#include "dxso_compiler.h" #include "dxso_analysis.h" #include "../d3d9/d3d9_caps.h" #include "../d3d9/d3d9_constant_set.h" #include "../d3d9/d3d9_state.h" #include "../d3d9/d3d9_spec_constants.h" #include "../d3d9/d3d9_fixed_function.h" #include "dxso_util.h" #include "../dxvk/dxvk_spec_const.h" #include namespace dxvk { DxsoCompiler::DxsoCompiler( const std::string& fileName, const DxsoModuleInfo& moduleInfo, const DxsoProgramInfo& programInfo, const DxsoAnalysisInfo& analysis, const D3D9ConstantLayout& layout) : m_moduleInfo ( moduleInfo ) , m_programInfo( programInfo ) , m_analysis ( &analysis ) , m_layout ( &layout ) , m_module ( spvVersion(1, 3) ) { // Declare an entry point ID. We'll need it during the // initialization phase where the execution mode is set. m_entryPointId = m_module.allocateId(); // Set the shader name so that we recognize it in renderdoc m_module.setDebugSource( spv::SourceLanguageUnknown, 0, m_module.addDebugString(fileName.c_str()), nullptr); // Set the memory model. This is the same for all shaders. m_module.setMemoryModel( spv::AddressingModelLogical, spv::MemoryModelGLSL450); m_usedSamplers = 0; m_usedRTs = 0; for (uint32_t i = 0; i < m_rRegs.size(); i++) m_rRegs.at(i) = DxsoRegisterPointer{ }; for (uint32_t i = 0; i < m_cFloat.size(); i++) m_cFloat.at(i) = 0; for (uint32_t i = 0; i < m_cInt.size(); i++) m_cInt.at(i) = 0; for (uint32_t i = 0; i < m_cBool.size(); i++) m_cBool.at(i) = 0; m_vs.addr = DxsoRegisterPointer{ }; m_vs.oPos = DxsoRegisterPointer{ }; m_fog = DxsoRegisterPointer{ }; m_vs.oPSize = DxsoRegisterPointer{ }; for (uint32_t i = 0; i < m_ps.oColor.size(); i++) m_ps.oColor.at(i) = DxsoRegisterPointer{ }; m_ps.oDepth = DxsoRegisterPointer{ }; m_ps.vFace = DxsoRegisterPointer{ }; m_ps.vPos = DxsoRegisterPointer{ }; m_loopCounter = DxsoRegisterPointer{ }; this->emitInit(); } void DxsoCompiler::processInstruction( const DxsoInstructionContext& ctx, uint32_t currentCoissueIdx) { const DxsoOpcode opcode = ctx.instruction.opcode; for (const auto& coissue : m_analysis->coissues) { if (coissue.instructionIdx == ctx.instructionIdx && coissue.instructionIdx != currentCoissueIdx) return; if (coissue.instructionIdx == ctx.instructionIdx + 1) processInstruction(coissue, coissue.instructionIdx); } switch (opcode) { case DxsoOpcode::Nop: return; case DxsoOpcode::Dcl: return this->emitDcl(ctx); case DxsoOpcode::Def: case DxsoOpcode::DefI: case DxsoOpcode::DefB: return this->emitDef(ctx); case DxsoOpcode::Mov: case DxsoOpcode::Mova: return this->emitMov(ctx); case DxsoOpcode::Add: case DxsoOpcode::Sub: case DxsoOpcode::Mad: case DxsoOpcode::Mul: case DxsoOpcode::Rcp: case DxsoOpcode::Rsq: case DxsoOpcode::Dp3: case DxsoOpcode::Dp4: case DxsoOpcode::Slt: case DxsoOpcode::Sge: case DxsoOpcode::Min: case DxsoOpcode::ExpP: case DxsoOpcode::Exp: case DxsoOpcode::Max: case DxsoOpcode::Pow: case DxsoOpcode::Crs: case DxsoOpcode::Abs: case DxsoOpcode::Nrm: case DxsoOpcode::SinCos: case DxsoOpcode::Lit: case DxsoOpcode::Dst: case DxsoOpcode::LogP: case DxsoOpcode::Log: case DxsoOpcode::Lrp: case DxsoOpcode::Frc: case DxsoOpcode::Cmp: case DxsoOpcode::Cnd: case DxsoOpcode::Dp2Add: case DxsoOpcode::DsX: case DxsoOpcode::DsY: return this->emitVectorAlu(ctx); case DxsoOpcode::SetP: return this->emitPredicateOp(ctx); case DxsoOpcode::M3x2: case DxsoOpcode::M3x3: case DxsoOpcode::M3x4: case DxsoOpcode::M4x3: case DxsoOpcode::M4x4: return this->emitMatrixAlu(ctx); case DxsoOpcode::Loop: return this->emitControlFlowLoop(ctx); case DxsoOpcode::EndLoop: return this->emitControlFlowEndLoop(ctx); case DxsoOpcode::Rep: return this->emitControlFlowRep(ctx); case DxsoOpcode::EndRep: return this->emitControlFlowEndRep(ctx); case DxsoOpcode::Break: return this->emitControlFlowBreak(ctx); case DxsoOpcode::BreakC: return this->emitControlFlowBreakC(ctx); case DxsoOpcode::If: case DxsoOpcode::Ifc: return this->emitControlFlowIf(ctx); case DxsoOpcode::Else: return this->emitControlFlowElse(ctx); case DxsoOpcode::EndIf: return this->emitControlFlowEndIf(ctx); case DxsoOpcode::TexCoord: return this->emitTexCoord(ctx); case DxsoOpcode::Tex: case DxsoOpcode::TexLdl: case DxsoOpcode::TexLdd: case DxsoOpcode::TexDp3Tex: case DxsoOpcode::TexReg2Ar: case DxsoOpcode::TexReg2Gb: case DxsoOpcode::TexReg2Rgb: case DxsoOpcode::TexBem: case DxsoOpcode::TexM3x2Tex: case DxsoOpcode::TexM3x3Tex: case DxsoOpcode::TexM3x3Spec: case DxsoOpcode::TexM3x3VSpec: return this->emitTextureSample(ctx); case DxsoOpcode::TexKill: return this->emitTextureKill(ctx); case DxsoOpcode::TexM3x3Pad: case DxsoOpcode::TexM3x2Pad: // We don't need to do anything here, these are just padding instructions break; case DxsoOpcode::End: case DxsoOpcode::Comment: break; default: Logger::warn(str::format("DxsoCompiler::processInstruction: unhandled opcode: ", opcode)); break; } } void DxsoCompiler::finalize() { if (m_programInfo.type() == DxsoProgramTypes::VertexShader) this->emitVsFinalize(); else this->emitPsFinalize(); // Declare the entry point, we now have all the // information we need, including the interfaces m_module.addEntryPoint(m_entryPointId, m_programInfo.executionModel(), "main", m_entryPointInterfaces.size(), m_entryPointInterfaces.data()); m_module.setDebugName(m_entryPointId, "main"); } DxsoPermutations DxsoCompiler::compile() { DxsoPermutations permutations = { }; // Create the shader module object permutations[D3D9ShaderPermutations::None] = compileShader(); // If we need to add more permuations, might be worth making a copy of module // before we do anything more. :-) if (m_programInfo.type() == DxsoProgramType::PixelShader) { if (m_ps.diffuseColorIn) m_module.decorate(m_ps.diffuseColorIn, spv::DecorationFlat); if (m_ps.specularColorIn) m_module.decorate(m_ps.specularColorIn, spv::DecorationFlat); permutations[D3D9ShaderPermutations::FlatShade] = compileShader(); } return permutations; } Rc DxsoCompiler::compileShader() { DxvkShaderOptions shaderOptions = { }; DxvkShaderConstData constData = { }; return new DxvkShader( m_programInfo.shaderStage(), m_resourceSlots.size(), m_resourceSlots.data(), m_interfaceSlots, m_module.compile(), shaderOptions, std::move(constData)); } void DxsoCompiler::emitInit() { // Set up common capabilities for all shaders m_module.enableCapability(spv::CapabilityShader); m_module.enableCapability(spv::CapabilityImageQuery); this->emitDclConstantBuffer(); this->emitDclInputArray(); // Initialize the shader module with capabilities // etc. Each shader type has its own peculiarities. switch (m_programInfo.type()) { case DxsoProgramTypes::VertexShader: return this->emitVsInit(); case DxsoProgramTypes::PixelShader: return this->emitPsInit(); default: break; } } void DxsoCompiler::emitDclConstantBuffer() { std::array members = { // float f[256 or 224 or 8192] m_module.defArrayTypeUnique( getVectorTypeId({ DxsoScalarType::Float32, 4 }), m_module.constu32(m_layout->floatCount)), // int i[16 or 2048] m_module.defArrayTypeUnique( getVectorTypeId({ DxsoScalarType::Sint32, 4 }), m_module.constu32(m_layout->intCount)), // uint32_t boolBitmask // or uvec4 boolBitmask[512] // Defined later... 0 }; // Decorate array strides, this is required. m_module.decorateArrayStride(members[0], 16); m_module.decorateArrayStride(members[1], 16); const bool swvp = m_layout->bitmaskCount != 1; if (swvp) { // Must be a multiple of 4 otherwise. members[2] = m_module.defArrayTypeUnique( getVectorTypeId({ DxsoScalarType::Uint32, 4 }), m_module.constu32(m_layout->bitmaskCount / 4)); m_module.decorateArrayStride(members[2], 16); } const uint32_t structType = m_module.defStructType(swvp ? 3 : 2, members.data()); m_module.decorateBlock(structType); m_module.memberDecorateOffset(structType, 0, m_layout->floatOffset()); m_module.memberDecorateOffset(structType, 1, m_layout->intOffset()); if (swvp) m_module.memberDecorateOffset(structType, 2, m_layout->bitmaskOffset()); m_module.setDebugName(structType, "cbuffer_t"); m_module.setDebugMemberName(structType, 0, "f"); m_module.setDebugMemberName(structType, 1, "i"); if (swvp) m_module.setDebugMemberName(structType, 2, "b"); m_cBuffer = m_module.newVar( m_module.defPointerType(structType, spv::StorageClassUniform), spv::StorageClassUniform); m_module.setDebugName(m_cBuffer, "c"); const uint32_t bindingId = computeResourceSlotId( m_programInfo.type(), DxsoBindingType::ConstantBuffer, 0); m_module.decorateDescriptorSet(m_cBuffer, 0); m_module.decorateBinding(m_cBuffer, bindingId); DxvkResourceSlot resource; resource.slot = bindingId; resource.type = VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER; resource.view = VK_IMAGE_VIEW_TYPE_MAX_ENUM; resource.access = VK_ACCESS_UNIFORM_READ_BIT; m_resourceSlots.push_back(resource); m_boolSpecConstant = m_module.specConst32(m_module.defIntType(32, 0), 0); m_module.decorateSpecId(m_boolSpecConstant, getSpecId( m_programInfo.type() == DxsoProgramType::VertexShader ? D3D9SpecConstantId::VertexShaderBools : D3D9SpecConstantId::PixelShaderBools)); m_module.setDebugName(m_boolSpecConstant, "boolConstants"); } void DxsoCompiler::emitDclInputArray() { DxsoArrayType info; info.ctype = DxsoScalarType::Float32; info.ccount = 4; info.alength = DxsoMaxInterfaceRegs; uint32_t arrayTypeId = getArrayTypeId(info); // Define the actual variable. Note that this is private // because we will copy input registers // to the array during the setup phase. const uint32_t ptrTypeId = m_module.defPointerType( arrayTypeId, spv::StorageClassPrivate); m_vArray = m_module.newVar( ptrTypeId, spv::StorageClassPrivate); m_module.setDebugName(m_vArray, "v"); } void DxsoCompiler::emitDclOutputArray() { DxsoArrayType info; info.ctype = DxsoScalarType::Float32; info.ccount = 4; info.alength = m_programInfo.type() == DxsoProgramTypes::VertexShader ? DxsoMaxInterfaceRegs : caps::MaxSimultaneousRenderTargets; uint32_t arrayTypeId = getArrayTypeId(info); // Define the actual variable. Note that this is private // because we will copy input registers // to the array during the setup phase. const uint32_t ptrTypeId = m_module.defPointerType( arrayTypeId, spv::StorageClassPrivate); m_oArray = m_module.newVar( ptrTypeId, spv::StorageClassPrivate); m_module.setDebugName(m_oArray, "o"); } void DxsoCompiler::emitVsInit() { m_module.enableCapability(spv::CapabilityClipDistance); // Only VS needs this, because PS has // non-indexable specialized output regs this->emitDclOutputArray(); // Main function of the vertex shader m_vs.functionId = m_module.allocateId(); m_module.setDebugName(m_vs.functionId, "vs_main"); this->setupRenderStateInfo(); this->emitFunctionBegin( m_vs.functionId, m_module.defVoidType(), m_module.defFunctionType( m_module.defVoidType(), 0, nullptr)); this->emitFunctionLabel(); } void DxsoCompiler::emitPsSharedConstants() { m_ps.sharedState = GetSharedConstants(m_module); const uint32_t bindingId = computeResourceSlotId( m_programInfo.type(), DxsoBindingType::ConstantBuffer, PSShared); m_module.decorateDescriptorSet(m_ps.sharedState, 0); m_module.decorateBinding(m_ps.sharedState, bindingId); DxvkResourceSlot resource; resource.slot = bindingId; resource.type = VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER; resource.view = VK_IMAGE_VIEW_TYPE_MAX_ENUM; resource.access = VK_ACCESS_UNIFORM_READ_BIT; m_resourceSlots.push_back(resource); } void DxsoCompiler::emitPsInit() { m_module.enableCapability(spv::CapabilityDerivativeControl); m_module.setExecutionMode(m_entryPointId, spv::ExecutionModeOriginUpperLeft); // Main function of the pixel shader m_ps.functionId = m_module.allocateId(); m_module.setDebugName(m_ps.functionId, "ps_main"); if (m_programInfo.majorVersion() < 2 || m_moduleInfo.options.forceSamplerTypeSpecConstants) { m_ps.samplerTypeSpec = m_module.specConst32(m_module.defIntType(32, 0), 0); m_module.decorateSpecId(m_ps.samplerTypeSpec, getSpecId(D3D9SpecConstantId::SamplerType)); m_module.setDebugName(m_ps.samplerTypeSpec, "s_sampler_types"); if (m_programInfo.majorVersion() < 2) { m_ps.projectionSpec = m_module.specConst32(m_module.defIntType(32, 0), 0); m_module.decorateSpecId(m_ps.projectionSpec, getSpecId(D3D9SpecConstantId::ProjectionType)); m_module.setDebugName(m_ps.projectionSpec, "s_projections"); } } this->setupRenderStateInfo(); this->emitPsSharedConstants(); this->emitFunctionBegin( m_ps.functionId, m_module.defVoidType(), m_module.defFunctionType( m_module.defVoidType(), 0, nullptr)); this->emitFunctionLabel(); // We may have to defer kill operations to the end of // the shader in order to keep derivatives correct. if (m_analysis->usesKill && m_moduleInfo.options.useDemoteToHelperInvocation) { // This extension basically implements D3D-style discard m_module.enableExtension("SPV_EXT_demote_to_helper_invocation"); m_module.enableCapability(spv::CapabilityDemoteToHelperInvocationEXT); } else if (m_analysis->usesKill && m_analysis->usesDerivatives) { m_ps.killState = m_module.newVarInit( m_module.defPointerType(m_module.defBoolType(), spv::StorageClassPrivate), spv::StorageClassPrivate, m_module.constBool(false)); m_module.setDebugName(m_ps.killState, "ps_kill"); if (m_moduleInfo.options.useSubgroupOpsForEarlyDiscard) { m_module.enableCapability(spv::CapabilityGroupNonUniform); m_module.enableCapability(spv::CapabilityGroupNonUniformBallot); DxsoRegisterInfo laneId; laneId.type = { DxsoScalarType::Uint32, 1, 0 }; laneId.sclass = spv::StorageClassInput; m_ps.builtinLaneId = emitNewBuiltinVariable( laneId, spv::BuiltInSubgroupLocalInvocationId, "fLaneId", 0); } } } void DxsoCompiler::emitFunctionBegin( uint32_t entryPoint, uint32_t returnType, uint32_t funcType) { this->emitFunctionEnd(); m_module.functionBegin( returnType, entryPoint, funcType, spv::FunctionControlMaskNone); m_insideFunction = true; } void DxsoCompiler::emitFunctionEnd() { if (m_insideFunction) { m_module.opReturn(); m_module.functionEnd(); } m_insideFunction = false; } uint32_t DxsoCompiler::emitFunctionLabel() { uint32_t labelId = m_module.allocateId(); m_module.opLabel(labelId); return labelId; } void DxsoCompiler::emitMainFunctionBegin() { this->emitFunctionBegin( m_entryPointId, m_module.defVoidType(), m_module.defFunctionType( m_module.defVoidType(), 0, nullptr)); m_mainFuncLabel = this->emitFunctionLabel(); } uint32_t DxsoCompiler::emitNewVariable(const DxsoRegisterInfo& info) { const uint32_t ptrTypeId = this->getPointerTypeId(info); return m_module.newVar(ptrTypeId, info.sclass); } uint32_t DxsoCompiler::emitNewVariableDefault( const DxsoRegisterInfo& info, uint32_t value) { const uint32_t ptrTypeId = this->getPointerTypeId(info); if (value == 0) return m_module.newVar(ptrTypeId, info.sclass); else return m_module.newVarInit(ptrTypeId, info.sclass, value); } uint32_t DxsoCompiler::emitNewBuiltinVariable( const DxsoRegisterInfo& info, spv::BuiltIn builtIn, const char* name, uint32_t value) { const uint32_t varId = emitNewVariableDefault(info, value); m_module.setDebugName(varId, name); m_module.decorateBuiltIn(varId, builtIn); if (m_programInfo.type() == DxsoProgramTypes::PixelShader && info.type.ctype != DxsoScalarType::Float32 && info.type.ctype != DxsoScalarType::Bool && info.sclass == spv::StorageClassInput) m_module.decorate(varId, spv::DecorationFlat); m_entryPointInterfaces.push_back(varId); return varId; } DxsoCfgBlock* DxsoCompiler::cfgFindBlock( const std::initializer_list& types) { for (auto cur = m_controlFlowBlocks.rbegin(); cur != m_controlFlowBlocks.rend(); cur++) { for (auto type : types) { if (cur->type == type) return &(*cur); } } return nullptr; } spv::BuiltIn semanticToBuiltIn(bool input, DxsoSemantic semantic) { if (input) return spv::BuiltInMax; if (semantic == DxsoSemantic{ DxsoUsage::Position, 0 }) return spv::BuiltInPosition; if (semantic == DxsoSemantic{ DxsoUsage::PointSize, 0 }) return spv::BuiltInPointSize; return spv::BuiltInMax; } void DxsoCompiler::emitDclInterface( bool input, uint32_t regNumber, DxsoSemantic semantic, DxsoRegMask mask, bool centroid) { auto& sgn = input ? m_isgn : m_osgn; const bool pixel = m_programInfo.type() == DxsoProgramTypes::PixelShader; const bool vertex = !pixel; uint32_t slot = 0; uint32_t& slots = input ? m_interfaceSlots.inputSlots : m_interfaceSlots.outputSlots; uint16_t& explicits = input ? m_explicitInputs : m_explicitOutputs; // Some things we consider builtins could be packed in an output reg. bool builtin = semanticToBuiltIn(input, semantic) != spv::BuiltInMax; uint32_t i = sgn.elemCount++; if (input && vertex) { // Any slot will do! Let's chose the next one slot = i; } else if ( (!input && vertex) || (input && pixel ) ) { // Don't register the slot if it belongs to a builtin if (!builtin) slot = RegisterLinkerSlot(semantic); } else { //if (!input && pixel) // We want to make the output slot the same as the // output register for pixel shaders so they go to // the right render target. slot = regNumber; } // Don't want to mark down any of these builtins. if (!builtin) slots |= 1u << slot; explicits |= 1u << regNumber; auto& elem = sgn.elems[i]; elem.slot = slot; elem.regNumber = regNumber; elem.semantic = semantic; elem.mask = mask; elem.centroid = centroid; } void DxsoCompiler::emitDclSampler( uint32_t idx, DxsoTextureType type) { m_usedSamplers |= (1u << idx); auto DclSampler = [this]( uint32_t idx, DxsoSamplerType type, bool depth, bool implicit) { // Setup our combines sampler. DxsoSamplerInfo& sampler = !depth ? m_samplers[idx].color[type] : m_samplers[idx].depth[type]; spv::Dim dimensionality; VkImageViewType viewType; const char* suffix = "_2d"; switch (type) { default: case SamplerTypeTexture2D: sampler.dimensions = 2; dimensionality = spv::Dim2D; viewType = VK_IMAGE_VIEW_TYPE_2D; break; case SamplerTypeTextureCube: suffix = "_cube"; sampler.dimensions = 3; dimensionality = spv::DimCube; viewType = VK_IMAGE_VIEW_TYPE_CUBE; break; case SamplerTypeTexture3D: suffix = "_3d"; sampler.dimensions = 3; dimensionality = spv::Dim3D; viewType = VK_IMAGE_VIEW_TYPE_3D; break; } sampler.typeId = m_module.defImageType( m_module.defFloatType(32), dimensionality, depth ? 1 : 0, 0, 0, 1, spv::ImageFormatUnknown); sampler.typeId = m_module.defSampledImageType(sampler.typeId); sampler.varId = m_module.newVar( m_module.defPointerType( sampler.typeId, spv::StorageClassUniformConstant), spv::StorageClassUniformConstant); std::string name = str::format("s", idx, suffix, depth ? "_shadow" : ""); m_module.setDebugName(sampler.varId, name.c_str()); const uint32_t bindingId = computeResourceSlotId(m_programInfo.type(), !depth ? DxsoBindingType::ColorImage : DxsoBindingType::DepthImage, idx); m_module.decorateDescriptorSet(sampler.varId, 0); m_module.decorateBinding (sampler.varId, bindingId); // Store descriptor info for the shader interface DxvkResourceSlot resource; resource.slot = bindingId; resource.type = VK_DESCRIPTOR_TYPE_COMBINED_IMAGE_SAMPLER; resource.view = implicit ? VK_IMAGE_VIEW_TYPE_MAX_ENUM : viewType; resource.access = VK_ACCESS_SHADER_READ_BIT; m_resourceSlots.push_back(resource); }; if (m_programInfo.majorVersion() >= 2 && !m_moduleInfo.options.forceSamplerTypeSpecConstants) { DxsoSamplerType samplerType = SamplerTypeFromTextureType(type); DclSampler(idx, samplerType, false, false); if (samplerType != SamplerTypeTexture3D) { // We could also be depth compared! DclSampler(idx, samplerType, true, false); } } else { // Could be any of these! // We will check with the spec constant at sample time. for (uint32_t i = 0; i < SamplerTypeCount; i++) { auto samplerType = static_cast(i); DclSampler(idx, samplerType, false, true); if (samplerType != SamplerTypeTexture3D) DclSampler(idx, samplerType, true, true); } } // Declare a specialization constant which will // store whether or not the depth/color views are bound. const uint32_t colorBinding = computeResourceSlotId(m_programInfo.type(), DxsoBindingType::ColorImage, idx); const uint32_t depthBinding = computeResourceSlotId(m_programInfo.type(), DxsoBindingType::DepthImage, idx); DxsoSampler& sampler = m_samplers[idx]; sampler.colorSpecConst = m_module.specConstBool(true); sampler.depthSpecConst = m_module.specConstBool(true); sampler.type = type; m_module.decorateSpecId(sampler.colorSpecConst, colorBinding); m_module.decorateSpecId(sampler.depthSpecConst, depthBinding); m_module.setDebugName(sampler.colorSpecConst, str::format("s", idx, "_useColor").c_str()); m_module.setDebugName(sampler.depthSpecConst, str::format("s", idx, "_useShadow").c_str()); } uint32_t DxsoCompiler::emitArrayIndex( uint32_t idx, const DxsoBaseRegister* relative) { uint32_t result = m_module.consti32(idx); if (relative != nullptr) { DxsoRegisterValue offset = emitRegisterLoad(*relative, DxsoRegMask(true, false, false, false), nullptr); result = m_module.opIAdd( getVectorTypeId(offset.type), result, offset.id); } return result; } DxsoRegisterPointer DxsoCompiler::emitInputPtr( bool texture, const DxsoBaseRegister& reg, const DxsoBaseRegister* relative) { uint32_t idx = reg.id.num; // Account for the two color regs. if (texture) idx += 2; DxsoRegisterPointer input; input.type = DxsoVectorType{ DxsoScalarType::Float32, 4 }; uint32_t index = this->emitArrayIndex(idx, relative); const uint32_t typeId = getVectorTypeId(input.type); input.id = m_module.opAccessChain( m_module.defPointerType(typeId, spv::StorageClassPrivate), m_vArray, 1, &index); return input; } DxsoRegisterPointer DxsoCompiler::emitRegisterPtr( const char* name, DxsoScalarType ctype, uint32_t ccount, uint32_t defaultVal, spv::StorageClass storageClass, spv::BuiltIn builtIn) { DxsoRegisterPointer result; DxsoRegisterInfo info; info.type.ctype = ctype; info.type.ccount = ccount; info.type.alength = 1; info.sclass = storageClass; result.type = DxsoVectorType{ ctype, ccount }; if (builtIn == spv::BuiltInMax) { result.id = this->emitNewVariableDefault(info, defaultVal); m_module.setDebugName(result.id, name); } else { result.id = this->emitNewBuiltinVariable( info, builtIn, name, defaultVal); } return result; } DxsoRegisterValue DxsoCompiler::emitLoadConstant( const DxsoBaseRegister& reg, const DxsoBaseRegister* relative) { // struct cBuffer_t { // // Type Member Index // // float f[256 or 224]; 0 // int32_t i[16]; 1 // uint32_t boolBitmask; 2 // } DxsoRegisterValue result = { }; switch (reg.id.type) { case DxsoRegisterType::Const: result.type = { DxsoScalarType::Float32, 4 }; if (!relative) result.id = m_cFloat.at(reg.id.num); break; case DxsoRegisterType::ConstInt: result.type = { DxsoScalarType::Sint32, 4 }; result.id = m_cInt.at(reg.id.num); break; case DxsoRegisterType::ConstBool: result.type = { DxsoScalarType::Bool, 1 }; result.id = m_cBool.at(reg.id.num); break; default: break; } if (result.id) return result; switch (reg.id.type) { case DxsoRegisterType::Const: if (!relative) { m_meta.maxConstIndexF = std::max(m_meta.maxConstIndexF, reg.id.num + 1); m_meta.maxConstIndexF = std::min(m_meta.maxConstIndexF, m_layout->floatCount); } else { m_meta.maxConstIndexF = m_layout->floatCount; m_meta.needsConstantCopies |= m_moduleInfo.options.strictConstantCopies || m_cFloat.at(reg.id.num) != 0; } break; case DxsoRegisterType::ConstInt: m_meta.maxConstIndexI = std::max(m_meta.maxConstIndexI, reg.id.num + 1); m_meta.maxConstIndexI = std::min(m_meta.maxConstIndexI, m_layout->intCount); break; case DxsoRegisterType::ConstBool: m_meta.maxConstIndexB = std::max(m_meta.maxConstIndexB, reg.id.num + 1); m_meta.maxConstIndexB = std::min(m_meta.maxConstIndexB, m_layout->boolCount); m_meta.boolConstantMask |= 1 << reg.id.num; break; default: break; } uint32_t relativeIdx = this->emitArrayIndex(reg.id.num, relative); if (reg.id.type != DxsoRegisterType::ConstBool) { uint32_t structIdx = reg.id.type == DxsoRegisterType::Const ? m_module.constu32(0) : m_module.constu32(1); std::array indices = { structIdx, relativeIdx }; uint32_t typeId = getVectorTypeId(result.type); uint32_t ptrId = m_module.opAccessChain( m_module.defPointerType(typeId, spv::StorageClassUniform), m_cBuffer, indices.size(), indices.data()); result.id = m_module.opLoad(typeId, ptrId); if (relative) { uint32_t constCount = m_module.constu32(m_layout->floatCount); // Expand condition to bvec4 since the result has four components uint32_t cond = m_module.opULessThan(m_module.defBoolType(), relativeIdx, constCount); std::array condIds = { cond, cond, cond, cond }; cond = m_module.opCompositeConstruct( m_module.defVectorType(m_module.defBoolType(), 4), condIds.size(), condIds.data()); result.id = m_module.opSelect(typeId, cond, result.id, m_module.constvec4f32(0.0f, 0.0f, 0.0f, 0.0f)); } } else { // Bool constants have no relative indexing, so we can do the bitfield // magic for SWVP at compile time. uint32_t uintType = getScalarTypeId(DxsoScalarType::Uint32); uint32_t uvec4Type = getVectorTypeId({ DxsoScalarType::Uint32, 4 }); // If not SWVP, spec const this uint32_t bitfield; if (m_layout->bitmaskCount != 1) { std::array indices = { m_module.constu32(2), m_module.constu32(reg.id.num / 128) }; uint32_t indexCount = m_layout->bitmaskCount == 1 ? 1 : 2; uint32_t accessType = m_layout->bitmaskCount == 1 ? uintType : uvec4Type; uint32_t ptrId = m_module.opAccessChain( m_module.defPointerType(accessType, spv::StorageClassUniform), m_cBuffer, indexCount, indices.data()); bitfield = m_module.opLoad(accessType, ptrId); } else bitfield = m_boolSpecConstant; uint32_t bitIdx = m_module.consti32(reg.id.num % 32); if (m_layout->bitmaskCount != 1) { uint32_t index = (reg.id.num % 128) / 32; bitfield = m_module.opCompositeExtract(uintType, bitfield, 1, &index); } uint32_t bit = m_module.opBitFieldUExtract( uintType, bitfield, bitIdx, m_module.consti32(1)); result.id = m_module.opINotEqual( getVectorTypeId(result.type), bit, m_module.constu32(0)); } return result; } DxsoRegisterPointer DxsoCompiler::emitOutputPtr( bool texcrdOut, const DxsoBaseRegister& reg, const DxsoBaseRegister* relative) { uint32_t idx = reg.id.num; // Account for the two color regs. if (texcrdOut) idx += 2; DxsoRegisterPointer input; input.type = DxsoVectorType{ DxsoScalarType::Float32, 4 }; uint32_t index = this->emitArrayIndex(idx, relative); const uint32_t typeId = getVectorTypeId(input.type); input.id = m_module.opAccessChain( m_module.defPointerType(typeId, spv::StorageClassPrivate), m_oArray, 1, &index); return input; } DxsoRegisterPointer DxsoCompiler::emitGetOperandPtr( const DxsoBaseRegister& reg, const DxsoBaseRegister* relative) { switch (reg.id.type) { case DxsoRegisterType::Temp: { DxsoRegisterPointer& ptr = m_rRegs.at(reg.id.num); if (ptr.id == 0) { std::string name = str::format("r", reg.id.num); ptr = this->emitRegisterPtr( name.c_str(), DxsoScalarType::Float32, 4, m_module.constvec4f32(0.0f, 0.0f, 0.0f, 0.0f)); } return ptr; } case DxsoRegisterType::Input: { if (!(m_explicitInputs & 1u << reg.id.num)) { this->emitDclInterface( true, reg.id.num, DxsoSemantic{ DxsoUsage::Color, reg.id.num }, IdentityWriteMask, false); } return this->emitInputPtr(false, reg, relative); } case DxsoRegisterType::PixelTexcoord: case DxsoRegisterType::Texture: { if (m_programInfo.type() == DxsoProgramTypes::PixelShader) { // Texture register // SM2, or SM 1.4 if (reg.id.type == DxsoRegisterType::PixelTexcoord || m_programInfo.majorVersion() >= 2 || (m_programInfo.majorVersion() == 1 && m_programInfo.minorVersion() == 4)) { uint32_t adjustedNumber = reg.id.num + 2; if (!(m_explicitInputs & 1u << adjustedNumber)) { this->emitDclInterface( true, adjustedNumber, DxsoSemantic{ DxsoUsage::Texcoord, reg.id.num }, IdentityWriteMask, false); } return this->emitInputPtr(true, reg, relative); } else { // User must use tex/texcoord to put data in this private register. // We use the an oob id which fxc never generates for the texcoord data. DxsoRegisterPointer& ptr = m_tRegs.at(reg.id.num); if (ptr.id == 0) { std::string name = str::format("t", reg.id.num); ptr = this->emitRegisterPtr( name.c_str(), DxsoScalarType::Float32, 4, m_module.constvec4f32(0.0f, 0.0f, 0.0f, 0.0f)); } return ptr; } } else { // Address register if (m_vs.addr.id == 0) { m_vs.addr = this->emitRegisterPtr( "a0", DxsoScalarType::Sint32, 4, m_module.constvec4i32(0, 0, 0, 0)); } return m_vs.addr; } } case DxsoRegisterType::RasterizerOut: switch (reg.id.num) { case RasterOutPosition: if (m_vs.oPos.id == 0) { m_vs.oPos = this->emitRegisterPtr( "oPos", DxsoScalarType::Float32, 4, m_module.constvec4f32(0.0f, 0.0f, 0.0f, 0.0f), spv::StorageClassOutput, spv::BuiltInPosition); } return m_vs.oPos; case RasterOutFog: if (m_fog.id == 0) { bool input = m_programInfo.type() == DxsoProgramType::PixelShader; DxsoSemantic semantic = DxsoSemantic{ DxsoUsage::Fog, 0 }; uint32_t slot = RegisterLinkerSlot(semantic); uint32_t& slots = input ? m_interfaceSlots.inputSlots : m_interfaceSlots.outputSlots; slots |= 1u << slot; m_fog = this->emitRegisterPtr( input ? "vFog" : "oFog", DxsoScalarType::Float32, 1, input ? 0 : m_module.constf32(1.0f), input ? spv::StorageClassInput : spv::StorageClassOutput); m_entryPointInterfaces.push_back(m_fog.id); m_module.decorateLocation(m_fog.id, slot); } return m_fog; case RasterOutPointSize: if (m_vs.oPSize.id == 0) { m_vs.oPSize = this->emitRegisterPtr( "oPSize", DxsoScalarType::Float32, 1, m_module.constf32(0.0f), spv::StorageClassOutput, spv::BuiltInPointSize); } return m_vs.oPSize; } case DxsoRegisterType::ColorOut: { uint32_t idx = std::min(reg.id.num, 4u); if (m_ps.oColor[idx].id == 0) { std::string name = str::format("oC", idx); m_ps.oColor[idx] = this->emitRegisterPtr( name.c_str(), DxsoScalarType::Float32, 4, m_module.constvec4f32(0.0f, 0.0f, 0.0f, 0.0f), spv::StorageClassOutput); m_interfaceSlots.outputSlots |= 1u << idx; m_module.decorateLocation(m_ps.oColor[idx].id, idx); m_module.decorateIndex(m_ps.oColor[idx].id, 0); m_entryPointInterfaces.push_back(m_ps.oColor[idx].id); m_usedRTs |= (1u << idx); } return m_ps.oColor[idx]; } case DxsoRegisterType::AttributeOut: { auto ptr = this->emitOutputPtr(false, reg, nullptr); if (!(m_explicitOutputs & 1u << reg.id.num)) { this->emitDclInterface( false, reg.id.num, DxsoSemantic{ DxsoUsage::Color, reg.id.num }, IdentityWriteMask, false); // TODO: Do we want to make this centroid? m_module.opStore(ptr.id, m_module.constfReplicant(0, ptr.type.ccount)); } return ptr; } case DxsoRegisterType::Output: { bool texcrdOut = m_programInfo.type() == DxsoProgramTypes::VertexShader && m_programInfo.majorVersion() != 3; auto ptr = this->emitOutputPtr(texcrdOut, reg, !texcrdOut ? relative : nullptr); if (texcrdOut) { uint32_t adjustedNumber = reg.id.num + 2; if (!(m_explicitOutputs & 1u << adjustedNumber)) { this->emitDclInterface( false, adjustedNumber, DxsoSemantic{ DxsoUsage::Texcoord, reg.id.num }, IdentityWriteMask, false); m_module.opStore(ptr.id, m_module.constfReplicant(0, ptr.type.ccount)); } } return ptr; } case DxsoRegisterType::DepthOut: if (m_ps.oDepth.id == 0) { m_module.setExecutionMode(m_entryPointId, spv::ExecutionModeDepthReplacing); m_ps.oDepth = this->emitRegisterPtr( "oDepth", DxsoScalarType::Float32, 1, m_module.constf32(0.0f), spv::StorageClassOutput, spv::BuiltInFragDepth); } return m_ps.oDepth; case DxsoRegisterType::Loop: if (m_loopCounter.id == 0) { m_loopCounter = this->emitRegisterPtr( "aL", DxsoScalarType::Sint32, 1, m_module.consti32(0)); } return m_loopCounter; case DxsoRegisterType::MiscType: if (reg.id.num == MiscTypePosition) { if (m_ps.vPos.id == 0) { m_ps.vPos = this->emitRegisterPtr( "vPos", DxsoScalarType::Float32, 4, 0); } return m_ps.vPos; } else { // MiscTypeFace if (m_ps.vFace.id == 0) { m_ps.vFace = this->emitRegisterPtr( "vFace", DxsoScalarType::Float32, 4, 0); } return m_ps.vFace; } case DxsoRegisterType::Predicate: { DxsoRegisterPointer& ptr = m_pRegs.at(reg.id.num); if (ptr.id == 0) { std::string name = str::format("p", reg.id.num); ptr = this->emitRegisterPtr( name.c_str(), DxsoScalarType::Bool, 4, m_module.constvec4b32(false, false, false, false)); } return ptr; } default: { //Logger::warn(str::format("emitGetOperandPtr: unhandled reg type: ", reg.id.type)); DxsoRegisterPointer nullPointer; nullPointer.id = 0; return nullPointer; } } } uint32_t DxsoCompiler::emitBoolComparison(DxsoVectorType type, DxsoComparison cmp, uint32_t a, uint32_t b) { const uint32_t typeId = getVectorTypeId(type); switch (cmp) { default: case DxsoComparison::Never: return m_module.constbReplicant(false, type.ccount); break; case DxsoComparison::GreaterThan: return m_module.opFOrdGreaterThan (typeId, a, b); break; case DxsoComparison::Equal: return m_module.opFOrdEqual (typeId, a, b); break; case DxsoComparison::GreaterEqual: return m_module.opFOrdGreaterThanEqual(typeId, a, b); break; case DxsoComparison::LessThan: return m_module.opFOrdLessThan (typeId, a, b); break; case DxsoComparison::NotEqual: return m_module.opFOrdNotEqual (typeId, a, b); break; case DxsoComparison::LessEqual: return m_module.opFOrdLessThanEqual (typeId, a, b); break; case DxsoComparison::Always: return m_module.constbReplicant(true, type.ccount); break; } } DxsoRegisterValue DxsoCompiler::emitValueLoad( DxsoRegisterPointer ptr) { DxsoRegisterValue result; result.type = ptr.type; result.id = m_module.opLoad( getVectorTypeId(result.type), ptr.id); return result; } DxsoRegisterValue DxsoCompiler::applyPredicate(DxsoRegisterValue pred, DxsoRegisterValue dst, DxsoRegisterValue src) { if (dst.type.ccount != pred.type.ccount) { DxsoRegMask mask = DxsoRegMask( pred.type.ccount > 0, pred.type.ccount > 1, pred.type.ccount > 2, pred.type.ccount > 3); pred = emitRegisterSwizzle(pred, IdentitySwizzle, mask); } dst.id = m_module.opSelect( getVectorTypeId(dst.type), pred.id, src.id, dst.id); return dst; } void DxsoCompiler::emitValueStore( DxsoRegisterPointer ptr, DxsoRegisterValue value, DxsoRegMask writeMask, DxsoRegisterValue predicate) { // If the source value consists of only one component, // it is stored in all components of the destination. if (value.type.ccount == 1) value = emitRegisterExtend(value, writeMask.popCount()); if (ptr.type.ccount == writeMask.popCount()) { if (predicate.id) value = applyPredicate(predicate, emitValueLoad(ptr), value); // Simple case: We write to the entire register m_module.opStore(ptr.id, value.id); } else { // We only write to part of the destination // register, so we need to load and modify it DxsoRegisterValue tmp = emitValueLoad(ptr); tmp = emitRegisterInsert(tmp, value, writeMask); if (predicate.id) value = applyPredicate(predicate, emitValueLoad(ptr), tmp); m_module.opStore(ptr.id, tmp.id); } } DxsoRegisterValue DxsoCompiler::emitClampBoundReplicant( DxsoRegisterValue srcValue, float lb, float ub) { srcValue.id = m_module.opFClamp(getVectorTypeId(srcValue.type), srcValue.id, m_module.constfReplicant(lb, srcValue.type.ccount), m_module.constfReplicant(ub, srcValue.type.ccount)); return srcValue; } DxsoRegisterValue DxsoCompiler::emitSaturate( DxsoRegisterValue srcValue) { return emitClampBoundReplicant(srcValue, 0.0f, 1.0f); } DxsoRegisterValue DxsoCompiler::emitDot( DxsoRegisterValue a, DxsoRegisterValue b) { DxsoRegisterValue dot; dot.type = a.type; dot.type.ccount = 1; dot.id = m_module.opDot(getVectorTypeId(dot.type), a.id, b.id); return dot; } DxsoRegisterValue DxsoCompiler::emitRegisterInsert( DxsoRegisterValue dstValue, DxsoRegisterValue srcValue, DxsoRegMask srcMask) { DxsoRegisterValue result; result.type = dstValue.type; const uint32_t typeId = getVectorTypeId(result.type); if (srcMask.popCount() == 0) { // Nothing to do if the insertion mask is empty result.id = dstValue.id; } else if (dstValue.type.ccount == 1) { // Both values are scalar, so the first component // of the write mask decides which one to take. result.id = srcMask[0] ? srcValue.id : dstValue.id; } else if (srcValue.type.ccount == 1) { // The source value is scalar. Since OpVectorShuffle // requires both arguments to be vectors, we have to // use OpCompositeInsert to modify the vector instead. const uint32_t componentId = srcMask.firstSet(); result.id = m_module.opCompositeInsert(typeId, srcValue.id, dstValue.id, 1, &componentId); } else { // Both arguments are vectors. We can determine which // components to take from which vector and use the // OpVectorShuffle instruction. std::array components; uint32_t srcComponentId = dstValue.type.ccount; for (uint32_t i = 0; i < dstValue.type.ccount; i++) components.at(i) = srcMask[i] ? srcComponentId++ : i; result.id = m_module.opVectorShuffle( typeId, dstValue.id, srcValue.id, dstValue.type.ccount, components.data()); } return result; } DxsoRegisterValue DxsoCompiler::emitRegisterLoadRaw( const DxsoBaseRegister& reg, const DxsoBaseRegister* relative) { switch (reg.id.type) { case DxsoRegisterType::Const: case DxsoRegisterType::ConstInt: case DxsoRegisterType::ConstBool: return emitLoadConstant(reg, relative); default: return emitValueLoad(emitGetOperandPtr(reg, relative)); } } DxsoRegisterValue DxsoCompiler::emitRegisterExtend( DxsoRegisterValue value, uint32_t size) { if (size == 1) return value; std::array ids = {{ value.id, value.id, value.id, value.id, }}; DxsoRegisterValue result; result.type.ctype = value.type.ctype; result.type.ccount = size; result.id = m_module.opCompositeConstruct( getVectorTypeId(result.type), size, ids.data()); return result; } DxsoRegisterValue DxsoCompiler::emitRegisterSwizzle( DxsoRegisterValue value, DxsoRegSwizzle swizzle, DxsoRegMask writeMask) { if (value.type.ccount == 1) return emitRegisterExtend(value, writeMask.popCount()); std::array indices; uint32_t dstIndex = 0; for (uint32_t i = 0; i < 4; i++) { if (writeMask[i]) indices[dstIndex++] = swizzle[i]; } // If the swizzle combined with the mask can be reduced // to a no-op, we don't need to insert any instructions. bool isIdentitySwizzle = dstIndex == value.type.ccount; for (uint32_t i = 0; i < dstIndex && isIdentitySwizzle; i++) isIdentitySwizzle &= indices[i] == i; if (isIdentitySwizzle) return value; // Use OpCompositeExtract if the resulting vector contains // only one component, and OpVectorShuffle if it is a vector. DxsoRegisterValue result; result.type.ctype = value.type.ctype; result.type.ccount = dstIndex; const uint32_t typeId = getVectorTypeId(result.type); if (dstIndex == 1) { result.id = m_module.opCompositeExtract( typeId, value.id, 1, indices.data()); } else { result.id = m_module.opVectorShuffle( typeId, value.id, value.id, dstIndex, indices.data()); } return result; } DxsoRegisterValue DxsoCompiler::emitSrcOperandPreSwizzleModifiers( DxsoRegisterValue value, DxsoRegModifier modifier) { // r / r.z // r / r.w if (modifier == DxsoRegModifier::Dz || modifier == DxsoRegModifier::Dw) { const uint32_t index = modifier == DxsoRegModifier::Dz ? 2 : 3; std::array indices = { index, index, index, index }; uint32_t component = m_module.opVectorShuffle( getVectorTypeId(value.type), value.id, value.id, value.type.ccount, indices.data()); value.id = m_module.opFDiv( getVectorTypeId(value.type), value.id, component); } return value; } DxsoRegisterValue DxsoCompiler::emitSrcOperandPostSwizzleModifiers( DxsoRegisterValue value, DxsoRegModifier modifier) { // r - 0.5 if (modifier == DxsoRegModifier::Bias || modifier == DxsoRegModifier::BiasNeg) { uint32_t halfVec = m_module.constfReplicant( 0.5f, value.type.ccount); value.id = m_module.opFSub( getVectorTypeId(value.type), value.id, halfVec); } // fma(r, 2.0f, -1.0f) if (modifier == DxsoRegModifier::Sign || modifier == DxsoRegModifier::SignNeg) { uint32_t twoVec = m_module.constfReplicant( 2.0f, value.type.ccount); uint32_t minusOneVec = m_module.constfReplicant( -1.0f, value.type.ccount); value.id = m_module.opFFma( getVectorTypeId(value.type), value.id, twoVec, minusOneVec); } // 1 - r if (modifier == DxsoRegModifier::Comp) { uint32_t oneVec = m_module.constfReplicant( 1.0f, value.type.ccount); value.id = m_module.opFSub( getVectorTypeId(value.type), oneVec, value.id); } // r * 2 if (modifier == DxsoRegModifier::X2 || modifier == DxsoRegModifier::X2Neg) { uint32_t twoVec = m_module.constfReplicant( 2.0f, value.type.ccount); value.id = m_module.opFMul( getVectorTypeId(value.type), value.id, twoVec); } // abs( r ) if (modifier == DxsoRegModifier::Abs || modifier == DxsoRegModifier::AbsNeg) { value.id = m_module.opFAbs( getVectorTypeId(value.type), value.id); } // !r if (modifier == DxsoRegModifier::Not) { value.id = m_module.opLogicalNot(getVectorTypeId(value.type), value.id); } // -r // Treating as -r // Treating as -r // -r * 2 // -abs(r) if (modifier == DxsoRegModifier::Neg || modifier == DxsoRegModifier::BiasNeg || modifier == DxsoRegModifier::SignNeg || modifier == DxsoRegModifier::X2Neg || modifier == DxsoRegModifier::AbsNeg) { value.id = m_module.opFNegate( getVectorTypeId(value.type), value.id); } return value; } DxsoRegisterValue DxsoCompiler::emitRegisterLoad( const DxsoBaseRegister& reg, DxsoRegMask writeMask, const DxsoBaseRegister* relative) { // Load operand from the operand pointer DxsoRegisterValue result = emitRegisterLoadRaw(reg, relative); // PS 1.x clamps float constants if (m_programInfo.type() == DxsoProgramType::PixelShader && m_programInfo.majorVersion() == 1 && reg.id.type == DxsoRegisterType::Const) result = emitClampBoundReplicant(result, -1.0f, 1.0f); // Apply operand modifiers result = emitSrcOperandPreSwizzleModifiers(result, reg.modifier); // Apply operand swizzle to the operand value result = emitRegisterSwizzle(result, reg.swizzle, writeMask); // Apply operand modifiers result = emitSrcOperandPostSwizzleModifiers(result, reg.modifier); return result; } void DxsoCompiler::emitDcl(const DxsoInstructionContext& ctx) { auto id = ctx.dst.id; if (id.type == DxsoRegisterType::Sampler) { this->emitDclSampler( ctx.dst.id.num, ctx.dcl.textureType); } else if (id.type == DxsoRegisterType::Input || id.type == DxsoRegisterType::Texture || id.type == DxsoRegisterType::Output) { DxsoSemantic semantic = ctx.dcl.semantic; uint32_t vIndex = id.num; if (m_programInfo.type() == DxsoProgramTypes::PixelShader) { // Semantic in PS < 3 is based upon id. if (m_programInfo.majorVersion() < 3) { // Account for the two color registers. if (id.type == DxsoRegisterType::Texture) vIndex += 2; semantic = DxsoSemantic{ id.type == DxsoRegisterType::Texture ? DxsoUsage::Texcoord : DxsoUsage::Color, id.num }; } } this->emitDclInterface( id.type != DxsoRegisterType::Output, vIndex, semantic, ctx.dst.mask, ctx.dst.centroid); } else { //Logger::warn(str::format("DxsoCompiler::emitDcl: unhandled register type ", id.type)); } } void DxsoCompiler::emitDef(const DxsoInstructionContext& ctx) { switch (ctx.instruction.opcode) { case DxsoOpcode::Def: emitDefF(ctx); break; case DxsoOpcode::DefI: emitDefI(ctx); break; case DxsoOpcode::DefB: emitDefB(ctx); break; default: throw DxvkError("DxsoCompiler::emitDef: Invalid definition opcode"); break; } } void DxsoCompiler::emitDefF(const DxsoInstructionContext& ctx) { const float* data = ctx.def.float32; uint32_t constId = m_module.constvec4f32(data[0], data[1], data[2], data[3]); m_cFloat.at(ctx.dst.id.num) = constId; std::string name = str::format("cF", ctx.dst.id.num, "_def"); m_module.setDebugName(constId, name.c_str()); DxsoDefinedConstant constant; constant.uboIdx = ctx.dst.id.num; for (uint32_t i = 0; i < 4; i++) constant.float32[i] = data[i]; m_constants.push_back(constant); } void DxsoCompiler::emitDefI(const DxsoInstructionContext& ctx) { const int32_t* data = ctx.def.int32; uint32_t constId = m_module.constvec4i32(data[0], data[1], data[2], data[3]); m_cInt.at(ctx.dst.id.num) = constId; std::string name = str::format("cI", ctx.dst.id.num, "_def"); m_module.setDebugName(constId, name.c_str()); } void DxsoCompiler::emitDefB(const DxsoInstructionContext& ctx) { const int32_t* data = ctx.def.int32; uint32_t constId = m_module.constBool(data[0] != 0); m_cBool.at(ctx.dst.id.num) = constId; std::string name = str::format("cB", ctx.dst.id.num, "_def"); m_module.setDebugName(constId, name.c_str()); } bool DxsoCompiler::isScalarRegister(DxsoRegisterId id) { return id == DxsoRegisterId{DxsoRegisterType::DepthOut, 0} || id == DxsoRegisterId{DxsoRegisterType::RasterizerOut, RasterOutPointSize} || id == DxsoRegisterId{DxsoRegisterType::RasterizerOut, RasterOutFog}; } void DxsoCompiler::emitMov(const DxsoInstructionContext& ctx) { DxsoRegisterPointer dst = emitGetOperandPtr(ctx.dst); DxsoRegMask mask = ctx.dst.mask; if (isScalarRegister(ctx.dst.id)) mask = DxsoRegMask(true, false, false, false); DxsoRegisterValue src0 = emitRegisterLoad(ctx.src[0], mask); DxsoRegisterValue result; result.type.ctype = dst.type.ctype; result.type.ccount = mask.popCount(); const uint32_t typeId = getVectorTypeId(result.type); if (dst.type.ctype != src0.type.ctype) { // We have Mova for this... but it turns out Mov has the same behaviour in d3d9! // Convert float -> int32_t // and vice versa if (dst.type.ctype == DxsoScalarType::Sint32) { // We need to floor for VS 1.1 and below, the documentation is a dirty stinking liar. if (m_programInfo.majorVersion() < 2 && m_programInfo.minorVersion() < 2) result.id = m_module.opFloor(getVectorTypeId(src0.type), src0.id); else result.id = m_module.opRound(getVectorTypeId(src0.type), src0.id); result.id = m_module.opConvertFtoS(typeId, result.id); } else // Float32 result.id = m_module.opConvertStoF(typeId, src0.id); } else // No special stuff needed! result.id = src0.id; this->emitDstStore(dst, result, mask, ctx.dst.saturate, emitPredicateLoad(ctx), ctx.dst.shift, ctx.dst.id); } void DxsoCompiler::emitVectorAlu(const DxsoInstructionContext& ctx) { const auto& src = ctx.src; DxsoRegMask mask = ctx.dst.mask; DxsoRegisterPointer dst = emitGetOperandPtr(ctx.dst); if (isScalarRegister(ctx.dst.id)) mask = DxsoRegMask(true, false, false, false); DxsoRegisterValue result; result.type.ctype = dst.type.ctype; result.type.ccount = mask.popCount(); DxsoVectorType scalarType = result.type; scalarType.ccount = 1; const uint32_t typeId = getVectorTypeId(result.type); const uint32_t scalarTypeId = getVectorTypeId(scalarType); const DxsoOpcode opcode = ctx.instruction.opcode; switch (opcode) { case DxsoOpcode::Add: result.id = m_module.opFAdd(typeId, emitRegisterLoad(src[0], mask).id, emitRegisterLoad(src[1], mask).id); break; case DxsoOpcode::Sub: result.id = m_module.opFSub(typeId, emitRegisterLoad(src[0], mask).id, emitRegisterLoad(src[1], mask).id); break; case DxsoOpcode::Mad: result.id = m_module.opFFma(typeId, emitRegisterLoad(src[0], mask).id, emitRegisterLoad(src[1], mask).id, emitRegisterLoad(src[2], mask).id); break; case DxsoOpcode::Mul: result.id = m_module.opFMul(typeId, emitRegisterLoad(src[0], mask).id, emitRegisterLoad(src[1], mask).id); break; case DxsoOpcode::Rcp: result.id = m_module.opFDiv(typeId, m_module.constfReplicant(1.0f, result.type.ccount), emitRegisterLoad(src[0], mask).id); if (m_moduleInfo.options.d3d9FloatEmulation) { result.id = m_module.opNMin(typeId, result.id, m_module.constfReplicant(FLT_MAX, result.type.ccount)); } break; case DxsoOpcode::Rsq: result.id = m_module.opFAbs(typeId, emitRegisterLoad(src[0], mask).id); result.id = m_module.opInverseSqrt(typeId, result.id); if (m_moduleInfo.options.d3d9FloatEmulation) { result.id = m_module.opNMin(typeId, result.id, m_module.constfReplicant(FLT_MAX, result.type.ccount)); } break; case DxsoOpcode::Dp3: { DxsoRegMask srcMask(true, true, true, false); result = emitDot( emitRegisterLoad(src[0], srcMask), emitRegisterLoad(src[1], srcMask)); break; } case DxsoOpcode::Dp4: result = emitDot( emitRegisterLoad(src[0], IdentityWriteMask), emitRegisterLoad(src[1], IdentityWriteMask)); break; case DxsoOpcode::Slt: case DxsoOpcode::Sge: { const uint32_t boolTypeId = getVectorTypeId({ DxsoScalarType::Bool, result.type.ccount }); uint32_t cmpResult = opcode == DxsoOpcode::Slt ? m_module.opFOrdLessThan (boolTypeId, emitRegisterLoad(src[0], mask).id, emitRegisterLoad(src[1], mask).id) : m_module.opFOrdGreaterThanEqual(boolTypeId, emitRegisterLoad(src[0], mask).id, emitRegisterLoad(src[1], mask).id); result.id = m_module.opSelect(typeId, cmpResult, m_module.constfReplicant(1.0f, result.type.ccount), m_module.constfReplicant(0.0f, result.type.ccount)); break; } case DxsoOpcode::Min: result.id = m_module.opFMin(typeId, emitRegisterLoad(src[0], mask).id, emitRegisterLoad(src[1], mask).id); break; case DxsoOpcode::Max: result.id = m_module.opFMax(typeId, emitRegisterLoad(src[0], mask).id, emitRegisterLoad(src[1], mask).id); break; case DxsoOpcode::ExpP: if (m_programInfo.majorVersion() < 2) { DxsoRegMask srcMask(true, false, false, false); uint32_t src0 = emitRegisterLoad(src[0], srcMask).id; uint32_t index = 0; std::array resultIndices; if (mask[0]) resultIndices[index++] = m_module.opExp2(scalarTypeId, m_module.opFloor(scalarTypeId, src0)); if (mask[1]) resultIndices[index++] = m_module.opFSub(scalarTypeId, src0, m_module.opFloor(scalarTypeId, src0)); if (mask[2]) resultIndices[index++] = m_module.opExp2(scalarTypeId, src0); if (mask[3]) resultIndices[index++] = m_module.constf32(1.0f); if (result.type.ccount == 1) result.id = resultIndices[0]; else result.id = m_module.opCompositeConstruct(typeId, result.type.ccount, resultIndices.data()); break; } case DxsoOpcode::Exp: result.id = m_module.opExp2(typeId, emitRegisterLoad(src[0], mask).id); break; case DxsoOpcode::Pow: { uint32_t base = emitRegisterLoad(src[0], mask).id; base = m_module.opFAbs(typeId, base); uint32_t exponent = emitRegisterLoad(src[1], mask).id; result.id = m_module.opPow(typeId, base, exponent); if (m_moduleInfo.options.strictPow && m_moduleInfo.options.d3d9FloatEmulation) { DxsoRegisterValue cmp; cmp.type = { DxsoScalarType::Bool, result.type.ccount }; cmp.id = m_module.opFOrdEqual(getVectorTypeId(cmp.type), exponent, m_module.constfReplicant(0.0f, cmp.type.ccount)); result.id = m_module.opSelect(typeId, cmp.id, m_module.constfReplicant(1.0f, cmp.type.ccount), result.id); } break; } case DxsoOpcode::Crs: { DxsoRegMask vec3Mask(true, true, true, false); DxsoRegisterValue crossValue; crossValue.type = { DxsoScalarType::Float32, 3 }; crossValue.id = m_module.opCross(getVectorTypeId(crossValue.type), emitRegisterLoad(src[0], vec3Mask).id, emitRegisterLoad(src[1], vec3Mask).id); std::array indices = { 0, 0, 0 }; uint32_t index = 0; for (uint32_t i = 0; i < indices.size(); i++) { if (mask[i]) indices[index++] = m_module.opCompositeExtract(m_module.defFloatType(32), crossValue.id, 1, &i); } result.id = m_module.opCompositeConstruct(getVectorTypeId(result.type), result.type.ccount, indices.data()); break; } case DxsoOpcode::Abs: result.id = m_module.opFAbs(typeId, emitRegisterLoad(src[0], mask).id); break; case DxsoOpcode::Nrm: { // Nrm is 3D... DxsoRegMask srcMask(true, true, true, false); auto vec3 = emitRegisterLoad(src[0], srcMask); DxsoRegisterValue dot = emitDot(vec3, vec3); dot.id = m_module.opInverseSqrt (scalarTypeId, dot.id); if (m_moduleInfo.options.d3d9FloatEmulation) { dot.id = m_module.opNMin (scalarTypeId, dot.id, m_module.constf32(FLT_MAX)); } // r * rsq(r . r); result.id = m_module.opVectorTimesScalar( typeId, emitRegisterLoad(src[0], mask).id, dot.id); break; } case DxsoOpcode::SinCos: { DxsoRegMask srcMask(true, false, false, false); uint32_t src0 = emitRegisterLoad(src[0], srcMask).id; std::array sincosVectorIndices = { 0, 0, 0, 0 }; uint32_t index = 0; if (mask[0]) sincosVectorIndices[index++] = m_module.opCos(scalarTypeId, src0); if (mask[1]) sincosVectorIndices[index++] = m_module.opSin(scalarTypeId, src0); for (; index < result.type.ccount; index++) { if (sincosVectorIndices[index] == 0) sincosVectorIndices[index] = m_module.constf32(0.0f); } if (result.type.ccount == 1) result.id = sincosVectorIndices[0]; else result.id = m_module.opCompositeConstruct(typeId, result.type.ccount, sincosVectorIndices.data()); break; } case DxsoOpcode::Lit: { DxsoRegMask srcMask(true, true, true, true); uint32_t srcOp = emitRegisterLoad(src[0], srcMask).id; const uint32_t x = 0; const uint32_t y = 1; const uint32_t w = 3; uint32_t srcX = m_module.opCompositeExtract(scalarTypeId, srcOp, 1, &x); uint32_t srcY = m_module.opCompositeExtract(scalarTypeId, srcOp, 1, &y); uint32_t srcW = m_module.opCompositeExtract(scalarTypeId, srcOp, 1, &w); uint32_t power = m_module.opFClamp( scalarTypeId, srcW, m_module.constf32(-127.9961f), m_module.constf32(127.9961f)); std::array resultIndices; uint32_t index = 0; if (mask[0]) resultIndices[index++] = m_module.constf32(1.0f); if (mask[1]) resultIndices[index++] = m_module.opFMax(scalarTypeId, srcX, m_module.constf32(0)); if (mask[2]) resultIndices[index++] = m_module.opPow (scalarTypeId, srcY, power); if (mask[3]) resultIndices[index++] = m_module.constf32(1.0f); const uint32_t boolType = m_module.defBoolType(); uint32_t zTestX = m_module.opFOrdGreaterThanEqual(boolType, srcX, m_module.constf32(0)); uint32_t zTestY = m_module.opFOrdGreaterThanEqual(boolType, srcY, m_module.constf32(0)); uint32_t zTest = m_module.opLogicalAnd(boolType, zTestX, zTestY); if (result.type.ccount > 2) resultIndices[2] = m_module.opSelect( scalarTypeId, zTest, resultIndices[2], m_module.constf32(0.0f)); if (result.type.ccount == 1) result.id = resultIndices[0]; else result.id = m_module.opCompositeConstruct(typeId, result.type.ccount, resultIndices.data()); break; } case DxsoOpcode::Dst: { //dest.x = 1; //dest.y = src0.y * src1.y; //dest.z = src0.z; //dest.w = src1.w; DxsoRegMask srcMask(true, true, true, true); uint32_t src0 = emitRegisterLoad(src[0], srcMask).id; uint32_t src1 = emitRegisterLoad(src[1], srcMask).id; const uint32_t y = 1; const uint32_t z = 2; const uint32_t w = 3; uint32_t src0Y = m_module.opCompositeExtract(scalarTypeId, src0, 1, &y); uint32_t src1Y = m_module.opCompositeExtract(scalarTypeId, src1, 1, &y); uint32_t src0Z = m_module.opCompositeExtract(scalarTypeId, src0, 1, &z); uint32_t src1W = m_module.opCompositeExtract(scalarTypeId, src1, 1, &w); std::array resultIndices; resultIndices[0] = m_module.constf32(1.0f); resultIndices[1] = m_module.opFMul(scalarTypeId, src0Y, src1Y); resultIndices[2] = src0Z; resultIndices[3] = src1W; if (result.type.ccount == 1) result.id = resultIndices[0]; else result.id = m_module.opCompositeConstruct(typeId, result.type.ccount, resultIndices.data()); break; } case DxsoOpcode::LogP: case DxsoOpcode::Log: result.id = m_module.opFAbs(typeId, emitRegisterLoad(src[0], mask).id); result.id = m_module.opLog2(typeId, result.id); if (m_moduleInfo.options.d3d9FloatEmulation) { result.id = m_module.opNMax(typeId, result.id, m_module.constfReplicant(-FLT_MAX, result.type.ccount)); } break; case DxsoOpcode::Lrp: result.id = m_module.opFMix(typeId, emitRegisterLoad(src[2], mask).id, emitRegisterLoad(src[1], mask).id, emitRegisterLoad(src[0], mask).id); break; case DxsoOpcode::Frc: result.id = m_module.opFract(typeId, emitRegisterLoad(src[0], mask).id); break; case DxsoOpcode::Cmp: { const uint32_t boolTypeId = getVectorTypeId({ DxsoScalarType::Bool, result.type.ccount }); uint32_t cmp = m_module.opFOrdGreaterThanEqual( boolTypeId, emitRegisterLoad(src[0], mask).id, m_module.constfReplicant(0.0f, result.type.ccount)); result.id = m_module.opSelect( typeId, cmp, emitRegisterLoad(src[1], mask).id, emitRegisterLoad(src[2], mask).id); break; } case DxsoOpcode::Cnd: { const uint32_t boolTypeId = getVectorTypeId({ DxsoScalarType::Bool, result.type.ccount }); uint32_t cmp = m_module.opFOrdGreaterThan( boolTypeId, emitRegisterLoad(src[0], mask).id, m_module.constfReplicant(0.5f, result.type.ccount)); result.id = m_module.opSelect( typeId, cmp, emitRegisterLoad(src[1], mask).id, emitRegisterLoad(src[2], mask).id); break; } case DxsoOpcode::Dp2Add: { DxsoRegMask dotSrcMask(true, true, false, false); DxsoRegMask addSrcMask(true, false, false, false); DxsoRegisterValue dot = emitDot( emitRegisterLoad(src[0], dotSrcMask), emitRegisterLoad(src[1], dotSrcMask)); dot.id = m_module.opFAdd(scalarTypeId, dot.id, emitRegisterLoad(src[2], addSrcMask).id); result.id = dot.id; result.type = scalarType; break; } case DxsoOpcode::DsX: result.id = m_module.opDpdx( typeId, emitRegisterLoad(src[0], mask).id); break; case DxsoOpcode::DsY: result.id = m_module.opDpdy( typeId, emitRegisterLoad(src[0], mask).id); break; default: Logger::warn(str::format("DxsoCompiler::emitVectorAlu: unimplemented op ", opcode)); return; } this->emitDstStore(dst, result, mask, ctx.dst.saturate, emitPredicateLoad(ctx), ctx.dst.shift, ctx.dst.id); } void DxsoCompiler::emitPredicateOp(const DxsoInstructionContext& ctx) { const auto& src = ctx.src; DxsoRegMask mask = ctx.dst.mask; DxsoRegisterPointer dst = emitGetOperandPtr(ctx.dst); DxsoRegisterValue result; result.type.ctype = dst.type.ctype; result.type.ccount = mask.popCount(); result.id = emitBoolComparison( result.type, ctx.instruction.specificData.comparison, emitRegisterLoad(src[0], mask).id, emitRegisterLoad(src[1], mask).id); this->emitValueStore(dst, result, mask, emitPredicateLoad(ctx)); } void DxsoCompiler::emitMatrixAlu(const DxsoInstructionContext& ctx) { const auto& src = ctx.src; DxsoRegMask mask = ctx.dst.mask; DxsoRegisterPointer dst = emitGetOperandPtr(ctx.dst); DxsoRegisterValue result; result.type.ctype = dst.type.ctype; result.type.ccount = mask.popCount(); DxsoVectorType scalarType = result.type; scalarType.ccount = 1; const uint32_t typeId = getVectorTypeId(result.type); const uint32_t scalarTypeId = getVectorTypeId(scalarType); const DxsoOpcode opcode = ctx.instruction.opcode; uint32_t dotCount; uint32_t iterCount; switch (opcode) { case DxsoOpcode::M3x2: dotCount = 3; iterCount = 2; break; case DxsoOpcode::M3x3: dotCount = 3; iterCount = 3; break; case DxsoOpcode::M3x4: dotCount = 3; iterCount = 4; break; case DxsoOpcode::M4x3: dotCount = 4; iterCount = 3; break; case DxsoOpcode::M4x4: dotCount = 4; iterCount = 4; break; default: Logger::warn(str::format("DxsoCompiler::emitMatrixAlu: unimplemented op ", opcode)); return; } DxsoRegMask srcMask(true, true, true, dotCount == 4); std::array indices; DxsoRegister src0 = src[0]; DxsoRegister src1 = src[1]; for (uint32_t i = 0; i < iterCount; i++) { indices[i] = m_module.opDot(scalarTypeId, emitRegisterLoad(src0, srcMask).id, emitRegisterLoad(src1, srcMask).id); src1.id.num++; } result.id = m_module.opCompositeConstruct( typeId, iterCount, indices.data()); this->emitDstStore(dst, result, mask, ctx.dst.saturate, emitPredicateLoad(ctx), ctx.dst.shift, ctx.dst.id); } void DxsoCompiler::emitControlFlowGenericLoop( bool count, uint32_t initialVar, uint32_t strideVar, uint32_t iterationCountVar) { const uint32_t itType = m_module.defIntType(32, 1); DxsoCfgBlock block; block.type = DxsoCfgBlockType::Loop; block.b_loop.labelHeader = m_module.allocateId(); block.b_loop.labelBegin = m_module.allocateId(); block.b_loop.labelContinue = m_module.allocateId(); block.b_loop.labelBreak = m_module.allocateId(); block.b_loop.iteratorPtr = m_module.newVar( m_module.defPointerType(itType, spv::StorageClassPrivate), spv::StorageClassPrivate); block.b_loop.strideVar = strideVar; block.b_loop.countBackup = 0; if (count) { DxsoBaseRegister loop; loop.id = { DxsoRegisterType::Loop, 0 }; DxsoRegisterPointer loopPtr = emitGetOperandPtr(loop, nullptr); uint32_t loopVal = m_module.opLoad( getVectorTypeId(loopPtr.type), loopPtr.id); block.b_loop.countBackup = loopVal; m_module.opStore(loopPtr.id, initialVar); } m_module.setDebugName(block.b_loop.iteratorPtr, "iter"); m_module.opStore(block.b_loop.iteratorPtr, iterationCountVar); m_module.opBranch(block.b_loop.labelHeader); m_module.opLabel (block.b_loop.labelHeader); m_module.opLoopMerge( block.b_loop.labelBreak, block.b_loop.labelContinue, spv::LoopControlMaskNone); m_module.opBranch(block.b_loop.labelBegin); m_module.opLabel (block.b_loop.labelBegin); uint32_t iterator = m_module.opLoad(itType, block.b_loop.iteratorPtr); uint32_t complete = m_module.opIEqual(m_module.defBoolType(), iterator, m_module.consti32(0)); const uint32_t breakBlock = m_module.allocateId(); const uint32_t mergeBlock = m_module.allocateId(); m_module.opSelectionMerge(mergeBlock, spv::SelectionControlMaskNone); m_module.opBranchConditional( complete, breakBlock, mergeBlock); m_module.opLabel(breakBlock); m_module.opBranch(block.b_loop.labelBreak); m_module.opLabel(mergeBlock); iterator = m_module.opISub(itType, iterator, m_module.consti32(1)); m_module.opStore(block.b_loop.iteratorPtr, iterator); m_controlFlowBlocks.push_back(block); } void DxsoCompiler::emitControlFlowGenericLoopEnd() { if (m_controlFlowBlocks.size() == 0 || m_controlFlowBlocks.back().type != DxsoCfgBlockType::Loop) throw DxvkError("DxsoCompiler: 'EndRep' without 'Rep' or 'Loop' found"); // Remove the block from the stack, it's closed const DxsoCfgBlock block = m_controlFlowBlocks.back(); m_controlFlowBlocks.pop_back(); if (block.b_loop.strideVar) { DxsoBaseRegister loop; loop.id = { DxsoRegisterType::Loop, 0 }; DxsoRegisterPointer loopPtr = emitGetOperandPtr(loop, nullptr); uint32_t val = m_module.opLoad( getVectorTypeId(loopPtr.type), loopPtr.id); val = m_module.opIAdd( getVectorTypeId(loopPtr.type), val, block.b_loop.strideVar); m_module.opStore(loopPtr.id, val); } // Declare the continue block m_module.opBranch(block.b_loop.labelContinue); m_module.opLabel(block.b_loop.labelContinue); // Declare the merge block m_module.opBranch(block.b_loop.labelHeader); m_module.opLabel(block.b_loop.labelBreak); if (block.b_loop.countBackup) { DxsoBaseRegister loop; loop.id = { DxsoRegisterType::Loop, 0 }; DxsoRegisterPointer loopPtr = emitGetOperandPtr(loop, nullptr); m_module.opStore(loopPtr.id, block.b_loop.countBackup); } } void DxsoCompiler::emitControlFlowRep(const DxsoInstructionContext& ctx) { DxsoRegMask srcMask(true, false, false, false); this->emitControlFlowGenericLoop( false, 0, 0, emitRegisterLoad(ctx.src[0], srcMask).id); } void DxsoCompiler::emitControlFlowEndRep(const DxsoInstructionContext& ctx) { emitControlFlowGenericLoopEnd(); } void DxsoCompiler::emitControlFlowLoop(const DxsoInstructionContext& ctx) { const uint32_t itType = m_module.defIntType(32, 1); DxsoRegMask srcMask(true, true, true, false); uint32_t integerRegister = emitRegisterLoad(ctx.src[1], srcMask).id; uint32_t x = 0; uint32_t y = 1; uint32_t z = 2; uint32_t iterCount = m_module.opCompositeExtract(itType, integerRegister, 1, &x); uint32_t initialValue = m_module.opCompositeExtract(itType, integerRegister, 1, &y); uint32_t strideSize = m_module.opCompositeExtract(itType, integerRegister, 1, &z); this->emitControlFlowGenericLoop( true, initialValue, strideSize, iterCount); } void DxsoCompiler::emitControlFlowEndLoop(const DxsoInstructionContext& ctx) { this->emitControlFlowGenericLoopEnd(); } void DxsoCompiler::emitControlFlowBreak(const DxsoInstructionContext& ctx) { DxsoCfgBlock* cfgBlock = cfgFindBlock({ DxsoCfgBlockType::Loop }); if (cfgBlock == nullptr) throw DxvkError("DxbcCompiler: 'Break' outside 'Rep' or 'Loop' found"); m_module.opBranch(cfgBlock->b_loop.labelBreak); // Subsequent instructions assume that there is an open block const uint32_t labelId = m_module.allocateId(); m_module.opLabel(labelId); } void DxsoCompiler::emitControlFlowBreakC(const DxsoInstructionContext& ctx) { DxsoCfgBlock* cfgBlock = cfgFindBlock({ DxsoCfgBlockType::Loop }); if (cfgBlock == nullptr) throw DxvkError("DxbcCompiler: 'BreakC' outside 'Rep' or 'Loop' found"); DxsoRegMask srcMask(true, false, false, false); auto a = emitRegisterLoad(ctx.src[0], srcMask); auto b = emitRegisterLoad(ctx.src[1], srcMask); uint32_t result = this->emitBoolComparison( { DxsoScalarType::Bool, a.type.ccount }, ctx.instruction.specificData.comparison, a.id, b.id); // We basically have to wrap this into an 'if' block const uint32_t breakBlock = m_module.allocateId(); const uint32_t mergeBlock = m_module.allocateId(); m_module.opSelectionMerge(mergeBlock, spv::SelectionControlMaskNone); m_module.opBranchConditional( result, breakBlock, mergeBlock); m_module.opLabel(breakBlock); m_module.opBranch(cfgBlock->b_loop.labelBreak); m_module.opLabel(mergeBlock); } void DxsoCompiler::emitControlFlowIf(const DxsoInstructionContext& ctx) { const auto opcode = ctx.instruction.opcode; uint32_t result; DxsoRegMask srcMask(true, false, false, false); if (opcode == DxsoOpcode::Ifc) { auto a = emitRegisterLoad(ctx.src[0], srcMask); auto b = emitRegisterLoad(ctx.src[1], srcMask); result = this->emitBoolComparison( { DxsoScalarType::Bool, a.type.ccount }, ctx.instruction.specificData.comparison, a.id, b.id); } else result = emitRegisterLoad(ctx.src[0], srcMask).id; // Declare the 'if' block. We do not know if there // will be an 'else' block or not, so we'll assume // that there is one and leave it empty otherwise. DxsoCfgBlock block; block.type = DxsoCfgBlockType::If; block.b_if.ztestId = result; block.b_if.labelIf = m_module.allocateId(); block.b_if.labelElse = 0; block.b_if.labelEnd = m_module.allocateId(); block.b_if.headerPtr = m_module.getInsertionPtr(); m_controlFlowBlocks.push_back(block); // We'll insert the branch instruction when closing // the block, since we don't know whether or not an // else block is needed right now. m_module.opLabel(block.b_if.labelIf); } void DxsoCompiler::emitControlFlowElse(const DxsoInstructionContext& ctx) { if (m_controlFlowBlocks.size() == 0 || m_controlFlowBlocks.back().type != DxsoCfgBlockType::If || m_controlFlowBlocks.back().b_if.labelElse != 0) throw DxvkError("DxsoCompiler: 'Else' without 'If' found"); // Set the 'Else' flag so that we do // not insert a dummy block on 'EndIf' DxsoCfgBlock& block = m_controlFlowBlocks.back(); block.b_if.labelElse = m_module.allocateId(); // Close the 'If' block by branching to // the merge block we declared earlier m_module.opBranch(block.b_if.labelEnd); m_module.opLabel (block.b_if.labelElse); } void DxsoCompiler::emitControlFlowEndIf(const DxsoInstructionContext& ctx) { if (m_controlFlowBlocks.size() == 0 || m_controlFlowBlocks.back().type != DxsoCfgBlockType::If) throw DxvkError("DxsoCompiler: 'EndIf' without 'If' found"); // Remove the block from the stack, it's closed DxsoCfgBlock block = m_controlFlowBlocks.back(); m_controlFlowBlocks.pop_back(); // Write out the 'if' header m_module.beginInsertion(block.b_if.headerPtr); m_module.opSelectionMerge( block.b_if.labelEnd, spv::SelectionControlMaskNone); m_module.opBranchConditional( block.b_if.ztestId, block.b_if.labelIf, block.b_if.labelElse != 0 ? block.b_if.labelElse : block.b_if.labelEnd); m_module.endInsertion(); // End the active 'if' or 'else' block m_module.opBranch(block.b_if.labelEnd); m_module.opLabel (block.b_if.labelEnd); } void DxsoCompiler::emitTexCoord(const DxsoInstructionContext& ctx) { DxsoRegisterValue result; if (m_programInfo.majorVersion() == 1 && m_programInfo.minorVersion() == 4) { // TexCrd Op (PS 1.4) DxsoRegister texcoord; texcoord.id.type = DxsoRegisterType::PixelTexcoord; texcoord.id.num = ctx.src[0].id.num; result = emitRegisterLoadRaw(texcoord, nullptr); } else { // TexCoord Op (PS 1.0 - PS 1.3) DxsoRegister texcoord; texcoord.id.type = DxsoRegisterType::PixelTexcoord; texcoord.id.num = ctx.dst.id.num; result = emitRegisterLoadRaw(texcoord, nullptr); // Saturate result = emitSaturate(result); // w = 1.0f uint32_t wIndex = 3; result.id = m_module.opCompositeInsert(getVectorTypeId(result.type), m_module.constf32(1.0f), result.id, 1, &wIndex); } DxsoRegisterPointer dst = emitGetOperandPtr(ctx.dst); this->emitDstStore(dst, result, ctx.dst.mask, ctx.dst.saturate, emitPredicateLoad(ctx), ctx.dst.shift, ctx.dst.id); } void DxsoCompiler::emitTextureSample(const DxsoInstructionContext& ctx) { DxsoRegisterPointer dst = emitGetOperandPtr(ctx.dst); const DxsoOpcode opcode = ctx.instruction.opcode; DxsoRegisterValue texcoordVar; uint32_t samplerIdx; DxsoRegMask vec3Mask(true, true, true, false); DxsoRegMask srcMask (true, true, true, true); auto GetProjectionValue = [&]() { uint32_t w = 3; return m_module.opCompositeExtract( m_module.defFloatType(32), texcoordVar.id, 1, &w); }; if (opcode == DxsoOpcode::TexM3x2Tex || opcode == DxsoOpcode::TexM3x3Tex || opcode == DxsoOpcode::TexM3x3Spec || opcode == DxsoOpcode::TexM3x3VSpec) { const uint32_t count = opcode == DxsoOpcode::TexM3x2Tex ? 2 : 3; auto n = emitRegisterLoad(ctx.src[0], vec3Mask); std::array indices = { 0, 0, m_module.constf32(0.0f), m_module.constf32(0.0f) }; for (uint32_t i = 0; i < count; i++) { auto reg = ctx.dst; reg.id.num -= (count - 1) - i; auto m = emitRegisterLoadTexcoord(reg, vec3Mask); indices[i] = m_module.opDot(getScalarTypeId(DxsoScalarType::Float32), m.id, n.id); } if (opcode == DxsoOpcode::TexM3x3Spec || opcode == DxsoOpcode::TexM3x3VSpec) { uint32_t vec3Type = getVectorTypeId({ DxsoScalarType::Float32, 3 }); uint32_t normal = m_module.opCompositeConstruct(vec3Type, 3, indices.data()); uint32_t eyeRay; // VSpec -> Create eye ray from .w of last 3 tex coords (m, m-1, m-2) // Spec -> Get eye ray from src[1] if (opcode == DxsoOpcode::TexM3x3VSpec) { DxsoRegMask wMask(false, false, false, true); std::array eyeRayIndices; for (uint32_t i = 0; i < 3; i++) { auto reg = ctx.dst; reg.id.num -= (count - 1) - i; eyeRayIndices[i] = emitRegisterLoadTexcoord(reg, wMask).id; } eyeRay = m_module.opCompositeConstruct(vec3Type, eyeRayIndices.size(), eyeRayIndices.data()); } else eyeRay = emitRegisterLoad(ctx.src[1], vec3Mask).id; eyeRay = m_module.opNormalize(vec3Type, eyeRay); normal = m_module.opNormalize(vec3Type, normal); uint32_t reflection = m_module.opReflect(vec3Type, eyeRay, normal); reflection = m_module.opFNegate(vec3Type, reflection); for (uint32_t i = 0; i < 3; i++) indices[i] = m_module.opCompositeExtract(m_module.defFloatType(32), reflection, 1, &i); } texcoordVar.type = { DxsoScalarType::Float32, 4 }; texcoordVar.id = m_module.opCompositeConstruct(getVectorTypeId(texcoordVar.type), indices.size(), indices.data()); samplerIdx = ctx.dst.id.num; } else if (opcode == DxsoOpcode::TexBem) { auto m = emitRegisterLoadTexcoord(ctx.dst, srcMask); auto n = emitRegisterLoad(ctx.src[0], srcMask); texcoordVar = m; samplerIdx = ctx.dst.id.num; uint32_t texcoord_t = getVectorTypeId(texcoordVar.type); // The projection (/.w) happens before this... // Of course it does... uint32_t bool_t = m_module.defBoolType(); uint32_t shouldProj = m_module.opBitFieldUExtract( m_module.defIntType(32, 0), m_ps.projectionSpec, m_module.consti32(samplerIdx), m_module.consti32(1)); shouldProj = m_module.opIEqual(bool_t, shouldProj, m_module.constu32(1)); uint32_t bvec4_t = m_module.defVectorType(bool_t, 4); std::array indices = { shouldProj, shouldProj, shouldProj, shouldProj }; shouldProj = m_module.opCompositeConstruct(bvec4_t, indices.size(), indices.data()); uint32_t projScalar = m_module.opFDiv(m_module.defFloatType(32), m_module.constf32(1.0), GetProjectionValue()); uint32_t projResult = m_module.opVectorTimesScalar(texcoord_t, texcoordVar.id, projScalar); texcoordVar.id = m_module.opSelect(texcoord_t, shouldProj, projResult, texcoordVar.id); // u' = tc(m).x + [bm00(m) * t(n).x + bm10(m) * t(n).y] // v' = tc(m).y + [bm01(m) * t(n).x + bm11(m) * t(n).y] // But we flipped the bm indices so we can use dot here... // u' = tc(m).x + dot(bm0, tn) // v' = tc(m).y + dot(bm1, tn) for (uint32_t i = 0; i < 2; i++) { uint32_t fl_t = getScalarTypeId(DxsoScalarType::Float32); uint32_t vec2_t = getVectorTypeId({ DxsoScalarType::Float32, 2 }); std::array indices = { 0, 1, 2, 3 }; uint32_t tc_m_n = m_module.opCompositeExtract(fl_t, texcoordVar.id, 1, &i); uint32_t offset = m_module.constu32(D3D9SharedPSStages_Count * ctx.dst.id.num + D3D9SharedPSStages_BumpEnvMat0 + i); uint32_t bm = m_module.opAccessChain(m_module.defPointerType(vec2_t, spv::StorageClassUniform), m_ps.sharedState, 1, &offset); bm = m_module.opLoad(vec2_t, bm); uint32_t t = m_module.opVectorShuffle(vec2_t, n.id, n.id, 2, indices.data()); uint32_t dot = m_module.opDot(fl_t, bm, t); uint32_t result = m_module.opFAdd(fl_t, tc_m_n, dot); texcoordVar.id = m_module.opCompositeInsert(getVectorTypeId(texcoordVar.type), result, texcoordVar.id, 1, &i); } } else if (opcode == DxsoOpcode::TexReg2Ar) { texcoordVar = emitRegisterLoad(ctx.src[0], srcMask); texcoordVar = emitRegisterSwizzle(texcoordVar, DxsoRegSwizzle(3, 0, 0, 0), srcMask); samplerIdx = ctx.dst.id.num; } else if (opcode == DxsoOpcode::TexReg2Gb) { texcoordVar = emitRegisterLoad(ctx.src[0], srcMask); texcoordVar = emitRegisterSwizzle(texcoordVar, DxsoRegSwizzle(1, 2, 2, 2), srcMask); samplerIdx = ctx.dst.id.num; } else if (opcode == DxsoOpcode::TexReg2Rgb) { texcoordVar = emitRegisterLoad(ctx.src[0], srcMask); texcoordVar = emitRegisterSwizzle(texcoordVar, DxsoRegSwizzle(0, 1, 2, 2), srcMask); samplerIdx = ctx.dst.id.num; } else if (opcode == DxsoOpcode::TexDp3Tex) { auto m = emitRegisterLoadTexcoord(ctx.dst, vec3Mask); auto n = emitRegisterLoad(ctx.src[0], vec3Mask); auto dot = emitDot(m, n); std::array indices = { dot.id, m_module.constf32(0.0f), m_module.constf32(0.0f), m_module.constf32(0.0f) }; texcoordVar.type = { DxsoScalarType::Float32, 4 }; texcoordVar.id = m_module.opCompositeConstruct(getVectorTypeId(texcoordVar.type), indices.size(), indices.data()); samplerIdx = ctx.dst.id.num; } else { if (m_programInfo.majorVersion() >= 2) { // SM 2.0+ texcoordVar = emitRegisterLoad(ctx.src[0], srcMask); samplerIdx = ctx.src[1].id.num; } else if ( m_programInfo.majorVersion() == 1 && m_programInfo.minorVersion() == 4) { // SM 1.4 texcoordVar = emitRegisterLoad(ctx.src[0], srcMask); samplerIdx = ctx.dst.id.num; } else { // SM 1.0-1.3 texcoordVar = emitRegisterLoadTexcoord(ctx.dst, srcMask); samplerIdx = ctx.dst.id.num; } } // SM < 1.x does not have dcl sampler type. if (m_programInfo.majorVersion() < 2 && m_samplers[samplerIdx].color[SamplerTypeTexture2D].varId == 0) emitDclSampler(samplerIdx, DxsoTextureType::Texture2D); DxsoSampler sampler = m_samplers.at(samplerIdx); auto SampleImage = [this, opcode, dst, ctx, samplerIdx, GetProjectionValue](DxsoRegisterValue texcoordVar, DxsoSamplerInfo& sampler, bool depth, DxsoSamplerType samplerType, uint32_t specConst) { DxsoRegisterValue result; result.type.ctype = dst.type.ctype; result.type.ccount = depth ? 1 : 4; const uint32_t typeId = getVectorTypeId(result.type); const uint32_t imageVarId = m_module.opLoad(sampler.typeId, sampler.varId); SpirvImageOperands imageOperands; if (m_programInfo.type() == DxsoProgramTypes::VertexShader) { imageOperands.sLod = m_module.constf32(0.0f); imageOperands.flags |= spv::ImageOperandsLodMask; } if (opcode == DxsoOpcode::TexLdl) { uint32_t w = 3; imageOperands.sLod = m_module.opCompositeExtract( m_module.defFloatType(32), texcoordVar.id, 1, &w); imageOperands.flags |= spv::ImageOperandsLodMask; } if (opcode == DxsoOpcode::TexLdd) { DxsoRegMask gradMask(true, true, false, false); imageOperands.flags |= spv::ImageOperandsGradMask; imageOperands.sGradX = emitRegisterLoad(ctx.src[2], gradMask).id; imageOperands.sGradY = emitRegisterLoad(ctx.src[3], gradMask).id; } uint32_t projDivider = 0; if (opcode == DxsoOpcode::Tex && m_programInfo.majorVersion() >= 2) { if (ctx.instruction.specificData.texld == DxsoTexLdMode::Project) { projDivider = GetProjectionValue(); } else if (ctx.instruction.specificData.texld == DxsoTexLdMode::Bias) { uint32_t w = 3; imageOperands.sLodBias = m_module.opCompositeExtract( m_module.defFloatType(32), texcoordVar.id, 1, &w); imageOperands.flags |= spv::ImageOperandsBiasMask; } } bool switchProjResult = m_programInfo.majorVersion() < 2 && samplerType != SamplerTypeTextureCube; if (switchProjResult) projDivider = GetProjectionValue(); // We already handled this... if (opcode == DxsoOpcode::TexBem) { switchProjResult = false; projDivider = 0; } uint32_t reference = 0; if (depth) { uint32_t component = sampler.dimensions; reference = m_module.opCompositeExtract( m_module.defFloatType(32), texcoordVar.id, 1, &component); } if (projDivider != 0) { for (uint32_t i = sampler.dimensions; i < 4; i++) { texcoordVar.id = m_module.opCompositeInsert(getVectorTypeId(texcoordVar.type), projDivider, texcoordVar.id, 1, &i); } } result.id = this->emitSample( projDivider != 0, typeId, imageVarId, texcoordVar.id, reference, imageOperands); if (switchProjResult) { uint32_t bool_t = m_module.defBoolType(); uint32_t nonProjResult = this->emitSample( 0, typeId, imageVarId, texcoordVar.id, reference, imageOperands); uint32_t shouldProj = m_module.opBitFieldUExtract( m_module.defIntType(32, 0), m_ps.projectionSpec, m_module.consti32(samplerIdx), m_module.consti32(1)); shouldProj = m_module.opIEqual(m_module.defBoolType(), shouldProj, m_module.constu32(1)); // Depth -> .x // Colour -> .xyzw // Need to replicate the bool for the opSelect. if (!depth) { uint32_t bvec4_t = m_module.defVectorType(bool_t, 4); std::array indices = { shouldProj, shouldProj, shouldProj, shouldProj }; shouldProj = m_module.opCompositeConstruct(bvec4_t, indices.size(), indices.data()); } result.id = m_module.opSelect(typeId, shouldProj, result.id, nonProjResult); } // If we are sampling depth we've already specc'ed this! // This path is always size 4 because it only hits on color. if (specConst != 0) { uint32_t bool_t = m_module.defBoolType(); uint32_t bvec4_t = m_module.defVectorType(bool_t, 4); std::array indices = { specConst, specConst, specConst, specConst }; specConst = m_module.opCompositeConstruct(bvec4_t, indices.size(), indices.data()); result.id = m_module.opSelect(typeId, specConst, result.id, m_module.constvec4f32(0.0f, 0.0f, 0.0f, 1.0f)); } // Apply operand swizzle to the operand value result = emitRegisterSwizzle(result, IdentitySwizzle, ctx.dst.mask); this->emitDstStore(dst, result, ctx.dst.mask, ctx.dst.saturate, emitPredicateLoad(ctx), ctx.dst.shift, ctx.dst.id); }; auto SampleType = [&](DxsoSamplerType samplerType) { // Only do the check for depth comp. samplers // if we aren't a 3D texture if (samplerType != SamplerTypeTexture3D) { uint32_t colorLabel = m_module.allocateId(); uint32_t depthLabel = m_module.allocateId(); uint32_t endLabel = m_module.allocateId(); m_module.opSelectionMerge(endLabel, spv::SelectionControlMaskNone); m_module.opBranchConditional(sampler.depthSpecConst, depthLabel, colorLabel); m_module.opLabel(colorLabel); SampleImage(texcoordVar, sampler.color[samplerType], false, samplerType, sampler.colorSpecConst); m_module.opBranch(endLabel); m_module.opLabel(depthLabel); SampleImage(texcoordVar, sampler.depth[samplerType], true, samplerType, 0); // already specc'ed m_module.opBranch(endLabel); m_module.opLabel(endLabel); } else SampleImage(texcoordVar, sampler.color[samplerType], false, samplerType, sampler.colorSpecConst); }; if (m_programInfo.majorVersion() >= 2 && !m_moduleInfo.options.forceSamplerTypeSpecConstants) { DxsoSamplerType samplerType = SamplerTypeFromTextureType(sampler.type); SampleType(samplerType); } else { std::array typeCaseLabels = {{ { uint32_t(SamplerTypeTexture2D), m_module.allocateId() }, { uint32_t(SamplerTypeTexture3D), m_module.allocateId() }, { uint32_t(SamplerTypeTextureCube), m_module.allocateId() }, }}; uint32_t switchEndLabel = m_module.allocateId(); uint32_t typeId = m_module.defIntType(32, 0); uint32_t offset = m_module.consti32(samplerIdx * 2); uint32_t bitCnt = m_module.consti32(2); uint32_t type = m_module.opBitFieldUExtract(typeId, m_ps.samplerTypeSpec, offset, bitCnt); m_module.opSelectionMerge(switchEndLabel, spv::SelectionControlMaskNone); m_module.opSwitch(type, typeCaseLabels[uint32_t(SamplerTypeTexture2D)].labelId, typeCaseLabels.size(), typeCaseLabels.data()); for (const auto& label : typeCaseLabels) { m_module.opLabel(label.labelId); SampleType(DxsoSamplerType(label.literal)); m_module.opBranch(switchEndLabel); } m_module.opLabel(switchEndLabel); } } void DxsoCompiler::emitTextureKill(const DxsoInstructionContext& ctx) { DxsoRegisterValue texReg; if (m_programInfo.majorVersion() >= 2 || (m_programInfo.majorVersion() == 1 && m_programInfo.minorVersion() == 4)) // SM 2.0+ or 1.4 texReg = emitRegisterLoadRaw(ctx.dst, ctx.dst.hasRelative ? &ctx.dst.relative : nullptr); else { // SM 1.0-1.3 DxsoRegister texcoord; texcoord.id = { DxsoRegisterType::PixelTexcoord, ctx.dst.id.num }; texReg = emitRegisterLoadRaw(texcoord, nullptr); } std::array indices = { 0, 1, 2, 3 }; // On SM1 it only works on the first if (m_programInfo.majorVersion() < 2) { texReg.type.ccount = 3; texReg.id = m_module.opVectorShuffle( getVectorTypeId(texReg.type), texReg.id, texReg.id, texReg.type.ccount, indices.data()); } else { // The writemask actually applies and works here... // (FXC doesn't generate this but it fixes broken ENB shaders) texReg = emitRegisterSwizzle(texReg, IdentitySwizzle, ctx.dst.mask); } const uint32_t boolVecTypeId = getVectorTypeId({ DxsoScalarType::Bool, texReg.type.ccount }); uint32_t result = m_module.opFOrdLessThan( boolVecTypeId, texReg.id, m_module.constfReplicant(0.0f, texReg.type.ccount)); if (texReg.type.ccount != 1) result = m_module.opAny(m_module.defBoolType(), result); if (m_ps.killState == 0) { uint32_t labelIf = m_module.allocateId(); uint32_t labelEnd = m_module.allocateId(); m_module.opSelectionMerge(labelEnd, spv::SelectionControlMaskNone); m_module.opBranchConditional(result, labelIf, labelEnd); m_module.opLabel(labelIf); if (m_moduleInfo.options.useDemoteToHelperInvocation) { m_module.opDemoteToHelperInvocation(); m_module.opBranch(labelEnd); } else { // OpKill terminates the block m_module.opKill(); } m_module.opLabel(labelEnd); } else { uint32_t typeId = m_module.defBoolType(); uint32_t killState = m_module.opLoad (typeId, m_ps.killState); killState = m_module.opLogicalOr(typeId, killState, result); m_module.opStore(m_ps.killState, killState); if (m_moduleInfo.options.useSubgroupOpsForEarlyDiscard) { uint32_t ballot = m_module.opGroupNonUniformBallot( getVectorTypeId({ DxsoScalarType::Uint32, 4 }), m_module.constu32(spv::ScopeSubgroup), killState); uint32_t laneId = m_module.opLoad( getScalarTypeId(DxsoScalarType::Uint32), m_ps.builtinLaneId); uint32_t laneIdPart = m_module.opShiftRightLogical( getScalarTypeId(DxsoScalarType::Uint32), laneId, m_module.constu32(5)); uint32_t laneMask = m_module.opVectorExtractDynamic( getScalarTypeId(DxsoScalarType::Uint32), ballot, laneIdPart); uint32_t laneIdQuad = m_module.opBitwiseAnd( getScalarTypeId(DxsoScalarType::Uint32), laneId, m_module.constu32(0x1c)); laneMask = m_module.opShiftRightLogical( getScalarTypeId(DxsoScalarType::Uint32), laneMask, laneIdQuad); laneMask = m_module.opBitwiseAnd( getScalarTypeId(DxsoScalarType::Uint32), laneMask, m_module.constu32(0xf)); uint32_t killSubgroup = m_module.opIEqual( m_module.defBoolType(), laneMask, m_module.constu32(0xf)); uint32_t labelIf = m_module.allocateId(); uint32_t labelEnd = m_module.allocateId(); m_module.opSelectionMerge(labelEnd, spv::SelectionControlMaskNone); m_module.opBranchConditional(killSubgroup, labelIf, labelEnd); // OpKill terminates the block m_module.opLabel(labelIf); m_module.opKill(); m_module.opLabel(labelEnd); } } } uint32_t DxsoCompiler::emitSample( bool projected, uint32_t resultType, uint32_t sampledImage, uint32_t coordinates, uint32_t reference, const SpirvImageOperands& operands) { const bool depthCompare = reference != 0; const bool explicitLod = (operands.flags & spv::ImageOperandsLodMask) || (operands.flags & spv::ImageOperandsGradMask); if (projected) { if (depthCompare) { if (explicitLod) return m_module.opImageSampleProjDrefExplicitLod(resultType, sampledImage, coordinates, reference, operands); else return m_module.opImageSampleProjDrefImplicitLod(resultType, sampledImage, coordinates, reference, operands); } else { if (explicitLod) return m_module.opImageSampleProjExplicitLod(resultType, sampledImage, coordinates, operands); else return m_module.opImageSampleProjImplicitLod(resultType, sampledImage, coordinates, operands); } } else { if (depthCompare) { if (explicitLod) return m_module.opImageSampleDrefExplicitLod(resultType, sampledImage, coordinates, reference, operands); else return m_module.opImageSampleDrefImplicitLod(resultType, sampledImage, coordinates, reference, operands); } else { if (explicitLod) return m_module.opImageSampleExplicitLod(resultType, sampledImage, coordinates, operands); else return m_module.opImageSampleImplicitLod(resultType, sampledImage, coordinates, operands); } } } void DxsoCompiler::emitInputSetup() { uint32_t pointCoord = 0; D3D9PointSizeInfoPS pointInfo; if (m_programInfo.type() == DxsoProgramType::PixelShader) { pointCoord = GetPointCoord(m_module, m_entryPointInterfaces); pointInfo = GetPointSizeInfoPS(m_module, m_rsBlock); } for (uint32_t i = 0; i < m_isgn.elemCount; i++) { const auto& elem = m_isgn.elems[i]; const uint32_t slot = elem.slot; DxsoRegisterInfo info; info.type.ctype = DxsoScalarType::Float32; info.type.ccount = 4; info.type.alength = 1; info.sclass = spv::StorageClassInput; DxsoRegisterPointer inputPtr; inputPtr.id = emitNewVariable(info); inputPtr.type.ctype = DxsoScalarType::Float32; inputPtr.type.ccount = info.type.ccount; m_module.decorateLocation(inputPtr.id, slot); std::string name = str::format("in_", elem.semantic.usage, elem.semantic.usageIndex); m_module.setDebugName(inputPtr.id, name.c_str()); if (elem.centroid) m_module.decorate(inputPtr.id, spv::DecorationCentroid); m_entryPointInterfaces.push_back(inputPtr.id); uint32_t typeId = this->getVectorTypeId({ DxsoScalarType::Float32, 4 }); uint32_t ptrTypeId = m_module.defPointerType(typeId, spv::StorageClassPrivate); uint32_t regNumVar = m_module.constu32(elem.regNumber); DxsoRegisterPointer indexPtr; indexPtr.id = m_module.opAccessChain(ptrTypeId, m_vArray, 1, ®NumVar); indexPtr.type = inputPtr.type; indexPtr.type.ccount = 4; DxsoRegisterValue indexVal = this->emitValueLoad(inputPtr); DxsoRegisterValue workingReg; workingReg.type = indexVal.type; workingReg.id = m_module.constvec4f32(0.0f, 0.0f, 0.0f, 0.0f); DxsoRegMask mask = elem.mask; if (mask.popCount() == 0) mask = DxsoRegMask(true, true, true, true); std::array indices = { 0, 1, 2, 3 }; uint32_t count = 0; for (uint32_t i = 0; i < 4; i++) { if (mask[i]) { indices[i] = i + 4; count++; } } workingReg.id = m_module.opVectorShuffle(getVectorTypeId(workingReg.type), workingReg.id, indexVal.id, 4, indices.data()); // We need to replace TEXCOORD inputs with gl_PointCoord // if D3DRS_POINTSPRITEENABLE is set. if (m_programInfo.type() == DxsoProgramType::PixelShader && elem.semantic.usage == DxsoUsage::Texcoord) workingReg.id = m_module.opSelect(getVectorTypeId(workingReg.type), pointInfo.isSprite, pointCoord, workingReg.id); if (m_programInfo.type() == DxsoProgramType::PixelShader && elem.semantic.usage == DxsoUsage::Color) { if (elem.semantic.usageIndex == 0) m_ps.diffuseColorIn = inputPtr.id; else if (elem.semantic.usageIndex == 1) m_ps.specularColorIn = inputPtr.id; } m_module.opStore(indexPtr.id, workingReg.id); } } void DxsoCompiler::emitLinkerOutputSetup() { bool outputtedColor0 = false; bool outputtedColor1 = false; for (uint32_t i = 0; i < m_osgn.elemCount; i++) { const auto& elem = m_osgn.elems[i]; const uint32_t slot = elem.slot; if (elem.semantic.usage == DxsoUsage::Color) { if (elem.semantic.usageIndex == 0) outputtedColor0 = true; else outputtedColor1 = true; } DxsoRegisterInfo info; info.type.ctype = DxsoScalarType::Float32; info.type.ccount = 4; info.type.alength = 1; info.sclass = spv::StorageClassOutput; spv::BuiltIn builtIn = semanticToBuiltIn(false, elem.semantic); DxsoRegisterPointer outputPtr; outputPtr.type.ctype = DxsoScalarType::Float32; outputPtr.type.ccount = 4; DxsoRegMask mask = elem.mask; bool scalar = false; if (builtIn == spv::BuiltInMax) { outputPtr.id = emitNewVariableDefault(info, m_module.constvec4f32(0.0f, 0.0f, 0.0f, 0.0f)); m_module.decorateLocation(outputPtr.id, slot); std::string name = str::format("out_", elem.semantic.usage, elem.semantic.usageIndex); m_module.setDebugName(outputPtr.id, name.c_str()); } else { const char* name = "unknown_builtin"; if (builtIn == spv::BuiltInPosition) name = "oPos"; else if (builtIn == spv::BuiltInPointSize) { outputPtr.type.ccount = 1; info.type.ccount = 1; name = "oPSize"; bool maskValues[4]; for (uint32_t i = 0; i < 4; i++) maskValues[i] = i == elem.mask.firstSet(); mask = DxsoRegMask(maskValues[0], maskValues[1], maskValues[2], maskValues[3]); } outputPtr.id = emitNewVariableDefault(info, m_module.constfReplicant(0.0f, info.type.ccount)); m_module.setDebugName(outputPtr.id, name); m_module.decorateBuiltIn(outputPtr.id, builtIn); if (builtIn == spv::BuiltInPosition) m_vs.oPos = outputPtr; else if (builtIn == spv::BuiltInPointSize) { scalar = true; m_vs.oPSize = outputPtr; } } m_entryPointInterfaces.push_back(outputPtr.id); uint32_t typeId = this->getVectorTypeId({ DxsoScalarType::Float32, 4 }); uint32_t ptrTypeId = m_module.defPointerType(typeId, spv::StorageClassPrivate); uint32_t regNumVar = m_module.constu32(elem.regNumber); DxsoRegisterPointer indexPtr; indexPtr.id = m_module.opAccessChain(ptrTypeId, m_oArray, 1, ®NumVar); indexPtr.type = outputPtr.type; indexPtr.type.ccount = 4; DxsoRegisterValue indexVal = this->emitValueLoad(indexPtr); DxsoRegisterValue workingReg; workingReg.type.ctype = indexVal.type.ctype; workingReg.type.ccount = scalar ? 1 : 4; workingReg.id = scalar ? m_module.constf32(0.0f) : m_module.constvec4f32(0.0f, 0.0f, 0.0f, 0.0f); std::array indices = { 0, 1, 2, 3 }; if (scalar) { workingReg.id = m_module.opCompositeExtract(getVectorTypeId(workingReg.type), indexVal.id, 1, indices.data()); } else { if (mask.popCount() == 0) mask = DxsoRegMask(true, true, true, true); uint32_t count = 0; for (uint32_t i = 0; i < 4; i++) { if (mask[i]) indices[count++] = i + 4; } workingReg.id = m_module.opVectorShuffle(getVectorTypeId(workingReg.type), workingReg.id, indexVal.id, 4, indices.data()); } // Ie. 0 or 1 for diffuse and specular color // and for Shader Model 1 or 2 // (because those have dedicated color registers // where this rule applies) if (elem.semantic.usage == DxsoUsage::Color && elem.semantic.usageIndex < 2 && m_programInfo.majorVersion() < 3) workingReg = emitSaturate(workingReg); m_module.opStore(outputPtr.id, workingReg.id); } auto OutputDefault = [&](DxsoSemantic semantic) { DxsoRegisterInfo info; info.type.ctype = DxsoScalarType::Float32; info.type.ccount = 4; info.type.alength = 1; info.sclass = spv::StorageClassOutput; uint32_t slot = RegisterLinkerSlot(semantic); uint32_t value = semantic == DxsoSemantic{ DxsoUsage::Color, 0 } ? m_module.constvec4f32(1.0f, 1.0f, 1.0f, 1.0f) : m_module.constvec4f32(0.0f, 0.0f, 0.0f, 0.0f); uint32_t outputPtr = emitNewVariableDefault(info, value); m_module.decorateLocation(outputPtr, slot); std::string name = str::format("out_", semantic.usage, semantic.usageIndex, "_default"); m_module.setDebugName(outputPtr, name.c_str()); m_interfaceSlots.outputSlots |= 1u << slot; m_entryPointInterfaces.push_back(outputPtr); }; if (!outputtedColor0) OutputDefault(DxsoSemantic{ DxsoUsage::Color, 0 }); if (!outputtedColor1) OutputDefault(DxsoSemantic{ DxsoUsage::Color, 1 }); auto pointInfo = GetPointSizeInfoVS(m_module, m_vs.oPos.id, 0, 0, m_rsBlock); if (m_vs.oPSize.id == 0) { m_vs.oPSize = this->emitRegisterPtr( "oPSize", DxsoScalarType::Float32, 1, 0, spv::StorageClassOutput, spv::BuiltInPointSize); uint32_t pointSize = m_module.opFClamp(m_module.defFloatType(32), pointInfo.defaultValue, pointInfo.min, pointInfo.max); m_module.opStore(m_vs.oPSize.id, pointSize); } else { uint32_t float_t = m_module.defFloatType(32); uint32_t pointSize = m_module.opFClamp(m_module.defFloatType(32), m_module.opLoad(float_t, m_vs.oPSize.id), pointInfo.min, pointInfo.max); m_module.opStore(m_vs.oPSize.id, pointSize); } } void DxsoCompiler::emitVsClipping() { uint32_t clipPlaneCountId = m_module.constu32(caps::MaxClipPlanes); uint32_t floatType = m_module.defFloatType(32); uint32_t vec4Type = m_module.defVectorType(floatType, 4); // Declare uniform buffer containing clip planes uint32_t clipPlaneArray = m_module.defArrayTypeUnique(vec4Type, clipPlaneCountId); uint32_t clipPlaneStruct = m_module.defStructTypeUnique(1, &clipPlaneArray); uint32_t clipPlaneBlock = m_module.newVar( m_module.defPointerType(clipPlaneStruct, spv::StorageClassUniform), spv::StorageClassUniform); m_module.decorateArrayStride (clipPlaneArray, 16); m_module.setDebugName (clipPlaneStruct, "clip_info_t"); m_module.setDebugMemberName (clipPlaneStruct, 0, "clip_planes"); m_module.decorate (clipPlaneStruct, spv::DecorationBlock); m_module.memberDecorateOffset (clipPlaneStruct, 0, 0); uint32_t bindingId = computeResourceSlotId( m_programInfo.type(), DxsoBindingType::ConstantBuffer, DxsoConstantBuffers::VSClipPlanes); m_module.setDebugName (clipPlaneBlock, "clip_info"); m_module.decorateDescriptorSet(clipPlaneBlock, 0); m_module.decorateBinding (clipPlaneBlock, bindingId); DxvkResourceSlot resource; resource.slot = bindingId; resource.type = VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER; resource.view = VK_IMAGE_VIEW_TYPE_MAX_ENUM; resource.access = VK_ACCESS_UNIFORM_READ_BIT; m_resourceSlots.push_back(resource); // Declare output array for clip distances uint32_t clipDistArray = m_module.newVar( m_module.defPointerType( m_module.defArrayType(floatType, clipPlaneCountId), spv::StorageClassOutput), spv::StorageClassOutput); m_module.decorateBuiltIn(clipDistArray, spv::BuiltInClipDistance); m_entryPointInterfaces.push_back(clipDistArray); if (m_moduleInfo.options.invariantPosition) m_module.decorate(m_vs.oPos.id, spv::DecorationInvariant); const uint32_t positionPtr = m_vs.oPos.id; // We generated a bad shader, let's not make it even worse. if (positionPtr == 0) { Logger::warn("Shader without Position output. Something is likely wrong here."); return; } // Compute clip distances uint32_t positionId = m_module.opLoad(vec4Type, positionPtr); for (uint32_t i = 0; i < caps::MaxClipPlanes; i++) { std::array blockMembers = {{ m_module.constu32(0), m_module.constu32(i), }}; uint32_t planeId = m_module.opLoad(vec4Type, m_module.opAccessChain( m_module.defPointerType(vec4Type, spv::StorageClassUniform), clipPlaneBlock, blockMembers.size(), blockMembers.data())); uint32_t distId = m_module.opDot(floatType, positionId, planeId); m_module.opStore( m_module.opAccessChain( m_module.defPointerType(floatType, spv::StorageClassOutput), clipDistArray, 1, &blockMembers[1]), distId); } } void DxsoCompiler::setupRenderStateInfo() { m_rsBlock = SetupRenderStateBlock(m_module); // Only need alpha ref for PS 3. // No FF fog component. if (m_programInfo.type() == DxsoProgramType::PixelShader) { if (m_programInfo.majorVersion() == 3) { m_interfaceSlots.pushConstOffset = offsetof(D3D9RenderStateInfo, alphaRef); m_interfaceSlots.pushConstSize = sizeof(float); } else { m_interfaceSlots.pushConstOffset = 0; m_interfaceSlots.pushConstSize = offsetof(D3D9RenderStateInfo, pointSize); } } else { m_interfaceSlots.pushConstOffset = offsetof(D3D9RenderStateInfo, pointSize); // Point scale never triggers on programmable m_interfaceSlots.pushConstSize = sizeof(float) * 3; } } void DxsoCompiler::emitFog() { DxsoRegister color0; color0.id = DxsoRegisterId{ DxsoRegisterType::ColorOut, 0 }; auto oColor0Ptr = this->emitGetOperandPtr(color0); DxsoRegister vFog; vFog.id = DxsoRegisterId{ DxsoRegisterType::RasterizerOut, RasterOutFog }; auto vFogPtr = this->emitGetOperandPtr(vFog); DxsoRegister vPos; vPos.id = DxsoRegisterId{ DxsoRegisterType::MiscType, DxsoMiscTypeIndices::MiscTypePosition }; auto vPosPtr = this->emitGetOperandPtr(vPos); D3D9FogContext fogCtx; fogCtx.IsPixel = true; fogCtx.RangeFog = false; fogCtx.RenderState = m_rsBlock; fogCtx.vPos = m_module.opLoad(getVectorTypeId(vPosPtr.type), vPosPtr.id); fogCtx.vFog = m_module.opLoad(getVectorTypeId(vFogPtr.type), vFogPtr.id); fogCtx.oColor = m_module.opLoad(getVectorTypeId(oColor0Ptr.type), oColor0Ptr.id); m_module.opStore(oColor0Ptr.id, DoFixedFunctionFog(m_module, fogCtx)); } void DxsoCompiler::emitPsProcessing() { uint32_t boolType = m_module.defBoolType(); uint32_t floatType = m_module.defFloatType(32); uint32_t floatPtr = m_module.defPointerType(floatType, spv::StorageClassPushConstant); // Declare spec constants for render states uint32_t alphaTestId = m_module.specConstBool(false); uint32_t alphaFuncId = m_module.specConst32(m_module.defIntType(32, 0), uint32_t(VK_COMPARE_OP_ALWAYS)); m_module.setDebugName (alphaTestId, "alpha_test"); m_module.decorateSpecId (alphaTestId, getSpecId(D3D9SpecConstantId::AlphaTestEnable)); m_module.setDebugName (alphaFuncId, "alpha_func"); m_module.decorateSpecId (alphaFuncId, getSpecId(D3D9SpecConstantId::AlphaCompareOp)); // Implement alpha test and fog DxsoRegister color0; color0.id = DxsoRegisterId{ DxsoRegisterType::ColorOut, 0 }; auto oC0 = this->emitGetOperandPtr(color0); if (oC0.id) { if (m_programInfo.majorVersion() < 3) emitFog(); // Labels for the alpha test std::array atestCaseLabels = {{ { uint32_t(VK_COMPARE_OP_NEVER), m_module.allocateId() }, { uint32_t(VK_COMPARE_OP_LESS), m_module.allocateId() }, { uint32_t(VK_COMPARE_OP_EQUAL), m_module.allocateId() }, { uint32_t(VK_COMPARE_OP_LESS_OR_EQUAL), m_module.allocateId() }, { uint32_t(VK_COMPARE_OP_GREATER), m_module.allocateId() }, { uint32_t(VK_COMPARE_OP_NOT_EQUAL), m_module.allocateId() }, { uint32_t(VK_COMPARE_OP_GREATER_OR_EQUAL), m_module.allocateId() }, { uint32_t(VK_COMPARE_OP_ALWAYS), m_module.allocateId() }, }}; uint32_t atestBeginLabel = m_module.allocateId(); uint32_t atestTestLabel = m_module.allocateId(); uint32_t atestDiscardLabel = m_module.allocateId(); uint32_t atestKeepLabel = m_module.allocateId(); uint32_t atestSkipLabel = m_module.allocateId(); // if (alpha_test) { ... } m_module.opSelectionMerge(atestSkipLabel, spv::SelectionControlMaskNone); m_module.opBranchConditional(alphaTestId, atestBeginLabel, atestSkipLabel); m_module.opLabel(atestBeginLabel); // Load alpha component uint32_t alphaComponentId = 3; uint32_t alphaId = m_module.opCompositeExtract(floatType, m_module.opLoad(m_module.defVectorType(floatType, 4), oC0.id), 1, &alphaComponentId); // Load alpha reference uint32_t alphaRefMember = m_module.constu32(uint32_t(D3D9RenderStateItem::AlphaRef)); uint32_t alphaRefId = m_module.opLoad(floatType, m_module.opAccessChain(floatPtr, m_rsBlock, 1, &alphaRefMember)); // switch (alpha_func) { ... } m_module.opSelectionMerge(atestTestLabel, spv::SelectionControlMaskNone); m_module.opSwitch(alphaFuncId, atestCaseLabels[uint32_t(VK_COMPARE_OP_ALWAYS)].labelId, atestCaseLabels.size(), atestCaseLabels.data()); std::array atestVariables; for (uint32_t i = 0; i < atestCaseLabels.size(); i++) { m_module.opLabel(atestCaseLabels[i].labelId); atestVariables[i].labelId = atestCaseLabels[i].labelId; atestVariables[i].varId = [&] { switch (VkCompareOp(atestCaseLabels[i].literal)) { case VK_COMPARE_OP_NEVER: return m_module.constBool(false); case VK_COMPARE_OP_LESS: return m_module.opFOrdLessThan (boolType, alphaId, alphaRefId); case VK_COMPARE_OP_EQUAL: return m_module.opFOrdEqual (boolType, alphaId, alphaRefId); case VK_COMPARE_OP_LESS_OR_EQUAL: return m_module.opFOrdLessThanEqual (boolType, alphaId, alphaRefId); case VK_COMPARE_OP_GREATER: return m_module.opFOrdGreaterThan (boolType, alphaId, alphaRefId); case VK_COMPARE_OP_NOT_EQUAL: return m_module.opFOrdNotEqual (boolType, alphaId, alphaRefId); case VK_COMPARE_OP_GREATER_OR_EQUAL: return m_module.opFOrdGreaterThanEqual(boolType, alphaId, alphaRefId); default: case VK_COMPARE_OP_ALWAYS: return m_module.constBool(true); } }(); m_module.opBranch(atestTestLabel); } // end switch m_module.opLabel(atestTestLabel); uint32_t atestResult = m_module.opPhi(boolType, atestVariables.size(), atestVariables.data()); uint32_t atestDiscard = m_module.opLogicalNot(boolType, atestResult); atestResult = m_module.opLogicalNot(boolType, atestResult); // if (do_discard) { ... } m_module.opSelectionMerge(atestKeepLabel, spv::SelectionControlMaskNone); m_module.opBranchConditional(atestDiscard, atestDiscardLabel, atestKeepLabel); m_module.opLabel(atestDiscardLabel); m_module.opKill(); // end if (do_discard) m_module.opLabel(atestKeepLabel); m_module.opBranch(atestSkipLabel); // end if (alpha_test) m_module.opLabel(atestSkipLabel); } } void DxsoCompiler::emitOutputDepthClamp() { // HACK: Some drivers do not clamp FragDepth to [minDepth..maxDepth] // before writing to the depth attachment, but we do not have acccess // to those. Clamp to [0..1] instead. if (m_ps.oDepth.id != 0) { auto result = emitValueLoad(m_ps.oDepth); result = emitSaturate(result); m_module.opStore( m_ps.oDepth.id, result.id); } } void DxsoCompiler::emitVsFinalize() { this->emitMainFunctionBegin(); this->emitInputSetup(); m_module.opFunctionCall( m_module.defVoidType(), m_vs.functionId, 0, nullptr); this->emitLinkerOutputSetup(); this->emitVsClipping(); this->emitFunctionEnd(); } void DxsoCompiler::emitPsFinalize() { this->emitMainFunctionBegin(); this->emitInputSetup(); bool canUsePixelFog = m_programInfo.majorVersion() < 3; if (canUsePixelFog) { // Look up vPos so it gets initted. DxsoRegister vPos; vPos.id = DxsoRegisterId{ DxsoRegisterType::MiscType, DxsoMiscTypeIndices::MiscTypePosition }; this->emitGetOperandPtr(vPos); } if (m_ps.vPos.id != 0) { DxsoRegisterPointer fragCoord = this->emitRegisterPtr( "ps_frag_coord", DxsoScalarType::Float32, 4, 0, spv::StorageClassInput, spv::BuiltInFragCoord); DxsoRegisterValue val = this->emitValueLoad(fragCoord); val.id = m_module.opFSub( getVectorTypeId(val.type), val.id, m_module.constvec4f32(0.5f, 0.5f, 0.0f, 0.0f)); m_module.opStore(m_ps.vPos.id, val.id); } if (m_ps.vFace.id != 0) { DxsoRegisterPointer faceBool = this->emitRegisterPtr( "ps_is_front_face", DxsoScalarType::Bool, 1, 0, spv::StorageClassInput, spv::BuiltInFrontFacing); DxsoRegisterValue frontFace = emitValueLoad(faceBool); DxsoRegisterValue selectOp = emitRegisterExtend(frontFace, 4); m_module.opStore( m_ps.vFace.id, m_module.opSelect(getVectorTypeId(m_ps.vFace.type), selectOp.id, m_module.constvec4f32( 1.0f, 1.0f, 1.0f, 1.0f), m_module.constvec4f32(-1.0f, -1.0f, -1.0f, -1.0f))); } m_module.opFunctionCall( m_module.defVoidType(), m_ps.functionId, 0, nullptr); if (m_ps.killState != 0) { uint32_t labelIf = m_module.allocateId(); uint32_t labelEnd = m_module.allocateId(); uint32_t killTest = m_module.opLoad(m_module.defBoolType(), m_ps.killState); m_module.opSelectionMerge(labelEnd, spv::SelectionControlMaskNone); m_module.opBranchConditional(killTest, labelIf, labelEnd); m_module.opLabel(labelIf); m_module.opKill(); m_module.opLabel(labelEnd); } // r0 in PS1 is the colour output register. Move r0 -> cO0 here. if (m_programInfo.majorVersion() == 1 && m_programInfo.type() == DxsoProgramTypes::PixelShader) { DxsoRegister r0; r0.id = { DxsoRegisterType::Temp, 0 }; DxsoRegister c0; c0.id = { DxsoRegisterType::ColorOut, 0 }; DxsoRegisterValue val = emitRegisterLoadRaw(r0, nullptr); DxsoRegisterPointer out = emitGetOperandPtr(c0); m_module.opStore(out.id, val.id); } // No need to setup output here as it's non-indexable // everything has already gone to the right place! this->emitPsProcessing(); this->emitOutputDepthClamp(); this->emitFunctionEnd(); } uint32_t DxsoCompiler::getScalarTypeId(DxsoScalarType type) { switch (type) { case DxsoScalarType::Uint32: return m_module.defIntType(32, 0); case DxsoScalarType::Sint32: return m_module.defIntType(32, 1); case DxsoScalarType::Float32: return m_module.defFloatType(32); case DxsoScalarType::Bool: return m_module.defBoolType(); } throw DxvkError("DxsoCompiler: Invalid scalar type"); } uint32_t DxsoCompiler::getVectorTypeId(const DxsoVectorType& type) { uint32_t typeId = this->getScalarTypeId(type.ctype); if (type.ccount > 1) typeId = m_module.defVectorType(typeId, type.ccount); return typeId; } uint32_t DxsoCompiler::getArrayTypeId(const DxsoArrayType& type) { DxsoVectorType vtype; vtype.ctype = type.ctype; vtype.ccount = type.ccount; uint32_t typeId = this->getVectorTypeId(vtype); if (type.alength > 1) { typeId = m_module.defArrayType(typeId, m_module.constu32(type.alength)); } return typeId; } uint32_t DxsoCompiler::getPointerTypeId(const DxsoRegisterInfo& type) { return m_module.defPointerType( this->getArrayTypeId(type.type), type.sclass); } }