/* * Copyright (c) 2002 Patrick Julien * Copyright (c) 2004 Boudewijn Rempt * Copyright (c) 2005 Adrian Page * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, * Boston, MA 02110-1301, USA. */ #include #include #include #include LCMS_HEADER #include #include #include #include "kis_rgb_f32_colorspace.h" #include "kis_color_conversions.h" namespace { const TQ_INT32 MAX_CHANNEL_RGB = 3; const TQ_INT32 MAX_CHANNEL_RGBA = 4; } #include "kis_integer_maths.h" #ifndef HAVE_POWF #undef powf #define powf pow #endif #define FLOAT_MAX 1.0f //temp #define EPSILON 1e-6 // FIXME: lcms doesn't support 32-bit float #define F32_LCMS_TYPE TYPE_BGRA_16 // disable the lcms handling by setting profile=0 KisRgbF32ColorSpace::KisRgbF32ColorSpace(KisColorSpaceFactoryRegistry * parent, KisProfile */*p*/) : KisF32BaseColorSpace(KisID("RGBAF32", i18n("RGB (32-bit float/channel)")), F32_LCMS_TYPE, icSigRgbData, parent, 0) { m_channels.push_back(new KisChannelInfo(i18n("Red"), i18n("R"), PIXEL_RED * sizeof(float), KisChannelInfo::COLOR, KisChannelInfo::FLOAT32, sizeof(float))); m_channels.push_back(new KisChannelInfo(i18n("Green"), i18n("G"), PIXEL_GREEN * sizeof(float), KisChannelInfo::COLOR, KisChannelInfo::FLOAT32, sizeof(float))); m_channels.push_back(new KisChannelInfo(i18n("Blue"), i18n("B"), PIXEL_BLUE * sizeof(float), KisChannelInfo::COLOR, KisChannelInfo::FLOAT32, sizeof(float))); m_channels.push_back(new KisChannelInfo(i18n("Alpha"), i18n("A"), PIXEL_ALPHA * sizeof(float), KisChannelInfo::ALPHA, KisChannelInfo::FLOAT32, sizeof(float))); m_alphaPos = PIXEL_ALPHA * sizeof(float); } KisRgbF32ColorSpace::~KisRgbF32ColorSpace() { } void KisRgbF32ColorSpace::setPixel(TQ_UINT8 *dst, float red, float green, float blue, float alpha) const { Pixel *dstPixel = reinterpret_cast(dst); dstPixel->red = red; dstPixel->green = green; dstPixel->blue = blue; dstPixel->alpha = alpha; } void KisRgbF32ColorSpace::getPixel(const TQ_UINT8 *src, float *red, float *green, float *blue, float *alpha) const { const Pixel *srcPixel = reinterpret_cast(src); *red = srcPixel->red; *green = srcPixel->green; *blue = srcPixel->blue; *alpha = srcPixel->alpha; } void KisRgbF32ColorSpace::fromTQColor(const TQColor& c, TQ_UINT8 *dstU8, KisProfile * /*profile*/) { Pixel *dst = reinterpret_cast(dstU8); dst->red = UINT8_TO_FLOAT(c.red()); dst->green = UINT8_TO_FLOAT(c.green()); dst->blue = UINT8_TO_FLOAT(c.blue()); } void KisRgbF32ColorSpace::fromTQColor(const TQColor& c, TQ_UINT8 opacity, TQ_UINT8 *dstU8, KisProfile * /*profile*/) { Pixel *dst = reinterpret_cast(dstU8); dst->red = UINT8_TO_FLOAT(c.red()); dst->green = UINT8_TO_FLOAT(c.green()); dst->blue = UINT8_TO_FLOAT(c.blue()); dst->alpha = UINT8_TO_FLOAT(opacity); } void KisRgbF32ColorSpace::toTQColor(const TQ_UINT8 *srcU8, TQColor *c, KisProfile * /*profile*/) { const Pixel *src = reinterpret_cast(srcU8); c->setRgb(FLOAT_TO_UINT8(src->red), FLOAT_TO_UINT8(src->green), FLOAT_TO_UINT8(src->blue)); } void KisRgbF32ColorSpace::toTQColor(const TQ_UINT8 *srcU8, TQColor *c, TQ_UINT8 *opacity, KisProfile * /*profile*/) { const Pixel *src = reinterpret_cast(srcU8); c->setRgb(FLOAT_TO_UINT8(src->red), FLOAT_TO_UINT8(src->green), FLOAT_TO_UINT8(src->blue)); *opacity = FLOAT_TO_UINT8(src->alpha); } TQ_UINT8 KisRgbF32ColorSpace::difference(const TQ_UINT8 *src1U8, const TQ_UINT8 *src2U8) { const Pixel *src1 = reinterpret_cast(src1U8); const Pixel *src2 = reinterpret_cast(src2U8); return FLOAT_TO_UINT8(TQMAX(TQABS(src2->red - src1->red), TQMAX(TQABS(src2->green - src1->green), TQABS(src2->blue - src1->blue)))); } void KisRgbF32ColorSpace::mixColors(const TQ_UINT8 **colors, const TQ_UINT8 *weights, TQ_UINT32 nColors, TQ_UINT8 *dst) const { float totalRed = 0, totalGreen = 0, totalBlue = 0, newAlpha = 0; while (nColors--) { const Pixel *pixel = reinterpret_cast(*colors); float alpha = pixel->alpha; float alphaTimesWeight = alpha * UINT8_TO_FLOAT(*weights); totalRed += pixel->red * alphaTimesWeight; totalGreen += pixel->green * alphaTimesWeight; totalBlue += pixel->blue * alphaTimesWeight; newAlpha += alphaTimesWeight; weights++; colors++; } Q_ASSERT(newAlpha <= F32_OPACITY_OPAQUE); Pixel *dstPixel = reinterpret_cast(dst); dstPixel->alpha = newAlpha; if (newAlpha > EPSILON) { totalRed = totalRed / newAlpha; totalGreen = totalGreen / newAlpha; totalBlue = totalBlue / newAlpha; } dstPixel->red = totalRed; dstPixel->green = totalGreen; dstPixel->blue = totalBlue; } void KisRgbF32ColorSpace::convolveColors(TQ_UINT8** colors, TQ_INT32 * kernelValues, KisChannelInfo::enumChannelFlags channelFlags, TQ_UINT8 *dst, TQ_INT32 factor, TQ_INT32 offset, TQ_INT32 nColors) const { float totalRed = 0, totalGreen = 0, totalBlue = 0, totalAlpha = 0; while (nColors--) { const Pixel * pixel = reinterpret_cast( *colors ); float weight = *kernelValues; if (weight != 0) { totalRed += pixel->red * weight; totalGreen += pixel->green * weight; totalBlue += pixel->blue * weight; totalAlpha += pixel->alpha * weight; } colors++; kernelValues++; } Pixel * p = reinterpret_cast< Pixel *>( dst ); if (channelFlags & KisChannelInfo::FLAG_COLOR) { p->red = CLAMP( ( totalRed / factor) + offset, 0, FLOAT_MAX); p->green = CLAMP( ( totalGreen / factor) + offset, 0, FLOAT_MAX); p->blue = CLAMP( ( totalBlue / factor) + offset, 0, FLOAT_MAX); } if (channelFlags & KisChannelInfo::FLAG_ALPHA) { p->alpha = CLAMP((totalAlpha/ factor) + offset, 0, FLOAT_MAX); } } void KisRgbF32ColorSpace::invertColor(TQ_UINT8 * src, TQ_INT32 nPixels) { TQ_UINT32 psize = pixelSize(); while (nPixels--) { Pixel * p = reinterpret_cast< Pixel *>( src ); p->red = FLOAT_MAX - p->red; p->green = FLOAT_MAX - p->green; p->blue = FLOAT_MAX - p->blue; src += psize; } } TQ_UINT8 KisRgbF32ColorSpace::intensity8(const TQ_UINT8 * src) const { const Pixel * p = reinterpret_cast( src ); return FLOAT_TO_UINT8((p->red * 0.30 + p->green * 0.59 + p->blue * 0.11) + 0.5); } TQValueVector KisRgbF32ColorSpace::channels() const { return m_channels; } TQ_UINT32 KisRgbF32ColorSpace::nChannels() const { return MAX_CHANNEL_RGBA; } TQ_UINT32 KisRgbF32ColorSpace::nColorChannels() const { return MAX_CHANNEL_RGB; } TQ_UINT32 KisRgbF32ColorSpace::pixelSize() const { return MAX_CHANNEL_RGBA * sizeof(float); } TQ_UINT8 convertToDisplay(float value, float exposureFactor, float gamma) { //value *= pow(2, exposure + 2.47393); value *= exposureFactor; value = powf(value, gamma); // scale middle gray to the target framebuffer value value *= 84.66f; int valueInt = (int)(value + 0.5); return CLAMP(valueInt, 0, 255); } TQImage KisRgbF32ColorSpace::convertToTQImage(const TQ_UINT8 *dataU8, TQ_INT32 width, TQ_INT32 height, KisProfile * /*dstProfile*/, TQ_INT32 /*renderingIntent*/, float exposure) { const float *data = reinterpret_cast(dataU8); TQImage img = TQImage(width, height, 32, 0, TQImage::LittleEndian); img.setAlphaBuffer(true); TQ_INT32 i = 0; uchar *j = img.bits(); // XXX: For now assume gamma 2.2. float gamma = 1 / 2.2; float exposureFactor = powf(2, exposure + 2.47393); while ( i < width * height * MAX_CHANNEL_RGBA) { *( j + 3) = FLOAT_TO_UINT8(*( data + i + PIXEL_ALPHA )); *( j + 2 ) = convertToDisplay(*( data + i + PIXEL_RED ), exposureFactor, gamma); *( j + 1 ) = convertToDisplay(*( data + i + PIXEL_GREEN ), exposureFactor, gamma); *( j + 0 ) = convertToDisplay(*( data + i + PIXEL_BLUE ), exposureFactor, gamma); i += MAX_CHANNEL_RGBA; j += MAX_CHANNEL_RGBA; } /* if (srcProfile != 0 && dstProfile != 0) { convertPixelsTo(img.bits(), srcProfile, img.bits(), this, dstProfile, width * height, renderingIntent); } */ return img; } void KisRgbF32ColorSpace::compositeOver(TQ_UINT8 *dstRowStart, TQ_INT32 dstRowStride, const TQ_UINT8 *srcRowStart, TQ_INT32 srcRowStride, const TQ_UINT8 *maskRowStart, TQ_INT32 maskRowStride, TQ_INT32 rows, TQ_INT32 numColumns, float opacity) { while (rows > 0) { const float *src = reinterpret_cast(srcRowStart); float *dst = reinterpret_cast(dstRowStart); const TQ_UINT8 *mask = maskRowStart; TQ_INT32 columns = numColumns; while (columns > 0) { float srcAlpha = src[PIXEL_ALPHA]; // apply the alphamask if (mask != 0) { TQ_UINT8 U8_mask = *mask; if (U8_mask != OPACITY_OPAQUE) { srcAlpha *= UINT8_TO_FLOAT(U8_mask); } mask++; } if (srcAlpha > F32_OPACITY_TRANSPARENT + EPSILON) { if (opacity < F32_OPACITY_OPAQUE - EPSILON) { srcAlpha *= opacity; } if (srcAlpha > F32_OPACITY_OPAQUE - EPSILON) { memcpy(dst, src, MAX_CHANNEL_RGBA * sizeof(float)); } else { float dstAlpha = dst[PIXEL_ALPHA]; float srcBlend; if (dstAlpha > F32_OPACITY_OPAQUE - EPSILON) { srcBlend = srcAlpha; } else { float newAlpha = dstAlpha + (F32_OPACITY_OPAQUE - dstAlpha) * srcAlpha; dst[PIXEL_ALPHA] = newAlpha; if (newAlpha > EPSILON) { srcBlend = srcAlpha / newAlpha; } else { srcBlend = srcAlpha; } } if (srcBlend > F32_OPACITY_OPAQUE - EPSILON) { memcpy(dst, src, MAX_CHANNEL_RGB * sizeof(float)); } else { dst[PIXEL_RED] = FLOAT_BLEND(src[PIXEL_RED], dst[PIXEL_RED], srcBlend); dst[PIXEL_GREEN] = FLOAT_BLEND(src[PIXEL_GREEN], dst[PIXEL_GREEN], srcBlend); dst[PIXEL_BLUE] = FLOAT_BLEND(src[PIXEL_BLUE], dst[PIXEL_BLUE], srcBlend); } } } columns--; src += MAX_CHANNEL_RGBA; dst += MAX_CHANNEL_RGBA; } rows--; srcRowStart += srcRowStride; dstRowStart += dstRowStride; if(maskRowStart) { maskRowStart += maskRowStride; } } } #define COMMON_COMPOSITE_OP_PROLOG() \ while (rows > 0) { \ \ const float *src = reinterpret_cast(srcRowStart); \ float *dst = reinterpret_cast(dstRowStart); \ TQ_INT32 columns = numColumns; \ const TQ_UINT8 *mask = maskRowStart; \ \ while (columns > 0) { \ \ float srcAlpha = src[PIXEL_ALPHA]; \ float dstAlpha = dst[PIXEL_ALPHA]; \ \ srcAlpha = TQMIN(srcAlpha, dstAlpha); \ \ if (mask != 0) { \ TQ_UINT8 U8_mask = *mask; \ \ if (U8_mask != OPACITY_OPAQUE) { \ srcAlpha *= UINT8_TO_FLOAT(U8_mask); \ } \ mask++; \ } \ \ if (srcAlpha > F32_OPACITY_TRANSPARENT + EPSILON) { \ \ if (opacity < F32_OPACITY_OPAQUE - EPSILON) { \ srcAlpha *= opacity; \ } \ \ float srcBlend; \ \ if (dstAlpha > F32_OPACITY_OPAQUE - EPSILON) { \ srcBlend = srcAlpha; \ } else { \ float newAlpha = dstAlpha + (F32_OPACITY_OPAQUE - dstAlpha) * srcAlpha; \ dst[PIXEL_ALPHA] = newAlpha; \ \ if (newAlpha > EPSILON) { \ srcBlend = srcAlpha / newAlpha; \ } else { \ srcBlend = srcAlpha; \ } \ } #define COMMON_COMPOSITE_OP_EPILOG() \ } \ \ columns--; \ src += MAX_CHANNEL_RGBA; \ dst += MAX_CHANNEL_RGBA; \ } \ \ rows--; \ srcRowStart += srcRowStride; \ dstRowStart += dstRowStride; \ if(maskRowStart) { \ maskRowStart += maskRowStride; \ } \ } void KisRgbF32ColorSpace::compositeMultiply(TQ_UINT8 *dstRowStart, TQ_INT32 dstRowStride, const TQ_UINT8 *srcRowStart, TQ_INT32 srcRowStride, const TQ_UINT8 *maskRowStart, TQ_INT32 maskRowStride, TQ_INT32 rows, TQ_INT32 numColumns, float opacity) { COMMON_COMPOSITE_OP_PROLOG(); { float srcColor = src[PIXEL_RED]; float dstColor = dst[PIXEL_RED]; srcColor = srcColor * dstColor; dst[PIXEL_RED] = FLOAT_BLEND(srcColor, dstColor, srcBlend); srcColor = src[PIXEL_GREEN]; dstColor = dst[PIXEL_GREEN]; srcColor = srcColor * dstColor; dst[PIXEL_GREEN] = FLOAT_BLEND(srcColor, dstColor, srcBlend); srcColor = src[PIXEL_BLUE]; dstColor = dst[PIXEL_BLUE]; srcColor = srcColor * dstColor; dst[PIXEL_BLUE] = FLOAT_BLEND(srcColor, dstColor, srcBlend); } COMMON_COMPOSITE_OP_EPILOG(); } void KisRgbF32ColorSpace::compositeDivide(TQ_UINT8 *dstRowStart, TQ_INT32 dstRowStride, const TQ_UINT8 *srcRowStart, TQ_INT32 srcRowStride, const TQ_UINT8 *maskRowStart, TQ_INT32 maskRowStride, TQ_INT32 rows, TQ_INT32 numColumns, float opacity) { COMMON_COMPOSITE_OP_PROLOG(); { for (int channel = 0; channel < MAX_CHANNEL_RGB; channel++) { float srcColor = src[channel]; float dstColor = dst[channel]; srcColor = TQMIN(dstColor / (srcColor + EPSILON), FLOAT_MAX); float newColor = FLOAT_BLEND(srcColor, dstColor, srcBlend); dst[channel] = newColor; } } COMMON_COMPOSITE_OP_EPILOG(); } void KisRgbF32ColorSpace::compositeScreen(TQ_UINT8 *dstRowStart, TQ_INT32 dstRowStride, const TQ_UINT8 *srcRowStart, TQ_INT32 srcRowStride, const TQ_UINT8 *maskRowStart, TQ_INT32 maskRowStride, TQ_INT32 rows, TQ_INT32 numColumns, float opacity) { COMMON_COMPOSITE_OP_PROLOG(); { for (int channel = 0; channel < MAX_CHANNEL_RGB; channel++) { float srcColor = src[channel]; float dstColor = dst[channel]; srcColor = FLOAT_MAX - ((FLOAT_MAX - dstColor) * (FLOAT_MAX - srcColor)); float newColor = FLOAT_BLEND(srcColor, dstColor, srcBlend); dst[channel] = newColor; } } COMMON_COMPOSITE_OP_EPILOG(); } void KisRgbF32ColorSpace::compositeOverlay(TQ_UINT8 *dstRowStart, TQ_INT32 dstRowStride, const TQ_UINT8 *srcRowStart, TQ_INT32 srcRowStride, const TQ_UINT8 *maskRowStart, TQ_INT32 maskRowStride, TQ_INT32 rows, TQ_INT32 numColumns, float opacity) { COMMON_COMPOSITE_OP_PROLOG(); { for (int channel = 0; channel < MAX_CHANNEL_RGB; channel++) { float srcColor = src[channel]; float dstColor = dst[channel]; srcColor = dstColor * (dstColor + 2 * (srcColor * (FLOAT_MAX - dstColor))); float newColor = FLOAT_BLEND(srcColor, dstColor, srcBlend); dst[channel] = newColor; } } COMMON_COMPOSITE_OP_EPILOG(); } void KisRgbF32ColorSpace::compositeDodge(TQ_UINT8 *dstRowStart, TQ_INT32 dstRowStride, const TQ_UINT8 *srcRowStart, TQ_INT32 srcRowStride, const TQ_UINT8 *maskRowStart, TQ_INT32 maskRowStride, TQ_INT32 rows, TQ_INT32 numColumns, float opacity) { COMMON_COMPOSITE_OP_PROLOG(); { for (int channel = 0; channel < MAX_CHANNEL_RGB; channel++) { float srcColor = src[channel]; float dstColor = dst[channel]; srcColor = TQMIN(dstColor / (FLOAT_MAX + EPSILON - srcColor), FLOAT_MAX); float newColor = FLOAT_BLEND(srcColor, dstColor, srcBlend); dst[channel] = newColor; } } COMMON_COMPOSITE_OP_EPILOG(); } void KisRgbF32ColorSpace::compositeBurn(TQ_UINT8 *dstRowStart, TQ_INT32 dstRowStride, const TQ_UINT8 *srcRowStart, TQ_INT32 srcRowStride, const TQ_UINT8 *maskRowStart, TQ_INT32 maskRowStride, TQ_INT32 rows, TQ_INT32 numColumns, float opacity) { COMMON_COMPOSITE_OP_PROLOG(); { for (int channel = 0; channel < MAX_CHANNEL_RGB; channel++) { float srcColor = src[channel]; float dstColor = dst[channel]; srcColor = TQMIN((FLOAT_MAX - dstColor) / (srcColor + EPSILON), FLOAT_MAX); srcColor = CLAMP(FLOAT_MAX - srcColor, 0, FLOAT_MAX); float newColor = FLOAT_BLEND(srcColor, dstColor, srcBlend); dst[channel] = newColor; } } COMMON_COMPOSITE_OP_EPILOG(); } void KisRgbF32ColorSpace::compositeDarken(TQ_UINT8 *dstRowStart, TQ_INT32 dstRowStride, const TQ_UINT8 *srcRowStart, TQ_INT32 srcRowStride, const TQ_UINT8 *maskRowStart, TQ_INT32 maskRowStride, TQ_INT32 rows, TQ_INT32 numColumns, float opacity) { COMMON_COMPOSITE_OP_PROLOG(); { for (int channel = 0; channel < MAX_CHANNEL_RGB; channel++) { float srcColor = src[channel]; float dstColor = dst[channel]; srcColor = TQMIN(srcColor, dstColor); float newColor = FLOAT_BLEND(srcColor, dstColor, srcBlend); dst[channel] = newColor; } } COMMON_COMPOSITE_OP_EPILOG(); } void KisRgbF32ColorSpace::compositeLighten(TQ_UINT8 *dstRowStart, TQ_INT32 dstRowStride, const TQ_UINT8 *srcRowStart, TQ_INT32 srcRowStride, const TQ_UINT8 *maskRowStart, TQ_INT32 maskRowStride, TQ_INT32 rows, TQ_INT32 numColumns, float opacity) { COMMON_COMPOSITE_OP_PROLOG(); { for (int channel = 0; channel < MAX_CHANNEL_RGB; channel++) { float srcColor = src[channel]; float dstColor = dst[channel]; srcColor = TQMAX(srcColor, dstColor); float newColor = FLOAT_BLEND(srcColor, dstColor, srcBlend); dst[channel] = newColor; } } COMMON_COMPOSITE_OP_EPILOG(); } void KisRgbF32ColorSpace::compositeHue(TQ_UINT8 *dstRowStart, TQ_INT32 dstRowStride, const TQ_UINT8 *srcRowStart, TQ_INT32 srcRowStride, const TQ_UINT8 *maskRowStart, TQ_INT32 maskRowStride, TQ_INT32 rows, TQ_INT32 numColumns, float opacity) { COMMON_COMPOSITE_OP_PROLOG(); { float srcRed = src[PIXEL_RED]; float srcGreen = src[PIXEL_GREEN]; float srcBlue = src[PIXEL_BLUE]; float dstRed = dst[PIXEL_RED]; float dstGreen = dst[PIXEL_GREEN]; float dstBlue = dst[PIXEL_BLUE]; float srcHue; float srcSaturation; float srcValue; float dstHue; float dstSaturation; float dstValue; RGBToHSV(srcRed, srcGreen, srcBlue, &srcHue, &srcSaturation, &srcValue); RGBToHSV(dstRed, dstGreen, dstBlue, &dstHue, &dstSaturation, &dstValue); HSVToRGB(srcHue, dstSaturation, dstValue, &srcRed, &srcGreen, &srcBlue); dst[PIXEL_RED] = FLOAT_BLEND(srcRed, dstRed, srcBlend); dst[PIXEL_GREEN] = FLOAT_BLEND(srcGreen, dstGreen, srcBlend); dst[PIXEL_BLUE] = FLOAT_BLEND(srcBlue, dstBlue, srcBlend); } COMMON_COMPOSITE_OP_EPILOG(); } void KisRgbF32ColorSpace::compositeSaturation(TQ_UINT8 *dstRowStart, TQ_INT32 dstRowStride, const TQ_UINT8 *srcRowStart, TQ_INT32 srcRowStride, const TQ_UINT8 *maskRowStart, TQ_INT32 maskRowStride, TQ_INT32 rows, TQ_INT32 numColumns, float opacity) { COMMON_COMPOSITE_OP_PROLOG(); { float srcRed = src[PIXEL_RED]; float srcGreen = src[PIXEL_GREEN]; float srcBlue = src[PIXEL_BLUE]; float dstRed = dst[PIXEL_RED]; float dstGreen = dst[PIXEL_GREEN]; float dstBlue = dst[PIXEL_BLUE]; float srcHue; float srcSaturation; float srcValue; float dstHue; float dstSaturation; float dstValue; RGBToHSV(srcRed, srcGreen, srcBlue, &srcHue, &srcSaturation, &srcValue); RGBToHSV(dstRed, dstGreen, dstBlue, &dstHue, &dstSaturation, &dstValue); HSVToRGB(dstHue, srcSaturation, dstValue, &srcRed, &srcGreen, &srcBlue); dst[PIXEL_RED] = FLOAT_BLEND(srcRed, dstRed, srcBlend); dst[PIXEL_GREEN] = FLOAT_BLEND(srcGreen, dstGreen, srcBlend); dst[PIXEL_BLUE] = FLOAT_BLEND(srcBlue, dstBlue, srcBlend); } COMMON_COMPOSITE_OP_EPILOG(); } void KisRgbF32ColorSpace::compositeValue(TQ_UINT8 *dstRowStart, TQ_INT32 dstRowStride, const TQ_UINT8 *srcRowStart, TQ_INT32 srcRowStride, const TQ_UINT8 *maskRowStart, TQ_INT32 maskRowStride, TQ_INT32 rows, TQ_INT32 numColumns, float opacity) { COMMON_COMPOSITE_OP_PROLOG(); { float srcRed = src[PIXEL_RED]; float srcGreen = src[PIXEL_GREEN]; float srcBlue = src[PIXEL_BLUE]; float dstRed = dst[PIXEL_RED]; float dstGreen = dst[PIXEL_GREEN]; float dstBlue = dst[PIXEL_BLUE]; float srcHue; float srcSaturation; float srcValue; float dstHue; float dstSaturation; float dstValue; RGBToHSV(srcRed, srcGreen, srcBlue, &srcHue, &srcSaturation, &srcValue); RGBToHSV(dstRed, dstGreen, dstBlue, &dstHue, &dstSaturation, &dstValue); HSVToRGB(dstHue, dstSaturation, srcValue, &srcRed, &srcGreen, &srcBlue); dst[PIXEL_RED] = FLOAT_BLEND(srcRed, dstRed, srcBlend); dst[PIXEL_GREEN] = FLOAT_BLEND(srcGreen, dstGreen, srcBlend); dst[PIXEL_BLUE] = FLOAT_BLEND(srcBlue, dstBlue, srcBlend); } COMMON_COMPOSITE_OP_EPILOG(); } void KisRgbF32ColorSpace::compositeColor(TQ_UINT8 *dstRowStart, TQ_INT32 dstRowStride, const TQ_UINT8 *srcRowStart, TQ_INT32 srcRowStride, const TQ_UINT8 *maskRowStart, TQ_INT32 maskRowStride, TQ_INT32 rows, TQ_INT32 numColumns, float opacity) { COMMON_COMPOSITE_OP_PROLOG(); { float srcRed = src[PIXEL_RED]; float srcGreen = src[PIXEL_GREEN]; float srcBlue = src[PIXEL_BLUE]; float dstRed = dst[PIXEL_RED]; float dstGreen = dst[PIXEL_GREEN]; float dstBlue = dst[PIXEL_BLUE]; float srcHue; float srcSaturation; float srcLightness; float dstHue; float dstSaturation; float dstLightness; RGBToHSL(srcRed, srcGreen, srcBlue, &srcHue, &srcSaturation, &srcLightness); RGBToHSL(dstRed, dstGreen, dstBlue, &dstHue, &dstSaturation, &dstLightness); HSLToRGB(srcHue, srcSaturation, dstLightness, &srcRed, &srcGreen, &srcBlue); dst[PIXEL_RED] = FLOAT_BLEND(srcRed, dstRed, srcBlend); dst[PIXEL_GREEN] = FLOAT_BLEND(srcGreen, dstGreen, srcBlend); dst[PIXEL_BLUE] = FLOAT_BLEND(srcBlue, dstBlue, srcBlend); } COMMON_COMPOSITE_OP_EPILOG(); } void KisRgbF32ColorSpace::compositeErase(TQ_UINT8 *dst, TQ_INT32 dstRowSize, const TQ_UINT8 *src, TQ_INT32 srcRowSize, const TQ_UINT8 *srcAlphaMask, TQ_INT32 maskRowStride, TQ_INT32 rows, TQ_INT32 cols, float /*opacity*/) { while (rows-- > 0) { const Pixel *s = reinterpret_cast(src); Pixel *d = reinterpret_cast(dst); const TQ_UINT8 *mask = srcAlphaMask; for (TQ_INT32 i = cols; i > 0; i--, s++, d++) { float srcAlpha = s->alpha; // apply the alphamask if (mask != 0) { TQ_UINT8 U8_mask = *mask; if (U8_mask != OPACITY_OPAQUE) { srcAlpha = FLOAT_BLEND(srcAlpha, F32_OPACITY_OPAQUE, UINT8_TO_FLOAT(U8_mask)); } mask++; } d->alpha = srcAlpha * d->alpha; } dst += dstRowSize; src += srcRowSize; if(srcAlphaMask) { srcAlphaMask += maskRowStride; } } } void KisRgbF32ColorSpace::bitBlt(TQ_UINT8 *dst, TQ_INT32 dstRowStride, const TQ_UINT8 *src, TQ_INT32 srcRowStride, const TQ_UINT8 *mask, TQ_INT32 maskRowStride, TQ_UINT8 U8_opacity, TQ_INT32 rows, TQ_INT32 cols, const KisCompositeOp& op) { float opacity = UINT8_TO_FLOAT(U8_opacity); switch (op.op()) { case COMPOSITE_UNDEF: // Undefined == no composition break; case COMPOSITE_OVER: compositeOver(dst, dstRowStride, src, srcRowStride, mask, maskRowStride, rows, cols, opacity); break; case COMPOSITE_IN: //compositeIn(pixelSize(), dst, dstRowStride, src, srcRowStride, rows, cols, opacity); case COMPOSITE_OUT: //compositeOut(pixelSize(), dst, dstRowStride, src, srcRowStride, rows, cols, opacity); break; case COMPOSITE_ATOP: //compositeAtop(pixelSize(), dst, dstRowStride, src, srcRowStride, rows, cols, opacity); break; case COMPOSITE_XOR: //compositeXor(pixelSize(), dst, dstRowStride, src, srcRowStride, rows, cols, opacity); break; case COMPOSITE_PLUS: //compositePlus(pixelSize(), dst, dstRowStride, src, srcRowStride, rows, cols, opacity); break; case COMPOSITE_MINUS: //compositeMinus(pixelSize(), dst, dstRowStride, src, srcRowStride, rows, cols, opacity); break; case COMPOSITE_ADD: //compositeAdd(pixelSize(), dst, dstRowStride, src, srcRowStride, rows, cols, opacity); break; case COMPOSITE_SUBTRACT: //compositeSubtract(pixelSize(), dst, dstRowStride, src, srcRowStride, rows, cols, opacity); break; case COMPOSITE_DIFF: //compositeDiff(pixelSize(), dst, dstRowStride, src, srcRowStride, rows, cols, opacity); break; case COMPOSITE_MULT: compositeMultiply(dst, dstRowStride, src, srcRowStride, mask, maskRowStride, rows, cols, opacity); break; case COMPOSITE_DIVIDE: compositeDivide(dst, dstRowStride, src, srcRowStride, mask, maskRowStride, rows, cols, opacity); break; case COMPOSITE_BUMPMAP: //compositeBumpmap(pixelSize(), dst, dstRowStride, src, srcRowStride, rows, cols, opacity); break; case COMPOSITE_COPY: compositeCopy(dst, dstRowStride, src, srcRowStride, mask, maskRowStride, rows, cols, U8_opacity); break; case COMPOSITE_COPY_RED: //compositeCopyRed(pixelSize(), dst, dstRowStride, src, srcRowStride, rows, cols, opacity); break; case COMPOSITE_COPY_GREEN: //compositeCopyGreen(pixelSize(), dst, dstRowStride, src, srcRowStride, rows, cols, opacity); break; case COMPOSITE_COPY_BLUE: //compositeCopyBlue(pixelSize(), dst, dstRowStride, src, srcRowStride, rows, cols, opacity); break; case COMPOSITE_COPY_OPACITY: //compositeCopyOpacity(pixelSize(), dst, dstRowStride, src, srcRowStride, rows, cols, opacity); break; case COMPOSITE_CLEAR: //compositeClear(pixelSize(), dst, dstRowStride, src, srcRowStride, rows, cols, opacity); break; case COMPOSITE_DISSOLVE: //compositeDissolve(pixelSize(), dst, dstRowStride, src, srcRowStride, rows, cols, opacity); break; case COMPOSITE_DISPLACE: //compositeDisplace(pixelSize(), dst, dstRowStride, src, srcRowStride, rows, cols, opacity); break; #if 0 case COMPOSITE_MODULATE: compositeModulate(pixelSize(), dst, dstRowStride, src, srcRowStride, rows, cols, opacity); break; case COMPOSITE_THRESHOLD: compositeThreshold(pixelSize(), dst, dstRowStride, src, srcRowStride, rows, cols, opacity); break; #endif case COMPOSITE_NO: // No composition. break; case COMPOSITE_DARKEN: compositeDarken(dst, dstRowStride, src, srcRowStride, mask, maskRowStride, rows, cols, opacity); break; case COMPOSITE_LIGHTEN: compositeLighten(dst, dstRowStride, src, srcRowStride, mask, maskRowStride, rows, cols, opacity); break; case COMPOSITE_HUE: compositeHue(dst, dstRowStride, src, srcRowStride, mask, maskRowStride, rows, cols, opacity); break; case COMPOSITE_SATURATION: compositeSaturation(dst, dstRowStride, src, srcRowStride, mask, maskRowStride, rows, cols, opacity); break; case COMPOSITE_VALUE: compositeValue(dst, dstRowStride, src, srcRowStride, mask, maskRowStride, rows, cols, opacity); break; case COMPOSITE_COLOR: compositeColor(dst, dstRowStride, src, srcRowStride, mask, maskRowStride, rows, cols, opacity); break; case COMPOSITE_COLORIZE: //compositeColorize(pixelSize(), dst, dstRowStride, src, srcRowStride, rows, cols, opacity); break; case COMPOSITE_LUMINIZE: //compositeLuminize(pixelSize(), dst, dstRowStride, src, srcRowStride, rows, cols, opacity); break; case COMPOSITE_SCREEN: compositeScreen(dst, dstRowStride, src, srcRowStride, mask, maskRowStride, rows, cols, opacity); break; case COMPOSITE_OVERLAY: compositeOverlay(dst, dstRowStride, src, srcRowStride, mask, maskRowStride, rows, cols, opacity); break; case COMPOSITE_ERASE: compositeErase(dst, dstRowStride, src, srcRowStride, mask, maskRowStride, rows, cols, opacity); break; case COMPOSITE_DODGE: compositeDodge(dst, dstRowStride, src, srcRowStride, mask, maskRowStride, rows, cols, opacity); break; case COMPOSITE_BURN: compositeBurn(dst, dstRowStride, src, srcRowStride, mask, maskRowStride, rows, cols, opacity); break; case COMPOSITE_ALPHA_DARKEN: abstractCompositeAlphaDarken( dst, dstRowStride, src, srcRowStride, mask, maskRowStride, rows, cols, U8_opacity, F32Mult(), Uint8ToF32(), F32OpacityTest()); default: break; } } KisCompositeOpList KisRgbF32ColorSpace::userVisiblecompositeOps() const { KisCompositeOpList list; list.append(KisCompositeOp(COMPOSITE_OVER)); list.append(KisCompositeOp(COMPOSITE_ALPHA_DARKEN)); list.append(KisCompositeOp(COMPOSITE_MULT)); list.append(KisCompositeOp(COMPOSITE_BURN)); list.append(KisCompositeOp(COMPOSITE_DODGE)); list.append(KisCompositeOp(COMPOSITE_DIVIDE)); list.append(KisCompositeOp(COMPOSITE_SCREEN)); list.append(KisCompositeOp(COMPOSITE_OVERLAY)); list.append(KisCompositeOp(COMPOSITE_DARKEN)); list.append(KisCompositeOp(COMPOSITE_LIGHTEN)); list.append(KisCompositeOp(COMPOSITE_HUE)); list.append(KisCompositeOp(COMPOSITE_SATURATION)); list.append(KisCompositeOp(COMPOSITE_VALUE)); list.append(KisCompositeOp(COMPOSITE_COLOR)); return list; }