// Copyright 2018 Dolphin Emulator Project // SPDX-License-Identifier: GPL-2.0-or-later #include "VideoCommon/ShaderCache.h" #include #include "Common/Assert.h" #include "Common/FileUtil.h" #include "Common/MsgHandler.h" #include "Core/ConfigManager.h" #include "VideoCommon/AbstractGfx.h" #include "VideoCommon/ConstantManager.h" #include "VideoCommon/DriverDetails.h" #include "VideoCommon/FramebufferManager.h" #include "VideoCommon/FramebufferShaderGen.h" #include "VideoCommon/Present.h" #include "VideoCommon/Statistics.h" #include "VideoCommon/VertexLoaderManager.h" #include "VideoCommon/VertexManagerBase.h" #include "VideoCommon/VideoCommon.h" #include "VideoCommon/VideoConfig.h" #include std::unique_ptr g_shader_cache; namespace VideoCommon { ShaderCache::ShaderCache() : m_api_type{APIType::Nothing} { } ShaderCache::~ShaderCache() { ClearCaches(); } bool ShaderCache::Initialize() { m_api_type = g_ActiveConfig.backend_info.api_type; m_host_config.bits = ShaderHostConfig::GetCurrent().bits; if (!CompileSharedPipelines()) return false; m_async_shader_compiler = g_gfx->CreateAsyncShaderCompiler(); m_frame_end_handler = AfterFrameEvent::Register([this](Core::System&) { RetrieveAsyncShaders(); }, "RetrieveAsyncShaders"); return true; } void ShaderCache::InitializeShaderCache() { m_async_shader_compiler->ResizeWorkerThreads(g_ActiveConfig.GetShaderPrecompilerThreads()); // Load shader and UID caches. if (g_ActiveConfig.bShaderCache && m_api_type != APIType::Nothing) { LoadCaches(); LoadPipelineUIDCache(); } // Queue ubershader precompiling if required. if (g_ActiveConfig.UsingUberShaders()) QueueUberShaderPipelines(); // Compile all known UIDs. CompileMissingPipelines(); if (g_ActiveConfig.bWaitForShadersBeforeStarting) WaitForAsyncCompiler(); // Switch to the runtime shader compiler thread configuration. m_async_shader_compiler->ResizeWorkerThreads(g_ActiveConfig.GetShaderCompilerThreads()); } void ShaderCache::Reload() { WaitForAsyncCompiler(); ClosePipelineUIDCache(); ClearCaches(); if (!CompileSharedPipelines()) PanicAlertFmt("Failed to compile shared pipelines after reload."); if (g_ActiveConfig.bShaderCache) LoadCaches(); // Switch to the precompiling shader configuration while we rebuild. m_async_shader_compiler->ResizeWorkerThreads(g_ActiveConfig.GetShaderPrecompilerThreads()); // We don't need to explicitly recompile the individual ubershaders here, as the pipelines // UIDs are still be in the map. Therefore, when these are rebuilt, the shaders will also // be recompiled. CompileMissingPipelines(); if (g_ActiveConfig.bWaitForShadersBeforeStarting) WaitForAsyncCompiler(); m_async_shader_compiler->ResizeWorkerThreads(g_ActiveConfig.GetShaderCompilerThreads()); } void ShaderCache::RetrieveAsyncShaders() { m_async_shader_compiler->RetrieveWorkItems(); } void ShaderCache::Shutdown() { // This may leave shaders uncommitted to the cache, but it's better than blocking shutdown // until everything has finished compiling. if (m_async_shader_compiler) m_async_shader_compiler->StopWorkerThreads(); ClosePipelineUIDCache(); } const AbstractPipeline* ShaderCache::GetPipelineForUid(const GXPipelineUid& uid) { auto it = m_gx_pipeline_cache.find(uid); if (it != m_gx_pipeline_cache.end() && !it->second.second) return it->second.first.get(); const bool exists_in_cache = it != m_gx_pipeline_cache.end(); std::unique_ptr pipeline; std::optional pipeline_config = GetGXPipelineConfig(uid); if (pipeline_config) pipeline = g_gfx->CreatePipeline(*pipeline_config); if (g_ActiveConfig.bShaderCache && !exists_in_cache) AppendGXPipelineUID(uid); return InsertGXPipeline(uid, std::move(pipeline)); } std::optional ShaderCache::GetPipelineForUidAsync(const GXPipelineUid& uid) { auto it = m_gx_pipeline_cache.find(uid); if (it != m_gx_pipeline_cache.end()) { // .second is the pending flag, i.e. compiling in the background. if (!it->second.second) return it->second.first.get(); else return {}; } AppendGXPipelineUID(uid); QueuePipelineCompile(uid, COMPILE_PRIORITY_ONDEMAND_PIPELINE); return {}; } const AbstractPipeline* ShaderCache::GetUberPipelineForUid(const GXUberPipelineUid& uid) { auto it = m_gx_uber_pipeline_cache.find(uid); if (it != m_gx_uber_pipeline_cache.end() && !it->second.second) return it->second.first.get(); std::unique_ptr pipeline; std::optional pipeline_config = GetGXPipelineConfig(uid); if (pipeline_config) pipeline = g_gfx->CreatePipeline(*pipeline_config); return InsertGXUberPipeline(uid, std::move(pipeline)); } void ShaderCache::WaitForAsyncCompiler() { bool running = true; constexpr auto update_ui_progress = [](size_t completed, size_t total) { const float center_x = ImGui::GetIO().DisplaySize.x * 0.5f; const float center_y = ImGui::GetIO().DisplaySize.y * 0.5f; const float scale = ImGui::GetIO().DisplayFramebufferScale.x; ImGui::SetNextWindowSize(ImVec2(400.0f * scale, 50.0f * scale), ImGuiCond_Always); ImGui::SetNextWindowPos(ImVec2(center_x, center_y), ImGuiCond_Always, ImVec2(0.5f, 0.5f)); if (ImGui::Begin(Common::GetStringT("Compiling Shaders").c_str(), nullptr, ImGuiWindowFlags_NoTitleBar | ImGuiWindowFlags_NoInputs | ImGuiWindowFlags_NoMove | ImGuiWindowFlags_NoSavedSettings | ImGuiWindowFlags_NoScrollbar | ImGuiWindowFlags_NoNav | ImGuiWindowFlags_AlwaysAutoResize | ImGuiWindowFlags_NoFocusOnAppearing)) { ImGui::Text("Compiling shaders: %zu/%zu", completed, total); ImGui::ProgressBar(static_cast(completed) / static_cast(std::max(total, static_cast(1))), ImVec2(-1.0f, 0.0f), ""); } ImGui::End(); g_presenter->Present(); }; while (running && (m_async_shader_compiler->HasPendingWork() || m_async_shader_compiler->HasCompletedWork())) { running = m_async_shader_compiler->WaitUntilCompletion(update_ui_progress); m_async_shader_compiler->RetrieveWorkItems(); } // An extra Present to clear the screen g_presenter->Present(); } template static void SerializePipelineUid(const UidType& uid, SerializedUidType& serialized_uid) { // Convert to disk format. Ensure all padding bytes are zero. std::memset(reinterpret_cast(&serialized_uid), 0, sizeof(serialized_uid)); serialized_uid.vertex_decl = uid.vertex_format->GetVertexDeclaration(); serialized_uid.vs_uid = uid.vs_uid; serialized_uid.gs_uid = uid.gs_uid; serialized_uid.ps_uid = uid.ps_uid; serialized_uid.rasterization_state_bits = uid.rasterization_state.hex; serialized_uid.depth_state_bits = uid.depth_state.hex; serialized_uid.blending_state_bits = uid.blending_state.hex; } template static void UnserializePipelineUid(const SerializedUidType& uid, UidType& real_uid) { real_uid.vertex_format = VertexLoaderManager::GetOrCreateMatchingFormat(uid.vertex_decl); real_uid.vs_uid = uid.vs_uid; real_uid.gs_uid = uid.gs_uid; real_uid.ps_uid = uid.ps_uid; real_uid.rasterization_state.hex = uid.rasterization_state_bits; real_uid.depth_state.hex = uid.depth_state_bits; real_uid.blending_state.hex = uid.blending_state_bits; } template void ShaderCache::LoadShaderCache(T& cache, APIType api_type, const char* type, bool include_gameid) { class CacheReader : public Common::LinearDiskCacheReader { public: CacheReader(T& cache_) : cache(cache_) {} void Read(const K& key, const u8* value, u32 value_size) override { auto shader = g_gfx->CreateShaderFromBinary(stage, value, value_size); if (shader) { auto& entry = cache.shader_map[key]; entry.shader = std::move(shader); entry.pending = false; switch (stage) { case ShaderStage::Vertex: INCSTAT(g_stats.num_vertex_shaders_created); INCSTAT(g_stats.num_vertex_shaders_alive); break; case ShaderStage::Pixel: INCSTAT(g_stats.num_pixel_shaders_created); INCSTAT(g_stats.num_pixel_shaders_alive); break; default: break; } } } private: T& cache; }; std::string filename = GetDiskShaderCacheFileName(api_type, type, include_gameid, true); CacheReader reader(cache); u32 count = cache.disk_cache.OpenAndRead(filename, reader); INFO_LOG_FMT(VIDEO, "Loaded {} cached shaders from {}", count, filename); } template void ShaderCache::ClearShaderCache(T& cache) { cache.disk_cache.Sync(); cache.disk_cache.Close(); cache.shader_map.clear(); } template void ShaderCache::LoadPipelineCache(T& cache, Common::LinearDiskCache& disk_cache, APIType api_type, const char* type, bool include_gameid) { class CacheReader : public Common::LinearDiskCacheReader { public: CacheReader(ShaderCache* this_ptr_, T& cache_) : this_ptr(this_ptr_), cache(cache_) {} bool AnyFailed() const { return failed; } void Read(const DiskKeyType& key, const u8* value, u32 value_size) override { KeyType real_uid; UnserializePipelineUid(key, real_uid); // Skip those which are already compiled. if (failed || cache.find(real_uid) != cache.end()) return; auto config = this_ptr->GetGXPipelineConfig(real_uid); if (!config) return; auto pipeline = g_gfx->CreatePipeline(*config, value, value_size); if (!pipeline) { // If any of the pipelines fail to create, consider the cache stale. failed = true; return; } auto& entry = cache[real_uid]; entry.first = std::move(pipeline); entry.second = false; } private: ShaderCache* this_ptr; T& cache; bool failed = false; }; std::string filename = GetDiskShaderCacheFileName(api_type, type, include_gameid, true); CacheReader reader(this, cache); const u32 count = disk_cache.OpenAndRead(filename, reader); INFO_LOG_FMT(VIDEO, "Loaded {} cached pipelines from {}", count, filename); // If any of the pipelines in the cache failed to create, it's likely because of a change of // driver version, or system configuration. In this case, when the UID cache picks up the pipeline // later on, we'll write a duplicate entry to the pipeline cache. There's also no point in keeping // the old cache data around, so discard and recreate the disk cache. if (reader.AnyFailed()) { WARN_LOG_FMT(VIDEO, "Failed to load one or more pipelines from cache '{}'. Discarding.", filename); disk_cache.Close(); File::Delete(filename); disk_cache.OpenAndRead(filename, reader); } } template void ShaderCache::ClearPipelineCache(T& cache, Y& disk_cache) { disk_cache.Sync(); disk_cache.Close(); // Set the pending flag to false, and destroy the pipeline. for (auto& it : cache) { it.second.first.reset(); it.second.second = false; } } void ShaderCache::LoadCaches() { // Ubershader caches, if present. if (g_ActiveConfig.backend_info.bSupportsShaderBinaries) { LoadShaderCache(m_uber_vs_cache, m_api_type, "uber-vs", false); LoadShaderCache(m_uber_ps_cache, m_api_type, "uber-ps", false); // We also share geometry shaders, as there aren't many variants. if (m_host_config.backend_geometry_shaders) LoadShaderCache(m_gs_cache, m_api_type, "gs", false); // Specialized shaders, gameid-specific. LoadShaderCache(m_vs_cache, m_api_type, "specialized-vs", true); LoadShaderCache(m_ps_cache, m_api_type, "specialized-ps", true); } if (g_ActiveConfig.backend_info.bSupportsPipelineCacheData) { LoadPipelineCache( m_gx_pipeline_cache, m_gx_pipeline_disk_cache, m_api_type, "specialized-pipeline", true); LoadPipelineCache( m_gx_uber_pipeline_cache, m_gx_uber_pipeline_disk_cache, m_api_type, "uber-pipeline", false); } } void ShaderCache::ClearCaches() { ClearPipelineCache(m_gx_pipeline_cache, m_gx_pipeline_disk_cache); ClearShaderCache(m_vs_cache); ClearShaderCache(m_gs_cache); ClearShaderCache(m_ps_cache); ClearPipelineCache(m_gx_uber_pipeline_cache, m_gx_uber_pipeline_disk_cache); ClearShaderCache(m_uber_vs_cache); ClearShaderCache(m_uber_ps_cache); m_screen_quad_vertex_shader.reset(); m_texture_copy_vertex_shader.reset(); m_efb_copy_vertex_shader.reset(); m_texcoord_geometry_shader.reset(); m_color_geometry_shader.reset(); m_texture_copy_pixel_shader.reset(); m_color_pixel_shader.reset(); m_efb_copy_to_vram_pipelines.clear(); m_efb_copy_to_ram_pipelines.clear(); m_copy_rgba8_pipeline.reset(); m_rgba8_stereo_copy_pipeline.reset(); for (auto& pipeline : m_palette_conversion_pipelines) pipeline.reset(); m_texture_reinterpret_pipelines.clear(); m_texture_decoding_shaders.clear(); SETSTAT(g_stats.num_pixel_shaders_created, 0); SETSTAT(g_stats.num_pixel_shaders_alive, 0); SETSTAT(g_stats.num_vertex_shaders_created, 0); SETSTAT(g_stats.num_vertex_shaders_alive, 0); } void ShaderCache::CompileMissingPipelines() { // Queue all uids with a null pipeline for compilation. for (auto& it : m_gx_pipeline_cache) { if (!it.second.first) QueuePipelineCompile(it.first, COMPILE_PRIORITY_SHADERCACHE_PIPELINE); } for (auto& it : m_gx_uber_pipeline_cache) { if (!it.second.first) QueueUberPipelineCompile(it.first, COMPILE_PRIORITY_UBERSHADER_PIPELINE); } } std::unique_ptr ShaderCache::CompileVertexShader(const VertexShaderUid& uid) const { const ShaderCode source_code = GenerateVertexShaderCode(m_api_type, m_host_config, uid.GetUidData()); return g_gfx->CreateShaderFromSource(ShaderStage::Vertex, source_code.GetBuffer()); } std::unique_ptr ShaderCache::CompileVertexUberShader(const UberShader::VertexShaderUid& uid) const { const ShaderCode source_code = UberShader::GenVertexShader(m_api_type, m_host_config, uid.GetUidData()); return g_gfx->CreateShaderFromSource(ShaderStage::Vertex, source_code.GetBuffer(), fmt::to_string(*uid.GetUidData())); } std::unique_ptr ShaderCache::CompilePixelShader(const PixelShaderUid& uid) const { const ShaderCode source_code = GeneratePixelShaderCode(m_api_type, m_host_config, uid.GetUidData(), {}); return g_gfx->CreateShaderFromSource(ShaderStage::Pixel, source_code.GetBuffer()); } std::unique_ptr ShaderCache::CompilePixelUberShader(const UberShader::PixelShaderUid& uid) const { const ShaderCode source_code = UberShader::GenPixelShader(m_api_type, m_host_config, uid.GetUidData(), {}); return g_gfx->CreateShaderFromSource(ShaderStage::Pixel, source_code.GetBuffer(), fmt::to_string(*uid.GetUidData())); } const AbstractShader* ShaderCache::InsertVertexShader(const VertexShaderUid& uid, std::unique_ptr shader) { auto& entry = m_vs_cache.shader_map[uid]; entry.pending = false; if (shader && !entry.shader) { if (g_ActiveConfig.bShaderCache && g_ActiveConfig.backend_info.bSupportsShaderBinaries) { auto binary = shader->GetBinary(); if (!binary.empty()) m_vs_cache.disk_cache.Append(uid, binary.data(), static_cast(binary.size())); } INCSTAT(g_stats.num_vertex_shaders_created); INCSTAT(g_stats.num_vertex_shaders_alive); entry.shader = std::move(shader); } return entry.shader.get(); } const AbstractShader* ShaderCache::InsertVertexUberShader(const UberShader::VertexShaderUid& uid, std::unique_ptr shader) { auto& entry = m_uber_vs_cache.shader_map[uid]; entry.pending = false; if (shader && !entry.shader) { if (g_ActiveConfig.bShaderCache && g_ActiveConfig.backend_info.bSupportsShaderBinaries) { auto binary = shader->GetBinary(); if (!binary.empty()) m_uber_vs_cache.disk_cache.Append(uid, binary.data(), static_cast(binary.size())); } INCSTAT(g_stats.num_vertex_shaders_created); INCSTAT(g_stats.num_vertex_shaders_alive); entry.shader = std::move(shader); } return entry.shader.get(); } const AbstractShader* ShaderCache::InsertPixelShader(const PixelShaderUid& uid, std::unique_ptr shader) { auto& entry = m_ps_cache.shader_map[uid]; entry.pending = false; if (shader && !entry.shader) { if (g_ActiveConfig.bShaderCache && g_ActiveConfig.backend_info.bSupportsShaderBinaries) { auto binary = shader->GetBinary(); if (!binary.empty()) m_ps_cache.disk_cache.Append(uid, binary.data(), static_cast(binary.size())); } INCSTAT(g_stats.num_pixel_shaders_created); INCSTAT(g_stats.num_pixel_shaders_alive); entry.shader = std::move(shader); } return entry.shader.get(); } const AbstractShader* ShaderCache::InsertPixelUberShader(const UberShader::PixelShaderUid& uid, std::unique_ptr shader) { auto& entry = m_uber_ps_cache.shader_map[uid]; entry.pending = false; if (shader && !entry.shader) { if (g_ActiveConfig.bShaderCache && g_ActiveConfig.backend_info.bSupportsShaderBinaries) { auto binary = shader->GetBinary(); if (!binary.empty()) m_uber_ps_cache.disk_cache.Append(uid, binary.data(), static_cast(binary.size())); } INCSTAT(g_stats.num_pixel_shaders_created); INCSTAT(g_stats.num_pixel_shaders_alive); entry.shader = std::move(shader); } return entry.shader.get(); } const AbstractShader* ShaderCache::CreateGeometryShader(const GeometryShaderUid& uid) { const ShaderCode source_code = GenerateGeometryShaderCode(m_api_type, m_host_config, uid.GetUidData()); std::unique_ptr shader = g_gfx->CreateShaderFromSource(ShaderStage::Geometry, source_code.GetBuffer(), fmt::format("Geometry shader: {}", *uid.GetUidData())); auto& entry = m_gs_cache.shader_map[uid]; entry.pending = false; if (shader && !entry.shader) { if (g_ActiveConfig.bShaderCache && g_ActiveConfig.backend_info.bSupportsShaderBinaries) { auto binary = shader->GetBinary(); if (!binary.empty()) m_gs_cache.disk_cache.Append(uid, binary.data(), static_cast(binary.size())); } entry.shader = std::move(shader); } return entry.shader.get(); } bool ShaderCache::NeedsGeometryShader(const GeometryShaderUid& uid) const { return m_host_config.backend_geometry_shaders && !uid.GetUidData()->IsPassthrough(); } bool ShaderCache::UseGeometryShaderForEFBCopies() const { return m_host_config.backend_geometry_shaders && m_host_config.stereo; } AbstractPipelineConfig ShaderCache::GetGXPipelineConfig( const NativeVertexFormat* vertex_format, const AbstractShader* vertex_shader, const AbstractShader* geometry_shader, const AbstractShader* pixel_shader, const RasterizationState& rasterization_state, const DepthState& depth_state, const BlendingState& blending_state, AbstractPipelineUsage usage) { AbstractPipelineConfig config = {}; config.usage = usage; config.vertex_format = vertex_format; config.vertex_shader = vertex_shader; config.geometry_shader = geometry_shader; config.pixel_shader = pixel_shader; config.rasterization_state = rasterization_state; config.depth_state = depth_state; config.blending_state = blending_state; config.framebuffer_state = g_framebuffer_manager->GetEFBFramebufferState(); return config; } /// Edits the UID based on driver bugs and other special configurations static GXPipelineUid ApplyDriverBugs(const GXPipelineUid& in) { GXPipelineUid out; // TODO: static_assert(std::is_trivially_copyable_v); // GXPipelineUid is not trivially copyable because RasterizationState and BlendingState aren't // either, but we can pretend it is for now. This will be improved after PR #10848 is finished. memcpy(static_cast(&out), static_cast(&in), sizeof(out)); // copy padding pixel_shader_uid_data* ps = out.ps_uid.GetUidData(); BlendingState& blend = out.blending_state; if (ps->ztest == EmulatedZ::ForcedEarly && !out.depth_state.updateenable) { // No need to force early depth test if you're not writing z ps->ztest = EmulatedZ::Early; } // If framebuffer fetch is available, we can emulate logic ops in the fragment shader // and don't need the below blend approximation if (blend.logicopenable && !g_ActiveConfig.backend_info.bSupportsLogicOp && !g_ActiveConfig.backend_info.bSupportsFramebufferFetch) { if (!blend.LogicOpApproximationIsExact()) WARN_LOG_FMT(VIDEO, "Approximating logic op with blending, this will produce incorrect rendering."); if (blend.LogicOpApproximationWantsShaderHelp()) { ps->emulate_logic_op_with_blend = true; ps->logic_op_mode = static_cast(blend.logicmode.Value()); } blend.ApproximateLogicOpWithBlending(); } const bool benefits_from_ps_dual_source_off = (!g_ActiveConfig.backend_info.bSupportsDualSourceBlend && g_ActiveConfig.backend_info.bSupportsFramebufferFetch) || DriverDetails::HasBug(DriverDetails::BUG_BROKEN_DUAL_SOURCE_BLENDING); if (benefits_from_ps_dual_source_off && !blend.RequiresDualSrc()) { // Only use dual-source blending when required on drivers that don't support it very well. ps->no_dual_src = true; blend.usedualsrc = false; } if (g_ActiveConfig.backend_info.bSupportsFramebufferFetch) { bool fbfetch_blend = false; if ((DriverDetails::HasBug(DriverDetails::BUG_BROKEN_DISCARD_WITH_EARLY_Z) || !g_ActiveConfig.backend_info.bSupportsEarlyZ) && ps->ztest == EmulatedZ::ForcedEarly) { ps->ztest = EmulatedZ::EarlyWithFBFetch; fbfetch_blend |= static_cast(out.blending_state.blendenable); ps->no_dual_src = true; } fbfetch_blend |= blend.logicopenable && !g_ActiveConfig.backend_info.bSupportsLogicOp; fbfetch_blend |= blend.usedualsrc && !g_ActiveConfig.backend_info.bSupportsDualSourceBlend; if (fbfetch_blend) { ps->no_dual_src = true; if (blend.logicopenable) { ps->logic_op_enable = true; ps->logic_op_mode = static_cast(blend.logicmode.Value()); blend.logicopenable = false; } if (blend.blendenable) { ps->blend_enable = true; ps->blend_src_factor = blend.srcfactor; ps->blend_src_factor_alpha = blend.srcfactoralpha; ps->blend_dst_factor = blend.dstfactor; ps->blend_dst_factor_alpha = blend.dstfactoralpha; ps->blend_subtract = blend.subtract; ps->blend_subtract_alpha = blend.subtractAlpha; blend.blendenable = false; } } } // force dual src off if we can't support it if (!g_ActiveConfig.backend_info.bSupportsDualSourceBlend) { ps->no_dual_src = true; blend.usedualsrc = false; } if (ps->ztest == EmulatedZ::ForcedEarly && !g_ActiveConfig.backend_info.bSupportsEarlyZ) { // These things should be false ASSERT(!ps->zfreeze); // ZCOMPLOC HACK: // The only way to emulate alpha test + early-z is to force early-z in the shader. // As this isn't available on all drivers and as we can't emulate this feature otherwise, // we are only able to choose which one we want to respect more. // Tests seem to have proven that writing depth even when the alpha test fails is more // important that a reliable alpha test, so we just force the alpha test to always succeed. // At least this seems to be less buggy. ps->ztest = EmulatedZ::EarlyWithZComplocHack; } if (g_ActiveConfig.UseVSForLinePointExpand() && (out.rasterization_state.primitive == PrimitiveType::Points || out.rasterization_state.primitive == PrimitiveType::Lines)) { // All primitives are expanded to triangles in the vertex shader vertex_shader_uid_data* vs = out.vs_uid.GetUidData(); const PortableVertexDeclaration& decl = out.vertex_format->GetVertexDeclaration(); vs->position_has_3_elems = decl.position.components >= 3; vs->texcoord_elem_count = 0; for (int i = 0; i < 8; i++) { if (decl.texcoords[i].enable) { ASSERT(decl.texcoords[i].components <= 3); vs->texcoord_elem_count |= decl.texcoords[i].components << (i * 2); } } out.vertex_format = nullptr; if (out.rasterization_state.primitive == PrimitiveType::Points) vs->vs_expand = VSExpand::Point; else vs->vs_expand = VSExpand::Line; PrimitiveType prim = g_ActiveConfig.backend_info.bSupportsPrimitiveRestart ? PrimitiveType::TriangleStrip : PrimitiveType::Triangles; out.rasterization_state.primitive = prim; out.gs_uid.GetUidData()->primitive_type = static_cast(prim); } return out; } std::optional ShaderCache::GetGXPipelineConfig(const GXPipelineUid& config_in) { GXPipelineUid config = ApplyDriverBugs(config_in); const AbstractShader* vs; auto vs_iter = m_vs_cache.shader_map.find(config.vs_uid); if (vs_iter != m_vs_cache.shader_map.end() && !vs_iter->second.pending) vs = vs_iter->second.shader.get(); else vs = InsertVertexShader(config.vs_uid, CompileVertexShader(config.vs_uid)); PixelShaderUid ps_uid = config.ps_uid; ClearUnusedPixelShaderUidBits(m_api_type, m_host_config, &ps_uid); const AbstractShader* ps; auto ps_iter = m_ps_cache.shader_map.find(ps_uid); if (ps_iter != m_ps_cache.shader_map.end() && !ps_iter->second.pending) ps = ps_iter->second.shader.get(); else ps = InsertPixelShader(ps_uid, CompilePixelShader(ps_uid)); if (!vs || !ps) return {}; const AbstractShader* gs = nullptr; if (NeedsGeometryShader(config.gs_uid)) { auto gs_iter = m_gs_cache.shader_map.find(config.gs_uid); if (gs_iter != m_gs_cache.shader_map.end() && !gs_iter->second.pending) gs = gs_iter->second.shader.get(); else gs = CreateGeometryShader(config.gs_uid); if (!gs) return {}; } return GetGXPipelineConfig(config.vertex_format, vs, gs, ps, config.rasterization_state, config.depth_state, config.blending_state, AbstractPipelineUsage::GX); } /// Edits the UID based on driver bugs and other special configurations static GXUberPipelineUid ApplyDriverBugs(const GXUberPipelineUid& in) { GXUberPipelineUid out; // TODO: static_assert(std::is_trivially_copyable_v); // GXUberPipelineUid is not trivially copyable because RasterizationState and BlendingState aren't // either, but we can pretend it is for now. This will be improved after PR #10848 is finished. memcpy(static_cast(&out), static_cast(&in), sizeof(out)); // Copy padding if (g_ActiveConfig.backend_info.bSupportsDynamicVertexLoader) out.vertex_format = nullptr; // If framebuffer fetch is available, we can emulate logic ops in the fragment shader // and don't need the below blend approximation if (out.blending_state.logicopenable && !g_ActiveConfig.backend_info.bSupportsLogicOp && !g_ActiveConfig.backend_info.bSupportsFramebufferFetch) { if (!out.blending_state.LogicOpApproximationIsExact()) WARN_LOG_FMT(VIDEO, "Approximating logic op with blending, this will produce incorrect rendering."); out.blending_state.ApproximateLogicOpWithBlending(); } if (g_ActiveConfig.backend_info.bSupportsFramebufferFetch) { // Always blend in shader out.blending_state.hex = 0; out.blending_state.colorupdate = in.blending_state.colorupdate.Value(); out.blending_state.alphaupdate = in.blending_state.alphaupdate.Value(); out.ps_uid.GetUidData()->no_dual_src = true; } else if (!g_ActiveConfig.backend_info.bSupportsDualSourceBlend || (DriverDetails::HasBug(DriverDetails::BUG_BROKEN_DUAL_SOURCE_BLENDING) && !out.blending_state.RequiresDualSrc())) { out.blending_state.usedualsrc = false; out.ps_uid.GetUidData()->no_dual_src = true; } if (g_ActiveConfig.UseVSForLinePointExpand()) { // All primitives are expanded to triangles in the vertex shader PrimitiveType prim = g_ActiveConfig.backend_info.bSupportsPrimitiveRestart ? PrimitiveType::TriangleStrip : PrimitiveType::Triangles; out.rasterization_state.primitive = prim; out.gs_uid.GetUidData()->primitive_type = static_cast(prim); } return out; } std::optional ShaderCache::GetGXPipelineConfig(const GXUberPipelineUid& config_in) { GXUberPipelineUid config = ApplyDriverBugs(config_in); const AbstractShader* vs; auto vs_iter = m_uber_vs_cache.shader_map.find(config.vs_uid); if (vs_iter != m_uber_vs_cache.shader_map.end() && !vs_iter->second.pending) vs = vs_iter->second.shader.get(); else vs = InsertVertexUberShader(config.vs_uid, CompileVertexUberShader(config.vs_uid)); UberShader::PixelShaderUid ps_uid = config.ps_uid; UberShader::ClearUnusedPixelShaderUidBits(m_api_type, m_host_config, &ps_uid); const AbstractShader* ps; auto ps_iter = m_uber_ps_cache.shader_map.find(ps_uid); if (ps_iter != m_uber_ps_cache.shader_map.end() && !ps_iter->second.pending) ps = ps_iter->second.shader.get(); else ps = InsertPixelUberShader(ps_uid, CompilePixelUberShader(ps_uid)); if (!vs || !ps) return {}; const AbstractShader* gs = nullptr; if (NeedsGeometryShader(config.gs_uid)) { auto gs_iter = m_gs_cache.shader_map.find(config.gs_uid); if (gs_iter != m_gs_cache.shader_map.end() && !gs_iter->second.pending) gs = gs_iter->second.shader.get(); else gs = CreateGeometryShader(config.gs_uid); if (!gs) return {}; } return GetGXPipelineConfig(config.vertex_format, vs, gs, ps, config.rasterization_state, config.depth_state, config.blending_state, AbstractPipelineUsage::GXUber); } const AbstractPipeline* ShaderCache::InsertGXPipeline(const GXPipelineUid& config, std::unique_ptr pipeline) { auto& entry = m_gx_pipeline_cache[config]; entry.second = false; if (!entry.first && pipeline) { entry.first = std::move(pipeline); if (g_ActiveConfig.bShaderCache) { auto cache_data = entry.first->GetCacheData(); if (!cache_data.empty()) { SerializedGXPipelineUid disk_uid; SerializePipelineUid(config, disk_uid); m_gx_pipeline_disk_cache.Append(disk_uid, cache_data.data(), static_cast(cache_data.size())); } } } return entry.first.get(); } const AbstractPipeline* ShaderCache::InsertGXUberPipeline(const GXUberPipelineUid& config, std::unique_ptr pipeline) { auto& entry = m_gx_uber_pipeline_cache[config]; entry.second = false; if (!entry.first && pipeline) { entry.first = std::move(pipeline); if (g_ActiveConfig.bShaderCache) { auto cache_data = entry.first->GetCacheData(); if (!cache_data.empty()) { SerializedGXUberPipelineUid disk_uid; SerializePipelineUid(config, disk_uid); m_gx_uber_pipeline_disk_cache.Append(disk_uid, cache_data.data(), static_cast(cache_data.size())); } } } return entry.first.get(); } void ShaderCache::LoadPipelineUIDCache() { constexpr u32 CACHE_FILE_MAGIC = 0x44495550; // PUID constexpr size_t CACHE_HEADER_SIZE = sizeof(u32) + sizeof(u32); std::string filename = File::GetUserPath(D_CACHE_IDX) + SConfig::GetInstance().GetGameID() + ".uidcache"; if (m_gx_pipeline_uid_cache_file.Open(filename, "rb+")) { // If an existing case exists, validate the version before reading entries. u32 existing_magic; u32 existing_version; bool uid_file_valid = false; if (m_gx_pipeline_uid_cache_file.ReadBytes(&existing_magic, sizeof(existing_magic)) && m_gx_pipeline_uid_cache_file.ReadBytes(&existing_version, sizeof(existing_version)) && existing_magic == CACHE_FILE_MAGIC && existing_version == GX_PIPELINE_UID_VERSION) { // Ensure the expected size matches the actual size of the file. If it doesn't, it means // the cache file may be corrupted, and we should not proceed with loading potentially // garbage or invalid UIDs. const u64 file_size = m_gx_pipeline_uid_cache_file.GetSize(); const size_t uid_count = static_cast(file_size - CACHE_HEADER_SIZE) / sizeof(SerializedGXPipelineUid); const size_t expected_size = uid_count * sizeof(SerializedGXPipelineUid) + CACHE_HEADER_SIZE; uid_file_valid = file_size == expected_size; if (uid_file_valid) { for (size_t i = 0; i < uid_count; i++) { SerializedGXPipelineUid serialized_uid; if (m_gx_pipeline_uid_cache_file.ReadBytes(&serialized_uid, sizeof(serialized_uid))) { // This just adds the pipeline to the map, it is compiled later. AddSerializedGXPipelineUID(serialized_uid); } else { uid_file_valid = false; break; } } } // We open the file for reading and writing, so we must seek to the end before writing. if (uid_file_valid) uid_file_valid = m_gx_pipeline_uid_cache_file.Seek(expected_size, File::SeekOrigin::Begin); } // If the file is invalid, close it. We re-open and truncate it below. if (!uid_file_valid) m_gx_pipeline_uid_cache_file.Close(); } // If the file is not open, it means it was either corrupted or didn't exist. if (!m_gx_pipeline_uid_cache_file.IsOpen()) { if (m_gx_pipeline_uid_cache_file.Open(filename, "wb")) { // Write the version identifier. m_gx_pipeline_uid_cache_file.WriteBytes(&CACHE_FILE_MAGIC, sizeof(GX_PIPELINE_UID_VERSION)); m_gx_pipeline_uid_cache_file.WriteBytes(&GX_PIPELINE_UID_VERSION, sizeof(GX_PIPELINE_UID_VERSION)); // Write any current UIDs out to the file. // This way, if we load a UID cache where the data was incomplete (e.g. Dolphin crashed), // we don't lose the existing UIDs which were previously at the beginning. for (const auto& it : m_gx_pipeline_cache) AppendGXPipelineUID(it.first); } } INFO_LOG_FMT(VIDEO, "Read {} pipeline UIDs from {}", m_gx_pipeline_cache.size(), filename); } void ShaderCache::ClosePipelineUIDCache() { // This is left as a method in case we need to append extra data to the file in the future. m_gx_pipeline_uid_cache_file.Close(); } void ShaderCache::AddSerializedGXPipelineUID(const SerializedGXPipelineUid& uid) { GXPipelineUid real_uid; UnserializePipelineUid(uid, real_uid); auto iter = m_gx_pipeline_cache.find(real_uid); if (iter != m_gx_pipeline_cache.end()) return; // Flag it as empty with a null pipeline object, for later compilation. auto& entry = m_gx_pipeline_cache[real_uid]; entry.second = false; } void ShaderCache::AppendGXPipelineUID(const GXPipelineUid& config) { if (!m_gx_pipeline_uid_cache_file.IsOpen()) return; SerializedGXPipelineUid disk_uid; SerializePipelineUid(config, disk_uid); if (!m_gx_pipeline_uid_cache_file.WriteBytes(&disk_uid, sizeof(disk_uid))) { WARN_LOG_FMT(VIDEO, "Writing pipeline UID to cache failed, closing file."); m_gx_pipeline_uid_cache_file.Close(); } } void ShaderCache::QueueVertexShaderCompile(const VertexShaderUid& uid, u32 priority) { class VertexShaderWorkItem final : public AsyncShaderCompiler::WorkItem { public: VertexShaderWorkItem(ShaderCache* shader_cache_, const VertexShaderUid& uid_) : shader_cache(shader_cache_), uid(uid_) { } bool Compile() override { shader = shader_cache->CompileVertexShader(uid); return true; } void Retrieve() override { shader_cache->InsertVertexShader(uid, std::move(shader)); } private: ShaderCache* shader_cache; std::unique_ptr shader; VertexShaderUid uid; }; m_vs_cache.shader_map[uid].pending = true; auto wi = m_async_shader_compiler->CreateWorkItem(this, uid); m_async_shader_compiler->QueueWorkItem(std::move(wi), priority); } void ShaderCache::QueueVertexUberShaderCompile(const UberShader::VertexShaderUid& uid, u32 priority) { class VertexUberShaderWorkItem final : public AsyncShaderCompiler::WorkItem { public: VertexUberShaderWorkItem(ShaderCache* shader_cache_, const UberShader::VertexShaderUid& uid_) : shader_cache(shader_cache_), uid(uid_) { } bool Compile() override { shader = shader_cache->CompileVertexUberShader(uid); return true; } void Retrieve() override { shader_cache->InsertVertexUberShader(uid, std::move(shader)); } private: ShaderCache* shader_cache; std::unique_ptr shader; UberShader::VertexShaderUid uid; }; m_uber_vs_cache.shader_map[uid].pending = true; auto wi = m_async_shader_compiler->CreateWorkItem(this, uid); m_async_shader_compiler->QueueWorkItem(std::move(wi), priority); } void ShaderCache::QueuePixelShaderCompile(const PixelShaderUid& uid, u32 priority) { class PixelShaderWorkItem final : public AsyncShaderCompiler::WorkItem { public: PixelShaderWorkItem(ShaderCache* shader_cache_, const PixelShaderUid& uid_) : shader_cache(shader_cache_), uid(uid_) { } bool Compile() override { shader = shader_cache->CompilePixelShader(uid); return true; } void Retrieve() override { shader_cache->InsertPixelShader(uid, std::move(shader)); } private: ShaderCache* shader_cache; std::unique_ptr shader; PixelShaderUid uid; }; m_ps_cache.shader_map[uid].pending = true; auto wi = m_async_shader_compiler->CreateWorkItem(this, uid); m_async_shader_compiler->QueueWorkItem(std::move(wi), priority); } void ShaderCache::QueuePixelUberShaderCompile(const UberShader::PixelShaderUid& uid, u32 priority) { class PixelUberShaderWorkItem final : public AsyncShaderCompiler::WorkItem { public: PixelUberShaderWorkItem(ShaderCache* shader_cache_, const UberShader::PixelShaderUid& uid_) : shader_cache(shader_cache_), uid(uid_) { } bool Compile() override { shader = shader_cache->CompilePixelUberShader(uid); return true; } void Retrieve() override { shader_cache->InsertPixelUberShader(uid, std::move(shader)); } private: ShaderCache* shader_cache; std::unique_ptr shader; UberShader::PixelShaderUid uid; }; m_uber_ps_cache.shader_map[uid].pending = true; auto wi = m_async_shader_compiler->CreateWorkItem(this, uid); m_async_shader_compiler->QueueWorkItem(std::move(wi), priority); } void ShaderCache::QueuePipelineCompile(const GXPipelineUid& uid, u32 priority) { class PipelineWorkItem final : public AsyncShaderCompiler::WorkItem { public: PipelineWorkItem(ShaderCache* shader_cache_, const GXPipelineUid& uid_, u32 priority_) : shader_cache(shader_cache_), uid(uid_), priority(priority_) { // Check if all the stages required for this pipeline have been compiled. // If not, this work item becomes a no-op, and re-queues the pipeline for the next frame. if (SetStagesReady()) config = shader_cache->GetGXPipelineConfig(uid); } bool SetStagesReady() { stages_ready = true; GXPipelineUid actual_uid = ApplyDriverBugs(uid); auto vs_it = shader_cache->m_vs_cache.shader_map.find(actual_uid.vs_uid); stages_ready &= vs_it != shader_cache->m_vs_cache.shader_map.end() && !vs_it->second.pending; if (vs_it == shader_cache->m_vs_cache.shader_map.end()) shader_cache->QueueVertexShaderCompile(actual_uid.vs_uid, priority); PixelShaderUid ps_uid = actual_uid.ps_uid; ClearUnusedPixelShaderUidBits(shader_cache->m_api_type, shader_cache->m_host_config, &ps_uid); auto ps_it = shader_cache->m_ps_cache.shader_map.find(ps_uid); stages_ready &= ps_it != shader_cache->m_ps_cache.shader_map.end() && !ps_it->second.pending; if (ps_it == shader_cache->m_ps_cache.shader_map.end()) shader_cache->QueuePixelShaderCompile(ps_uid, priority); return stages_ready; } bool Compile() override { if (config) pipeline = g_gfx->CreatePipeline(*config); return true; } void Retrieve() override { if (stages_ready) { shader_cache->InsertGXPipeline(uid, std::move(pipeline)); } else { // Re-queue for next frame. auto wi = shader_cache->m_async_shader_compiler->CreateWorkItem( shader_cache, uid, priority); shader_cache->m_async_shader_compiler->QueueWorkItem(std::move(wi), priority); } } private: ShaderCache* shader_cache; std::unique_ptr pipeline; GXPipelineUid uid; u32 priority; std::optional config; bool stages_ready; }; auto wi = m_async_shader_compiler->CreateWorkItem(this, uid, priority); m_async_shader_compiler->QueueWorkItem(std::move(wi), priority); m_gx_pipeline_cache[uid].second = true; } void ShaderCache::QueueUberPipelineCompile(const GXUberPipelineUid& uid, u32 priority) { class UberPipelineWorkItem final : public AsyncShaderCompiler::WorkItem { public: UberPipelineWorkItem(ShaderCache* shader_cache_, const GXUberPipelineUid& uid_, u32 priority_) : shader_cache(shader_cache_), uid(uid_), priority(priority_) { // Check if all the stages required for this UberPipeline have been compiled. // If not, this work item becomes a no-op, and re-queues the UberPipeline for the next frame. if (SetStagesReady()) config = shader_cache->GetGXPipelineConfig(uid); } bool SetStagesReady() { stages_ready = true; GXUberPipelineUid actual_uid = ApplyDriverBugs(uid); auto vs_it = shader_cache->m_uber_vs_cache.shader_map.find(actual_uid.vs_uid); stages_ready &= vs_it != shader_cache->m_uber_vs_cache.shader_map.end() && !vs_it->second.pending; if (vs_it == shader_cache->m_uber_vs_cache.shader_map.end()) shader_cache->QueueVertexUberShaderCompile(actual_uid.vs_uid, priority); UberShader::PixelShaderUid ps_uid = actual_uid.ps_uid; UberShader::ClearUnusedPixelShaderUidBits(shader_cache->m_api_type, shader_cache->m_host_config, &ps_uid); auto ps_it = shader_cache->m_uber_ps_cache.shader_map.find(ps_uid); stages_ready &= ps_it != shader_cache->m_uber_ps_cache.shader_map.end() && !ps_it->second.pending; if (ps_it == shader_cache->m_uber_ps_cache.shader_map.end()) shader_cache->QueuePixelUberShaderCompile(ps_uid, priority); return stages_ready; } bool Compile() override { if (config) UberPipeline = g_gfx->CreatePipeline(*config); return true; } void Retrieve() override { if (stages_ready) { shader_cache->InsertGXUberPipeline(uid, std::move(UberPipeline)); } else { // Re-queue for next frame. auto wi = shader_cache->m_async_shader_compiler->CreateWorkItem( shader_cache, uid, priority); shader_cache->m_async_shader_compiler->QueueWorkItem(std::move(wi), priority); } } private: ShaderCache* shader_cache; std::unique_ptr UberPipeline; GXUberPipelineUid uid; u32 priority; std::optional config; bool stages_ready; }; auto wi = m_async_shader_compiler->CreateWorkItem(this, uid, priority); m_async_shader_compiler->QueueWorkItem(std::move(wi), priority); m_gx_uber_pipeline_cache[uid].second = true; } void ShaderCache::QueueUberShaderPipelines() { // Create a dummy vertex format with no attributes. // All attributes will be enabled in GetUberVertexFormat. PortableVertexDeclaration dummy_vertex_decl = {}; dummy_vertex_decl.position.components = 4; dummy_vertex_decl.position.type = ComponentFormat::Float; dummy_vertex_decl.position.enable = true; dummy_vertex_decl.stride = sizeof(float) * 4; NativeVertexFormat* dummy_vertex_format = VertexLoaderManager::GetUberVertexFormat(dummy_vertex_decl); auto QueueDummyPipeline = [&](const UberShader::VertexShaderUid& vs_uid, const GeometryShaderUid& gs_uid, const UberShader::PixelShaderUid& ps_uid, const BlendingState& blend) { GXUberPipelineUid config; config.vertex_format = dummy_vertex_format; config.vs_uid = vs_uid; config.gs_uid = gs_uid; config.ps_uid = ps_uid; config.rasterization_state = RenderState::GetCullBackFaceRasterizationState( static_cast(gs_uid.GetUidData()->primitive_type)); config.depth_state = RenderState::GetNoDepthTestingDepthState(); config.blending_state = blend; if (ps_uid.GetUidData()->uint_output) { // uint_output is only ever enabled when logic ops are enabled. config.blending_state.logicopenable = true; config.blending_state.logicmode = LogicOp::And; } auto iter = m_gx_uber_pipeline_cache.find(config); if (iter != m_gx_uber_pipeline_cache.end()) return; auto& entry = m_gx_uber_pipeline_cache[config]; entry.second = false; }; // Populate the pipeline configs with empty entries, these will be compiled afterwards. UberShader::EnumerateVertexShaderUids([&](const UberShader::VertexShaderUid& vuid) { UberShader::EnumeratePixelShaderUids([&](const UberShader::PixelShaderUid& puid) { // UIDs must have compatible texgens, a mismatching combination will never be queried. if (vuid.GetUidData()->num_texgens != puid.GetUidData()->num_texgens) return; UberShader::PixelShaderUid cleared_puid = puid; UberShader::ClearUnusedPixelShaderUidBits(m_api_type, m_host_config, &cleared_puid); EnumerateGeometryShaderUids([&](const GeometryShaderUid& guid) { if (guid.GetUidData()->numTexGens != vuid.GetUidData()->num_texgens || (!guid.GetUidData()->IsPassthrough() && !m_host_config.backend_geometry_shaders)) { return; } BlendingState blend = RenderState::GetNoBlendingBlendState(); QueueDummyPipeline(vuid, guid, cleared_puid, blend); if (g_ActiveConfig.backend_info.bSupportsDynamicVertexLoader) { // Not all GPUs need all the pipeline state compiled into shaders, so they tend to key // compiled shaders based on some subset of the pipeline state. // Some test results: // (GPUs tested: AMD Radeon Pro 5600M, Nvidia GT 750M, Intel UHD 630, // Intel Iris Pro 5200, Apple M1) // MacOS Metal: // - AMD, Nvidia, Intel GPUs: Shaders are keyed on vertex layout and whether or not // dual source blend is enabled. That's it. // - Apple GPUs: Shaders are keyed on vertex layout and all blending settings. We use // framebuffer fetch here, so the only blending settings used by ubershaders are the // alphaupdate and colorupdate ones. Also keyed on primitive type, but Metal supports // setting it to "unknown" and we do for ubershaders (but MoltenVK won't). // Windows Vulkan: // - AMD, Nvidia: Definitely keyed on dual source blend, but the others seem more random // Changing a setting on one shader will require a recompile, but changing the same // setting on another won't. Compiling a copy with alphaupdate off, colorupdate off, // and one with DSB on seems to get pretty good coverage though. // Windows D3D12: // - AMD: Keyed on dual source blend and vertex layout // - Nvidia Kepler: No recompiles for changes to vertex layout or blend blend.alphaupdate = false; QueueDummyPipeline(vuid, guid, cleared_puid, blend); blend.alphaupdate = true; blend.colorupdate = false; QueueDummyPipeline(vuid, guid, cleared_puid, blend); blend.colorupdate = true; if (!cleared_puid.GetUidData()->no_dual_src && !cleared_puid.GetUidData()->uint_output) { blend.blendenable = true; blend.usedualsrc = true; blend.srcfactor = SrcBlendFactor::SrcAlpha; blend.dstfactor = DstBlendFactor::InvSrcAlpha; QueueDummyPipeline(vuid, guid, cleared_puid, blend); } } }); }); }); } const AbstractPipeline* ShaderCache::GetEFBCopyToVRAMPipeline(const TextureConversionShaderGen::TCShaderUid& uid) { auto iter = m_efb_copy_to_vram_pipelines.find(uid); if (iter != m_efb_copy_to_vram_pipelines.end()) return iter->second.get(); auto shader_code = TextureConversionShaderGen::GeneratePixelShader(m_api_type, uid.GetUidData()); auto shader = g_gfx->CreateShaderFromSource( ShaderStage::Pixel, shader_code.GetBuffer(), fmt::format("EFB copy to VRAM pixel shader: {}", *uid.GetUidData())); if (!shader) { m_efb_copy_to_vram_pipelines.emplace(uid, nullptr); return nullptr; } AbstractPipelineConfig config = {}; config.vertex_format = nullptr; config.vertex_shader = m_efb_copy_vertex_shader.get(); config.geometry_shader = UseGeometryShaderForEFBCopies() ? m_texcoord_geometry_shader.get() : nullptr; config.pixel_shader = shader.get(); config.rasterization_state = RenderState::GetNoCullRasterizationState(PrimitiveType::Triangles); config.depth_state = RenderState::GetNoDepthTestingDepthState(); config.blending_state = RenderState::GetNoBlendingBlendState(); config.framebuffer_state = RenderState::GetRGBA8FramebufferState(); config.usage = AbstractPipelineUsage::Utility; auto iiter = m_efb_copy_to_vram_pipelines.emplace(uid, g_gfx->CreatePipeline(config)); return iiter.first->second.get(); } const AbstractPipeline* ShaderCache::GetEFBCopyToRAMPipeline(const EFBCopyParams& uid) { auto iter = m_efb_copy_to_ram_pipelines.find(uid); if (iter != m_efb_copy_to_ram_pipelines.end()) return iter->second.get(); const std::string shader_code = TextureConversionShaderTiled::GenerateEncodingShader(uid, m_api_type); const auto shader = g_gfx->CreateShaderFromSource( ShaderStage::Pixel, shader_code, fmt::format("EFB copy to RAM pixel shader: {}", uid)); if (!shader) { m_efb_copy_to_ram_pipelines.emplace(uid, nullptr); return nullptr; } AbstractPipelineConfig config = {}; config.vertex_shader = m_screen_quad_vertex_shader.get(); config.pixel_shader = shader.get(); config.rasterization_state = RenderState::GetNoCullRasterizationState(PrimitiveType::Triangles); config.depth_state = RenderState::GetNoDepthTestingDepthState(); config.blending_state = RenderState::GetNoBlendingBlendState(); config.framebuffer_state = RenderState::GetColorFramebufferState(AbstractTextureFormat::BGRA8); config.usage = AbstractPipelineUsage::Utility; auto iiter = m_efb_copy_to_ram_pipelines.emplace(uid, g_gfx->CreatePipeline(config)); return iiter.first->second.get(); } bool ShaderCache::CompileSharedPipelines() { m_screen_quad_vertex_shader = g_gfx->CreateShaderFromSource( ShaderStage::Vertex, FramebufferShaderGen::GenerateScreenQuadVertexShader(), "Screen quad vertex shader"); m_texture_copy_vertex_shader = g_gfx->CreateShaderFromSource( ShaderStage::Vertex, FramebufferShaderGen::GenerateTextureCopyVertexShader(), "Texture copy vertex shader"); m_efb_copy_vertex_shader = g_gfx->CreateShaderFromSource( ShaderStage::Vertex, TextureConversionShaderGen::GenerateVertexShader(m_api_type).GetBuffer(), "EFB copy vertex shader"); if (!m_screen_quad_vertex_shader || !m_texture_copy_vertex_shader || !m_efb_copy_vertex_shader) return false; if (UseGeometryShaderForEFBCopies()) { m_texcoord_geometry_shader = g_gfx->CreateShaderFromSource( ShaderStage::Geometry, FramebufferShaderGen::GeneratePassthroughGeometryShader(1, 0), "Texcoord passthrough geometry shader"); m_color_geometry_shader = g_gfx->CreateShaderFromSource( ShaderStage::Geometry, FramebufferShaderGen::GeneratePassthroughGeometryShader(0, 1), "Color passthrough geometry shader"); if (!m_texcoord_geometry_shader || !m_color_geometry_shader) return false; } m_texture_copy_pixel_shader = g_gfx->CreateShaderFromSource( ShaderStage::Pixel, FramebufferShaderGen::GenerateTextureCopyPixelShader(), "Texture copy pixel shader"); m_color_pixel_shader = g_gfx->CreateShaderFromSource( ShaderStage::Pixel, FramebufferShaderGen::GenerateColorPixelShader(), "Color pixel shader"); if (!m_texture_copy_pixel_shader || !m_color_pixel_shader) return false; AbstractPipelineConfig config; config.vertex_format = nullptr; config.vertex_shader = m_texture_copy_vertex_shader.get(); config.geometry_shader = nullptr; config.pixel_shader = m_texture_copy_pixel_shader.get(); config.rasterization_state = RenderState::GetNoCullRasterizationState(PrimitiveType::Triangles); config.depth_state = RenderState::GetNoDepthTestingDepthState(); config.blending_state = RenderState::GetNoBlendingBlendState(); config.framebuffer_state = RenderState::GetRGBA8FramebufferState(); config.usage = AbstractPipelineUsage::Utility; m_copy_rgba8_pipeline = g_gfx->CreatePipeline(config); if (!m_copy_rgba8_pipeline) return false; if (UseGeometryShaderForEFBCopies()) { config.geometry_shader = m_texcoord_geometry_shader.get(); m_rgba8_stereo_copy_pipeline = g_gfx->CreatePipeline(config); if (!m_rgba8_stereo_copy_pipeline) return false; } if (m_host_config.backend_palette_conversion) { config.vertex_shader = m_screen_quad_vertex_shader.get(); config.geometry_shader = nullptr; for (size_t i = 0; i < NUM_PALETTE_CONVERSION_SHADERS; i++) { TLUTFormat format = static_cast(i); auto shader = g_gfx->CreateShaderFromSource( ShaderStage::Pixel, TextureConversionShaderTiled::GeneratePaletteConversionShader(format, m_api_type), fmt::format("Palette conversion pixel shader: {}", format)); if (!shader) return false; config.pixel_shader = shader.get(); m_palette_conversion_pipelines[i] = g_gfx->CreatePipeline(config); if (!m_palette_conversion_pipelines[i]) return false; } } return true; } const AbstractPipeline* ShaderCache::GetPaletteConversionPipeline(TLUTFormat format) { ASSERT(static_cast(format) < NUM_PALETTE_CONVERSION_SHADERS); return m_palette_conversion_pipelines[static_cast(format)].get(); } const AbstractPipeline* ShaderCache::GetTextureReinterpretPipeline(TextureFormat from_format, TextureFormat to_format) { const auto key = std::make_pair(from_format, to_format); auto iter = m_texture_reinterpret_pipelines.find(key); if (iter != m_texture_reinterpret_pipelines.end()) return iter->second.get(); std::string shader_source = FramebufferShaderGen::GenerateTextureReinterpretShader(from_format, to_format); if (shader_source.empty()) { m_texture_reinterpret_pipelines.emplace(key, nullptr); return nullptr; } std::unique_ptr shader = g_gfx->CreateShaderFromSource( ShaderStage::Pixel, shader_source, fmt::format("Texture reinterpret pixel shader: {} to {}", from_format, to_format)); if (!shader) { m_texture_reinterpret_pipelines.emplace(key, nullptr); return nullptr; } AbstractPipelineConfig config; config.vertex_format = nullptr; config.vertex_shader = m_screen_quad_vertex_shader.get(); config.geometry_shader = nullptr; config.pixel_shader = shader.get(); config.rasterization_state = RenderState::GetNoCullRasterizationState(PrimitiveType::Triangles); config.depth_state = RenderState::GetNoDepthTestingDepthState(); config.blending_state = RenderState::GetNoBlendingBlendState(); config.framebuffer_state = RenderState::GetRGBA8FramebufferState(); config.usage = AbstractPipelineUsage::Utility; auto iiter = m_texture_reinterpret_pipelines.emplace(key, g_gfx->CreatePipeline(config)); return iiter.first->second.get(); } const AbstractShader* ShaderCache::GetTextureDecodingShader(TextureFormat format, std::optional palette_format) { const auto key = std::make_pair(static_cast(format), static_cast(palette_format.value_or(TLUTFormat::IA8))); const auto iter = m_texture_decoding_shaders.find(key); if (iter != m_texture_decoding_shaders.end()) return iter->second.get(); const std::string shader_source = TextureConversionShaderTiled::GenerateDecodingShader(format, palette_format, APIType::OpenGL); if (shader_source.empty()) { m_texture_decoding_shaders.emplace(key, nullptr); return nullptr; } const std::string name = palette_format.has_value() ? fmt::format("Texture decoding compute shader: {}, {}", format, *palette_format) : fmt::format("Texture decoding compute shader: {}", format); std::unique_ptr shader = g_gfx->CreateShaderFromSource(ShaderStage::Compute, shader_source, name); if (!shader) { m_texture_decoding_shaders.emplace(key, nullptr); return nullptr; } const auto iiter = m_texture_decoding_shaders.emplace(key, std::move(shader)); return iiter.first->second.get(); } } // namespace VideoCommon