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Diffstat (limited to 'src/3rdparty/angle/src/image_util/loadimage_etc.cpp')
| -rw-r--r-- | src/3rdparty/angle/src/image_util/loadimage_etc.cpp | 1729 |
1 files changed, 1729 insertions, 0 deletions
diff --git a/src/3rdparty/angle/src/image_util/loadimage_etc.cpp b/src/3rdparty/angle/src/image_util/loadimage_etc.cpp new file mode 100644 index 0000000000..67f73837c0 --- /dev/null +++ b/src/3rdparty/angle/src/image_util/loadimage_etc.cpp @@ -0,0 +1,1729 @@ +// +// Copyright (c) 2013-2015 The ANGLE Project Authors. All rights reserved. +// Use of this source code is governed by a BSD-style license that can be +// found in the LICENSE file. +// + +// loadimage_etc.cpp: Decodes ETC and EAC encoded textures. + +#include "image_util/loadimage.h" + +#include "common/mathutil.h" + +#include "image_util/imageformats.h" + +namespace angle +{ +namespace +{ + +using IntensityModifier = const int[4]; + +// Table 3.17.2 sorted according to table 3.17.3 +// clang-format off +static IntensityModifier intensityModifierDefault[] = +{ + { 2, 8, -2, -8 }, + { 5, 17, -5, -17 }, + { 9, 29, -9, -29 }, + { 13, 42, -13, -42 }, + { 18, 60, -18, -60 }, + { 24, 80, -24, -80 }, + { 33, 106, -33, -106 }, + { 47, 183, -47, -183 }, +}; +// clang-format on + +// Table C.12, intensity modifier for non opaque punchthrough alpha +// clang-format off +static IntensityModifier intensityModifierNonOpaque[] = +{ + { 0, 8, 0, -8 }, + { 0, 17, 0, -17 }, + { 0, 29, 0, -29 }, + { 0, 42, 0, -42 }, + { 0, 60, 0, -60 }, + { 0, 80, 0, -80 }, + { 0, 106, 0, -106 }, + { 0, 183, 0, -183 }, +}; +// clang-format on + +static const int kNumPixelsInBlock = 16; + +struct ETC2Block +{ + // Decodes unsigned single or dual channel block to bytes + void decodeAsSingleChannel(uint8_t *dest, + size_t x, + size_t y, + size_t w, + size_t h, + size_t destPixelStride, + size_t destRowPitch, + bool isSigned) const + { + for (size_t j = 0; j < 4 && (y + j) < h; j++) + { + uint8_t *row = dest + (j * destRowPitch); + for (size_t i = 0; i < 4 && (x + i) < w; i++) + { + uint8_t *pixel = row + (i * destPixelStride); + if (isSigned) + { + *pixel = clampSByte(getSingleChannel(i, j, isSigned)); + } + else + { + *pixel = clampByte(getSingleChannel(i, j, isSigned)); + } + } + } + } + + // Decodes RGB block to rgba8 + void decodeAsRGB(uint8_t *dest, + size_t x, + size_t y, + size_t w, + size_t h, + size_t destRowPitch, + const uint8_t alphaValues[4][4], + bool punchThroughAlpha) const + { + bool opaqueBit = u.idht.mode.idm.diffbit; + bool nonOpaquePunchThroughAlpha = punchThroughAlpha && !opaqueBit; + // Select mode + if (u.idht.mode.idm.diffbit || punchThroughAlpha) + { + const auto &block = u.idht.mode.idm.colors.diff; + int r = (block.R + block.dR); + int g = (block.G + block.dG); + int b = (block.B + block.dB); + if (r < 0 || r > 31) + { + decodeTBlock(dest, x, y, w, h, destRowPitch, alphaValues, + nonOpaquePunchThroughAlpha); + } + else if (g < 0 || g > 31) + { + decodeHBlock(dest, x, y, w, h, destRowPitch, alphaValues, + nonOpaquePunchThroughAlpha); + } + else if (b < 0 || b > 31) + { + decodePlanarBlock(dest, x, y, w, h, destRowPitch, alphaValues); + } + else + { + decodeDifferentialBlock(dest, x, y, w, h, destRowPitch, alphaValues, + nonOpaquePunchThroughAlpha); + } + } + else + { + decodeIndividualBlock(dest, x, y, w, h, destRowPitch, alphaValues, + nonOpaquePunchThroughAlpha); + } + } + + // Transcodes RGB block to BC1 + void transcodeAsBC1(uint8_t *dest, + size_t x, + size_t y, + size_t w, + size_t h, + const uint8_t alphaValues[4][4], + bool punchThroughAlpha) const + { + bool opaqueBit = u.idht.mode.idm.diffbit; + bool nonOpaquePunchThroughAlpha = punchThroughAlpha && !opaqueBit; + // Select mode + if (u.idht.mode.idm.diffbit || punchThroughAlpha) + { + const auto &block = u.idht.mode.idm.colors.diff; + int r = (block.R + block.dR); + int g = (block.G + block.dG); + int b = (block.B + block.dB); + if (r < 0 || r > 31) + { + transcodeTBlockToBC1(dest, x, y, w, h, alphaValues, nonOpaquePunchThroughAlpha); + } + else if (g < 0 || g > 31) + { + transcodeHBlockToBC1(dest, x, y, w, h, alphaValues, nonOpaquePunchThroughAlpha); + } + else if (b < 0 || b > 31) + { + transcodePlanarBlockToBC1(dest, x, y, w, h, alphaValues); + } + else + { + transcodeDifferentialBlockToBC1(dest, x, y, w, h, alphaValues, + nonOpaquePunchThroughAlpha); + } + } + else + { + transcodeIndividualBlockToBC1(dest, x, y, w, h, alphaValues, + nonOpaquePunchThroughAlpha); + } + } + + private: + union { + // Individual, differential, H and T modes + struct + { + union { + // Individual and differential modes + struct + { + union { + struct // Individual colors + { + unsigned char R2 : 4; + unsigned char R1 : 4; + unsigned char G2 : 4; + unsigned char G1 : 4; + unsigned char B2 : 4; + unsigned char B1 : 4; + } indiv; + struct // Differential colors + { + signed char dR : 3; + unsigned char R : 5; + signed char dG : 3; + unsigned char G : 5; + signed char dB : 3; + unsigned char B : 5; + } diff; + } colors; + bool flipbit : 1; + bool diffbit : 1; + unsigned char cw2 : 3; + unsigned char cw1 : 3; + } idm; + // T mode + struct + { + // Byte 1 + unsigned char TR1b : 2; + unsigned char TdummyB : 1; + unsigned char TR1a : 2; + unsigned char TdummyA : 3; + // Byte 2 + unsigned char TB1 : 4; + unsigned char TG1 : 4; + // Byte 3 + unsigned char TG2 : 4; + unsigned char TR2 : 4; + // Byte 4 + unsigned char Tdb : 1; + bool Tflipbit : 1; + unsigned char Tda : 2; + unsigned char TB2 : 4; + } tm; + // H mode + struct + { + // Byte 1 + unsigned char HG1a : 3; + unsigned char HR1 : 4; + unsigned char HdummyA : 1; + // Byte 2 + unsigned char HB1b : 2; + unsigned char HdummyC : 1; + unsigned char HB1a : 1; + unsigned char HG1b : 1; + unsigned char HdummyB : 3; + // Byte 3 + unsigned char HG2a : 3; + unsigned char HR2 : 4; + unsigned char HB1c : 1; + // Byte 4 + unsigned char Hdb : 1; + bool Hflipbit : 1; + unsigned char Hda : 1; + unsigned char HB2 : 4; + unsigned char HG2b : 1; + } hm; + } mode; + unsigned char pixelIndexMSB[2]; + unsigned char pixelIndexLSB[2]; + } idht; + // planar mode + struct + { + // Byte 1 + unsigned char GO1 : 1; + unsigned char RO : 6; + unsigned char PdummyA : 1; + // Byte 2 + unsigned char BO1 : 1; + unsigned char GO2 : 6; + unsigned char PdummyB : 1; + // Byte 3 + unsigned char BO3a : 2; + unsigned char PdummyD : 1; + unsigned char BO2 : 2; + unsigned char PdummyC : 3; + // Byte 4 + unsigned char RH2 : 1; + bool Pflipbit : 1; + unsigned char RH1 : 5; + unsigned char BO3b : 1; + // Byte 5 + unsigned char BHa : 1; + unsigned char GH : 7; + // Byte 6 + unsigned char RVa : 3; + unsigned char BHb : 5; + // Byte 7 + unsigned char GVa : 5; + unsigned char RVb : 3; + // Byte 8 + unsigned char BV : 6; + unsigned char GVb : 2; + } pblk; + // Single channel block + struct + { + union { + unsigned char us; + signed char s; + } base_codeword; + unsigned char table_index : 4; + unsigned char multiplier : 4; + unsigned char mc1 : 2; + unsigned char mb : 3; + unsigned char ma : 3; + unsigned char mf1 : 1; + unsigned char me : 3; + unsigned char md : 3; + unsigned char mc2 : 1; + unsigned char mh : 3; + unsigned char mg : 3; + unsigned char mf2 : 2; + unsigned char mk1 : 2; + unsigned char mj : 3; + unsigned char mi : 3; + unsigned char mn1 : 1; + unsigned char mm : 3; + unsigned char ml : 3; + unsigned char mk2 : 1; + unsigned char mp : 3; + unsigned char mo : 3; + unsigned char mn2 : 2; + } scblk; + } u; + + static unsigned char clampByte(int value) + { + return static_cast<unsigned char>(gl::clamp(value, 0, 255)); + } + + static signed char clampSByte(int value) + { + return static_cast<signed char>(gl::clamp(value, -128, 127)); + } + + static R8G8B8A8 createRGBA(int red, int green, int blue, int alpha) + { + R8G8B8A8 rgba; + rgba.R = clampByte(red); + rgba.G = clampByte(green); + rgba.B = clampByte(blue); + rgba.A = clampByte(alpha); + return rgba; + } + + static R8G8B8A8 createRGBA(int red, int green, int blue) + { + return createRGBA(red, green, blue, 255); + } + + static int extend_4to8bits(int x) { return (x << 4) | x; } + static int extend_5to8bits(int x) { return (x << 3) | (x >> 2); } + static int extend_6to8bits(int x) { return (x << 2) | (x >> 4); } + static int extend_7to8bits(int x) { return (x << 1) | (x >> 6); } + + void decodeIndividualBlock(uint8_t *dest, + size_t x, + size_t y, + size_t w, + size_t h, + size_t destRowPitch, + const uint8_t alphaValues[4][4], + bool nonOpaquePunchThroughAlpha) const + { + const auto &block = u.idht.mode.idm.colors.indiv; + int r1 = extend_4to8bits(block.R1); + int g1 = extend_4to8bits(block.G1); + int b1 = extend_4to8bits(block.B1); + int r2 = extend_4to8bits(block.R2); + int g2 = extend_4to8bits(block.G2); + int b2 = extend_4to8bits(block.B2); + decodeIndividualOrDifferentialBlock(dest, x, y, w, h, destRowPitch, r1, g1, b1, r2, g2, b2, + alphaValues, nonOpaquePunchThroughAlpha); + } + + void decodeDifferentialBlock(uint8_t *dest, + size_t x, + size_t y, + size_t w, + size_t h, + size_t destRowPitch, + const uint8_t alphaValues[4][4], + bool nonOpaquePunchThroughAlpha) const + { + const auto &block = u.idht.mode.idm.colors.diff; + int b1 = extend_5to8bits(block.B); + int g1 = extend_5to8bits(block.G); + int r1 = extend_5to8bits(block.R); + int r2 = extend_5to8bits(block.R + block.dR); + int g2 = extend_5to8bits(block.G + block.dG); + int b2 = extend_5to8bits(block.B + block.dB); + decodeIndividualOrDifferentialBlock(dest, x, y, w, h, destRowPitch, r1, g1, b1, r2, g2, b2, + alphaValues, nonOpaquePunchThroughAlpha); + } + + void decodeIndividualOrDifferentialBlock(uint8_t *dest, + size_t x, + size_t y, + size_t w, + size_t h, + size_t destRowPitch, + int r1, + int g1, + int b1, + int r2, + int g2, + int b2, + const uint8_t alphaValues[4][4], + bool nonOpaquePunchThroughAlpha) const + { + const IntensityModifier *intensityModifier = + nonOpaquePunchThroughAlpha ? intensityModifierNonOpaque : intensityModifierDefault; + + R8G8B8A8 subblockColors0[4]; + R8G8B8A8 subblockColors1[4]; + for (size_t modifierIdx = 0; modifierIdx < 4; modifierIdx++) + { + const int i1 = intensityModifier[u.idht.mode.idm.cw1][modifierIdx]; + subblockColors0[modifierIdx] = createRGBA(r1 + i1, g1 + i1, b1 + i1); + + const int i2 = intensityModifier[u.idht.mode.idm.cw2][modifierIdx]; + subblockColors1[modifierIdx] = createRGBA(r2 + i2, g2 + i2, b2 + i2); + } + + if (u.idht.mode.idm.flipbit) + { + uint8_t *curPixel = dest; + for (size_t j = 0; j < 2 && (y + j) < h; j++) + { + R8G8B8A8 *row = reinterpret_cast<R8G8B8A8 *>(curPixel); + for (size_t i = 0; i < 4 && (x + i) < w; i++) + { + row[i] = subblockColors0[getIndex(i, j)]; + row[i].A = alphaValues[j][i]; + } + curPixel += destRowPitch; + } + for (size_t j = 2; j < 4 && (y + j) < h; j++) + { + R8G8B8A8 *row = reinterpret_cast<R8G8B8A8 *>(curPixel); + for (size_t i = 0; i < 4 && (x + i) < w; i++) + { + row[i] = subblockColors1[getIndex(i, j)]; + row[i].A = alphaValues[j][i]; + } + curPixel += destRowPitch; + } + } + else + { + uint8_t *curPixel = dest; + for (size_t j = 0; j < 4 && (y + j) < h; j++) + { + R8G8B8A8 *row = reinterpret_cast<R8G8B8A8 *>(curPixel); + for (size_t i = 0; i < 2 && (x + i) < w; i++) + { + row[i] = subblockColors0[getIndex(i, j)]; + row[i].A = alphaValues[j][i]; + } + for (size_t i = 2; i < 4 && (x + i) < w; i++) + { + row[i] = subblockColors1[getIndex(i, j)]; + row[i].A = alphaValues[j][i]; + } + curPixel += destRowPitch; + } + } + if (nonOpaquePunchThroughAlpha) + { + decodePunchThroughAlphaBlock(dest, x, y, w, h, destRowPitch); + } + } + + void decodeTBlock(uint8_t *dest, + size_t x, + size_t y, + size_t w, + size_t h, + size_t destRowPitch, + const uint8_t alphaValues[4][4], + bool nonOpaquePunchThroughAlpha) const + { + // Table C.8, distance index for T and H modes + const auto &block = u.idht.mode.tm; + + int r1 = extend_4to8bits(block.TR1a << 2 | block.TR1b); + int g1 = extend_4to8bits(block.TG1); + int b1 = extend_4to8bits(block.TB1); + int r2 = extend_4to8bits(block.TR2); + int g2 = extend_4to8bits(block.TG2); + int b2 = extend_4to8bits(block.TB2); + + static int distance[8] = {3, 6, 11, 16, 23, 32, 41, 64}; + const int d = distance[block.Tda << 1 | block.Tdb]; + + const R8G8B8A8 paintColors[4] = { + createRGBA(r1, g1, b1), createRGBA(r2 + d, g2 + d, b2 + d), createRGBA(r2, g2, b2), + createRGBA(r2 - d, g2 - d, b2 - d), + }; + + uint8_t *curPixel = dest; + for (size_t j = 0; j < 4 && (y + j) < h; j++) + { + R8G8B8A8 *row = reinterpret_cast<R8G8B8A8 *>(curPixel); + for (size_t i = 0; i < 4 && (x + i) < w; i++) + { + row[i] = paintColors[getIndex(i, j)]; + row[i].A = alphaValues[j][i]; + } + curPixel += destRowPitch; + } + + if (nonOpaquePunchThroughAlpha) + { + decodePunchThroughAlphaBlock(dest, x, y, w, h, destRowPitch); + } + } + + void decodeHBlock(uint8_t *dest, + size_t x, + size_t y, + size_t w, + size_t h, + size_t destRowPitch, + const uint8_t alphaValues[4][4], + bool nonOpaquePunchThroughAlpha) const + { + // Table C.8, distance index for T and H modes + const auto &block = u.idht.mode.hm; + + int r1 = extend_4to8bits(block.HR1); + int g1 = extend_4to8bits(block.HG1a << 1 | block.HG1b); + int b1 = extend_4to8bits(block.HB1a << 3 | block.HB1b << 1 | block.HB1c); + int r2 = extend_4to8bits(block.HR2); + int g2 = extend_4to8bits(block.HG2a << 1 | block.HG2b); + int b2 = extend_4to8bits(block.HB2); + + static const int distance[8] = {3, 6, 11, 16, 23, 32, 41, 64}; + const int orderingTrickBit = + ((r1 << 16 | g1 << 8 | b1) >= (r2 << 16 | g2 << 8 | b2) ? 1 : 0); + const int d = distance[(block.Hda << 2) | (block.Hdb << 1) | orderingTrickBit]; + + const R8G8B8A8 paintColors[4] = { + createRGBA(r1 + d, g1 + d, b1 + d), createRGBA(r1 - d, g1 - d, b1 - d), + createRGBA(r2 + d, g2 + d, b2 + d), createRGBA(r2 - d, g2 - d, b2 - d), + }; + + uint8_t *curPixel = dest; + for (size_t j = 0; j < 4 && (y + j) < h; j++) + { + R8G8B8A8 *row = reinterpret_cast<R8G8B8A8 *>(curPixel); + for (size_t i = 0; i < 4 && (x + i) < w; i++) + { + row[i] = paintColors[getIndex(i, j)]; + row[i].A = alphaValues[j][i]; + } + curPixel += destRowPitch; + } + + if (nonOpaquePunchThroughAlpha) + { + decodePunchThroughAlphaBlock(dest, x, y, w, h, destRowPitch); + } + } + + void decodePlanarBlock(uint8_t *dest, + size_t x, + size_t y, + size_t w, + size_t h, + size_t pitch, + const uint8_t alphaValues[4][4]) const + { + int ro = extend_6to8bits(u.pblk.RO); + int go = extend_7to8bits(u.pblk.GO1 << 6 | u.pblk.GO2); + int bo = + extend_6to8bits(u.pblk.BO1 << 5 | u.pblk.BO2 << 3 | u.pblk.BO3a << 1 | u.pblk.BO3b); + int rh = extend_6to8bits(u.pblk.RH1 << 1 | u.pblk.RH2); + int gh = extend_7to8bits(u.pblk.GH); + int bh = extend_6to8bits(u.pblk.BHa << 5 | u.pblk.BHb); + int rv = extend_6to8bits(u.pblk.RVa << 3 | u.pblk.RVb); + int gv = extend_7to8bits(u.pblk.GVa << 2 | u.pblk.GVb); + int bv = extend_6to8bits(u.pblk.BV); + + uint8_t *curPixel = dest; + for (size_t j = 0; j < 4 && (y + j) < h; j++) + { + R8G8B8A8 *row = reinterpret_cast<R8G8B8A8 *>(curPixel); + + int ry = static_cast<int>(j) * (rv - ro) + 2; + int gy = static_cast<int>(j) * (gv - go) + 2; + int by = static_cast<int>(j) * (bv - bo) + 2; + for (size_t i = 0; i < 4 && (x + i) < w; i++) + { + row[i] = createRGBA(((static_cast<int>(i) * (rh - ro) + ry) >> 2) + ro, + ((static_cast<int>(i) * (gh - go) + gy) >> 2) + go, + ((static_cast<int>(i) * (bh - bo) + by) >> 2) + bo, + alphaValues[j][i]); + } + curPixel += pitch; + } + } + + // Index for individual, differential, H and T modes + size_t getIndex(size_t x, size_t y) const + { + size_t bitIndex = x * 4 + y; + size_t bitOffset = bitIndex & 7; + size_t lsb = (u.idht.pixelIndexLSB[1 - (bitIndex >> 3)] >> bitOffset) & 1; + size_t msb = (u.idht.pixelIndexMSB[1 - (bitIndex >> 3)] >> bitOffset) & 1; + return (msb << 1) | lsb; + } + + void decodePunchThroughAlphaBlock(uint8_t *dest, + size_t x, + size_t y, + size_t w, + size_t h, + size_t destRowPitch) const + { + uint8_t *curPixel = dest; + for (size_t j = 0; j < 4 && (y + j) < h; j++) + { + R8G8B8A8 *row = reinterpret_cast<R8G8B8A8 *>(curPixel); + for (size_t i = 0; i < 4 && (x + i) < w; i++) + { + if (getIndex(i, j) == 2) // msb == 1 && lsb == 0 + { + row[i] = createRGBA(0, 0, 0, 0); + } + } + curPixel += destRowPitch; + } + } + + uint16_t RGB8ToRGB565(const R8G8B8A8 &rgba) const + { + return (static_cast<uint16_t>(rgba.R >> 3) << 11) | + (static_cast<uint16_t>(rgba.G >> 2) << 5) | + (static_cast<uint16_t>(rgba.B >> 3) << 0); + } + + uint32_t matchBC1Bits(const int *pixelIndices, + const int *pixelIndexCounts, + const R8G8B8A8 *subblockColors, + size_t numColors, + const R8G8B8A8 &minColor, + const R8G8B8A8 &maxColor, + bool nonOpaquePunchThroughAlpha) const + { + // Project each pixel on the (maxColor, minColor) line to decide which + // BC1 code to assign to it. + + uint8_t decodedColors[2][3] = {{maxColor.R, maxColor.G, maxColor.B}, + {minColor.R, minColor.G, minColor.B}}; + + int direction[3]; + for (int ch = 0; ch < 3; ch++) + { + direction[ch] = decodedColors[0][ch] - decodedColors[1][ch]; + } + + int stops[2]; + for (int i = 0; i < 2; i++) + { + stops[i] = decodedColors[i][0] * direction[0] + decodedColors[i][1] * direction[1] + + decodedColors[i][2] * direction[2]; + } + + ASSERT(numColors <= kNumPixelsInBlock); + + int encodedColors[kNumPixelsInBlock]; + if (nonOpaquePunchThroughAlpha) + { + for (size_t i = 0; i < numColors; i++) + { + const int count = pixelIndexCounts[i]; + if (count > 0) + { + // In non-opaque mode, 3 is for tranparent pixels. + + if (0 == subblockColors[i].A) + { + encodedColors[i] = 3; + } + else + { + const R8G8B8A8 &pixel = subblockColors[i]; + const int dot = pixel.R * direction[0] + pixel.G * direction[1] + + pixel.B * direction[2]; + const int factor = gl::clamp( + static_cast<int>( + (static_cast<float>(dot - stops[1]) / (stops[0] - stops[1])) * 2 + + 0.5f), + 0, 2); + switch (factor) + { + case 0: + encodedColors[i] = 0; + break; + case 1: + encodedColors[i] = 2; + break; + case 2: + default: + encodedColors[i] = 1; + break; + } + } + } + } + } + else + { + for (size_t i = 0; i < numColors; i++) + { + const int count = pixelIndexCounts[i]; + if (count > 0) + { + // In opaque mode, the code is from 0 to 3. + + const R8G8B8A8 &pixel = subblockColors[i]; + const int dot = + pixel.R * direction[0] + pixel.G * direction[1] + pixel.B * direction[2]; + const int factor = gl::clamp( + static_cast<int>( + (static_cast<float>(dot - stops[1]) / (stops[0] - stops[1])) * 3 + + 0.5f), + 0, 3); + switch (factor) + { + case 0: + encodedColors[i] = 1; + break; + case 1: + encodedColors[i] = 3; + break; + case 2: + encodedColors[i] = 2; + break; + case 3: + default: + encodedColors[i] = 0; + break; + } + } + } + } + + uint32_t bits = 0; + for (int i = kNumPixelsInBlock - 1; i >= 0; i--) + { + bits <<= 2; + bits |= encodedColors[pixelIndices[i]]; + } + + return bits; + } + + void packBC1(void *bc1, + const int *pixelIndices, + const int *pixelIndexCounts, + const R8G8B8A8 *subblockColors, + size_t numColors, + int minColorIndex, + int maxColorIndex, + bool nonOpaquePunchThroughAlpha) const + { + const R8G8B8A8 &minColor = subblockColors[minColorIndex]; + const R8G8B8A8 &maxColor = subblockColors[maxColorIndex]; + + uint32_t bits; + uint16_t max16 = RGB8ToRGB565(maxColor); + uint16_t min16 = RGB8ToRGB565(minColor); + if (max16 != min16) + { + // Find the best BC1 code for each pixel + bits = matchBC1Bits(pixelIndices, pixelIndexCounts, subblockColors, numColors, minColor, + maxColor, nonOpaquePunchThroughAlpha); + } + else + { + // Same colors, BC1 index 0 is the color in both opaque and transparent mode + bits = 0; + // BC1 index 3 is transparent + if (nonOpaquePunchThroughAlpha) + { + for (int i = 0; i < kNumPixelsInBlock; i++) + { + if (0 == subblockColors[pixelIndices[i]].A) + { + bits |= (3 << (i * 2)); + } + } + } + } + + if (max16 < min16) + { + std::swap(max16, min16); + + uint32_t xorMask = 0; + if (nonOpaquePunchThroughAlpha) + { + // In transparent mode switching the colors is doing the + // following code swap: 0 <-> 1. 0xA selects the second bit of + // each code, bits >> 1 selects the first bit of the code when + // the seconds bit is set (case 2 and 3). We invert all the + // non-selected bits, that is the first bit when the code is + // 0 or 1. + xorMask = ~((bits >> 1) | 0xAAAAAAAA); + } + else + { + // In opaque mode switching the two colors is doing the + // following code swaps: 0 <-> 1 and 2 <-> 3. This is + // equivalent to flipping the first bit of each code + // (5 = 0b0101) + xorMask = 0x55555555; + } + bits ^= xorMask; + } + + struct BC1Block + { + uint16_t color0; + uint16_t color1; + uint32_t bits; + }; + + // Encode the opaqueness in the order of the two BC1 colors + BC1Block *dest = reinterpret_cast<BC1Block *>(bc1); + if (nonOpaquePunchThroughAlpha) + { + dest->color0 = min16; + dest->color1 = max16; + } + else + { + dest->color0 = max16; + dest->color1 = min16; + } + dest->bits = bits; + } + + void transcodeIndividualBlockToBC1(uint8_t *dest, + size_t x, + size_t y, + size_t w, + size_t h, + const uint8_t alphaValues[4][4], + bool nonOpaquePunchThroughAlpha) const + { + const auto &block = u.idht.mode.idm.colors.indiv; + int r1 = extend_4to8bits(block.R1); + int g1 = extend_4to8bits(block.G1); + int b1 = extend_4to8bits(block.B1); + int r2 = extend_4to8bits(block.R2); + int g2 = extend_4to8bits(block.G2); + int b2 = extend_4to8bits(block.B2); + transcodeIndividualOrDifferentialBlockToBC1(dest, x, y, w, h, r1, g1, b1, r2, g2, b2, + alphaValues, nonOpaquePunchThroughAlpha); + } + + void transcodeDifferentialBlockToBC1(uint8_t *dest, + size_t x, + size_t y, + size_t w, + size_t h, + const uint8_t alphaValues[4][4], + bool nonOpaquePunchThroughAlpha) const + { + const auto &block = u.idht.mode.idm.colors.diff; + int b1 = extend_5to8bits(block.B); + int g1 = extend_5to8bits(block.G); + int r1 = extend_5to8bits(block.R); + int r2 = extend_5to8bits(block.R + block.dR); + int g2 = extend_5to8bits(block.G + block.dG); + int b2 = extend_5to8bits(block.B + block.dB); + transcodeIndividualOrDifferentialBlockToBC1(dest, x, y, w, h, r1, g1, b1, r2, g2, b2, + alphaValues, nonOpaquePunchThroughAlpha); + } + + void extractPixelIndices(int *pixelIndices, + int *pixelIndicesCounts, + size_t x, + size_t y, + size_t w, + size_t h, + bool flipbit, + size_t subblockIdx) const + { + size_t dxBegin = 0; + size_t dxEnd = 4; + size_t dyBegin = subblockIdx * 2; + size_t dyEnd = dyBegin + 2; + if (!flipbit) + { + std::swap(dxBegin, dyBegin); + std::swap(dxEnd, dyEnd); + } + + for (size_t j = dyBegin; j < dyEnd; j++) + { + int *row = &pixelIndices[j * 4]; + for (size_t i = dxBegin; i < dxEnd; i++) + { + const size_t pixelIndex = subblockIdx * 4 + getIndex(i, j); + row[i] = static_cast<int>(pixelIndex); + pixelIndicesCounts[pixelIndex]++; + } + } + } + + void selectEndPointPCA(const int *pixelIndexCounts, + const R8G8B8A8 *subblockColors, + size_t numColors, + int *minColorIndex, + int *maxColorIndex) const + { + // determine color distribution + int mu[3], min[3], max[3]; + for (int ch = 0; ch < 3; ch++) + { + int muv = 0; + int minv = 255; + int maxv = 0; + for (size_t i = 0; i < numColors; i++) + { + const int count = pixelIndexCounts[i]; + if (count > 0) + { + const auto &pixel = subblockColors[i]; + if (pixel.A > 0) + { + // Non-transparent pixels + muv += (&pixel.R)[ch] * count; + minv = std::min<int>(minv, (&pixel.R)[ch]); + maxv = std::max<int>(maxv, (&pixel.R)[ch]); + } + } + } + + mu[ch] = (muv + kNumPixelsInBlock / 2) / kNumPixelsInBlock; + min[ch] = minv; + max[ch] = maxv; + } + + // determine covariance matrix + int cov[6] = {0, 0, 0, 0, 0, 0}; + for (size_t i = 0; i < numColors; i++) + { + const int count = pixelIndexCounts[i]; + if (count > 0) + { + const auto &pixel = subblockColors[i]; + if (pixel.A > 0) + { + int r = pixel.R - mu[0]; + int g = pixel.G - mu[1]; + int b = pixel.B - mu[2]; + + cov[0] += r * r * count; + cov[1] += r * g * count; + cov[2] += r * b * count; + cov[3] += g * g * count; + cov[4] += g * b * count; + cov[5] += b * b * count; + } + } + } + + // Power iteration algorithm to get the eigenvalues and eigenvector + + // Starts with diagonal vector + float vfr = static_cast<float>(max[0] - min[0]); + float vfg = static_cast<float>(max[1] - min[1]); + float vfb = static_cast<float>(max[2] - min[2]); + float eigenvalue; + + static const size_t kPowerIterations = 4; + for (size_t i = 0; i < kPowerIterations; i++) + { + float r = vfr * cov[0] + vfg * cov[1] + vfb * cov[2]; + float g = vfr * cov[1] + vfg * cov[3] + vfb * cov[4]; + float b = vfr * cov[2] + vfg * cov[4] + vfb * cov[5]; + + vfr = r; + vfg = g; + vfb = b; + + eigenvalue = sqrt(r * r + g * g + b * b); + if (eigenvalue > 0) + { + float invNorm = 1.0f / eigenvalue; + vfr *= invNorm; + vfg *= invNorm; + vfb *= invNorm; + } + } + + int vr, vg, vb; + + static const float kDefaultLuminanceThreshold = 4.0f * 255; + static const float kQuantizeRange = 512.0f; + if (eigenvalue < kDefaultLuminanceThreshold) // too small, default to luminance + { + // Luminance weights defined by ITU-R Recommendation BT.601, scaled by 1000 + vr = 299; + vg = 587; + vb = 114; + } + else + { + // From the eigenvalue and eigenvector, choose the axis to project + // colors on. When projecting colors we want to do integer computations + // for speed, so we normalize the eigenvector to the [0, 512] range. + float magn = std::max(std::max(std::abs(vfr), std::abs(vfg)), std::abs(vfb)); + magn = kQuantizeRange / magn; + vr = static_cast<int>(vfr * magn); + vg = static_cast<int>(vfg * magn); + vb = static_cast<int>(vfb * magn); + } + + // Pick colors at extreme points + int minD = INT_MAX; + int maxD = 0; + size_t minIndex = 0; + size_t maxIndex = 0; + for (size_t i = 0; i < numColors; i++) + { + const int count = pixelIndexCounts[i]; + if (count > 0) + { + const auto &pixel = subblockColors[i]; + if (pixel.A > 0) + { + int dot = pixel.R * vr + pixel.G * vg + pixel.B * vb; + if (dot < minD) + { + minD = dot; + minIndex = i; + } + if (dot > maxD) + { + maxD = dot; + maxIndex = i; + } + } + } + } + + *minColorIndex = static_cast<int>(minIndex); + *maxColorIndex = static_cast<int>(maxIndex); + } + + void transcodeIndividualOrDifferentialBlockToBC1(uint8_t *dest, + size_t x, + size_t y, + size_t w, + size_t h, + int r1, + int g1, + int b1, + int r2, + int g2, + int b2, + const uint8_t alphaValues[4][4], + bool nonOpaquePunchThroughAlpha) const + { + // A BC1 block has 2 endpoints, pixels is encoded as linear + // interpolations of them. A ETC1/ETC2 individual or differential block + // has 2 subblocks. Each subblock has one color and a modifier. We + // select axis by principal component analysis (PCA) to use as + // our two BC1 endpoints and then map pixels to BC1 by projecting on the + // line between the two endpoints and choosing the right fraction. + + // The goal of this algorithm is make it faster than decode ETC to RGBs + // and then encode to BC. To achieve this, we only extract subblock + // colors, pixel indices, and counts of each pixel indices from ETC. + // With those information, we can only encode used subblock colors + // to BC1, and copy the bits to the right pixels. + // Fully decode and encode need to process 16 RGBA pixels. With this + // algorithm, it's 8 pixels at maximum for a individual or + // differential block. Saves us bandwidth and computations. + + static const size_t kNumColors = 8; + + const IntensityModifier *intensityModifier = + nonOpaquePunchThroughAlpha ? intensityModifierNonOpaque : intensityModifierDefault; + + // Compute the colors that pixels can have in each subblock both for + // the decoding of the RGBA data and BC1 encoding + R8G8B8A8 subblockColors[kNumColors]; + for (size_t modifierIdx = 0; modifierIdx < 4; modifierIdx++) + { + if (nonOpaquePunchThroughAlpha && (modifierIdx == 2)) + { + // In ETC opaque punch through formats, individual and + // differential blocks take index 2 as transparent pixel. + // Thus we don't need to compute its color, just assign it + // as black. + subblockColors[modifierIdx] = createRGBA(0, 0, 0, 0); + subblockColors[4 + modifierIdx] = createRGBA(0, 0, 0, 0); + } + else + { + const int i1 = intensityModifier[u.idht.mode.idm.cw1][modifierIdx]; + subblockColors[modifierIdx] = createRGBA(r1 + i1, g1 + i1, b1 + i1); + + const int i2 = intensityModifier[u.idht.mode.idm.cw2][modifierIdx]; + subblockColors[4 + modifierIdx] = createRGBA(r2 + i2, g2 + i2, b2 + i2); + } + } + + int pixelIndices[kNumPixelsInBlock]; + int pixelIndexCounts[kNumColors] = {0}; + // Extract pixel indices from a ETC block. + for (size_t blockIdx = 0; blockIdx < 2; blockIdx++) + { + extractPixelIndices(pixelIndices, pixelIndexCounts, x, y, w, h, u.idht.mode.idm.flipbit, + blockIdx); + } + + int minColorIndex, maxColorIndex; + selectEndPointPCA(pixelIndexCounts, subblockColors, kNumColors, &minColorIndex, + &maxColorIndex); + + packBC1(dest, pixelIndices, pixelIndexCounts, subblockColors, kNumColors, minColorIndex, + maxColorIndex, nonOpaquePunchThroughAlpha); + } + + void transcodeTBlockToBC1(uint8_t *dest, + size_t x, + size_t y, + size_t w, + size_t h, + const uint8_t alphaValues[4][4], + bool nonOpaquePunchThroughAlpha) const + { + static const size_t kNumColors = 4; + + // Table C.8, distance index for T and H modes + const auto &block = u.idht.mode.tm; + + int r1 = extend_4to8bits(block.TR1a << 2 | block.TR1b); + int g1 = extend_4to8bits(block.TG1); + int b1 = extend_4to8bits(block.TB1); + int r2 = extend_4to8bits(block.TR2); + int g2 = extend_4to8bits(block.TG2); + int b2 = extend_4to8bits(block.TB2); + + static int distance[8] = {3, 6, 11, 16, 23, 32, 41, 64}; + const int d = distance[block.Tda << 1 | block.Tdb]; + + // In ETC opaque punch through formats, index == 2 means transparent pixel. + // Thus we don't need to compute its color, just assign it as black. + const R8G8B8A8 paintColors[kNumColors] = { + createRGBA(r1, g1, b1), createRGBA(r2 + d, g2 + d, b2 + d), + nonOpaquePunchThroughAlpha ? createRGBA(0, 0, 0, 0) : createRGBA(r2, g2, b2), + createRGBA(r2 - d, g2 - d, b2 - d), + }; + + int pixelIndices[kNumPixelsInBlock]; + int pixelIndexCounts[kNumColors] = {0}; + for (size_t j = 0; j < 4; j++) + { + int *row = &pixelIndices[j * 4]; + for (size_t i = 0; i < 4; i++) + { + const size_t pixelIndex = getIndex(i, j); + row[i] = static_cast<int>(pixelIndex); + pixelIndexCounts[pixelIndex]++; + } + } + + int minColorIndex, maxColorIndex; + selectEndPointPCA(pixelIndexCounts, paintColors, kNumColors, &minColorIndex, + &maxColorIndex); + + packBC1(dest, pixelIndices, pixelIndexCounts, paintColors, kNumColors, minColorIndex, + maxColorIndex, nonOpaquePunchThroughAlpha); + } + + void transcodeHBlockToBC1(uint8_t *dest, + size_t x, + size_t y, + size_t w, + size_t h, + const uint8_t alphaValues[4][4], + bool nonOpaquePunchThroughAlpha) const + { + static const size_t kNumColors = 4; + + // Table C.8, distance index for T and H modes + const auto &block = u.idht.mode.hm; + + int r1 = extend_4to8bits(block.HR1); + int g1 = extend_4to8bits(block.HG1a << 1 | block.HG1b); + int b1 = extend_4to8bits(block.HB1a << 3 | block.HB1b << 1 | block.HB1c); + int r2 = extend_4to8bits(block.HR2); + int g2 = extend_4to8bits(block.HG2a << 1 | block.HG2b); + int b2 = extend_4to8bits(block.HB2); + + static const int distance[8] = {3, 6, 11, 16, 23, 32, 41, 64}; + const int orderingTrickBit = + ((r1 << 16 | g1 << 8 | b1) >= (r2 << 16 | g2 << 8 | b2) ? 1 : 0); + const int d = distance[(block.Hda << 2) | (block.Hdb << 1) | orderingTrickBit]; + + // In ETC opaque punch through formats, index == 2 means transparent pixel. + // Thus we don't need to compute its color, just assign it as black. + const R8G8B8A8 paintColors[kNumColors] = { + createRGBA(r1 + d, g1 + d, b1 + d), createRGBA(r1 - d, g1 - d, b1 - d), + nonOpaquePunchThroughAlpha ? createRGBA(0, 0, 0, 0) + : createRGBA(r2 + d, g2 + d, b2 + d), + createRGBA(r2 - d, g2 - d, b2 - d), + }; + + int pixelIndices[kNumPixelsInBlock]; + int pixelIndexCounts[kNumColors] = {0}; + for (size_t j = 0; j < 4; j++) + { + int *row = &pixelIndices[j * 4]; + for (size_t i = 0; i < 4; i++) + { + const size_t pixelIndex = getIndex(i, j); + row[i] = static_cast<int>(pixelIndex); + pixelIndexCounts[pixelIndex]++; + } + } + + int minColorIndex, maxColorIndex; + selectEndPointPCA(pixelIndexCounts, paintColors, kNumColors, &minColorIndex, + &maxColorIndex); + + packBC1(dest, pixelIndices, pixelIndexCounts, paintColors, kNumColors, minColorIndex, + maxColorIndex, nonOpaquePunchThroughAlpha); + } + + void transcodePlanarBlockToBC1(uint8_t *dest, + size_t x, + size_t y, + size_t w, + size_t h, + const uint8_t alphaValues[4][4]) const + { + static const size_t kNumColors = kNumPixelsInBlock; + + R8G8B8A8 rgbaBlock[kNumColors]; + decodePlanarBlock(reinterpret_cast<uint8_t *>(rgbaBlock), x, y, w, h, sizeof(R8G8B8A8) * 4, + alphaValues); + + // Planar block doesn't have a color table, fill indices as full + int pixelIndices[kNumPixelsInBlock] = {0, 1, 2, 3, 4, 5, 6, 7, + 8, 9, 10, 11, 12, 13, 14, 15}; + int pixelIndexCounts[kNumColors] = {1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1}; + + int minColorIndex, maxColorIndex; + selectEndPointPCA(pixelIndexCounts, rgbaBlock, kNumColors, &minColorIndex, &maxColorIndex); + + packBC1(dest, pixelIndices, pixelIndexCounts, rgbaBlock, kNumColors, minColorIndex, + maxColorIndex, false); + } + + // Single channel utility functions + int getSingleChannel(size_t x, size_t y, bool isSigned) const + { + int codeword = isSigned ? u.scblk.base_codeword.s : u.scblk.base_codeword.us; + return codeword + getSingleChannelModifier(x, y) * u.scblk.multiplier; + } + + int getSingleChannelIndex(size_t x, size_t y) const + { + ASSERT(x < 4 && y < 4); + + // clang-format off + switch (x * 4 + y) + { + case 0: return u.scblk.ma; + case 1: return u.scblk.mb; + case 2: return u.scblk.mc1 << 1 | u.scblk.mc2; + case 3: return u.scblk.md; + case 4: return u.scblk.me; + case 5: return u.scblk.mf1 << 2 | u.scblk.mf2; + case 6: return u.scblk.mg; + case 7: return u.scblk.mh; + case 8: return u.scblk.mi; + case 9: return u.scblk.mj; + case 10: return u.scblk.mk1 << 1 | u.scblk.mk2; + case 11: return u.scblk.ml; + case 12: return u.scblk.mm; + case 13: return u.scblk.mn1 << 2 | u.scblk.mn2; + case 14: return u.scblk.mo; + case 15: return u.scblk.mp; + default: UNREACHABLE(); return 0; + } + // clang-format on + } + + int getSingleChannelModifier(size_t x, size_t y) const + { + // clang-format off + static const int modifierTable[16][8] = + { + { -3, -6, -9, -15, 2, 5, 8, 14 }, + { -3, -7, -10, -13, 2, 6, 9, 12 }, + { -2, -5, -8, -13, 1, 4, 7, 12 }, + { -2, -4, -6, -13, 1, 3, 5, 12 }, + { -3, -6, -8, -12, 2, 5, 7, 11 }, + { -3, -7, -9, -11, 2, 6, 8, 10 }, + { -4, -7, -8, -11, 3, 6, 7, 10 }, + { -3, -5, -8, -11, 2, 4, 7, 10 }, + { -2, -6, -8, -10, 1, 5, 7, 9 }, + { -2, -5, -8, -10, 1, 4, 7, 9 }, + { -2, -4, -8, -10, 1, 3, 7, 9 }, + { -2, -5, -7, -10, 1, 4, 6, 9 }, + { -3, -4, -7, -10, 2, 3, 6, 9 }, + { -1, -2, -3, -10, 0, 1, 2, 9 }, + { -4, -6, -8, -9, 3, 5, 7, 8 }, + { -3, -5, -7, -9, 2, 4, 6, 8 } + }; + // clang-format on + + return modifierTable[u.scblk.table_index][getSingleChannelIndex(x, y)]; + } +}; + +// clang-format off +static const uint8_t DefaultETCAlphaValues[4][4] = +{ + { 255, 255, 255, 255 }, + { 255, 255, 255, 255 }, + { 255, 255, 255, 255 }, + { 255, 255, 255, 255 }, +}; +// clang-format on + +void LoadR11EACToR8(size_t width, + size_t height, + size_t depth, + const uint8_t *input, + size_t inputRowPitch, + size_t inputDepthPitch, + uint8_t *output, + size_t outputRowPitch, + size_t outputDepthPitch, + bool isSigned) +{ + for (size_t z = 0; z < depth; z++) + { + for (size_t y = 0; y < height; y += 4) + { + const ETC2Block *sourceRow = + priv::OffsetDataPointer<ETC2Block>(input, y / 4, z, inputRowPitch, inputDepthPitch); + uint8_t *destRow = + priv::OffsetDataPointer<uint8_t>(output, y, z, outputRowPitch, outputDepthPitch); + + for (size_t x = 0; x < width; x += 4) + { + const ETC2Block *sourceBlock = sourceRow + (x / 4); + uint8_t *destPixels = destRow + x; + + sourceBlock->decodeAsSingleChannel(destPixels, x, y, width, height, 1, + outputRowPitch, isSigned); + } + } + } +} + +void LoadRG11EACToRG8(size_t width, + size_t height, + size_t depth, + const uint8_t *input, + size_t inputRowPitch, + size_t inputDepthPitch, + uint8_t *output, + size_t outputRowPitch, + size_t outputDepthPitch, + bool isSigned) +{ + for (size_t z = 0; z < depth; z++) + { + for (size_t y = 0; y < height; y += 4) + { + const ETC2Block *sourceRow = + priv::OffsetDataPointer<ETC2Block>(input, y / 4, z, inputRowPitch, inputDepthPitch); + uint8_t *destRow = + priv::OffsetDataPointer<uint8_t>(output, y, z, outputRowPitch, outputDepthPitch); + + for (size_t x = 0; x < width; x += 4) + { + uint8_t *destPixelsRed = destRow + (x * 2); + const ETC2Block *sourceBlockRed = sourceRow + (x / 2); + sourceBlockRed->decodeAsSingleChannel(destPixelsRed, x, y, width, height, 2, + outputRowPitch, isSigned); + + uint8_t *destPixelsGreen = destPixelsRed + 1; + const ETC2Block *sourceBlockGreen = sourceBlockRed + 1; + sourceBlockGreen->decodeAsSingleChannel(destPixelsGreen, x, y, width, height, 2, + outputRowPitch, isSigned); + } + } + } +} + +void LoadETC2RGB8ToRGBA8(size_t width, + size_t height, + size_t depth, + const uint8_t *input, + size_t inputRowPitch, + size_t inputDepthPitch, + uint8_t *output, + size_t outputRowPitch, + size_t outputDepthPitch, + bool punchthroughAlpha) +{ + for (size_t z = 0; z < depth; z++) + { + for (size_t y = 0; y < height; y += 4) + { + const ETC2Block *sourceRow = + priv::OffsetDataPointer<ETC2Block>(input, y / 4, z, inputRowPitch, inputDepthPitch); + uint8_t *destRow = + priv::OffsetDataPointer<uint8_t>(output, y, z, outputRowPitch, outputDepthPitch); + + for (size_t x = 0; x < width; x += 4) + { + const ETC2Block *sourceBlock = sourceRow + (x / 4); + uint8_t *destPixels = destRow + (x * 4); + + sourceBlock->decodeAsRGB(destPixels, x, y, width, height, outputRowPitch, + DefaultETCAlphaValues, punchthroughAlpha); + } + } + } +} + +void LoadETC2RGB8ToBC1(size_t width, + size_t height, + size_t depth, + const uint8_t *input, + size_t inputRowPitch, + size_t inputDepthPitch, + uint8_t *output, + size_t outputRowPitch, + size_t outputDepthPitch, + bool punchthroughAlpha) +{ + for (size_t z = 0; z < depth; z++) + { + for (size_t y = 0; y < height; y += 4) + { + const ETC2Block *sourceRow = + priv::OffsetDataPointer<ETC2Block>(input, y / 4, z, inputRowPitch, inputDepthPitch); + uint8_t *destRow = priv::OffsetDataPointer<uint8_t>(output, y / 4, z, outputRowPitch, + outputDepthPitch); + + for (size_t x = 0; x < width; x += 4) + { + const ETC2Block *sourceBlock = sourceRow + (x / 4); + uint8_t *destPixels = destRow + (x * 2); + + sourceBlock->transcodeAsBC1(destPixels, x, y, width, height, DefaultETCAlphaValues, + punchthroughAlpha); + } + } + } +} + +void LoadETC2RGBA8ToRGBA8(size_t width, + size_t height, + size_t depth, + const uint8_t *input, + size_t inputRowPitch, + size_t inputDepthPitch, + uint8_t *output, + size_t outputRowPitch, + size_t outputDepthPitch, + bool srgb) +{ + uint8_t decodedAlphaValues[4][4]; + + for (size_t z = 0; z < depth; z++) + { + for (size_t y = 0; y < height; y += 4) + { + const ETC2Block *sourceRow = + priv::OffsetDataPointer<ETC2Block>(input, y / 4, z, inputRowPitch, inputDepthPitch); + uint8_t *destRow = + priv::OffsetDataPointer<uint8_t>(output, y, z, outputRowPitch, outputDepthPitch); + + for (size_t x = 0; x < width; x += 4) + { + const ETC2Block *sourceBlockAlpha = sourceRow + (x / 2); + sourceBlockAlpha->decodeAsSingleChannel( + reinterpret_cast<uint8_t *>(decodedAlphaValues), x, y, width, height, 1, 4, + false); + + uint8_t *destPixels = destRow + (x * 4); + const ETC2Block *sourceBlockRGB = sourceBlockAlpha + 1; + sourceBlockRGB->decodeAsRGB(destPixels, x, y, width, height, outputRowPitch, + decodedAlphaValues, false); + } + } + } +} + +} // anonymous namespace + +void LoadETC1RGB8ToRGBA8(size_t width, + size_t height, + size_t depth, + const uint8_t *input, + size_t inputRowPitch, + size_t inputDepthPitch, + uint8_t *output, + size_t outputRowPitch, + size_t outputDepthPitch) +{ + LoadETC2RGB8ToRGBA8(width, height, depth, input, inputRowPitch, inputDepthPitch, output, + outputRowPitch, outputDepthPitch, false); +} + +void LoadETC1RGB8ToBC1(size_t width, + size_t height, + size_t depth, + const uint8_t *input, + size_t inputRowPitch, + size_t inputDepthPitch, + uint8_t *output, + size_t outputRowPitch, + size_t outputDepthPitch) +{ + LoadETC2RGB8ToBC1(width, height, depth, input, inputRowPitch, inputDepthPitch, output, + outputRowPitch, outputDepthPitch, false); +} + +void LoadEACR11ToR8(size_t width, + size_t height, + size_t depth, + const uint8_t *input, + size_t inputRowPitch, + size_t inputDepthPitch, + uint8_t *output, + size_t outputRowPitch, + size_t outputDepthPitch) +{ + LoadR11EACToR8(width, height, depth, input, inputRowPitch, inputDepthPitch, output, + outputRowPitch, outputDepthPitch, false); +} + +void LoadEACR11SToR8(size_t width, + size_t height, + size_t depth, + const uint8_t *input, + size_t inputRowPitch, + size_t inputDepthPitch, + uint8_t *output, + size_t outputRowPitch, + size_t outputDepthPitch) +{ + LoadR11EACToR8(width, height, depth, input, inputRowPitch, inputDepthPitch, output, + outputRowPitch, outputDepthPitch, true); +} + +void LoadEACRG11ToRG8(size_t width, + size_t height, + size_t depth, + const uint8_t *input, + size_t inputRowPitch, + size_t inputDepthPitch, + uint8_t *output, + size_t outputRowPitch, + size_t outputDepthPitch) +{ + LoadRG11EACToRG8(width, height, depth, input, inputRowPitch, inputDepthPitch, output, + outputRowPitch, outputDepthPitch, false); +} + +void LoadEACRG11SToRG8(size_t width, + size_t height, + size_t depth, + const uint8_t *input, + size_t inputRowPitch, + size_t inputDepthPitch, + uint8_t *output, + size_t outputRowPitch, + size_t outputDepthPitch) +{ + LoadRG11EACToRG8(width, height, depth, input, inputRowPitch, inputDepthPitch, output, + outputRowPitch, outputDepthPitch, true); +} + +void LoadETC2RGB8ToRGBA8(size_t width, + size_t height, + size_t depth, + const uint8_t *input, + size_t inputRowPitch, + size_t inputDepthPitch, + uint8_t *output, + size_t outputRowPitch, + size_t outputDepthPitch) +{ + LoadETC2RGB8ToRGBA8(width, height, depth, input, inputRowPitch, inputDepthPitch, output, + outputRowPitch, outputDepthPitch, false); +} + +void LoadETC2RGB8ToBC1(size_t width, + size_t height, + size_t depth, + const uint8_t *input, + size_t inputRowPitch, + size_t inputDepthPitch, + uint8_t *output, + size_t outputRowPitch, + size_t outputDepthPitch) +{ + LoadETC2RGB8ToBC1(width, height, depth, input, inputRowPitch, inputDepthPitch, output, + outputRowPitch, outputDepthPitch, false); +} + +void LoadETC2SRGB8ToRGBA8(size_t width, + size_t height, + size_t depth, + const uint8_t *input, + size_t inputRowPitch, + size_t inputDepthPitch, + uint8_t *output, + size_t outputRowPitch, + size_t outputDepthPitch) +{ + LoadETC2RGB8ToRGBA8(width, height, depth, input, inputRowPitch, inputDepthPitch, output, + outputRowPitch, outputDepthPitch, false); +} + +void LoadETC2SRGB8ToBC1(size_t width, + size_t height, + size_t depth, + const uint8_t *input, + size_t inputRowPitch, + size_t inputDepthPitch, + uint8_t *output, + size_t outputRowPitch, + size_t outputDepthPitch) +{ + LoadETC2RGB8ToBC1(width, height, depth, input, inputRowPitch, inputDepthPitch, output, + outputRowPitch, outputDepthPitch, false); +} + +void LoadETC2RGB8A1ToRGBA8(size_t width, + size_t height, + size_t depth, + const uint8_t *input, + size_t inputRowPitch, + size_t inputDepthPitch, + uint8_t *output, + size_t outputRowPitch, + size_t outputDepthPitch) +{ + LoadETC2RGB8ToRGBA8(width, height, depth, input, inputRowPitch, inputDepthPitch, output, + outputRowPitch, outputDepthPitch, true); +} + +void LoadETC2RGB8A1ToBC1(size_t width, + size_t height, + size_t depth, + const uint8_t *input, + size_t inputRowPitch, + size_t inputDepthPitch, + uint8_t *output, + size_t outputRowPitch, + size_t outputDepthPitch) +{ + LoadETC2RGB8ToBC1(width, height, depth, input, inputRowPitch, inputDepthPitch, output, + outputRowPitch, outputDepthPitch, true); +} + +void LoadETC2SRGB8A1ToRGBA8(size_t width, + size_t height, + size_t depth, + const uint8_t *input, + size_t inputRowPitch, + size_t inputDepthPitch, + uint8_t *output, + size_t outputRowPitch, + size_t outputDepthPitch) +{ + LoadETC2RGB8ToRGBA8(width, height, depth, input, inputRowPitch, inputDepthPitch, output, + outputRowPitch, outputDepthPitch, true); +} + +void LoadETC2SRGB8A1ToBC1(size_t width, + size_t height, + size_t depth, + const uint8_t *input, + size_t inputRowPitch, + size_t inputDepthPitch, + uint8_t *output, + size_t outputRowPitch, + size_t outputDepthPitch) +{ + LoadETC2RGB8ToBC1(width, height, depth, input, inputRowPitch, inputDepthPitch, output, + outputRowPitch, outputDepthPitch, true); +} + +void LoadETC2RGBA8ToRGBA8(size_t width, + size_t height, + size_t depth, + const uint8_t *input, + size_t inputRowPitch, + size_t inputDepthPitch, + uint8_t *output, + size_t outputRowPitch, + size_t outputDepthPitch) +{ + LoadETC2RGBA8ToRGBA8(width, height, depth, input, inputRowPitch, inputDepthPitch, output, + outputRowPitch, outputDepthPitch, false); +} + +void LoadETC2SRGBA8ToSRGBA8(size_t width, + size_t height, + size_t depth, + const uint8_t *input, + size_t inputRowPitch, + size_t inputDepthPitch, + uint8_t *output, + size_t outputRowPitch, + size_t outputDepthPitch) +{ + LoadETC2RGBA8ToRGBA8(width, height, depth, input, inputRowPitch, inputDepthPitch, output, + outputRowPitch, outputDepthPitch, true); +} + +} // namespace angle |