src/gpu/GrPersistentCacheUtils.h - skia - Git at Google

 /*
  * Copyright 2019 Google LLC.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef GrPersistentCacheEntry_DEFINED
 #define GrPersistentCacheEntry_DEFINED

 #include "include/core/SkData.h"
 #include "include/private/GrTypesPriv.h"
 #include "src/core/SkReader32.h"
 #include "src/core/SkWriter32.h"
 #include "src/sksl/SkSLString.h"
 #include "src/sksl/ir/SkSLProgram.h"

 // The GrPersistentCache stores opaque blobs, as far as clients are concerned. It's helpful to
 // inspect certain kinds of cached data within our tools, so for those cases (GLSL, SPIR-V), we
 // put the serialization logic here, to be shared by the backend code and the tool code.
 namespace GrPersistentCacheUtils {

 struct ShaderMetadata {
     SkSL::Program::Settings* fSettings = nullptr;
     SkTArray<SkSL::String> fAttributeNames;
     bool fHasCustomColorOutput = false;
     bool fHasSecondaryColorOutput = false;
 };

 static inline sk_sp<SkData> PackCachedShaders(SkFourByteTag shaderType,
                                               const SkSL::String shaders[],
                                               const SkSL::Program::Inputs inputs[],
                                               int numInputs,
                                               const ShaderMetadata* meta = nullptr) {
     // For consistency (so tools can blindly pack and unpack cached shaders), we always write
     // kGrShaderTypeCount inputs. If the backend gives us fewer, we just replicate the last one.
     SkASSERT(numInputs >= 1 && numInputs <= kGrShaderTypeCount);

     SkWriter32 writer;
     writer.write32(shaderType);
     for (int i = 0; i < kGrShaderTypeCount; ++i) {
         writer.writeString(shaders[i].c_str(), shaders[i].size());
         writer.writePad(&inputs[SkTMin(i, numInputs - 1)], sizeof(SkSL::Program::Inputs));
     }
     writer.writeBool(SkToBool(meta));
     if (meta) {
         writer.writeBool(SkToBool(meta->fSettings));
         if (meta->fSettings) {
             writer.writeBool(meta->fSettings->fFlipY);
             writer.writeBool(meta->fSettings->fFragColorIsInOut);
             writer.writeBool(meta->fSettings->fForceHighPrecision);
         }

         writer.writeInt(meta->fAttributeNames.count());
         for (const auto& attr : meta->fAttributeNames) {
             writer.writeString(attr.c_str(), attr.size());
         }

         writer.writeBool(meta->fHasCustomColorOutput);
         writer.writeBool(meta->fHasSecondaryColorOutput);
     }
     return writer.snapshotAsData();
 }

 static inline void UnpackCachedShaders(SkReader32* reader,
                                        SkSL::String shaders[],
                                        SkSL::Program::Inputs inputs[],
                                        int numInputs,
                                        ShaderMetadata* meta = nullptr) {
     for (int i = 0; i < kGrShaderTypeCount; ++i) {
         size_t stringLen = 0;
         const char* string = reader->readString(&stringLen);
         shaders[i] = SkSL::String(string, stringLen);

         // GL, for example, only wants one set of Inputs
         if (i < numInputs) {
             reader->read(&inputs[i], sizeof(inputs[i]));
         } else {
             reader->skip(sizeof(SkSL::Program::Inputs));
         }
     }
     if (reader->readBool() && meta) {
         SkASSERT(meta->fSettings != nullptr);

         if (reader->readBool()) {
             meta->fSettings->fFlipY              = reader->readBool();
             meta->fSettings->fFragColorIsInOut   = reader->readBool();
             meta->fSettings->fForceHighPrecision = reader->readBool();
         }

         meta->fAttributeNames.resize(reader->readInt());
         for (int i = 0; i < meta->fAttributeNames.count(); ++i) {
             size_t stringLen = 0;
             const char* string = reader->readString(&stringLen);
             meta->fAttributeNames[i] = SkSL::String(string, stringLen);
         }

         meta->fHasCustomColorOutput    = reader->readBool();
         meta->fHasSecondaryColorOutput = reader->readBool();
     }
 }

 }

 #endif
	/*
	* Copyright 2019 Google LLC.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef GrPersistentCacheEntry_DEFINED
	#define GrPersistentCacheEntry_DEFINED

	#include "include/core/SkData.h"
	#include "include/private/GrTypesPriv.h"
	#include "src/core/SkReader32.h"
	#include "src/core/SkWriter32.h"
	#include "src/sksl/SkSLString.h"
	#include "src/sksl/ir/SkSLProgram.h"

	// The GrPersistentCache stores opaque blobs, as far as clients are concerned. It's helpful to
	// inspect certain kinds of cached data within our tools, so for those cases (GLSL, SPIR-V), we
	// put the serialization logic here, to be shared by the backend code and the tool code.
	namespace GrPersistentCacheUtils {

	struct ShaderMetadata {
	SkSL::Program::Settings* fSettings = nullptr;
	SkTArray<SkSL::String> fAttributeNames;
	bool fHasCustomColorOutput = false;
	bool fHasSecondaryColorOutput = false;
	};

	static inline sk_sp<SkData> PackCachedShaders(SkFourByteTag shaderType,
	const SkSL::String shaders[],
	const SkSL::Program::Inputs inputs[],
	int numInputs,
	const ShaderMetadata* meta = nullptr) {
	// For consistency (so tools can blindly pack and unpack cached shaders), we always write
	// kGrShaderTypeCount inputs. If the backend gives us fewer, we just replicate the last one.
	SkASSERT(numInputs >= 1 && numInputs <= kGrShaderTypeCount);

	SkWriter32 writer;
	writer.write32(shaderType);
	for (int i = 0; i < kGrShaderTypeCount; ++i) {
	writer.writeString(shaders[i].c_str(), shaders[i].size());
	writer.writePad(&inputs[SkTMin(i, numInputs - 1)], sizeof(SkSL::Program::Inputs));
	}
	writer.writeBool(SkToBool(meta));
	if (meta) {
	writer.writeBool(SkToBool(meta->fSettings));
	if (meta->fSettings) {
	writer.writeBool(meta->fSettings->fFlipY);
	writer.writeBool(meta->fSettings->fFragColorIsInOut);
	writer.writeBool(meta->fSettings->fForceHighPrecision);
	}

	writer.writeInt(meta->fAttributeNames.count());
	for (const auto& attr : meta->fAttributeNames) {
	writer.writeString(attr.c_str(), attr.size());
	}

	writer.writeBool(meta->fHasCustomColorOutput);
	writer.writeBool(meta->fHasSecondaryColorOutput);
	}
	return writer.snapshotAsData();
	}

	static inline void UnpackCachedShaders(SkReader32* reader,
	SkSL::String shaders[],
	SkSL::Program::Inputs inputs[],
	int numInputs,
	ShaderMetadata* meta = nullptr) {
	for (int i = 0; i < kGrShaderTypeCount; ++i) {
	size_t stringLen = 0;
	const char* string = reader->readString(&stringLen);
	shaders[i] = SkSL::String(string, stringLen);

	// GL, for example, only wants one set of Inputs
	if (i < numInputs) {
	reader->read(&inputs[i], sizeof(inputs[i]));
	} else {
	reader->skip(sizeof(SkSL::Program::Inputs));
	}
	}
	if (reader->readBool() && meta) {
	SkASSERT(meta->fSettings != nullptr);

	if (reader->readBool()) {
	meta->fSettings->fFlipY = reader->readBool();
	meta->fSettings->fFragColorIsInOut = reader->readBool();
	meta->fSettings->fForceHighPrecision = reader->readBool();
	}

	meta->fAttributeNames.resize(reader->readInt());
	for (int i = 0; i < meta->fAttributeNames.count(); ++i) {
	size_t stringLen = 0;
	const char* string = reader->readString(&stringLen);
	meta->fAttributeNames[i] = SkSL::String(string, stringLen);
	}

	meta->fHasCustomColorOutput = reader->readBool();
	meta->fHasSecondaryColorOutput = reader->readBool();
	}
	}

	}

	#endif