From 6c449793b8a12cb4460d8c16d6a5a5d4d8595edf Mon Sep 17 00:00:00 2001 From: ReinUsesLisp Date: Sat, 24 Aug 2019 17:29:19 -0300 Subject: [PATCH] gl_shader_decompiler: Rework GLSL decompiler type system GLSL decompiler type system was broken. We converted all return values to float except for some cases where returning we couldn't and implicitly broke the rule of returning floats (e.g. for bools or bool pairs). Instead of doing this introduce class Expression that knows what type a return value has and when a consumer wants to use the string it asks for it with a required type, emitting a runtime error if types are incompatible. This has the disadvantage that there's more C++ code, but we can emit better GLSL code that's easier to read. --- .../renderer_opengl/gl_shader_decompiler.cpp | 911 ++++++++++-------- 1 file changed, 500 insertions(+), 411 deletions(-) diff --git a/src/video_core/renderer_opengl/gl_shader_decompiler.cpp b/src/video_core/renderer_opengl/gl_shader_decompiler.cpp index 359d58cbe9..f73bf63928 100644 --- a/src/video_core/renderer_opengl/gl_shader_decompiler.cpp +++ b/src/video_core/renderer_opengl/gl_shader_decompiler.cpp @@ -39,7 +39,7 @@ using namespace VideoCommon::Shader; using Maxwell = Tegra::Engines::Maxwell3D::Regs; using Operation = const OperationNode&; -enum class Type { Bool, Bool2, Float, Int, Uint, HalfFloat }; +enum class Type { Void, Bool, Bool2, Float, Int, Uint, HalfFloat }; struct TextureAoffi {}; using TextureArgument = std::pair; @@ -48,7 +48,7 @@ using TextureIR = std::variant; constexpr u32 MAX_CONSTBUFFER_ELEMENTS = static_cast(Maxwell::MaxConstBufferSize) / (4 * sizeof(float)); -class ShaderWriter { +class ShaderWriter final { public: void AddExpression(std::string_view text) { DEBUG_ASSERT(scope >= 0); @@ -93,9 +93,157 @@ private: u32 temporary_index = 1; }; +class Expression final { +public: + Expression(std::string code, Type type) : code{std::move(code)}, type{type} { + ASSERT(type != Type::Void); + } + Expression() : type{Type::Void} {} + + Type GetType() const { + return type; + } + + std::string GetCode() const { + return code; + } + + void CheckVoid() const { + ASSERT(type == Type::Void); + } + + std::string As(Type type) const { + switch (type) { + case Type::Bool: + return AsBool(); + case Type::Bool2: + return AsBool2(); + case Type::Float: + return AsFloat(); + case Type::Int: + return AsInt(); + case Type::Uint: + return AsUint(); + case Type::HalfFloat: + return AsHalfFloat(); + default: + UNREACHABLE_MSG("Invalid type"); + return code; + } + } + + std::string AsBool() const { + switch (type) { + case Type::Bool: + return code; + default: + UNREACHABLE_MSG("Incompatible types"); + return code; + } + } + + std::string AsBool2() const { + switch (type) { + case Type::Bool2: + return code; + default: + UNREACHABLE_MSG("Incompatible types"); + return code; + } + } + + std::string AsFloat() const { + switch (type) { + case Type::Float: + return code; + case Type::Uint: + return fmt::format("utof({})", code); + case Type::Int: + return fmt::format("itof({})", code); + case Type::HalfFloat: + return fmt::format("utof(packHalf2x16({}))", code); + default: + UNREACHABLE_MSG("Incompatible types"); + return code; + } + } + + std::string AsInt() const { + switch (type) { + case Type::Float: + return fmt::format("ftoi({})", code); + case Type::Uint: + return fmt::format("int({})", code); + case Type::Int: + return code; + case Type::HalfFloat: + return fmt::format("int(packHalf2x16({}))", code); + default: + UNREACHABLE_MSG("Incompatible types"); + return code; + } + } + + std::string AsUint() const { + switch (type) { + case Type::Float: + return fmt::format("ftou({})", code); + case Type::Uint: + return code; + case Type::Int: + return fmt::format("uint({})", code); + case Type::HalfFloat: + return fmt::format("packHalf2x16({})", code); + default: + UNREACHABLE_MSG("Incompatible types"); + return code; + } + } + + std::string AsHalfFloat() const { + switch (type) { + case Type::Float: + return fmt::format("unpackHalf2x16(ftou({}))", code); + case Type::Uint: + return fmt::format("unpackHalf2x16({})", code); + case Type::Int: + return fmt::format("unpackHalf2x16(int({}))", code); + case Type::HalfFloat: + return code; + default: + UNREACHABLE_MSG("Incompatible types"); + return code; + } + } + +private: + std::string code; + Type type{}; +}; + +constexpr const char* GetTypeString(Type type) { + switch (type) { + case Type::Bool: + return "bool"; + case Type::Bool2: + return "bvec2"; + case Type::Float: + return "float"; + case Type::Int: + return "int"; + case Type::Uint: + return "uint"; + case Type::HalfFloat: + return "vec2"; + default: + UNREACHABLE_MSG("Invalid type"); + return ""; + } +} + /// Generates code to use for a swizzle operation. constexpr const char* GetSwizzle(u32 element) { - constexpr std::array swizzle = {".x", ".y", ".z", ".w"}; + constexpr std::array swizzle = {".x", ".y", ".z", ".w"}; return swizzle.at(element); } @@ -134,8 +282,8 @@ constexpr bool IsGenericAttribute(Attribute::Index index) { return index >= Attribute::Index::Attribute_0 && index <= Attribute::Index::Attribute_31; } -constexpr Attribute::Index ToGenericAttribute(u32 value) { - return static_cast(value + static_cast(Attribute::Index::Attribute_0)); +constexpr Attribute::Index ToGenericAttribute(u64 value) { + return static_cast(value + static_cast(Attribute::Index::Attribute_0)); } u32 GetGenericAttributeIndex(Attribute::Index index) { @@ -191,7 +339,7 @@ public: // VM's program counter const auto first_address = ir.GetBasicBlocks().begin()->first; - code.AddLine("uint jmp_to = {}u;", first_address); + code.AddLine("uint jmp_to = {}U;", first_address); // TODO(Subv): Figure out the actual depth of the flow stack, for now it seems // unlikely that shaders will use 20 nested SSYs and PBKs. @@ -199,7 +347,7 @@ public: constexpr u32 FLOW_STACK_SIZE = 20; for (const auto stack : std::array{MetaStackClass::Ssy, MetaStackClass::Pbk}) { code.AddLine("uint {}[{}];", FlowStackName(stack), FLOW_STACK_SIZE); - code.AddLine("uint {} = 0u;", FlowStackTopName(stack)); + code.AddLine("uint {} = 0U;", FlowStackTopName(stack)); } } @@ -210,7 +358,7 @@ public: for (const auto& pair : ir.GetBasicBlocks()) { const auto [address, bb] = pair; - code.AddLine("case 0x{:x}u: {{", address); + code.AddLine("case 0x{:X}U: {{", address); ++code.scope; VisitBlock(bb); @@ -322,7 +470,7 @@ private: void DeclareRegisters() { const auto& registers = ir.GetRegisters(); for (const u32 gpr : registers) { - code.AddLine("float {} = 0;", GetRegister(gpr)); + code.AddLine("float {} = 0.0f;", GetRegister(gpr)); } if (!registers.empty()) { code.AddNewLine(); @@ -348,7 +496,7 @@ private: return; } const auto element_count = Common::AlignUp(local_memory_size, 4) / 4; - code.AddLine("float {}[{}];", GetLocalMemory(), element_count); + code.AddLine("uint {}[{}];", GetLocalMemory(), element_count); code.AddNewLine(); } @@ -371,8 +519,6 @@ private: return "noperspective "; default: case AttributeUse::Unused: - UNREACHABLE_MSG("Unused attribute being fetched"); - return {}; UNIMPLEMENTED_MSG("Unknown attribute usage index={}", static_cast(attribute)); return {}; } @@ -449,7 +595,7 @@ private: const auto [index, size] = entry; code.AddLine("layout (std140, binding = CBUF_BINDING_{}) uniform {} {{", index, GetConstBufferBlock(index)); - code.AddLine(" vec4 {}[MAX_CONSTBUFFER_ELEMENTS];", GetConstBuffer(index)); + code.AddLine(" uvec4 {}[{}];", GetConstBuffer(index), MAX_CONSTBUFFER_ELEMENTS); code.AddLine("}};"); code.AddNewLine(); } @@ -470,7 +616,7 @@ private: code.AddLine("layout (std430, binding = GMEM_BINDING_{}_{}) {} buffer {} {{", base.cbuf_index, base.cbuf_offset, qualifier, GetGlobalMemoryBlock(base)); - code.AddLine(" float {}[];", GetGlobalMemory(base)); + code.AddLine(" uint {}[];", GetGlobalMemory(base)); code.AddLine("}};"); code.AddNewLine(); } @@ -528,7 +674,7 @@ private: if (!ir.HasPhysicalAttributes()) { return; } - code.AddLine("float readPhysicalAttribute(uint physical_address) {{"); + code.AddLine("float ReadPhysicalAttribute(uint physical_address) {{"); ++code.scope; code.AddLine("switch (physical_address) {{"); @@ -537,15 +683,16 @@ private: for (u32 index = 0; index < num_attributes; ++index) { const auto attribute{ToGenericAttribute(index)}; for (u32 element = 0; element < 4; ++element) { - constexpr u32 generic_base{0x80}; - constexpr u32 generic_stride{16}; - constexpr u32 element_stride{4}; + constexpr u32 generic_base = 0x80; + constexpr u32 generic_stride = 16; + constexpr u32 element_stride = 4; const u32 address{generic_base + index * generic_stride + element * element_stride}; - const bool declared{stage != ProgramType::Fragment || - header.ps.GetAttributeUse(index) != AttributeUse::Unused}; - const std::string value{declared ? ReadAttribute(attribute, element) : "0"}; - code.AddLine("case 0x{:x}: return {};", address, value); + const bool declared = stage != ProgramType::Fragment || + header.ps.GetAttributeUse(index) != AttributeUse::Unused; + const std::string value = + declared ? ReadAttribute(attribute, element).AsFloat() : "0.0f"; + code.AddLine("case 0x{:X}U: return {};", address, value); } } @@ -590,13 +737,11 @@ private: void VisitBlock(const NodeBlock& bb) { for (const auto& node : bb) { - if (const std::string expr = Visit(node); !expr.empty()) { - code.AddLine(expr); - } + Visit(node).CheckVoid(); } } - std::string Visit(const Node& node) { + Expression Visit(const Node& node) { if (const auto operation = std::get_if(&*node)) { const auto operation_index = static_cast(operation->GetCode()); if (operation_index >= operation_decompilers.size()) { @@ -614,18 +759,18 @@ private: if (const auto gpr = std::get_if(&*node)) { const u32 index = gpr->GetIndex(); if (index == Register::ZeroIndex) { - return "0"; + return {"0U", Type::Uint}; } - return GetRegister(index); + return {GetRegister(index), Type::Float}; } if (const auto immediate = std::get_if(&*node)) { const u32 value = immediate->GetValue(); if (value < 10) { // For eyecandy avoid using hex numbers on single digits - return fmt::format("utof({}u)", immediate->GetValue()); + return {fmt::format("{}U", immediate->GetValue()), Type::Uint}; } - return fmt::format("utof(0x{:x}u)", immediate->GetValue()); + return {fmt::format("0x{:X}U", immediate->GetValue()), Type::Uint}; } if (const auto predicate = std::get_if(&*node)) { @@ -640,17 +785,18 @@ private: } }(); if (predicate->IsNegated()) { - return fmt::format("!({})", value); + return {fmt::format("!({})", value), Type::Bool}; } - return value; + return {value, Type::Bool}; } if (const auto abuf = std::get_if(&*node)) { UNIMPLEMENTED_IF_MSG(abuf->IsPhysicalBuffer() && stage == ProgramType::Geometry, "Physical attributes in geometry shaders are not implemented"); if (abuf->IsPhysicalBuffer()) { - return fmt::format("readPhysicalAttribute(ftou({}))", - Visit(abuf->GetPhysicalAddress())); + return {fmt::format("ReadPhysicalAttribute({})", + Visit(abuf->GetPhysicalAddress()).AsUint()), + Type::Float}; } return ReadAttribute(abuf->GetIndex(), abuf->GetElement(), abuf->GetBuffer()); } @@ -661,18 +807,20 @@ private: // Direct access const u32 offset_imm = immediate->GetValue(); ASSERT_MSG(offset_imm % 4 == 0, "Unaligned cbuf direct access"); - return fmt::format("{}[{}][{}]", GetConstBuffer(cbuf->GetIndex()), - offset_imm / (4 * 4), (offset_imm / 4) % 4); + return {fmt::format("{}[{}][{}]", GetConstBuffer(cbuf->GetIndex()), + offset_imm / (4 * 4), (offset_imm / 4) % 4), + Type::Uint}; } if (std::holds_alternative(*offset)) { // Indirect access const std::string final_offset = code.GenerateTemporary(); - code.AddLine("uint {} = ftou({}) >> 2;", final_offset, Visit(offset)); + code.AddLine("uint {} = {} >> 2;", final_offset, Visit(offset).AsUint()); if (!device.HasComponentIndexingBug()) { - return fmt::format("{}[{} >> 2][{} & 3]", GetConstBuffer(cbuf->GetIndex()), - final_offset, final_offset); + return {fmt::format("{}[{} >> 2][{} & 3]", GetConstBuffer(cbuf->GetIndex()), + final_offset, final_offset), + Type::Uint}; } // AMD's proprietary GLSL compiler emits ill code for variable component access. @@ -687,33 +835,36 @@ private: code.AddLine("if (({} & 3) == {}) {} = {}{};", final_offset, swizzle, result, pack, GetSwizzle(swizzle)); } - return result; + return {result, Type::Uint}; } UNREACHABLE_MSG("Unmanaged offset node type"); } if (const auto gmem = std::get_if(&*node)) { - const std::string real = Visit(gmem->GetRealAddress()); - const std::string base = Visit(gmem->GetBaseAddress()); - const std::string final_offset = fmt::format("(ftou({}) - ftou({})) / 4", real, base); - return fmt::format("{}[{}]", GetGlobalMemory(gmem->GetDescriptor()), final_offset); + const std::string real = Visit(gmem->GetRealAddress()).AsUint(); + const std::string base = Visit(gmem->GetBaseAddress()).AsUint(); + const std::string final_offset = fmt::format("({} - {}) >> 2", real, base); + return {fmt::format("{}[{}]", GetGlobalMemory(gmem->GetDescriptor()), final_offset), + Type::Uint}; } if (const auto lmem = std::get_if(&*node)) { if (stage == ProgramType::Compute) { LOG_WARNING(Render_OpenGL, "Local memory is stubbed on compute shaders"); } - return fmt::format("{}[ftou({}) / 4]", GetLocalMemory(), Visit(lmem->GetAddress())); + return { + fmt::format("{}[{} >> 2]", GetLocalMemory(), Visit(lmem->GetAddress()).AsUint()), + Type::Uint}; } if (const auto internal_flag = std::get_if(&*node)) { - return GetInternalFlag(internal_flag->GetFlag()); + return {GetInternalFlag(internal_flag->GetFlag()), Type::Bool}; } if (const auto conditional = std::get_if(&*node)) { // It's invalid to call conditional on nested nodes, use an operation instead - code.AddLine("if ({}) {{", Visit(conditional->GetCondition())); + code.AddLine("if ({}) {{", Visit(conditional->GetCondition()).AsBool()); ++code.scope; VisitBlock(conditional->GetCode()); @@ -724,20 +875,21 @@ private: } if (const auto comment = std::get_if(&*node)) { - return "// " + comment->GetText(); + code.AddLine("// " + comment->GetText()); + return {}; } UNREACHABLE(); return {}; } - std::string ReadAttribute(Attribute::Index attribute, u32 element, const Node& buffer = {}) { + Expression ReadAttribute(Attribute::Index attribute, u32 element, const Node& buffer = {}) { const auto GeometryPass = [&](std::string_view name) { if (stage == ProgramType::Geometry && buffer) { // TODO(Rodrigo): Guard geometry inputs against out of bound reads. Some games // set an 0x80000000 index for those and the shader fails to build. Find out why // this happens and what's its intent. - return fmt::format("gs_{}[ftou({}) % MAX_VERTEX_INPUT]", name, Visit(buffer)); + return fmt::format("gs_{}[{} % MAX_VERTEX_INPUT]", name, Visit(buffer).AsUint()); } return std::string(name); }; @@ -746,25 +898,27 @@ private: case Attribute::Index::Position: switch (stage) { case ProgramType::Geometry: - return fmt::format("gl_in[ftou({})].gl_Position{}", Visit(buffer), - GetSwizzle(element)); + return {fmt::format("gl_in[{}].gl_Position{}", Visit(buffer).AsUint(), + GetSwizzle(element)), + Type::Float}; case ProgramType::Fragment: - return element == 3 ? "1.0f" : ("gl_FragCoord"s + GetSwizzle(element)); + return {element == 3 ? "1.0f" : ("gl_FragCoord"s + GetSwizzle(element)), + Type::Float}; default: UNREACHABLE(); } case Attribute::Index::PointCoord: switch (element) { case 0: - return "gl_PointCoord.x"; + return {"gl_PointCoord.x", Type::Float}; case 1: - return "gl_PointCoord.y"; + return {"gl_PointCoord.y", Type::Float}; case 2: case 3: - return "0"; + return {"0.0f", Type::Float}; } UNREACHABLE(); - return "0"; + return {"0", Type::Int}; case Attribute::Index::TessCoordInstanceIDVertexID: // TODO(Subv): Find out what the values are for the first two elements when inside a // vertex shader, and what's the value of the fourth element when inside a Tess Eval @@ -773,44 +927,42 @@ private: switch (element) { case 2: // Config pack's first value is instance_id. - return "uintBitsToFloat(config_pack[0])"; + return {"config_pack[0]", Type::Uint}; case 3: - return "uintBitsToFloat(gl_VertexID)"; + return {"gl_VertexID", Type::Int}; } UNIMPLEMENTED_MSG("Unmanaged TessCoordInstanceIDVertexID element={}", element); - return "0"; + return {"0", Type::Int}; case Attribute::Index::FrontFacing: // TODO(Subv): Find out what the values are for the other elements. ASSERT(stage == ProgramType::Fragment); switch (element) { case 3: - return "itof(gl_FrontFacing ? -1 : 0)"; + return {"(gl_FrontFacing ? -1 : 0)", Type::Int}; } UNIMPLEMENTED_MSG("Unmanaged FrontFacing element={}", element); - return "0"; + return {"0", Type::Int}; default: if (IsGenericAttribute(attribute)) { - return GeometryPass(GetInputAttribute(attribute)) + GetSwizzle(element); + return {GeometryPass(GetInputAttribute(attribute)) + GetSwizzle(element), + Type::Float}; } break; } UNIMPLEMENTED_MSG("Unhandled input attribute: {}", static_cast(attribute)); - return "0"; + return {"0", Type::Int}; } - std::string ApplyPrecise(Operation operation, const std::string& value) { + Expression ApplyPrecise(Operation operation, std::string value, Type type) { if (!IsPrecise(operation)) { - return value; + return {std::move(value), type}; } - // There's a bug in NVidia's proprietary drivers that makes precise fail on fragment shaders - const std::string precise = stage != ProgramType::Fragment ? "precise " : ""; - - const std::string temporary = code.GenerateTemporary(); - code.AddLine("{}float {} = {};", precise, temporary, value); - return temporary; + std::string temporary = code.GenerateTemporary(); + code.AddLine("precise {} {} = {};", GetTypeString(type), temporary, value); + return {std::move(temporary), type}; } - std::string VisitOperand(Operation operation, std::size_t operand_index) { + Expression VisitOperand(Operation operation, std::size_t operand_index) { const auto& operand = operation[operand_index]; const bool parent_precise = IsPrecise(operation); const bool child_precise = IsPrecise(operand); @@ -819,19 +971,16 @@ private: return Visit(operand); } - const std::string temporary = code.GenerateTemporary(); - code.AddLine("float {} = {};", temporary, Visit(operand)); - return temporary; + Expression value = Visit(operand); + std::string temporary = code.GenerateTemporary(); + code.AddLine("{} {} = {};", GetTypeString(value.GetType()), temporary, value.GetCode()); + return {std::move(temporary), value.GetType()}; } - std::string VisitOperand(Operation operation, std::size_t operand_index, Type type) { - return CastOperand(VisitOperand(operation, operand_index), type); - } - - std::optional> GetOutputAttribute(const AbufNode* abuf) { + Expression GetOutputAttribute(const AbufNode* abuf) { switch (const auto attribute = abuf->GetIndex()) { case Attribute::Index::Position: - return std::make_pair("gl_Position"s + GetSwizzle(abuf->GetElement()), false); + return {"gl_Position"s + GetSwizzle(abuf->GetElement()), Type::Float}; case Attribute::Index::LayerViewportPointSize: switch (abuf->GetElement()) { case 0: @@ -841,119 +990,79 @@ private: if (IsVertexShader(stage) && !device.HasVertexViewportLayer()) { return {}; } - return std::make_pair("gl_Layer", true); + return {"gl_Layer", Type::Int}; case 2: if (IsVertexShader(stage) && !device.HasVertexViewportLayer()) { return {}; } - return std::make_pair("gl_ViewportIndex", true); + return {"gl_ViewportIndex", Type::Int}; case 3: UNIMPLEMENTED_MSG("Requires some state changes for gl_PointSize to work in shader"); - return std::make_pair("gl_PointSize", false); + return {"gl_PointSize", Type::Float}; } return {}; case Attribute::Index::ClipDistances0123: - return std::make_pair(fmt::format("gl_ClipDistance[{}]", abuf->GetElement()), false); + return {fmt::format("gl_ClipDistance[{}]", abuf->GetElement()), Type::Float}; case Attribute::Index::ClipDistances4567: - return std::make_pair(fmt::format("gl_ClipDistance[{}]", abuf->GetElement() + 4), - false); + return {fmt::format("gl_ClipDistance[{}]", abuf->GetElement() + 4), Type::Float}; default: if (IsGenericAttribute(attribute)) { - return std::make_pair( - GetOutputAttribute(attribute) + GetSwizzle(abuf->GetElement()), false); + return {GetOutputAttribute(attribute) + GetSwizzle(abuf->GetElement()), + Type::Float}; } UNIMPLEMENTED_MSG("Unhandled output attribute: {}", static_cast(attribute)); return {}; } } - std::string CastOperand(const std::string& value, Type type) const { - switch (type) { - case Type::Bool: - case Type::Bool2: - case Type::Float: - return value; - case Type::Int: - return fmt::format("ftoi({})", value); - case Type::Uint: - return fmt::format("ftou({})", value); - case Type::HalfFloat: - return fmt::format("toHalf2({})", value); - } - UNREACHABLE(); - return value; + Expression GenerateUnary(Operation operation, std::string_view func, Type result_type, + Type type_a) { + std::string op_str = fmt::format("{}({})", func, VisitOperand(operation, 0).As(type_a)); + return ApplyPrecise(operation, std::move(op_str), result_type); } - std::string BitwiseCastResult(const std::string& value, Type type, - bool needs_parenthesis = false) { - switch (type) { - case Type::Bool: - case Type::Bool2: - case Type::Float: - if (needs_parenthesis) { - return fmt::format("({})", value); - } - return value; - case Type::Int: - return fmt::format("itof({})", value); - case Type::Uint: - return fmt::format("utof({})", value); - case Type::HalfFloat: - return fmt::format("fromHalf2({})", value); - } - UNREACHABLE(); - return value; - } - - std::string GenerateUnary(Operation operation, const std::string& func, Type result_type, - Type type_a, bool needs_parenthesis = true) { - const std::string op_str = fmt::format("{}({})", func, VisitOperand(operation, 0, type_a)); - - return ApplyPrecise(operation, BitwiseCastResult(op_str, result_type, needs_parenthesis)); - } - - std::string GenerateBinaryInfix(Operation operation, const std::string& func, Type result_type, - Type type_a, Type type_b) { - const std::string op_a = VisitOperand(operation, 0, type_a); - const std::string op_b = VisitOperand(operation, 1, type_b); - const std::string op_str = fmt::format("({} {} {})", op_a, func, op_b); - - return ApplyPrecise(operation, BitwiseCastResult(op_str, result_type)); - } - - std::string GenerateBinaryCall(Operation operation, const std::string& func, Type result_type, + Expression GenerateBinaryInfix(Operation operation, std::string_view func, Type result_type, Type type_a, Type type_b) { - const std::string op_a = VisitOperand(operation, 0, type_a); - const std::string op_b = VisitOperand(operation, 1, type_b); - const std::string op_str = fmt::format("{}({}, {})", func, op_a, op_b); + const std::string op_a = VisitOperand(operation, 0).As(type_a); + const std::string op_b = VisitOperand(operation, 1).As(type_b); + std::string op_str = fmt::format("({} {} {})", op_a, func, op_b); - return ApplyPrecise(operation, BitwiseCastResult(op_str, result_type)); + return ApplyPrecise(operation, std::move(op_str), result_type); } - std::string GenerateTernary(Operation operation, const std::string& func, Type result_type, - Type type_a, Type type_b, Type type_c) { - const std::string op_a = VisitOperand(operation, 0, type_a); - const std::string op_b = VisitOperand(operation, 1, type_b); - const std::string op_c = VisitOperand(operation, 2, type_c); - const std::string op_str = fmt::format("{}({}, {}, {})", func, op_a, op_b, op_c); + Expression GenerateBinaryCall(Operation operation, std::string_view func, Type result_type, + Type type_a, Type type_b) { + const std::string op_a = VisitOperand(operation, 0).As(type_a); + const std::string op_b = VisitOperand(operation, 1).As(type_b); + std::string op_str = fmt::format("{}({}, {})", func, op_a, op_b); - return ApplyPrecise(operation, BitwiseCastResult(op_str, result_type)); + return ApplyPrecise(operation, std::move(op_str), result_type); } - std::string GenerateQuaternary(Operation operation, const std::string& func, Type result_type, - Type type_a, Type type_b, Type type_c, Type type_d) { - const std::string op_a = VisitOperand(operation, 0, type_a); - const std::string op_b = VisitOperand(operation, 1, type_b); - const std::string op_c = VisitOperand(operation, 2, type_c); - const std::string op_d = VisitOperand(operation, 3, type_d); - const std::string op_str = fmt::format("{}({}, {}, {}, {})", func, op_a, op_b, op_c, op_d); + Expression GenerateTernary(Operation operation, std::string_view func, Type result_type, + Type type_a, Type type_b, Type type_c) { + const std::string op_a = VisitOperand(operation, 0).As(type_a); + const std::string op_b = VisitOperand(operation, 1).As(type_b); + const std::string op_c = VisitOperand(operation, 2).As(type_c); + std::string op_str = fmt::format("{}({}, {}, {})", func, op_a, op_b, op_c); - return ApplyPrecise(operation, BitwiseCastResult(op_str, result_type)); + return ApplyPrecise(operation, std::move(op_str), result_type); + } + + Expression GenerateQuaternary(Operation operation, const std::string& func, Type result_type, + Type type_a, Type type_b, Type type_c, Type type_d) { + const std::string op_a = VisitOperand(operation, 0).As(type_a); + const std::string op_b = VisitOperand(operation, 1).As(type_b); + const std::string op_c = VisitOperand(operation, 2).As(type_c); + const std::string op_d = VisitOperand(operation, 3).As(type_d); + std::string op_str = fmt::format("{}({}, {}, {}, {})", func, op_a, op_b, op_c, op_d); + + return ApplyPrecise(operation, std::move(op_str), result_type); } std::string GenerateTexture(Operation operation, const std::string& function_suffix, const std::vector& extras) { - constexpr std::array coord_constructors = {"float", "vec2", "vec3", "vec4"}; + constexpr std::array coord_constructors = {"float", "vec2", "vec3", "vec4"}; const auto meta = std::get_if(&operation.GetMeta()); ASSERT(meta); @@ -970,17 +1079,17 @@ private: expr += coord_constructors.at(count + (has_array ? 1 : 0) + (has_shadow ? 1 : 0) - 1); expr += '('; for (std::size_t i = 0; i < count; ++i) { - expr += Visit(operation[i]); + expr += Visit(operation[i]).AsFloat(); const std::size_t next = i + 1; if (next < count) expr += ", "; } if (has_array) { - expr += ", float(ftoi(" + Visit(meta->array) + "))"; + expr += ", float(" + Visit(meta->array).AsInt() + ')'; } if (has_shadow) { - expr += ", " + Visit(meta->depth_compare); + expr += ", " + Visit(meta->depth_compare).AsFloat(); } expr += ')'; @@ -1011,11 +1120,11 @@ private: // required to be constant) expr += std::to_string(static_cast(immediate->GetValue())); } else { - expr += fmt::format("ftoi({})", Visit(operand)); + expr += Visit(operand).AsInt(); } break; case Type::Float: - expr += Visit(operand); + expr += Visit(operand).AsFloat(); break; default: { const auto type_int = static_cast(type); @@ -1031,7 +1140,7 @@ private: if (aoffi.empty()) { return {}; } - constexpr std::array coord_constructors = {"int", "ivec2", "ivec3"}; + constexpr std::array coord_constructors = {"int", "ivec2", "ivec3"}; std::string expr = ", "; expr += coord_constructors.at(aoffi.size() - 1); expr += '('; @@ -1044,7 +1153,7 @@ private: expr += std::to_string(static_cast(immediate->GetValue())); } else if (device.HasVariableAoffi()) { // Avoid using variable AOFFI on unsupported devices. - expr += fmt::format("ftoi({})", Visit(operand)); + expr += Visit(operand).AsInt(); } else { // Insert 0 on devices not supporting variable AOFFI. expr += '0'; @@ -1058,328 +1167,314 @@ private: return expr; } - std::string Assign(Operation operation) { + Expression Assign(Operation operation) { const Node& dest = operation[0]; const Node& src = operation[1]; - std::string target; - bool is_integer = false; - + Expression target; if (const auto gpr = std::get_if(&*dest)) { if (gpr->GetIndex() == Register::ZeroIndex) { // Writing to Register::ZeroIndex is a no op return {}; } - target = GetRegister(gpr->GetIndex()); + target = {GetRegister(gpr->GetIndex()), Type::Float}; } else if (const auto abuf = std::get_if(&*dest)) { UNIMPLEMENTED_IF(abuf->IsPhysicalBuffer()); - const auto result = GetOutputAttribute(abuf); - if (!result) { - return {}; - } - target = result->first; - is_integer = result->second; + target = GetOutputAttribute(abuf); } else if (const auto lmem = std::get_if(&*dest)) { if (stage == ProgramType::Compute) { LOG_WARNING(Render_OpenGL, "Local memory is stubbed on compute shaders"); } - target = fmt::format("{}[ftou({}) / 4]", GetLocalMemory(), Visit(lmem->GetAddress())); + target = { + fmt::format("{}[{} >> 2]", GetLocalMemory(), Visit(lmem->GetAddress()).AsUint()), + Type::Uint}; } else if (const auto gmem = std::get_if(&*dest)) { - const std::string real = Visit(gmem->GetRealAddress()); - const std::string base = Visit(gmem->GetBaseAddress()); - const std::string final_offset = fmt::format("(ftou({}) - ftou({})) / 4", real, base); - target = fmt::format("{}[{}]", GetGlobalMemory(gmem->GetDescriptor()), final_offset); + const std::string real = Visit(gmem->GetRealAddress()).AsUint(); + const std::string base = Visit(gmem->GetBaseAddress()).AsUint(); + const std::string final_offset = fmt::format("({} - {}) >> 2", real, base); + target = {fmt::format("{}[{}]", GetGlobalMemory(gmem->GetDescriptor()), final_offset), + Type::Uint}; } else { UNREACHABLE_MSG("Assign called without a proper target"); } - if (is_integer) { - code.AddLine("{} = ftoi({});", target, Visit(src)); - } else { - code.AddLine("{} = {};", target, Visit(src)); - } + code.AddLine("{} = {};", target.GetCode(), Visit(src).As(target.GetType())); return {}; } template - std::string Add(Operation operation) { + Expression Add(Operation operation) { return GenerateBinaryInfix(operation, "+", type, type, type); } template - std::string Mul(Operation operation) { + Expression Mul(Operation operation) { return GenerateBinaryInfix(operation, "*", type, type, type); } template - std::string Div(Operation operation) { + Expression Div(Operation operation) { return GenerateBinaryInfix(operation, "/", type, type, type); } template - std::string Fma(Operation operation) { + Expression Fma(Operation operation) { return GenerateTernary(operation, "fma", type, type, type, type); } template - std::string Negate(Operation operation) { - return GenerateUnary(operation, "-", type, type, true); + Expression Negate(Operation operation) { + return GenerateUnary(operation, "-", type, type); } template - std::string Absolute(Operation operation) { - return GenerateUnary(operation, "abs", type, type, false); + Expression Absolute(Operation operation) { + return GenerateUnary(operation, "abs", type, type); } - std::string FClamp(Operation operation) { + Expression FClamp(Operation operation) { return GenerateTernary(operation, "clamp", Type::Float, Type::Float, Type::Float, Type::Float); } - std::string FCastHalf0(Operation operation) { - const std::string op_a = VisitOperand(operation, 0, Type::HalfFloat); - return fmt::format("({})[0]", op_a); + Expression FCastHalf0(Operation operation) { + return {fmt::format("({})[0]", VisitOperand(operation, 0).AsHalfFloat()), Type::Float}; } - std::string FCastHalf1(Operation operation) { - const std::string op_a = VisitOperand(operation, 0, Type::HalfFloat); - return fmt::format("({})[1]", op_a); + Expression FCastHalf1(Operation operation) { + return {fmt::format("({})[1]", VisitOperand(operation, 0).AsHalfFloat()), Type::Float}; } template - std::string Min(Operation operation) { + Expression Min(Operation operation) { return GenerateBinaryCall(operation, "min", type, type, type); } template - std::string Max(Operation operation) { + Expression Max(Operation operation) { return GenerateBinaryCall(operation, "max", type, type, type); } - std::string Select(Operation operation) { - const std::string condition = Visit(operation[0]); - const std::string true_case = Visit(operation[1]); - const std::string false_case = Visit(operation[2]); - const std::string op_str = fmt::format("({} ? {} : {})", condition, true_case, false_case); + Expression Select(Operation operation) { + const std::string condition = Visit(operation[0]).AsBool(); + const std::string true_case = Visit(operation[1]).AsUint(); + const std::string false_case = Visit(operation[2]).AsUint(); + std::string op_str = fmt::format("({} ? {} : {})", condition, true_case, false_case); - return ApplyPrecise(operation, op_str); + return ApplyPrecise(operation, std::move(op_str), Type::Uint); } - std::string FCos(Operation operation) { - return GenerateUnary(operation, "cos", Type::Float, Type::Float, false); + Expression FCos(Operation operation) { + return GenerateUnary(operation, "cos", Type::Float, Type::Float); } - std::string FSin(Operation operation) { - return GenerateUnary(operation, "sin", Type::Float, Type::Float, false); + Expression FSin(Operation operation) { + return GenerateUnary(operation, "sin", Type::Float, Type::Float); } - std::string FExp2(Operation operation) { - return GenerateUnary(operation, "exp2", Type::Float, Type::Float, false); + Expression FExp2(Operation operation) { + return GenerateUnary(operation, "exp2", Type::Float, Type::Float); } - std::string FLog2(Operation operation) { - return GenerateUnary(operation, "log2", Type::Float, Type::Float, false); + Expression FLog2(Operation operation) { + return GenerateUnary(operation, "log2", Type::Float, Type::Float); } - std::string FInverseSqrt(Operation operation) { - return GenerateUnary(operation, "inversesqrt", Type::Float, Type::Float, false); + Expression FInverseSqrt(Operation operation) { + return GenerateUnary(operation, "inversesqrt", Type::Float, Type::Float); } - std::string FSqrt(Operation operation) { - return GenerateUnary(operation, "sqrt", Type::Float, Type::Float, false); + Expression FSqrt(Operation operation) { + return GenerateUnary(operation, "sqrt", Type::Float, Type::Float); } - std::string FRoundEven(Operation operation) { - return GenerateUnary(operation, "roundEven", Type::Float, Type::Float, false); + Expression FRoundEven(Operation operation) { + return GenerateUnary(operation, "roundEven", Type::Float, Type::Float); } - std::string FFloor(Operation operation) { - return GenerateUnary(operation, "floor", Type::Float, Type::Float, false); + Expression FFloor(Operation operation) { + return GenerateUnary(operation, "floor", Type::Float, Type::Float); } - std::string FCeil(Operation operation) { - return GenerateUnary(operation, "ceil", Type::Float, Type::Float, false); + Expression FCeil(Operation operation) { + return GenerateUnary(operation, "ceil", Type::Float, Type::Float); } - std::string FTrunc(Operation operation) { - return GenerateUnary(operation, "trunc", Type::Float, Type::Float, false); + Expression FTrunc(Operation operation) { + return GenerateUnary(operation, "trunc", Type::Float, Type::Float); } template - std::string FCastInteger(Operation operation) { - return GenerateUnary(operation, "float", Type::Float, type, false); + Expression FCastInteger(Operation operation) { + return GenerateUnary(operation, "float", Type::Float, type); } - std::string ICastFloat(Operation operation) { - return GenerateUnary(operation, "int", Type::Int, Type::Float, false); + Expression ICastFloat(Operation operation) { + return GenerateUnary(operation, "int", Type::Int, Type::Float); } - std::string ICastUnsigned(Operation operation) { - return GenerateUnary(operation, "int", Type::Int, Type::Uint, false); + Expression ICastUnsigned(Operation operation) { + return GenerateUnary(operation, "int", Type::Int, Type::Uint); } template - std::string LogicalShiftLeft(Operation operation) { + Expression LogicalShiftLeft(Operation operation) { return GenerateBinaryInfix(operation, "<<", type, type, Type::Uint); } - std::string ILogicalShiftRight(Operation operation) { - const std::string op_a = VisitOperand(operation, 0, Type::Uint); - const std::string op_b = VisitOperand(operation, 1, Type::Uint); - const std::string op_str = fmt::format("int({} >> {})", op_a, op_b); + Expression ILogicalShiftRight(Operation operation) { + const std::string op_a = VisitOperand(operation, 0).AsUint(); + const std::string op_b = VisitOperand(operation, 1).AsUint(); + std::string op_str = fmt::format("int({} >> {})", op_a, op_b); - return ApplyPrecise(operation, BitwiseCastResult(op_str, Type::Int)); + return ApplyPrecise(operation, std::move(op_str), Type::Int); } - std::string IArithmeticShiftRight(Operation operation) { + Expression IArithmeticShiftRight(Operation operation) { return GenerateBinaryInfix(operation, ">>", Type::Int, Type::Int, Type::Uint); } template - std::string BitwiseAnd(Operation operation) { + Expression BitwiseAnd(Operation operation) { return GenerateBinaryInfix(operation, "&", type, type, type); } template - std::string BitwiseOr(Operation operation) { + Expression BitwiseOr(Operation operation) { return GenerateBinaryInfix(operation, "|", type, type, type); } template - std::string BitwiseXor(Operation operation) { + Expression BitwiseXor(Operation operation) { return GenerateBinaryInfix(operation, "^", type, type, type); } template - std::string BitwiseNot(Operation operation) { - return GenerateUnary(operation, "~", type, type, false); + Expression BitwiseNot(Operation operation) { + return GenerateUnary(operation, "~", type, type); } - std::string UCastFloat(Operation operation) { - return GenerateUnary(operation, "uint", Type::Uint, Type::Float, false); + Expression UCastFloat(Operation operation) { + return GenerateUnary(operation, "uint", Type::Uint, Type::Float); } - std::string UCastSigned(Operation operation) { - return GenerateUnary(operation, "uint", Type::Uint, Type::Int, false); + Expression UCastSigned(Operation operation) { + return GenerateUnary(operation, "uint", Type::Uint, Type::Int); } - std::string UShiftRight(Operation operation) { + Expression UShiftRight(Operation operation) { return GenerateBinaryInfix(operation, ">>", Type::Uint, Type::Uint, Type::Uint); } template - std::string BitfieldInsert(Operation operation) { + Expression BitfieldInsert(Operation operation) { return GenerateQuaternary(operation, "bitfieldInsert", type, type, type, Type::Int, Type::Int); } template - std::string BitfieldExtract(Operation operation) { + Expression BitfieldExtract(Operation operation) { return GenerateTernary(operation, "bitfieldExtract", type, type, Type::Int, Type::Int); } template - std::string BitCount(Operation operation) { - return GenerateUnary(operation, "bitCount", type, type, false); + Expression BitCount(Operation operation) { + return GenerateUnary(operation, "bitCount", type, type); } - std::string HNegate(Operation operation) { + Expression HNegate(Operation operation) { const auto GetNegate = [&](std::size_t index) { - return VisitOperand(operation, index, Type::Bool) + " ? -1 : 1"; + return VisitOperand(operation, index).AsBool() + " ? -1 : 1"; }; - const std::string value = - fmt::format("({} * vec2({}, {}))", VisitOperand(operation, 0, Type::HalfFloat), - GetNegate(1), GetNegate(2)); - return BitwiseCastResult(value, Type::HalfFloat); + return {fmt::format("({} * vec2({}, {}))", VisitOperand(operation, 0).AsHalfFloat(), + GetNegate(1), GetNegate(2)), + Type::HalfFloat}; } - std::string HClamp(Operation operation) { - const std::string value = VisitOperand(operation, 0, Type::HalfFloat); - const std::string min = VisitOperand(operation, 1, Type::Float); - const std::string max = VisitOperand(operation, 2, Type::Float); - const std::string clamped = fmt::format("clamp({}, vec2({}), vec2({}))", value, min, max); + Expression HClamp(Operation operation) { + const std::string value = VisitOperand(operation, 0).AsHalfFloat(); + const std::string min = VisitOperand(operation, 1).AsFloat(); + const std::string max = VisitOperand(operation, 2).AsFloat(); + std::string clamped = fmt::format("clamp({}, vec2({}), vec2({}))", value, min, max); - return ApplyPrecise(operation, BitwiseCastResult(clamped, Type::HalfFloat)); + return ApplyPrecise(operation, std::move(clamped), Type::HalfFloat); } - std::string HCastFloat(Operation operation) { - const std::string op_a = VisitOperand(operation, 0, Type::Float); - return fmt::format("fromHalf2(vec2({}, 0.0f))", op_a); + Expression HCastFloat(Operation operation) { + return {fmt::format("vec2({})", VisitOperand(operation, 0).AsFloat()), Type::HalfFloat}; } - std::string HUnpack(Operation operation) { - const std::string operand{VisitOperand(operation, 0, Type::HalfFloat)}; - const auto value = [&]() -> std::string { - switch (std::get(operation.GetMeta())) { - case Tegra::Shader::HalfType::H0_H1: - return operand; - case Tegra::Shader::HalfType::F32: - return fmt::format("vec2(fromHalf2({}))", operand); - case Tegra::Shader::HalfType::H0_H0: - return fmt::format("vec2({}[0])", operand); - case Tegra::Shader::HalfType::H1_H1: - return fmt::format("vec2({}[1])", operand); - } - UNREACHABLE(); - return "0"; - }(); - return fmt::format("fromHalf2({})", value); + Expression HUnpack(Operation operation) { + Expression operand = VisitOperand(operation, 0); + switch (std::get(operation.GetMeta())) { + case Tegra::Shader::HalfType::H0_H1: + return operand; + case Tegra::Shader::HalfType::F32: + return {fmt::format("vec2({})", operand.AsFloat()), Type::HalfFloat}; + case Tegra::Shader::HalfType::H0_H0: + return {fmt::format("vec2({}[0])", operand.AsHalfFloat()), Type::HalfFloat}; + case Tegra::Shader::HalfType::H1_H1: + return {fmt::format("vec2({}[1])", operand.AsHalfFloat()), Type::HalfFloat}; + } } - std::string HMergeF32(Operation operation) { - return fmt::format("float(toHalf2({})[0])", Visit(operation[0])); + Expression HMergeF32(Operation operation) { + return {fmt::format("float({}[0])", VisitOperand(operation, 0).AsHalfFloat()), Type::Float}; } - std::string HMergeH0(Operation operation) { - return fmt::format("fromHalf2(vec2(toHalf2({})[0], toHalf2({})[1]))", Visit(operation[1]), - Visit(operation[0])); + Expression HMergeH0(Operation operation) { + std::string dest = VisitOperand(operation, 0).AsUint(); + std::string src = VisitOperand(operation, 1).AsUint(); + return {fmt::format("(({} & 0x0000FFFFU) | ({} & 0xFFFF0000U))", src, dest), Type::Uint}; } - std::string HMergeH1(Operation operation) { - return fmt::format("fromHalf2(vec2(toHalf2({})[0], toHalf2({})[1]))", Visit(operation[0]), - Visit(operation[1])); + Expression HMergeH1(Operation operation) { + std::string dest = VisitOperand(operation, 0).AsUint(); + std::string src = VisitOperand(operation, 1).AsUint(); + return {fmt::format("(({} & 0x0000FFFFU) | ({} & 0xFFFF0000U))", dest, src), Type::Uint}; } - std::string HPack2(Operation operation) { - return fmt::format("utof(packHalf2x16(vec2({}, {})))", Visit(operation[0]), - Visit(operation[1])); + Expression HPack2(Operation operation) { + return {fmt::format("vec2({}, {})", VisitOperand(operation, 0).AsFloat(), + VisitOperand(operation, 1).AsFloat()), + Type::HalfFloat}; } template - std::string LogicalLessThan(Operation operation) { + Expression LogicalLessThan(Operation operation) { return GenerateBinaryInfix(operation, "<", Type::Bool, type, type); } template - std::string LogicalEqual(Operation operation) { + Expression LogicalEqual(Operation operation) { return GenerateBinaryInfix(operation, "==", Type::Bool, type, type); } template - std::string LogicalLessEqual(Operation operation) { + Expression LogicalLessEqual(Operation operation) { return GenerateBinaryInfix(operation, "<=", Type::Bool, type, type); } template - std::string LogicalGreaterThan(Operation operation) { + Expression LogicalGreaterThan(Operation operation) { return GenerateBinaryInfix(operation, ">", Type::Bool, type, type); } template - std::string LogicalNotEqual(Operation operation) { + Expression LogicalNotEqual(Operation operation) { return GenerateBinaryInfix(operation, "!=", Type::Bool, type, type); } template - std::string LogicalGreaterEqual(Operation operation) { + Expression LogicalGreaterEqual(Operation operation) { return GenerateBinaryInfix(operation, ">=", Type::Bool, type, type); } - std::string LogicalFIsNan(Operation operation) { - return GenerateUnary(operation, "isnan", Type::Bool, Type::Float, false); + Expression LogicalFIsNan(Operation operation) { + return GenerateUnary(operation, "isnan", Type::Bool, Type::Float); } - std::string LogicalAssign(Operation operation) { + Expression LogicalAssign(Operation operation) { const Node& dest = operation[0]; const Node& src = operation[1]; @@ -1400,78 +1495,80 @@ private: target = GetInternalFlag(flag->GetFlag()); } - code.AddLine("{} = {};", target, Visit(src)); + code.AddLine("{} = {};", target, Visit(src).AsBool()); return {}; } - std::string LogicalAnd(Operation operation) { + Expression LogicalAnd(Operation operation) { return GenerateBinaryInfix(operation, "&&", Type::Bool, Type::Bool, Type::Bool); } - std::string LogicalOr(Operation operation) { + Expression LogicalOr(Operation operation) { return GenerateBinaryInfix(operation, "||", Type::Bool, Type::Bool, Type::Bool); } - std::string LogicalXor(Operation operation) { + Expression LogicalXor(Operation operation) { return GenerateBinaryInfix(operation, "^^", Type::Bool, Type::Bool, Type::Bool); } - std::string LogicalNegate(Operation operation) { - return GenerateUnary(operation, "!", Type::Bool, Type::Bool, false); + Expression LogicalNegate(Operation operation) { + return GenerateUnary(operation, "!", Type::Bool, Type::Bool); } - std::string LogicalPick2(Operation operation) { - const std::string pair = VisitOperand(operation, 0, Type::Bool2); - return fmt::format("{}[{}]", pair, VisitOperand(operation, 1, Type::Uint)); + Expression LogicalPick2(Operation operation) { + return {fmt::format("{}[{}]", VisitOperand(operation, 0).AsBool2(), + VisitOperand(operation, 1).AsUint()), + Type::Bool}; } - std::string LogicalAnd2(Operation operation) { + Expression LogicalAnd2(Operation operation) { return GenerateUnary(operation, "all", Type::Bool, Type::Bool2); } template - std::string GenerateHalfComparison(Operation operation, const std::string& compare_op) { - const std::string comparison{GenerateBinaryCall(operation, compare_op, Type::Bool2, - Type::HalfFloat, Type::HalfFloat)}; + Expression GenerateHalfComparison(Operation operation, std::string_view compare_op) { + Expression comparison = GenerateBinaryCall(operation, compare_op, Type::Bool2, + Type::HalfFloat, Type::HalfFloat); if constexpr (!with_nan) { return comparison; } - return fmt::format("halfFloatNanComparison({}, {}, {})", comparison, - VisitOperand(operation, 0, Type::HalfFloat), - VisitOperand(operation, 1, Type::HalfFloat)); + return {fmt::format("HalfFloatNanComparison({}, {}, {})", comparison.AsBool2(), + VisitOperand(operation, 0).AsHalfFloat(), + VisitOperand(operation, 1).AsHalfFloat()), + Type::Bool2}; } template - std::string Logical2HLessThan(Operation operation) { + Expression Logical2HLessThan(Operation operation) { return GenerateHalfComparison(operation, "lessThan"); } template - std::string Logical2HEqual(Operation operation) { + Expression Logical2HEqual(Operation operation) { return GenerateHalfComparison(operation, "equal"); } template - std::string Logical2HLessEqual(Operation operation) { + Expression Logical2HLessEqual(Operation operation) { return GenerateHalfComparison(operation, "lessThanEqual"); } template - std::string Logical2HGreaterThan(Operation operation) { + Expression Logical2HGreaterThan(Operation operation) { return GenerateHalfComparison(operation, "greaterThan"); } template - std::string Logical2HNotEqual(Operation operation) { + Expression Logical2HNotEqual(Operation operation) { return GenerateHalfComparison(operation, "notEqual"); } template - std::string Logical2HGreaterEqual(Operation operation) { + Expression Logical2HGreaterEqual(Operation operation) { return GenerateHalfComparison(operation, "greaterThanEqual"); } - std::string Texture(Operation operation) { + Expression Texture(Operation operation) { const auto meta = std::get_if(&operation.GetMeta()); ASSERT(meta); @@ -1480,10 +1577,10 @@ private: if (meta->sampler.IsShadow()) { expr = "vec4(" + expr + ')'; } - return expr + GetSwizzle(meta->element); + return {expr + GetSwizzle(meta->element), Type::Float}; } - std::string TextureLod(Operation operation) { + Expression TextureLod(Operation operation) { const auto meta = std::get_if(&operation.GetMeta()); ASSERT(meta); @@ -1492,54 +1589,54 @@ private: if (meta->sampler.IsShadow()) { expr = "vec4(" + expr + ')'; } - return expr + GetSwizzle(meta->element); + return {expr + GetSwizzle(meta->element), Type::Float}; } - std::string TextureGather(Operation operation) { + Expression TextureGather(Operation operation) { const auto meta = std::get_if(&operation.GetMeta()); ASSERT(meta); const auto type = meta->sampler.IsShadow() ? Type::Float : Type::Int; - return GenerateTexture(operation, "Gather", - {TextureArgument{type, meta->component}, TextureAoffi{}}) + - GetSwizzle(meta->element); + return {GenerateTexture(operation, "Gather", + {TextureArgument{type, meta->component}, TextureAoffi{}}) + + GetSwizzle(meta->element), + Type::Float}; } - std::string TextureQueryDimensions(Operation operation) { + Expression TextureQueryDimensions(Operation operation) { const auto meta = std::get_if(&operation.GetMeta()); ASSERT(meta); const std::string sampler = GetSampler(meta->sampler); - const std::string lod = VisitOperand(operation, 0, Type::Int); + const std::string lod = VisitOperand(operation, 0).AsInt(); switch (meta->element) { case 0: case 1: - return fmt::format("itof(int(textureSize({}, {}){}))", sampler, lod, - GetSwizzle(meta->element)); - case 2: - return "0"; + return {fmt::format("textureSize({}, {}){}", sampler, lod, GetSwizzle(meta->element)), + Type::Int}; case 3: - return fmt::format("itof(textureQueryLevels({}))", sampler); + return {fmt::format("textureQueryLevels({})", sampler), Type::Int}; } UNREACHABLE(); - return "0"; + return {"0", Type::Int}; } - std::string TextureQueryLod(Operation operation) { + Expression TextureQueryLod(Operation operation) { const auto meta = std::get_if(&operation.GetMeta()); ASSERT(meta); if (meta->element < 2) { - return fmt::format("itof(int(({} * vec2(256)){}))", - GenerateTexture(operation, "QueryLod", {}), - GetSwizzle(meta->element)); + return {fmt::format("int(({} * vec2(256)){})", + GenerateTexture(operation, "QueryLod", {}), + GetSwizzle(meta->element)), + Type::Int}; } - return "0"; + return {"0", Type::Int}; } - std::string TexelFetch(Operation operation) { - constexpr std::array constructors = {"int", "ivec2", "ivec3", "ivec4"}; + Expression TexelFetch(Operation operation) { + constexpr std::array constructors = {"int", "ivec2", "ivec3", "ivec4"}; const auto meta = std::get_if(&operation.GetMeta()); ASSERT(meta); UNIMPLEMENTED_IF(meta->sampler.IsArray()); @@ -1552,7 +1649,7 @@ private: expr += constructors.at(operation.GetOperandsCount() - 1); expr += '('; for (std::size_t i = 0; i < count; ++i) { - expr += VisitOperand(operation, i, Type::Int); + expr += VisitOperand(operation, i).AsInt(); const std::size_t next = i + 1; if (next == count) expr += ')'; @@ -1565,7 +1662,7 @@ private: if (meta->lod) { expr += ", "; - expr += CastOperand(Visit(meta->lod), Type::Int); + expr += Visit(meta->lod).AsInt(); } expr += ')'; expr += GetSwizzle(meta->element); @@ -1580,11 +1677,11 @@ private: code.AddLine("float {} = {};", tmp, expr); code.AddLine("#endif"); - return tmp; + return {tmp, Type::Float}; } - std::string ImageStore(Operation operation) { - constexpr std::array constructors{"int(", "ivec2(", "ivec3(", "ivec4("}; + Expression ImageStore(Operation operation) { + constexpr std::array constructors{"int(", "ivec2(", "ivec3(", "ivec4("}; const auto meta{std::get(operation.GetMeta())}; std::string expr = "imageStore("; @@ -1594,7 +1691,7 @@ private: const std::size_t coords_count{operation.GetOperandsCount()}; expr += constructors.at(coords_count - 1); for (std::size_t i = 0; i < coords_count; ++i) { - expr += VisitOperand(operation, i, Type::Int); + expr += VisitOperand(operation, i).AsInt(); if (i + 1 < coords_count) { expr += ", "; } @@ -1605,7 +1702,7 @@ private: UNIMPLEMENTED_IF(values_count != 4); expr += "vec4("; for (std::size_t i = 0; i < values_count; ++i) { - expr += Visit(meta.values.at(i)); + expr += Visit(meta.values.at(i)).AsFloat(); if (i + 1 < values_count) { expr += ", "; } @@ -1616,52 +1713,52 @@ private: return {}; } - std::string Branch(Operation operation) { + Expression Branch(Operation operation) { const auto target = std::get_if(&*operation[0]); UNIMPLEMENTED_IF(!target); - code.AddLine("jmp_to = 0x{:x}u;", target->GetValue()); + code.AddLine("jmp_to = 0x{:X}U;", target->GetValue()); code.AddLine("break;"); return {}; } - std::string BranchIndirect(Operation operation) { - const std::string op_a = VisitOperand(operation, 0, Type::Uint); + Expression BranchIndirect(Operation operation) { + const std::string op_a = VisitOperand(operation, 0).AsUint(); code.AddLine("jmp_to = {};", op_a); code.AddLine("break;"); return {}; } - std::string PushFlowStack(Operation operation) { + Expression PushFlowStack(Operation operation) { const auto stack = std::get(operation.GetMeta()); const auto target = std::get_if(&*operation[0]); UNIMPLEMENTED_IF(!target); - code.AddLine("{}[{}++] = 0x{:x}u;", FlowStackName(stack), FlowStackTopName(stack), + code.AddLine("{}[{}++] = 0x{:X}U;", FlowStackName(stack), FlowStackTopName(stack), target->GetValue()); return {}; } - std::string PopFlowStack(Operation operation) { + Expression PopFlowStack(Operation operation) { const auto stack = std::get(operation.GetMeta()); code.AddLine("jmp_to = {}[--{}];", FlowStackName(stack), FlowStackTopName(stack)); code.AddLine("break;"); return {}; } - std::string Exit(Operation operation) { + Expression Exit(Operation operation) { if (stage != ProgramType::Fragment) { code.AddLine("return;"); return {}; } const auto& used_registers = ir.GetRegisters(); - const auto SafeGetRegister = [&](u32 reg) -> std::string { + const auto SafeGetRegister = [&](u32 reg) -> Expression { // TODO(Rodrigo): Replace with contains once C++20 releases if (used_registers.find(reg) != used_registers.end()) { - return GetRegister(reg); + return {GetRegister(reg), Type::Float}; } - return "0.0f"; + return {"0.0f", Type::Float}; }; UNIMPLEMENTED_IF_MSG(header.ps.omap.sample_mask != 0, "Sample mask write is unimplemented"); @@ -1674,7 +1771,7 @@ private: for (u32 component = 0; component < 4; ++component) { if (header.ps.IsColorComponentOutputEnabled(render_target, component)) { code.AddLine("FragColor{}[{}] = {};", render_target, component, - SafeGetRegister(current_reg)); + SafeGetRegister(current_reg).AsFloat()); ++current_reg; } } @@ -1683,14 +1780,14 @@ private: if (header.ps.omap.depth) { // The depth output is always 2 registers after the last color output, and current_reg // already contains one past the last color register. - code.AddLine("gl_FragDepth = {};", SafeGetRegister(current_reg + 1)); + code.AddLine("gl_FragDepth = {};", SafeGetRegister(current_reg + 1).AsFloat()); } code.AddLine("return;"); return {}; } - std::string Discard(Operation operation) { + Expression Discard(Operation operation) { // Enclose "discard" in a conditional, so that GLSL compilation does not complain // about unexecuted instructions that may follow this. code.AddLine("if (true) {{"); @@ -1701,7 +1798,7 @@ private: return {}; } - std::string EmitVertex(Operation operation) { + Expression EmitVertex(Operation operation) { ASSERT_MSG(stage == ProgramType::Geometry, "EmitVertex is expected to be used in a geometry shader."); @@ -1712,7 +1809,7 @@ private: return {}; } - std::string EndPrimitive(Operation operation) { + Expression EndPrimitive(Operation operation) { ASSERT_MSG(stage == ProgramType::Geometry, "EndPrimitive is expected to be used in a geometry shader."); @@ -1720,59 +1817,59 @@ private: return {}; } - std::string YNegate(Operation operation) { + Expression YNegate(Operation operation) { // Config pack's third value is Y_NEGATE's state. - return "uintBitsToFloat(config_pack[2])"; + return {"config_pack[2]", Type::Uint}; } template - std::string LocalInvocationId(Operation) { - return "utof(gl_LocalInvocationID"s + GetSwizzle(element) + ')'; + Expression LocalInvocationId(Operation) { + return {"gl_LocalInvocationID"s + GetSwizzle(element), Type::Uint}; } template - std::string WorkGroupId(Operation) { - return "utof(gl_WorkGroupID"s + GetSwizzle(element) + ')'; + Expression WorkGroupId(Operation) { + return {"gl_WorkGroupID"s + GetSwizzle(element), Type::Uint}; } - std::string BallotThread(Operation operation) { - const std::string value = VisitOperand(operation, 0, Type::Bool); + Expression BallotThread(Operation operation) { + const std::string value = VisitOperand(operation, 0).AsBool(); if (!device.HasWarpIntrinsics()) { LOG_ERROR(Render_OpenGL, "Nvidia warp intrinsics are not available and its required by a shader"); // Stub on non-Nvidia devices by simulating all threads voting the same as the active // one. - return fmt::format("utof({} ? 0xFFFFFFFFU : 0U)", value); + return {fmt::format("({} ? 0xFFFFFFFFU : 0U)", value), Type::Uint}; } - return fmt::format("utof(ballotThreadNV({}))", value); + return {fmt::format("ballotThreadNV({})", value), Type::Uint}; } - std::string Vote(Operation operation, const char* func) { - const std::string value = VisitOperand(operation, 0, Type::Bool); + Expression Vote(Operation operation, const char* func) { + const std::string value = VisitOperand(operation, 0).AsBool(); if (!device.HasWarpIntrinsics()) { LOG_ERROR(Render_OpenGL, "Nvidia vote intrinsics are not available and its required by a shader"); // Stub with a warp size of one. - return value; + return {value, Type::Bool}; } - return fmt::format("{}({})", func, value); + return {fmt::format("{}({})", func, value), Type::Bool}; } - std::string VoteAll(Operation operation) { + Expression VoteAll(Operation operation) { return Vote(operation, "allThreadsNV"); } - std::string VoteAny(Operation operation) { + Expression VoteAny(Operation operation) { return Vote(operation, "anyThreadNV"); } - std::string VoteEqual(Operation operation) { + Expression VoteEqual(Operation operation) { if (!device.HasWarpIntrinsics()) { LOG_ERROR(Render_OpenGL, "Nvidia vote intrinsics are not available and its required by a shader"); // We must return true here since a stub for a theoretical warp size of 1 will always // return an equal result for all its votes. - return "true"; + return {"true", Type::Bool}; } return Vote(operation, "allThreadsEqualNV"); } @@ -1973,8 +2070,8 @@ private: } std::string GetInternalFlag(InternalFlag flag) const { - constexpr std::array InternalFlagNames = {"zero_flag", "sign_flag", - "carry_flag", "overflow_flag"}; + constexpr std::array InternalFlagNames = {"zero_flag", "sign_flag", "carry_flag", + "overflow_flag"}; const auto index = static_cast(flag); ASSERT(index < static_cast(InternalFlag::Amount)); @@ -2022,24 +2119,16 @@ private: std::string GetCommonDeclarations() { return fmt::format( - "#define MAX_CONSTBUFFER_ELEMENTS {}\n" "#define ftoi floatBitsToInt\n" "#define ftou floatBitsToUint\n" "#define itof intBitsToFloat\n" "#define utof uintBitsToFloat\n\n" - "float fromHalf2(vec2 pair) {{\n" - " return utof(packHalf2x16(pair));\n" - "}}\n\n" - "vec2 toHalf2(float value) {{\n" - " return unpackHalf2x16(ftou(value));\n" - "}}\n\n" - "bvec2 halfFloatNanComparison(bvec2 comparison, vec2 pair1, vec2 pair2) {{\n" + "bvec2 HalfFloatNanComparison(bvec2 comparison, vec2 pair1, vec2 pair2) {{\n" " bvec2 is_nan1 = isnan(pair1);\n" " bvec2 is_nan2 = isnan(pair2);\n" " return bvec2(comparison.x || is_nan1.x || is_nan2.x, comparison.y || is_nan1.y || " "is_nan2.y);\n" - "}}\n", - MAX_CONSTBUFFER_ELEMENTS); + "}}\n\n"); } ProgramResult Decompile(const Device& device, const ShaderIR& ir, ProgramType stage,