/* * Copyright 2018 Google Inc. * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #include "include/utils/SkBase64.h" #include "src/core/SkMD5.h" #include "src/gpu/GrPersistentCacheUtils.h" #include "tools/gpu/MemoryCache.h" #if defined(SK_VULKAN) #include "src/gpu/vk/GrVkGpu.h" #endif // Change this to 1 to log cache hits/misses/stores using SkDebugf. #define LOG_MEMORY_CACHE 0 static SkString data_to_str(const SkData& data) { size_t encodeLength = SkBase64::Encode(data.data(), data.size(), nullptr); SkString str; str.resize(encodeLength); SkBase64::Encode(data.data(), data.size(), str.writable_str()); static constexpr size_t kMaxLength = 60; static constexpr char kTail[] = "..."; static const size_t kTailLen = strlen(kTail); bool overlength = encodeLength > kMaxLength; if (overlength) { str = SkString(str.c_str(), kMaxLength - kTailLen); str.append(kTail); } return str; } namespace sk_gpu_test { sk_sp MemoryCache::load(const SkData& key) { auto result = fMap.find(key); if (result == fMap.end()) { if (LOG_MEMORY_CACHE) { SkDebugf("Load Key: %s\n\tNot Found.\n\n", data_to_str(key).c_str()); } ++fCacheMissCnt; return nullptr; } if (LOG_MEMORY_CACHE) { SkDebugf("Load Key: %s\n\tFound Data: %s\n\n", data_to_str(key).c_str(), data_to_str(*result->second.fData).c_str()); } result->second.fHitCount++; return result->second.fData; } void MemoryCache::store(const SkData& key, const SkData& data) { if (LOG_MEMORY_CACHE) { SkDebugf("Store Key: %s\n\tData: %s\n\n", data_to_str(key).c_str(), data_to_str(data).c_str()); } fMap[Key(key)] = Value(data); } void MemoryCache::writeShadersToDisk(const char* path, GrBackendApi api) { if (GrBackendApi::kOpenGL != api && GrBackendApi::kVulkan != api) { return; } for (auto it = fMap.begin(); it != fMap.end(); ++it) { SkMD5 hash; size_t bytesToHash = it->first.fKey->size(); #if defined(SK_VULKAN) if (GrBackendApi::kVulkan == api) { // Vulkan stores two kinds of data in the cache (shaders and pipelines). The last four // bytes of the key identify which one we have. We only want to extract shaders. // Additionally, we don't want to hash the tag bytes, so we get the same keys as GL, // which is good for cross-checking code generation and performance. GrVkGpu::PersistentCacheKeyType vkKeyType; SkASSERT(bytesToHash >= sizeof(vkKeyType)); bytesToHash -= sizeof(vkKeyType); memcpy(&vkKeyType, it->first.fKey->bytes() + bytesToHash, sizeof(vkKeyType)); if (vkKeyType != GrVkGpu::kShader_PersistentCacheKeyType) { continue; } } #endif hash.write(it->first.fKey->bytes(), bytesToHash); SkMD5::Digest digest = hash.finish(); SkString md5; for (int i = 0; i < 16; ++i) { md5.appendf("%02x", digest.data[i]); } SkSL::Program::Inputs inputsIgnored[kGrShaderTypeCount]; SkSL::String shaders[kGrShaderTypeCount]; const SkData* data = it->second.fData.get(); // Even with the SPIR-V switches, it seems like we must use .spv, or malisc tries to // run glslang on the input. const char* ext = GrBackendApi::kOpenGL == api ? "frag" : "spv"; SkReader32 reader(data->data(), data->size()); GrPersistentCacheUtils::GetType(&reader); // Shader type tag GrPersistentCacheUtils::UnpackCachedShaders(&reader, shaders, inputsIgnored, kGrShaderTypeCount); SkString filename = SkStringPrintf("%s/%s.%s", path, md5.c_str(), ext); SkFILEWStream file(filename.c_str()); file.write(shaders[kFragment_GrShaderType].c_str(), shaders[kFragment_GrShaderType].size()); } } } // namespace sk_gpu_test