/* * Copyright 2011-2015 Branimir Karadzic. All rights reserved. * License: http://www.opensource.org/licenses/BSD-2-Clause */ #include "bgfx_p.h" #include "shader_dxbc.h" namespace bgfx { struct DxbcOpcodeInfo { uint8_t numOperands; uint8_t numValues; }; static const DxbcOpcodeInfo s_dxbcOpcodeInfo[] = { { 3, 0 }, // ADD { 3, 0 }, // AND { 0, 0 }, // BREAK { 1, 0 }, // BREAKC { 0, 0 }, // CALL { 0, 0 }, // CALLC { 1, 0 }, // CASE { 0, 0 }, // CONTINUE { 1, 0 }, // CONTINUEC { 0, 0 }, // CUT { 0, 0 }, // DEFAULT { 2, 0 }, // DERIV_RTX { 2, 0 }, // DERIV_RTY { 1, 0 }, // DISCARD { 3, 0 }, // DIV { 3, 0 }, // DP2 { 3, 0 }, // DP3 { 3, 0 }, // DP4 { 0, 0 }, // ELSE { 0, 0 }, // EMIT { 0, 0 }, // EMITTHENCUT { 0, 0 }, // ENDIF { 0, 0 }, // ENDLOOP { 0, 0 }, // ENDSWITCH { 3, 0 }, // EQ { 2, 0 }, // EXP { 2, 0 }, // FRC { 2, 0 }, // FTOI { 2, 0 }, // FTOU { 3, 0 }, // GE { 3, 0 }, // IADD { 1, 0 }, // IF { 3, 0 }, // IEQ { 3, 0 }, // IGE { 3, 0 }, // ILT { 4, 0 }, // IMAD { 3, 0 }, // IMAX { 3, 0 }, // IMIN { 4, 0 }, // IMUL { 3, 0 }, // INE { 2, 0 }, // INEG { 3, 0 }, // ISHL { 3, 0 }, // ISHR { 2, 0 }, // ITOF { 0, 0 }, // LABEL { 3, 0 }, // LD { 4, 0 }, // LD_MS { 2, 0 }, // LOG { 0, 0 }, // LOOP { 3, 0 }, // LT { 4, 0 }, // MAD { 3, 0 }, // MIN { 3, 0 }, // MAX { 0, 1 }, // CUSTOMDATA { 2, 0 }, // MOV { 4, 0 }, // MOVC { 3, 0 }, // MUL { 3, 0 }, // NE { 0, 0 }, // NOP { 2, 0 }, // NOT { 3, 0 }, // OR { 3, 0 }, // RESINFO { 0, 0 }, // RET { 1, 0 }, // RETC { 2, 0 }, // ROUND_NE { 2, 0 }, // ROUND_NI { 2, 0 }, // ROUND_PI { 2, 0 }, // ROUND_Z { 2, 0 }, // RSQ { 4, 0 }, // SAMPLE { 5, 0 }, // SAMPLE_C { 5, 0 }, // SAMPLE_C_LZ { 5, 0 }, // SAMPLE_L { 6, 0 }, // SAMPLE_D { 5, 0 }, // SAMPLE_B { 2, 0 }, // SQRT { 1, 0 }, // SWITCH { 3, 0 }, // SINCOS { 3, 0 }, // UDIV { 3, 0 }, // ULT { 3, 0 }, // UGE { 4, 0 }, // UMUL { 4, 0 }, // UMAD { 3, 0 }, // UMAX { 3, 0 }, // UMIN { 3, 0 }, // USHR { 2, 0 }, // UTOF { 3, 0 }, // XOR { 1, 1 }, // DCL_RESOURCE { 1, 0 }, // DCL_CONSTANT_BUFFER { 1, 0 }, // DCL_SAMPLER { 1, 1 }, // DCL_INDEX_RANGE { 1, 0 }, // DCL_GS_OUTPUT_PRIMITIVE_TOPOLOGY { 1, 0 }, // DCL_GS_INPUT_PRIMITIVE { 0, 1 }, // DCL_MAX_OUTPUT_VERTEX_COUNT { 1, 0 }, // DCL_INPUT { 1, 1 }, // DCL_INPUT_SGV { 1, 0 }, // DCL_INPUT_SIV { 1, 0 }, // DCL_INPUT_PS { 1, 1 }, // DCL_INPUT_PS_SGV { 1, 1 }, // DCL_INPUT_PS_SIV { 1, 0 }, // DCL_OUTPUT { 1, 0 }, // DCL_OUTPUT_SGV { 1, 1 }, // DCL_OUTPUT_SIV { 0, 1 }, // DCL_TEMPS { 0, 3 }, // DCL_INDEXABLE_TEMP { 0, 0 }, // DCL_GLOBAL_FLAGS { 0, 0 }, // InstrD3D10 { 4, 0 }, // LOD { 4, 0 }, // GATHER4 { 0, 0 }, // SAMPLE_POS { 0, 0 }, // SAMPLE_INFO { 0, 0 }, // InstrD3D10_1 { 0, 0 }, // HS_DECLS { 0, 0 }, // HS_CONTROL_POINT_PHASE { 0, 0 }, // HS_FORK_PHASE { 0, 0 }, // HS_JOIN_PHASE { 0, 0 }, // EMIT_STREAM { 0, 0 }, // CUT_STREAM { 1, 0 }, // EMITTHENCUT_STREAM { 1, 0 }, // INTERFACE_CALL { 0, 0 }, // BUFINFO { 2, 0 }, // DERIV_RTX_COARSE { 2, 0 }, // DERIV_RTX_FINE { 2, 0 }, // DERIV_RTY_COARSE { 2, 0 }, // DERIV_RTY_FINE { 5, 0 }, // GATHER4_C { 5, 0 }, // GATHER4_PO { 0, 0 }, // GATHER4_PO_C { 0, 0 }, // RCP { 0, 0 }, // F32TOF16 { 0, 0 }, // F16TOF32 { 0, 0 }, // UADDC { 0, 0 }, // USUBB { 0, 0 }, // COUNTBITS { 0, 0 }, // FIRSTBIT_HI { 0, 0 }, // FIRSTBIT_LO { 0, 0 }, // FIRSTBIT_SHI { 0, 0 }, // UBFE { 0, 0 }, // IBFE { 5, 0 }, // BFI { 0, 0 }, // BFREV { 5, 0 }, // SWAPC { 0, 0 }, // DCL_STREAM { 1, 0 }, // DCL_FUNCTION_BODY { 0, 0 }, // DCL_FUNCTION_TABLE { 0, 0 }, // DCL_INTERFACE { 0, 0 }, // DCL_INPUT_CONTROL_POINT_COUNT { 0, 0 }, // DCL_OUTPUT_CONTROL_POINT_COUNT { 0, 0 }, // DCL_TESS_DOMAIN { 0, 0 }, // DCL_TESS_PARTITIONING { 0, 0 }, // DCL_TESS_OUTPUT_PRIMITIVE { 0, 0 }, // DCL_HS_MAX_TESSFACTOR { 0, 0 }, // DCL_HS_FORK_PHASE_INSTANCE_COUNT { 0, 0 }, // DCL_HS_JOIN_PHASE_INSTANCE_COUNT { 0, 3 }, // DCL_THREAD_GROUP { 1, 1 }, // DCL_UNORDERED_ACCESS_VIEW_TYPED { 1, 0 }, // DCL_UNORDERED_ACCESS_VIEW_RAW { 1, 1 }, // DCL_UNORDERED_ACCESS_VIEW_STRUCTURED { 1, 1 }, // DCL_THREAD_GROUP_SHARED_MEMORY_RAW { 1, 2 }, // DCL_THREAD_GROUP_SHARED_MEMORY_STRUCTURED { 1, 0 }, // DCL_RESOURCE_RAW { 1, 1 }, // DCL_RESOURCE_STRUCTURED { 3, 0 }, // LD_UAV_TYPED { 3, 0 }, // STORE_UAV_TYPED { 3, 0 }, // LD_RAW { 3, 0 }, // STORE_RAW { 4, 0 }, // LD_STRUCTURED { 4, 0 }, // STORE_STRUCTURED { 3, 0 }, // ATOMIC_AND { 3, 0 }, // ATOMIC_OR { 3, 0 }, // ATOMIC_XOR { 3, 0 }, // ATOMIC_CMP_STORE { 3, 0 }, // ATOMIC_IADD { 3, 0 }, // ATOMIC_IMAX { 3, 0 }, // ATOMIC_IMIN { 3, 0 }, // ATOMIC_UMAX { 3, 0 }, // ATOMIC_UMIN { 2, 0 }, // IMM_ATOMIC_ALLOC { 2, 0 }, // IMM_ATOMIC_CONSUME { 0, 0 }, // IMM_ATOMIC_IADD { 0, 0 }, // IMM_ATOMIC_AND { 0, 0 }, // IMM_ATOMIC_OR { 0, 0 }, // IMM_ATOMIC_XOR { 0, 0 }, // IMM_ATOMIC_EXCH { 0, 0 }, // IMM_ATOMIC_CMP_EXCH { 0, 0 }, // IMM_ATOMIC_IMAX { 0, 0 }, // IMM_ATOMIC_IMIN { 0, 0 }, // IMM_ATOMIC_UMAX { 0, 0 }, // IMM_ATOMIC_UMIN { 0, 0 }, // SYNC { 3, 0 }, // DADD { 3, 0 }, // DMAX { 3, 0 }, // DMIN { 3, 0 }, // DMUL { 3, 0 }, // DEQ { 3, 0 }, // DGE { 3, 0 }, // DLT { 3, 0 }, // DNE { 2, 0 }, // DMOV { 4, 0 }, // DMOVC { 0, 0 }, // DTOF { 0, 0 }, // FTOD { 3, 0 }, // EVAL_SNAPPED { 3, 0 }, // EVAL_SAMPLE_INDEX { 2, 0 }, // EVAL_CENTROID { 0, 1 }, // DCL_GS_INSTANCE_COUNT { 0, 0 }, // ABORT { 0, 0 }, // DEBUG_BREAK { 0, 0 }, // InstrD3D11 { 0, 0 }, // DDIV { 0, 0 }, // DFMA { 0, 0 }, // DRCP { 0, 0 }, // MSAD { 0, 0 }, // DTOI { 0, 0 }, // DTOU { 0, 0 }, // ITOD { 0, 0 }, // UTOD }; BX_STATIC_ASSERT(BX_COUNTOF(s_dxbcOpcodeInfo) == DxbcOpcode::Count); static const char* s_dxbcOpcode[] = { "add", "and", "break", "breakc", "call", "callc", "case", "continue", "continuec", "cut", "default", "deriv_rtx", "deriv_rty", "discard", "div", "dp2", "dp3", "dp4", "else", "emit", "emitthencut", "endif", "endloop", "endswitch", "eq", "exp", "frc", "ftoi", "ftou", "ge", "iadd", "if", "ieq", "ige", "ilt", "imad", "imax", "imin", "imul", "ine", "ineg", "ishl", "ishr", "itof", "label", "ld", "ld_ms", "log", "loop", "lt", "mad", "min", "max", "customdata", "mov", "movc", "mul", "ne", "nop", "not", "or", "resinfo", "ret", "retc", "round_ne", "round_ni", "round_pi", "round_z", "rsq", "sample", "sample_c", "sample_c_lz", "sample_l", "sample_d", "sample_b", "sqrt", "switch", "sincos", "udiv", "ult", "uge", "umul", "umad", "umax", "umin", "ushr", "utof", "xor", "dcl_resource", "dcl_constantbuffer", "dcl_sampler", "dcl_index_range", "dcl_gs_output_primitive_topology", "dcl_gs_input_primitive", "dcl_max_output_vertex_count", "dcl_input", "dcl_input_sgv", "dcl_input_siv", "dcl_input_ps", "dcl_input_ps_sgv", "dcl_input_ps_siv", "dcl_output", "dcl_output_sgv", "dcl_output_siv", "dcl_temps", "dcl_indexable_temp", "dcl_global_flags", NULL, "lod", "gather4", "sample_pos", "sample_info", NULL, "hs_decls", "hs_control_point_phase", "hs_fork_phase", "hs_join_phase", "emit_stream", "cut_stream", "emitthencut_stream", "interface_call", "bufinfo", "deriv_rtx_coarse", "deriv_rtx_fine", "deriv_rty_coarse", "deriv_rty_fine", "gather4_c", "gather4_po", "gather4_po_c", "rcp", "f32tof16", "f16tof32", "uaddc", "usubb", "countbits", "firstbit_hi", "firstbit_lo", "firstbit_shi", "ubfe", "ibfe", "bfi", "bfrev", "swapc", "dcl_stream", "dcl_function_body", "dcl_function_table", "dcl_interface", "dcl_input_control_point_count", "dcl_output_control_point_count", "dcl_tess_domain", "dcl_tess_partitioning", "dcl_tess_output_primitive", "dcl_hs_max_tessfactor", "dcl_hs_fork_phase_instance_count", "dcl_hs_join_phase_instance_count", "dcl_thread_group", "dcl_unordered_access_view_typed", "dcl_unordered_access_view_raw", "dcl_unordered_access_view_structured", "dcl_thread_group_shared_memory_raw", "dcl_thread_group_shared_memory_structured", "dcl_resource_raw", "dcl_resource_structured", "ld_uav_typed", "store_uav_typed", "ld_raw", "store_raw", "ld_structured", "store_structured", "atomic_and", "atomic_or", "atomic_xor", "atomic_cmp_store", "atomic_iadd", "atomic_imax", "atomic_imin", "atomic_umax", "atomic_umin", "imm_atomic_alloc", "imm_atomic_consume", "imm_atomic_iadd", "imm_atomic_and", "imm_atomic_or", "imm_atomic_xor", "imm_atomic_exch", "imm_atomic_cmp_exch", "imm_atomic_imax", "imm_atomic_imin", "imm_atomic_umax", "imm_atomic_umin", "sync", "dadd", "dmax", "dmin", "dmul", "deq", "dge", "dlt", "dne", "dmov", "dmovc", "dtof", "ftod", "eval_snapped", "eval_sample_index", "eval_centroid", "dcl_gs_instance_count", "abort", "debug_break", NULL, "ddiv", "dfma", "drcp", "msad", "dtoi", "dtou", "itod", "utod", }; BX_STATIC_ASSERT(BX_COUNTOF(s_dxbcOpcode) == DxbcOpcode::Count); const char* getName(DxbcOpcode::Enum _opcode) { BX_CHECK(_opcode < DxbcOpcode::Count, "Unknown opcode id %d.", _opcode); return s_dxbcOpcode[_opcode]; } static const char* s_dxbcSrvType[] = { "", // Unknown "Buffer", // Buffer "Texture1D", // Texture1D "Texture2D", // Texture2D "Texture2DMS", // Texture2DMS "Texture3D", // Texture3D "TextureCube", // TextureCube "Texture1DArray", // Texture1DArray "Texture2DArray", // Texture2DArray "Texture2DMSArray", // Texture2DMSArray "TextureCubearray", // TextureCubearray "RawBuffer", // RawBuffer "StructuredBuffer", // StructuredBuffer }; BX_STATIC_ASSERT(BX_COUNTOF(s_dxbcSrvType) == DxbcResourceDim::Count); static const char* s_dxbcInterpolationName[] = { "", "constant", "linear", "linear centroid", "linear noperspective", "linear noperspective centroid", "linear sample", "linear noperspective sample", }; BX_STATIC_ASSERT(BX_COUNTOF(s_dxbcInterpolationName) == DxbcInterpolation::Count); // mesa/src/gallium/state_trackers/d3d1x/d3d1xshader/defs/shortfiles.txt static const char* s_dxbcOperandType[] = { "r", // Temp "v", // Input "o", // Output "x", // TempArray "l", // Imm32 "d", // Imm64 "s", // Sampler "t", // Resource "cb", // ConstantBuffer "icb", // ImmConstantBuffer "label", // Label "vPrim", // PrimitiveID "oDepth", // OutputDepth "null", // Null "rasterizer", // Rasterizer "oMask", // CoverageMask "stream", // Stream "function_body", // FunctionBody "function_table", // FunctionTable "interface", // Interface "function_input", // FunctionInput "function_output", // FunctionOutput "vOutputControlPointID", // OutputControlPointId "vForkInstanceID", // InputForkInstanceId "vJoinInstanceID", // InputJoinInstanceId "vicp", // InputControlPoint "vocp", // OutputControlPoint "vpc", // InputPatchConstant "vDomain", // InputDomainPoint "this", // ThisPointer "u", // UnorderedAccessView "g", // ThreadGroupSharedMemory "vThreadID", // InputThreadId "vThreadGrouID", // InputThreadGroupId "vThreadIDInGroup", // InputThreadIdInGroup "vCoverage", // InputCoverageMask "vThreadIDInGroupFlattened", // InputThreadIdInGroupFlattened "vGSInstanceID", // InputGsInstanceId "oDepthGE", // OutputDepthGreaterEqual "oDepthLE", // OutputDepthLessEqual "vCycleCounter", // CycleCounter }; BX_STATIC_ASSERT(BX_COUNTOF(s_dxbcOperandType) == DxbcOperandType::Count); #define DXBC_MAX_NAME_STRING 512 int32_t readString(bx::ReaderSeekerI* _reader, int64_t _offset, char* _out, uint32_t _max = DXBC_MAX_NAME_STRING) { int64_t oldOffset = bx::seek(_reader); bx::seek(_reader, _offset, bx::Whence::Begin); int32_t size = 0; for (uint32_t ii = 0; ii < _max-1; ++ii) { char ch; size += bx::read(_reader, ch); *_out++ = ch; if ('\0' == ch) { break; } } *_out = '\0'; bx::seek(_reader, oldOffset, bx::Whence::Begin); return size; } inline uint32_t dxbcMixF(uint32_t _b, uint32_t _c, uint32_t _d) { const uint32_t tmp0 = bx::uint32_xor(_c, _d); const uint32_t tmp1 = bx::uint32_and(_b, tmp0); const uint32_t result = bx::uint32_xor(_d, tmp1); return result; } inline uint32_t dxbcMixG(uint32_t _b, uint32_t _c, uint32_t _d) { return dxbcMixF(_d, _b, _c); } inline uint32_t dxbcMixH(uint32_t _b, uint32_t _c, uint32_t _d) { const uint32_t tmp0 = bx::uint32_xor(_b, _c); const uint32_t result = bx::uint32_xor(_d, tmp0); return result; } inline uint32_t dxbcMixI(uint32_t _b, uint32_t _c, uint32_t _d) { const uint32_t tmp0 = bx::uint32_orc(_b, _d); const uint32_t result = bx::uint32_xor(_c, tmp0); return result; } void dxbcHashBlock(const uint32_t* data, uint32_t* hash) { const uint32_t d0 = data[ 0]; const uint32_t d1 = data[ 1]; const uint32_t d2 = data[ 2]; const uint32_t d3 = data[ 3]; const uint32_t d4 = data[ 4]; const uint32_t d5 = data[ 5]; const uint32_t d6 = data[ 6]; const uint32_t d7 = data[ 7]; const uint32_t d8 = data[ 8]; const uint32_t d9 = data[ 9]; const uint32_t d10 = data[10]; const uint32_t d11 = data[11]; const uint32_t d12 = data[12]; const uint32_t d13 = data[13]; const uint32_t d14 = data[14]; const uint32_t d15 = data[15]; uint32_t aa = hash[0]; uint32_t bb = hash[1]; uint32_t cc = hash[2]; uint32_t dd = hash[3]; aa = bb + bx::uint32_rol(aa + dxbcMixF(bb, cc, dd) + d0 + 0xd76aa478, 7); dd = aa + bx::uint32_rol(dd + dxbcMixF(aa, bb, cc) + d1 + 0xe8c7b756, 12); cc = dd + bx::uint32_ror(cc + dxbcMixF(dd, aa, bb) + d2 + 0x242070db, 15); bb = cc + bx::uint32_ror(bb + dxbcMixF(cc, dd, aa) + d3 + 0xc1bdceee, 10); aa = bb + bx::uint32_rol(aa + dxbcMixF(bb, cc, dd) + d4 + 0xf57c0faf, 7); dd = aa + bx::uint32_rol(dd + dxbcMixF(aa, bb, cc) + d5 + 0x4787c62a, 12); cc = dd + bx::uint32_ror(cc + dxbcMixF(dd, aa, bb) + d6 + 0xa8304613, 15); bb = cc + bx::uint32_ror(bb + dxbcMixF(cc, dd, aa) + d7 + 0xfd469501, 10); aa = bb + bx::uint32_rol(aa + dxbcMixF(bb, cc, dd) + d8 + 0x698098d8, 7); dd = aa + bx::uint32_rol(dd + dxbcMixF(aa, bb, cc) + d9 + 0x8b44f7af, 12); cc = dd + bx::uint32_ror(cc + dxbcMixF(dd, aa, bb) + d10 + 0xffff5bb1, 15); bb = cc + bx::uint32_ror(bb + dxbcMixF(cc, dd, aa) + d11 + 0x895cd7be, 10); aa = bb + bx::uint32_rol(aa + dxbcMixF(bb, cc, dd) + d12 + 0x6b901122, 7); dd = aa + bx::uint32_rol(dd + dxbcMixF(aa, bb, cc) + d13 + 0xfd987193, 12); cc = dd + bx::uint32_ror(cc + dxbcMixF(dd, aa, bb) + d14 + 0xa679438e, 15); bb = cc + bx::uint32_ror(bb + dxbcMixF(cc, dd, aa) + d15 + 0x49b40821, 10); aa = bb + bx::uint32_rol(aa + dxbcMixG(bb, cc, dd) + d1 + 0xf61e2562, 5); dd = aa + bx::uint32_rol(dd + dxbcMixG(aa, bb, cc) + d6 + 0xc040b340, 9); cc = dd + bx::uint32_rol(cc + dxbcMixG(dd, aa, bb) + d11 + 0x265e5a51, 14); bb = cc + bx::uint32_ror(bb + dxbcMixG(cc, dd, aa) + d0 + 0xe9b6c7aa, 12); aa = bb + bx::uint32_rol(aa + dxbcMixG(bb, cc, dd) + d5 + 0xd62f105d, 5); dd = aa + bx::uint32_rol(dd + dxbcMixG(aa, bb, cc) + d10 + 0x02441453, 9); cc = dd + bx::uint32_rol(cc + dxbcMixG(dd, aa, bb) + d15 + 0xd8a1e681, 14); bb = cc + bx::uint32_ror(bb + dxbcMixG(cc, dd, aa) + d4 + 0xe7d3fbc8, 12); aa = bb + bx::uint32_rol(aa + dxbcMixG(bb, cc, dd) + d9 + 0x21e1cde6, 5); dd = aa + bx::uint32_rol(dd + dxbcMixG(aa, bb, cc) + d14 + 0xc33707d6, 9); cc = dd + bx::uint32_rol(cc + dxbcMixG(dd, aa, bb) + d3 + 0xf4d50d87, 14); bb = cc + bx::uint32_ror(bb + dxbcMixG(cc, dd, aa) + d8 + 0x455a14ed, 12); aa = bb + bx::uint32_rol(aa + dxbcMixG(bb, cc, dd) + d13 + 0xa9e3e905, 5); dd = aa + bx::uint32_rol(dd + dxbcMixG(aa, bb, cc) + d2 + 0xfcefa3f8, 9); cc = dd + bx::uint32_rol(cc + dxbcMixG(dd, aa, bb) + d7 + 0x676f02d9, 14); bb = cc + bx::uint32_ror(bb + dxbcMixG(cc, dd, aa) + d12 + 0x8d2a4c8a, 12); aa = bb + bx::uint32_rol(aa + dxbcMixH(bb, cc, dd) + d5 + 0xfffa3942, 4); dd = aa + bx::uint32_rol(dd + dxbcMixH(aa, bb, cc) + d8 + 0x8771f681, 11); cc = dd + bx::uint32_rol(cc + dxbcMixH(dd, aa, bb) + d11 + 0x6d9d6122, 16); bb = cc + bx::uint32_ror(bb + dxbcMixH(cc, dd, aa) + d14 + 0xfde5380c, 9); aa = bb + bx::uint32_rol(aa + dxbcMixH(bb, cc, dd) + d1 + 0xa4beea44, 4); dd = aa + bx::uint32_rol(dd + dxbcMixH(aa, bb, cc) + d4 + 0x4bdecfa9, 11); cc = dd + bx::uint32_rol(cc + dxbcMixH(dd, aa, bb) + d7 + 0xf6bb4b60, 16); bb = cc + bx::uint32_ror(bb + dxbcMixH(cc, dd, aa) + d10 + 0xbebfbc70, 9); aa = bb + bx::uint32_rol(aa + dxbcMixH(bb, cc, dd) + d13 + 0x289b7ec6, 4); dd = aa + bx::uint32_rol(dd + dxbcMixH(aa, bb, cc) + d0 + 0xeaa127fa, 11); cc = dd + bx::uint32_rol(cc + dxbcMixH(dd, aa, bb) + d3 + 0xd4ef3085, 16); bb = cc + bx::uint32_ror(bb + dxbcMixH(cc, dd, aa) + d6 + 0x04881d05, 9); aa = bb + bx::uint32_rol(aa + dxbcMixH(bb, cc, dd) + d9 + 0xd9d4d039, 4); dd = aa + bx::uint32_rol(dd + dxbcMixH(aa, bb, cc) + d12 + 0xe6db99e5, 11); cc = dd + bx::uint32_rol(cc + dxbcMixH(dd, aa, bb) + d15 + 0x1fa27cf8, 16); bb = cc + bx::uint32_ror(bb + dxbcMixH(cc, dd, aa) + d2 + 0xc4ac5665, 9); aa = bb + bx::uint32_rol(aa + dxbcMixI(bb, cc, dd) + d0 + 0xf4292244, 6); dd = aa + bx::uint32_rol(dd + dxbcMixI(aa, bb, cc) + d7 + 0x432aff97, 10); cc = dd + bx::uint32_rol(cc + dxbcMixI(dd, aa, bb) + d14 + 0xab9423a7, 15); bb = cc + bx::uint32_ror(bb + dxbcMixI(cc, dd, aa) + d5 + 0xfc93a039, 11); aa = bb + bx::uint32_rol(aa + dxbcMixI(bb, cc, dd) + d12 + 0x655b59c3, 6); dd = aa + bx::uint32_rol(dd + dxbcMixI(aa, bb, cc) + d3 + 0x8f0ccc92, 10); cc = dd + bx::uint32_rol(cc + dxbcMixI(dd, aa, bb) + d10 + 0xffeff47d, 15); bb = cc + bx::uint32_ror(bb + dxbcMixI(cc, dd, aa) + d1 + 0x85845dd1, 11); aa = bb + bx::uint32_rol(aa + dxbcMixI(bb, cc, dd) + d8 + 0x6fa87e4f, 6); dd = aa + bx::uint32_rol(dd + dxbcMixI(aa, bb, cc) + d15 + 0xfe2ce6e0, 10); cc = dd + bx::uint32_rol(cc + dxbcMixI(dd, aa, bb) + d6 + 0xa3014314, 15); bb = cc + bx::uint32_ror(bb + dxbcMixI(cc, dd, aa) + d13 + 0x4e0811a1, 11); aa = bb + bx::uint32_rol(aa + dxbcMixI(bb, cc, dd) + d4 + 0xf7537e82, 6); dd = aa + bx::uint32_rol(dd + dxbcMixI(aa, bb, cc) + d11 + 0xbd3af235, 10); cc = dd + bx::uint32_rol(cc + dxbcMixI(dd, aa, bb) + d2 + 0x2ad7d2bb, 15); bb = cc + bx::uint32_ror(bb + dxbcMixI(cc, dd, aa) + d9 + 0xeb86d391, 11); hash[0] += aa; hash[1] += bb; hash[2] += cc; hash[3] += dd; } // dxbc hash function is slightly modified version of MD5 hash. // https://tools.ietf.org/html/rfc1321 // http://www.efgh.com/software/md5.txt // // Assumption is that data pointer, size are both 4-byte aligned, // and little endian. // void dxbcHash(const void* _data, uint32_t _size, void* _digest) { uint32_t hash[4] = { 0x67452301, 0xefcdab89, 0x98badcfe, 0x10325476, }; const uint32_t* data = (const uint32_t*)_data; for (uint32_t ii = 0, num = _size/64; ii < num; ++ii) { dxbcHashBlock(data, hash); data += 16; } uint32_t last[16]; memset(last, 0, sizeof(last) ); const uint32_t remaining = _size & 0x3f; if (remaining >= 56) { memcpy(&last[0], data, remaining); last[remaining/4] = 0x80; dxbcHashBlock(last, hash); memset(&last[1], 0, 56); } else { memcpy(&last[1], data, remaining); last[1 + remaining/4] = 0x80; } last[ 0] = _size * 8; last[15] = _size * 2 + 1; dxbcHashBlock(last, hash); memcpy(_digest, hash, 16); } int32_t read(bx::ReaderI* _reader, DxbcSubOperand& _subOperand) { uint32_t token; int32_t size = 0; // 0 1 2 3 // 76543210765432107654321076543210 // e222111000nnttttttttssssssssmmoo // ^^ ^ ^ ^ ^ ^ ^ ^-- number of operands // || | | | | | +---- operand mode // || | | | | +------------ operand mode bits // || | | | +-------------------- type // || | | +---------------------- number of addressing modes // || | +------------------------- addressing mode 0 // || +---------------------------- addressing mode 1 // |+------------------------------- addressing mode 2 // +-------------------------------- extended size += bx::read(_reader, token); _subOperand.type = DxbcOperandType::Enum( (token & UINT32_C(0x000ff000) ) >> 12); _subOperand.numAddrModes = uint8_t( (token & UINT32_C(0x00300000) ) >> 20); _subOperand.addrMode = uint8_t( (token & UINT32_C(0x01c00000) ) >> 22); _subOperand.mode = DxbcOperandMode::Enum( (token & UINT32_C(0x0000000c) ) >> 2); _subOperand.modeBits = uint8_t( (token & UINT32_C(0x00000ff0) ) >> 4) & "\x0f\xff\x03\x00"[_subOperand.mode]; _subOperand.num = uint8_t( (token & UINT32_C(0x00000003) ) ); switch (_subOperand.addrMode) { case DxbcOperandAddrMode::Imm32: size += bx::read(_reader, _subOperand.regIndex); break; case DxbcOperandAddrMode::Reg: { DxbcSubOperand subOperand; size += read(_reader, subOperand); } break; case DxbcOperandAddrMode::RegImm32: { size += bx::read(_reader, _subOperand.regIndex); DxbcSubOperand subOperand; size += read(_reader, subOperand); } break; case DxbcOperandAddrMode::RegImm64: { size += bx::read(_reader, _subOperand.regIndex); size += bx::read(_reader, _subOperand.regIndex); DxbcSubOperand subOperand; size += read(_reader, subOperand); } break; default: BX_CHECK(false, "sub operand addressing mode %d", _subOperand.addrMode); break; } return size; } int32_t write(bx::WriterI* _writer, const DxbcSubOperand& _subOperand) { int32_t size = 0; uint32_t token = 0; token |= (_subOperand.type << 12) & UINT32_C(0x000ff000); token |= (_subOperand.numAddrModes << 20) & UINT32_C(0x00300000); token |= (_subOperand.addrMode << 22) & UINT32_C(0x01c00000); token |= (_subOperand.mode << 2) & UINT32_C(0x0000000c); token |= (_subOperand.modeBits << 4) & UINT32_C(0x00000ff0); token |= _subOperand.num & UINT32_C(0x00000003); size += bx::write(_writer, token); switch (_subOperand.addrMode) { case DxbcOperandAddrMode::Imm32: size += bx::write(_writer, _subOperand.regIndex); break; case DxbcOperandAddrMode::Reg: { DxbcSubOperand subOperand; size += write(_writer, subOperand); } break; case DxbcOperandAddrMode::RegImm32: { size += bx::write(_writer, _subOperand.regIndex); DxbcSubOperand subOperand; size += write(_writer, subOperand); } break; case DxbcOperandAddrMode::RegImm64: { size += bx::write(_writer, _subOperand.regIndex); size += bx::write(_writer, _subOperand.regIndex); DxbcSubOperand subOperand; size += write(_writer, subOperand); } break; default: BX_CHECK(false, "sub operand addressing mode %d", _subOperand.addrMode); break; } return size; } int32_t read(bx::ReaderI* _reader, DxbcOperand& _operand) { int32_t size = 0; uint32_t token; size += bx::read(_reader, token); // 0 1 2 3 // 76543210765432107654321076543210 // e222111000nnttttttttssssssssmmoo // ^^ ^ ^ ^ ^ ^ ^ ^-- number of operands // || | | | | | +---- operand mode // || | | | | +------------ operand mode bits // || | | | +-------------------- type // || | | +---------------------- number of addressing modes // || | +------------------------- addressing mode 0 // || +---------------------------- addressing mode 1 // |+------------------------------- addressing mode 2 // +-------------------------------- extended _operand.extended = 0 != (token & UINT32_C(0x80000000) ); _operand.numAddrModes = uint8_t( (token & UINT32_C(0x00300000) ) >> 20); _operand.addrMode[0] = uint8_t( (token & UINT32_C(0x01c00000) ) >> 22); _operand.addrMode[1] = uint8_t( (token & UINT32_C(0x0e000000) ) >> 25); _operand.addrMode[2] = uint8_t( (token & UINT32_C(0x70000000) ) >> 28); _operand.type = DxbcOperandType::Enum( (token & UINT32_C(0x000ff000) ) >> 12); _operand.mode = DxbcOperandMode::Enum( (token & UINT32_C(0x0000000c) ) >> 2); _operand.modeBits = uint8_t( (token & UINT32_C(0x00000ff0) ) >> 4) & "\x0f\xff\x03\x00"[_operand.mode]; _operand.num = uint8_t( (token & UINT32_C(0x00000003) ) ); if (_operand.extended) { size += bx::read(_reader, _operand.extBits); } switch (_operand.type) { case DxbcOperandType::Imm32: _operand.num = 2 == _operand.num ? 4 : _operand.num; for (uint32_t ii = 0; ii < _operand.num; ++ii) { size += bx::read(_reader, _operand.un.imm32[ii]); } break; case DxbcOperandType::Imm64: _operand.num = 2 == _operand.num ? 4 : _operand.num; for (uint32_t ii = 0; ii < _operand.num; ++ii) { size += bx::read(_reader, _operand.un.imm64[ii]); } break; default: break; } for (uint32_t ii = 0; ii < _operand.numAddrModes; ++ii) { switch (_operand.addrMode[ii]) { case DxbcOperandAddrMode::Imm32: size += bx::read(_reader, _operand.regIndex[ii]); break; case DxbcOperandAddrMode::Reg: size += read(_reader, _operand.subOperand[ii]); break; case DxbcOperandAddrMode::RegImm32: size += bx::read(_reader, _operand.regIndex[ii]); size += read(_reader, _operand.subOperand[ii]); break; default: BX_CHECK(false, "operand %d addressing mode %d", ii, _operand.addrMode[ii]); break; } } return size; } int32_t write(bx::WriterI* _writer, const DxbcOperand& _operand) { int32_t size = 0; uint32_t token = 0; token |= _operand.extended ? UINT32_C(0x80000000) : 0; token |= (_operand.numAddrModes << 20) & UINT32_C(0x00300000); token |= (_operand.addrMode[0] << 22) & UINT32_C(0x01c00000); token |= (_operand.addrMode[1] << 25) & UINT32_C(0x0e000000); token |= (_operand.addrMode[2] << 28) & UINT32_C(0x70000000); token |= (_operand.type << 12) & UINT32_C(0x000ff000); token |= (_operand.mode << 2) & UINT32_C(0x0000000c); token |= (4 == _operand.num ? 2 : _operand.num) & UINT32_C(0x00000003); token |= ( (_operand.modeBits & "\x0f\xff\x03\x00"[_operand.mode]) << 4) & UINT32_C(0x00000ff0); size += bx::write(_writer, token); if (_operand.extended) { size += bx::write(_writer, _operand.extBits); } switch (_operand.type) { case DxbcOperandType::Imm32: for (uint32_t ii = 0; ii < _operand.num; ++ii) { size += bx::write(_writer, _operand.un.imm32[ii]); } break; case DxbcOperandType::Imm64: for (uint32_t ii = 0; ii < _operand.num; ++ii) { size += bx::write(_writer, _operand.un.imm64[ii]); } break; default: break; } for (uint32_t ii = 0; ii < _operand.numAddrModes; ++ii) { switch (_operand.addrMode[ii]) { case DxbcOperandAddrMode::Imm32: size += bx::write(_writer, _operand.regIndex[ii]); break; case DxbcOperandAddrMode::Reg: size += write(_writer, _operand.subOperand[ii]); break; case DxbcOperandAddrMode::RegImm32: size += bx::write(_writer, _operand.regIndex[ii]); size += write(_writer, _operand.subOperand[ii]); break; default: BX_CHECK(false, "operand %d addressing mode %d", ii, _operand.addrMode[ii]); break; } } return size; } int32_t read(bx::ReaderI* _reader, DxbcInstruction& _instruction) { uint32_t size = 0; uint32_t token; size += bx::read(_reader, token); // 0 1 2 3 // 76543210765432107654321076543210 // elllllll.............ooooooooooo // ^^ ^----------- opcode // |+------------------------------- length // +-------------------------------- extended _instruction.opcode = DxbcOpcode::Enum( (token & UINT32_C(0x000007ff) ) ); _instruction.length = uint8_t( (token & UINT32_C(0x7f000000) ) >> 24); bool extended = 0 != (token & UINT32_C(0x80000000) ); _instruction.srv = DxbcResourceDim::Unknown; _instruction.samples = 0; _instruction.shadow = false; _instruction.mono = false; _instruction.allowRefactoring = false; _instruction.fp64 = false; _instruction.earlyDepth = false; _instruction.enableBuffers = false; _instruction.skipOptimization = false; _instruction.enableMinPrecision = false; _instruction.enableDoubleExtensions = false; _instruction.enableShaderExtensions = false; _instruction.threadsInGroup = false; _instruction.sharedMemory = false; _instruction.uavGroup = false; _instruction.uavGlobal = false; _instruction.saturate = false; _instruction.testNZ = false; _instruction.retType = DxbcResourceReturnType::Unused; switch (_instruction.opcode) { case DxbcOpcode::CUSTOMDATA: { // uint32_t dataClass; size += bx::read(_reader, _instruction.length); for (uint32_t ii = 0, num = (_instruction.length-2)/4; ii < num; ++ii) { char temp[16]; size += bx::read(_reader, temp, 16); } } return size; case DxbcOpcode::DCL_CONSTANT_BUFFER: // 0 1 2 3 // 76543210765432107654321076543210 // ........ a........... // ^------------ Allow refactoring _instruction.allowRefactoring = 0 != (token & UINT32_C(0x00000800) ); break; case DxbcOpcode::DCL_GLOBAL_FLAGS: // 0 1 2 3 // 76543210765432107654321076543210 // ........ sxmoudfa........... // ^^^^^^^^------------ Allow refactoring // ||||||+------------- FP64 // |||||+-------------- Force early depth/stencil // ||||+--------------- Enable raw and structured buffers // |||+---------------- Skip optimizations // ||+----------------- Enable minimum precision // |+------------------ Enable double extension // +------------------- Enable shader extension _instruction.allowRefactoring = 0 != (token & UINT32_C(0x00000800) ); _instruction.fp64 = 0 != (token & UINT32_C(0x00001000) ); _instruction.earlyDepth = 0 != (token & UINT32_C(0x00002000) ); _instruction.enableBuffers = 0 != (token & UINT32_C(0x00004000) ); _instruction.skipOptimization = 0 != (token & UINT32_C(0x00008000) ); _instruction.enableMinPrecision = 0 != (token & UINT32_C(0x00010000) ); _instruction.enableDoubleExtensions = 0 != (token & UINT32_C(0x00020000) ); _instruction.enableShaderExtensions = 0 != (token & UINT32_C(0x00040000) ); break; case DxbcOpcode::DCL_INPUT_PS: // 0 1 2 3 // 76543210765432107654321076543210 // ........ iiiii........... // ^---------------- Interploation _instruction.interpolation = DxbcInterpolation::Enum( (token & UINT32_C(0x0000f800) ) >> 11); break; case DxbcOpcode::DCL_RESOURCE: // 0 1 2 3 // 76543210765432107654321076543210 // ........ sssssssrrrrr........... // ^ ^---------------- SRV // +----------------------- MSAA samples _instruction.srv = DxbcResourceDim::Enum( (token & UINT32_C(0x0000f800) ) >> 11); _instruction.samples = uint8_t( (token & UINT32_C(0x007f0000) ) >> 16); break; case DxbcOpcode::DCL_SAMPLER: // 0 1 2 3 // 76543210765432107654321076543210 // ........ ms........... // ^^------------ Shadow sampler // +------------- Mono _instruction.shadow = 0 != (token & UINT32_C(0x00000800) ); _instruction.mono = 0 != (token & UINT32_C(0x00001000) ); break; case DxbcOpcode::SYNC: // 0 1 2 3 // 76543210765432107654321076543210 // ........ gust........... // ^^^^------------ Threads in group // ||+------------- Shared memory // |+-------------- UAV group // +--------------- UAV global _instruction.threadsInGroup = 0 != (token & UINT32_C(0x00000800) ); _instruction.sharedMemory = 0 != (token & UINT32_C(0x00001000) ); _instruction.uavGroup = 0 != (token & UINT32_C(0x00002000) ); _instruction.uavGlobal = 0 != (token & UINT32_C(0x00004000) ); break; default: // 0 1 2 3 // 76543210765432107654321076543210 // ........ ppppn stt........... // ^ ^ ^^------------- Resource info return type // | | +-------------- Saturate // | +------------------- Test not zero // +----------------------- Precise mask _instruction.retType = DxbcResourceReturnType::Enum( (token & UINT32_C(0x00001800) ) >> 11); _instruction.saturate = 0 != (token & UINT32_C(0x00002000) ); _instruction.testNZ = 0 != (token & UINT32_C(0x00040000) ); // _instruction.precise = uint8_t( (token & UINT32_C(0x00780000) ) >> 19); break; } _instruction.extended[0] = DxbcInstruction::ExtendedType::Count; for (uint32_t ii = 0; extended; ++ii) { // 0 1 2 3 // 76543210765432107654321076543210 // e..........................ttttt // ^ ^ // | +----- type // +-------------------------------- extended uint32_t extBits; size += bx::read(_reader, extBits); extended = 0 != (extBits & UINT32_C(0x80000000) ); _instruction.extended[ii] = DxbcInstruction::ExtendedType::Enum(extBits & UINT32_C(0x0000001f) ); switch (_instruction.extended[ii]) { case DxbcInstruction::ExtendedType::SampleControls: // 0 1 2 3 // 76543210765432107654321076543210 // . zzzzyyyyxxxx ..... // ^ ^ ^ // | | +------------- x // | +----------------- y // +--------------------- z _instruction.sampleOffsets[0] = uint8_t( (extBits & UINT32_C(0x00001e00) ) >> 9); _instruction.sampleOffsets[1] = uint8_t( (extBits & UINT32_C(0x0001e000) ) >> 13); _instruction.sampleOffsets[2] = uint8_t( (extBits & UINT32_C(0x001e0000) ) >> 17); break; case DxbcInstruction::ExtendedType::ResourceDim: // 0 1 2 3 // 76543210765432107654321076543210 // . ..... // _instruction.resourceTarget = uint8_t( (extBits & UINT32_C(0x000003e0) ) >> 6); _instruction.resourceStride = uint8_t( (extBits & UINT32_C(0x0000f800) ) >> 11); break; case DxbcInstruction::ExtendedType::ResourceReturnType: // 0 1 2 3 // 76543210765432107654321076543210 // . 3333222211110000..... // ^ ^ ^ // | | +------------- x // | +----------------- y // +--------------------- z _instruction.resourceReturnTypes[0] = DxbcResourceReturnType::Enum( (extBits & UINT32_C(0x000001e0) ) >> 6); _instruction.resourceReturnTypes[1] = DxbcResourceReturnType::Enum( (extBits & UINT32_C(0x00001e00) ) >> 9); _instruction.resourceReturnTypes[2] = DxbcResourceReturnType::Enum( (extBits & UINT32_C(0x0001e000) ) >> 13); _instruction.resourceReturnTypes[3] = DxbcResourceReturnType::Enum( (extBits & UINT32_C(0x001e0000) ) >> 17); break; default: break; } } switch (_instruction.opcode) { case DxbcOpcode::DCL_FUNCTION_TABLE: { uint32_t tableId; size += read(_reader, tableId); uint32_t num; size += read(_reader, num); for (uint32_t ii = 0; ii < num; ++ii) { uint32_t bodyId; size += read(_reader, bodyId); } } break; case DxbcOpcode::DCL_INTERFACE: { uint32_t interfaceId; size += read(_reader, interfaceId); uint32_t num; size += read(_reader, num); BX_CHECK(false, "not implemented."); } break; default: break; }; uint32_t currOp = 0; const DxbcOpcodeInfo& info = s_dxbcOpcodeInfo[_instruction.opcode]; _instruction.numOperands = info.numOperands; switch (info.numOperands) { case 6: size += read(_reader, _instruction.operand[currOp++]); case 5: size += read(_reader, _instruction.operand[currOp++]); case 4: size += read(_reader, _instruction.operand[currOp++]); case 3: size += read(_reader, _instruction.operand[currOp++]); case 2: size += read(_reader, _instruction.operand[currOp++]); case 1: size += read(_reader, _instruction.operand[currOp++]); case 0: if (0 < info.numValues) { size += read(_reader, _instruction.value, info.numValues*sizeof(uint32_t) ); } break; default: BX_CHECK(false, "Instruction %s with invalid number of operands %d (numValues %d)." , getName(_instruction.opcode) , info.numOperands , info.numValues ); break; } return size; } int32_t write(bx::WriterI* _writer, const DxbcInstruction& _instruction) { uint32_t token = 0; token |= (_instruction.opcode ) & UINT32_C(0x000007ff); token |= (_instruction.length << 24) & UINT32_C(0x7f000000); token |= DxbcInstruction::ExtendedType::Count != _instruction.extended[0] ? UINT32_C(0x80000000) : 0 ; switch (_instruction.opcode) { // case DxbcOpcode::CUSTOMDATA: // return size; case DxbcOpcode::DCL_CONSTANT_BUFFER: token |= _instruction.allowRefactoring ? UINT32_C(0x00000800) : 0; break; case DxbcOpcode::DCL_GLOBAL_FLAGS: token |= _instruction.allowRefactoring ? UINT32_C(0x00000800) : 0; token |= _instruction.fp64 ? UINT32_C(0x00001000) : 0; token |= _instruction.earlyDepth ? UINT32_C(0x00002000) : 0; token |= _instruction.enableBuffers ? UINT32_C(0x00004000) : 0; token |= _instruction.skipOptimization ? UINT32_C(0x00008000) : 0; token |= _instruction.enableMinPrecision ? UINT32_C(0x00010000) : 0; token |= _instruction.enableDoubleExtensions ? UINT32_C(0x00020000) : 0; token |= _instruction.enableShaderExtensions ? UINT32_C(0x00040000) : 0; break; case DxbcOpcode::DCL_INPUT_PS: token |= (_instruction.interpolation << 11) & UINT32_C(0x0000f800); break; case DxbcOpcode::DCL_RESOURCE: token |= (_instruction.srv << 11) & UINT32_C(0x0000f800); token |= (_instruction.samples << 16) & UINT32_C(0x007f0000); break; case DxbcOpcode::DCL_SAMPLER: token |= _instruction.shadow ? (0x00000800) : 0; token |= _instruction.mono ? (0x00001000) : 0; break; case DxbcOpcode::SYNC: token |= _instruction.threadsInGroup ? UINT32_C(0x00000800) : 0; token |= _instruction.sharedMemory ? UINT32_C(0x00001000) : 0; token |= _instruction.uavGroup ? UINT32_C(0x00002000) : 0; token |= _instruction.uavGlobal ? UINT32_C(0x00004000) : 0; break; default: token |= (_instruction.retType << 11) & UINT32_C(0x00001800); token |= _instruction.saturate ? UINT32_C(0x00002000) : 0; token |= _instruction.testNZ ? UINT32_C(0x00040000) : 0; // _instruction.precise = uint8_t( (token & UINT32_C(0x00780000) ) >> 19); break; } uint32_t size =0; size += bx::write(_writer, token); for (uint32_t ii = 0; ii < _instruction.numOperands; ++ii) { size += write(_writer, _instruction.operand[ii]); } const DxbcOpcodeInfo& info = s_dxbcOpcodeInfo[_instruction.opcode]; if (0 < info.numValues) { size += bx::write(_writer, _instruction.value, info.numValues*sizeof(uint32_t) ); } return size; } int32_t toString(char* _out, int32_t _size, const DxbcInstruction& _instruction) { int32_t size = 0; size += bx::snprintf(&_out[size], bx::uint32_imax(0, _size-size) , "%s%s%s" , getName(_instruction.opcode) , _instruction.saturate ? "_sat" : "" , _instruction.testNZ ? "_nz" : "" ); if (DxbcResourceDim::Unknown != _instruction.srv) { size += bx::snprintf(&_out[size], bx::uint32_imax(0, _size-size) , " %s<%x>" , s_dxbcSrvType[_instruction.srv] , _instruction.value[0] ); } else if (0 < s_dxbcOpcodeInfo[_instruction.opcode].numValues) { size += bx::snprintf(&_out[size], bx::uint32_imax(0, _size-size) , " %d" , _instruction.value[0] ); } for (uint32_t ii = 0; ii < _instruction.numOperands; ++ii) { const DxbcOperand& operand = _instruction.operand[ii]; const bool array = false || 1 < operand.numAddrModes || DxbcOperandAddrMode::Imm32 != operand.addrMode[0] ; size += bx::snprintf(&_out[size], bx::uint32_imax(0, _size-size) , "%s%s%s" , 0 == ii ? " " : ", " , operand.extended ? "*" : "" , s_dxbcOperandType[operand.type] ); switch (operand.type) { case DxbcOperandType::Imm32: case DxbcOperandType::Imm64: for (uint32_t jj = 0; jj < operand.num; ++jj) { union { uint32_t i; float f; } cast = { operand.un.imm32[jj] }; size += bx::snprintf(&_out[size], bx::uint32_imax(0, _size-size) , "%s%f" , 0 == jj ? "(" : ", " , cast.f ); } size += bx::snprintf(&_out[size], bx::uint32_imax(0, _size-size) , ")" ); break; default: break; } const uint32_t first = DxbcOperandAddrMode::RegImm32 == operand.addrMode[0] ? 0 : 1; if (0 == first) { size += bx::snprintf(&_out[size], bx::uint32_imax(0, _size-size) , "[" ); } else { size += bx::snprintf(&_out[size], bx::uint32_imax(0, _size-size) , "%d%s" , operand.regIndex[0] , array ? "[" : "" ); } for (uint32_t jj = first; jj < operand.numAddrModes; ++jj) { switch (operand.addrMode[jj]) { case DxbcOperandAddrMode::Imm32: size += bx::snprintf(&_out[size], bx::uint32_imax(0, _size-size) , "%d" , operand.regIndex[jj] ); break; case DxbcOperandAddrMode::Reg: size += bx::snprintf(&_out[size], bx::uint32_imax(0, _size-size) , "%s%d" , s_dxbcOperandType[operand.subOperand[jj].type] , operand.regIndex[jj] ); break; case DxbcOperandAddrMode::RegImm32: size += bx::snprintf(&_out[size], bx::uint32_imax(0, _size-size) , "%d + %s%d" , operand.regIndex[jj] , s_dxbcOperandType[operand.subOperand[jj].type] , operand.regIndex[jj] ); break; default: break; } } size += bx::snprintf(&_out[size], bx::uint32_imax(0, _size-size) , "%s" , array ? "]" : "" ); switch (operand.mode) { case DxbcOperandMode::Mask: if (0xf > operand.modeBits && 0 < operand.modeBits) { size += bx::snprintf(&_out[size], bx::uint32_imax(0, _size-size) , ".%s%s%s%s" , 0 == (operand.modeBits & 1) ? "" : "x" , 0 == (operand.modeBits & 2) ? "" : "y" , 0 == (operand.modeBits & 4) ? "" : "z" , 0 == (operand.modeBits & 8) ? "" : "w" ); } break; case DxbcOperandMode::Swizzle: if (0xe4 != operand.modeBits) { size += bx::snprintf(&_out[size], bx::uint32_imax(0, _size-size) , ".%c%c%c%c" , "xyzw"[(operand.modeBits )&0x3] , "xyzw"[(operand.modeBits>>2)&0x3] , "xyzw"[(operand.modeBits>>4)&0x3] , "xyzw"[(operand.modeBits>>6)&0x3] ); } break; case DxbcOperandMode::Scalar: size += bx::snprintf(&_out[size], bx::uint32_imax(0, _size-size) , ".%c" , "xyzw"[operand.modeBits] ); break; default: break; } } return size; } int32_t read(bx::ReaderSeekerI* _reader, DxbcSignature& _signature) { int32_t size = 0; int64_t offset = bx::seek(_reader); uint32_t num; size += bx::read(_reader, num); size += bx::read(_reader, _signature.key); for (uint32_t ii = 0; ii < num; ++ii) { DxbcSignature::Element element; uint32_t nameOffset; size += bx::read(_reader, nameOffset); char name[DXBC_MAX_NAME_STRING]; readString(_reader, offset + nameOffset, name); element.name = name; size += bx::read(_reader, element.semanticIndex); size += bx::read(_reader, element.valueType); size += bx::read(_reader, element.componentType); size += bx::read(_reader, element.registerIndex); size += bx::read(_reader, element.mask); size += bx::read(_reader, element.readWriteMask); size += bx::read(_reader, element.stream); // padding uint8_t padding; size += bx::read(_reader, padding); _signature.elements.push_back(element); } return size; } int32_t write(bx::WriterI* _writer, const DxbcSignature& _signature) { int32_t size = 0; const uint32_t num = uint32_t(_signature.elements.size() ); size += bx::write(_writer, num); size += bx::write(_writer, _signature.key); typedef stl::unordered_map NameOffsetMap; NameOffsetMap nom; const uint8_t pad = 0; uint32_t nameOffset = num * 24 + 8; for (uint32_t ii = 0; ii < num; ++ii) { const DxbcSignature::Element& element = _signature.elements[ii]; NameOffsetMap::iterator it = nom.find(element.name); if (it == nom.end() ) { nom.insert(stl::make_pair(element.name, nameOffset) ); size += bx::write(_writer, nameOffset); nameOffset += uint32_t(element.name.size() + 1); } else { size += bx::write(_writer, it->second); } size += bx::write(_writer, element.semanticIndex); size += bx::write(_writer, element.valueType); size += bx::write(_writer, element.componentType); size += bx::write(_writer, element.registerIndex); size += bx::write(_writer, element.mask); size += bx::write(_writer, element.readWriteMask); size += bx::write(_writer, element.stream); size += bx::write(_writer, pad); } uint32_t len = 0; for (uint32_t ii = 0; ii < num; ++ii) { const DxbcSignature::Element& element = _signature.elements[ii]; NameOffsetMap::iterator it = nom.find(element.name); if (it != nom.end() ) { nom.erase(it); size += bx::write(_writer, element.name.c_str(), uint32_t(element.name.size() + 1) ); len += uint32_t(element.name.size() + 1); } } // align 4 bytes size += bx::writeRep(_writer, 0xab, (len+3)/4*4 - len); return size; } int32_t read(bx::ReaderSeekerI* _reader, DxbcShader& _shader) { int32_t size = 0; size += bx::read(_reader, _shader.version); uint32_t bcLength; size += bx::read(_reader, bcLength); uint32_t len = (bcLength-2)*sizeof(uint32_t); _shader.byteCode.resize(len); size += bx::read(_reader, _shader.byteCode.data(), len); return size; } int32_t write(bx::WriterI* _writer, const DxbcShader& _shader) { const uint32_t len = uint32_t(_shader.byteCode.size() ); const uint32_t bcLength = len / sizeof(uint32_t) + 2; int32_t size = 0; size += bx::write(_writer, _shader.version); size += bx::write(_writer, bcLength); size += bx::write(_writer, _shader.byteCode.data(), len); return size; } #define DXBC_CHUNK_HEADER BX_MAKEFOURCC('D', 'X', 'B', 'C') #define DXBC_CHUNK_SHADER BX_MAKEFOURCC('S', 'H', 'D', 'R') #define DXBC_CHUNK_INPUT_SIGNATURE BX_MAKEFOURCC('I', 'S', 'G', 'N') #define DXBC_CHUNK_OUTPUT_SIGNATURE BX_MAKEFOURCC('O', 'S', 'G', 'N') int32_t read(bx::ReaderSeekerI* _reader, DxbcContext& _dxbc) { int32_t size = 0; size += bx::read(_reader, _dxbc.header); for (uint32_t ii = 0; ii < _dxbc.header.numChunks; ++ii) { bx::seek(_reader, sizeof(DxbcContext::Header) + ii*sizeof(uint32_t), bx::Whence::Begin); uint32_t chunkOffset; size += bx::read(_reader, chunkOffset); bx::seek(_reader, chunkOffset, bx::Whence::Begin); uint32_t fourcc; size += bx::read(_reader, fourcc); uint32_t chunkSize; size += bx::read(_reader, chunkSize); switch (fourcc) { case DXBC_CHUNK_SHADER: case BX_MAKEFOURCC('S', 'H', 'E', 'X'): size += read(_reader, _dxbc.shader); break; case BX_MAKEFOURCC('I', 'S', 'G', '1'): case DXBC_CHUNK_INPUT_SIGNATURE: size += read(_reader, _dxbc.inputSignature); break; case BX_MAKEFOURCC('O', 'S', 'G', '1'): case BX_MAKEFOURCC('O', 'S', 'G', '5'): case DXBC_CHUNK_OUTPUT_SIGNATURE: size += read(_reader, _dxbc.outputSignature); break; case BX_MAKEFOURCC('R', 'D', 'E', 'F'): case BX_MAKEFOURCC('I', 'F', 'C', 'E'): case BX_MAKEFOURCC('P', 'C', 'S', 'G'): case BX_MAKEFOURCC('S', 'T', 'A', 'T'): case BX_MAKEFOURCC('S', 'F', 'I', '0'): case BX_MAKEFOURCC('P', 'S', 'O', '1'): case BX_MAKEFOURCC('P', 'S', 'O', '2'): size += chunkSize; break; default: size += chunkSize; BX_CHECK(false, "UNKNOWN FOURCC %c%c%c%c %d" , ( (char*)&fourcc)[0] , ( (char*)&fourcc)[1] , ( (char*)&fourcc)[2] , ( (char*)&fourcc)[3] , size ); break; } } return size; } int32_t write(bx::WriterSeekerI* _writer, const DxbcContext& _dxbc) { int32_t size = 0; int64_t dxbcOffset = bx::seek(_writer); size += bx::write(_writer, DXBC_CHUNK_HEADER); size += bx::writeRep(_writer, 0, 16); size += bx::write(_writer, UINT32_C(1) ); int64_t sizeOffset = bx::seek(_writer); size += bx::writeRep(_writer, 0, 4); uint32_t numChunks = 3; size += bx::write(_writer, numChunks); int64_t chunksOffsets = bx::seek(_writer); size += bx::writeRep(_writer, 0, numChunks*sizeof(uint32_t) ); uint32_t chunkOffset[3]; uint32_t chunkSize[3]; chunkOffset[0] = uint32_t(bx::seek(_writer) - dxbcOffset); size += write(_writer, DXBC_CHUNK_INPUT_SIGNATURE); size += write(_writer, UINT32_C(0) ); chunkSize[0] = write(_writer, _dxbc.inputSignature); chunkOffset[1] = uint32_t(bx::seek(_writer) - dxbcOffset); size += write(_writer, DXBC_CHUNK_OUTPUT_SIGNATURE); size += write(_writer, UINT32_C(0) ); chunkSize[1] = write(_writer, _dxbc.outputSignature); chunkOffset[2] = uint32_t(bx::seek(_writer) - dxbcOffset); size += write(_writer, DXBC_CHUNK_SHADER); size += write(_writer, UINT32_C(0) ); chunkSize[2] = write(_writer, _dxbc.shader); size += 0 + chunkSize[0] + chunkSize[1] + chunkSize[2] ; int64_t eof = bx::seek(_writer); bx::seek(_writer, sizeOffset, bx::Whence::Begin); bx::write(_writer, size); bx::seek(_writer, chunksOffsets, bx::Whence::Begin); bx::write(_writer, chunkOffset, sizeof(chunkOffset) ); for (uint32_t ii = 0; ii < BX_COUNTOF(chunkOffset); ++ii) { bx::seek(_writer, chunkOffset[ii]+4, bx::Whence::Begin); bx::write(_writer, chunkSize[ii]); } bx::seek(_writer, eof, bx::Whence::Begin); return size; } void parse(const DxbcShader& _src, DxbcParseFn _fn, void* _userData) { bx::MemoryReader reader(_src.byteCode.data(), uint32_t(_src.byteCode.size() ) ); for (uint32_t token = 0, numTokens = uint32_t(_src.byteCode.size() / sizeof(uint32_t) ); token < numTokens;) { DxbcInstruction instruction; uint32_t size = read(&reader, instruction); BX_CHECK(size/4 == instruction.length, "read %d, expected %d", size/4, instruction.length); BX_UNUSED(size); _fn(token * sizeof(uint32_t), instruction, _userData); token += instruction.length; } } void filter(DxbcShader& _dst, const DxbcShader& _src, DxbcFilterFn _fn, void* _userData) { bx::MemoryReader reader(_src.byteCode.data(), uint32_t(_src.byteCode.size() ) ); bx::CrtAllocator r; bx::MemoryBlock mb(&r); bx::MemoryWriter writer(&mb); for (uint32_t token = 0, numTokens = uint32_t(_src.byteCode.size() / sizeof(uint32_t) ); token < numTokens;) { DxbcInstruction instruction; uint32_t size = read(&reader, instruction); BX_CHECK(size/4 == instruction.length, "read %d, expected %d", size/4, instruction.length); BX_UNUSED(size); _fn(instruction, _userData); write(&writer, instruction); token += instruction.length; } uint8_t* data = (uint8_t*)mb.more(); uint32_t size = uint32_t(bx::getSize(&writer) ); _dst.byteCode.reserve(size); memcpy(_dst.byteCode.data(), data, size); } } // namespace bgfx