katie/src/gui/painting/qdrawhelper_p.h

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#ifndef QDRAWHELPER_P_H
#define QDRAWHELPER_P_H

//
//  W A R N I N G
//  -------------
//
// This file is not part of the Qt API.  It exists purely as an
// implementation detail.  This header file may change from version to
// version without notice, or even be removed.
//
// We mean it.
//

#include "QtCore/qglobal.h"
#include "QtGui/qcolor.h"
#include "QtGui/qpainter.h"
#include "QtGui/qimage.h"
#ifndef QT_FT_BEGIN_HEADER
#define QT_FT_BEGIN_HEADER
#define QT_FT_END_HEADER
#endif
#include "qrasterdefs_p.h"
#include <qmath_p.h>

QT_BEGIN_NAMESPACE

#if defined(Q_CC_MSVC) && _MSCVER <= 1300 && !defined(Q_CC_INTEL)
#define Q_STATIC_TEMPLATE_SPECIALIZATION static
#else
#define Q_STATIC_TEMPLATE_SPECIALIZATION
#endif

#if defined(Q_CC_RVCT)
// RVCT doesn't like static template functions
#  define Q_STATIC_TEMPLATE_FUNCTION
#  define Q_STATIC_INLINE_FUNCTION static __forceinline
#else
#  define Q_STATIC_TEMPLATE_FUNCTION static
#  define Q_STATIC_INLINE_FUNCTION static inline
#endif

static const uint AMASK = 0xff000000;
static const uint RMASK = 0x00ff0000;
static const uint GMASK = 0x0000ff00;
static const uint BMASK = 0x000000ff;

/*******************************************************************************
 * QSpan
 *
 * duplicate definition of FT_Span
 */
typedef QT_FT_Span QSpan;

struct QSolidData;
struct QTextureData;
struct QGradientData;
struct QLinearGradientData;
struct QRadialGradientData;
struct QConicalGradientData;
struct QSpanData;
class QGradient;
class QRasterBuffer;
class QClipData;
class QRasterPaintEngineState;

typedef QT_FT_SpanFunc ProcessSpans;
typedef void (*BitmapBlitFunc)(QRasterBuffer *rasterBuffer,
                               int x, int y, quint32 color,
                               const uchar *bitmap,
                               int mapWidth, int mapHeight, int mapStride);

typedef void (*AlphamapBlitFunc)(QRasterBuffer *rasterBuffer,
                                 int x, int y, quint32 color,
                                 const uchar *bitmap,
                                 int mapWidth, int mapHeight, int mapStride,
                                 const QClipData *clip);

typedef void (*AlphaRGBBlitFunc)(QRasterBuffer *rasterBuffer,
                                 int x, int y, quint32 color,
                                 const uint *rgbmask,
                                 int mapWidth, int mapHeight, int mapStride,
                                 const QClipData *clip);

typedef void (*RectFillFunc)(QRasterBuffer *rasterBuffer,
                             int x, int y, int width, int height,
                             quint32 color);

typedef void (*SrcOverBlendFunc)(uchar *destPixels, int dbpl,
                                 const uchar *src, int spbl,
                                 int w, int h,
                                 int const_alpha);

typedef void (*SrcOverScaleFunc)(uchar *destPixels, int dbpl,
                                 const uchar *src, int spbl, int srch,
                                 const QRectF &targetRect,
                                 const QRectF &sourceRect,
                                 const QRect &clipRect,
                                 int const_alpha);

typedef void (*SrcOverTransformFunc)(uchar *destPixels, int dbpl,
                                     const uchar *src, int spbl,
                                     const QRectF &targetRect,
                                     const QRectF &sourceRect,
                                     const QRect &clipRect,
                                     const QTransform &targetRectTransform,
                                     int const_alpha);

typedef void (*MemRotateFunc)(const uchar *srcPixels, int w, int h, int sbpl, uchar *destPixels, int dbpl);

struct DrawHelper {
    ProcessSpans blendColor;
    ProcessSpans blendGradient;
    BitmapBlitFunc bitmapBlit;
    AlphamapBlitFunc alphamapBlit;
    AlphaRGBBlitFunc alphaRGBBlit;
    RectFillFunc fillRect;
};

extern DrawHelper qDrawHelper[QImage::NImageFormats];

void qBlendTexture(int count, const QSpan *spans, void *userData);

typedef void (QT_FASTCALL *CompositionFunction)(uint *dest, const uint *src, int length, uint const_alpha);
typedef void (QT_FASTCALL *CompositionFunctionSolid)(uint *dest, int length, uint color, uint const_alpha);

struct LinearGradientValues
{
    qreal dx;
    qreal dy;
    qreal l;
    qreal off;
};

struct RadialGradientValues
{
    qreal dx;
    qreal dy;
    qreal dr;
    qreal sqrfr;
    qreal a;
    qreal inv2a;
    bool extended;
};

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;
    };
};

void qInitDrawhelperAsm();

class QRasterPaintEngine;

struct QSolidData
{
    uint color;
};

struct QLinearGradientData
{
    struct {
        qreal x;
        qreal y;
    } origin;
    struct {
        qreal x;
        qreal y;
    } end;
};

struct QRadialGradientData
{
    struct {
        qreal x;
        qreal y;
        qreal radius;
    } center;
    struct {
        qreal x;
        qreal y;
        qreal radius;
    } focal;
};

struct QConicalGradientData
{
    struct {
        qreal x;
        qreal y;
    } center;
    qreal angle;
};

struct QGradientData
{
    QGradient::Spread spread;

    union {
        QLinearGradientData linear;
        QRadialGradientData radial;
        QConicalGradientData conical;
    };

#define GRADIENT_STOPTABLE_SIZE 1024
#define GRADIENT_STOPTABLE_SIZE_SHIFT 10

    uint* colorTable; //[GRADIENT_STOPTABLE_SIZE];

    uint alphaColor : 1;
};

struct QTextureData
{
    const uchar *imageData;
    const uchar *scanLine(int y) const { return imageData + y*bytesPerLine; }

    int width;
    int height;
    // clip rect
    int x1;
    int y1;
    int x2;
    int y2;
    int bytesPerLine;
    QImage::Format format;
    const QVector<QRgb> *colorTable;
    bool hasAlpha;
    enum Type {
        Plain,
        Tiled
    };
    Type type;
    int const_alpha;
};

struct QSpanData
{
    QSpanData() : tempImage(0) {}
    ~QSpanData() { delete tempImage; }

    QRasterBuffer *rasterBuffer;
    ProcessSpans blend;
    ProcessSpans unclipped_blend;
    BitmapBlitFunc bitmapBlit;
    AlphamapBlitFunc alphamapBlit;
    AlphaRGBBlitFunc alphaRGBBlit;
    RectFillFunc fillRect;
    qreal m11, m12, m13, m21, m22, m23, m33, dx, dy;   // inverse xform matrix
    const QClipData *clip;
    enum Type {
        None,
        Solid,
        LinearGradient,
        RadialGradient,
        ConicalGradient,
        Texture
    } type : 8;
    int txop : 8;
    int fast_matrix : 1;
    bool bilinear;
    QImage *tempImage;
    union {
        QSolidData solid;
        QGradientData gradient;
        QTextureData texture;
    };

    void init(QRasterBuffer *rb, const QRasterPaintEngine *pe);
    void setup(const QBrush &brush, int alpha, QPainter::CompositionMode compositionMode);
    void setupMatrix(const QTransform &matrix, int bilinear);
    void initTexture(const QImage *image, int alpha, QTextureData::Type = QTextureData::Plain, const QRect &sourceRect = QRect());
    void adjustSpanMethods();
};

static inline uint qt_gradient_clamp(const QGradientData *data, int ipos)
{
    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;
            ipos = ipos % limit;
            ipos = ipos < 0 ? limit + ipos : ipos;
            ipos = ipos >= GRADIENT_STOPTABLE_SIZE ? limit - 1 - 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 ipos;
}

static inline uint qt_gradient_pixel(const QGradientData *data, qreal pos)
{
    int ipos = int(pos * (GRADIENT_STOPTABLE_SIZE - 1) + qreal(0.5));
    return data->colorTable[qt_gradient_clamp(data, ipos)];
}

static inline qreal qRadialDeterminant(qreal a, qreal b, qreal c)
{
    return (b * b) - (4 * a * c);
}

template <class RadialFetchFunc>
const uint * QT_FASTCALL qt_fetch_radial_gradient_template(uint *buffer, const Operator *op, const QSpanData *data,
                                                           int y, int x, int length)
{
    // avoid division by zero
    if (qFuzzyIsNull(op->radial.a)) {
        extern void (*qt_memfill32)(quint32 *dest, quint32 value, int count);
        qt_memfill32(buffer, 0, length);
        return buffer;
    }

    const uint *b = buffer;
    qreal rx = data->m21 * (y + qreal(0.5))
               + data->dx + data->m11 * (x + qreal(0.5));
    qreal ry = data->m22 * (y + qreal(0.5))
               + data->dy + data->m12 * (x + qreal(0.5));
    bool affine = !data->m13 && !data->m23;

    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*(op->radial.dr*data->gradient.radial.focal.radius + 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 * (op->radial.sqrfr - 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;

        RadialFetchFunc::fetch(buffer, end, op, data, det, delta_det, delta_delta_det, b, delta_b);
    } else {
        qreal rw = data->m23 * (y + qreal(0.5))
                   + data->m33 + data->m13 * (x + qreal(0.5));

        while (buffer < end) {
            if (rw == 0) {
                *buffer = 0;
            } else {
                qreal invRw = 1 / rw;
                qreal gx = rx * invRw - data->gradient.radial.focal.x;
                qreal gy = ry * invRw - data->gradient.radial.focal.y;
                qreal b  = 2*(op->radial.dr*data->gradient.radial.focal.radius + gx*op->radial.dx + gy*op->radial.dy);
                qreal det = qRadialDeterminant(op->radial.a, b, op->radial.sqrfr - (gx*gx + gy*gy));

                quint32 result = 0;
                if (det >= 0) {
                    qreal detSqrt = qSqrt(det);

                    qreal s0 = (-b - detSqrt) * op->radial.inv2a;
                    qreal s1 = (-b + detSqrt) * op->radial.inv2a;

                    qreal s = qMax(s0, s1);

                    if (data->gradient.radial.focal.radius + op->radial.dr * s >= 0)
                        result = qt_gradient_pixel(&data->gradient, s);
                }

                *buffer = result;
            }

            rx += data->m11;
            ry += data->m12;
            rw += data->m13;

            ++buffer;
        }
    }

    return b;
}

template <class Simd>
class QRadialFetchSimd
{
public:
    static void fetch(uint *buffer, uint *end, const Operator *op, const QSpanData *data, qreal det,
                      qreal delta_det, qreal delta_delta_det, qreal b, qreal delta_b)
    {
        typename Simd::Vect_buffer_f det_vec;
        typename Simd::Vect_buffer_f delta_det4_vec;
        typename Simd::Vect_buffer_f b_vec;

        for (int i = 0; i < 4; ++i) {
            det_vec.f[i] = det;
            delta_det4_vec.f[i] = 4 * delta_det;
            b_vec.f[i] = b;

            det += delta_det;
            delta_det += delta_delta_det;
            b += delta_b;
        }

        const typename Simd::Float32x4 v_delta_delta_det16 = Simd::v_dup(16 * delta_delta_det);
        const typename Simd::Float32x4 v_delta_delta_det6 = Simd::v_dup(6 * delta_delta_det);
        const typename Simd::Float32x4 v_delta_b4 = Simd::v_dup(4 * delta_b);

        const typename Simd::Float32x4 v_r0 = Simd::v_dup(data->gradient.radial.focal.radius);
        const typename Simd::Float32x4 v_dr = Simd::v_dup(op->radial.dr);

        const typename Simd::Float32x4 v_min = Simd::v_dup(0.0f);
        const typename Simd::Float32x4 v_max = Simd::v_dup(float(GRADIENT_STOPTABLE_SIZE-1));
        const typename Simd::Float32x4 v_half = Simd::v_dup(0.5f);

        const typename Simd::Int32x4 v_repeat_mask = Simd::v_dup(~(uint(0xffffff) << GRADIENT_STOPTABLE_SIZE_SHIFT));
        const typename Simd::Int32x4 v_reflect_mask = Simd::v_dup(~(uint(0xffffff) << (GRADIENT_STOPTABLE_SIZE_SHIFT+1)));

        const typename Simd::Int32x4 v_reflect_limit = Simd::v_dup(2 * GRADIENT_STOPTABLE_SIZE - 1);

        const int extended_mask = op->radial.extended ? 0x0 : ~0x0;

#define FETCH_RADIAL_LOOP_PROLOGUE \
        while (buffer < end) { \
            typename Simd::Vect_buffer_i v_buffer_mask; \
            v_buffer_mask.v = Simd::v_greaterOrEqual(det_vec.v, v_min); \
            const typename Simd::Float32x4 v_index_local = Simd::v_sub(Simd::v_sqrt(Simd::v_max(v_min, det_vec.v)), b_vec.v); \
            const typename Simd::Float32x4 v_index = Simd::v_add(Simd::v_mul(v_index_local, v_max), v_half); \
            v_buffer_mask.v = Simd::v_and(v_buffer_mask.v, Simd::v_greaterOrEqual(Simd::v_add(v_r0, Simd::v_mul(v_dr, v_index_local)), v_min)); \
            typename Simd::Vect_buffer_i index_vec;
#define FETCH_RADIAL_LOOP_CLAMP_REPEAT \
            index_vec.v = Simd::v_and(v_repeat_mask, Simd::v_toInt(v_index));
#define FETCH_RADIAL_LOOP_CLAMP_REFLECT \
            const typename Simd::Int32x4 v_index_i = Simd::v_and(v_reflect_mask, Simd::v_toInt(v_index)); \
            const typename Simd::Int32x4 v_index_i_inv = Simd::v_sub(v_reflect_limit, v_index_i); \
            index_vec.v = Simd::v_min_16(v_index_i, v_index_i_inv);
#define FETCH_RADIAL_LOOP_CLAMP_PAD \
            index_vec.v = Simd::v_toInt(Simd::v_min(v_max, Simd::v_max(v_min, v_index)));
#define FETCH_RADIAL_LOOP_EPILOGUE \
            det_vec.v = Simd::v_add(Simd::v_add(det_vec.v, delta_det4_vec.v), v_delta_delta_det6); \
            delta_det4_vec.v = Simd::v_add(delta_det4_vec.v, v_delta_delta_det16); \
            b_vec.v = Simd::v_add(b_vec.v, v_delta_b4); \
            for (int i = 0; i < 4; ++i) \
                *buffer++ = (extended_mask | v_buffer_mask.i[i]) & data->gradient.colorTable[index_vec.i[i]]; \
        }

#define FETCH_RADIAL_LOOP(FETCH_RADIAL_LOOP_CLAMP) \
        FETCH_RADIAL_LOOP_PROLOGUE \
        FETCH_RADIAL_LOOP_CLAMP \
        FETCH_RADIAL_LOOP_EPILOGUE

        switch (data->gradient.spread) {
        case QGradient::RepeatSpread:
            FETCH_RADIAL_LOOP(FETCH_RADIAL_LOOP_CLAMP_REPEAT)
            break;
        case QGradient::ReflectSpread:
            FETCH_RADIAL_LOOP(FETCH_RADIAL_LOOP_CLAMP_REFLECT)
            break;
        case QGradient::PadSpread:
            FETCH_RADIAL_LOOP(FETCH_RADIAL_LOOP_CLAMP_PAD)
            break;
        default:
            Q_ASSERT(false);
        }
    }
};

#if defined(Q_CC_RVCT)
#  pragma push
#  pragma arm
#endif
Q_STATIC_INLINE_FUNCTION uint INTERPOLATE_PIXEL_255(uint x, uint a, uint y, uint b) {
    uint t = (x & 0xff00ff) * a + (y & 0xff00ff) * b;
    t = (t + ((t >> 8) & 0xff00ff) + 0x800080) >> 8;
    t &= 0xff00ff;

    x = ((x >> 8) & 0xff00ff) * a + ((y >> 8) & 0xff00ff) * b;
    x = (x + ((x >> 8) & 0xff00ff) + 0x800080);
    x &= 0xff00ff00;
    x |= t;
    return x;
}
#if defined(Q_CC_RVCT)
#  pragma pop
#endif

#if QT_POINTER_SIZE == 8 // 64-bit versions

Q_STATIC_INLINE_FUNCTION uint INTERPOLATE_PIXEL_256(uint x, uint a, uint y, uint b) {
    quint64 t = (((quint64(x)) | ((quint64(x)) << 24)) & 0x00ff00ff00ff00ff) * a;
    t += (((quint64(y)) | ((quint64(y)) << 24)) & 0x00ff00ff00ff00ff) * b;
    t >>= 8;
    t &= 0x00ff00ff00ff00ff;
    return (uint(t)) | (uint(t >> 24));
}

Q_STATIC_INLINE_FUNCTION uint BYTE_MUL(uint x, uint a) {
    quint64 t = (((quint64(x)) | ((quint64(x)) << 24)) & 0x00ff00ff00ff00ff) * a;
    t = (t + ((t >> 8) & 0xff00ff00ff00ff) + 0x80008000800080) >> 8;
    t &= 0x00ff00ff00ff00ff;
    return (uint(t)) | (uint(t >> 24));
}

Q_STATIC_INLINE_FUNCTION uint PREMUL(uint x) {
    uint a = x >> 24;
    quint64 t = (((quint64(x)) | ((quint64(x)) << 24)) & 0x00ff00ff00ff00ff) * a;
    t = (t + ((t >> 8) & 0xff00ff00ff00ff) + 0x80008000800080) >> 8;
    t &= 0x000000ff00ff00ff;
    return (uint(t)) | (uint(t >> 24)) | (a << 24);
}

#else // 32-bit versions

Q_STATIC_INLINE_FUNCTION uint INTERPOLATE_PIXEL_256(uint x, uint a, uint y, uint b) {
    uint t = (x & 0xff00ff) * a + (y & 0xff00ff) * b;
    t >>= 8;
    t &= 0xff00ff;

    x = ((x >> 8) & 0xff00ff) * a + ((y >> 8) & 0xff00ff) * b;
    x &= 0xff00ff00;
    x |= t;
    return x;
}

#if defined(Q_CC_RVCT)
#  pragma push
#  pragma arm
#endif
Q_STATIC_INLINE_FUNCTION uint BYTE_MUL(uint x, uint a) {
    uint t = (x & 0xff00ff) * a;
    t = (t + ((t >> 8) & 0xff00ff) + 0x800080) >> 8;
    t &= 0xff00ff;

    x = ((x >> 8) & 0xff00ff) * a;
    x = (x + ((x >> 8) & 0xff00ff) + 0x800080);
    x &= 0xff00ff00;
    x |= t;
    return x;
}
#if defined(Q_CC_RVCT)
#  pragma pop
#endif

Q_STATIC_INLINE_FUNCTION uint PREMUL(uint x) {
    uint a = x >> 24;
    uint t = (x & 0xff00ff) * a;
    t = (t + ((t >> 8) & 0xff00ff) + 0x800080) >> 8;
    t &= 0xff00ff;

    x = ((x >> 8) & 0xff) * a;
    x = (x + ((x >> 8) & 0xff) + 0x80);
    x &= 0xff00;
    x |= t | (a << 24);
    return x;
}
#endif


Q_STATIC_INLINE_FUNCTION uint BYTE_MUL_RGB16(uint x, uint a) {
    a += 1;
    uint t = (((x & 0x07e0)*a) >> 8) & 0x07e0;
    t |= (((x & 0xf81f)*(a>>2)) >> 6) & 0xf81f;
    return t;
}

Q_STATIC_INLINE_FUNCTION uint BYTE_MUL_RGB16_32(uint x, uint a) {
    uint t = (((x & 0xf81f07e0) >> 5)*a) & 0xf81f07e0;
    t |= (((x & 0x07e0f81f)*a) >> 5) & 0x07e0f81f;
    return t;
}

#define INV_PREMUL(p)                                   \
    (qAlpha(p) == 0 ? 0 :                               \
    ((qAlpha(p) << 24)                                  \
     | (((255*qRed(p))/ qAlpha(p)) << 16)               \
     | (((255*qGreen(p)) / qAlpha(p))  << 8)            \
     | ((255*qBlue(p)) / qAlpha(p))))

template <class DST, class SRC>
inline DST qt_colorConvert(SRC color, DST dummy)
{
    Q_UNUSED(dummy);
    return DST(color);
}


template <>
inline quint32 qt_colorConvert(quint16 color, quint32 dummy)
{
    Q_UNUSED(dummy);
    const int r = (color & 0xf800);
    const int g = (color & 0x07e0);
    const int b = (color & 0x001f);
    const int tr = (r >> 8) | (r >> 13);
    const int tg = (g >> 3) | (g >> 9);
    const int tb = (b << 3) | (b >> 2);

    return qRgb(tr, tg, tb);
}

template <>
inline quint16 qt_colorConvert(quint32 color, quint16 dummy)
{
    Q_UNUSED(dummy);
    const int r = qRed(color) << 8;
    const int g = qGreen(color) << 3;
    const int b = qBlue(color) >> 3;

    return (r & 0xf800) | (g & 0x07e0)| (b & 0x001f);
}

class quint32p
{
public:
    inline quint32p(quint32 v) : data(PREMUL(v)) {}

    inline operator quint32() const { return data; }

    inline operator quint16() const
    {
        return qt_colorConvert<quint16, quint32>(data, 0);
    }

    Q_STATIC_INLINE_FUNCTION quint32p fromRawData(quint32 v)
    {
        quint32p p;
        p.data = v;
        return p;
    }

private:
    quint32p() {}
    quint32 data;
};

class qabgr8888
{
public:
    inline qabgr8888(quint32 v)
    {
        data = qRgba(qBlue(v), qGreen(v), qRed(v), qAlpha(v));
    }

    inline bool operator==(const qabgr8888 &v) const { return data == v.data; }

private:
    quint32 data;
};

class qrgb565;

class qargb8565
{
public:
    Q_STATIC_INLINE_FUNCTION bool hasAlpha() { return true; }

    inline qargb8565() {}
    inline qargb8565(quint32 v);
    inline explicit qargb8565(quint32p v);
    inline qargb8565(const qargb8565 &v);
    inline qargb8565(const qrgb565 &v);

    inline operator quint32() const;
    inline operator quint16() const;

    inline quint8 alpha() const { return data[0]; }
    inline qargb8565 truncedAlpha() {
        data[0] &= 0xf8;
        data[1] &= 0xdf;
        return *this;
    }
    Q_STATIC_INLINE_FUNCTION quint8 alpha(quint8 a) { return (a + 1) >> 3; }
    Q_STATIC_INLINE_FUNCTION quint8 ialpha(quint8 a) { return 0x20 - alpha(a); }

    inline qargb8565 byte_mul(quint8 a) const;
    inline qargb8565 operator+(qargb8565 v) const;
    inline bool operator==(const qargb8565 &v) const;

    inline quint32 rawValue() const;
    inline quint16 rawValue16() const;

private:
    friend class qrgb565;
    quint8 data[3];
};

class qrgb565
{
public:
    Q_STATIC_INLINE_FUNCTION bool hasAlpha() { return false; }

    qrgb565(int v = 0) : data(v) {}

    inline explicit qrgb565(quint32p v);
    inline explicit qrgb565(quint32 v);
    inline explicit qrgb565(const qargb8565 &v);

    inline operator quint32() const;
    inline operator quint16() const;

    inline qrgb565 operator+(qrgb565 v) const;

    inline quint8 alpha() const { return 0xff; }
    inline qrgb565 truncedAlpha() { return *this; }
    Q_STATIC_INLINE_FUNCTION quint8 alpha(quint8 a) { return (a + 1) >> 3; }
    Q_STATIC_INLINE_FUNCTION quint8 ialpha(quint8 a) { return 0x20 - alpha(a); }

    inline qrgb565 byte_mul(quint8 a) const;

    inline bool operator==(const qrgb565 &v) const;
    inline quint16 rawValue() const { return data; }

private:
    friend class qargb8565;
    quint16 data;
};

qargb8565::qargb8565(quint32 v)
{
    *this = qargb8565(quint32p(v));
}

qargb8565::qargb8565(quint32p v)
{
    data[0] = qAlpha(v);
    const int r = qRed(v);
    const int g = qGreen(v);
    const int b = qBlue(v);
    data[1] = ((g << 3) & 0xe0) | (b >> 3);
    data[2] = (r & 0xf8) | (g >> 5);
}

qargb8565::qargb8565(const qargb8565 &v)
{
    data[0] = v.data[0];
    data[1] = v.data[1];
    data[2] = v.data[2];
}

qargb8565::qargb8565(const qrgb565 &v)
{
    data[0] = 0xff;
    data[1] = v.data & 0xff;
    data[2] = v.data >> 8;
}

qargb8565::operator quint32() const
{
    const quint16 rgb = (data[2] << 8) | data[1];
    const int a = data[0];
    const int r = (rgb & 0xf800);
    const int g = (rgb & 0x07e0);
    const int b = (rgb & 0x001f);
    const int tr = qMin(a, (r >> 8) | (r >> 13));
    const int tg = qMin(a, (g >> 3) | (g >> 9));
    const int tb = qMin(a, (b << 3) | (b >> 2));
    return qRgba(tr, tg, tb, data[0]);
}

qargb8565::operator quint16() const
{
    return (data[2] << 8) | data[1];
}

qargb8565 qargb8565::operator+(qargb8565 v) const
{
    qargb8565 t;
    t.data[0] = data[0] + v.data[0];
    const quint16 rgb =  ((data[2] + v.data[2]) << 8)
                         + (data[1] + v.data[1]);
    t.data[1] = rgb & 0xff;
    t.data[2] = rgb >> 8;
    return t;
}

qargb8565 qargb8565::byte_mul(quint8 a) const
{
    qargb8565 result;
    result.data[0] = (data[0] * a) >> 5;

    const quint16 x = (data[2] << 8) | data[1];
    const quint16 t = ((((x & 0x07e0) >> 5) * a) & 0x07e0) |
                      ((((x & 0xf81f) * a) >> 5) & 0xf81f);
    result.data[1] = t & 0xff;
    result.data[2] = t >> 8;
    return result;
}

bool qargb8565::operator==(const qargb8565 &v) const
{
    return data[0] == v.data[0]
        && data[1] == v.data[1]
        && data[2] == v.data[2];
}

quint32 qargb8565::rawValue() const
{
    return (data[2] << 16) | (data[1] << 8) | data[0];
}

quint16 qargb8565::rawValue16() const
{
    return (data[2] << 8) | data[1];
}

qrgb565::qrgb565(quint32p v)
{
    *this = qrgb565(quint32(v));
}

qrgb565::qrgb565(quint32 v)
{
    const int r = qRed(v) << 8;
    const int g = qGreen(v) << 3;
    const int b = qBlue(v) >> 3;

    data = (r & 0xf800) | (g & 0x07e0)| (b & 0x001f);
}

qrgb565::qrgb565(const qargb8565 &v)
{
    data = (v.data[2] << 8) | v.data[1];
}

qrgb565::operator quint32() const
{
    const int r = (data & 0xf800);
    const int g = (data & 0x07e0);
    const int b = (data & 0x001f);
    const int tr = (r >> 8) | (r >> 13);
    const int tg = (g >> 3) | (g >> 9);
    const int tb = (b << 3) | (b >> 2);
    return qRgb(tr, tg, tb);
}

qrgb565::operator quint16() const
{
    return data;
}

qrgb565 qrgb565::operator+(qrgb565 v) const
{
    qrgb565 t;
    t.data = data + v.data;
    return t;
}

qrgb565 qrgb565::byte_mul(quint8 a) const
{
    qrgb565 result;
    result.data = ((((data & 0x07e0) >> 5) * a) & 0x07e0) |
                  ((((data & 0xf81f) * a) >> 5) & 0xf81f);
    return result;
}

bool qrgb565::operator==(const qrgb565 &v) const
{
    return data == v.data;
}

class qbgr565
{
public:
    inline qbgr565(quint16 v)
    {
        data = ((v & 0x001f) << 11) |
               (v & 0x07e0) |
               ((v & 0xf800) >> 11);
    }

    inline bool operator==(const qbgr565 &v) const
    {
        return data == v.data;
    }

private:
    quint16 data;
};

class qrgb555;

class qargb8555
{
public:
    Q_STATIC_INLINE_FUNCTION bool hasAlpha() { return true; }

    qargb8555() {}
    inline qargb8555(quint32 v);
    inline explicit qargb8555(quint32p v);
    inline qargb8555(const qargb8555 &v);
    inline qargb8555(const qrgb555 &v);

    inline operator quint32() const;

    inline quint8 alpha() const { return data[0]; }
    inline qargb8555 truncedAlpha() { data[0] &= 0xf8; return *this; }
    Q_STATIC_INLINE_FUNCTION quint8 alpha(quint8 a) { return (a + 1) >> 3; }
    Q_STATIC_INLINE_FUNCTION quint8 ialpha(quint8 a) { return 0x20 - alpha(a); }

    inline qargb8555 operator+(qargb8555 v) const;
    inline qargb8555 byte_mul(quint8 a) const;

    inline bool operator==(const qargb8555 &v) const;

    inline quint32 rawValue() const;

private:
    friend class qrgb555;
    quint8 data[3];
};

class qrgb555
{
public:
    Q_STATIC_INLINE_FUNCTION bool hasAlpha() { return false; }

    inline qrgb555(int v = 0) : data(v) {}

    inline explicit qrgb555(quint32p v) { *this = qrgb555(quint32(v)); }

    inline explicit qrgb555(quint32 v)
    {
        const int r = qRed(v) << 7;
        const int g = qGreen(v) << 2;
        const int b = qBlue(v) >> 3;

        data = (r & 0x7c00) | (g & 0x03e0) | (b & 0x001f);
    }

    inline explicit qrgb555(quint16 v)
    {
        data = ((v >> 1) & (0x7c00 | 0x03e0)) |
               (v & 0x001f);
    }

    inline explicit qrgb555(const qargb8555 &v);

    inline operator quint32() const
    {
        const int r = (data & 0x7c00);
        const int g = (data & 0x03e0);
        const int b = (data & 0x001f);
        const int tr = (r >> 7) | (r >> 12);
        const int tg = (g >> 2) | (g >> 7);
        const int tb = (b << 3) | (b >> 2);

        return qRgb(tr, tg, tb);
    }

    inline operator quint16() const
    {
        const int r = ((data & 0x7c00) << 1) & 0xf800;
        const int g = (((data & 0x03e0) << 1) | ((data >> 4) & 0x0020)) & 0x07e0;
        const int b = (data & 0x001f);

        return r | g | b;
    }

    inline qrgb555 operator+(qrgb555 v) const;
    inline qrgb555 byte_mul(quint8 a) const;

    inline quint8 alpha() const { return 0xff; }
    inline qrgb555 truncedAlpha() { return *this; }
    Q_STATIC_INLINE_FUNCTION quint8 alpha(quint8 a) { return (a + 1) >> 3; }
    Q_STATIC_INLINE_FUNCTION quint8 ialpha(quint8 a) { return 0x20 - alpha(a); }

    inline bool operator==(const qrgb555 &v) const { return v.data == data; }
    inline bool operator!=(const qrgb555 &v) const { return v.data != data; }

    inline quint16 rawValue() const { return data; }

private:
    friend class qargb8555;
    friend class qbgr555;
    quint16 data;
};

qrgb555::qrgb555(const qargb8555 &v)
{
    data = (v.data[2] << 8) | v.data[1];
}

qrgb555 qrgb555::operator+(qrgb555 v) const
{
    qrgb555 t;
    t.data = data + v.data;
    return t;
}

qrgb555 qrgb555::byte_mul(quint8 a) const
{
    quint16 t = (((data & 0x3e0) * a) >> 5) & 0x03e0;
    t |= (((data & 0x7c1f) * a) >> 5) & 0x7c1f;

    qrgb555 result;
    result.data = t;
    return result;
}

class qbgr555
{
public:
    inline qbgr555(quint32 v) { *this = qbgr555(qrgb555(v)); }

    inline qbgr555(qrgb555 v)
    {
        data = ((v.data & 0x001f) << 10) |
               (v.data & 0x03e0) |
               ((v.data & 0x7c00) >> 10);
    }

    inline bool operator==(const qbgr555 &v) const
    {
        return data == v.data;
    }

private:
    quint16 data;
};

qargb8555::qargb8555(quint32 v)
{
    v = quint32p(v);
    data[0] = qAlpha(v);
    const int r = qRed(v);
    const int g = qGreen(v);
    const int b = qBlue(v);
    data[1] = ((g << 2) & 0xe0) | (b >> 3);
    data[2] = ((r >> 1) & 0x7c) | (g >> 6);

}

qargb8555::qargb8555(quint32p v)
{
    data[0] = qAlpha(v);
    const int r = qRed(v);
    const int g = qGreen(v);
    const int b = qBlue(v);
    data[1] = ((g << 2) & 0xe0) | (b >> 3);
    data[2] = ((r >> 1) & 0x7c) | (g >> 6);
}

qargb8555::qargb8555(const qargb8555 &v)
{
    data[0] = v.data[0];
    data[1] = v.data[1];
    data[2] = v.data[2];
}

qargb8555::qargb8555(const qrgb555 &v)
{
    data[0] = 0xff;
    data[1] = v.data & 0xff;
    data[2] = v.data >> 8;
}

qargb8555::operator quint32() const
{
    const quint16 rgb = (data[2] << 8) | data[1];
    const int r = (rgb & 0x7c00);
    const int g = (rgb & 0x03e0);
    const int b = (rgb & 0x001f);
    const int tr = (r >> 7) | (r >> 12);
    const int tg = (g >> 2) | (g >> 7);
    const int tb = (b << 3) | (b >> 2);

    return qRgba(tr, tg, tb, data[0]);
}

bool qargb8555::operator==(const qargb8555 &v) const
{
    return data[0] == v.data[0]
        && data[1] == v.data[1]
        && data[2] == v.data[2];
}

quint32 qargb8555::rawValue() const
{
    return (data[2] << 16) | (data[1] << 8) | data[0];
}

qargb8555 qargb8555::operator+(qargb8555 v) const
{
    qargb8555 t;
    t.data[0] = data[0] + v.data[0];
    const quint16 rgb =  ((data[2] + v.data[2]) << 8)
                         + (data[1] + v.data[1]);
    t.data[1] = rgb & 0xff;
    t.data[2] = rgb >> 8;
    return t;
}

qargb8555 qargb8555::byte_mul(quint8 a) const
{
    qargb8555 result;
    result.data[0] = (data[0] * a) >> 5;

    const quint16 x = (data[2] << 8) | data[1];
    quint16 t = (((x & 0x3e0) * a) >> 5) & 0x03e0;
    t |= (((x & 0x7c1f) * a) >> 5) & 0x7c1f;
    result.data[1] = t & 0xff;
    result.data[2] = t >> 8;
    return result;

}

class qrgb666;

class qargb6666
{
public:
    Q_STATIC_INLINE_FUNCTION bool hasAlpha() { return true; }

    inline qargb6666() {}
    inline qargb6666(quint32 v) { *this = qargb6666(quint32p(v)); }
    inline explicit qargb6666(quint32p v);
    inline qargb6666(const qargb6666 &v);
    inline qargb6666(const qrgb666 &v);

    inline operator quint32 () const;

    inline quint8 alpha() const;
    inline qargb6666 truncedAlpha() { return *this; }
    Q_STATIC_INLINE_FUNCTION quint8 alpha(quint8 a) { return (a + 1) >> 2; }
    Q_STATIC_INLINE_FUNCTION quint8 ialpha(quint8 a) { return (255 - a + 1) >> 2; }

    inline qargb6666 byte_mul(quint8 a) const;
    inline qargb6666 operator+(qargb6666 v) const;
    inline bool operator==(const qargb6666 &v) const;

    inline quint32 rawValue() const;

private:
    friend class qrgb666;
    quint8 data[3];
};

class qrgb666
{
public:
    Q_STATIC_INLINE_FUNCTION bool hasAlpha() { return false; }

    inline qrgb666() {}
    inline qrgb666(quint32 v);
    inline qrgb666(const qargb6666 &v);

    inline operator quint32 () const;

    inline quint8 alpha() const { return 0xff; }
    inline qrgb666 truncedAlpha() { return *this; }
    Q_STATIC_INLINE_FUNCTION quint8 alpha(quint8 a) { return (a + 1) >> 2; }
    Q_STATIC_INLINE_FUNCTION quint8 ialpha(quint8 a) { return (255 - a + 1) >> 2; }

    inline qrgb666 operator+(qrgb666 v) const;
    inline qrgb666 byte_mul(quint8 a) const;

    inline bool operator==(const qrgb666 &v) const;
    inline bool operator!=(const qrgb666 &v) const { return !(*this == v); }

    inline quint32 rawValue() const
    {
        return (data[2] << 16) | (data[1] << 8) | data[0];
    }

private:
    friend class qargb6666;
    quint8 data[3];
};

qrgb666::qrgb666(quint32 v)
{
    const uchar b = qBlue(v);
    const uchar g = qGreen(v);
    const uchar r = qRed(v);
    const uint p = (b >> 2) | ((g >> 2) << 6) | ((r >> 2) << 12);
    data[0] = qBlue(p);
    data[1] = qGreen(p);
    data[2] = qRed(p);
}

qrgb666::qrgb666(const qargb6666 &v)
{
    data[0] = v.data[0];
    data[1] = v.data[1];
    data[2] = v.data[2] & 0x03;
}

qrgb666::operator quint32 () const
{
    const uchar r = (data[2] << 6) | ((data[1] & 0xf0) >> 2) | (data[2] & 0x3);
    const uchar g = (data[1] << 4) | ((data[0] & 0xc0) >> 4) | ((data[1] & 0x0f) >> 2);
    const uchar b = (data[0] << 2) | ((data[0] & 0x3f) >> 4);
    return qRgb(r, g, b);
}

qrgb666 qrgb666::operator+(qrgb666 v) const
{
    const quint32 x1 = (data[2] << 16) | (data[1] << 8) | data[0];
    const quint32 x2 = (v.data[2] << 16) | (v.data[1] << 8) | v.data[0];
    const quint32 t = x1 + x2;
    qrgb666 r;
    r.data[0] = t & 0xff;
    r.data[1] = (t >> 8) & 0xff;
    r.data[2] = (t >> 16) & 0xff;
    return r;
}

qrgb666 qrgb666::byte_mul(quint8 a) const
{
    const quint32 x = (data[2] << 16) | (data[1] << 8) | data[0];
    const quint32 t = ((((x & 0x03f03f) * a) >> 6) & 0x03f03f) |
                      ((((x & 0x000fc0) * a) >> 6) & 0x000fc0);

    qrgb666 r;
    r.data[0] = t & 0xff;
    r.data[1] = (t >> 8) & 0xff;
    r.data[2] = (t >> 16) & 0xff;
    return r;
}

bool qrgb666::operator==(const qrgb666 &v) const
{
    return (data[0] == v.data[0] &&
            data[1] == v.data[1] &&
            data[2] == v.data[2]);
}

qargb6666::qargb6666(quint32p v)
{
    const quint8 b = qBlue(v) >> 2;
    const quint8 g = qGreen(v) >> 2;
    const quint8 r = qRed(v) >> 2;
    const quint8 a = qAlpha(v) >> 2;
    const uint p = (a << 18) | (r << 12) | (g << 6) | b;
    data[0] = qBlue(p);
    data[1] = qGreen(p);
    data[2] = qRed(p);
}

qargb6666::qargb6666(const qargb6666 &v)
{
    data[0] = v.data[0];
    data[1] = v.data[1];
    data[2] = v.data[2];
}

qargb6666::qargb6666(const qrgb666 &v)
{
    data[0] = v.data[0];
    data[1] = v.data[1];
    data[2] = (v.data[2] | 0xfc);
}

qargb6666::operator quint32 () const
{
    const quint8 r = (data[2] << 6) | ((data[1] & 0xf0) >> 2) | (data[2] & 0x3);
    const quint8 g = (data[1] << 4) | ((data[0] & 0xc0) >> 4) | ((data[1] & 0x0f) >> 2);
    const quint8 b = (data[0] << 2) | ((data[0] & 0x3f) >> 4);
    const quint8 a = (data[2] & 0xfc) | (data[2] >> 6);
    return qRgba(r, g, b, a);
}

qargb6666 qargb6666::operator+(qargb6666 v) const
{
    const quint32 x1 = (data[2] << 16) | (data[1] << 8) | data[0];
    const quint32 x2 = (v.data[2] << 16) | (v.data[1] << 8) | v.data[0];
    const quint32 t = x1 + x2;
    qargb6666 r;
    r.data[0] = t & 0xff;
    r.data[1] = (t >> 8) & 0xff;
    r.data[2] = (t >> 16) & 0xff;
    return r;
}

quint8 qargb6666::alpha() const
{
    return (data[2] & 0xfc) | (data[2] >> 6);
}

inline qargb6666 qargb6666::byte_mul(quint8 a) const
{
    const quint32 x = (data[2] << 16) | (data[1] << 8) | data[0];
    const quint32 t = ((((x & 0x03f03f) * a) >> 6) & 0x03f03f) |
                      ((((x & 0xfc0fc0) * a) >> 6) & 0xfc0fc0);

    qargb6666 r;
    r.data[0] = t & 0xff;
    r.data[1] = (t >> 8) & 0xff;
    r.data[2] = (t >> 16) & 0xff;
    return r;
}

bool qargb6666::operator==(const qargb6666 &v) const
{
    return data[0] == v.data[0]
        && data[1] == v.data[1]
        && data[2] == v.data[2];
}

quint32 qargb6666::rawValue() const
{
    return (data[2] << 16) | (data[1] << 8) | data[0];
}

class qrgb888
{
public:
    Q_STATIC_INLINE_FUNCTION bool hasAlpha() { return false; }

    inline qrgb888() {}
    inline qrgb888(quint32 v);

    inline operator quint32() const;

    inline quint8 alpha() const { return 0xff; }
    inline qrgb888 truncedAlpha() { return *this; }
    Q_STATIC_INLINE_FUNCTION quint8 alpha(quint8 a) { return a; }
    Q_STATIC_INLINE_FUNCTION quint8 ialpha(quint8 a) { return 255 - a; }

    inline qrgb888 byte_mul(quint8 a) const;
    inline qrgb888 operator+(qrgb888 v) const;
    inline bool operator==(qrgb888 v) const;

    inline quint32 rawValue() const;

private:
    uchar data[3];
};

qrgb888::qrgb888(quint32 v)
{
    data[0] = qRed(v);
    data[1] = qGreen(v);
    data[2] = qBlue(v);
}

qrgb888::operator quint32() const
{
    return qRgb(data[0], data[1], data[2]);
}

qrgb888 qrgb888::operator+(qrgb888 v) const
{
    qrgb888 t = *this;
    t.data[0] += v.data[0];
    t.data[1] += v.data[1];
    t.data[2] += v.data[2];
    return t;
}

qrgb888 qrgb888::byte_mul(quint8 a) const
{
    quint32 x(*this);

    quint32 t = (x & 0xff00ff) * a;
    t = (t + ((t >> 8) & 0xff00ff) + 0x800080) >> 8;
    t &= 0xff00ff;

    x = ((x >> 8) & 0xff00ff) * a;
    x = (x + ((x >> 8) & 0xff00ff) + 0x800080);
    x &= 0xff00ff00;
    x |= t;
    return qrgb888(x);
}

bool qrgb888::operator==(qrgb888 v) const
{
    return (data[0] == v.data[0] &&
            data[1] == v.data[1] &&
            data[2] == v.data[2]);
}

quint32 qrgb888::rawValue() const
{
    return (data[2] << 16) | (data[1] << 8) | data[0];
}

template <>
inline qrgb888 qt_colorConvert(quint32 color, qrgb888 dummy)
{
    Q_UNUSED(dummy);
    return qrgb888(color);
}

template <>
inline quint32 qt_colorConvert(qrgb888 color, quint32 dummy)
{
    Q_UNUSED(dummy);
    return quint32(color);
}

// hw: endianess??
class quint24
{
public:
    inline quint24(quint32 v)
    {
        data[0] = qBlue(v);
        data[1] = qGreen(v);
        data[2] = qRed(v);
    }

    inline operator quint32 ()
    {
        return qRgb(data[2], data[1], data[0]);
    }

    inline bool operator==(const quint24 &v) const
    {
        return data[0] == v.data[0]
            && data[1] == v.data[1]
            && data[2] == v.data[2];
    }

private:
    uchar data[3];
};

template <>
inline quint24 qt_colorConvert(quint32 color, quint24 dummy)
{
    Q_UNUSED(dummy);
    return quint24(color);
}

// hw: endianess??
class quint18
{
public:
    inline quint18(quint32 v)
    {
        uchar b = qBlue(v);
        uchar g = qGreen(v);
        uchar r = qRed(v);
        uint p = (b >> 2) | ((g >> 2) << 6) | ((r >> 2) << 12);
        data[0] = qBlue(p);
        data[1] = qGreen(p);
        data[2] = qRed(p);
    }

    inline operator quint32 ()
    {
        const uchar r = (data[2] << 6) | ((data[1] & 0xf0) >> 2) | (data[2] & 0x3);
        const uchar g = (data[1] << 4) | ((data[0] & 0xc0) >> 4) | ((data[1] & 0x0f) >> 2);
        const uchar b = (data[0] << 2) | ((data[0] & 0x3f) >> 4);
        return qRgb(r, g, b);
    }

private:
    uchar data[3];
};

template <>
inline quint18 qt_colorConvert(quint32 color, quint18 dummy)
{
    Q_UNUSED(dummy);
    return quint18(color);
}

class qrgb444;

class qargb4444
{
public:
    Q_STATIC_INLINE_FUNCTION bool hasAlpha() { return true; }

    inline qargb4444() {}
    inline qargb4444(quint32 v) { *this = qargb4444(quint32p(v)); }
    inline explicit qargb4444(quint32p v);
    inline qargb4444(const qrgb444 &v);

    inline operator quint32() const;
    inline operator quint8() const;

    inline qargb4444 operator+(qargb4444 v) const;

    inline quint8 alpha() const { return ((data & 0xf000) >> 8) | ((data & 0xf000) >> 12); }
    inline qargb4444 truncedAlpha() { return *this; }
    Q_STATIC_INLINE_FUNCTION quint8 alpha(quint8 a) { return (a + 1) >> 4; }
    Q_STATIC_INLINE_FUNCTION quint8 ialpha(quint8 a) { return 0x10 - alpha(a); }
    inline qargb4444 byte_mul(quint8 a) const;

    inline bool operator==(const qargb4444 &v) const { return data == v.data; }

    inline quint16 rawValue() const { return data; }

private:
    friend class qrgb444;
    quint16 data;
};

class qrgb444
{
public:
    Q_STATIC_INLINE_FUNCTION bool hasAlpha() { return false; }

    inline qrgb444() {}
    inline qrgb444(quint32 v);
    inline explicit qrgb444(qargb4444 v);

    inline operator quint32() const;
    inline operator quint8() const;

    inline qrgb444 operator+(qrgb444 v) const;
    inline quint8 alpha() const { return 0xff; }
    inline qrgb444 truncedAlpha() { return *this; }
    Q_STATIC_INLINE_FUNCTION quint8 alpha(quint8 a) { return (a + 1) >> 4; }
    Q_STATIC_INLINE_FUNCTION quint8 ialpha(quint8 a) { return 0x10 - alpha(a); }
    inline qrgb444 byte_mul(quint8 a) const;

    inline bool operator==(const qrgb444 &v) const { return data == v.data; }
    inline bool operator!=(const qrgb444 &v) const { return data != v.data; }

    inline quint16 rawValue() const { return data; }

private:
    friend class qargb4444;
    quint16 data;
};


qargb4444::qargb4444(quint32p color)
{
    quint32 v = color;
    v &= 0xf0f0f0f0;
    const int a = qAlpha(v) << 8;
    const int r = qRed(v) << 4;
    const int g = qGreen(v);
    const int b = qBlue(v) >> 4;

    data = a | r | g | b;
}

qargb4444::qargb4444(const qrgb444 &v)
{
    data = v.data | 0xf000;
}

qargb4444::operator quint32() const
{
    const int a = (data & 0xf000);
    const int r = (data & 0x0f00);
    const int g = (data & 0x00f0);
    const int b = (data & 0x000f);
    const int ta = (a >> 8) | (a >> 12);
    const int tr = (r >> 4) | (r >> 8);
    const int tg = g | (g >> 4);
    const int tb = (b << 4) | b;

    return qRgba(tr, tg, tb, ta);
}

qargb4444::operator quint8() const
{
    // hw: optimize!
    return qt_colorConvert<quint8, quint32>(operator quint32(), 0);
}

qargb4444 qargb4444::operator+(qargb4444 v) const
{
    qargb4444 t;
    t.data = data + v.data;
    return t;
}

qargb4444 qargb4444::byte_mul(quint8 a) const
{
    quint16 t = (((data & 0xf0f0) * a) >> 4) & 0xf0f0;
    t |= (((data & 0x0f0f) * a) >> 4) & 0x0f0f;

    qargb4444 result;
    result.data = t;
    return result;
}

qrgb444::qrgb444(quint32 v)
{
    v &= 0xf0f0f0f0;
    const int r = qRed(v) << 4;
    const int g = qGreen(v);
    const int b = qBlue(v) >> 4;

    data = r | g | b;
}

qrgb444::qrgb444(qargb4444 v)
{
    data = v.data & 0x0fff;
}

qrgb444::operator quint32() const
{
    const int r = (data & 0x0f00);
    const int g = (data & 0x00f0);
    const int b = (data & 0x000f);
    const int tr = (r >> 4) | (r >> 8);
    const int tg = g | (g >> 4);
    const int tb = (b << 4) | b;

    return qRgb(tr, tg, tb);
}

qrgb444::operator quint8() const
{
    // hw: optimize!
    return qt_colorConvert<quint8, quint32>(operator quint32(), 0);
}

qrgb444 qrgb444::operator+(qrgb444 v) const
{
    qrgb444 t;
    t.data = data + v.data;
    return t;
}

qrgb444 qrgb444::byte_mul(quint8 a) const
{
    quint16 t = (((data & 0xf0f0) * a) >> 4) & 0xf0f0;
    t |= (((data & 0x0f0f) * a) >> 4) & 0x0f0f;

    qrgb444 result;
    result.data = t;
    return result;
}

template <class T>
void qt_memfill(T *dest, T value, int count);

template<> inline void qt_memfill(quint32 *dest, quint32 color, int count)
{
    extern void (*qt_memfill32)(quint32 *dest, quint32 value, int count);
    qt_memfill32(dest, color, count);
}

template<> inline void qt_memfill(quint16 *dest, quint16 color, int count)
{
    extern void (*qt_memfill16)(quint16 *dest, quint16 value, int count);
    qt_memfill16(dest, color, count);
}

template<> inline void qt_memfill(quint8 *dest, quint8 color, int count)
{
    memset(dest, color, count);
}

template <class T>
inline void qt_memfill(T *dest, T value, int count)
{
    if (!count)
        return;

    int n = (count + 7) / 8;
    switch (count & 0x07)
    {
    case 0: do { *dest++ = value;
    case 7:      *dest++ = value;
    case 6:      *dest++ = value;
    case 5:      *dest++ = value;
    case 4:      *dest++ = value;
    case 3:      *dest++ = value;
    case 2:      *dest++ = value;
    case 1:      *dest++ = value;
    } while (--n > 0);
    }
}

template <class T>
inline void qt_rectfill(T *dest, T value,
                        int x, int y, int width, int height, int stride)
{
    char *d = reinterpret_cast<char*>(dest + x) + y * stride;
    if (uint(stride) == (width * sizeof(T))) {
        qt_memfill(reinterpret_cast<T*>(d), value, width * height);
    } else {
        for (int j = 0; j < height; ++j) {
            dest = reinterpret_cast<T*>(d);
            qt_memfill(dest, value, width);
            d += stride;
        }
    }
}

template <class DST, class SRC>
inline void qt_memconvert(DST *dest, const SRC *src, int count)
{
    if (sizeof(DST) == 1) {
        while (count) {
            int n = 1;
            const SRC color = *src++;
            const DST dstColor = qt_colorConvert<DST, SRC>(color, 0);
            while (--count && (*src == color || dstColor == qt_colorConvert<DST, SRC>(*src, 0))) {
                ++n;
                ++src;
            }
            qt_memfill(dest, dstColor, n);
            dest += n;
        }
    } else {
        /* Duff's device */
        int n = (count + 7) / 8;
        switch (count & 0x07)
        {
        case 0: do { *dest++ = qt_colorConvert<DST, SRC>(*src++, 0);
            case 7:      *dest++ = qt_colorConvert<DST, SRC>(*src++, 0);
            case 6:      *dest++ = qt_colorConvert<DST, SRC>(*src++, 0);
            case 5:      *dest++ = qt_colorConvert<DST, SRC>(*src++, 0);
            case 4:      *dest++ = qt_colorConvert<DST, SRC>(*src++, 0);
            case 3:      *dest++ = qt_colorConvert<DST, SRC>(*src++, 0);
            case 2:      *dest++ = qt_colorConvert<DST, SRC>(*src++, 0);
            case 1:      *dest++ = qt_colorConvert<DST, SRC>(*src++, 0);
            } while (--n > 0);
        }
    }
}

#define QT_TRIVIAL_MEMCONVERT_IMPL(T) \
    template <> \
    inline void qt_memconvert(T *dest, const T *src, int count) \
    { \
        memcpy(dest, src, count * sizeof(T)); \
    }
QT_TRIVIAL_MEMCONVERT_IMPL(quint32)
QT_TRIVIAL_MEMCONVERT_IMPL(qrgb888)
QT_TRIVIAL_MEMCONVERT_IMPL(qargb6666)
QT_TRIVIAL_MEMCONVERT_IMPL(qrgb666)
QT_TRIVIAL_MEMCONVERT_IMPL(quint16)
QT_TRIVIAL_MEMCONVERT_IMPL(qrgb565)
QT_TRIVIAL_MEMCONVERT_IMPL(qargb8565)
QT_TRIVIAL_MEMCONVERT_IMPL(qargb8555)
QT_TRIVIAL_MEMCONVERT_IMPL(qrgb555)
QT_TRIVIAL_MEMCONVERT_IMPL(qargb4444)
QT_TRIVIAL_MEMCONVERT_IMPL(qrgb444)
#undef QT_TRIVIAL_MEMCONVERT_IMPL

#if Q_BYTE_ORDER == Q_LITTLE_ENDIAN
template <>
inline void qt_memconvert(qrgb666 *dest, const quint32 *src, int count)
{
    if (count < 3) {
        switch (count) {
        case 2: *dest++ = qrgb666(*src++);
        case 1: *dest = qrgb666(*src);
        }
        return;
    }

    const int align = (quintptr(dest) & 3);
    switch (align) {
    case 1: *dest++ = qrgb666(*src++); --count;
    case 2: *dest++ = qrgb666(*src++); --count;
    case 3: *dest++ = qrgb666(*src++); --count;
    }

    quint32 *dest32 = reinterpret_cast<quint32*>(dest);
    int sourceCount = count >> 2;
    while (sourceCount--) {
        dest32[0] = ((src[1] & 0x00000c00) << 20)
                    | ((src[1] & 0x000000fc) << 22)
                    | ((src[0] & 0x00fc0000) >> 6)
                    | ((src[0] & 0x0000fc00) >> 4)
                    |  ((src[0] & 0x000000fc) >> 2);
        dest32[1] = ((src[2] & 0x003c0000) << 10)
                    | ((src[2] & 0x0000fc00) << 12)
                    | ((src[2] & 0x000000fc) << 14)
                    | ((src[1] & 0x00fc0000) >> 14)
                    | ((src[1] & 0x0000f000) >> 12);
        dest32[2] = ((src[3] & 0x00fc0000) << 2)
                    | ((src[3] & 0x0000fc00) << 4)
                    | ((src[3] & 0x000000fc) << 6)
                    | ((src[2] & 0x00c00000) >> 22);
        dest32 += 3;
        src += 4;
    }

    dest = reinterpret_cast<qrgb666*>(dest32);
    switch (count & 3) {
    case 3: *dest++ = qrgb666(*src++);
    case 2: *dest++ = qrgb666(*src++);
    case 1: *dest = qrgb666(*src);
    }
}
#endif // Q_BYTE_ORDER

template <class T>
inline void qt_rectcopy(T *dest, const T *src,
                        int x, int y, int width, int height,
                        int dstStride, int srcStride)
{
    char *d = (char*)(dest + x) + y * dstStride;
    const char *s = (char*)(src);
    for (int i = 0; i < height; ++i) {
        ::memcpy(d, s, width * sizeof(T));
        d += dstStride;
        s += srcStride;
    }
}

template <class DST, class SRC>
inline void qt_rectconvert(DST *dest, const SRC *src,
                           int x, int y, int width, int height,
                           int dstStride, int srcStride)
{
    char *d = (char*)(dest + x) + y * dstStride;
    const char *s = (char*)(src);
    for (int i = 0; i < height; ++i) {
        qt_memconvert<DST,SRC>((DST*)d, (const SRC*)s, width);
        d += dstStride;
        s += srcStride;
    }
}

#define QT_RECTCONVERT_TRIVIAL_IMPL(T)                                  \
    template <>                                                         \
    inline void qt_rectconvert(T *dest, const T *src,                   \
                               int x, int y, int width, int height,     \
                               int dstStride, int srcStride)            \
    {                                                                   \
        qt_rectcopy(dest, src, x, y, width, height, dstStride, srcStride); \
    }
QT_RECTCONVERT_TRIVIAL_IMPL(quint32)
QT_RECTCONVERT_TRIVIAL_IMPL(qrgb888)
QT_RECTCONVERT_TRIVIAL_IMPL(qargb6666)
QT_RECTCONVERT_TRIVIAL_IMPL(qrgb666)
QT_RECTCONVERT_TRIVIAL_IMPL(qrgb565)
QT_RECTCONVERT_TRIVIAL_IMPL(qargb8565)
QT_RECTCONVERT_TRIVIAL_IMPL(quint16)
QT_RECTCONVERT_TRIVIAL_IMPL(qargb8555)
QT_RECTCONVERT_TRIVIAL_IMPL(qrgb555)
QT_RECTCONVERT_TRIVIAL_IMPL(qargb4444)
QT_RECTCONVERT_TRIVIAL_IMPL(qrgb444)
#undef QT_RECTCONVERT_TRIVIAL_IMPL

#define QT_MEMFILL_UINT(dest, length, color)            \
    qt_memfill<quint32>(dest, color, length);

#define QT_MEMFILL_USHORT(dest, length, color) \
    qt_memfill<quint16>(dest, color, length);

#define QT_MEMCPY_REV_UINT(dest, src, length) \
do {                                          \
    /* Duff's device */                       \
    uint *_d = (uint*)(dest) + length;         \
    const uint *_s = (uint*)(src) + length;    \
    int n = ((length) + 7) / 8;               \
    switch ((length) & 0x07)                  \
    {                                         \
    case 0: do { *--_d = *--_s;                 \
    case 7:      *--_d = *--_s;                 \
    case 6:      *--_d = *--_s;                 \
    case 5:      *--_d = *--_s;                 \
    case 4:      *--_d = *--_s;                 \
    case 3:      *--_d = *--_s;                 \
    case 2:      *--_d = *--_s;                 \
    case 1:      *--_d = *--_s;                 \
    } while (--n > 0);                        \
    }                                         \
} while (0)

#define QT_MEMCPY_USHORT(dest, src, length) \
do {                                          \
    /* Duff's device */                       \
    ushort *_d = (ushort*)(dest);         \
    const ushort *_s = (ushort*)(src);    \
    int n = ((length) + 7) / 8;               \
    switch ((length) & 0x07)                  \
    {                                         \
    case 0: do { *_d++ = *_s++;                 \
    case 7:      *_d++ = *_s++;                 \
    case 6:      *_d++ = *_s++;                 \
    case 5:      *_d++ = *_s++;                 \
    case 4:      *_d++ = *_s++;                 \
    case 3:      *_d++ = *_s++;                 \
    case 2:      *_d++ = *_s++;                 \
    case 1:      *_d++ = *_s++;                 \
    } while (--n > 0);                        \
    }                                         \
} while (0)

#if defined(Q_CC_RVCT)
#  pragma push
#  pragma arm
#endif
Q_STATIC_INLINE_FUNCTION int qt_div_255(int x) { return (x + (x>>8) + 0x80) >> 8; }
#if defined(Q_CC_RVCT)
#  pragma pop
#endif

inline ushort qConvertRgb32To16(uint c)
{
   return (((c) >> 3) & 0x001f)
       | (((c) >> 5) & 0x07e0)
       | (((c) >> 8) & 0xf800);
}

inline quint32 qConvertRgb32To16x2(quint64 c)
{
    c = (((c) >> 3) & Q_UINT64_C(0x001f0000001f))
        | (((c) >> 5) & Q_UINT64_C(0x07e0000007e0))
        | (((c) >> 8) & Q_UINT64_C(0xf8000000f800));
    return c | (c >> 16);
}

inline QRgb qConvertRgb16To32(uint c)
{
    return 0xff000000
        | ((((c) << 3) & 0xf8) | (((c) >> 2) & 0x7))
        | ((((c) << 5) & 0xfc00) | (((c) >> 1) & 0x300))
        | ((((c) << 8) & 0xf80000) | (((c) << 3) & 0x70000));
}

inline int qRed565(quint16 rgb) {
    const int r = (rgb & 0xf800);
    return (r >> 8) | (r >> 13);
}

inline int qGreen565(quint16 rgb) {
    const int g = (rgb & 0x07e0);
    return (g >> 3) | (g >> 9);
}

inline int qBlue565(quint16 rgb) {
    const int b = (rgb & 0x001f);
    return (b << 3) | (b >> 2);
}

const uint qt_bayer_matrix[16][16] = {
    { 0x1, 0xc0, 0x30, 0xf0, 0xc, 0xcc, 0x3c, 0xfc,
      0x3, 0xc3, 0x33, 0xf3, 0xf, 0xcf, 0x3f, 0xff},
    { 0x80, 0x40, 0xb0, 0x70, 0x8c, 0x4c, 0xbc, 0x7c,
      0x83, 0x43, 0xb3, 0x73, 0x8f, 0x4f, 0xbf, 0x7f},
    { 0x20, 0xe0, 0x10, 0xd0, 0x2c, 0xec, 0x1c, 0xdc,
      0x23, 0xe3, 0x13, 0xd3, 0x2f, 0xef, 0x1f, 0xdf},
    { 0xa0, 0x60, 0x90, 0x50, 0xac, 0x6c, 0x9c, 0x5c,
      0xa3, 0x63, 0x93, 0x53, 0xaf, 0x6f, 0x9f, 0x5f},
    { 0x8, 0xc8, 0x38, 0xf8, 0x4, 0xc4, 0x34, 0xf4,
      0xb, 0xcb, 0x3b, 0xfb, 0x7, 0xc7, 0x37, 0xf7},
    { 0x88, 0x48, 0xb8, 0x78, 0x84, 0x44, 0xb4, 0x74,
      0x8b, 0x4b, 0xbb, 0x7b, 0x87, 0x47, 0xb7, 0x77},
    { 0x28, 0xe8, 0x18, 0xd8, 0x24, 0xe4, 0x14, 0xd4,
      0x2b, 0xeb, 0x1b, 0xdb, 0x27, 0xe7, 0x17, 0xd7},
    { 0xa8, 0x68, 0x98, 0x58, 0xa4, 0x64, 0x94, 0x54,
      0xab, 0x6b, 0x9b, 0x5b, 0xa7, 0x67, 0x97, 0x57},
    { 0x2, 0xc2, 0x32, 0xf2, 0xe, 0xce, 0x3e, 0xfe,
      0x1, 0xc1, 0x31, 0xf1, 0xd, 0xcd, 0x3d, 0xfd},
    { 0x82, 0x42, 0xb2, 0x72, 0x8e, 0x4e, 0xbe, 0x7e,
      0x81, 0x41, 0xb1, 0x71, 0x8d, 0x4d, 0xbd, 0x7d},
    { 0x22, 0xe2, 0x12, 0xd2, 0x2e, 0xee, 0x1e, 0xde,
      0x21, 0xe1, 0x11, 0xd1, 0x2d, 0xed, 0x1d, 0xdd},
    { 0xa2, 0x62, 0x92, 0x52, 0xae, 0x6e, 0x9e, 0x5e,
      0xa1, 0x61, 0x91, 0x51, 0xad, 0x6d, 0x9d, 0x5d},
    { 0xa, 0xca, 0x3a, 0xfa, 0x6, 0xc6, 0x36, 0xf6,
      0x9, 0xc9, 0x39, 0xf9, 0x5, 0xc5, 0x35, 0xf5},
    { 0x8a, 0x4a, 0xba, 0x7a, 0x86, 0x46, 0xb6, 0x76,
      0x89, 0x49, 0xb9, 0x79, 0x85, 0x45, 0xb5, 0x75},
    { 0x2a, 0xea, 0x1a, 0xda, 0x26, 0xe6, 0x16, 0xd6,
      0x29, 0xe9, 0x19, 0xd9, 0x25, 0xe5, 0x15, 0xd5},
    { 0xaa, 0x6a, 0x9a, 0x5a, 0xa6, 0x66, 0x96, 0x56,
      0xa9, 0x69, 0x99, 0x59, 0xa5, 0x65, 0x95, 0x55}
};

#define ARGB_COMBINE_ALPHA(argb, alpha) \
    ((((argb >> 24) * alpha) >> 8) << 24) | (argb & 0x00ffffff)


#if QT_POINTER_SIZE == 8 // 64-bit versions
#define AMIX(mask) (qMin(((qint64(s)&mask) + (qint64(d)&mask)), qint64(mask)))
#define MIX(mask) (qMin(((qint64(s)&mask) + (qint64(d)&mask)), qint64(mask)))
#else // 32 bits
// The mask for alpha can overflow over 32 bits
#define AMIX(mask) quint32(qMin(((qint64(s)&mask) + (qint64(d)&mask)), qint64(mask)))
#define MIX(mask) (qMin(((quint32(s)&mask) + (quint32(d)&mask)), quint32(mask)))
#endif

inline int comp_func_Plus_one_pixel_const_alpha(uint d, const uint s, const uint const_alpha, const uint one_minus_const_alpha)
{
    const int result = (AMIX(AMASK) | MIX(RMASK) | MIX(GMASK) | MIX(BMASK));
    return INTERPOLATE_PIXEL_255(result, const_alpha, d, one_minus_const_alpha);
}

inline int comp_func_Plus_one_pixel(uint d, const uint s)
{
    const int result = (AMIX(AMASK) | MIX(RMASK) | MIX(GMASK) | MIX(BMASK));
    return result;
}

#undef MIX
#undef AMIX

// prototypes of all the composition functions
void QT_FASTCALL comp_func_SourceOver(uint *dest, const uint *src, int length, uint const_alpha);
void QT_FASTCALL comp_func_DestinationOver(uint *dest, const uint *src, int length, uint const_alpha);
void QT_FASTCALL comp_func_Clear(uint *dest, const uint *, int length, uint const_alpha);
void QT_FASTCALL comp_func_Source(uint *dest, const uint *src, int length, uint const_alpha);
void QT_FASTCALL comp_func_Destination(uint *, const uint *, int, uint);
void QT_FASTCALL comp_func_SourceIn(uint *dest, const uint *src, int length, uint const_alpha);
void QT_FASTCALL comp_func_DestinationIn(uint *dest, const uint *src, int length, uint const_alpha);
void QT_FASTCALL comp_func_SourceOut(uint *dest, const uint *src, int length, uint const_alpha);
void QT_FASTCALL comp_func_DestinationOut(uint *dest, const uint *src, int length, uint const_alpha);
void QT_FASTCALL comp_func_SourceAtop(uint *dest, const uint *src, int length, uint const_alpha);
void QT_FASTCALL comp_func_DestinationAtop(uint *dest, const uint *src, int length, uint const_alpha);
void QT_FASTCALL comp_func_XOR(uint *dest, const uint *src, int length, uint const_alpha);
void QT_FASTCALL comp_func_Plus(uint *dest, const uint *src, int length, uint const_alpha);
void QT_FASTCALL comp_func_Multiply(uint *dest, const uint *src, int length, uint const_alpha);
void QT_FASTCALL comp_func_Screen(uint *dest, const uint *src, int length, uint const_alpha);
void QT_FASTCALL comp_func_Overlay(uint *dest, const uint *src, int length, uint const_alpha);
void QT_FASTCALL comp_func_Darken(uint *dest, const uint *src, int length, uint const_alpha);
void QT_FASTCALL comp_func_Lighten(uint *dest, const uint *src, int length, uint const_alpha);
void QT_FASTCALL comp_func_ColorDodge(uint *dest, const uint *src, int length, uint const_alpha);
void QT_FASTCALL comp_func_ColorBurn(uint *dest, const uint *src, int length, uint const_alpha);
void QT_FASTCALL comp_func_HardLight(uint *dest, const uint *src, int length, uint const_alpha);
void QT_FASTCALL comp_func_SoftLight(uint *dest, const uint *src, int length, uint const_alpha);
void QT_FASTCALL comp_func_Difference(uint *dest, const uint *src, int length, uint const_alpha);
void QT_FASTCALL comp_func_Exclusion(uint *dest, const uint *src, int length, uint const_alpha);
void QT_FASTCALL rasterop_SourceOrDestination(uint *dest, const uint *src, int length, uint const_alpha);
void QT_FASTCALL rasterop_SourceAndDestination(uint *dest, const uint *src, int length, uint const_alpha);
void QT_FASTCALL rasterop_SourceXorDestination(uint *dest, const uint *src, int length, uint const_alpha);
void QT_FASTCALL rasterop_NotSourceAndNotDestination(uint *dest, const uint *src, int length, uint const_alpha);
void QT_FASTCALL rasterop_NotSourceOrNotDestination(uint *dest, const uint *src, int length, uint const_alpha);
void QT_FASTCALL rasterop_NotSourceXorDestination(uint *dest, const uint *src, int length, uint const_alpha);
void QT_FASTCALL rasterop_NotSource(uint *dest, const uint *src, int length, uint const_alpha);
void QT_FASTCALL rasterop_NotSourceAndDestination(uint *dest, const uint *src, int length, uint const_alpha);
void QT_FASTCALL rasterop_SourceAndNotDestination(uint *dest, const uint *src, int length, uint const_alpha);

// prototypes of all the solid composition functions
void QT_FASTCALL comp_func_solid_SourceOver(uint *dest, int length, uint color, uint const_alpha);
void QT_FASTCALL comp_func_solid_DestinationOver(uint *dest, int length, uint color, uint const_alpha);
void QT_FASTCALL comp_func_solid_Clear(uint *dest, int length, uint color, uint const_alpha);
void QT_FASTCALL comp_func_solid_Source(uint *dest, int length, uint color, uint const_alpha);
void QT_FASTCALL comp_func_solid_Destination(uint *dest, int length, uint color, uint const_alpha);
void QT_FASTCALL comp_func_solid_SourceIn(uint *dest, int length, uint color, uint const_alpha);
void QT_FASTCALL comp_func_solid_DestinationIn(uint *dest, int length, uint color, uint const_alpha);
void QT_FASTCALL comp_func_solid_SourceOut(uint *dest, int length, uint color, uint const_alpha);
void QT_FASTCALL comp_func_solid_DestinationOut(uint *dest, int length, uint color, uint const_alpha);
void QT_FASTCALL comp_func_solid_SourceAtop(uint *dest, int length, uint color, uint const_alpha);
void QT_FASTCALL comp_func_solid_DestinationAtop(uint *dest, int length, uint color, uint const_alpha);
void QT_FASTCALL comp_func_solid_XOR(uint *dest, int length, uint color, uint const_alpha);
void QT_FASTCALL comp_func_solid_Plus(uint *dest, int length, uint color, uint const_alpha);
void QT_FASTCALL comp_func_solid_Multiply(uint *dest, int length, uint color, uint const_alpha);
void QT_FASTCALL comp_func_solid_Screen(uint *dest, int length, uint color, uint const_alpha);
void QT_FASTCALL comp_func_solid_Overlay(uint *dest, int length, uint color, uint const_alpha);
void QT_FASTCALL comp_func_solid_Darken(uint *dest, int length, uint color, uint const_alpha);
void QT_FASTCALL comp_func_solid_Lighten(uint *dest, int length, uint color, uint const_alpha);
void QT_FASTCALL comp_func_solid_ColorDodge(uint *dest, int length, uint color, uint const_alpha);
void QT_FASTCALL comp_func_solid_ColorBurn(uint *dest, int length, uint color, uint const_alpha);
void QT_FASTCALL comp_func_solid_HardLight(uint *dest, int length, uint color, uint const_alpha);
void QT_FASTCALL comp_func_solid_SoftLight(uint *dest, int length, uint color, uint const_alpha);
void QT_FASTCALL comp_func_solid_Difference(uint *dest, int length, uint color, uint const_alpha);
void QT_FASTCALL comp_func_solid_Exclusion(uint *dest, int length, uint color, uint const_alpha);
void QT_FASTCALL rasterop_solid_SourceOrDestination(uint *dest, int length, uint color, uint const_alpha);
void QT_FASTCALL rasterop_solid_SourceAndDestination(uint *dest, int length, uint color, uint const_alpha);
void QT_FASTCALL rasterop_solid_SourceXorDestination(uint *dest, int length, uint color, uint const_alpha);
void QT_FASTCALL rasterop_solid_NotSourceAndNotDestination(uint *dest, int length, uint color, uint const_alpha);
void QT_FASTCALL rasterop_solid_NotSourceOrNotDestination(uint *dest, int length, uint color, uint const_alpha);
void QT_FASTCALL rasterop_solid_NotSourceXorDestination(uint *dest, int length, uint color, uint const_alpha);
void QT_FASTCALL rasterop_solid_NotSource(uint *dest, int length, uint color, uint const_alpha);
void QT_FASTCALL rasterop_solid_NotSourceAndDestination(uint *dest, int length, uint color, uint const_alpha);
void QT_FASTCALL rasterop_solid_SourceAndNotDestination(uint *dest, int length, uint color, uint const_alpha);

QT_END_NAMESPACE

#endif // QDRAWHELPER_P_H