width;
DST *src = ((DST*)data->rasterBuffer->scanLine(spans->y)) + x;
DST *dest = src + copy_image_width;
while (copy_image_width < length) {
qt_memconvert(dest, src, copy_image_width);
dest += copy_image_width;
length -= copy_image_width;
copy_image_width *= 2;
}
qt_memconvert(dest, src, length);
} else {
while (length) {
int l = qMin(image_width - sx, length);
if (buffer_size < l)
l = buffer_size;
DST *dest = ((DST*)data->rasterBuffer->scanLine(spans->y)) + x;
const SRC *src = (SRC*)data->texture.scanLine(sy) + sx;
if (sizeof(DST) == 3 && sizeof(SRC) == 3 && l >= 4 &&
(quintptr(dest) & 3) == (quintptr(src) & 3))
{
blendUntransformed_dest24(dest, src, coverage, l);
} else if (sizeof(DST) == 2 && sizeof(SRC) == 2 && l >= 2 &&
(quintptr(dest) & 3) == (quintptr(src) & 3))
{
blendUntransformed_dest16(dest, src, coverage, l);
} else {
blendUntransformed_unaligned(dest, src, coverage, l);
}
x += l;
length -= l;
sx = 0;
}
}
++spans;
}
}
static void blend_tiled_rgb888(int count, const QSpan *spans, void *userData)
{
#if defined(QT_QWS_DEPTH_24)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_RGB888)
blendTiled<qrgb888, qrgb888>(count, spans, userData);
else
#endif
blend_tiled_generic<RegularSpans>(count, spans, userData);
}
static void blend_tiled_argb6666(int count, const QSpan *spans, void *userData)
{
#if defined(QT_QWS_DEPTH_18)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB6666_Premultiplied)
blendTiled<qargb6666, qargb6666>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB666)
blendTiled<qargb6666, qrgb666>(count, spans, userData);
else
#endif
blend_tiled_generic<RegularSpans>(count, spans, userData);
}
static void blend_tiled_rgb666(int count, const QSpan *spans, void *userData)
{
#if defined(QT_QWS_DEPTH_18)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB6666_Premultiplied)
blendTiled<qrgb666, qargb6666>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB666)
blendTiled<qrgb666, qrgb666>(count, spans, userData);
else
#endif
blend_tiled_generic<RegularSpans>(count, spans, userData);
}
static void blend_tiled_argb8565(int count, const QSpan *spans, void *userData)
{
#if defined(QT_QWS_DEPTH_16)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB8565_Premultiplied)
blendTiled<qargb8565, qargb8565>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB16)
blendTiled<qargb8565, qrgb565>(count, spans, userData);
else
#endif
blend_tiled_generic<RegularSpans>(count, spans, userData);
}
static void blend_tiled_rgb565(int count, const QSpan *spans, void *userData)
{
#if defined(QT_QWS_DEPTH_16)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB8565_Premultiplied)
blendTiled<qrgb565, qargb8565>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB16)
blendTiled<qrgb565, qrgb565>(count, spans, userData);
else
#endif
blend_tiled_generic<RegularSpans>(count, spans, userData);
}
static void blend_tiled_argb8555(int count, const QSpan *spans, void *userData)
{
#if defined(QT_QWS_DEPTH_15)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB8555_Premultiplied)
blendTiled<qargb8555, qargb8555>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB555)
blendTiled<qargb8555, qrgb555>(count, spans, userData);
else
#endif
blend_tiled_generic<RegularSpans>(count, spans, userData);
}
static void blend_tiled_rgb555(int count, const QSpan *spans, void *userData)
{
#if defined(QT_QWS_DEPTH_15)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB8555_Premultiplied)
blendTiled<qrgb555, qargb8555>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB555)
blendTiled<qrgb555, qrgb555>(count, spans, userData);
else
#endif
blend_tiled_generic<RegularSpans>(count, spans, userData);
}
static void blend_tiled_argb4444(int count, const QSpan *spans, void *userData)
{
#if defined(QT_QWS_DEPTH_12)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB4444_Premultiplied)
blendTiled<qargb4444, qargb4444>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB444)
blendTiled<qargb4444, qrgb444>(count, spans, userData);
else
#endif
blend_tiled_generic<RegularSpans>(count, spans, userData);
}
static void blend_tiled_rgb444(int count, const QSpan *spans, void *userData)
{
#if defined(QT_QWS_DEPTH_12)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB4444_Premultiplied)
blendTiled<qrgb444, qargb4444>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB444)
blendTiled<qrgb444, qrgb444>(count, spans, userData);
else
#endif
blend_tiled_generic<RegularSpans>(count, spans, userData);
}
template <SpanMethod spanMethod>
Q_STATIC_TEMPLATE_FUNCTION void blend_transformed_bilinear_argb(int count, const QSpan *spans, void *userData)
{
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format != QImage::Format_ARGB32_Premultiplied
&& data->texture.format != QImage::Format_RGB32) {
blend_src_generic<spanMethod>(count, spans, userData);
return;
}
CompositionFunction func = functionForMode[data->rasterBuffer->compositionMode];
uint buffer[buffer_size];
int image_x1 = data->texture.x1;
int image_y1 = data->texture.y1;
int image_x2 = data->texture.x2;
int image_y2 = data->texture.y2;
const int scanline_offset = data->texture.bytesPerLine / 4;
if (data->fast_matrix) {
// The increment pr x in the scanline
int fdx = (int)(data->m11 * fixed_scale);
int fdy = (int)(data->m12 * fixed_scale);
while (count--) {
void *t = data->rasterBuffer->scanLine(spans->y);
uint *target = ((uint *)t) + spans->x;
uint *image_bits = (uint *)data->texture.imageData;
const qreal cx = spans->x + 0.5;
const qreal cy = spans->y + 0.5;
int x = int((data->m21 * cy
+ data->m11 * cx + data->dx) * fixed_scale) - half_point;
int y = int((data->m22 * cy
+ data->m12 * cx + data->dy) * fixed_scale) - half_point;
int length = spans->len;
const int coverage = (data->texture.const_alpha * spans->coverage) >> 8;
while (length) {
int l = qMin(length, buffer_size);
const uint *end = buffer + l;
uint *b = buffer;
while (b < end) {
int x1 = (x >> 16);
int x2 = x1 + 1;
int y1 = (y >> 16);
int y2 = y1 + 1;
int distx = ((x - (x1 << 16)) >> 8);
int disty = ((y - (y1 << 16)) >> 8);
int idistx = 256 - distx;
int idisty = 256 - disty;
x1 = qBound(image_x1, x1, image_x2 - 1);
x2 = qBound(image_x1, x2, image_x2 - 1);
y1 = qBound(image_y1, y1, image_y2 - 1);
y2 = qBound(image_y1, y2, image_y2 - 1);
int y1_offset = y1 * scanline_offset;
int y2_offset = y2 * scanline_offset;
#if defined(Q_IRIX_GCC3_3_WORKAROUND)
uint tl = gccBug(image_bits[y1_offset + x1]);
uint tr = gccBug(image_bits[y1_offset + x2]);
uint bl = gccBug(image_bits[y2_offset + x1]);
uint br = gccBug(image_bits[y2_offset + x2]);
#else
uint tl = image_bits[y1_offset + x1];
uint tr = image_bits[y1_offset + x2];
uint bl = image_bits[y2_offset + x1];
uint br = image_bits[y2_offset + x2];
#endif
uint xtop = INTERPOLATE_PIXEL_256(tl, idistx, tr, distx);
uint xbot = INTERPOLATE_PIXEL_256(bl, idistx, br, distx);
*b = INTERPOLATE_PIXEL_256(xtop, idisty, xbot, disty);
++b;
x += fdx;
y += fdy;
}
if (spanMethod == RegularSpans)
func(target, buffer, l, coverage);
else
drawBufferSpan(data, buffer, buffer_size,
spans->x + spans->len - length,
spans->y, l, coverage);
target += l;
length -= l;
}
++spans;
}
} else {
const qreal fdx = data->m11;
const qreal fdy = data->m12;
const qreal fdw = data->m13;
while (count--) {
void *t = data->rasterBuffer->scanLine(spans->y);
uint *target = ((uint *)t) + spans->x;
uint *image_bits = (uint *)data->texture.imageData;
const qreal cx = spans->x + 0.5;
const qreal cy = spans->y + 0.5;
qreal x = data->m21 * cy + data->m11 * cx + data->dx;
qreal y = data->m22 * cy + data->m12 * cx + data->dy;
qreal w = data->m23 * cy + data->m13 * cx + data->m33;
int length = spans->len;
const int coverage = (data->texture.const_alpha * spans->coverage) >> 8;
while (length) {
int l = qMin(length, buffer_size);
const uint *end = buffer + l;
uint *b = buffer;
while (b < end) {
const qreal iw = w == 0 ? 1 : 1 / w;
const qreal px = x * iw - 0.5;
const qreal py = y * iw - 0.5;
int x1 = int(px) - (px < 0);
int x2 = x1 + 1;
int y1 = int(py) - (py < 0);
int y2 = y1 + 1;
int distx = int((px - x1) * 256);
int disty = int((py - y1) * 256);
int idistx = 256 - distx;
int idisty = 256 - disty;
x1 = qBound(image_x1, x1, image_x2 - 1);
x2 = qBound(image_x1, x2, image_x2 - 1);
y1 = qBound(image_y1, y1, image_y2 - 1);
y2 = qBound(image_y1, y2, image_y2 - 1);
int y1_offset = y1 * scanline_offset;
int y2_offset = y2 * scanline_offset;
#if defined(Q_IRIX_GCC3_3_WORKAROUND)
uint tl = gccBug(image_bits[y1_offset + x1]);
uint tr = gccBug(image_bits[y1_offset + x2]);
uint bl = gccBug(image_bits[y2_offset + x1]);
uint br = gccBug(image_bits[y2_offset + x2]);
#else
uint tl = image_bits[y1_offset + x1];
uint tr = image_bits[y1_offset + x2];
uint bl = image_bits[y2_offset + x1];
uint br = image_bits[y2_offset + x2];
#endif
uint xtop = INTERPOLATE_PIXEL_256(tl, idistx, tr, distx);
uint xbot = INTERPOLATE_PIXEL_256(bl, idistx, br, distx);
*b = INTERPOLATE_PIXEL_256(xtop, idisty, xbot, disty);
++b;
x += fdx;
y += fdy;
w += fdw;
}
if (spanMethod == RegularSpans)
func(target, buffer, l, coverage);
else
drawBufferSpan(data, buffer, buffer_size,
spans->x + spans->len - length,
spans->y, l, coverage);
target += l;
length -= l;
}
++spans;
}
}
}
template <class DST, class SRC>
Q_STATIC_TEMPLATE_FUNCTION void blendTransformedBilinear(int count, const QSpan *spans,
void *userData)
{
QSpanData *data = reinterpret_cast<QSpanData*>(userData);
QPainter::CompositionMode mode = data->rasterBuffer->compositionMode;
if (mode != QPainter::CompositionMode_SourceOver) {
blend_src_generic<RegularSpans>(count, spans, userData);
return;
}
SRC buffer[buffer_size];
const int src_minx = data->texture.x1;
const int src_miny = data->texture.y1;
const int src_maxx = data->texture.x2 - 1;
const int src_maxy = data->texture.y2 - 1;
if (data->fast_matrix) {
// The increment pr x in the scanline
const int fdx = (int)(data->m11 * fixed_scale);
const int fdy = (int)(data->m12 * fixed_scale);
while (count--) {
const quint8 coverage = (data->texture.const_alpha * spans->coverage) >> 8;
if (coverage == 0) {
++spans;
continue;
}
DST *dest = (DST*)data->rasterBuffer->scanLine(spans->y)
+ spans->x;
const qreal cx = spans->x + qreal(0.5);
const qreal cy = spans->y + qreal(0.5);
int x = int((data->m21 * cy
+ data->m11 * cx + data->dx) * fixed_scale) - half_point;
int y = int((data->m22 * cy
+ data->m12 * cx + data->dy) * fixed_scale) - half_point;
int length = spans->len;
while (length) {
const int l = qMin(length, buffer_size);
const SRC *end = buffer + l;
SRC *b = buffer;
while (b < end) {
int x1 = (x >> 16);
int x2 = x1 + 1;
int y1 = (y >> 16);
int y2 = y1 + 1;
const int distx = ((x - (x1 << 16)) >> 8);
const int disty = ((y - (y1 << 16)) >> 8);
x1 = qBound(src_minx, x1, src_maxx);
x2 = qBound(src_minx, x2, src_maxx);
y1 = qBound(src_miny, y1, src_maxy);
y2 = qBound(src_miny, y2, src_maxy);
#if 0
if (x1 == x2) {
if (y1 == y2) {
*b = ((SRC*)data->texture.scanLine(y1))[x1];
} else {
*b = ((SRC*)data->texture.scanLine(y1))[x1];
const SRC t = data->texture.scanLine(y2)[x1];
interpolate_pixel(*b, SRC::ialpha(disty),
t, SRC::alpha(disty));
}
} else if (y1 == y2) {
*b = ((SRC*)data->texture.scanLine(y1))[x1];
const SRC t = ((SRC*)data->texture.scanLine(y1))[x2];
interpolate_pixel(*b, SRC::ialpha(distx),
t, SRC::alpha(distx));
} else
#endif
{
const SRC *src1 = (SRC*)data->texture.scanLine(y1);
const SRC *src2 = (SRC*)data->texture.scanLine(y2);
SRC tl = src1[x1];
const SRC tr = src1[x2];
SRC bl = src2[x1];
const SRC br = src2[x2];
const quint8 ax = SRC::alpha(distx);
const quint8 iax = SRC::ialpha(distx);
interpolate_pixel(tl, iax, tr, ax);
interpolate_pixel(bl, iax, br, ax);
interpolate_pixel(tl, SRC::ialpha(disty),
bl, SRC::alpha(disty));
*b = tl;
}
++b;
x += fdx;
y += fdy;
}
if (!SRC::hasAlpha() && coverage == 255) {
qt_memconvert(dest, buffer, l);
} else if (sizeof(DST) == 3 && l >= 4 &&
(quintptr(dest) & 3) == (quintptr(buffer) & 3))
{
blendUntransformed_dest24(dest, buffer, coverage, l);
} else if (sizeof(DST) == 2 && sizeof(SRC) == 2 && l >= 2 &&
(quintptr(dest) & 3) == (quintptr(buffer) & 3)) {
blendUntransformed_dest16(dest, buffer, coverage, l);
} else {
blendUntransformed_unaligned(dest, buffer, coverage, l);
}
dest += l;
length -= l;
}
++spans;
}
} else {
const qreal fdx = data->m11;
const qreal fdy = data->m12;
const qreal fdw = data->m13;
while (count--) {
const quint8 coverage = (data->texture.const_alpha * spans->coverage) >> 8;
if (coverage == 0) {
++spans;
continue;
}
DST *dest = (DST*)data->rasterBuffer->scanLine(spans->y)
+ spans->x;
const qreal cx = spans->x + qreal(0.5);
const qreal cy = spans->y + qreal(0.5);
qreal x = data->m21 * cy + data->m11 * cx + data->dx;
qreal y = data->m22 * cy + data->m12 * cx + data->dy;
qreal w = data->m23 * cy + data->m13 * cx + data->m33;
int length = spans->len;
while (length) {
const int l = qMin(length, buffer_size);
const SRC *end = buffer + l;
SRC *b = buffer;
while (b < end) {
const qreal iw = w == 0 ? 1 : 1 / w;
const qreal px = x * iw - qreal(0.5);
const qreal py = y * iw - qreal(0.5);
int x1 = int(px) - (px < 0);
int x2 = x1 + 1;
int y1 = int(py) - (py < 0);
int y2 = y1 + 1;
const int distx = int((px - x1) * 256);
const int disty = int((py - y1) * 256);
x1 = qBound(src_minx, x1, src_maxx);
x2 = qBound(src_minx, x2, src_maxx);
y1 = qBound(src_miny, y1, src_maxy);
y2 = qBound(src_miny, y2, src_maxy);
const SRC *src1 = (SRC*)data->texture.scanLine(y1);
const SRC *src2 = (SRC*)data->texture.scanLine(y2);
SRC tl = src1[x1];
const SRC tr = src1[x2];
SRC bl = src2[x1];
const SRC br = src2[x2];
const quint8 ax = SRC::alpha(distx);
const quint8 iax = SRC::ialpha(distx);
interpolate_pixel(tl, iax, tr, ax);
interpolate_pixel(bl, iax, br, ax);
interpolate_pixel(tl, SRC::ialpha(disty),
bl, SRC::alpha(disty));
*b = tl;
++b;
x += fdx;
y += fdy;
w += fdw;
}
if (!SRC::hasAlpha() && coverage == 255) {
qt_memconvert(dest, buffer, l);
} else if (sizeof(DST) == 3 && l >= 4 &&
(quintptr(dest) & 3) == (quintptr(buffer) & 3))
{
blendUntransformed_dest24(dest, buffer, coverage, l);
} else if (sizeof(DST) == 2 && sizeof(SRC) == 2 && l >= 2 &&
(quintptr(dest) & 3) == (quintptr(buffer) & 3)) {
blendUntransformed_dest16(dest, buffer, coverage, l);
} else {
blendUntransformed_unaligned(dest, buffer, coverage, l);
}
dest += l;
length -= l;
}
++spans;
}
}
}
static void blend_transformed_bilinear_rgb888(int count, const QSpan *spans, void *userData)
{
#if defined(QT_QWS_DEPTH_24)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_RGB888)
blendTransformedBilinear<qrgb888, qrgb888>(count, spans, userData);
else
#endif
blend_src_generic<RegularSpans>(count, spans, userData);
}
static void blend_transformed_bilinear_argb6666(int count, const QSpan *spans, void *userData)
{
#if defined(QT_QWS_DEPTH_18)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB6666_Premultiplied)
blendTransformedBilinear<qargb6666, qargb6666>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB666)
blendTransformedBilinear<qargb6666, qrgb666>(count, spans, userData);
else
#endif
blend_src_generic<RegularSpans>(count, spans, userData);
}
static void blend_transformed_bilinear_rgb666(int count, const QSpan *spans, void *userData)
{
#if defined(QT_QWS_DEPTH_18)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB6666_Premultiplied)
blendTransformedBilinear<qrgb666, qargb6666>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB666)
blendTransformedBilinear<qrgb666, qrgb666>(count, spans, userData);
else
#endif
blend_src_generic<RegularSpans>(count, spans, userData);
}
static void blend_transformed_bilinear_argb8565(int count, const QSpan *spans, void *userData)
{
#if defined(QT_QWS_DEPTH_16)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB8565_Premultiplied)
blendTransformedBilinear<qargb8565, qargb8565>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB16)
blendTransformedBilinear<qargb8565, qrgb565>(count, spans, userData);
else
#endif
blend_src_generic<RegularSpans>(count, spans, userData);
}
static void blend_transformed_bilinear_rgb565(int count, const QSpan *spans,
void *userData)
{
#if defined(QT_QWS_DEPTH_16)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_RGB16)
blendTransformedBilinear<qrgb565, qrgb565>(count, spans, userData);
else if (data->texture.format == QImage::Format_ARGB8565_Premultiplied)
blendTransformedBilinear<qrgb565, qargb8565>(count, spans, userData);
else
#endif
blend_src_generic<RegularSpans>(count, spans, userData);
}
static void blend_transformed_bilinear_argb8555(int count, const QSpan *spans, void *userData)
{
#if defined(QT_QWS_DEPTH_15)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB8555_Premultiplied)
blendTransformedBilinear<qargb8555, qargb8555>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB555)
blendTransformedBilinear<qargb8555, qrgb555>(count, spans, userData);
else
#endif
blend_src_generic<RegularSpans>(count, spans, userData);
}
static void blend_transformed_bilinear_rgb555(int count, const QSpan *spans, void *userData)
{
#if defined(QT_QWS_DEPTH_15)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB8555_Premultiplied)
blendTransformedBilinear<qrgb555, qargb8555>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB555)
blendTransformedBilinear<qrgb555, qrgb555>(count, spans, userData);
else
#endif
blend_src_generic<RegularSpans>(count, spans, userData);
}
static void blend_transformed_bilinear_argb4444(int count, const QSpan *spans, void *userData)
{
#if defined(QT_QWS_DEPTH_12)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB4444_Premultiplied)
blendTransformedBilinear<qargb4444, qargb4444>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB444)
blendTransformedBilinear<qargb4444, qrgb444>(count, spans, userData);
else
#endif
blend_src_generic<RegularSpans>(count, spans, userData);
}
static void blend_transformed_bilinear_rgb444(int count, const QSpan *spans, void *userData)
{
#if defined(QT_QWS_DEPTH_12)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB4444_Premultiplied)
blendTransformedBilinear<qrgb444, qargb4444>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB444)
blendTransformedBilinear<qrgb444, qrgb444>(count, spans, userData);
else
#endif
blend_src_generic<RegularSpans>(count, spans, userData);
}
template <SpanMethod spanMethod>
Q_STATIC_TEMPLATE_FUNCTION void blend_transformed_bilinear_tiled_argb(int count, const QSpan *spans, void *userData)
{
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format != QImage::Format_ARGB32_Premultiplied
&& data->texture.format != QImage::Format_RGB32) {
blend_src_generic<spanMethod>(count, spans, userData);
return;
}
CompositionFunction func = functionForMode[data->rasterBuffer->compositionMode];
uint buffer[buffer_size];
int image_width = data->texture.width;
int image_height = data->texture.height;
const int scanline_offset = data->texture.bytesPerLine / 4;
if (data->fast_matrix) {
// The increment pr x in the scanline
int fdx = (int)(data->m11 * fixed_scale);
int fdy = (int)(data->m12 * fixed_scale);
while (count--) {
void *t = data->rasterBuffer->scanLine(spans->y);
uint *target = ((uint *)t) + spans->x;
uint *image_bits = (uint *)data->texture.imageData;
const qreal cx = spans->x + 0.5;
const qreal cy = spans->y + 0.5;
int x = int((data->m21 * cy
+ data->m11 * cx + data->dx) * fixed_scale) - half_point;
int y = int((data->m22 * cy
+ data->m12 * cx + data->dy) * fixed_scale) - half_point;
int length = spans->len;
const int coverage = (spans->coverage * data->texture.const_alpha) >> 8;
while (length) {
int l = qMin(length, buffer_size);
const uint *end = buffer + l;
uint *b = buffer;
while (b < end) {
int x1 = (x >> 16);
int x2 = (x1 + 1);
int y1 = (y >> 16);
int y2 = (y1 + 1);
int distx = ((x - (x1 << 16)) >> 8);
int disty = ((y - (y1 << 16)) >> 8);
int idistx = 256 - distx;
int idisty = 256 - disty;
x1 %= image_width;
x2 %= image_width;
y1 %= image_height;
y2 %= image_height;
if (x1 < 0) x1 += image_width;
if (x2 < 0) x2 += image_width;
if (y1 < 0) y1 += image_height;
if (y2 < 0) y2 += image_height;
Q_ASSERT(x1 >= 0 && x1 < image_width);
Q_ASSERT(x2 >= 0 && x2 < image_width);
Q_ASSERT(y1 >= 0 && y1 < image_height);
Q_ASSERT(y2 >= 0 && y2 < image_height);
int y1_offset = y1 * scanline_offset;
int y2_offset = y2 * scanline_offset;
#if defined(Q_IRIX_GCC3_3_WORKAROUND)
uint tl = gccBug(image_bits[y1_offset + x1]);
uint tr = gccBug(image_bits[y1_offset + x2]);
uint bl = gccBug(image_bits[y2_offset + x1]);
uint br = gccBug(image_bits[y2_offset + x2]);
#else
uint tl = image_bits[y1_offset + x1];
uint tr = image_bits[y1_offset + x2];
uint bl = image_bits[y2_offset + x1];
uint br = image_bits[y2_offset + x2];
#endif
uint xtop = INTERPOLATE_PIXEL_256(tl, idistx, tr, distx);
uint xbot = INTERPOLATE_PIXEL_256(bl, idistx, br, distx);
*b = INTERPOLATE_PIXEL_256(xtop, idisty, xbot, disty);
++b;
x += fdx;
y += fdy;
}
if (spanMethod == RegularSpans)
func(target, buffer, l, coverage);
else
drawBufferSpan(data, buffer, buffer_size,
spans->x + spans->len - length,
spans->y, l, coverage);
target += l;
length -= l;
}
++spans;
}
} else {
const qreal fdx = data->m11;
const qreal fdy = data->m12;
const qreal fdw = data->m13;
while (count--) {
void *t = data->rasterBuffer->scanLine(spans->y);
uint *target = ((uint *)t) + spans->x;
uint *image_bits = (uint *)data->texture.imageData;
const qreal cx = spans->x + 0.5;
const qreal cy = spans->y + 0.5;
qreal x = data->m21 * cy + data->m11 * cx + data->dx;
qreal y = data->m22 * cy + data->m12 * cx + data->dy;
qreal w = data->m23 * cy + data->m13 * cx + data->m33;
int length = spans->len;
const int coverage = (spans->coverage * data->texture.const_alpha) >> 8;
while (length) {
int l = qMin(length, buffer_size);
const uint *end = buffer + l;
uint *b = buffer;
while (b < end) {
const qreal iw = w == 0 ? 1 : 1 / w;
const qreal px = x * iw - 0.5;
const qreal py = y * iw - 0.5;
int x1 = int(px) - (px < 0);
int x2 = x1 + 1;
int y1 = int(py) - (py < 0);
int y2 = y1 + 1;
int distx = int((px - x1) * 256);
int disty = int((py - y1) * 256);
int idistx = 256 - distx;
int idisty = 256 - disty;
x1 %= image_width;
x2 %= image_width;
y1 %= image_height;
y2 %= image_height;
if (x1 < 0) x1 += image_width;
if (x2 < 0) x2 += image_width;
if (y1 < 0) y1 += image_height;
if (y2 < 0) y2 += image_height;
Q_ASSERT(x1 >= 0 && x1 < image_width);
Q_ASSERT(x2 >= 0 && x2 < image_width);
Q_ASSERT(y1 >= 0 && y1 < image_height);
Q_ASSERT(y2 >= 0 && y2 < image_height);
int y1_offset = y1 * scanline_offset;
int y2_offset = y2 * scanline_offset;
#if defined(Q_IRIX_GCC3_3_WORKAROUND)
uint tl = gccBug(image_bits[y1_offset + x1]);
uint tr = gccBug(image_bits[y1_offset + x2]);
uint bl = gccBug(image_bits[y2_offset + x1]);
uint br = gccBug(image_bits[y2_offset + x2]);
#else
uint tl = image_bits[y1_offset + x1];
uint tr = image_bits[y1_offset + x2];
uint bl = image_bits[y2_offset + x1];
uint br = image_bits[y2_offset + x2];
#endif
uint xtop = INTERPOLATE_PIXEL_256(tl, idistx, tr, distx);
uint xbot = INTERPOLATE_PIXEL_256(bl, idistx, br, distx);
*b = INTERPOLATE_PIXEL_256(xtop, idisty, xbot, disty);
++b;
x += fdx;
y += fdy;
w += fdw;
}
if (spanMethod == RegularSpans)
func(target, buffer, l, coverage);
else
drawBufferSpan(data, buffer, buffer_size,
spans->x + spans->len - length,
spans->y, l, coverage);
target += l;
length -= l;
}
++spans;
}
}
}
template <SpanMethod spanMethod>
Q_STATIC_TEMPLATE_FUNCTION void blend_transformed_argb(int count, const QSpan *spans, void *userData)
{
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format != QImage::Format_ARGB32_Premultiplied
&& data->texture.format != QImage::Format_RGB32) {
blend_src_generic<spanMethod>(count, spans, userData);
return;
}
CompositionFunction func = functionForMode[data->rasterBuffer->compositionMode];
uint buffer[buffer_size];
int image_width = data->texture.width;
int image_height = data->texture.height;
const int scanline_offset = data->texture.bytesPerLine / 4;
if (data->fast_matrix) {
// The increment pr x in the scanline
int fdx = (int)(data->m11 * fixed_scale);
int fdy = (int)(data->m12 * fixed_scale);
while (count--) {
void *t = data->rasterBuffer->scanLine(spans->y);
uint *target = ((uint *)t) + spans->x;
uint *image_bits = (uint *)data->texture.imageData;
const qreal cx = spans->x + 0.5;
const qreal cy = spans->y + 0.5;
int x = int((data->m21 * cy
+ data->m11 * cx + data->dx) * fixed_scale);
int y = int((data->m22 * cy
+ data->m12 * cx + data->dy) * fixed_scale);
int length = spans->len;
const int coverage = (spans->coverage * data->texture.const_alpha) >> 8;
while (length) {
int l = qMin(length, buffer_size);
const uint *end = buffer + l;
uint *b = buffer;
while (b < end) {
int px = x >> 16;
int py = y >> 16;
bool out = (px < 0) || (px >= image_width)
|| (py < 0) || (py >= image_height);
int y_offset = py * scanline_offset;
*b = out ? uint(0) : image_bits[y_offset + px];
x += fdx;
y += fdy;
++b;
}
if (spanMethod == RegularSpans)
func(target, buffer, l, coverage);
else
drawBufferSpan(data, buffer, buffer_size,
spans->x + spans->len - length,
spans->y, l, coverage);
target += l;
length -= l;
}
++spans;
}
} else {
const qreal fdx = data->m11;
const qreal fdy = data->m12;
const qreal fdw = data->m13;
while (count--) {
void *t = data->rasterBuffer->scanLine(spans->y);
uint *target = ((uint *)t) + spans->x;
uint *image_bits = (uint *)data->texture.imageData;
const qreal cx = spans->x + 0.5;
const qreal cy = spans->y + 0.5;
qreal x = data->m21 * cy + data->m11 * cx + data->dx;
qreal y = data->m22 * cy + data->m12 * cx + data->dy;
qreal w = data->m23 * cy + data->m13 * cx + data->m33;
int length = spans->len;
const int coverage = (spans->coverage * data->texture.const_alpha) >> 8;
while (length) {
int l = qMin(length, buffer_size);
const uint *end = buffer + l;
uint *b = buffer;
while (b < end) {
const qreal iw = w == 0 ? 1 : 1 / w;
const qreal tx = x * iw;
const qreal ty = y * iw;
const int px = int(tx) - (tx < 0);
const int py = int(ty) - (ty < 0);
bool out = (px < 0) || (px >= image_width)
|| (py < 0) || (py >= image_height);
int y_offset = py * scanline_offset;
*b = out ? uint(0) : image_bits[y_offset + px];
x += fdx;
y += fdy;
w += fdw;
++b;
}
if (spanMethod == RegularSpans)
func(target, buffer, l, coverage);
else
drawBufferSpan(data, buffer, buffer_size,
spans->x + spans->len - length,
spans->y, l, coverage);
target += l;
length -= l;
}
++spans;
}
}
}
template <class DST, class SRC>
Q_STATIC_TEMPLATE_FUNCTION void blendTransformed(int count, const QSpan *spans, void *userData)
{
QSpanData *data = reinterpret_cast<QSpanData*>(userData);
QPainter::CompositionMode mode = data->rasterBuffer->compositionMode;
if (mode != QPainter::CompositionMode_SourceOver) {
blend_src_generic<RegularSpans>(count, spans, userData);
return;
}
SRC buffer[buffer_size];
const int image_width = data->texture.width;
const int image_height = data->texture.height;
if (data->fast_matrix) {
// The increment pr x in the scanline
const int fdx = (int)(data->m11 * fixed_scale);
const int fdy = (int)(data->m12 * fixed_scale);
while (count--) {
const quint8 coverage = (data->texture.const_alpha * spans->coverage) >> 8;
if (coverage == 0) {
++spans;
continue;
}
DST *dest = (DST*)data->rasterBuffer->scanLine(spans->y)
+ spans->x;
const qreal cx = spans->x + qreal(0.5);
const qreal cy = spans->y + qreal(0.5);
int x = int((data->m21 * cy
+ data->m11 * cx + data->dx) * fixed_scale);
int y = int((data->m22 * cy
+ data->m12 * cx + data->dy) * fixed_scale);
int length = spans->len;
while (length) {
const int l = qMin(length, buffer_size);
const SRC *end = buffer + l;
SRC *b = buffer;
while (b < end) {
const int px = (x >> 16);
const int py = (y >> 16);
if ((px < 0) || (px >= image_width) ||
(py < 0) || (py >= image_height))
{
*b = 0;
} else {
*b = ((SRC*)data->texture.scanLine(py))[px];
}
++b;
x += fdx;
y += fdy;
}
if (!SRC::hasAlpha() && coverage == 255) {
qt_memconvert(dest, buffer, l);
} else if (sizeof(DST) == 3 && sizeof(SRC) == 3 && l >= 4 &&
(quintptr(dest) & 3) == (quintptr(buffer) & 3))
{
blendUntransformed_dest24(dest, buffer, coverage, l);
} else if (sizeof(DST) == 2 && sizeof(SRC) == 2 && l >= 2 &&
(quintptr(dest) & 3) == (quintptr(buffer) & 3)) {
blendUntransformed_dest16(dest, buffer, coverage, l);
} else {
blendUntransformed_unaligned(dest, buffer, coverage, l);
}
dest += l;
length -= l;
}
++spans;
}
} else {
const qreal fdx = data->m11;
const qreal fdy = data->m12;
const qreal fdw = data->m13;
while (count--) {
const quint8 coverage = (data->texture.const_alpha * spans->coverage) >> 8;
if (coverage == 0) {
++spans;
continue;
}
DST *dest = (DST*)data->rasterBuffer->scanLine(spans->y)
+ spans->x;
const qreal cx = spans->x + qreal(0.5);
const qreal cy = spans->y + qreal(0.5);
qreal x = data->m21 * cy + data->m11 * cx + data->dx;
qreal y = data->m22 * cy + data->m12 * cx + data->dy;
qreal w = data->m23 * cy + data->m13 * cx + data->m33;
int length = spans->len;
while (length) {
const int l = qMin(length, buffer_size);
const SRC *end = buffer + l;
SRC *b = buffer;
while (b < end) {
const qreal iw = w == 0 ? 1 : 1 / w;
const qreal tx = x * iw;
const qreal ty = y * iw;
const int px = int(tx) - (tx < 0);
const int py = int(ty) - (ty < 0);
if ((px < 0) || (px >= image_width) ||
(py < 0) || (py >= image_height))
{
*b = 0;
} else {
*b = ((SRC*)data->texture.scanLine(py))[px];
}
++b;
x += fdx;
y += fdy;
w += fdw;
}
if (!SRC::hasAlpha() && coverage == 255) {
qt_memconvert(dest, buffer, l);
} else if (sizeof(DST) == 3 && sizeof(SRC) == 3 && l >= 4 &&
(quintptr(dest) & 3) == (quintptr(buffer) & 3))
{
blendUntransformed_dest24(dest, buffer, coverage, l);
} else if (sizeof(DST) == 2 && sizeof(SRC) == 2 && l >= 2 &&
(quintptr(dest) & 3) == (quintptr(buffer) & 3)) {
blendUntransformed_dest16(dest, buffer, coverage, l);
} else {
blendUntransformed_unaligned(dest, buffer, coverage, l);
}
dest += l;
length -= l;
}
++spans;
}
}
}
static void blend_transformed_rgb888(int count, const QSpan *spans,
void *userData)
{
#if defined(QT_QWS_DEPTH_24)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_RGB888)
blendTransformed<qrgb888, qrgb888>(count, spans, userData);
else
#endif
blend_src_generic<RegularSpans>(count, spans, userData);
}
static void blend_transformed_argb6666(int count, const QSpan *spans,
void *userData)
{
#if defined(QT_QWS_DEPTH_18)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB6666_Premultiplied)
blendTransformed<qargb6666, qargb6666>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB666)
blendTransformed<qargb6666, qrgb666>(count, spans, userData);
else
#endif
blend_src_generic<RegularSpans>(count, spans, userData);
}
static void blend_transformed_rgb666(int count, const QSpan *spans,
void *userData)
{
#if defined(QT_QWS_DEPTH_18)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB6666_Premultiplied)
blendTransformed<qrgb666, qargb6666>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB666)
blendTransformed<qrgb666, qrgb666>(count, spans, userData);
else
#endif
blend_src_generic<RegularSpans>(count, spans, userData);
}
static void blend_transformed_argb8565(int count, const QSpan *spans,
void *userData)
{
#if defined(QT_QWS_DEPTH_16)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB8565_Premultiplied)
blendTransformed<qargb8565, qargb8565>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB16)
blendTransformed<qargb8565, qrgb565>(count, spans, userData);
else
#endif
blend_src_generic<RegularSpans>(count, spans, userData);
}
static void blend_transformed_rgb565(int count, const QSpan *spans,
void *userData)
{
#if defined(QT_QWS_DEPTH_16)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB8565_Premultiplied)
blendTransformed<qrgb565, qargb8565>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB16)
blendTransformed<qrgb565, qrgb565>(count, spans, userData);
else
#endif
blend_src_generic<RegularSpans>(count, spans, userData);
}
static void blend_transformed_argb8555(int count, const QSpan *spans,
void *userData)
{
#if defined(QT_QWS_DEPTH_15)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB8555_Premultiplied)
blendTransformed<qargb8555, qargb8555>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB555)
blendTransformed<qargb8555, qrgb555>(count, spans, userData);
else
#endif
blend_src_generic<RegularSpans>(count, spans, userData);
}
static void blend_transformed_rgb555(int count, const QSpan *spans,
void *userData)
{
#if defined(QT_QWS_DEPTH_15)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB8555_Premultiplied)
blendTransformed<qrgb555, qargb8555>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB555)
blendTransformed<qrgb555, qrgb555>(count, spans, userData);
else
#endif
blend_src_generic<RegularSpans>(count, spans, userData);
}
static void blend_transformed_argb4444(int count, const QSpan *spans,
void *userData)
{
#if defined(QT_QWS_DEPTH_12)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB4444_Premultiplied)
blendTransformed<qargb4444, qargb4444>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB444)
blendTransformed<qargb4444, qrgb444>(count, spans, userData);
else
#endif
blend_src_generic<RegularSpans>(count, spans, userData);
}
static void blend_transformed_rgb444(int count, const QSpan *spans,
void *userData)
{
#if defined(QT_QWS_DEPTH_12)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB4444_Premultiplied)
blendTransformed<qrgb444, qargb4444>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB444)
blendTransformed<qrgb444, qrgb444>(count, spans, userData);
else
#endif
blend_src_generic<RegularSpans>(count, spans, userData);
}
template <SpanMethod spanMethod>
Q_STATIC_TEMPLATE_FUNCTION void blend_transformed_tiled_argb(int count, const QSpan *spans, void *userData)
{
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format != QImage::Format_ARGB32_Premultiplied
&& data->texture.format != QImage::Format_RGB32) {
blend_src_generic<spanMethod>(count, spans, userData);
return;
}
CompositionFunction func = functionForMode[data->rasterBuffer->compositionMode];
uint buffer[buffer_size];
int image_width = data->texture.width;
int image_height = data->texture.height;
const int scanline_offset = data->texture.bytesPerLine / 4;
if (data->fast_matrix) {
// The increment pr x in the scanline
int fdx = (int)(data->m11 * fixed_scale);
int fdy = (int)(data->m12 * fixed_scale);
while (count--) {
void *t = data->rasterBuffer->scanLine(spans->y);
uint *target = ((uint *)t) + spans->x;
uint *image_bits = (uint *)data->texture.imageData;
const qreal cx = spans->x + 0.5;
const qreal cy = spans->y + 0.5;
int x = int((data->m21 * cy
+ data->m11 * cx + data->dx) * fixed_scale);
int y = int((data->m22 * cy
+ data->m12 * cx + data->dy) * fixed_scale);
const int coverage = (spans->coverage * data->texture.const_alpha) >> 8;
int length = spans->len;
while (length) {
int l = qMin(length, buffer_size);
const uint *end = buffer + l;
uint *b = buffer;
while (b < end) {
int px = x >> 16;
int py = y >> 16;
px %= image_width;
py %= image_height;
if (px < 0) px += image_width;
if (py < 0) py += image_height;
int y_offset = py * scanline_offset;
Q_ASSERT(px >= 0 && px < image_width);
Q_ASSERT(py >= 0 && py < image_height);
*b = image_bits[y_offset + px];
x += fdx;
y += fdy;
++b;
}
if (spanMethod == RegularSpans)
func(target, buffer, l, coverage);
else
drawBufferSpan(data, buffer, buffer_size,
spans->x + spans->len - length,
spans->y, l, coverage);
target += l;
length -= l;
}
++spans;
}
} else {
const qreal fdx = data->m11;
const qreal fdy = data->m12;
const qreal fdw = data->m13;
while (count--) {
void *t = data->rasterBuffer->scanLine(spans->y);
uint *target = ((uint *)t) + spans->x;
uint *image_bits = (uint *)data->texture.imageData;
const qreal cx = spans->x + 0.5;
const qreal cy = spans->y + 0.5;
qreal x = data->m21 * cy + data->m11 * cx + data->dx;
qreal y = data->m22 * cy + data->m12 * cx + data->dy;
qreal w = data->m23 * cy + data->m13 * cx + data->m33;
const int coverage = (spans->coverage * data->texture.const_alpha) >> 8;
int length = spans->len;
while (length) {
int l = qMin(length, buffer_size);
const uint *end = buffer + l;
uint *b = buffer;
while (b < end) {
const qreal iw = w == 0 ? 1 : 1 / w;
const qreal tx = x * iw;
const qreal ty = y * iw;
int px = int(tx) - (tx < 0);
int py = int(ty) - (ty < 0);
px %= image_width;
py %= image_height;
if (px < 0) px += image_width;
if (py < 0) py += image_height;
int y_offset = py * scanline_offset;
Q_ASSERT(px >= 0 && px < image_width);
Q_ASSERT(py >= 0 && py < image_height);
*b = image_bits[y_offset + px];
x += fdx;
y += fdy;
w += fdw;
//force increment to avoid /0
if (!w) {
w += fdw;
}
++b;
}
if (spanMethod == RegularSpans)
func(target, buffer, l, coverage);
else
drawBufferSpan(data, buffer, buffer_size,
spans->x + spans->len - length,
spans->y, l, coverage);
target += l;
length -= l;
}
++spans;
}
}
}
template <class DST, class SRC>
Q_STATIC_TEMPLATE_FUNCTION void blendTransformedTiled(int count, const QSpan *spans, void *userData)
{
QSpanData *data = reinterpret_cast<QSpanData*>(userData);
QPainter::CompositionMode mode = data->rasterBuffer->compositionMode;
if (mode != QPainter::CompositionMode_SourceOver) {
blend_src_generic<RegularSpans>(count, spans, userData);
return;
}
SRC buffer[buffer_size];
const int image_width = data->texture.width;
const int image_height = data->texture.height;
if (data->fast_matrix) {
// The increment pr x in the scanline
const int fdx = (int)(data->m11 * fixed_scale);
const int fdy = (int)(data->m12 * fixed_scale);
while (count--) {
const quint8 coverage = (data->texture.const_alpha * spans->coverage) >> 8;
if (coverage == 0) {
++spans;
continue;
}
DST *dest = (DST*)data->rasterBuffer->scanLine(spans->y)
+ spans->x;
const qreal cx = spans->x + qreal(0.5);
const qreal cy = spans->y + qreal(0.5);
int x = int((data->m21 * cy
+ data->m11 * cx + data->dx) * fixed_scale);
int y = int((data->m22 * cy
+ data->m12 * cx + data->dy) * fixed_scale);
int length = spans->len;
while (length) {
const int l = qMin(length, buffer_size);
const SRC *end = buffer + l;
SRC *b = buffer;
while (b < end) {
int px = (x >> 16) % image_width;
int py = (y >> 16) % image_height;
if (px < 0)
px += image_width;
if (py < 0)
py += image_height;
*b = ((SRC*)data->texture.scanLine(py))[px];
++b;
x += fdx;
y += fdy;
}
if (!SRC::hasAlpha() && coverage == 255) {
qt_memconvert(dest, buffer, l);
} else if (sizeof(DST) == 3 && sizeof(SRC) == 3 && l >= 4 &&
(quintptr(dest) & 3) == (quintptr(buffer) & 3))
{
blendUntransformed_dest24(dest, buffer, coverage, l);
} else if (sizeof(DST) == 2 && sizeof(SRC) == 2 && l >= 2 &&
(quintptr(dest) & 3) == (quintptr(buffer) & 3)) {
blendUntransformed_dest16(dest, buffer, coverage, l);
} else {
blendUntransformed_unaligned(dest, buffer, coverage, l);
}
dest += l;
length -= l;
}
++spans;
}
} else {
const qreal fdx = data->m11;
const qreal fdy = data->m12;
const qreal fdw = data->m13;
while (count--) {
const quint8 coverage = (data->texture.const_alpha * spans->coverage) >> 8;
if (coverage == 0) {
++spans;
continue;
}
DST *dest = (DST*)data->rasterBuffer->scanLine(spans->y)
+ spans->x;
const qreal cx = spans->x + qreal(0.5);
const qreal cy = spans->y + qreal(0.5);
qreal x = data->m21 * cy + data->m11 * cx + data->dx;
qreal y = data->m22 * cy + data->m12 * cx + data->dy;
qreal w = data->m23 * cy + data->m13 * cx + data->m33;
int length = spans->len;
while (length) {
const int l = qMin(length, buffer_size);
const SRC *end = buffer + l;
SRC *b = buffer;
while (b < end) {
const qreal iw = w == 0 ? 1 : 1 / w;
const qreal tx = x * iw;
const qreal ty = y * iw;
int px = int(tx) - (tx < 0);
int py = int(ty) - (ty < 0);
if (px < 0)
px += image_width;
if (py < 0)
py += image_height;
*b = ((SRC*)data->texture.scanLine(py))[px];
++b;
x += fdx;
y += fdy;
w += fdw;
// force increment to avoid /0
if (!w)
w += fdw;
}
if (!SRC::hasAlpha() && coverage == 255) {
qt_memconvert(dest, buffer, l);
} else if (sizeof(DST) == 3 && sizeof(SRC) == 3 && l >= 4 &&
(quintptr(dest) & 3) == (quintptr(buffer) & 3))
{
blendUntransformed_dest24(dest, buffer, coverage, l);
} else if (sizeof(DST) == 2 && sizeof(SRC) == 2 && l >= 2 &&
(quintptr(dest) & 3) == (quintptr(buffer) & 3)) {
blendUntransformed_dest16(dest, buffer, coverage, l);
} else {
blendUntransformed_unaligned(dest, buffer, coverage, l);
}
dest += l;
length -= l;
}
++spans;
}
}
}
static void blend_transformed_tiled_rgb888(int count, const QSpan *spans,
void *userData)
{
#if defined(QT_QWS_DEPTH_24)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_RGB888)
blendTransformedTiled<qrgb888, qrgb888>(count, spans, userData);
else
#endif
blend_src_generic<RegularSpans>(count, spans, userData);
}
static void blend_transformed_tiled_argb6666(int count, const QSpan *spans,
void *userData)
{
#if defined(QT_QWS_DEPTH_18)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB6666_Premultiplied)
blendTransformedTiled<qargb6666, qargb6666>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB666)
blendTransformedTiled<qargb6666, qrgb666>(count, spans, userData);
else
#endif
blend_src_generic<RegularSpans>(count, spans, userData);
}
static void blend_transformed_tiled_rgb666(int count, const QSpan *spans,
void *userData)
{
#if defined(QT_QWS_DEPTH_18)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB6666_Premultiplied)
blendTransformedTiled<qrgb666, qargb6666>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB666)
blendTransformedTiled<qrgb666, qrgb666>(count, spans, userData);
else
#endif
blend_src_generic<RegularSpans>(count, spans, userData);
}
static void blend_transformed_tiled_argb8565(int count, const QSpan *spans,
void *userData)
{
#if defined(QT_QWS_DEPTH_16)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB8565_Premultiplied)
blendTransformedTiled<qargb8565, qargb8565>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB16)
blendTransformedTiled<qargb8565, qrgb565>(count, spans, userData);
else
#endif
blend_src_generic<RegularSpans>(count, spans, userData);
}
static void blend_transformed_tiled_rgb565(int count, const QSpan *spans,
void *userData)
{
#if defined(QT_QWS_DEPTH_16)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB8565_Premultiplied)
blendTransformedTiled<qrgb565, qargb8565>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB16)
blendTransformedTiled<qrgb565, qrgb565>(count, spans, userData);
else
#endif
blend_src_generic<RegularSpans>(count, spans, userData);
}
static void blend_transformed_tiled_argb8555(int count, const QSpan *spans,
void *userData)
{
#if defined(QT_QWS_DEPTH_15)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB8555_Premultiplied)
blendTransformedTiled<qargb8555, qargb8555>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB555)
blendTransformedTiled<qargb8555, qrgb555>(count, spans, userData);
else
#endif
blend_src_generic<RegularSpans>(count, spans, userData);
}
static void blend_transformed_tiled_rgb555(int count, const QSpan *spans,
void *userData)
{
#if defined(QT_QWS_DEPTH_15)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB8555_Premultiplied)
blendTransformedTiled<qrgb555, qargb8555>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB555)
blendTransformedTiled<qrgb555, qrgb555>(count, spans, userData);
else
#endif
blend_src_generic<RegularSpans>(count, spans, userData);
}
static void blend_transformed_tiled_argb4444(int count, const QSpan *spans,
void *userData)
{
#if defined(QT_QWS_DEPTH_12)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB4444_Premultiplied)
blendTransformedTiled<qargb4444, qargb4444>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB444)
blendTransformedTiled<qargb4444, qrgb444>(count, spans, userData);
else
#endif
blend_src_generic<RegularSpans>(count, spans, userData);
}
static void blend_transformed_tiled_rgb444(int count, const QSpan *spans,
void *userData)
{
#if defined(QT_QWS_DEPTH_12)
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
if (data->texture.format == QImage::Format_ARGB4444_Premultiplied)
blendTransformedTiled<qrgb444, qargb4444>(count, spans, userData);
else if (data->texture.format == QImage::Format_RGB444)
blendTransformedTiled<qrgb444, qrgb444>(count, spans, userData);
else
#endif
blend_src_generic<RegularSpans>(count, spans, userData);
}
# define SPANFUNC_POINTER(Name, Arg) Name<Arg>
/* Image formats here are target formats */
static const ProcessSpans processTextureSpans[NBlendTypes][QImage::NImageFormats] = {
// Untransformed
{
0, // Invalid
SPANFUNC_POINTER(blend_untransformed_generic, RegularSpans), // Mono
SPANFUNC_POINTER(blend_untransformed_generic, RegularSpans), // MonoLsb
SPANFUNC_POINTER(blend_untransformed_generic, RegularSpans), // Indexed8
SPANFUNC_POINTER(blend_untransformed_generic, RegularSpans), // RGB32
SPANFUNC_POINTER(blend_untransformed_generic, RegularSpans), // ARGB32
SPANFUNC_POINTER(blend_untransformed_argb, RegularSpans), // ARGB32_Premultiplied
blend_untransformed_rgb565,
blend_untransformed_argb8565,
blend_untransformed_rgb666,
blend_untransformed_argb6666,
blend_untransformed_rgb555,
blend_untransformed_argb8555,
blend_untransformed_rgb888,
blend_untransformed_rgb444,
blend_untransformed_argb4444,
},
// Tiled
{
0, // Invalid
SPANFUNC_POINTER(blend_tiled_generic, RegularSpans), // Mono
SPANFUNC_POINTER(blend_tiled_generic, RegularSpans), // MonoLsb
SPANFUNC_POINTER(blend_tiled_generic, RegularSpans), // Indexed8
SPANFUNC_POINTER(blend_tiled_generic, RegularSpans), // RGB32
SPANFUNC_POINTER(blend_tiled_generic, RegularSpans), // ARGB32
SPANFUNC_POINTER(blend_tiled_argb, RegularSpans), // ARGB32_Premultiplied
blend_tiled_rgb565,
blend_tiled_argb8565,
blend_tiled_rgb666,
blend_tiled_argb6666,
blend_tiled_rgb555,
blend_tiled_argb8555,
blend_tiled_rgb888,
blend_tiled_rgb444,
blend_tiled_argb4444,
},
// Transformed
{
0, // Invalid
SPANFUNC_POINTER(blend_src_generic, RegularSpans), // Mono
SPANFUNC_POINTER(blend_src_generic, RegularSpans), // MonoLsb
SPANFUNC_POINTER(blend_src_generic, RegularSpans), // Indexed8
SPANFUNC_POINTER(blend_src_generic, RegularSpans), // RGB32
SPANFUNC_POINTER(blend_src_generic, RegularSpans), // ARGB32
SPANFUNC_POINTER(blend_transformed_argb, RegularSpans), // ARGB32_Premultiplied
blend_transformed_rgb565,
blend_transformed_argb8565,
blend_transformed_rgb666,
blend_transformed_argb6666,
blend_transformed_rgb555,
blend_transformed_argb8555,
blend_transformed_rgb888,
blend_transformed_rgb444,
blend_transformed_argb4444,
},
// TransformedTiled
{
0,
SPANFUNC_POINTER(blend_src_generic, RegularSpans), // Mono
SPANFUNC_POINTER(blend_src_generic, RegularSpans), // MonoLsb
SPANFUNC_POINTER(blend_src_generic, RegularSpans), // Indexed8
SPANFUNC_POINTER(blend_src_generic, RegularSpans), // RGB32
SPANFUNC_POINTER(blend_src_generic, RegularSpans), // ARGB32
SPANFUNC_POINTER(blend_transformed_tiled_argb, RegularSpans), // ARGB32_Premultiplied
blend_transformed_tiled_rgb565,
blend_transformed_tiled_argb8565,
blend_transformed_tiled_rgb666,
blend_transformed_tiled_argb6666,
blend_transformed_tiled_rgb555,
blend_transformed_tiled_argb8555,
blend_transformed_tiled_rgb888,
blend_transformed_tiled_rgb444,
blend_transformed_tiled_argb4444
},
// Bilinear
{
0,
SPANFUNC_POINTER(blend_src_generic, RegularSpans), // Mono
SPANFUNC_POINTER(blend_src_generic, RegularSpans), // MonoLsb
SPANFUNC_POINTER(blend_src_generic, RegularSpans), // Indexed8
SPANFUNC_POINTER(blend_src_generic, RegularSpans), // RGB32
SPANFUNC_POINTER(blend_src_generic, RegularSpans), // ARGB32
SPANFUNC_POINTER(blend_transformed_bilinear_argb, RegularSpans), // ARGB32_Premultiplied
blend_transformed_bilinear_rgb565,
blend_transformed_bilinear_argb8565,
blend_transformed_bilinear_rgb666,
blend_transformed_bilinear_argb6666,
blend_transformed_bilinear_rgb555,
blend_transformed_bilinear_argb8555,
blend_transformed_bilinear_rgb888,
blend_transformed_bilinear_rgb444,
blend_transformed_bilinear_argb4444,
},
// BilinearTiled
{
0,
SPANFUNC_POINTER(blend_src_generic, RegularSpans), // Mono
SPANFUNC_POINTER(blend_src_generic, RegularSpans), // MonoLsb
SPANFUNC_POINTER(blend_src_generic, RegularSpans), // Indexed8
SPANFUNC_POINTER(blend_src_generic, RegularSpans), // RGB32
SPANFUNC_POINTER(blend_src_generic, RegularSpans), // ARGB32
SPANFUNC_POINTER(blend_transformed_bilinear_tiled_argb, RegularSpans), // ARGB32_Premultiplied
SPANFUNC_POINTER(blend_src_generic, RegularSpans), // RGB16
SPANFUNC_POINTER(blend_src_generic, RegularSpans), // ARGB8565_Premultiplied
SPANFUNC_POINTER(blend_src_generic, RegularSpans), // RGB666
SPANFUNC_POINTER(blend_src_generic, RegularSpans), // ARGB6666_Premultiplied
SPANFUNC_POINTER(blend_src_generic, RegularSpans), // RGB555
SPANFUNC_POINTER(blend_src_generic, RegularSpans), // ARGB8555_Premultiplied
SPANFUNC_POINTER(blend_src_generic, RegularSpans), // RGB888
SPANFUNC_POINTER(blend_src_generic, RegularSpans), // RGB444
SPANFUNC_POINTER(blend_src_generic, RegularSpans), // ARGB4444_Premultiplied
}
};
#if defined (Q_WS_QWS) && !defined(QT_NO_RASTERCALLBACKS)
static const ProcessSpans processTextureSpansCallback[NBlendTypes][QImage::NImageFormats] = {
// Untransformed
{
0, // Invalid
blend_untransformed_generic<CallbackSpans>, // Mono
blend_untransformed_generic<CallbackSpans>, // MonoLsb
blend_untransformed_generic<CallbackSpans>, // Indexed8
blend_untransformed_generic<CallbackSpans>, // RGB32
blend_untransformed_generic<CallbackSpans>, // ARGB32
blend_untransformed_argb<CallbackSpans>, // ARGB32_Premultiplied
blend_untransformed_generic<CallbackSpans>, // RGB16
blend_untransformed_generic<CallbackSpans>, // ARGB8565_Premultiplied
blend_untransformed_generic<CallbackSpans>, // RGB666
blend_untransformed_generic<CallbackSpans>, // ARGB6666_Premultiplied
blend_untransformed_generic<CallbackSpans>, // RGB555
blend_untransformed_generic<CallbackSpans>, // ARGB8555_Premultiplied
blend_untransformed_generic<CallbackSpans>, // RGB888
blend_untransformed_generic<CallbackSpans>, // RGB444
blend_untransformed_generic<CallbackSpans> // ARGB4444_Premultiplied
},
// Tiled
{
0, // Invalid
blend_tiled_generic<CallbackSpans>, // Mono
blend_tiled_generic<CallbackSpans>, // MonoLsb
blend_tiled_generic<CallbackSpans>, // Indexed8
blend_tiled_generic<CallbackSpans>, // RGB32
blend_tiled_generic<CallbackSpans>, // ARGB32
blend_tiled_argb<CallbackSpans>, // ARGB32_Premultiplied
blend_tiled_generic<CallbackSpans>, // RGB16
blend_tiled_generic<CallbackSpans>, // ARGB8565_Premultiplied
blend_tiled_generic<CallbackSpans>, // RGB666
blend_tiled_generic<CallbackSpans>, // ARGB6666_Premultiplied
blend_tiled_generic<CallbackSpans>, // RGB555
blend_tiled_generic<CallbackSpans>, // ARGB8555_Premultiplied
blend_tiled_generic<CallbackSpans>, // RGB888
blend_tiled_generic<CallbackSpans>, // RGB444
blend_tiled_generic<CallbackSpans> // ARGB4444_Premultiplied
},
// Transformed
{
0, // Invalid
blend_src_generic<CallbackSpans>, // Mono
blend_src_generic<CallbackSpans>, // MonoLsb
blend_src_generic<CallbackSpans>, // Indexed8
blend_src_generic<CallbackSpans>, // RGB32
blend_src_generic<CallbackSpans>, // ARGB32
blend_transformed_argb<CallbackSpans>, // ARGB32_Premultiplied
blend_src_generic<CallbackSpans>, // RGB16
blend_src_generic<CallbackSpans>, // ARGB8565_Premultiplied
blend_src_generic<CallbackSpans>, // RGB666
blend_src_generic<CallbackSpans>, // ARGB6666_Premultiplied
blend_src_generic<CallbackSpans>, // RGB555
blend_src_generic<CallbackSpans>, // ARGB8555_Premultiplied
blend_src_generic<CallbackSpans>, // RGB888
blend_src_generic<CallbackSpans>, // RGB444
blend_src_generic<CallbackSpans>, // ARGB4444_Premultiplied
},
// TransformedTiled
{
0,
blend_src_generic<CallbackSpans>, // Mono
blend_src_generic<CallbackSpans>, // MonoLsb
blend_src_generic<CallbackSpans>, // Indexed8
blend_src_generic<CallbackSpans>, // RGB32
blend_src_generic<CallbackSpans>, // ARGB32
blend_transformed_tiled_argb<CallbackSpans>, // ARGB32_Premultiplied
blend_src_generic<CallbackSpans>, // RGB16
blend_src_generic<CallbackSpans>, // ARGB8565_Premultiplied
blend_src_generic<CallbackSpans>, // RGB666
blend_src_generic<CallbackSpans>, // ARGB6666_Premultiplied
blend_src_generic<CallbackSpans>, // RGB555
blend_src_generic<CallbackSpans>, // ARGB8555_Premultiplied
blend_src_generic<CallbackSpans>, // RGB888
blend_src_generic<CallbackSpans>, // RGB444
blend_src_generic<CallbackSpans> // ARGB4444_Premultiplied
},
// Bilinear
{
0,
blend_src_generic<CallbackSpans>, // Mono
blend_src_generic<CallbackSpans>, // MonoLsb
blend_src_generic<CallbackSpans>, // Indexed8
blend_src_generic<CallbackSpans>, // RGB32
blend_src_generic<CallbackSpans>, // ARGB32
blend_transformed_bilinear_argb<CallbackSpans>, // ARGB32_Premultiplied
blend_src_generic<CallbackSpans>, // RGB16
blend_src_generic<CallbackSpans>, // ARGB8565_Premultiplied
blend_src_generic<CallbackSpans>, // RGB666
blend_src_generic<CallbackSpans>, // ARGB6666_Premultiplied
blend_src_generic<CallbackSpans>, // RGB555
blend_src_generic<CallbackSpans>, // ARGB8555_Premultiplied
blend_src_generic<CallbackSpans>, // RGB888
blend_src_generic<CallbackSpans>, // RGB444
blend_src_generic<CallbackSpans> // ARGB4444_Premultiplied
},
// BilinearTiled
{
0,
blend_src_generic<CallbackSpans>, // Mono
blend_src_generic<CallbackSpans>, // MonoLsb
blend_src_generic<CallbackSpans>, // Indexed8
blend_src_generic<CallbackSpans>, // RGB32
blend_src_generic<CallbackSpans>, // ARGB32
blend_transformed_bilinear_tiled_argb<CallbackSpans>, // ARGB32_Premultiplied
blend_src_generic<CallbackSpans>, // RGB16
blend_src_generic<CallbackSpans>, // ARGB8565_Premultiplied
blend_src_generic<CallbackSpans>, // RGB666
blend_src_generic<CallbackSpans>, // ARGB6666_Premultiplied
blend_src_generic<CallbackSpans>, // RGB555
blend_src_generic<CallbackSpans>, // ARGB8555_Premultiplied
blend_src_generic<CallbackSpans>, // RGB888
blend_src_generic<CallbackSpans>, // RGB444
blend_src_generic<CallbackSpans> // ARGB4444_Premultiplied
}
};
#endif // QT_NO_RASTERCALLBACKS
void qBlendTexture(int count, const QSpan *spans, void *userData)
{
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
ProcessSpans proc = processTextureSpans[getBlendType(data)][data->rasterBuffer->format];
proc(count, spans, userData);
}
#if defined (Q_WS_QWS) && !defined(QT_NO_RASTERCALLBACKS)
void qBlendTextureCallback(int count, const QSpan *spans, void *userData)
{
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
ProcessSpans proc = processTextureSpansCallback[getBlendType(data)][data->rasterBuffer->format];
proc(count, spans, userData);
}
#endif // QT_NO_RASTERCALLBACKS
template <class DST>
inline void qt_bitmapblit_template(QRasterBuffer *rasterBuffer,
int x, int y, quint32 color,
const uchar *map,
int mapWidth, int mapHeight, int mapStride,
DST dummy = 0)
{
Q_UNUSED(dummy);
const DST c = qt_colorConvert<DST, quint32>(color, 0);
DST *dest = reinterpret_cast<DST*>(rasterBuffer->scanLine(y)) + x;
const int destStride = rasterBuffer->bytesPerLine() / sizeof(DST);
if (mapWidth > 8) {
while (mapHeight--) {
int x0 = 0;
int n = 0;
for (int x = 0; x < mapWidth; x += 8) {
uchar s = map[x >> 3];
for (int i = 0; i < 8; ++i) {
if (s & 0x80) {
++n;
} else {
if (n) {
qt_memfill(dest + x0, c, n);
x0 += n + 1;
n = 0;
} else {
++x0;
}
if (!s) {
x0 += 8 - 1 - i;
break;
}
}
s <<= 1;
}
}
if (n)
qt_memfill(dest + x0, c, n);
dest += destStride;
map += mapStride;
}
} else {
while (mapHeight--) {
int x0 = 0;
int n = 0;
for (uchar s = *map; s; s <<= 1) {
if (s & 0x80) {
++n;
} else if (n) {
qt_memfill(dest + x0, c, n);
x0 += n + 1;
n = 0;
} else {
++x0;
}
}
if (n)
qt_memfill(dest + x0, c, n);
dest += destStride;
map += mapStride;
}
}
}
static void qt_gradient_quint32(int count, const QSpan *spans, void *userData)
{
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
bool isVerticalGradient =
data->txop <= QTransform::TxScale &&
data->type == QSpanData::LinearGradient &&
data->gradient.linear.end.x == data->gradient.linear.origin.x;
if (isVerticalGradient) {
LinearGradientValues linear;
getLinearGradientValues(&linear, data);
CompositionFunctionSolid funcSolid =
functionForModeSolid[data->rasterBuffer->compositionMode];
/*
The logic for vertical gradient calculations is a mathematically
reduced copy of that in fetchLinearGradient() - which is basically:
qreal ry = data->m22 * (y + 0.5) + data->dy;
qreal t = linear.dy*ry + linear.off;
t *= (GRADIENT_STOPTABLE_SIZE - 1);
quint32 color =
qt_gradient_pixel_fixed(&data->gradient,
int(t * FIXPT_SIZE));
This has then been converted to fixed point to improve performance.
*/
const int gss = GRADIENT_STOPTABLE_SIZE - 1;
int yinc = int((linear.dy * data->m22 * gss) * FIXPT_SIZE);
int off = int((((linear.dy * (data->m22 * 0.5 + data->dy) + linear.off) * gss) * FIXPT_SIZE));
while (count--) {
int y = spans->y;
int x = spans->x;
quint32 *dst = (quint32 *)(data->rasterBuffer->scanLine(y)) + x;
quint32 color =
qt_gradient_pixel_fixed(&data->gradient, yinc * y + off);
funcSolid(dst, spans->len, color, spans->coverage);
++spans;
}
} else {
blend_src_generic<RegularSpans>(count, spans, userData);
}
}
static void qt_gradient_quint16(int count, const QSpan *spans, void *userData)
{
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
bool isVerticalGradient =
data->txop <= QTransform::TxScale &&
data->type == QSpanData::LinearGradient &&
data->gradient.linear.end.x == data->gradient.linear.origin.x;
if (isVerticalGradient) {
LinearGradientValues linear;
getLinearGradientValues(&linear, data);
/*
The logic for vertical gradient calculations is a mathematically
reduced copy of that in fetchLinearGradient() - which is basically:
qreal ry = data->m22 * (y + 0.5) + data->dy;
qreal t = linear.dy*ry + linear.off;
t *= (GRADIENT_STOPTABLE_SIZE - 1);
quint32 color =
qt_gradient_pixel_fixed(&data->gradient,
int(t * FIXPT_SIZE));
This has then been converted to fixed point to improve performance.
*/
const int gss = GRADIENT_STOPTABLE_SIZE - 1;
int yinc = int((linear.dy * data->m22 * gss) * FIXPT_SIZE);
int off = int((((linear.dy * (data->m22 * 0.5 + data->dy) + linear.off) * gss) * FIXPT_SIZE));
uint oldColor = data->solid.color;
while (count--) {
int y = spans->y;
quint32 color = qt_gradient_pixel_fixed(&data->gradient, yinc * y + off);
data->solid.color = color;
blend_color_rgb16(1, spans, userData);
++spans;
}
data->solid.color = oldColor;
} else {
blend_src_generic<RegularSpans>(count, spans, userData);
}
}
inline static void qt_bitmapblit_quint32(QRasterBuffer *rasterBuffer,
int x, int y, quint32 color,
const uchar *map,
int mapWidth, int mapHeight, int mapStride)
{
qt_bitmapblit_template<quint32>(rasterBuffer, x, y, color,
map, mapWidth, mapHeight, mapStride);
}
inline static void qt_bitmapblit_quint16(QRasterBuffer *rasterBuffer,
int x, int y, quint32 color,
const uchar *map,
int mapWidth, int mapHeight, int mapStride)
{
qt_bitmapblit_template<quint16>(rasterBuffer, x, y, color,
map, mapWidth, mapHeight, mapStride);
}
uchar qt_pow_rgb_gamma[256];
uchar qt_pow_rgb_invgamma[256];
uint qt_pow_gamma[256];
uchar qt_pow_invgamma[2048];
static void qt_alphamapblit_quint16(QRasterBuffer *rasterBuffer,
int x, int y, quint32 color,
const uchar *map,
int mapWidth, int mapHeight, int mapStride,
const QClipData *)
{
const quint16 c = qt_colorConvert<quint16, quint32>(color, 0);
quint16 *dest = reinterpret_cast<quint16*>(rasterBuffer->scanLine(y)) + x;
const int destStride = rasterBuffer->bytesPerLine() / sizeof(quint16);
while (mapHeight--) {
for (int i = 0; i < mapWidth; ++i) {
const int coverage = map[i];
if (coverage == 0) {
// nothing
} else if (coverage == 255) {
dest[i] = c;
} else {
int ialpha = 255 - coverage;
dest[i] = BYTE_MUL_RGB16(c, coverage)
+ BYTE_MUL_RGB16(dest[i], ialpha);
}
}
dest += destStride;
map += mapStride;
}
}
void qt_build_pow_tables() {
qreal smoothing = qreal(1.7);
#ifdef Q_WS_MAC
// decided by testing a few things on an iMac, should probably get this from the
// system...
smoothing = 2.0;
#endif
#ifdef Q_WS_WIN
int winSmooth;
if (SystemParametersInfo(0x200C /* SPI_GETFONTSMOOTHINGCONTRAST */, 0, &winSmooth, 0))
smoothing = winSmooth / 1000.0;
#endif
#ifdef Q_WS_X11
Q_UNUSED(smoothing);
for (int i=0; i<256; ++i) {
qt_pow_rgb_gamma[i] = uchar(i);
qt_pow_rgb_invgamma[i] = uchar(i);
}
#else
for (int i=0; i<256; ++i) {
qt_pow_rgb_gamma[i] = uchar(qRound(qPow(i / qreal(255.0), smoothing) * 255));
qt_pow_rgb_invgamma[i] = uchar(qRound(qPow(i / qreal(255.), 1 / smoothing) * 255));
}
#endif
#if defined(Q_OS_WIN) && !defined(Q_OS_WINCE)
const qreal gray_gamma = 2.31;
for (int i=0; i<256; ++i)
qt_pow_gamma[i] = uint(qRound(qPow(i / qreal(255.), gray_gamma) * 2047));
for (int i=0; i<2048; ++i)
qt_pow_invgamma[i] = uchar(qRound(qPow(i / 2047.0, 1 / gray_gamma) * 255));
#endif
}
static inline void rgbBlendPixel(quint32 *dst, int coverage, int sr, int sg, int sb)
{
// Do a gray alphablend...
int da = qAlpha(*dst);
int dr = qRed(*dst);
int dg = qGreen(*dst);
int db = qBlue(*dst);
if (da != 255
#if defined (Q_WS_WIN)
// Work around GDI messing up alpha channel
&& qRed(*dst) <= da && qBlue(*dst) <= da && qGreen(*dst) <= da
#endif
) {
int a = qGray(coverage);
sr = qt_div_255(sr * a);
sg = qt_div_255(sg * a);
sb = qt_div_255(sb * a);
int ia = 255 - a;
dr = qt_div_255(dr * ia);
dg = qt_div_255(dg * ia);
db = qt_div_255(db * ia);
*dst = ((a + qt_div_255((255 - a) * da)) << 24)
| ((sr + dr) << 16)
| ((sg + dg) << 8)
| ((sb + db));
return;
}
int mr = qRed(coverage);
int mg = qGreen(coverage);
int mb = qBlue(coverage);
dr = qt_pow_rgb_gamma[dr];
dg = qt_pow_rgb_gamma[dg];
db = qt_pow_rgb_gamma[db];
int nr = qt_div_255((sr - dr) * mr) + dr;
int ng = qt_div_255((sg - dg) * mg) + dg;
int nb = qt_div_255((sb - db) * mb) + db;
nr = qt_pow_rgb_invgamma[nr];
ng = qt_pow_rgb_invgamma[ng];
nb = qt_pow_rgb_invgamma[nb];
*dst = qRgb(nr, ng, nb);
}
#if defined(Q_OS_WIN) && !defined(Q_OS_WINCE)
static inline void grayBlendPixel(quint32 *dst, int coverage, int sr, int sg, int sb)
{
// Do a gammacorrected gray alphablend...
int dr = qRed(*dst);
int dg = qGreen(*dst);
int db = qBlue(*dst);
dr = qt_pow_gamma[dr];
dg = qt_pow_gamma[dg];
db = qt_pow_gamma[db];
int alpha = coverage;
int ialpha = 255 - alpha;
int nr = (sr * alpha + ialpha * dr) / 255;
int ng = (sg * alpha + ialpha * dg) / 255;
int nb = (sb * alpha + ialpha * db) / 255;
nr = qt_pow_invgamma[nr];
ng = qt_pow_invgamma[ng];
nb = qt_pow_invgamma[nb];
*dst = qRgb(nr, ng, nb);
}
#endif
static void qt_alphamapblit_quint32(QRasterBuffer *rasterBuffer,
int x, int y, quint32 color,
const uchar *map,
int mapWidth, int mapHeight, int mapStride,
const QClipData *clip)
{
const quint32 c = color;
const int destStride = rasterBuffer->bytesPerLine() / sizeof(quint32);
#if defined(Q_OS_WIN) && !defined(Q_OS_WINCE)
int sr = qRed(color);
int sg = qGreen(color);
int sb = qBlue(color);
sr = qt_pow_gamma[sr];
sg = qt_pow_gamma[sg];
sb = qt_pow_gamma[sb];
bool opaque_src = (qAlpha(color) == 255);
#endif
if (!clip) {
quint32 *dest = reinterpret_cast<quint32*>(rasterBuffer->scanLine(y)) + x;
while (mapHeight--) {
for (int i = 0; i < mapWidth; ++i) {
const int coverage = map[i];
if (coverage == 0) {
// nothing
} else if (coverage == 255) {
dest[i] = c;
} else {
#if defined(Q_OS_WIN) && !defined(Q_OS_WINCE)
if (QSysInfo::WindowsVersion >= QSysInfo::WV_XP && opaque_src
&& qAlpha(dest[i]) == 255) {
grayBlendPixel(dest+i, coverage, sr, sg, sb);
} else
#endif
{
int ialpha = 255 - coverage;
dest[i] = INTERPOLATE_PIXEL_255(c, coverage, dest[i], ialpha);
}
}
}
dest += destStride;
map += mapStride;
}
} else {
int bottom = qMin(y + mapHeight, rasterBuffer->height());
int top = qMax(y, 0);
map += (top - y) * mapStride;
const_cast<QClipData *>(clip)->initialize();
for (int yp = top; yp<bottom; ++yp) {
const QClipData::ClipLine &line = clip->m_clipLines[yp];
quint32 *dest = reinterpret_cast<quint32 *>(rasterBuffer->scanLine(yp));
for (int i=0; i<line.count; ++i) {
const QSpan &clip = line.spans[i];
int start = qMax<int>(x, clip.x);
int end = qMin<int>(x + mapWidth, clip.x + clip.len);
for (int xp=start; xp<end; ++xp) {
const int coverage = map[xp - x];
if (coverage == 0) {
// nothing
} else if (coverage == 255) {
dest[xp] = c;
} else {
#if defined(Q_OS_WIN) && !defined(Q_OS_WINCE)
if (QSysInfo::WindowsVersion >= QSysInfo::WV_XP && opaque_src
&& qAlpha(dest[xp]) == 255) {
grayBlendPixel(dest+xp, coverage, sr, sg, sb);
} else
#endif
{
int ialpha = 255 - coverage;
dest[xp] = INTERPOLATE_PIXEL_255(c, coverage, dest[xp], ialpha);
}
}
} // for (i -> line.count)
} // for (yp -> bottom)
map += mapStride;
}
}
}
static void qt_alphargbblit_quint32(QRasterBuffer *rasterBuffer,
int x, int y, quint32 color,
const uint *src, int mapWidth, int mapHeight, int srcStride,
const QClipData *clip)
{
const quint32 c = color;
int sr = qRed(color);
int sg = qGreen(color);
int sb = qBlue(color);
int sa = qAlpha(color);
sr = qt_pow_rgb_gamma[sr];
sg = qt_pow_rgb_gamma[sg];
sb = qt_pow_rgb_gamma[sb];
if (sa == 0)
return;
if (!clip) {
quint32 *dst = reinterpret_cast<quint32*>(rasterBuffer->scanLine(y)) + x;
const int destStride = rasterBuffer->bytesPerLine() / sizeof(quint32);
while (mapHeight--) {
for (int i = 0; i < mapWidth; ++i) {
const uint coverage = src[i];
if (coverage == 0xffffffff) {
dst[i] = c;
} else if (coverage != 0xff000000) {
rgbBlendPixel(dst+i, coverage, sr, sg, sb);
}
}
dst += destStride;
src += srcStride;
}
} else {
int bottom = qMin(y + mapHeight, rasterBuffer->height());
int top = qMax(y, 0);
src += (top - y) * srcStride;
const_cast<QClipData *>(clip)->initialize();
for (int yp = top; yp<bottom; ++yp) {
const QClipData::ClipLine &line = clip->m_clipLines[yp];
quint32 *dst = reinterpret_cast<quint32 *>(rasterBuffer->scanLine(yp));
for (int i=0; i<line.count; ++i) {
const QSpan &clip = line.spans[i];
int start = qMax<int>(x, clip.x);
int end = qMin<int>(x + mapWidth, clip.x + clip.len);
for (int xp=start; xp<end; ++xp) {
const uint coverage = src[xp - x];
if (coverage == 0xffffffff) {
dst[xp] = c;
} else if (coverage != 0xff000000) {
rgbBlendPixel(dst+xp, coverage, sr, sg, sb);
}
}
} // for (i -> line.count)
src += srcStride;
} // for (yp -> bottom)
}
}
template <class T>
inline void qt_rectfill_template(QRasterBuffer *rasterBuffer,
int x, int y, int width, int height,
quint32 color, T dummy = 0)
{
Q_UNUSED(dummy);
qt_rectfill<T>(reinterpret_cast<T*>(rasterBuffer->buffer()),
qt_colorConvert<T, quint32p>(quint32p::fromRawData(color), 0),
x, y, width, height, rasterBuffer->bytesPerLine());
}
#define QT_RECTFILL(T) \
inline static void qt_rectfill_##T(QRasterBuffer *rasterBuffer, \
int x, int y, int width, int height, \
quint32 color) \
{ \
qt_rectfill_template<T>(rasterBuffer, x, y, width, height, color); \
}
QT_RECTFILL(quint32)
QT_RECTFILL(quint16)
QT_RECTFILL(qargb8565)
QT_RECTFILL(qrgb666)
QT_RECTFILL(qargb6666)
QT_RECTFILL(qrgb555)
QT_RECTFILL(qargb8555)
QT_RECTFILL(qrgb888)
QT_RECTFILL(qrgb444)
QT_RECTFILL(qargb4444)
#undef QT_RECTFILL
inline static void qt_rectfill_nonpremul_quint32(QRasterBuffer *rasterBuffer,
int x, int y, int width, int height,
quint32 color)
{
qt_rectfill<quint32>(reinterpret_cast<quint32 *>(rasterBuffer->buffer()),
INV_PREMUL(color), x, y, width, height, rasterBuffer->bytesPerLine());
}
// Map table for destination image format. Contains function pointers
// for blends of various types unto the destination
DrawHelper qDrawHelper[QImage::NImageFormats] =
{
// Format_Invalid,
{ 0, 0, 0, 0, 0, 0 },
// Format_Mono,
{
blend_color_generic,
SPANFUNC_POINTER(blend_src_generic, RegularSpans),
0, 0, 0, 0
},
// Format_MonoLSB,
{
blend_color_generic,
SPANFUNC_POINTER(blend_src_generic, RegularSpans),
0, 0, 0, 0
},
// Format_Indexed8,
{
blend_color_generic,
SPANFUNC_POINTER(blend_src_generic, RegularSpans),
0, 0, 0, 0
},
// Format_RGB32,
{
blend_color_argb,
qt_gradient_quint32,
qt_bitmapblit_quint32,
qt_alphamapblit_quint32,
qt_alphargbblit_quint32,
qt_rectfill_quint32
},
// Format_ARGB32,
{
blend_color_generic,
qt_gradient_quint32,
qt_bitmapblit_quint32,
qt_alphamapblit_quint32,
qt_alphargbblit_quint32,
qt_rectfill_nonpremul_quint32
},
// Format_ARGB32_Premultiplied
{
blend_color_argb,
qt_gradient_quint32,
qt_bitmapblit_quint32,
qt_alphamapblit_quint32,
qt_alphargbblit_quint32,
qt_rectfill_quint32
},
// Format_RGB16
{
blend_color_rgb16,
qt_gradient_quint16,
qt_bitmapblit_quint16,
qt_alphamapblit_quint16,
0,
qt_rectfill_quint16
},
// Format_ARGB8565_Premultiplied
{
SPANFUNC_POINTER_BLENDCOLOR(qargb8565),
SPANFUNC_POINTER(blend_src_generic, RegularSpans),
0, 0, 0,
qt_rectfill_qargb8565
},
// Format_RGB666
{
SPANFUNC_POINTER_BLENDCOLOR(qrgb666),
SPANFUNC_POINTER(blend_src_generic, RegularSpans),
0, 0, 0,
qt_rectfill_qrgb666
},
// Format_ARGB6666_Premultiplied
{
SPANFUNC_POINTER_BLENDCOLOR(qargb6666),
SPANFUNC_POINTER(blend_src_generic, RegularSpans),
0, 0, 0,
qt_rectfill_qargb6666
},
// Format_RGB555
{
SPANFUNC_POINTER_BLENDCOLOR(qrgb555),
SPANFUNC_POINTER(blend_src_generic, RegularSpans),
0, 0, 0,
qt_rectfill_qrgb555
},
// Format_ARGB8555_Premultiplied
{
SPANFUNC_POINTER_BLENDCOLOR(qargb8555),
SPANFUNC_POINTER(blend_src_generic, RegularSpans),
0, 0, 0,
qt_rectfill_qargb8555
},
// Format_RGB888
{
SPANFUNC_POINTER_BLENDCOLOR(qrgb888),
SPANFUNC_POINTER(blend_src_generic, RegularSpans),
0, 0, 0,
qt_rectfill_qrgb888
},
// Format_RGB444
{
SPANFUNC_POINTER_BLENDCOLOR(qrgb444),
SPANFUNC_POINTER(blend_src_generic, RegularSpans),
0, 0, 0,
qt_rectfill_qrgb444
},
// Format_ARGB4444_Premultiplied
{
SPANFUNC_POINTER_BLENDCOLOR(qargb4444),
SPANFUNC_POINTER(blend_src_generic, RegularSpans),
0, 0, 0,
qt_rectfill_qargb4444
}
};
#if defined (Q_WS_QWS) && !defined(QT_NO_RASTERCALLBACKS)
DrawHelper qDrawHelperCallback[QImage::NImageFormats] =
{
// Format_Invalid,
{ 0, 0, 0, 0, 0, 0 },
// Format_Mono,
{
blend_color_generic_callback,
blend_src_generic<CallbackSpans>,
0, 0, 0, 0
},
// Format_MonoLSB,
{
blend_color_generic_callback,
blend_src_generic<CallbackSpans>,
0, 0, 0, 0
},
// Format_Indexed8,
{
blend_color_generic_callback,
blend_src_generic<CallbackSpans>,
0, 0, 0, 0
},
// Format_RGB32,
{
blend_color_generic_callback,
blend_src_generic<CallbackSpans>,
0, 0, 0, 0
},
// Format_ARGB32,
{
blend_color_generic_callback,
blend_src_generic<CallbackSpans>,
0, 0, 0, 0
},
// Format_ARGB32_Premultiplied
{
blend_color_generic_callback,
blend_src_generic<CallbackSpans>,
0, 0, 0, 0
},
// Format_RGB16
{
blend_color_generic_callback,
blend_src_generic<CallbackSpans>,
0, 0, 0, 0
},
// Format_ARGB8565_Premultiplied
{
blend_color_generic_callback,
blend_src_generic<CallbackSpans>,
0, 0, 0, 0
},
// Format_RGB666
{
blend_color_generic_callback,
blend_src_generic<CallbackSpans>,
0, 0, 0, 0
},
// Format_ARGB6666_Premultiplied
{
blend_color_generic_callback,
blend_src_generic<CallbackSpans>,
0, 0, 0, 0
},
// Format_RGB555
{
blend_color_generic_callback,
blend_src_generic<CallbackSpans>,
0, 0, 0, 0
},
// Format_ARGB8555_Premultiplied
{
blend_color_generic_callback,
blend_src_generic<CallbackSpans>,
0, 0, 0, 0
},
// Format_RGB888
{
blend_color_generic_callback,
blend_src_generic<CallbackSpans>,
0, 0, 0, 0
},
// Format_RGB444
{
blend_color_generic_callback,
blend_src_generic<CallbackSpans>,
0, 0, 0, 0
},
// Format_ARGB4444_Premultiplied
{
blend_color_generic_callback,
blend_src_generic<CallbackSpans>,
0, 0, 0, 0
}
};
#endif
#if defined(Q_CC_MSVC) && !defined(_MIPS_)
template <class DST, class SRC>
inline void qt_memfill_template(DST *dest, SRC color, int count)
{
const DST c = qt_colorConvert<DST, SRC>(color, 0);
while (count--)
*dest++ = c;
}
#else
template <class DST, class SRC>
inline void qt_memfill_template(DST *dest, SRC color, int count)
{
const DST c = qt_colorConvert<DST, SRC>(color, 0);
int n = (count + 7) / 8;
switch (count & 0x07)
{
case 0: do { *dest++ = c;
case 7: *dest++ = c;
case 6: *dest++ = c;
case 5: *dest++ = c;
case 4: *dest++ = c;
case 3: *dest++ = c;
case 2: *dest++ = c;
case 1: *dest++ = c;
} while (--n > 0);
}
}
template <>
inline void qt_memfill_template(quint16 *dest, quint16 value, int count)
{
if (count < 3) {
switch (count) {
case 2: *dest++ = value;
case 1: *dest = value;
}
return;
}
const int align = (quintptr)(dest) & 0x3;
switch (align) {
case 2: *dest++ = value; --count;
}
const quint32 value32 = (value << 16) | value;
qt_memfill(reinterpret_cast<quint32*>(dest), value32, count / 2);
if (count & 0x1)
dest[count - 1] = value;
}
#endif
static void qt_memfill_quint16(quint16 *dest, quint16 color, int count)
{
qt_memfill_template<quint16, quint16>(dest, color, count);
}
typedef void (*qt_memfill32_func)(quint32 *dest, quint32 value, int count);
typedef void (*qt_memfill16_func)(quint16 *dest, quint16 value, int count);
static void qt_memfill32_setup(quint32 *dest, quint32 value, int count);
static void qt_memfill16_setup(quint16 *dest, quint16 value, int count);
qt_memfill32_func qt_memfill32 = qt_memfill32_setup;
qt_memfill16_func qt_memfill16 = qt_memfill16_setup;
enum CPUFeatures {
None = 0,
MMX = 0x1,
MMXEXT = 0x2,
MMX3DNOW = 0x4,
MMX3DNOWEXT = 0x8,
SSE = 0x10,
SSE2 = 0x20,
CMOV = 0x40,
IWMMXT = 0x80,
NEON = 0x100
};
static uint detectCPUFeatures()
{
#if defined (Q_OS_WINCE)
#if defined (ARM)
if (IsProcessorFeaturePresent(PF_ARM_INTEL_WMMX))
return IWMMXT;
#elif defined(_X86_)
uint features = 0;
#if defined QT_HAVE_MMX
if (IsProcessorFeaturePresent(PF_MMX_INSTRUCTIONS_AVAILABLE))
features |= MMX;
#endif
#if defined QT_HAVE_3DNOW
if (IsProcessorFeaturePresent(PF_3DNOW_INSTRUCTIONS_AVAILABLE))
features |= MMX3DNOW;
#endif
return features;
#endif
return 0;
#elif defined(QT_HAVE_IWMMXT)
// runtime detection only available when running as a previlegied process
static const bool doIWMMXT = !qgetenv("QT_NO_IWMMXT").toInt();
return doIWMMXT ? IWMMXT : 0;
#elif defined(QT_HAVE_NEON)
static const bool doNEON = !qgetenv("QT_NO_NEON").toInt();
return doNEON ? NEON : 0;
#else
uint features = 0;
#if defined(__x86_64__) || defined(Q_OS_WIN64)
features = MMX|SSE|SSE2|CMOV;
#elif defined(__ia64__)
features = MMX|SSE|SSE2;
#elif defined(__i386__) || defined(_M_IX86)
unsigned int extended_result = 0;
uint result = 0;
/* see p. 118 of amd64 instruction set manual Vol3 */
#if defined(Q_CC_GNU)
asm ("push %%ebx\n"
"pushf\n"
"pop %%eax\n"
"mov %%eax, %%ebx\n"
"xor $0x00200000, %%eax\n"
"push %%eax\n"
"popf\n"
"pushf\n"
"pop %%eax\n"
"xor %%edx, %%edx\n"
"xor %%ebx, %%eax\n"
"jz 1f\n"
"mov $0x00000001, %%eax\n"
"cpuid\n"
"1:\n"
"pop %%ebx\n"
"mov %%edx, %0\n"
: "=r" (result)
:
: "%eax", "%ecx", "%edx"
);
asm ("push %%ebx\n"
"pushf\n"
"pop %%eax\n"
"mov %%eax, %%ebx\n"
"xor $0x00200000, %%eax\n"
"push %%eax\n"
"popf\n"
"pushf\n"
"pop %%eax\n"
"xor %%edx, %%edx\n"
"xor %%ebx, %%eax\n"
"jz 2f\n"
"mov $0x80000000, %%eax\n"
"cpuid\n"
"cmp $0x80000000, %%eax\n"
"jbe 2f\n"
"mov $0x80000001, %%eax\n"
"cpuid\n"
"2:\n"
"pop %%ebx\n"
"mov %%edx, %0\n"
: "=r" (extended_result)
:
: "%eax", "%ecx", "%edx"
);
#elif defined (Q_OS_WIN)
_asm {
push eax
push ebx
push ecx
push edx
pushfd
pop eax
mov ebx, eax
xor eax, 00200000h
push eax
popfd
pushfd
pop eax
mov edx, 0
xor eax, ebx
jz skip
mov eax, 1
cpuid
mov result, edx
skip:
pop edx
pop ecx
pop ebx
pop eax
}
_asm {
push eax
push ebx
push ecx
push edx
pushfd
pop eax
mov ebx, eax
xor eax, 00200000h
push eax
popfd
pushfd
pop eax
mov edx, 0
xor eax, ebx
jz skip2
mov eax, 80000000h
cpuid
cmp eax, 80000000h
jbe skip2
mov eax, 80000001h
cpuid
mov extended_result, edx
skip2:
pop edx
pop ecx
pop ebx
pop eax
}
#endif
// result now contains the standard feature bits
if (result & (1u << 15))
features |= CMOV;
if (result & (1u << 23))
features |= MMX;
if (extended_result & (1u << 22))
features |= MMXEXT;
if (extended_result & (1u << 31))
features |= MMX3DNOW;
if (extended_result & (1u << 30))
features |= MMX3DNOWEXT;
if (result & (1u << 25))
features |= SSE;
if (result & (1u << 26))
features |= SSE2;
#endif // i386
if (qgetenv("QT_NO_MMX").toInt())
features ^= MMX;
if (qgetenv("QT_NO_MMXEXT").toInt())
features ^= MMXEXT;
if (qgetenv("QT_NO_3DNOW").toInt())
features ^= MMX3DNOW;
if (qgetenv("QT_NO_3DNOWEXT").toInt())
features ^= MMX3DNOWEXT;
if (qgetenv("QT_NO_SSE").toInt())
features ^= SSE;
if (qgetenv("QT_NO_SSE2").toInt())
features ^= SSE2;
return features;
#endif
}
#if defined(Q_CC_RVCT) && defined(QT_HAVE_ARMV6)
// Move these to qdrawhelper_arm.c when all
// functions are implemented using arm assembly.
static CompositionFunctionSolid qt_functionForModeSolid_ARMv6[numCompositionFunctions] = {
comp_func_solid_SourceOver,
comp_func_solid_DestinationOver,
comp_func_solid_Clear,
comp_func_solid_Source,
comp_func_solid_Destination,
comp_func_solid_SourceIn,
comp_func_solid_DestinationIn,
comp_func_solid_SourceOut,
comp_func_solid_DestinationOut,
comp_func_solid_SourceAtop,
comp_func_solid_DestinationAtop,
comp_func_solid_XOR,
comp_func_solid_Plus,
comp_func_solid_Multiply,
comp_func_solid_Screen,
comp_func_solid_Overlay,
comp_func_solid_Darken,
comp_func_solid_Lighten,
comp_func_solid_ColorDodge,
comp_func_solid_ColorBurn,
comp_func_solid_HardLight,
comp_func_solid_SoftLight,
comp_func_solid_Difference,
comp_func_solid_Exclusion,
rasterop_solid_SourceOrDestination,
rasterop_solid_SourceAndDestination,
rasterop_solid_SourceXorDestination,
rasterop_solid_NotSourceAndNotDestination,
rasterop_solid_NotSourceOrNotDestination,
rasterop_solid_NotSourceXorDestination,
rasterop_solid_NotSource,
rasterop_solid_NotSourceAndDestination,
rasterop_solid_SourceAndNotDestination
};
static CompositionFunction qt_functionForMode_ARMv6[numCompositionFunctions] = {
comp_func_SourceOver_armv6,
comp_func_DestinationOver,
comp_func_Clear,
comp_func_Source_armv6,
comp_func_Destination,
comp_func_SourceIn,
comp_func_DestinationIn,
comp_func_SourceOut,
comp_func_DestinationOut,
comp_func_SourceAtop,
comp_func_DestinationAtop,
comp_func_XOR,
comp_func_Plus,
comp_func_Multiply,
comp_func_Screen,
comp_func_Overlay,
comp_func_Darken,
comp_func_Lighten,
comp_func_ColorDodge,
comp_func_ColorBurn,
comp_func_HardLight,
comp_func_SoftLight,
comp_func_Difference,
comp_func_Exclusion,
rasterop_SourceOrDestination,
rasterop_SourceAndDestination,
rasterop_SourceXorDestination,
rasterop_NotSourceAndNotDestination,
rasterop_NotSourceOrNotDestination,
rasterop_NotSourceXorDestination,
rasterop_NotSource,
rasterop_NotSourceAndDestination,
rasterop_SourceAndNotDestination
};
static void qt_blend_color_argb_armv6(int count, const QSpan *spans, void *userData)
{
QSpanData *data = reinterpret_cast<QSpanData *>(userData);
CompositionFunctionSolid func = qt_functionForModeSolid_ARMv6[data->rasterBuffer->compositionMode];
while (count--) {
uint *target = ((uint *)data->rasterBuffer->scanLine(spans->y)) + spans->x;
func(target, spans->len, data->solid.color, spans->coverage);
++spans;
}
}
#endif // Q_CC_RVCT && QT_HAVE_ARMV6
void qInitDrawhelperAsm()
{
static uint features = 0xffffffff;
if (features != 0xffffffff)
return;
features = detectCPUFeatures();
qt_memfill32 = qt_memfill_template<quint32, quint32>;
qt_memfill16 = qt_memfill_quint16; //qt_memfill_template<quint16, quint16>;
CompositionFunction *functionForModeAsm = 0;
CompositionFunctionSolid *functionForModeSolidAsm = 0;
#ifdef QT_NO_DEBUG
if (false) {
#ifdef QT_HAVE_SSE2
} else if (features & SSE2) {
qt_memfill32 = qt_memfill32_sse2;
qt_memfill16 = qt_memfill16_sse2;
qDrawHelper[QImage::Format_RGB32].bitmapBlit = qt_bitmapblit32_sse2;
qDrawHelper[QImage::Format_ARGB32].bitmapBlit = qt_bitmapblit32_sse2;
qDrawHelper[QImage::Format_ARGB32_Premultiplied].bitmapBlit = qt_bitmapblit32_sse2;
qDrawHelper[QImage::Format_RGB16].bitmapBlit = qt_bitmapblit16_sse2;
#endif
#ifdef QT_HAVE_SSE
} else if (features & SSE) {
// qt_memfill32 = qt_memfill32_sse;
qDrawHelper[QImage::Format_RGB16].bitmapBlit = qt_bitmapblit16_sse;
#ifdef QT_HAVE_3DNOW
if (features & MMX3DNOW) {
qt_memfill32 = qt_memfill32_sse3dnow;
qDrawHelper[QImage::Format_RGB16].bitmapBlit = qt_bitmapblit16_sse3dnow;
}
#endif
#endif // SSE
#if defined(QT_HAVE_MMXEXT) && defined(QT_HAVE_SSE)
} else if (features & MMXEXT) {
qt_memfill32 = qt_memfill32_sse;
qDrawHelper[QImage::Format_RGB16].bitmapBlit = qt_bitmapblit16_sse;
# ifdef QT_HAVE_3DNOW
if (features & MMX3DNOW) {
qt_memfill32 = qt_memfill32_sse3dnow;
qDrawHelper[QImage::Format_RGB16].bitmapBlit = qt_bitmapblit16_sse3dnow;
}
# endif // 3DNOW
#endif // MMXEXT
}
#ifdef QT_HAVE_MMX
if (features & MMX) {
functionForModeAsm = qt_functionForMode_MMX;
functionForModeSolidAsm = qt_functionForModeSolid_MMX;
qDrawHelper[QImage::Format_ARGB32_Premultiplied].blendColor = qt_blend_color_argb_mmx;
#ifdef QT_HAVE_3DNOW
if (features & MMX3DNOW) {
functionForModeAsm = qt_functionForMode_MMX3DNOW;
functionForModeSolidAsm = qt_functionForModeSolid_MMX3DNOW;
qDrawHelper[QImage::Format_ARGB32_Premultiplied].blendColor = qt_blend_color_argb_mmx3dnow;
}
#endif // 3DNOW
extern void qt_blend_rgb32_on_rgb32_mmx(uchar *destPixels, int dbpl,
const uchar *srcPixels, int sbpl,
int w, int h,
int const_alpha);
extern void qt_blend_argb32_on_argb32_mmx(uchar *destPixels, int dbpl,
const uchar *srcPixels, int sbpl,
int w, int h,
int const_alpha);
qBlendFunctions[QImage::Format_RGB32][QImage::Format_RGB32] = qt_blend_rgb32_on_rgb32_mmx;
qBlendFunctions[QImage::Format_ARGB32_Premultiplied][QImage::Format_RGB32] = qt_blend_rgb32_on_rgb32_mmx;
qBlendFunctions[QImage::Format_RGB32][QImage::Format_ARGB32_Premultiplied] = qt_blend_argb32_on_argb32_mmx;
qBlendFunctions[QImage::Format_ARGB32_Premultiplied][QImage::Format_ARGB32_Premultiplied] = qt_blend_argb32_on_argb32_mmx;
}
#endif // MMX
#ifdef QT_HAVE_SSE
if (features & SSE) {
functionForModeAsm = qt_functionForMode_SSE;
functionForModeSolidAsm = qt_functionForModeSolid_SSE;
qDrawHelper[QImage::Format_ARGB32_Premultiplied].blendColor = qt_blend_color_argb_sse;
#ifdef QT_HAVE_3DNOW
if (features & MMX3DNOW) {
functionForModeAsm = qt_functionForMode_SSE3DNOW;
functionForModeSolidAsm = qt_functionForModeSolid_SSE3DNOW;
qDrawHelper[QImage::Format_ARGB32_Premultiplied].blendColor = qt_blend_color_argb_sse3dnow;
}
#endif // 3DNOW
extern void qt_blend_rgb32_on_rgb32_sse(uchar *destPixels, int dbpl,
const uchar *srcPixels, int sbpl,
int w, int h,
int const_alpha);
extern void qt_blend_argb32_on_argb32_sse(uchar *destPixels, int dbpl,
const uchar *srcPixels, int sbpl,
int w, int h,
int const_alpha);
qBlendFunctions[QImage::Format_RGB32][QImage::Format_RGB32] = qt_blend_rgb32_on_rgb32_sse;
qBlendFunctions[QImage::Format_ARGB32_Premultiplied][QImage::Format_RGB32] = qt_blend_rgb32_on_rgb32_sse;
qBlendFunctions[QImage::Format_RGB32][QImage::Format_ARGB32_Premultiplied] = qt_blend_argb32_on_argb32_sse;
qBlendFunctions[QImage::Format_ARGB32_Premultiplied][QImage::Format_ARGB32_Premultiplied] = qt_blend_argb32_on_argb32_sse;
}
#endif // SSE
#ifdef QT_HAVE_IWMMXT
if (features & IWMMXT) {
functionForModeAsm = qt_functionForMode_IWMMXT;
functionForModeSolidAsm = qt_functionForModeSolid_IWMMXT;
qDrawHelper[QImage::Format_ARGB32_Premultiplied].blendColor = qt_blend_color_argb_iwmmxt;
}
#endif // IWMMXT
#endif // QT_NO_DEBUG
#if defined(Q_CC_RVCT) && defined(QT_HAVE_ARMV6)
functionForModeAsm = qt_functionForMode_ARMv6;
functionForModeSolidAsm = qt_functionForModeSolid_ARMv6;
qt_memfill32 = qt_memfill32_armv6;
qDrawHelper[QImage::Format_ARGB32_Premultiplied].blendColor = qt_blend_color_argb_armv6;
qBlendFunctions[QImage::Format_RGB32][QImage::Format_RGB32] = qt_blend_rgb32_on_rgb32_armv6;
qBlendFunctions[QImage::Format_ARGB32_Premultiplied][QImage::Format_RGB32] = qt_blend_rgb32_on_rgb32_armv6;
qBlendFunctions[QImage::Format_RGB32][QImage::Format_ARGB32_Premultiplied] = qt_blend_argb32_on_argb32_armv6;
qBlendFunctions[QImage::Format_ARGB32_Premultiplied][QImage::Format_ARGB32_Premultiplied] = qt_blend_argb32_on_argb32_armv6;
#elif defined(QT_HAVE_NEON)
if (features & NEON) {
qBlendFunctions[QImage::Format_RGB32][QImage::Format_RGB32] = qt_blend_rgb32_on_rgb32_neon;
qBlendFunctions[QImage::Format_ARGB32_Premultiplied][QImage::Format_RGB32] = qt_blend_rgb32_on_rgb32_neon;
qBlendFunctions[QImage::Format_RGB32][QImage::Format_ARGB32_Premultiplied] = qt_blend_argb32_on_argb32_neon;
qBlendFunctions[QImage::Format_ARGB32_Premultiplied][QImage::Format_ARGB32_Premultiplied] = qt_blend_argb32_on_argb32_neon;
}
#endif
if (functionForModeSolidAsm) {
const int destinationMode = QPainter::CompositionMode_Destination;
functionForModeSolidAsm[destinationMode] = functionForModeSolid_C[destinationMode];
// use the default qdrawhelper implementation for the
// extended composition modes
for (int mode = 12; mode < 24; ++mode)
functionForModeSolidAsm[mode] = functionForModeSolid_C[mode];
functionForModeSolid = functionForModeSolidAsm;
}
if (functionForModeAsm) {
const int destinationMode = QPainter::CompositionMode_Destination;
functionForModeAsm[destinationMode] = functionForMode_C[destinationMode];
// use the default qdrawhelper implementation for the
// extended composition modes
for (int mode = 12; mode < numCompositionFunctions; ++mode)
functionForModeAsm[mode] = functionForMode_C[mode];
functionForMode = functionForModeAsm;
}
qt_build_pow_tables();
}
static void qt_memfill32_setup(quint32 *dest, quint32 value, int count)
{
qInitDrawhelperAsm();
qt_memfill32(dest, value, count);
}
static void qt_memfill16_setup(quint16 *dest, quint16 value, int count)
{
qInitDrawhelperAsm();
qt_memfill16(dest, value, count);
}
#ifdef QT_QWS_DEPTH_GENERIC
int qrgb::bpp = 0;
int qrgb::len_red = 0;
int qrgb::len_green = 0;
int qrgb::len_blue = 0;
int qrgb::len_alpha = 0;
int qrgb::off_red = 0;
int qrgb::off_green = 0;
int qrgb::off_blue = 0;
int qrgb::off_alpha = 0;
template <typename SRC>
Q_STATIC_TEMPLATE_FUNCTION inline void qt_rectconvert_rgb(qrgb *dest, const SRC *src,
int x, int y, int width, int height,
int dstStride, int srcStride)
{
quint8 *dest8 = reinterpret_cast<quint8*>(dest)
+ y * dstStride + x * qrgb::bpp;
srcStride = srcStride / sizeof(SRC) - width;
dstStride -= (width * qrgb::bpp);
for (int j = 0; j < height; ++j) {
for (int i = 0; i < width; ++i) {
const quint32 v = qt_convertToRgb<SRC>(*src++);
#if Q_BYTE_ORDER == Q_BIG_ENDIAN
for (int j = qrgb::bpp - 1; j >= 0; --j)
*dest8++ = (v >> (8 * j)) & 0xff;
#else
for (int j = 0; j < qrgb::bpp; ++j)
*dest8++ = (v >> (8 * j)) & 0xff;
#endif
}
dest8 += dstStride;
src += srcStride;
}
}
template <>
void qt_rectconvert(qrgb *dest, const quint32 *src,
int x, int y, int width, int height,
int dstStride, int srcStride)
{
qt_rectconvert_rgb<quint32>(dest, src, x, y, width, height,
dstStride, srcStride);
}
template <>
void qt_rectconvert(qrgb *dest, const quint16 *src,
int x, int y, int width, int height,
int dstStride, int srcStride)
{
qt_rectconvert_rgb<quint16>(dest, src, x, y, width, height,
dstStride, srcStride);
}
#endif // QT_QWS_DEPTH_GENERIC
QT_END_NAMESPACE