src/gpu/DataUtils.cpp - skia - Git at Google

 /*
  * Copyright 2024 Google LLC
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "src/gpu/DataUtils.h"

 #include "include/core/SkTextureCompressionType.h"
 #include "include/gpu/GpuTypes.h"
 #include "include/private/base/SkAssert.h"
 #include "include/private/base/SkMath.h"
 #include "include/private/base/SkTPin.h"
 #include "include/private/base/SkTemplates.h"
 #include "src/base/SkMathPriv.h"
 #include "src/core/SkCompressedDataUtils.h"
 #include "src/core/SkMipmap.h"
 #include "src/core/SkTraceEvent.h"

 #include <algorithm>
 #include <cstdint>
 #include <cstring>

 using namespace skia_private;

 namespace skgpu {

 struct ETC1Block {
     uint32_t fHigh;
     uint32_t fLow;
 };

 constexpr uint32_t kDiffBit = 0x2; // set -> differential; not-set -> individual

 static inline int extend_5To8bits(int b) {
     int c = b & 0x1f;
     return (c << 3) | (c >> 2);
 }

 static const int kNumETC1ModifierTables = 8;
 static const int kNumETC1PixelIndices = 4;

 // The index of each row in this table is the ETC1 table codeword
 // The index of each column in this table is the ETC1 pixel index value
 static const int kETC1ModifierTables[kNumETC1ModifierTables][kNumETC1PixelIndices] = {
     /* 0 */ { 2,    8,  -2,   -8 },
     /* 1 */ { 5,   17,  -5,  -17 },
     /* 2 */ { 9,   29,  -9,  -29 },
     /* 3 */ { 13,  42, -13,  -42 },
     /* 4 */ { 18,  60, -18,  -60 },
     /* 5 */ { 24,  80, -24,  -80 },
     /* 6 */ { 33, 106, -33, -106 },
     /* 7 */ { 47, 183, -47, -183 }
 };

 // Evaluate one of the entries in 'kModifierTables' to see how close it can get (r8,g8,b8) to
 // the original color (rOrig, gOrib, bOrig).
 static int test_table_entry(int rOrig, int gOrig, int bOrig,
                             int r8, int g8, int b8,
                             int table, int offset) {
     SkASSERT(0 <= table && table < 8);
     SkASSERT(0 <= offset && offset < 4);

     r8 = SkTPin<int>(r8 + kETC1ModifierTables[table][offset], 0, 255);
     g8 = SkTPin<int>(g8 + kETC1ModifierTables[table][offset], 0, 255);
     b8 = SkTPin<int>(b8 + kETC1ModifierTables[table][offset], 0, 255);

     return SkTAbs(rOrig - r8) + SkTAbs(gOrig - g8) + SkTAbs(bOrig - b8);
 }

 // Create an ETC1 compressed block that is filled with 'col'
 static void create_etc1_block(SkColor col, ETC1Block* block) {
     uint32_t high = 0;
     uint32_t low = 0;

     int rOrig = SkColorGetR(col);
     int gOrig = SkColorGetG(col);
     int bOrig = SkColorGetB(col);

     int r5 = SkMulDiv255Round(31, rOrig);
     int g5 = SkMulDiv255Round(31, gOrig);
     int b5 = SkMulDiv255Round(31, bOrig);

     int r8 = extend_5To8bits(r5);
     int g8 = extend_5To8bits(g5);
     int b8 = extend_5To8bits(b5);

     // We always encode solid color textures in differential mode (i.e., with a 555 base color) but
     // with zero diffs (i.e., bits 26-24, 18-16 and 10-8 are left 0).
     high |= (r5 << 27) | (g5 << 19) | (b5 << 11) | kDiffBit;

     int bestTableIndex = 0, bestPixelIndex = 0;
     int bestSoFar = 1024;
     for (int tableIndex = 0; tableIndex < kNumETC1ModifierTables; ++tableIndex) {
         for (int pixelIndex = 0; pixelIndex < kNumETC1PixelIndices; ++pixelIndex) {
             int score = test_table_entry(rOrig, gOrig, bOrig, r8, g8, b8,
                                          tableIndex, pixelIndex);

             if (bestSoFar > score) {
                 bestSoFar = score;
                 bestTableIndex = tableIndex;
                 bestPixelIndex = pixelIndex;
             }
         }
     }

     high |= (bestTableIndex << 5) | (bestTableIndex << 2);

     if (bestPixelIndex & 0x1) {
         low |= 0xFFFF;
     }
     if (bestPixelIndex & 0x2) {
         low |= 0xFFFF0000;
     }

     block->fHigh = SkBSwap32(high);
     block->fLow = SkBSwap32(low);
 }

 static int num_4x4_blocks(int size) {
     return ((size + 3) & ~3) >> 2;
 }

 static int num_ETC1_blocks(int w, int h) {
     w = num_4x4_blocks(w);
     h = num_4x4_blocks(h);

     return w * h;
 }

 struct BC1Block {
     uint16_t fColor0;
     uint16_t fColor1;
     uint32_t fIndices;
 };

 static uint16_t to565(SkColor col) {
     int r5 = SkMulDiv255Round(31, SkColorGetR(col));
     int g6 = SkMulDiv255Round(63, SkColorGetG(col));
     int b5 = SkMulDiv255Round(31, SkColorGetB(col));

     return (r5 << 11) | (g6 << 5) | b5;
 }

 // Create a BC1 compressed block that has two colors but is initialized to 'col0'
 static void create_BC1_block(SkColor col0, SkColor col1, BC1Block* block) {
     block->fColor0 = to565(col0);
     block->fColor1 = to565(col1);
     SkASSERT(block->fColor0 <= block->fColor1); // we always assume transparent blocks

     if (col0 == SK_ColorTRANSPARENT) {
         // This sets all 16 pixels to just use color3 (under the assumption
         // that this is a kBC1_RGBA8_UNORM texture. Note that in this case
         // fColor0 will be opaque black.
         block->fIndices = 0xFFFFFFFF;
     } else {
         // This sets all 16 pixels to just use 'fColor0'
         block->fIndices = 0;
     }
 }

 size_t NumCompressedBlocks(SkTextureCompressionType type, SkISize baseDimensions) {
     switch (type) {
         case SkTextureCompressionType::kNone:
             return baseDimensions.width() * baseDimensions.height();
         case SkTextureCompressionType::kETC2_RGB8_UNORM:
         case SkTextureCompressionType::kBC1_RGB8_UNORM:
         case SkTextureCompressionType::kBC1_RGBA8_UNORM: {
             int numBlocksWidth = num_4x4_blocks(baseDimensions.width());
             int numBlocksHeight = num_4x4_blocks(baseDimensions.height());

             return numBlocksWidth * numBlocksHeight;
         }
     }
     SkUNREACHABLE;
 }

 size_t CompressedRowBytes(SkTextureCompressionType type, int width) {
     switch (type) {
         case SkTextureCompressionType::kNone:
             return 0;
         case SkTextureCompressionType::kETC2_RGB8_UNORM:
         case SkTextureCompressionType::kBC1_RGB8_UNORM:
         case SkTextureCompressionType::kBC1_RGBA8_UNORM: {
             int numBlocksWidth = num_4x4_blocks(width);

             static_assert(sizeof(ETC1Block) == sizeof(BC1Block));
             return numBlocksWidth * sizeof(ETC1Block);
         }
     }
     SkUNREACHABLE;
 }

 SkISize CompressedDimensions(SkTextureCompressionType type, SkISize baseDimensions) {
     switch (type) {
         case SkTextureCompressionType::kNone:
             return baseDimensions;
         case SkTextureCompressionType::kETC2_RGB8_UNORM:
         case SkTextureCompressionType::kBC1_RGB8_UNORM:
         case SkTextureCompressionType::kBC1_RGBA8_UNORM: {
             SkISize blockDims = CompressedDimensionsInBlocks(type, baseDimensions);
             // Each BC1_RGB8_UNORM and ETC1 block has 16 pixels
             return { 4 * blockDims.fWidth, 4 * blockDims.fHeight };
         }
     }
     SkUNREACHABLE;
 }

 SkISize CompressedDimensionsInBlocks(SkTextureCompressionType type, SkISize baseDimensions) {
     switch (type) {
         case SkTextureCompressionType::kNone:
             return baseDimensions;
         case SkTextureCompressionType::kETC2_RGB8_UNORM:
         case SkTextureCompressionType::kBC1_RGB8_UNORM:
         case SkTextureCompressionType::kBC1_RGBA8_UNORM: {
             int numBlocksWidth = num_4x4_blocks(baseDimensions.width());
             int numBlocksHeight = num_4x4_blocks(baseDimensions.height());

             // Each BC1_RGB8_UNORM and ETC1 block has 16 pixels
             return { numBlocksWidth, numBlocksHeight };
         }
     }
     SkUNREACHABLE;
 }

 // Fill in 'dest' with ETC1 blocks derived from 'colorf'
 static void fillin_ETC1_with_color(SkISize dimensions, const SkColor4f& colorf, char* dest) {
     SkColor color = colorf.toSkColor();

     ETC1Block block;
     create_etc1_block(color, &block);

     int numBlocks = num_ETC1_blocks(dimensions.width(), dimensions.height());

     for (int i = 0; i < numBlocks; ++i) {
         memcpy(dest, &block, sizeof(ETC1Block));
         dest += sizeof(ETC1Block);
     }
 }

 // Fill in 'dest' with BC1 blocks derived from 'colorf'
 static void fillin_BC1_with_color(SkISize dimensions, const SkColor4f& colorf, char* dest) {
     SkColor color = colorf.toSkColor();

     BC1Block block;
     create_BC1_block(color, color, &block);

     int numBlocks = num_ETC1_blocks(dimensions.width(), dimensions.height());

     for (int i = 0; i < numBlocks; ++i) {
         memcpy(dest, &block, sizeof(BC1Block));
         dest += sizeof(BC1Block);
     }
 }

 void FillInCompressedData(SkTextureCompressionType type,
                           SkISize dimensions,
                           skgpu::Mipmapped mipmapped,
                           char* dstPixels,
                           const SkColor4f& colorf) {
     TRACE_EVENT0("skia.gpu", TRACE_FUNC);

     int numMipLevels = 1;
     if (mipmapped == skgpu::Mipmapped::kYes) {
         numMipLevels = SkMipmap::ComputeLevelCount(dimensions.width(), dimensions.height()) + 1;
     }

     size_t offset = 0;

     for (int i = 0; i < numMipLevels; ++i) {
         size_t levelSize = SkCompressedDataSize(type, dimensions, nullptr, false);

         if (SkTextureCompressionType::kETC2_RGB8_UNORM == type) {
             fillin_ETC1_with_color(dimensions, colorf, &dstPixels[offset]);
         } else {
             SkASSERT(type == SkTextureCompressionType::kBC1_RGB8_UNORM ||
                      type == SkTextureCompressionType::kBC1_RGBA8_UNORM);
             fillin_BC1_with_color(dimensions, colorf, &dstPixels[offset]);
         }

         offset += levelSize;
         dimensions = {std::max(1, dimensions.width()/2), std::max(1, dimensions.height()/2)};
     }
 }

 } // namespace skgpu
	/*
	* Copyright 2024 Google LLC
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "src/gpu/DataUtils.h"

	#include "include/core/SkTextureCompressionType.h"
	#include "include/gpu/GpuTypes.h"
	#include "include/private/base/SkAssert.h"
	#include "include/private/base/SkMath.h"
	#include "include/private/base/SkTPin.h"
	#include "include/private/base/SkTemplates.h"
	#include "src/base/SkMathPriv.h"
	#include "src/core/SkCompressedDataUtils.h"
	#include "src/core/SkMipmap.h"
	#include "src/core/SkTraceEvent.h"

	#include <algorithm>
	#include <cstdint>
	#include <cstring>

	using namespace skia_private;

	namespace skgpu {

	struct ETC1Block {
	uint32_t fHigh;
	uint32_t fLow;
	};

	constexpr uint32_t kDiffBit = 0x2; // set -> differential; not-set -> individual

	static inline int extend_5To8bits(int b) {
	int c = b & 0x1f;
	return (c << 3) \| (c >> 2);
	}

	static const int kNumETC1ModifierTables = 8;
	static const int kNumETC1PixelIndices = 4;

	// The index of each row in this table is the ETC1 table codeword
	// The index of each column in this table is the ETC1 pixel index value
	static const int kETC1ModifierTables[kNumETC1ModifierTables][kNumETC1PixelIndices] = {
	/* 0 */ { 2, 8, -2, -8 },
	/* 1 */ { 5, 17, -5, -17 },
	/* 2 */ { 9, 29, -9, -29 },
	/* 3 */ { 13, 42, -13, -42 },
	/* 4 */ { 18, 60, -18, -60 },
	/* 5 */ { 24, 80, -24, -80 },
	/* 6 */ { 33, 106, -33, -106 },
	/* 7 */ { 47, 183, -47, -183 }
	};

	// Evaluate one of the entries in 'kModifierTables' to see how close it can get (r8,g8,b8) to
	// the original color (rOrig, gOrib, bOrig).
	static int test_table_entry(int rOrig, int gOrig, int bOrig,
	int r8, int g8, int b8,
	int table, int offset) {
	SkASSERT(0 <= table && table < 8);
	SkASSERT(0 <= offset && offset < 4);

	r8 = SkTPin<int>(r8 + kETC1ModifierTables[table][offset], 0, 255);
	g8 = SkTPin<int>(g8 + kETC1ModifierTables[table][offset], 0, 255);
	b8 = SkTPin<int>(b8 + kETC1ModifierTables[table][offset], 0, 255);

	return SkTAbs(rOrig - r8) + SkTAbs(gOrig - g8) + SkTAbs(bOrig - b8);
	}

	// Create an ETC1 compressed block that is filled with 'col'
	static void create_etc1_block(SkColor col, ETC1Block* block) {
	uint32_t high = 0;
	uint32_t low = 0;

	int rOrig = SkColorGetR(col);
	int gOrig = SkColorGetG(col);
	int bOrig = SkColorGetB(col);

	int r5 = SkMulDiv255Round(31, rOrig);
	int g5 = SkMulDiv255Round(31, gOrig);
	int b5 = SkMulDiv255Round(31, bOrig);

	int r8 = extend_5To8bits(r5);
	int g8 = extend_5To8bits(g5);
	int b8 = extend_5To8bits(b5);

	// We always encode solid color textures in differential mode (i.e., with a 555 base color) but
	// with zero diffs (i.e., bits 26-24, 18-16 and 10-8 are left 0).
	high \|= (r5 << 27) \| (g5 << 19) \| (b5 << 11) \| kDiffBit;

	int bestTableIndex = 0, bestPixelIndex = 0;
	int bestSoFar = 1024;
	for (int tableIndex = 0; tableIndex < kNumETC1ModifierTables; ++tableIndex) {
	for (int pixelIndex = 0; pixelIndex < kNumETC1PixelIndices; ++pixelIndex) {
	int score = test_table_entry(rOrig, gOrig, bOrig, r8, g8, b8,
	tableIndex, pixelIndex);

	if (bestSoFar > score) {
	bestSoFar = score;
	bestTableIndex = tableIndex;
	bestPixelIndex = pixelIndex;
	}
	}
	}

	high \|= (bestTableIndex << 5) \| (bestTableIndex << 2);

	if (bestPixelIndex & 0x1) {
	low \|= 0xFFFF;
	}
	if (bestPixelIndex & 0x2) {
	low \|= 0xFFFF0000;
	}

	block->fHigh = SkBSwap32(high);
	block->fLow = SkBSwap32(low);
	}

	static int num_4x4_blocks(int size) {
	return ((size + 3) & ~3) >> 2;
	}

	static int num_ETC1_blocks(int w, int h) {
	w = num_4x4_blocks(w);
	h = num_4x4_blocks(h);

	return w * h;
	}

	struct BC1Block {
	uint16_t fColor0;
	uint16_t fColor1;
	uint32_t fIndices;
	};

	static uint16_t to565(SkColor col) {
	int r5 = SkMulDiv255Round(31, SkColorGetR(col));
	int g6 = SkMulDiv255Round(63, SkColorGetG(col));
	int b5 = SkMulDiv255Round(31, SkColorGetB(col));

	return (r5 << 11) \| (g6 << 5) \| b5;
	}

	// Create a BC1 compressed block that has two colors but is initialized to 'col0'
	static void create_BC1_block(SkColor col0, SkColor col1, BC1Block* block) {
	block->fColor0 = to565(col0);
	block->fColor1 = to565(col1);
	SkASSERT(block->fColor0 <= block->fColor1); // we always assume transparent blocks

	if (col0 == SK_ColorTRANSPARENT) {
	// This sets all 16 pixels to just use color3 (under the assumption
	// that this is a kBC1_RGBA8_UNORM texture. Note that in this case
	// fColor0 will be opaque black.
	block->fIndices = 0xFFFFFFFF;
	} else {
	// This sets all 16 pixels to just use 'fColor0'
	block->fIndices = 0;
	}
	}

	size_t NumCompressedBlocks(SkTextureCompressionType type, SkISize baseDimensions) {
	switch (type) {
	case SkTextureCompressionType::kNone:
	return baseDimensions.width() * baseDimensions.height();
	case SkTextureCompressionType::kETC2_RGB8_UNORM:
	case SkTextureCompressionType::kBC1_RGB8_UNORM:
	case SkTextureCompressionType::kBC1_RGBA8_UNORM: {
	int numBlocksWidth = num_4x4_blocks(baseDimensions.width());
	int numBlocksHeight = num_4x4_blocks(baseDimensions.height());

	return numBlocksWidth * numBlocksHeight;
	}
	}
	SkUNREACHABLE;
	}

	size_t CompressedRowBytes(SkTextureCompressionType type, int width) {
	switch (type) {
	case SkTextureCompressionType::kNone:
	return 0;
	case SkTextureCompressionType::kETC2_RGB8_UNORM:
	case SkTextureCompressionType::kBC1_RGB8_UNORM:
	case SkTextureCompressionType::kBC1_RGBA8_UNORM: {
	int numBlocksWidth = num_4x4_blocks(width);

	static_assert(sizeof(ETC1Block) == sizeof(BC1Block));
	return numBlocksWidth * sizeof(ETC1Block);
	}
	}
	SkUNREACHABLE;
	}

	SkISize CompressedDimensions(SkTextureCompressionType type, SkISize baseDimensions) {
	switch (type) {
	case SkTextureCompressionType::kNone:
	return baseDimensions;
	case SkTextureCompressionType::kETC2_RGB8_UNORM:
	case SkTextureCompressionType::kBC1_RGB8_UNORM:
	case SkTextureCompressionType::kBC1_RGBA8_UNORM: {
	SkISize blockDims = CompressedDimensionsInBlocks(type, baseDimensions);
	// Each BC1_RGB8_UNORM and ETC1 block has 16 pixels
	return { 4 * blockDims.fWidth, 4 * blockDims.fHeight };
	}
	}
	SkUNREACHABLE;
	}

	SkISize CompressedDimensionsInBlocks(SkTextureCompressionType type, SkISize baseDimensions) {
	switch (type) {
	case SkTextureCompressionType::kNone:
	return baseDimensions;
	case SkTextureCompressionType::kETC2_RGB8_UNORM:
	case SkTextureCompressionType::kBC1_RGB8_UNORM:
	case SkTextureCompressionType::kBC1_RGBA8_UNORM: {
	int numBlocksWidth = num_4x4_blocks(baseDimensions.width());
	int numBlocksHeight = num_4x4_blocks(baseDimensions.height());

	// Each BC1_RGB8_UNORM and ETC1 block has 16 pixels
	return { numBlocksWidth, numBlocksHeight };
	}
	}
	SkUNREACHABLE;
	}

	// Fill in 'dest' with ETC1 blocks derived from 'colorf'
	static void fillin_ETC1_with_color(SkISize dimensions, const SkColor4f& colorf, char* dest) {
	SkColor color = colorf.toSkColor();

	ETC1Block block;
	create_etc1_block(color, &block);

	int numBlocks = num_ETC1_blocks(dimensions.width(), dimensions.height());

	for (int i = 0; i < numBlocks; ++i) {
	memcpy(dest, &block, sizeof(ETC1Block));
	dest += sizeof(ETC1Block);
	}
	}

	// Fill in 'dest' with BC1 blocks derived from 'colorf'
	static void fillin_BC1_with_color(SkISize dimensions, const SkColor4f& colorf, char* dest) {
	SkColor color = colorf.toSkColor();

	BC1Block block;
	create_BC1_block(color, color, &block);

	int numBlocks = num_ETC1_blocks(dimensions.width(), dimensions.height());

	for (int i = 0; i < numBlocks; ++i) {
	memcpy(dest, &block, sizeof(BC1Block));
	dest += sizeof(BC1Block);
	}
	}

	void FillInCompressedData(SkTextureCompressionType type,
	SkISize dimensions,
	skgpu::Mipmapped mipmapped,
	char* dstPixels,
	const SkColor4f& colorf) {
	TRACE_EVENT0("skia.gpu", TRACE_FUNC);

	int numMipLevels = 1;
	if (mipmapped == skgpu::Mipmapped::kYes) {
	numMipLevels = SkMipmap::ComputeLevelCount(dimensions.width(), dimensions.height()) + 1;
	}

	size_t offset = 0;

	for (int i = 0; i < numMipLevels; ++i) {
	size_t levelSize = SkCompressedDataSize(type, dimensions, nullptr, false);

	if (SkTextureCompressionType::kETC2_RGB8_UNORM == type) {
	fillin_ETC1_with_color(dimensions, colorf, &dstPixels[offset]);
	} else {
	SkASSERT(type == SkTextureCompressionType::kBC1_RGB8_UNORM \|\|
	type == SkTextureCompressionType::kBC1_RGBA8_UNORM);
	fillin_BC1_with_color(dimensions, colorf, &dstPixels[offset]);
	}

	offset += levelSize;
	dimensions = {std::max(1, dimensions.width()/2), std::max(1, dimensions.height()/2)};
	}
	}

	} // namespace skgpu