#include "dxbc_decoder.h" namespace dxvk { const uint32_t* DxbcCodeSlice::ptrAt(uint32_t id) const { if (m_ptr + id >= m_end) throw DxvkError("DxbcCodeSlice: End of stream"); return m_ptr + id; } uint32_t DxbcCodeSlice::at(uint32_t id) const { if (m_ptr + id >= m_end) throw DxvkError("DxbcCodeSlice: End of stream"); return m_ptr[id]; } uint32_t DxbcCodeSlice::read() { if (m_ptr >= m_end) throw DxvkError("DxbcCodeSlice: End of stream"); return *(m_ptr++); } DxbcCodeSlice DxbcCodeSlice::take(uint32_t n) const { if (m_ptr + n > m_end) throw DxvkError("DxbcCodeSlice: End of stream"); return DxbcCodeSlice(m_ptr, m_ptr + n); } DxbcCodeSlice DxbcCodeSlice::skip(uint32_t n) const { if (m_ptr + n > m_end) throw DxvkError("DxbcCodeSlice: End of stream"); return DxbcCodeSlice(m_ptr + n, m_end); } void DxbcDecodeContext::decodeInstruction(DxbcCodeSlice& code) { const uint32_t token0 = code.at(0); // Initialize the instruction structure. Some of these values // may not get written otherwise while decoding the instruction. m_instruction.op = static_cast(bit::extract(token0, 0, 10)); m_instruction.opClass = DxbcInstClass::Undefined; m_instruction.sampleControls = { 0, 0, 0 }; m_instruction.dstCount = 0; m_instruction.srcCount = 0; m_instruction.immCount = 0; m_instruction.dst = m_dstOperands.data(); m_instruction.src = m_srcOperands.data(); m_instruction.imm = m_immOperands.data(); m_instruction.customDataType = DxbcCustomDataClass::Comment; m_instruction.customDataSize = 0; m_instruction.customData = nullptr; // Reset the index pointer, which may still contain // a non-zero value from the previous iteration m_indexId = 0; // Instruction length, in DWORDs. This includes the token // itself and any other prefix that an instruction may have. uint32_t length = 0; if (m_instruction.op == DxbcOpcode::CustomData) { length = code.at(1); this->decodeCustomData(code.take(length)); } else { length = bit::extract(token0, 24, 30); this->decodeOperation(code.take(length)); } // Advance the caller's slice to the next token so that // they can make consecutive calls to decodeInstruction() code = code.skip(length); } void DxbcDecodeContext::decodeCustomData(DxbcCodeSlice code) { const uint32_t blockLength = code.at(1); if (blockLength < 2) { Logger::err("DxbcDecodeContext: Invalid custom data block"); return; } // Custom data blocks have their own instruction class m_instruction.op = DxbcOpcode::CustomData; m_instruction.opClass = DxbcInstClass::CustomData; // We'll point into the code buffer rather than making a copy m_instruction.customDataType = static_cast( bit::extract(code.at(0), 11, 31)); m_instruction.customDataSize = blockLength - 2; m_instruction.customData = code.ptrAt(2); } void DxbcDecodeContext::decodeOperation(DxbcCodeSlice code) { uint32_t token = code.read(); // Result modifiers, which are applied to common ALU ops m_instruction.modifiers.saturate = !!bit::extract(token, 13, 13); m_instruction.modifiers.precise = !!bit::extract(token, 19, 22); // Opcode controls. It will depend on the // opcode itself which ones are valid. m_instruction.controls = DxbcShaderOpcodeControls(token); // Process extended opcode tokens while (bit::extract(token, 31, 31)) { token = code.read(); const DxbcExtOpcode extOpcode = static_cast(bit::extract(token, 0, 5)); switch (extOpcode) { case DxbcExtOpcode::SampleControls: { struct { int u : 4; int v : 4; int w : 4; } aoffimmi; aoffimmi.u = bit::extract(token, 9, 12); aoffimmi.v = bit::extract(token, 13, 16); aoffimmi.w = bit::extract(token, 17, 20); // Four-bit signed numbers, sign-extend them m_instruction.sampleControls.u = aoffimmi.u; m_instruction.sampleControls.v = aoffimmi.v; m_instruction.sampleControls.w = aoffimmi.w; } break; case DxbcExtOpcode::ResourceDim: case DxbcExtOpcode::ResourceReturnType: break; // part of resource description default: Logger::warn(str::format( "DxbcDecodeContext: Unhandled extended opcode: ", extOpcode)); } } // Retrieve the instruction format in order to parse the // operands. Doing this mostly automatically means that // the compiler can rely on the operands being valid. const DxbcInstFormat format = dxbcInstructionFormat(m_instruction.op); m_instruction.opClass = format.instructionClass; for (uint32_t i = 0; i < format.operandCount; i++) this->decodeOperand(code, format.operands[i]); } void DxbcDecodeContext::decodeComponentSelection(DxbcRegister& reg, uint32_t token) { // Pick the correct component selection mode based on the // component count. We'll simplify this here so that the // compiler can assume that everything is a 4D vector. reg.componentCount = static_cast(bit::extract(token, 0, 1)); switch (reg.componentCount) { // No components - used for samplers etc. case DxbcComponentCount::Component0: reg.mask = DxbcRegMask(false, false, false, false); reg.swizzle = DxbcRegSwizzle(0, 0, 0, 0); break; // One component - used for immediates // and a few built-in registers. case DxbcComponentCount::Component1: reg.mask = DxbcRegMask(true, false, false, false); reg.swizzle = DxbcRegSwizzle(0, 0, 0, 0); break; // Four components - everything else. This requires us // to actually parse the component selection mode. case DxbcComponentCount::Component4: { const DxbcRegMode componentMode = static_cast(bit::extract(token, 2, 3)); switch (componentMode) { // Write mask for destination operands case DxbcRegMode::Mask: reg.mask = bit::extract(token, 4, 7); reg.swizzle = DxbcRegSwizzle(0, 1, 2, 3); break; // Swizzle for source operands (including resources) case DxbcRegMode::Swizzle: reg.mask = DxbcRegMask(true, true, true, true); reg.swizzle = DxbcRegSwizzle( bit::extract(token, 4, 5), bit::extract(token, 6, 7), bit::extract(token, 8, 9), bit::extract(token, 10, 11)); break; // Selection of one component. We can generate both a // mask and a swizzle for this so that the compiler // won't have to deal with this case specifically. case DxbcRegMode::Select1: { const uint32_t n = bit::extract(token, 4, 5); reg.mask = DxbcRegMask(n == 0, n == 1, n == 2, n == 3); reg.swizzle = DxbcRegSwizzle(n, n, n, n); } break; default: Logger::warn("DxbcDecodeContext: Invalid component selection mode"); } } break; default: Logger::warn("DxbcDecodeContext: Invalid component count"); } } void DxbcDecodeContext::decodeOperandExtensions(DxbcCodeSlice& code, DxbcRegister& reg, uint32_t token) { while (bit::extract(token, 31, 31)) { token = code.read(); // Type of the extended operand token const DxbcOperandExt extTokenType = static_cast(bit::extract(token, 0, 5)); switch (extTokenType) { // Operand modifiers, which are used to manipulate the // value of a source operand during the load operation case DxbcOperandExt::OperandModifier: reg.modifiers = bit::extract(token, 6, 13); break; default: Logger::warn(str::format( "DxbcDecodeContext: Unhandled extended operand token: ", extTokenType)); } } } void DxbcDecodeContext::decodeOperandImmediates(DxbcCodeSlice& code, DxbcRegister& reg) { if (reg.type == DxbcOperandType::Imm32 || reg.type == DxbcOperandType::Imm64) { switch (reg.componentCount) { // This is commonly used if only one vector // component is involved in an operation case DxbcComponentCount::Component1: { reg.imm.u32_1 = code.read(); } break; // Typical four-component vector case DxbcComponentCount::Component4: { reg.imm.u32_4[0] = code.read(); reg.imm.u32_4[1] = code.read(); reg.imm.u32_4[2] = code.read(); reg.imm.u32_4[3] = code.read(); } break; default: Logger::warn("DxbcDecodeContext: Invalid component count for immediate operand"); } } } void DxbcDecodeContext::decodeOperandIndex(DxbcCodeSlice& code, DxbcRegister& reg, uint32_t token) { reg.idxDim = bit::extract(token, 20, 21); for (uint32_t i = 0; i < reg.idxDim; i++) { // An index can be encoded in various different ways const DxbcOperandIndexRepresentation repr = static_cast( bit::extract(token, 22 + 3 * i, 24 + 3 * i)); switch (repr) { case DxbcOperandIndexRepresentation::Imm32: reg.idx[i].offset = static_cast(code.read()); reg.idx[i].relReg = nullptr; break; case DxbcOperandIndexRepresentation::Relative: reg.idx[i].offset = 0; reg.idx[i].relReg = &m_indices.at(m_indexId); this->decodeRegister(code, m_indices.at(m_indexId++), DxbcScalarType::Sint32); break; case DxbcOperandIndexRepresentation::Imm32Relative: reg.idx[i].offset = static_cast(code.read()); reg.idx[i].relReg = &m_indices.at(m_indexId); this->decodeRegister(code, m_indices.at(m_indexId++), DxbcScalarType::Sint32); break; default: Logger::warn(str::format( "DxbcDecodeContext: Unhandled index representation: ", repr)); } } } void DxbcDecodeContext::decodeRegister(DxbcCodeSlice& code, DxbcRegister& reg, DxbcScalarType type) { const uint32_t token = code.read(); reg.type = static_cast(bit::extract(token, 12, 19)); reg.dataType = type; reg.modifiers = 0; reg.idxDim = 0; for (uint32_t i = 0; i < DxbcMaxRegIndexDim; i++) { reg.idx[i].relReg = nullptr; reg.idx[i].offset = 0; } this->decodeComponentSelection(reg, token); this->decodeOperandExtensions(code, reg, token); this->decodeOperandImmediates(code, reg); this->decodeOperandIndex(code, reg, token); } void DxbcDecodeContext::decodeImm32(DxbcCodeSlice& code, DxbcImmediate& imm, DxbcScalarType type) { imm.u32 = code.read(); } void DxbcDecodeContext::decodeOperand(DxbcCodeSlice& code, const DxbcInstOperandFormat& format) { switch (format.kind) { case DxbcOperandKind::DstReg: { const uint32_t operandId = m_instruction.dstCount++; this->decodeRegister(code, m_dstOperands.at(operandId), format.type); } break; case DxbcOperandKind::SrcReg: { const uint32_t operandId = m_instruction.srcCount++; this->decodeRegister(code, m_srcOperands.at(operandId), format.type); } break; case DxbcOperandKind::Imm32: { const uint32_t operandId = m_instruction.immCount++; this->decodeImm32(code, m_immOperands.at(operandId), format.type); } break; default: throw DxvkError("DxbcDecodeContext: Invalid operand format"); } } }