//===-- SOPInstructions.td - SOP Instruction Definitions ------------------===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// def GPRIdxMode : CustomOperand; class SOP_Pseudo pattern=[]> : InstSI, SIMCInstr { let isPseudo = 1; let isCodeGenOnly = 1; let Size = 4; string Mnemonic = opName; string AsmOperands = asmOps; bits<1> has_sdst = 0; } //===----------------------------------------------------------------------===// // SOP1 Instructions //===----------------------------------------------------------------------===// class SOP1_Pseudo pattern=[]> : SOP_Pseudo { let mayLoad = 0; let mayStore = 0; let hasSideEffects = 0; let SALU = 1; let SOP1 = 1; let SchedRW = [WriteSALU]; let UseNamedOperandTable = 1; bits<1> has_src0 = 1; let has_sdst = 1; } class SOP1_Real op, SOP1_Pseudo ps, string real_name = ps.Mnemonic> : InstSI , Enc32 { let SALU = 1; let SOP1 = 1; let isPseudo = 0; let isCodeGenOnly = 0; let Size = 4; // copy relevant pseudo op flags let SubtargetPredicate = ps.SubtargetPredicate; let AsmMatchConverter = ps.AsmMatchConverter; let SchedRW = ps.SchedRW; let mayLoad = ps.mayLoad; let mayStore = ps.mayStore; let isTerminator = ps.isTerminator; let isReturn = ps.isReturn; let isCall = ps.isCall; let isBranch = ps.isBranch; let isBarrier = ps.isBarrier; let Uses = ps.Uses; let Defs = ps.Defs; // encoding bits<7> sdst; bits<8> src0; let Inst{7-0} = !if(ps.has_src0, src0, ?); let Inst{15-8} = op; let Inst{22-16} = !if(ps.has_sdst, sdst, ?); let Inst{31-23} = 0x17d; //encoding; } class SOP1_32 pattern=[], bit tied_in = 0> : SOP1_Pseudo < opName, (outs SReg_32:$sdst), !if(tied_in, (ins SSrc_b32:$src0, SReg_32:$sdst_in), (ins SSrc_b32:$src0)), "$sdst, $src0", pattern> { let Constraints = !if(tied_in, "$sdst = $sdst_in", ""); } // Only register input allowed. class SOP1_32R pattern=[]> : SOP1_Pseudo < opName, (outs SReg_32:$sdst), (ins SReg_32:$src0), "$sdst, $src0", pattern>; // 32-bit input, no output. class SOP1_0_32 pattern = []> : SOP1_Pseudo < opName, (outs), (ins SSrc_b32:$src0), "$src0", pattern> { let has_sdst = 0; } // Special case for movreld where sdst is treated as a use operand. class SOP1_32_movreld pattern=[]> : SOP1_Pseudo < opName, (outs), (ins SReg_32:$sdst, SSrc_b32:$src0), "$sdst, $src0", pattern>; // Special case for movreld where sdst is treated as a use operand. class SOP1_64_movreld pattern=[]> : SOP1_Pseudo < opName, (outs), (ins SReg_64:$sdst, SSrc_b64:$src0), "$sdst, $src0", pattern >; class SOP1_0_32R pattern = []> : SOP1_Pseudo < opName, (outs), (ins SReg_32:$src0), "$src0", pattern> { let has_sdst = 0; } class SOP1_64 pattern=[]> : SOP1_Pseudo < opName, (outs SReg_64:$sdst), (ins SSrc_b64:$src0), "$sdst, $src0", pattern >; // Only register input allowed. class SOP1_64R pattern=[]> : SOP1_Pseudo < opName, (outs SReg_64:$sdst), (ins SReg_64:$src0), "$sdst, $src0", pattern >; // 64-bit input, 32-bit output. class SOP1_32_64 pattern=[]> : SOP1_Pseudo < opName, (outs SReg_32:$sdst), (ins SSrc_b64:$src0), "$sdst, $src0", pattern >; // 32-bit input, 64-bit output. class SOP1_64_32 pattern=[], bit tied_in = 0> : SOP1_Pseudo < opName, (outs SReg_64:$sdst), !if(tied_in, (ins SSrc_b32:$src0, SReg_64:$sdst_in), (ins SSrc_b32:$src0)), "$sdst, $src0", pattern> { let Constraints = !if(tied_in, "$sdst = $sdst_in", ""); } // no input, 64-bit output. class SOP1_64_0 pattern=[]> : SOP1_Pseudo < opName, (outs SReg_64:$sdst), (ins), "$sdst", pattern> { let has_src0 = 0; } // 64-bit input, no output class SOP1_1 pattern=[]> : SOP1_Pseudo < opName, (outs), (ins SReg_64:$src0), "$src0", pattern> { let has_sdst = 0; } class UniformUnaryFrag : PatFrag < (ops node:$src0), (Op $src0), [{ return !N->isDivergent(); }]> { // This check is unnecessary as it's captured by the result register // bank constraint. // // FIXME: Should add a way for the emitter to recognize this is a // trivially true predicate to eliminate the check. let GISelPredicateCode = [{return true;}]; } class UniformBinFrag : PatFrag < (ops node:$src0, node:$src1), (Op $src0, $src1), [{ return !N->isDivergent(); }]> { // This check is unnecessary as it's captured by the result register // bank constraint. // // FIXME: Should add a way for the emitter to recognize this is a // trivially true predicate to eliminate the check. let GISelPredicateCode = [{return true;}]; } class UniformTernaryFrag : PatFrag < (ops node:$src0, node:$src1, node:$src2), (Op $src0, $src1, $src2), [{ return !N->isDivergent(); }]> { // This check is unnecessary as it's captured by the result register // bank constraint. // // FIXME: Should add a way for the emitter to recognize this is a // trivially true predicate to eliminate the check. let GISelPredicateCode = [{return true;}]; } class DivergentBinFrag : PatFrag < (ops node:$src0, node:$src1), (Op $src0, $src1), [{ return N->isDivergent(); }]> { // This check is unnecessary as it's captured by the result register // bank constraint. // // FIXME: Should add a way for the emitter to recognize this is a // trivially true predicate to eliminate the check. let GISelPredicateCode = [{return true;}]; } let isMoveImm = 1 in { let isReMaterializable = 1, isAsCheapAsAMove = 1 in { def S_MOV_B32 : SOP1_32 <"s_mov_b32">; def S_MOV_B64 : SOP1_64 <"s_mov_b64">; } // End isReMaterializable = 1 let Uses = [SCC] in { def S_CMOV_B32 : SOP1_32 <"s_cmov_b32">; def S_CMOV_B64 : SOP1_64 <"s_cmov_b64">; } // End Uses = [SCC] } // End isMoveImm = 1 // Variant of S_MOV_B32 used for reading from volatile registers like // SRC_POPS_EXITING_WAVE_ID. let hasSideEffects = 1 in def S_MOV_B32_sideeffects : SOP1_32 <"s_mov_b32">; let Defs = [SCC] in { def S_NOT_B32 : SOP1_32 <"s_not_b32", [(set i32:$sdst, (UniformUnaryFrag i32:$src0))] >; def S_NOT_B64 : SOP1_64 <"s_not_b64", [(set i64:$sdst, (UniformUnaryFrag i64:$src0))] >; def S_WQM_B32 : SOP1_32 <"s_wqm_b32", [(set i32:$sdst, (int_amdgcn_s_wqm i32:$src0))]>; def S_WQM_B64 : SOP1_64 <"s_wqm_b64", [(set i64:$sdst, (int_amdgcn_s_wqm i64:$src0))]>; } // End Defs = [SCC] let WaveSizePredicate = isWave32 in { def : GCNPat < (int_amdgcn_wqm_vote i1:$src0), (S_WQM_B32 SSrc_b32:$src0) >; } let WaveSizePredicate = isWave64 in { def : GCNPat < (int_amdgcn_wqm_vote i1:$src0), (S_WQM_B64 SSrc_b64:$src0) >; } let isReMaterializable = 1, isAsCheapAsAMove = 1 in { def S_BREV_B32 : SOP1_32 <"s_brev_b32", [(set i32:$sdst, (UniformUnaryFrag i32:$src0))] >; def S_BREV_B64 : SOP1_64 <"s_brev_b64", [(set i64:$sdst, (UniformUnaryFrag i64:$src0))] >; } // End isReMaterializable = 1, isAsCheapAsAMove = 1 let Defs = [SCC] in { def S_BCNT0_I32_B32 : SOP1_32 <"s_bcnt0_i32_b32">; def S_BCNT0_I32_B64 : SOP1_32_64 <"s_bcnt0_i32_b64">; def S_BCNT1_I32_B32 : SOP1_32 <"s_bcnt1_i32_b32", [(set i32:$sdst, (UniformUnaryFrag i32:$src0))] >; def S_BCNT1_I32_B64 : SOP1_32_64 <"s_bcnt1_i32_b64", [(set i32:$sdst, (UniformUnaryFrag i64:$src0))] >; } // End Defs = [SCC] let isReMaterializable = 1 in { def S_FF0_I32_B32 : SOP1_32 <"s_ff0_i32_b32">; def S_FF0_I32_B64 : SOP1_32_64 <"s_ff0_i32_b64">; def S_FF1_I32_B64 : SOP1_32_64 <"s_ff1_i32_b64", [(set i32:$sdst, (UniformUnaryFrag i64:$src0))] >; def S_FF1_I32_B32 : SOP1_32 <"s_ff1_i32_b32", [(set i32:$sdst, (UniformUnaryFrag i32:$src0))] >; def S_FLBIT_I32_B32 : SOP1_32 <"s_flbit_i32_b32", [(set i32:$sdst, (UniformUnaryFrag i32:$src0))] >; def S_FLBIT_I32_B64 : SOP1_32_64 <"s_flbit_i32_b64", [(set i32:$sdst, (UniformUnaryFrag i64:$src0))] >; def S_FLBIT_I32 : SOP1_32 <"s_flbit_i32", [(set i32:$sdst, (UniformUnaryFrag i32:$src0))] >; def S_FLBIT_I32_I64 : SOP1_32_64 <"s_flbit_i32_i64">; def S_SEXT_I32_I8 : SOP1_32 <"s_sext_i32_i8", [(set i32:$sdst, (UniformSextInreg i32:$src0))] >; def S_SEXT_I32_I16 : SOP1_32 <"s_sext_i32_i16", [(set i32:$sdst, (UniformSextInreg i32:$src0))] >; } // End isReMaterializable = 1 def S_BITSET0_B32 : SOP1_32 <"s_bitset0_b32", [], 1>; def S_BITSET0_B64 : SOP1_64_32 <"s_bitset0_b64", [], 1>; def S_BITSET1_B32 : SOP1_32 <"s_bitset1_b32", [], 1>; def S_BITSET1_B64 : SOP1_64_32 <"s_bitset1_b64", [], 1>; def S_GETPC_B64 : SOP1_64_0 <"s_getpc_b64">; // PSEUDO includes a workaround for a hardware anomaly where some ASICs // zero-extend the result from 48 bits instead of sign-extending. let isReMaterializable = 1 in def S_GETPC_B64_pseudo : SOP1_64_0 <"s_getpc_b64", [(set i64:$sdst, (int_amdgcn_s_getpc))] >; let isTerminator = 1, isBarrier = 1, SchedRW = [WriteBranch] in { let isBranch = 1, isIndirectBranch = 1 in { def S_SETPC_B64 : SOP1_1 <"s_setpc_b64">; } // End isBranch = 1, isIndirectBranch = 1 let isReturn = 1 in { // Define variant marked as return rather than branch. def S_SETPC_B64_return : SOP1_1<"">; } } // End isTerminator = 1, isBarrier = 1 let isCall = 1 in { def S_SWAPPC_B64 : SOP1_64 <"s_swappc_b64" >; } def S_RFE_B64 : SOP1_1 <"s_rfe_b64">; let hasSideEffects = 1, Uses = [EXEC], Defs = [EXEC, SCC] in { def S_AND_SAVEEXEC_B64 : SOP1_64 <"s_and_saveexec_b64">; def S_OR_SAVEEXEC_B64 : SOP1_64 <"s_or_saveexec_b64">; def S_XOR_SAVEEXEC_B64 : SOP1_64 <"s_xor_saveexec_b64">; def S_ANDN2_SAVEEXEC_B64 : SOP1_64 <"s_andn2_saveexec_b64">; def S_ORN2_SAVEEXEC_B64 : SOP1_64 <"s_orn2_saveexec_b64">; def S_NAND_SAVEEXEC_B64 : SOP1_64 <"s_nand_saveexec_b64">; def S_NOR_SAVEEXEC_B64 : SOP1_64 <"s_nor_saveexec_b64">; def S_XNOR_SAVEEXEC_B64 : SOP1_64 <"s_xnor_saveexec_b64">; } // End hasSideEffects = 1, Uses = [EXEC], Defs = [EXEC, SCC] def S_QUADMASK_B32 : SOP1_32 <"s_quadmask_b32", [(set i32:$sdst, (int_amdgcn_s_quadmask i32:$src0))]>; def S_QUADMASK_B64 : SOP1_64 <"s_quadmask_b64", [(set i64:$sdst, (int_amdgcn_s_quadmask i64:$src0))]>; let Uses = [M0] in { def S_MOVRELS_B32 : SOP1_32R <"s_movrels_b32">; def S_MOVRELS_B64 : SOP1_64R <"s_movrels_b64">; def S_MOVRELD_B32 : SOP1_32_movreld <"s_movreld_b32">; def S_MOVRELD_B64 : SOP1_64_movreld <"s_movreld_b64">; } // End Uses = [M0] let SubtargetPredicate = isGFX6GFX7GFX8GFX9 in { def S_CBRANCH_JOIN : SOP1_0_32R <"s_cbranch_join">; } // End SubtargetPredicate = isGFX6GFX7GFX8GFX9 let Defs = [SCC] in { def S_ABS_I32 : SOP1_32 <"s_abs_i32", [(set i32:$sdst, (UniformUnaryFrag i32:$src0))] >; } // End Defs = [SCC] let SubtargetPredicate = HasVGPRIndexMode in { def S_SET_GPR_IDX_IDX : SOP1_0_32<"s_set_gpr_idx_idx"> { let Uses = [M0, MODE]; let Defs = [M0, MODE]; } } let SubtargetPredicate = isGFX9Plus in { let hasSideEffects = 1, Defs = [EXEC, SCC], Uses = [EXEC] in { def S_ANDN1_SAVEEXEC_B64 : SOP1_64<"s_andn1_saveexec_b64">; def S_ORN1_SAVEEXEC_B64 : SOP1_64<"s_orn1_saveexec_b64">; def S_ANDN1_WREXEC_B64 : SOP1_64<"s_andn1_wrexec_b64">; def S_ANDN2_WREXEC_B64 : SOP1_64<"s_andn2_wrexec_b64">; } // End hasSideEffects = 1, Defs = [EXEC, SCC], Uses = [EXEC] let isReMaterializable = 1 in def S_BITREPLICATE_B64_B32 : SOP1_64_32<"s_bitreplicate_b64_b32", [(set i64:$sdst, (int_amdgcn_s_bitreplicate i32:$src0))]>; } // End SubtargetPredicate = isGFX9Plus let SubtargetPredicate = isGFX10Plus in { let hasSideEffects = 1, Defs = [EXEC, SCC], Uses = [EXEC] in { def S_AND_SAVEEXEC_B32 : SOP1_32<"s_and_saveexec_b32">; def S_OR_SAVEEXEC_B32 : SOP1_32<"s_or_saveexec_b32">; def S_XOR_SAVEEXEC_B32 : SOP1_32<"s_xor_saveexec_b32">; def S_ANDN2_SAVEEXEC_B32 : SOP1_32<"s_andn2_saveexec_b32">; def S_ORN2_SAVEEXEC_B32 : SOP1_32<"s_orn2_saveexec_b32">; def S_NAND_SAVEEXEC_B32 : SOP1_32<"s_nand_saveexec_b32">; def S_NOR_SAVEEXEC_B32 : SOP1_32<"s_nor_saveexec_b32">; def S_XNOR_SAVEEXEC_B32 : SOP1_32<"s_xnor_saveexec_b32">; def S_ANDN1_SAVEEXEC_B32 : SOP1_32<"s_andn1_saveexec_b32">; def S_ORN1_SAVEEXEC_B32 : SOP1_32<"s_orn1_saveexec_b32">; def S_ANDN1_WREXEC_B32 : SOP1_32<"s_andn1_wrexec_b32">; def S_ANDN2_WREXEC_B32 : SOP1_32<"s_andn2_wrexec_b32">; } // End hasSideEffects = 1, Defs = [EXEC, SCC], Uses = [EXEC] let Uses = [M0] in { def S_MOVRELSD_2_B32 : SOP1_32<"s_movrelsd_2_b32">; } // End Uses = [M0] } // End SubtargetPredicate = isGFX10Plus let SubtargetPredicate = isGFX11Plus in { let hasSideEffects = 1 in { // For s_sendmsg_rtn_* the src0 field encodes the message type directly; it // is not an SGPR number. def S_SENDMSG_RTN_B32 : SOP1_Pseudo< "s_sendmsg_rtn_b32", (outs SReg_32:$sdst), (ins SendMsg:$src0), "$sdst, $src0", [(set i32:$sdst, (int_amdgcn_s_sendmsg_rtn timm:$src0))] >; def S_SENDMSG_RTN_B64 : SOP1_Pseudo< "s_sendmsg_rtn_b64", (outs SReg_64:$sdst), (ins SendMsg:$src0), "$sdst, $src0", [(set i64:$sdst, (int_amdgcn_s_sendmsg_rtn timm:$src0))] >; } } // End SubtargetPredicate = isGFX11Plus class SOP1_F32_Inst : SOP1_32 vt1:$src0))]>; let SubtargetPredicate = HasSALUFloatInsts, Uses = [MODE], SchedRW = [WriteSFPU], isReMaterializable = 1 in { def S_CVT_F32_I32 : SOP1_F32_Inst<"s_cvt_f32_i32", sint_to_fp, f32, i32>; def S_CVT_F32_U32 : SOP1_F32_Inst<"s_cvt_f32_u32", uint_to_fp, f32, i32>; let mayRaiseFPException = 1 in { def S_CVT_I32_F32 : SOP1_F32_Inst<"s_cvt_i32_f32", fp_to_sint, i32, f32>; def S_CVT_U32_F32 : SOP1_F32_Inst<"s_cvt_u32_f32", fp_to_uint, i32, f32>; def S_CVT_F32_F16 : SOP1_F32_Inst<"s_cvt_f32_f16", fpextend, f32, f16>; def S_CVT_HI_F32_F16 : SOP1_32<"s_cvt_hi_f32_f16">; def S_CEIL_F32 : SOP1_F32_Inst<"s_ceil_f32", fceil>; def S_FLOOR_F32 : SOP1_F32_Inst<"s_floor_f32", ffloor>; def S_TRUNC_F32 : SOP1_F32_Inst<"s_trunc_f32", ftrunc>; def S_RNDNE_F32 : SOP1_F32_Inst<"s_rndne_f32", froundeven>; let FPDPRounding = 1 in def S_CVT_F16_F32 : SOP1_F32_Inst<"s_cvt_f16_f32", fpround, f16, f32>; def S_CEIL_F16 : SOP1_F32_Inst<"s_ceil_f16", fceil, f16>; def S_FLOOR_F16 : SOP1_F32_Inst<"s_floor_f16", ffloor, f16>; def S_TRUNC_F16 : SOP1_F32_Inst<"s_trunc_f16", ftrunc, f16>; def S_RNDNE_F16 : SOP1_F32_Inst<"s_rndne_f16", froundeven, f16>; } // End mayRaiseFPException = 1 } // End SubtargetPredicate = HasSALUFloatInsts, Uses = [MODE] // SchedRW = [WriteSFPU], isReMaterializable = 1 let hasSideEffects = 1 in { let has_sdst = 0 in { let Uses = [M0] in { def S_BARRIER_SIGNAL_M0 : SOP1_Pseudo <"s_barrier_signal m0", (outs), (ins), "", [(int_amdgcn_s_barrier_signal_var M0)]>{ let SchedRW = [WriteBarrier]; let isConvergent = 1; } def S_BARRIER_SIGNAL_ISFIRST_M0 : SOP1_Pseudo <"s_barrier_signal_isfirst m0", (outs), (ins), "", [(set SCC, (int_amdgcn_s_barrier_signal_isfirst_var M0))]>{ let Defs = [SCC]; let SchedRW = [WriteBarrier]; let isConvergent = 1; } def S_BARRIER_INIT_M0 : SOP1_Pseudo <"s_barrier_init m0", (outs), (ins), "", []>{ let SchedRW = [WriteBarrier]; let isConvergent = 1; } def S_BARRIER_INIT_IMM : SOP1_Pseudo <"s_barrier_init", (outs), (ins SplitBarrier:$src0), "$src0", []>{ let SchedRW = [WriteBarrier]; let isConvergent = 1; } def S_BARRIER_JOIN_M0 : SOP1_Pseudo <"s_barrier_join m0", (outs), (ins), "", []>{ let SchedRW = [WriteBarrier]; let isConvergent = 1; } def S_WAKEUP_BARRIER_M0 : SOP1_Pseudo <"s_wakeup_barrier m0", (outs), (ins), "", []>{ let SchedRW = [WriteBarrier]; let isConvergent = 1; } } // End Uses = [M0] def S_BARRIER_SIGNAL_IMM : SOP1_Pseudo <"s_barrier_signal", (outs), (ins SplitBarrier:$src0), "$src0", [(int_amdgcn_s_barrier_signal timm:$src0)]>{ let SchedRW = [WriteBarrier]; let isConvergent = 1; } def S_BARRIER_SIGNAL_ISFIRST_IMM : SOP1_Pseudo <"s_barrier_signal_isfirst", (outs), (ins SplitBarrier:$src0), "$src0", [(set SCC, (int_amdgcn_s_barrier_signal_isfirst timm:$src0))]>{ let Defs = [SCC]; let SchedRW = [WriteBarrier]; let isConvergent = 1; } def S_BARRIER_JOIN_IMM : SOP1_Pseudo <"s_barrier_join", (outs), (ins SplitBarrier:$src0), "$src0", []>{ let SchedRW = [WriteBarrier]; let isConvergent = 1; } def S_WAKEUP_BARRIER_IMM : SOP1_Pseudo <"s_wakeup_barrier", (outs), (ins SplitBarrier:$src0), "$src0", []>{ let SchedRW = [WriteBarrier]; let isConvergent = 1; } } // End has_sdst = 0 def S_GET_BARRIER_STATE_IMM : SOP1_Pseudo <"s_get_barrier_state", (outs SSrc_b32:$sdst), (ins SplitBarrier:$src0), "$sdst, $src0", []>{ let SchedRW = [WriteBarrier]; let isConvergent = 1; } def S_GET_BARRIER_STATE_M0 : SOP1_Pseudo <"s_get_barrier_state $sdst, m0", (outs SSrc_b32:$sdst), (ins), "", []>{ let Uses = [M0]; let SchedRW = [WriteBarrier]; let isConvergent = 1; } } // End hasSideEffects = 1 //===----------------------------------------------------------------------===// // SOP2 Instructions //===----------------------------------------------------------------------===// class SOP2_Pseudo pattern=[]> : SOP_Pseudo { let mayLoad = 0; let mayStore = 0; let hasSideEffects = 0; let SALU = 1; let SOP2 = 1; let SchedRW = [WriteSALU]; let UseNamedOperandTable = 1; let has_sdst = 1; // Pseudo instructions have no encodings, but adding this field here allows // us to do: // let sdst = xxx in { // for multiclasses that include both real and pseudo instructions. // field bits<7> sdst = 0; } class SOP2_Real : InstSI { let SALU = 1; let SOP2 = 1; let isPseudo = 0; let isCodeGenOnly = 0; // copy relevant pseudo op flags let SubtargetPredicate = ps.SubtargetPredicate; let AsmMatchConverter = ps.AsmMatchConverter; let UseNamedOperandTable = ps.UseNamedOperandTable; let TSFlags = ps.TSFlags; let SchedRW = ps.SchedRW; let mayLoad = ps.mayLoad; let mayStore = ps.mayStore; let Constraints = ps.Constraints; let DisableEncoding = ps.DisableEncoding; let Uses = ps.Uses; let Defs = ps.Defs; // encoding bits<7> sdst; bits<8> src0; bits<8> src1; bits<32> imm; } class SOP2_Real32 op, SOP_Pseudo ps, string name = ps.Mnemonic> : SOP2_Real, Enc32 { let Inst{7-0} = src0; let Inst{15-8} = src1; let Inst{22-16} = !if(ps.has_sdst, sdst, ?); let Inst{29-23} = op; let Inst{31-30} = 0x2; // encoding } class SOP2_Real64 op, SOP_Pseudo ps, string name = ps.Mnemonic> : SOP2_Real, Enc64 { let Inst{7-0} = src0; let Inst{15-8} = src1; let Inst{22-16} = !if(ps.has_sdst, sdst, ?); let Inst{29-23} = op; let Inst{31-30} = 0x2; // encoding let Inst{63-32} = imm; } class SOP2_F16 pattern=[]> : SOP2_Pseudo < opName, (outs SReg_32:$sdst), (ins SSrc_f16:$src0, SSrc_f16:$src1), "$sdst, $src0, $src1", pattern >; class SOP2_32 pattern=[]> : SOP2_Pseudo < opName, (outs SReg_32:$sdst), (ins SSrc_b32:$src0, SSrc_b32:$src1), "$sdst, $src0, $src1", pattern >; class SOP2_F32 pattern=[]> : SOP2_Pseudo < opName, (outs SReg_32:$sdst), (ins SSrc_f32:$src0, SSrc_f32:$src1), "$sdst, $src0, $src1", pattern >; class SOP2_64 pattern=[]> : SOP2_Pseudo < opName, (outs SReg_64:$sdst), (ins SSrc_b64:$src0, SSrc_b64:$src1), "$sdst, $src0, $src1", pattern >; class SOP2_64_32 pattern=[]> : SOP2_Pseudo < opName, (outs SReg_64:$sdst), (ins SSrc_b64:$src0, SSrc_b32:$src1), "$sdst, $src0, $src1", pattern >; class SOP2_64_32_32 pattern=[]> : SOP2_Pseudo < opName, (outs SReg_64:$sdst), (ins SSrc_b32:$src0, SSrc_b32:$src1), "$sdst, $src0, $src1", pattern >; let Defs = [SCC] in { // Carry out goes to SCC let isCommutable = 1 in { def S_ADD_U32 : SOP2_32 <"s_add_u32">; def S_ADD_I32 : SOP2_32 <"s_add_i32", [(set i32:$sdst, (UniformBinFrag SSrc_b32:$src0, SSrc_b32:$src1))] >; } // End isCommutable = 1 def S_SUB_U32 : SOP2_32 <"s_sub_u32">; def S_SUB_I32 : SOP2_32 <"s_sub_i32", [(set i32:$sdst, (UniformBinFrag SSrc_b32:$src0, SSrc_b32:$src1))] >; let Uses = [SCC] in { // Carry in comes from SCC let isCommutable = 1 in { def S_ADDC_U32 : SOP2_32 <"s_addc_u32", [(set i32:$sdst, (UniformBinFrag (i32 SSrc_b32:$src0), (i32 SSrc_b32:$src1)))]>; } // End isCommutable = 1 def S_SUBB_U32 : SOP2_32 <"s_subb_u32", [(set i32:$sdst, (UniformBinFrag (i32 SSrc_b32:$src0), (i32 SSrc_b32:$src1)))]>; } // End Uses = [SCC] let isCommutable = 1 in { def S_MIN_I32 : SOP2_32 <"s_min_i32", [(set i32:$sdst, (UniformBinFrag i32:$src0, i32:$src1))] >; def S_MIN_U32 : SOP2_32 <"s_min_u32", [(set i32:$sdst, (UniformBinFrag i32:$src0, i32:$src1))] >; def S_MAX_I32 : SOP2_32 <"s_max_i32", [(set i32:$sdst, (UniformBinFrag i32:$src0, i32:$src1))] >; def S_MAX_U32 : SOP2_32 <"s_max_u32", [(set i32:$sdst, (UniformBinFrag i32:$src0, i32:$src1))] >; } // End isCommutable = 1 } // End Defs = [SCC] let SubtargetPredicate = isGFX12Plus in { def S_ADD_U64 : SOP2_64<"s_add_u64">{ let isCommutable = 1; } def S_SUB_U64 : SOP2_64<"s_sub_u64">; def S_MUL_U64 : SOP2_64 <"s_mul_u64", [(set i64:$sdst, (UniformBinFrag i64:$src0, i64:$src1))]> { let isCommutable = 1; } // The higher 32-bits of the inputs contain the sign extension bits. def S_MUL_I64_I32_PSEUDO : SPseudoInstSI < (outs SReg_64:$sdst), (ins SSrc_b64:$src0, SSrc_b64:$src1) >; // The higher 32-bits of the inputs are zero. def S_MUL_U64_U32_PSEUDO : SPseudoInstSI < (outs SReg_64:$sdst), (ins SSrc_b64:$src0, SSrc_b64:$src1) >; } // End SubtargetPredicate = isGFX12Plus let Uses = [SCC] in { def S_CSELECT_B32 : SOP2_32 <"s_cselect_b32">; def S_CSELECT_B64 : SOP2_64 <"s_cselect_b64">; } // End Uses = [SCC] let Defs = [SCC] in { let isCommutable = 1 in { def S_AND_B32 : SOP2_32 <"s_and_b32", [(set i32:$sdst, (UniformBinFrag i32:$src0, i32:$src1))] >; def S_AND_B64 : SOP2_64 <"s_and_b64", [(set i64:$sdst, (UniformBinFrag i64:$src0, i64:$src1))] >; def S_OR_B32 : SOP2_32 <"s_or_b32", [(set i32:$sdst, (UniformBinFrag i32:$src0, i32:$src1))] >; def S_OR_B64 : SOP2_64 <"s_or_b64", [(set i64:$sdst, (UniformBinFrag i64:$src0, i64:$src1))] >; def S_XOR_B32 : SOP2_32 <"s_xor_b32", [(set i32:$sdst, (UniformBinFrag i32:$src0, i32:$src1))] >; def S_XOR_B64 : SOP2_64 <"s_xor_b64", [(set i64:$sdst, (UniformBinFrag i64:$src0, i64:$src1))] >; def S_XNOR_B32 : SOP2_32 <"s_xnor_b32", [(set i32:$sdst, (UniformUnaryFrag (xor_oneuse i32:$src0, i32:$src1)))] >; def S_XNOR_B64 : SOP2_64 <"s_xnor_b64", [(set i64:$sdst, (UniformUnaryFrag (xor_oneuse i64:$src0, i64:$src1)))] >; def S_NAND_B32 : SOP2_32 <"s_nand_b32", [(set i32:$sdst, (UniformUnaryFrag (and_oneuse i32:$src0, i32:$src1)))] >; def S_NAND_B64 : SOP2_64 <"s_nand_b64", [(set i64:$sdst, (UniformUnaryFrag (and_oneuse i64:$src0, i64:$src1)))] >; def S_NOR_B32 : SOP2_32 <"s_nor_b32", [(set i32:$sdst, (UniformUnaryFrag (or_oneuse i32:$src0, i32:$src1)))] >; def S_NOR_B64 : SOP2_64 <"s_nor_b64", [(set i64:$sdst, (UniformUnaryFrag (or_oneuse i64:$src0, i64:$src1)))] >; } // End isCommutable = 1 // There are also separate patterns for types other than i32 def S_ANDN2_B32 : SOP2_32 <"s_andn2_b32", [(set i32:$sdst, (UniformBinFrag i32:$src0, (not i32:$src1)))] >; def S_ANDN2_B64 : SOP2_64 <"s_andn2_b64", [(set i64:$sdst, (UniformBinFrag i64:$src0, (not i64:$src1)))] >; def S_ORN2_B32 : SOP2_32 <"s_orn2_b32", [(set i32:$sdst, (UniformBinFrag i32:$src0, (not i32:$src1)))] >; def S_ORN2_B64 : SOP2_64 <"s_orn2_b64", [(set i64:$sdst, (UniformBinFrag i64:$src0, (not i64:$src1)))] >; } // End Defs = [SCC] // Use added complexity so these patterns are preferred to the VALU patterns. let AddedComplexity = 1 in { let Defs = [SCC] in { // TODO: b64 versions require VOP3 change since v_lshlrev_b64 is VOP3 def S_LSHL_B32 : SOP2_32 <"s_lshl_b32", [(set SReg_32:$sdst, (UniformBinFrag (i32 SSrc_b32:$src0), (i32 SSrc_b32:$src1)))] >; def S_LSHL_B64 : SOP2_64_32 <"s_lshl_b64", [(set SReg_64:$sdst, (UniformBinFrag (i64 SSrc_b64:$src0), (i32 SSrc_b32:$src1)))] >; def S_LSHR_B32 : SOP2_32 <"s_lshr_b32", [(set SReg_32:$sdst, (UniformBinFrag (i32 SSrc_b32:$src0), (i32 SSrc_b32:$src1)))] >; def S_LSHR_B64 : SOP2_64_32 <"s_lshr_b64", [(set SReg_64:$sdst, (UniformBinFrag (i64 SSrc_b64:$src0), (i32 SSrc_b32:$src1)))] >; def S_ASHR_I32 : SOP2_32 <"s_ashr_i32", [(set SReg_32:$sdst, (UniformBinFrag (i32 SSrc_b32:$src0), (i32 SSrc_b32:$src1)))] >; def S_ASHR_I64 : SOP2_64_32 <"s_ashr_i64", [(set SReg_64:$sdst, (UniformBinFrag (i64 SSrc_b64:$src0), (i32 SSrc_b32:$src1)))] >; } // End Defs = [SCC] let isReMaterializable = 1 in { def S_BFM_B32 : SOP2_32 <"s_bfm_b32", [(set i32:$sdst, (UniformBinFrag i32:$src0, i32:$src1))]>; def S_BFM_B64 : SOP2_64_32_32 <"s_bfm_b64">; def S_MUL_I32 : SOP2_32 <"s_mul_i32", [(set i32:$sdst, (UniformBinFrag i32:$src0, i32:$src1))]> { let isCommutable = 1; } } // End isReMaterializable = 1 } // End AddedComplexity = 1 let Defs = [SCC] in { def S_BFE_U32 : SOP2_32 <"s_bfe_u32">; def S_BFE_I32 : SOP2_32 <"s_bfe_i32">; def S_BFE_U64 : SOP2_64_32 <"s_bfe_u64">; def S_BFE_I64 : SOP2_64_32 <"s_bfe_i64">; } // End Defs = [SCC] def S_CBRANCH_G_FORK : SOP2_Pseudo < "s_cbranch_g_fork", (outs), (ins SCSrc_b64:$src0, SCSrc_b64:$src1), "$src0, $src1" > { let has_sdst = 0; let SubtargetPredicate = isGFX6GFX7GFX8GFX9; } let Defs = [SCC] in { def S_ABSDIFF_I32 : SOP2_32 <"s_absdiff_i32">; } // End Defs = [SCC] let SubtargetPredicate = isGFX8GFX9 in { def S_RFE_RESTORE_B64 : SOP2_Pseudo < "s_rfe_restore_b64", (outs), (ins SSrc_b64:$src0, SSrc_b32:$src1), "$src0, $src1" > { let hasSideEffects = 1; let has_sdst = 0; } } let SubtargetPredicate = isGFX9Plus in { let isReMaterializable = 1 in { def S_PACK_LL_B32_B16 : SOP2_32<"s_pack_ll_b32_b16">; def S_PACK_LH_B32_B16 : SOP2_32<"s_pack_lh_b32_b16">; def S_PACK_HH_B32_B16 : SOP2_32<"s_pack_hh_b32_b16">; } // End isReMaterializable = 1 let Defs = [SCC] in { def S_LSHL1_ADD_U32 : SOP2_32<"s_lshl1_add_u32", [(set i32:$sdst, (shl1_add SSrc_b32:$src0, SSrc_b32:$src1))] >; def S_LSHL2_ADD_U32 : SOP2_32<"s_lshl2_add_u32", [(set i32:$sdst, (shl2_add SSrc_b32:$src0, SSrc_b32:$src1))] >; def S_LSHL3_ADD_U32 : SOP2_32<"s_lshl3_add_u32", [(set i32:$sdst, (shl3_add SSrc_b32:$src0, SSrc_b32:$src1))] >; def S_LSHL4_ADD_U32 : SOP2_32<"s_lshl4_add_u32", [(set i32:$sdst, (shl4_add SSrc_b32:$src0, SSrc_b32:$src1))] >; } // End Defs = [SCC] let isCommutable = 1, isReMaterializable = 1 in { def S_MUL_HI_U32 : SOP2_32<"s_mul_hi_u32", [(set i32:$sdst, (UniformBinFrag SSrc_b32:$src0, SSrc_b32:$src1))]>; def S_MUL_HI_I32 : SOP2_32<"s_mul_hi_i32", [(set i32:$sdst, (UniformBinFrag SSrc_b32:$src0, SSrc_b32:$src1))]>; } // End isCommutable = 1, isReMaterializable = 1 } // End SubtargetPredicate = isGFX9Plus let SubtargetPredicate = isGFX11Plus in { def S_PACK_HL_B32_B16 : SOP2_32<"s_pack_hl_b32_b16">; } // End SubtargetPredicate = isGFX11Plus class SOP2_F32_Inst : SOP2_F32 SSrc_f32:$src0, SSrc_f32:$src1))]>; class SOP2_F16_Inst : SOP2_F16 SSrc_f16:$src0, SSrc_f16:$src1))]>; let SubtargetPredicate = HasSALUFloatInsts, mayRaiseFPException = 1, Uses = [MODE], SchedRW = [WriteSFPU] in { let isReMaterializable = 1 in { let isCommutable = 1 in { def S_ADD_F32 : SOP2_F32_Inst<"s_add_f32", any_fadd>; def S_MIN_F32 : SOP2_F32_Inst<"s_min_f32", fminnum_like>; def S_MAX_F32 : SOP2_F32_Inst<"s_max_f32", fmaxnum_like>; def S_MUL_F32 : SOP2_F32_Inst<"s_mul_f32", any_fmul>; let FixedSize = 1 in def S_FMAAK_F32 : SOP2_Pseudo< "s_fmaak_f32", (outs SReg_32:$sdst), (ins SSrc_f32_Deferred:$src0, SSrc_f32_Deferred:$src1, KImmFP32:$imm), "$sdst, $src0, $src1, $imm" >; let FPDPRounding = 1 in { def S_ADD_F16 : SOP2_F16_Inst<"s_add_f16", any_fadd>; def S_MUL_F16 : SOP2_F16_Inst<"s_mul_f16", any_fmul>; } // End FPDPRounding def S_MIN_F16 : SOP2_F16_Inst<"s_min_f16", fminnum_like>; def S_MAX_F16 : SOP2_F16_Inst<"s_max_f16", fmaxnum_like>; } // End isCommutable = 1 let FPDPRounding = 1 in def S_SUB_F16 : SOP2_F16_Inst<"s_sub_f16", any_fsub>; def S_SUB_F32 : SOP2_F32_Inst<"s_sub_f32", any_fsub>; def S_CVT_PK_RTZ_F16_F32 : SOP2_F32_Inst<"s_cvt_pk_rtz_f16_f32", AMDGPUpkrtz_f16_f32, v2f16>; let FixedSize = 1 in def S_FMAMK_F32 : SOP2_Pseudo< "s_fmamk_f32", (outs SReg_32:$sdst), (ins SSrc_f32_Deferred:$src0, KImmFP32:$imm, SSrc_f32_Deferred:$src1), "$sdst, $src0, $imm, $src1" >; } // End isReMaterializable = 1 let Constraints = "$sdst = $src2", DisableEncoding="$src2", isCommutable = 1, AddedComplexity = 20 in { def S_FMAC_F32 : SOP2_Pseudo< "s_fmac_f32", (outs SReg_32:$sdst), (ins SSrc_f32:$src0, SSrc_f32:$src1, SReg_32:$src2), "$sdst, $src0, $src1", [(set f32:$sdst, (UniformTernaryFrag SSrc_f32:$src0, SSrc_f32:$src1, SReg_32:$src2))] >; def S_FMAC_F16 : SOP2_Pseudo< "s_fmac_f16", (outs SReg_32:$sdst), (ins SSrc_f16:$src0, SSrc_f16:$src1, SReg_32:$src2), "$sdst, $src0, $src1", [(set f16:$sdst, (UniformTernaryFrag SSrc_f16:$src0, SSrc_f16:$src1, SReg_32:$src2))] >; } // End Constraints = "$sdst = $src2", DisableEncoding="$src2", // isCommutable = 1, AddedComplexity = 20 } // End SubtargetPredicate = HasSALUFloatInsts, mayRaiseFPException = 1, // Uses = [MODE], SchedRW = [WriteSFPU] // On GFX12 MIN/MAX instructions do not read MODE register. let SubtargetPredicate = isGFX12Plus, mayRaiseFPException = 1, isCommutable = 1, isReMaterializable = 1, SchedRW = [WriteSFPU] in { def S_MINIMUM_F32 : SOP2_F32_Inst<"s_minimum_f32", fminimum>; def S_MAXIMUM_F32 : SOP2_F32_Inst<"s_maximum_f32", fmaximum>; def S_MINIMUM_F16 : SOP2_F16_Inst<"s_minimum_f16", fminimum>; def S_MAXIMUM_F16 : SOP2_F16_Inst<"s_maximum_f16", fmaximum>; } //===----------------------------------------------------------------------===// // SOPK Instructions //===----------------------------------------------------------------------===// class SOPK_Pseudo pattern=[]> : SOP_Pseudo { let mayLoad = 0; let mayStore = 0; let hasSideEffects = 0; let SALU = 1; let SOPK = 1; let FixedSize = 1; let SchedRW = [WriteSALU]; let UseNamedOperandTable = 1; let has_sdst = 1; } class SOPK_Real : InstSI { let SALU = 1; let SOPK = 1; let isPseudo = 0; let isCodeGenOnly = 0; let UseNamedOperandTable = 1; // copy relevant pseudo op flags let SubtargetPredicate = ps.SubtargetPredicate; let AsmMatchConverter = ps.AsmMatchConverter; let DisableEncoding = ps.DisableEncoding; let Constraints = ps.Constraints; let SchedRW = ps.SchedRW; let mayLoad = ps.mayLoad; let mayStore = ps.mayStore; let isBranch = ps.isBranch; let isCall = ps.isCall; let isTerminator = ps.isTerminator; let isReturn = ps.isReturn; let isBarrier = ps.isBarrier; let Uses = ps.Uses; let Defs = ps.Defs; // encoding bits<7> sdst; bits<16> simm16; bits<32> imm; } class SOPK_Real32 op, SOPK_Pseudo ps, string name = ps.Mnemonic> : SOPK_Real , Enc32 { let Inst{15-0} = simm16; let Inst{22-16} = !if(ps.has_sdst, sdst, ?); let Inst{27-23} = op; let Inst{31-28} = 0xb; //encoding } class SOPK_Real64 op, SOPK_Pseudo ps> : SOPK_Real, Enc64 { let Inst{15-0} = simm16; let Inst{22-16} = !if(ps.has_sdst, sdst, ?); let Inst{27-23} = op; let Inst{31-28} = 0xb; //encoding let Inst{63-32} = imm; } class SOPKInstTable { bit IsSOPK = is_sopk; string BaseCmpOp = cmpOp; } class SOPK_32 pattern=[]> : SOPK_Pseudo < opName, (outs SReg_32:$sdst), (ins s16imm:$simm16), "$sdst, $simm16", pattern>; class SOPK_32_BR pattern=[]> : SOPK_Pseudo < opName, (outs), (ins SOPPBrTarget:$simm16, SReg_32:$sdst), "$sdst, $simm16", pattern> { let Defs = [EXEC]; let Uses = [EXEC]; let isBranch = 1; let isTerminator = 1; let SchedRW = [WriteBranch]; } class SOPK_SCC : SOPK_Pseudo < opName, (outs), !if(isSignExt, (ins SReg_32:$sdst, s16imm:$simm16), (ins SReg_32:$sdst, u16imm:$simm16)), "$sdst, $simm16">, SOPKInstTable<1, base_op>{ let Defs = [SCC]; } class SOPK_32TIE pattern=[]> : SOPK_Pseudo < opName, (outs SReg_32:$sdst), (ins SReg_32:$src0, s16imm:$simm16), "$sdst, $simm16", pattern >; let isReMaterializable = 1, isMoveImm = 1 in { def S_MOVK_I32 : SOPK_32 <"s_movk_i32">; } // End isReMaterializable = 1 let Uses = [SCC] in { def S_CMOVK_I32 : SOPK_32 <"s_cmovk_i32">; } let isCompare = 1 in { // This instruction is disabled for now until we can figure out how to teach // the instruction selector to correctly use the S_CMP* vs V_CMP* // instructions. // // When this instruction is enabled the code generator sometimes produces this // invalid sequence: // // SCC = S_CMPK_EQ_I32 SGPR0, imm // VCC = COPY SCC // VGPR0 = V_CNDMASK VCC, VGPR0, VGPR1 // // def S_CMPK_EQ_I32 : SOPK_SCC <"s_cmpk_eq_i32", // [(set i1:$dst, (setcc i32:$src0, imm:$src1, SETEQ))] // >; def S_CMPK_EQ_I32 : SOPK_SCC <"s_cmpk_eq_i32", "s_cmp_eq_i32", 1>; def S_CMPK_LG_I32 : SOPK_SCC <"s_cmpk_lg_i32", "s_cmp_lg_i32", 1>; def S_CMPK_GT_I32 : SOPK_SCC <"s_cmpk_gt_i32", "s_cmp_gt_i32", 1>; def S_CMPK_GE_I32 : SOPK_SCC <"s_cmpk_ge_i32", "s_cmp_ge_i32", 1>; def S_CMPK_LT_I32 : SOPK_SCC <"s_cmpk_lt_i32", "s_cmp_lt_i32", 1>; def S_CMPK_LE_I32 : SOPK_SCC <"s_cmpk_le_i32", "s_cmp_le_i32", 1>; def S_CMPK_EQ_U32 : SOPK_SCC <"s_cmpk_eq_u32", "s_cmp_eq_u32", 0>; def S_CMPK_LG_U32 : SOPK_SCC <"s_cmpk_lg_u32", "s_cmp_lg_u32", 0>; def S_CMPK_GT_U32 : SOPK_SCC <"s_cmpk_gt_u32", "s_cmp_gt_u32", 0>; def S_CMPK_GE_U32 : SOPK_SCC <"s_cmpk_ge_u32", "s_cmp_ge_u32", 0>; def S_CMPK_LT_U32 : SOPK_SCC <"s_cmpk_lt_u32", "s_cmp_lt_u32", 0>; def S_CMPK_LE_U32 : SOPK_SCC <"s_cmpk_le_u32", "s_cmp_le_u32", 0>; } // End isCompare = 1 let isCommutable = 1, DisableEncoding = "$src0", Constraints = "$sdst = $src0" in { let Defs = [SCC] in def S_ADDK_I32 : SOPK_32TIE <"s_addk_i32">; def S_MULK_I32 : SOPK_32TIE <"s_mulk_i32">; } let SubtargetPredicate = isGFX6GFX7GFX8GFX9 in def S_CBRANCH_I_FORK : SOPK_Pseudo < "s_cbranch_i_fork", (outs), (ins SReg_64:$sdst, SOPPBrTarget:$simm16), "$sdst, $simm16" >; // This is hasSideEffects to allow its use in readcyclecounter selection. // FIXME: Need to truncate immediate to 16-bits. // FIXME: Should have separate pseudos for known may read MODE and // only read MODE. def S_GETREG_B32 : SOPK_Pseudo < "s_getreg_b32", (outs SReg_32:$sdst), (ins hwreg:$simm16), "$sdst, $simm16", [(set i32:$sdst, (int_amdgcn_s_getreg (i32 timm:$simm16)))]> { let hasSideEffects = 1; let Uses = [MODE]; } let Defs = [MODE], Uses = [MODE] in { // FIXME: Need to truncate immediate to 16-bits. class S_SETREG_B32_Pseudo pattern=[]> : SOPK_Pseudo < "s_setreg_b32", (outs), (ins SReg_32:$sdst, hwreg:$simm16), "$simm16, $sdst", pattern>; def S_SETREG_B32 : S_SETREG_B32_Pseudo < [(int_amdgcn_s_setreg (i32 SIMM16bit:$simm16), i32:$sdst)]> { // Use custom inserter to optimize some cases to // S_DENORM_MODE/S_ROUND_MODE/S_SETREG_B32_mode. let usesCustomInserter = 1; let hasSideEffects = 1; } // Variant of SETREG that is guaranteed to only touch FP bits in the MODE // register, so doesn't have unmodeled side effects. def S_SETREG_B32_mode : S_SETREG_B32_Pseudo { let hasSideEffects = 0; } // FIXME: Not on SI? //def S_GETREG_REGRD_B32 : SOPK_32 , "s_getreg_regrd_b32">; class S_SETREG_IMM32_B32_Pseudo : SOPK_Pseudo < "s_setreg_imm32_b32", (outs), (ins i32imm:$imm, hwreg:$simm16), "$simm16, $imm"> { let Size = 8; // Unlike every other SOPK instruction. let has_sdst = 0; } def S_SETREG_IMM32_B32 : S_SETREG_IMM32_B32_Pseudo { let hasSideEffects = 1; } // Variant of SETREG_IMM32 that is guaranteed to only touch FP bits in the MODE // register, so doesn't have unmodeled side effects. def S_SETREG_IMM32_B32_mode : S_SETREG_IMM32_B32_Pseudo { let hasSideEffects = 0; } } // End Defs = [MODE], Uses = [MODE] class SOPK_WAITCNT pat=[]> : SOPK_Pseudo< opName, (outs), (ins SReg_32:$sdst, s16imm:$simm16), "$sdst, $simm16", pat> { let hasSideEffects = 1; let mayLoad = 1; let mayStore = 1; let has_sdst = 1; // First source takes place of sdst in encoding } let SubtargetPredicate = isGFX9Plus in { def S_CALL_B64 : SOPK_Pseudo< "s_call_b64", (outs SReg_64:$sdst), (ins SOPPBrTarget:$simm16), "$sdst, $simm16"> { let isCall = 1; } } // End SubtargetPredicate = isGFX9Plus def VersionImm : S16ImmOperand { let DecoderMethod = "decodeVersionImm"; } let SubtargetPredicate = isGFX10Plus in { def S_VERSION : SOPK_Pseudo< "s_version", (outs), (ins VersionImm:$simm16), "$simm16"> { let has_sdst = 0; } } // End SubtargetPredicate = isGFX10Plus let SubtargetPredicate = isGFX10GFX11 in { def S_SUBVECTOR_LOOP_BEGIN : SOPK_32_BR<"s_subvector_loop_begin">; def S_SUBVECTOR_LOOP_END : SOPK_32_BR<"s_subvector_loop_end">; def S_WAITCNT_VSCNT : SOPK_WAITCNT<"s_waitcnt_vscnt">; def S_WAITCNT_VMCNT : SOPK_WAITCNT<"s_waitcnt_vmcnt">; def S_WAITCNT_EXPCNT : SOPK_WAITCNT<"s_waitcnt_expcnt">; def S_WAITCNT_LGKMCNT : SOPK_WAITCNT<"s_waitcnt_lgkmcnt">; } // End SubtargetPredicate = isGFX10GFX11 //===----------------------------------------------------------------------===// // SOPC Instructions //===----------------------------------------------------------------------===// class SOPC_Pseudo pattern=[]> : SOP_Pseudo { let mayLoad = 0; let mayStore = 0; let hasSideEffects = 0; let SALU = 1; let SOPC = 1; let Defs = [SCC]; let SchedRW = [WriteSALU]; let UseNamedOperandTable = 1; } class SOPC_Real op, SOPC_Pseudo ps> : InstSI , Enc32 { let SALU = 1; let SOPC = 1; let isPseudo = 0; let isCodeGenOnly = 0; // copy relevant pseudo op flags let SubtargetPredicate = ps.SubtargetPredicate; let OtherPredicates = ps.OtherPredicates; let AsmMatchConverter = ps.AsmMatchConverter; let UseNamedOperandTable = ps.UseNamedOperandTable; let TSFlags = ps.TSFlags; let SchedRW = ps.SchedRW; let mayLoad = ps.mayLoad; let mayStore = ps.mayStore; let Uses = ps.Uses; let Defs = ps.Defs; // encoding bits<8> src0; bits<8> src1; let Inst{7-0} = src0; let Inst{15-8} = src1; let Inst{22-16} = op; let Inst{31-23} = 0x17e; } class SOPC_Base pattern = []> : SOPC_Pseudo < opName, (outs), (ins rc0:$src0, rc1:$src1), "$src0, $src1", pattern > { } class SOPC_Helper : SOPC_Base < rc, rc, opName, [(set SCC, (UniformTernaryFrag vt:$src0, vt:$src1, cond))] > { } class SOPC_CMP_32 : SOPC_Helper, Commutable_REV, SOPKInstTable<0, opName> { let isCompare = 1; let isCommutable = 1; } class SOPC_CMP_F32 : SOPC_Helper, Commutable_REV, SOPKInstTable<0, opName> { let isCompare = 1; let isCommutable = 1; let mayRaiseFPException = 1; let Uses = [MODE]; let SchedRW = [WriteSFPU]; } class SOPC_CMP_F16 : SOPC_Helper, Commutable_REV, SOPKInstTable<0, opName> { let isCompare = 1; let isCommutable = 1; let mayRaiseFPException = 1; let Uses = [MODE]; let SchedRW = [WriteSFPU]; } class SOPC_CMP_64 : SOPC_Helper, Commutable_REV { let isCompare = 1; let isCommutable = 1; } class SOPC_32 pattern = []> : SOPC_Base; class SOPC_64_32 pattern = []> : SOPC_Base; def S_CMP_EQ_I32 : SOPC_CMP_32 <"s_cmp_eq_i32">; def S_CMP_LG_I32 : SOPC_CMP_32 <"s_cmp_lg_i32">; def S_CMP_GT_I32 : SOPC_CMP_32 <"s_cmp_gt_i32", COND_SGT>; def S_CMP_GE_I32 : SOPC_CMP_32 <"s_cmp_ge_i32", COND_SGE>; def S_CMP_LT_I32 : SOPC_CMP_32 <"s_cmp_lt_i32", COND_SLT, "s_cmp_gt_i32">; def S_CMP_LE_I32 : SOPC_CMP_32 <"s_cmp_le_i32", COND_SLE, "s_cmp_ge_i32">; def S_CMP_EQ_U32 : SOPC_CMP_32 <"s_cmp_eq_u32", COND_EQ>; def S_CMP_LG_U32 : SOPC_CMP_32 <"s_cmp_lg_u32", COND_NE>; def S_CMP_GT_U32 : SOPC_CMP_32 <"s_cmp_gt_u32", COND_UGT>; def S_CMP_GE_U32 : SOPC_CMP_32 <"s_cmp_ge_u32", COND_UGE>; def S_CMP_LT_U32 : SOPC_CMP_32 <"s_cmp_lt_u32", COND_ULT, "s_cmp_gt_u32">; def S_CMP_LE_U32 : SOPC_CMP_32 <"s_cmp_le_u32", COND_ULE, "s_cmp_ge_u32">; def S_BITCMP0_B32 : SOPC_32 <"s_bitcmp0_b32">; def S_BITCMP1_B32 : SOPC_32 <"s_bitcmp1_b32">; def S_BITCMP0_B64 : SOPC_64_32 <"s_bitcmp0_b64">; def S_BITCMP1_B64 : SOPC_64_32 <"s_bitcmp1_b64">; let SubtargetPredicate = isGFX6GFX7GFX8GFX9 in def S_SETVSKIP : SOPC_32 <"s_setvskip">; let SubtargetPredicate = isGFX8Plus in { def S_CMP_EQ_U64 : SOPC_CMP_64 <"s_cmp_eq_u64", COND_EQ>; def S_CMP_LG_U64 : SOPC_CMP_64 <"s_cmp_lg_u64", COND_NE>; } // End SubtargetPredicate = isGFX8Plus let SubtargetPredicate = HasVGPRIndexMode in { // Setting the GPR index mode is really writing the fields in the mode // register. We don't want to add mode register uses to every // instruction, and it's too complicated to deal with anyway. This is // modeled just as a side effect. def S_SET_GPR_IDX_ON : SOPC_Pseudo < "s_set_gpr_idx_on" , (outs), (ins SSrc_b32:$src0, GPRIdxMode:$src1), "$src0, $src1"> { let Defs = [M0, MODE]; // No scc def let Uses = [M0, MODE]; // Other bits of mode, m0 unmodified. let hasSideEffects = 1; // Sets mode.gpr_idx_en let FixedSize = 1; } } let SubtargetPredicate = HasSALUFloatInsts in { def S_CMP_LT_F32 : SOPC_CMP_F32<"s_cmp_lt_f32", COND_OLT, "s_cmp_gt_f32">; def S_CMP_EQ_F32 : SOPC_CMP_F32<"s_cmp_eq_f32", COND_OEQ>; def S_CMP_LE_F32 : SOPC_CMP_F32<"s_cmp_le_f32", COND_OLE, "s_cmp_ge_f32">; def S_CMP_GT_F32 : SOPC_CMP_F32<"s_cmp_gt_f32", COND_OGT>; def S_CMP_LG_F32 : SOPC_CMP_F32<"s_cmp_lg_f32", COND_ONE>; def S_CMP_GE_F32 : SOPC_CMP_F32<"s_cmp_ge_f32", COND_OGE>; def S_CMP_O_F32 : SOPC_CMP_F32<"s_cmp_o_f32", COND_O>; def S_CMP_U_F32 : SOPC_CMP_F32<"s_cmp_u_f32", COND_UO>; def S_CMP_NGE_F32 : SOPC_CMP_F32<"s_cmp_nge_f32", COND_ULT, "s_cmp_nle_f32">; def S_CMP_NLG_F32 : SOPC_CMP_F32<"s_cmp_nlg_f32", COND_UEQ>; def S_CMP_NGT_F32 : SOPC_CMP_F32<"s_cmp_ngt_f32", COND_ULE, "s_cmp_nlt_f32">; def S_CMP_NLE_F32 : SOPC_CMP_F32<"s_cmp_nle_f32", COND_UGT>; def S_CMP_NEQ_F32 : SOPC_CMP_F32<"s_cmp_neq_f32", COND_UNE>; def S_CMP_NLT_F32 : SOPC_CMP_F32<"s_cmp_nlt_f32", COND_UGE>; def S_CMP_LT_F16 : SOPC_CMP_F16<"s_cmp_lt_f16", COND_OLT, "s_cmp_gt_f16">; def S_CMP_EQ_F16 : SOPC_CMP_F16<"s_cmp_eq_f16", COND_OEQ>; def S_CMP_LE_F16 : SOPC_CMP_F16<"s_cmp_le_f16", COND_OLE, "s_cmp_ge_f16">; def S_CMP_GT_F16 : SOPC_CMP_F16<"s_cmp_gt_f16", COND_OGT>; def S_CMP_LG_F16 : SOPC_CMP_F16<"s_cmp_lg_f16", COND_ONE>; def S_CMP_GE_F16 : SOPC_CMP_F16<"s_cmp_ge_f16", COND_OGE>; def S_CMP_O_F16 : SOPC_CMP_F16<"s_cmp_o_f16", COND_O>; def S_CMP_U_F16 : SOPC_CMP_F16<"s_cmp_u_f16", COND_UO>; def S_CMP_NGE_F16 : SOPC_CMP_F16<"s_cmp_nge_f16", COND_ULT, "s_cmp_nle_f16">; def S_CMP_NLG_F16 : SOPC_CMP_F16<"s_cmp_nlg_f16", COND_UEQ>; def S_CMP_NGT_F16 : SOPC_CMP_F16<"s_cmp_ngt_f16", COND_ULE, "s_cmp_nlt_f16">; def S_CMP_NLE_F16 : SOPC_CMP_F16<"s_cmp_nle_f16", COND_UGT>; def S_CMP_NEQ_F16 : SOPC_CMP_F16<"s_cmp_neq_f16", COND_UNE>; def S_CMP_NLT_F16 : SOPC_CMP_F16<"s_cmp_nlt_f16", COND_UGE>; } // End SubtargetPredicate = HasSALUFloatInsts //===----------------------------------------------------------------------===// // SOPP Instructions //===----------------------------------------------------------------------===// class SOPP_Pseudo pattern=[], string sep = !if(!empty(asmOps), "", " "), string keyName = opName> : SOP_Pseudo { let mayLoad = 0; let mayStore = 0; let hasSideEffects = 0; let SALU = 1; let SOPP = 1; let FixedSize = 1; let SchedRW = [WriteSALU]; let UseNamedOperandTable = 1; bits <16> simm16; bits <1> fixed_imm = 0; string KeyName = keyName; } class SOPPRelaxTable { bit IsRelaxed = isRelaxed; string KeyName = keyName # gfxip; } class SOPP_Real : InstSI { let SALU = 1; let SOPP = 1; let isPseudo = 0; let isCodeGenOnly = 0; // copy relevant pseudo op flags let SubtargetPredicate = ps.SubtargetPredicate; let OtherPredicates = ps.OtherPredicates; let AsmMatchConverter = ps.AsmMatchConverter; let UseNamedOperandTable = ps.UseNamedOperandTable; let TSFlags = ps.TSFlags; let SchedRW = ps.SchedRW; let mayLoad = ps.mayLoad; let mayStore = ps.mayStore; let isTerminator = ps.isTerminator; let isReturn = ps.isReturn; let isCall = ps.isCall; let isBranch = ps.isBranch; let isBarrier = ps.isBarrier; let Uses = ps.Uses; let Defs = ps.Defs; bits <16> simm16; } class SOPP_Real_32 op, SOPP_Pseudo ps, string name = ps.Mnemonic> : SOPP_Real, Enc32 { let Inst{15-0} = !if(ps.fixed_imm, ps.simm16, simm16); let Inst{22-16} = op; let Inst{31-23} = 0x17f; } class SOPP_Real_64 op, SOPP_Pseudo ps, string name = ps.Mnemonic> : SOPP_Real, Enc64 { // encoding let Inst{15-0} = !if(ps.fixed_imm, ps.simm16, simm16); let Inst{22-16} = op; let Inst{31-23} = 0x17f; //effectively a nop let Inst{47-32} = 0x0; let Inst{54-48} = 0x0; let Inst{63-55} = 0x17f; } multiclass SOPP_With_Relaxation pattern=[]> { def "" : SOPP_Pseudo ; def _pad_s_nop : SOPP_Pseudo ; } def S_NOP : SOPP_Pseudo<"s_nop" , (ins i16imm:$simm16), "$simm16", [(int_amdgcn_s_nop timm:$simm16)]> { let hasSideEffects = 1; } let isTerminator = 1 in { def S_ENDPGM : SOPP_Pseudo<"s_endpgm", (ins Endpgm:$simm16), "$simm16", [], ""> { let isBarrier = 1; let isReturn = 1; let hasSideEffects = 1; } def S_ENDPGM_SAVED : SOPP_Pseudo<"s_endpgm_saved", (ins)> { let SubtargetPredicate = isGFX8Plus; let simm16 = 0; let fixed_imm = 1; let isBarrier = 1; let isReturn = 1; } let SubtargetPredicate = isGFX9GFX10 in { let isBarrier = 1, isReturn = 1, simm16 = 0, fixed_imm = 1 in { def S_ENDPGM_ORDERED_PS_DONE : SOPP_Pseudo<"s_endpgm_ordered_ps_done", (ins)>; } // End isBarrier = 1, isReturn = 1, simm16 = 0, fixed_imm = 1 } // End SubtargetPredicate = isGFX9GFX10 let SubtargetPredicate = isGFX10Plus in { let isBarrier = 1, isReturn = 1, simm16 = 0, fixed_imm = 1 in { def S_CODE_END : SOPP_Pseudo<"s_code_end", (ins)>; } // End isBarrier = 1, isReturn = 1, simm16 = 0, fixed_imm = 1 } // End SubtargetPredicate = isGFX10Plus let isBranch = 1, SchedRW = [WriteBranch] in { let isBarrier = 1 in { defm S_BRANCH : SOPP_With_Relaxation< "s_branch" , (ins SOPPBrTarget:$simm16), "$simm16", [(br bb:$simm16)]>; } let Uses = [SCC] in { defm S_CBRANCH_SCC0 : SOPP_With_Relaxation< "s_cbranch_scc0" , (ins SOPPBrTarget:$simm16), "$simm16" >; defm S_CBRANCH_SCC1 : SOPP_With_Relaxation < "s_cbranch_scc1" , (ins SOPPBrTarget:$simm16), "$simm16" >; } // End Uses = [SCC] let Uses = [VCC] in { defm S_CBRANCH_VCCZ : SOPP_With_Relaxation < "s_cbranch_vccz" , (ins SOPPBrTarget:$simm16), "$simm16" >; defm S_CBRANCH_VCCNZ : SOPP_With_Relaxation < "s_cbranch_vccnz" , (ins SOPPBrTarget:$simm16), "$simm16" >; } // End Uses = [VCC] let Uses = [EXEC] in { defm S_CBRANCH_EXECZ : SOPP_With_Relaxation < "s_cbranch_execz" , (ins SOPPBrTarget:$simm16), "$simm16" >; defm S_CBRANCH_EXECNZ : SOPP_With_Relaxation < "s_cbranch_execnz" , (ins SOPPBrTarget:$simm16), "$simm16" >; } // End Uses = [EXEC] defm S_CBRANCH_CDBGSYS : SOPP_With_Relaxation < "s_cbranch_cdbgsys" , (ins SOPPBrTarget:$simm16), "$simm16" >; defm S_CBRANCH_CDBGSYS_AND_USER : SOPP_With_Relaxation < "s_cbranch_cdbgsys_and_user" , (ins SOPPBrTarget:$simm16), "$simm16" >; defm S_CBRANCH_CDBGSYS_OR_USER : SOPP_With_Relaxation < "s_cbranch_cdbgsys_or_user" , (ins SOPPBrTarget:$simm16), "$simm16" >; defm S_CBRANCH_CDBGUSER : SOPP_With_Relaxation < "s_cbranch_cdbguser" , (ins SOPPBrTarget:$simm16), "$simm16" >; } // End isBranch = 1 } // End isTerminator = 1 let hasSideEffects = 1 in { def S_BARRIER : SOPP_Pseudo <"s_barrier", (ins), "", [(int_amdgcn_s_barrier)]> { let SchedRW = [WriteBarrier]; let simm16 = 0; let fixed_imm = 1; let isConvergent = 1; } def S_BARRIER_WAIT : SOPP_Pseudo <"s_barrier_wait", (ins i16imm:$simm16), "$simm16", [(int_amdgcn_s_barrier_wait timm:$simm16)]> { let SchedRW = [WriteBarrier]; let isConvergent = 1; } def S_BARRIER_LEAVE : SOPP_Pseudo <"s_barrier_leave", (ins), "", [(set SCC, (int_amdgcn_s_barrier_leave))]> { let SchedRW = [WriteBarrier]; let simm16 = 0; let fixed_imm = 1; let isConvergent = 1; let Defs = [SCC]; } def S_WAKEUP : SOPP_Pseudo <"s_wakeup", (ins) > { let SubtargetPredicate = isGFX8Plus; let simm16 = 0; let fixed_imm = 1; let mayLoad = 1; let mayStore = 1; } def S_WAITCNT : SOPP_Pseudo <"s_waitcnt" , (ins SWaitCnt:$simm16), "$simm16", [(int_amdgcn_s_waitcnt timm:$simm16)]>; // "_soft" waitcnts are waitcnts that are either relaxed into their non-soft // counterpart, or completely removed. // // These are inserted by SIMemoryLegalizer to resolve memory dependencies // and later optimized by SIInsertWaitcnts // For example, a S_WAITCNT_soft 0 can be completely removed in a function // that doesn't access memory. def S_WAITCNT_soft : SOPP_Pseudo <"s_soft_waitcnt" , (ins SWaitCnt:$simm16), "$simm16">; def S_WAITCNT_VSCNT_soft : SOPK_WAITCNT<"s_soft_waitcnt_vscnt">; let SubtargetPredicate = isGFX12Plus in { def S_WAIT_LOADCNT_soft : SOPP_Pseudo <"s_soft_wait_loadcnt", (ins s16imm:$simm16), "$simm16">; def S_WAIT_STORECNT_soft : SOPP_Pseudo <"s_soft_wait_storecnt", (ins s16imm:$simm16), "$simm16">; let OtherPredicates = [HasImageInsts] in { def S_WAIT_SAMPLECNT_soft : SOPP_Pseudo <"s_soft_wait_samplecnt", (ins s16imm:$simm16), "$simm16">; def S_WAIT_BVHCNT_soft : SOPP_Pseudo <"s_soft_wait_bvhcnt", (ins s16imm:$simm16), "$simm16">; } // End OtherPredicates = [HasImageInsts]. def S_WAIT_DSCNT_soft : SOPP_Pseudo <"s_soft_wait_dscnt", (ins s16imm:$simm16), "$simm16">; def S_WAIT_KMCNT_soft : SOPP_Pseudo <"s_soft_wait_kmcnt", (ins s16imm:$simm16), "$simm16">; } def S_SETHALT : SOPP_Pseudo <"s_sethalt" , (ins i32imm:$simm16), "$simm16", [(int_amdgcn_s_sethalt timm:$simm16)]>; def S_SETKILL : SOPP_Pseudo <"s_setkill" , (ins i16imm:$simm16), "$simm16">; // On SI the documentation says sleep for approximately 64 * low 2 // bits, consistent with the reported maximum of 448. On VI the // maximum reported is 960 cycles, so 960 / 64 = 15 max, so is the // maximum really 15 on VI? def S_SLEEP : SOPP_Pseudo <"s_sleep", (ins i32imm:$simm16), "$simm16", [(int_amdgcn_s_sleep timm:$simm16)]> { } def S_SLEEP_VAR : SOP1_0_32 <"s_sleep_var", [(int_amdgcn_s_sleep_var SSrc_b32:$src0)]> { let hasSideEffects = 1; } def S_SETPRIO : SOPP_Pseudo <"s_setprio", (ins i16imm:$simm16), "$simm16", [(int_amdgcn_s_setprio timm:$simm16)]> { } let Uses = [EXEC, M0] in { def S_SENDMSG : SOPP_Pseudo <"s_sendmsg" , (ins SendMsg:$simm16), "$simm16", [(int_amdgcn_s_sendmsg (i32 timm:$simm16), M0)]> { } def S_SENDMSGHALT : SOPP_Pseudo <"s_sendmsghalt" , (ins SendMsg:$simm16), "$simm16", [(int_amdgcn_s_sendmsghalt (i32 timm:$simm16), M0)]> { } } // End Uses = [EXEC, M0] def S_TRAP : SOPP_Pseudo <"s_trap" , (ins i16imm:$simm16), "$simm16"> { let isTrap = 1; } def S_ICACHE_INV : SOPP_Pseudo <"s_icache_inv", (ins)> { let simm16 = 0; let fixed_imm = 1; } def S_INCPERFLEVEL : SOPP_Pseudo <"s_incperflevel", (ins i32imm:$simm16), "$simm16", [(int_amdgcn_s_incperflevel timm:$simm16)]> { } def S_DECPERFLEVEL : SOPP_Pseudo <"s_decperflevel", (ins i32imm:$simm16), "$simm16", [(int_amdgcn_s_decperflevel timm:$simm16)]> { } let Uses = [M0] in def S_TTRACEDATA : SOPP_Pseudo <"s_ttracedata", (ins), "", [(int_amdgcn_s_ttracedata M0)]> { let simm16 = 0; let fixed_imm = 1; } let SubtargetPredicate = HasVGPRIndexMode in { def S_SET_GPR_IDX_OFF : SOPP_Pseudo<"s_set_gpr_idx_off", (ins) > { let simm16 = 0; let fixed_imm = 1; let Defs = [MODE]; let Uses = [MODE]; } } } // End hasSideEffects let SubtargetPredicate = HasVGPRIndexMode in { def S_SET_GPR_IDX_MODE : SOPP_Pseudo<"s_set_gpr_idx_mode", (ins GPRIdxMode:$simm16), "$simm16"> { let Defs = [M0, MODE]; let Uses = [MODE]; } } let SubtargetPredicate = isGFX10Plus in { def S_INST_PREFETCH : SOPP_Pseudo<"s_inst_prefetch", (ins s16imm:$simm16), "$simm16">; def S_CLAUSE : SOPP_Pseudo<"s_clause", (ins s16imm:$simm16), "$simm16">; def S_WAIT_IDLE : SOPP_Pseudo <"s_wait_idle", (ins)> { let simm16 = 0; let fixed_imm = 1; } def S_WAITCNT_DEPCTR : SOPP_Pseudo <"s_waitcnt_depctr" , (ins DepCtr:$simm16), "$simm16">; let hasSideEffects = 0, Uses = [MODE], Defs = [MODE] in { def S_ROUND_MODE : SOPP_Pseudo<"s_round_mode", (ins s16imm:$simm16), "$simm16">; def S_DENORM_MODE : SOPP_Pseudo<"s_denorm_mode", (ins i32imm:$simm16), "$simm16", [(SIdenorm_mode (i32 timm:$simm16))]>; } let hasSideEffects = 1 in def S_TTRACEDATA_IMM : SOPP_Pseudo<"s_ttracedata_imm", (ins s16imm:$simm16), "$simm16", [(int_amdgcn_s_ttracedata_imm timm:$simm16)]>; } // End SubtargetPredicate = isGFX10Plus let SubtargetPredicate = isGFX11Plus in { let OtherPredicates = [HasExportInsts] in def S_WAIT_EVENT : SOPP_Pseudo<"s_wait_event", (ins s16imm:$simm16), "$simm16"> { let hasSideEffects = 1; } def S_DELAY_ALU : SOPP_Pseudo<"s_delay_alu", (ins SDelayALU:$simm16), "$simm16">; } // End SubtargetPredicate = isGFX11Plus let SubtargetPredicate = HasVGPRSingleUseHintInsts in { def S_SINGLEUSE_VDST : SOPP_Pseudo<"s_singleuse_vdst", (ins s16imm:$simm16), "$simm16">; } // End SubtargetPredicate = HasVGPRSingeUseHintInsts let SubtargetPredicate = isGFX12Plus, hasSideEffects = 1 in { def S_WAIT_LOADCNT : SOPP_Pseudo<"s_wait_loadcnt", (ins s16imm:$simm16), "$simm16", [(int_amdgcn_s_wait_loadcnt timm:$simm16)]>; def S_WAIT_LOADCNT_DSCNT : SOPP_Pseudo<"s_wait_loadcnt_dscnt", (ins s16imm:$simm16), "$simm16">; def S_WAIT_STORECNT : SOPP_Pseudo<"s_wait_storecnt", (ins s16imm:$simm16), "$simm16", [(int_amdgcn_s_wait_storecnt timm:$simm16)]>; def S_WAIT_STORECNT_DSCNT : SOPP_Pseudo<"s_wait_storecnt_dscnt", (ins s16imm:$simm16), "$simm16">; let OtherPredicates = [HasImageInsts] in { def S_WAIT_SAMPLECNT : SOPP_Pseudo<"s_wait_samplecnt", (ins s16imm:$simm16), "$simm16", [(int_amdgcn_s_wait_samplecnt timm:$simm16)]>; def S_WAIT_BVHCNT : SOPP_Pseudo<"s_wait_bvhcnt", (ins s16imm:$simm16), "$simm16", [(int_amdgcn_s_wait_bvhcnt timm:$simm16)]>; } // End OtherPredicates = [HasImageInsts]. let OtherPredicates = [HasExportInsts] in def S_WAIT_EXPCNT : SOPP_Pseudo<"s_wait_expcnt", (ins s16imm:$simm16), "$simm16", [(int_amdgcn_s_wait_expcnt timm:$simm16)]>; def S_WAIT_DSCNT : SOPP_Pseudo<"s_wait_dscnt", (ins s16imm:$simm16), "$simm16", [(int_amdgcn_s_wait_dscnt timm:$simm16)]>; def S_WAIT_KMCNT : SOPP_Pseudo<"s_wait_kmcnt", (ins s16imm:$simm16), "$simm16", [(int_amdgcn_s_wait_kmcnt timm:$simm16)]>; } // End SubtargetPredicate = isGFX12Plus, hasSideEffects = 1 //===----------------------------------------------------------------------===// // SOP1 Patterns //===----------------------------------------------------------------------===// def : GCNPat < (AMDGPUendpgm), (S_ENDPGM (i16 0)) >; def : GCNPat < (int_amdgcn_endpgm), (S_ENDPGM (i16 0)) >; def : GCNPat < (i64 (UniformUnaryFrag i64:$src)), (i64 (REG_SEQUENCE SReg_64, (i32 (COPY_TO_REGCLASS (S_BCNT1_I32_B64 $src), SReg_32)), sub0, (S_MOV_B32 (i32 0)), sub1)) >; def : GCNPat < (i32 (UniformBinFrag i32:$x, (i32 (ineg i32:$x)))), (S_ABS_I32 SReg_32:$x) >; def : GCNPat < (i16 imm:$imm), (S_MOV_B32 imm:$imm) >; // Same as a 32-bit inreg def : GCNPat< (i32 (UniformUnaryFrag i16:$src)), (S_SEXT_I32_I16 $src) >; let SubtargetPredicate = isNotGFX12Plus in def : GCNPat <(int_amdgcn_s_wait_event_export_ready), (S_WAIT_EVENT (i16 0))>; let SubtargetPredicate = isGFX12Plus in def : GCNPat <(int_amdgcn_s_wait_event_export_ready), (S_WAIT_EVENT (i16 2))>; // The first 10 bits of the mode register are the core FP mode on all // subtargets. // // The high bits include additional fields, intermixed with some // non-floating point environment information. We extract the full // register and clear non-relevant bits. // // EXCP_EN covers floating point exceptions, but also some other // non-FP exceptions. // // Bits 12-18 cover the relevant exception mask on all subtargets. // // FIXME: Bit 18 is int_div0, should this be in the FP environment? I // think the only source is v_rcp_iflag_i32. // // On GFX9+: // Bit 23 is the additional FP16_OVFL mode. // // Bits 19, 20, and 21 cover non-FP exceptions and differ between // gfx9/10/11, so we ignore them here. // TODO: Would it be cheaper to emit multiple s_getreg_b32 calls for // the ranges and combine the results? defvar fp_round_mask = !add(!shl(1, 4), -1); defvar fp_denorm_mask = !shl(!add(!shl(1, 4), -1), 4); defvar dx10_clamp_mask = !shl(1, 8); defvar ieee_mode_mask = !shl(1, 9); // Covers fp_round, fp_denorm, dx10_clamp, and IEEE bit. defvar fpmode_mask = !or(fp_round_mask, fp_denorm_mask, dx10_clamp_mask, ieee_mode_mask); defvar fp_excp_en_mask = !shl(!add(!shl(1, 7), -1), 12); defvar fp16_ovfl = !shl(1, 23); defvar fpmode_mask_gfx6plus = !or(fpmode_mask, fp_excp_en_mask); defvar fpmode_mask_gfx9plus = !or(fpmode_mask_gfx6plus, fp16_ovfl); class GetFPModePat : GCNPat< (i32 get_fpmode), (S_AND_B32 (i32 fpmode_mask), (S_GETREG_B32 getHwRegImm< HWREG.MODE, 0, !add(!logtwo(fpmode_mask), 1)>.ret)) >; // TODO: Might be worth moving to custom lowering so the and is // exposed to demanded bits optimizations. Most users probably only // care about the rounding or denorm mode bits. We also can reduce the // demanded read from the getreg immediate. let SubtargetPredicate = isGFX9Plus in { // Last bit = FP16_OVFL def : GetFPModePat; } // Last bit = EXCP_EN.int_div0 let SubtargetPredicate = isNotGFX9Plus in { def : GetFPModePat; } let SubtargetPredicate = isGFX9GFX10 in def : GCNPat< (int_amdgcn_pops_exiting_wave_id), (S_MOV_B32_sideeffects (i32 SRC_POPS_EXITING_WAVE_ID)) >; //===----------------------------------------------------------------------===// // SOP2 Patterns //===----------------------------------------------------------------------===// def UniformSelect : PatFrag< (ops node:$src0, node:$src1), (select SCC, $src0, $src1), [{ return !N->isDivergent(); }] >; let AddedComplexity = 20 in { def : GCNPat< (i32 (UniformSelect i32:$src0, i32:$src1)), (S_CSELECT_B32 SSrc_b32:$src0, SSrc_b32:$src1) >; // TODO: The predicate should not be necessary, but enabling this pattern for // all subtargets generates worse code in some cases. let OtherPredicates = [HasPseudoScalarTrans] in def : GCNPat< (f32 (UniformSelect f32:$src0, f32:$src1)), (S_CSELECT_B32 SSrc_b32:$src0, SSrc_b32:$src1) >; } // V_ADD_I32_e32/S_ADD_U32 produces carry in VCC/SCC. For the vector // case, the sgpr-copies pass will fix this to use the vector version. def : GCNPat < (i32 (addc i32:$src0, i32:$src1)), (S_ADD_U32 $src0, $src1) >; // FIXME: We need to use COPY_TO_REGCLASS to work-around the fact that // REG_SEQUENCE patterns don't support instructions with multiple // outputs. def : GCNPat< (i64 (UniformUnaryFrag i16:$src)), (REG_SEQUENCE SReg_64, (i32 (COPY_TO_REGCLASS (S_AND_B32 $src, (S_MOV_B32 (i32 0xffff))), SGPR_32)), sub0, (S_MOV_B32 (i32 0)), sub1) >; def : GCNPat < (i64 (UniformUnaryFrag i16:$src)), (REG_SEQUENCE SReg_64, (i32 (S_SEXT_I32_I16 $src)), sub0, (i32 (COPY_TO_REGCLASS (S_ASHR_I32 (i32 (S_SEXT_I32_I16 $src)), (S_MOV_B32 (i32 31))), SGPR_32)), sub1) >; def : GCNPat< (i32 (UniformUnaryFrag i16:$src)), (S_AND_B32 (S_MOV_B32 (i32 0xffff)), $src) >; class ScalarNot2Pat : GCNPat< (UniformBinFrag vt:$src0, (notnode vt:$src1)), (inst getSOPSrcForVT.ret:$src0, getSOPSrcForVT.ret:$src1) >; // Match these for some more types // TODO: i1 def : ScalarNot2Pat; def : ScalarNot2Pat; def : ScalarNot2Pat; def : ScalarNot2Pat; def : ScalarNot2Pat; def : ScalarNot2Pat; def : ScalarNot2Pat; def : ScalarNot2Pat; //===----------------------------------------------------------------------===// // Target-specific instruction encodings. //===----------------------------------------------------------------------===// class Select : SIMCInstr { Predicate AssemblerPredicate = Gen.AssemblerPredicate; string DecoderNamespace = Gen.DecoderNamespace; } class Select_vi : SIMCInstr { Predicate AssemblerPredicate = isGFX8GFX9; string DecoderNamespace = "GFX8"; } class Select_gfx6_gfx7 : SIMCInstr { Predicate AssemblerPredicate = isGFX6GFX7; string DecoderNamespace = "GFX6GFX7"; } //===----------------------------------------------------------------------===// // SOP1 - GFX11, GFX12 //===----------------------------------------------------------------------===// multiclass SOP1_Real_gfx11 op, string name = !tolower(NAME)> { defvar ps = !cast(NAME); def _gfx11 : SOP1_Real, Select; if !ne(ps.Mnemonic, name) then def : AMDGPUMnemonicAlias { let AssemblerPredicate = isGFX11Only; } } multiclass SOP1_Real_gfx12 op, string name = !tolower(NAME)> { defvar ps = !cast(NAME); def _gfx12 : SOP1_Real, Select; if !ne(ps.Mnemonic, name) then def : AMDGPUMnemonicAlias { let AssemblerPredicate = isGFX12Plus; } } multiclass SOP1_M0_Real_gfx12 op> { def _gfx12 : SOP1_Real(NAME)>, Select(NAME).PseudoInstr> { let Inst{7-0} = M0_gfx11plus.HWEncoding{7-0}; // Set Src0 encoding to M0 } } multiclass SOP1_IMM_Real_gfx12 op> { defvar ps = !cast(NAME); def _gfx12 : SOP1_Real, Select; } multiclass SOP1_Real_gfx11_gfx12 op, string name = !tolower(NAME)> : SOP1_Real_gfx11, SOP1_Real_gfx12; defm S_MOV_B32 : SOP1_Real_gfx11_gfx12<0x000>; defm S_MOV_B64 : SOP1_Real_gfx11_gfx12<0x001>; defm S_CMOV_B32 : SOP1_Real_gfx11_gfx12<0x002>; defm S_CMOV_B64 : SOP1_Real_gfx11_gfx12<0x003>; defm S_BREV_B32 : SOP1_Real_gfx11_gfx12<0x004>; defm S_BREV_B64 : SOP1_Real_gfx11_gfx12<0x005>; defm S_FF1_I32_B32 : SOP1_Real_gfx11_gfx12<0x008, "s_ctz_i32_b32">; defm S_FF1_I32_B64 : SOP1_Real_gfx11_gfx12<0x009, "s_ctz_i32_b64">; defm S_FLBIT_I32_B32 : SOP1_Real_gfx11_gfx12<0x00a, "s_clz_i32_u32">; defm S_FLBIT_I32_B64 : SOP1_Real_gfx11_gfx12<0x00b, "s_clz_i32_u64">; defm S_FLBIT_I32 : SOP1_Real_gfx11_gfx12<0x00c, "s_cls_i32">; defm S_FLBIT_I32_I64 : SOP1_Real_gfx11_gfx12<0x00d, "s_cls_i32_i64">; defm S_SEXT_I32_I8 : SOP1_Real_gfx11_gfx12<0x00e>; defm S_SEXT_I32_I16 : SOP1_Real_gfx11_gfx12<0x00f>; defm S_BITSET0_B32 : SOP1_Real_gfx11_gfx12<0x010>; defm S_BITSET0_B64 : SOP1_Real_gfx11_gfx12<0x011>; defm S_BITSET1_B32 : SOP1_Real_gfx11_gfx12<0x012>; defm S_BITSET1_B64 : SOP1_Real_gfx11_gfx12<0x013>; defm S_BITREPLICATE_B64_B32 : SOP1_Real_gfx11_gfx12<0x014>; defm S_ABS_I32 : SOP1_Real_gfx11_gfx12<0x015>; defm S_BCNT0_I32_B32 : SOP1_Real_gfx11_gfx12<0x016>; defm S_BCNT0_I32_B64 : SOP1_Real_gfx11_gfx12<0x017>; defm S_BCNT1_I32_B32 : SOP1_Real_gfx11_gfx12<0x018>; defm S_BCNT1_I32_B64 : SOP1_Real_gfx11_gfx12<0x019>; defm S_QUADMASK_B32 : SOP1_Real_gfx11_gfx12<0x01a>; defm S_QUADMASK_B64 : SOP1_Real_gfx11_gfx12<0x01b>; defm S_WQM_B32 : SOP1_Real_gfx11_gfx12<0x01c>; defm S_WQM_B64 : SOP1_Real_gfx11_gfx12<0x01d>; defm S_NOT_B32 : SOP1_Real_gfx11_gfx12<0x01e>; defm S_NOT_B64 : SOP1_Real_gfx11_gfx12<0x01f>; defm S_AND_SAVEEXEC_B32 : SOP1_Real_gfx11_gfx12<0x020>; defm S_AND_SAVEEXEC_B64 : SOP1_Real_gfx11_gfx12<0x021>; defm S_OR_SAVEEXEC_B32 : SOP1_Real_gfx11_gfx12<0x022>; defm S_OR_SAVEEXEC_B64 : SOP1_Real_gfx11_gfx12<0x023>; defm S_XOR_SAVEEXEC_B32 : SOP1_Real_gfx11_gfx12<0x024>; defm S_XOR_SAVEEXEC_B64 : SOP1_Real_gfx11_gfx12<0x025>; defm S_NAND_SAVEEXEC_B32 : SOP1_Real_gfx11_gfx12<0x026>; defm S_NAND_SAVEEXEC_B64 : SOP1_Real_gfx11_gfx12<0x027>; defm S_NOR_SAVEEXEC_B32 : SOP1_Real_gfx11_gfx12<0x028>; defm S_NOR_SAVEEXEC_B64 : SOP1_Real_gfx11_gfx12<0x029>; defm S_XNOR_SAVEEXEC_B32 : SOP1_Real_gfx11_gfx12<0x02a>; defm S_ANDN1_SAVEEXEC_B32 : SOP1_Real_gfx11_gfx12<0x02c, "s_and_not0_saveexec_b32">; defm S_ANDN1_SAVEEXEC_B64 : SOP1_Real_gfx11_gfx12<0x02d, "s_and_not0_saveexec_b64">; defm S_ORN1_SAVEEXEC_B32 : SOP1_Real_gfx11_gfx12<0x02e, "s_or_not0_saveexec_b32">; defm S_ORN1_SAVEEXEC_B64 : SOP1_Real_gfx11_gfx12<0x02f, "s_or_not0_saveexec_b64">; defm S_ANDN2_SAVEEXEC_B32 : SOP1_Real_gfx11_gfx12<0x030, "s_and_not1_saveexec_b32">; defm S_ANDN2_SAVEEXEC_B64 : SOP1_Real_gfx11_gfx12<0x031, "s_and_not1_saveexec_b64">; defm S_ORN2_SAVEEXEC_B32 : SOP1_Real_gfx11_gfx12<0x032, "s_or_not1_saveexec_b32">; defm S_ORN2_SAVEEXEC_B64 : SOP1_Real_gfx11_gfx12<0x033, "s_or_not1_saveexec_b64">; defm S_ANDN1_WREXEC_B32 : SOP1_Real_gfx11_gfx12<0x034, "s_and_not0_wrexec_b32">; defm S_ANDN1_WREXEC_B64 : SOP1_Real_gfx11_gfx12<0x035, "s_and_not0_wrexec_b64">; defm S_ANDN2_WREXEC_B32 : SOP1_Real_gfx11_gfx12<0x036, "s_and_not1_wrexec_b32">; defm S_ANDN2_WREXEC_B64 : SOP1_Real_gfx11_gfx12<0x037, "s_and_not1_wrexec_b64">; defm S_MOVRELS_B32 : SOP1_Real_gfx11_gfx12<0x040>; defm S_MOVRELS_B64 : SOP1_Real_gfx11_gfx12<0x041>; defm S_MOVRELD_B32 : SOP1_Real_gfx11_gfx12<0x042>; defm S_MOVRELD_B64 : SOP1_Real_gfx11_gfx12<0x043>; defm S_MOVRELSD_2_B32 : SOP1_Real_gfx11_gfx12<0x044>; defm S_GETPC_B64 : SOP1_Real_gfx11_gfx12<0x047>; defm S_SETPC_B64 : SOP1_Real_gfx11_gfx12<0x048>; defm S_SWAPPC_B64 : SOP1_Real_gfx11_gfx12<0x049>; defm S_RFE_B64 : SOP1_Real_gfx11_gfx12<0x04a>; defm S_SENDMSG_RTN_B32 : SOP1_Real_gfx11_gfx12<0x04c>; defm S_SENDMSG_RTN_B64 : SOP1_Real_gfx11_gfx12<0x04d>; defm S_BARRIER_SIGNAL_M0 : SOP1_M0_Real_gfx12<0x04e>; defm S_BARRIER_SIGNAL_ISFIRST_M0 : SOP1_M0_Real_gfx12<0x04f>; defm S_GET_BARRIER_STATE_M0 : SOP1_M0_Real_gfx12<0x050>; defm S_BARRIER_INIT_M0 : SOP1_M0_Real_gfx12<0x051>; defm S_BARRIER_JOIN_M0 : SOP1_M0_Real_gfx12<0x052>; defm S_WAKEUP_BARRIER_M0 : SOP1_M0_Real_gfx12<0x057>; defm S_BARRIER_SIGNAL_IMM : SOP1_IMM_Real_gfx12<0x04e>; defm S_BARRIER_SIGNAL_ISFIRST_IMM : SOP1_IMM_Real_gfx12<0x04f>; defm S_GET_BARRIER_STATE_IMM : SOP1_IMM_Real_gfx12<0x050>; defm S_BARRIER_INIT_IMM : SOP1_IMM_Real_gfx12<0x051>; defm S_BARRIER_JOIN_IMM : SOP1_IMM_Real_gfx12<0x052>; defm S_WAKEUP_BARRIER_IMM : SOP1_IMM_Real_gfx12<0x057>; defm S_SLEEP_VAR : SOP1_IMM_Real_gfx12<0x058>; //===----------------------------------------------------------------------===// // SOP1 - GFX1150, GFX12 //===----------------------------------------------------------------------===// defm S_CEIL_F32 : SOP1_Real_gfx11_gfx12<0x060>; defm S_FLOOR_F32 : SOP1_Real_gfx11_gfx12<0x061>; defm S_TRUNC_F32 : SOP1_Real_gfx11_gfx12<0x062>; defm S_RNDNE_F32 : SOP1_Real_gfx11_gfx12<0x063>; defm S_CVT_F32_I32 : SOP1_Real_gfx11_gfx12<0x064>; defm S_CVT_F32_U32 : SOP1_Real_gfx11_gfx12<0x065>; defm S_CVT_I32_F32 : SOP1_Real_gfx11_gfx12<0x066>; defm S_CVT_U32_F32 : SOP1_Real_gfx11_gfx12<0x067>; defm S_CVT_F16_F32 : SOP1_Real_gfx11_gfx12<0x068>; defm S_CVT_F32_F16 : SOP1_Real_gfx11_gfx12<0x069>; defm S_CVT_HI_F32_F16 : SOP1_Real_gfx11_gfx12<0x06a>; defm S_CEIL_F16 : SOP1_Real_gfx11_gfx12<0x06b>; defm S_FLOOR_F16 : SOP1_Real_gfx11_gfx12<0x06c>; defm S_TRUNC_F16 : SOP1_Real_gfx11_gfx12<0x06d>; defm S_RNDNE_F16 : SOP1_Real_gfx11_gfx12<0x06e>; //===----------------------------------------------------------------------===// // SOP1 - GFX10. //===----------------------------------------------------------------------===// multiclass SOP1_Real_gfx10 op> { defvar ps = !cast(NAME); def _gfx10 : SOP1_Real, Select; } multiclass SOP1_Real_gfx10_gfx11_gfx12 op> : SOP1_Real_gfx10, SOP1_Real_gfx11_gfx12; defm S_ANDN1_SAVEEXEC_B64 : SOP1_Real_gfx10<0x037>; defm S_ORN1_SAVEEXEC_B64 : SOP1_Real_gfx10<0x038>; defm S_ANDN1_WREXEC_B64 : SOP1_Real_gfx10<0x039>; defm S_ANDN2_WREXEC_B64 : SOP1_Real_gfx10<0x03a>; defm S_BITREPLICATE_B64_B32 : SOP1_Real_gfx10<0x03b>; defm S_AND_SAVEEXEC_B32 : SOP1_Real_gfx10<0x03c>; defm S_OR_SAVEEXEC_B32 : SOP1_Real_gfx10<0x03d>; defm S_XOR_SAVEEXEC_B32 : SOP1_Real_gfx10<0x03e>; defm S_ANDN2_SAVEEXEC_B32 : SOP1_Real_gfx10<0x03f>; defm S_ORN2_SAVEEXEC_B32 : SOP1_Real_gfx10<0x040>; defm S_NAND_SAVEEXEC_B32 : SOP1_Real_gfx10<0x041>; defm S_NOR_SAVEEXEC_B32 : SOP1_Real_gfx10<0x042>; defm S_XNOR_SAVEEXEC_B32 : SOP1_Real_gfx10<0x043>; defm S_ANDN1_SAVEEXEC_B32 : SOP1_Real_gfx10<0x044>; defm S_ORN1_SAVEEXEC_B32 : SOP1_Real_gfx10<0x045>; defm S_ANDN1_WREXEC_B32 : SOP1_Real_gfx10<0x046>; defm S_ANDN2_WREXEC_B32 : SOP1_Real_gfx10<0x047>; defm S_MOVRELSD_2_B32 : SOP1_Real_gfx10<0x049>; //===----------------------------------------------------------------------===// // SOP1 - GFX6, GFX7, GFX10, GFX11. //===----------------------------------------------------------------------===// multiclass SOP1_Real_gfx6_gfx7 op> { defvar ps = !cast(NAME); def _gfx6_gfx7 : SOP1_Real, Select_gfx6_gfx7; } multiclass SOP1_Real_gfx6_gfx7_gfx10 op> : SOP1_Real_gfx6_gfx7, SOP1_Real_gfx10; multiclass SOP1_Real_gfx6_gfx7_gfx10_gfx11_gfx12 op> : SOP1_Real_gfx6_gfx7, SOP1_Real_gfx10_gfx11_gfx12; defm S_CBRANCH_JOIN : SOP1_Real_gfx6_gfx7<0x032>; defm S_MOV_B32 : SOP1_Real_gfx6_gfx7_gfx10<0x003>; defm S_MOV_B64 : SOP1_Real_gfx6_gfx7_gfx10<0x004>; defm S_CMOV_B32 : SOP1_Real_gfx6_gfx7_gfx10<0x005>; defm S_CMOV_B64 : SOP1_Real_gfx6_gfx7_gfx10<0x006>; defm S_NOT_B32 : SOP1_Real_gfx6_gfx7_gfx10<0x007>; defm S_NOT_B64 : SOP1_Real_gfx6_gfx7_gfx10<0x008>; defm S_WQM_B32 : SOP1_Real_gfx6_gfx7_gfx10<0x009>; defm S_WQM_B64 : SOP1_Real_gfx6_gfx7_gfx10<0x00a>; defm S_BREV_B32 : SOP1_Real_gfx6_gfx7_gfx10<0x00b>; defm S_BREV_B64 : SOP1_Real_gfx6_gfx7_gfx10<0x00c>; defm S_BCNT0_I32_B32 : SOP1_Real_gfx6_gfx7_gfx10<0x00d>; defm S_BCNT0_I32_B64 : SOP1_Real_gfx6_gfx7_gfx10<0x00e>; defm S_BCNT1_I32_B32 : SOP1_Real_gfx6_gfx7_gfx10<0x00f>; defm S_BCNT1_I32_B64 : SOP1_Real_gfx6_gfx7_gfx10<0x010>; defm S_FF0_I32_B32 : SOP1_Real_gfx6_gfx7_gfx10<0x011>; defm S_FF0_I32_B64 : SOP1_Real_gfx6_gfx7_gfx10<0x012>; defm S_FF1_I32_B32 : SOP1_Real_gfx6_gfx7_gfx10<0x013>; defm S_FF1_I32_B64 : SOP1_Real_gfx6_gfx7_gfx10<0x014>; defm S_FLBIT_I32_B32 : SOP1_Real_gfx6_gfx7_gfx10<0x015>; defm S_FLBIT_I32_B64 : SOP1_Real_gfx6_gfx7_gfx10<0x016>; defm S_FLBIT_I32 : SOP1_Real_gfx6_gfx7_gfx10<0x017>; defm S_FLBIT_I32_I64 : SOP1_Real_gfx6_gfx7_gfx10<0x018>; defm S_SEXT_I32_I8 : SOP1_Real_gfx6_gfx7_gfx10<0x019>; defm S_SEXT_I32_I16 : SOP1_Real_gfx6_gfx7_gfx10<0x01a>; defm S_BITSET0_B32 : SOP1_Real_gfx6_gfx7_gfx10<0x01b>; defm S_BITSET0_B64 : SOP1_Real_gfx6_gfx7_gfx10<0x01c>; defm S_BITSET1_B32 : SOP1_Real_gfx6_gfx7_gfx10<0x01d>; defm S_BITSET1_B64 : SOP1_Real_gfx6_gfx7_gfx10<0x01e>; defm S_GETPC_B64 : SOP1_Real_gfx6_gfx7_gfx10<0x01f>; defm S_SETPC_B64 : SOP1_Real_gfx6_gfx7_gfx10<0x020>; defm S_SWAPPC_B64 : SOP1_Real_gfx6_gfx7_gfx10<0x021>; defm S_RFE_B64 : SOP1_Real_gfx6_gfx7_gfx10<0x022>; defm S_AND_SAVEEXEC_B64 : SOP1_Real_gfx6_gfx7_gfx10<0x024>; defm S_OR_SAVEEXEC_B64 : SOP1_Real_gfx6_gfx7_gfx10<0x025>; defm S_XOR_SAVEEXEC_B64 : SOP1_Real_gfx6_gfx7_gfx10<0x026>; defm S_ANDN2_SAVEEXEC_B64 : SOP1_Real_gfx6_gfx7_gfx10<0x027>; defm S_ORN2_SAVEEXEC_B64 : SOP1_Real_gfx6_gfx7_gfx10<0x028>; defm S_NAND_SAVEEXEC_B64 : SOP1_Real_gfx6_gfx7_gfx10<0x029>; defm S_NOR_SAVEEXEC_B64 : SOP1_Real_gfx6_gfx7_gfx10<0x02a>; defm S_XNOR_SAVEEXEC_B64 : SOP1_Real_gfx6_gfx7_gfx10_gfx11_gfx12<0x02b>; defm S_QUADMASK_B32 : SOP1_Real_gfx6_gfx7_gfx10<0x02c>; defm S_QUADMASK_B64 : SOP1_Real_gfx6_gfx7_gfx10<0x02d>; defm S_MOVRELS_B32 : SOP1_Real_gfx6_gfx7_gfx10<0x02e>; defm S_MOVRELS_B64 : SOP1_Real_gfx6_gfx7_gfx10<0x02f>; defm S_MOVRELD_B32 : SOP1_Real_gfx6_gfx7_gfx10<0x030>; defm S_MOVRELD_B64 : SOP1_Real_gfx6_gfx7_gfx10<0x031>; defm S_ABS_I32 : SOP1_Real_gfx6_gfx7_gfx10<0x034>; //===----------------------------------------------------------------------===// // SOP2 - GFX12 //===----------------------------------------------------------------------===// multiclass SOP2_Real_gfx12 op, string name = !tolower(NAME)> { defvar ps = !cast(NAME); def _gfx12 : SOP2_Real32, Select; if !ne(ps.Mnemonic, name) then def : AMDGPUMnemonicAlias { let AssemblerPredicate = isGFX12Plus; } } defm S_MINIMUM_F32 : SOP2_Real_gfx12<0x04f>; defm S_MAXIMUM_F32 : SOP2_Real_gfx12<0x050>; defm S_MINIMUM_F16 : SOP2_Real_gfx12<0x051>; defm S_MAXIMUM_F16 : SOP2_Real_gfx12<0x052>; //===----------------------------------------------------------------------===// // SOP2 - GFX11, GFX12. //===----------------------------------------------------------------------===// multiclass SOP2_Real_gfx11 op, string name = !tolower(NAME)> { defvar ps = !cast(NAME); def _gfx11 : SOP2_Real32, Select; if !ne(ps.Mnemonic, name) then def : AMDGPUMnemonicAlias { let AssemblerPredicate = isGFX11Only; } } multiclass SOP2_Real_gfx11_gfx12 op, string name = !tolower(NAME)> : SOP2_Real_gfx11, SOP2_Real_gfx12; defm S_ABSDIFF_I32 : SOP2_Real_gfx11_gfx12<0x006>; defm S_LSHL_B32 : SOP2_Real_gfx11_gfx12<0x008>; defm S_LSHL_B64 : SOP2_Real_gfx11_gfx12<0x009>; defm S_LSHR_B32 : SOP2_Real_gfx11_gfx12<0x00a>; defm S_LSHR_B64 : SOP2_Real_gfx11_gfx12<0x00b>; defm S_ASHR_I32 : SOP2_Real_gfx11_gfx12<0x00c>; defm S_ASHR_I64 : SOP2_Real_gfx11_gfx12<0x00d>; defm S_LSHL1_ADD_U32 : SOP2_Real_gfx11_gfx12<0x00e>; defm S_LSHL2_ADD_U32 : SOP2_Real_gfx11_gfx12<0x00f>; defm S_LSHL3_ADD_U32 : SOP2_Real_gfx11_gfx12<0x010>; defm S_LSHL4_ADD_U32 : SOP2_Real_gfx11_gfx12<0x011>; defm S_MIN_I32 : SOP2_Real_gfx11_gfx12<0x012>; defm S_MIN_U32 : SOP2_Real_gfx11_gfx12<0x013>; defm S_MAX_I32 : SOP2_Real_gfx11_gfx12<0x014>; defm S_MAX_U32 : SOP2_Real_gfx11_gfx12<0x015>; defm S_AND_B32 : SOP2_Real_gfx11_gfx12<0x016>; defm S_AND_B64 : SOP2_Real_gfx11_gfx12<0x017>; defm S_OR_B32 : SOP2_Real_gfx11_gfx12<0x018>; defm S_OR_B64 : SOP2_Real_gfx11_gfx12<0x019>; defm S_XOR_B32 : SOP2_Real_gfx11_gfx12<0x01a>; defm S_XOR_B64 : SOP2_Real_gfx11_gfx12<0x01b>; defm S_NAND_B32 : SOP2_Real_gfx11_gfx12<0x01c>; defm S_NAND_B64 : SOP2_Real_gfx11_gfx12<0x01d>; defm S_NOR_B32 : SOP2_Real_gfx11_gfx12<0x01e>; defm S_NOR_B64 : SOP2_Real_gfx11_gfx12<0x01f>; defm S_XNOR_B32 : SOP2_Real_gfx11_gfx12<0x020>; defm S_XNOR_B64 : SOP2_Real_gfx11_gfx12<0x021>; defm S_ANDN2_B32 : SOP2_Real_gfx11_gfx12<0x022, "s_and_not1_b32">; defm S_ANDN2_B64 : SOP2_Real_gfx11_gfx12<0x023, "s_and_not1_b64">; defm S_ORN2_B32 : SOP2_Real_gfx11_gfx12<0x024, "s_or_not1_b32">; defm S_ORN2_B64 : SOP2_Real_gfx11_gfx12<0x025, "s_or_not1_b64">; defm S_BFE_U32 : SOP2_Real_gfx11_gfx12<0x026>; defm S_BFE_I32 : SOP2_Real_gfx11_gfx12<0x027>; defm S_BFE_U64 : SOP2_Real_gfx11_gfx12<0x028>; defm S_BFE_I64 : SOP2_Real_gfx11_gfx12<0x029>; defm S_BFM_B32 : SOP2_Real_gfx11_gfx12<0x02a>; defm S_BFM_B64 : SOP2_Real_gfx11_gfx12<0x02b>; defm S_MUL_I32 : SOP2_Real_gfx11_gfx12<0x02c>; defm S_MUL_HI_U32 : SOP2_Real_gfx11_gfx12<0x02d>; defm S_MUL_HI_I32 : SOP2_Real_gfx11_gfx12<0x02e>; defm S_CSELECT_B32 : SOP2_Real_gfx11_gfx12<0x030>; defm S_CSELECT_B64 : SOP2_Real_gfx11_gfx12<0x031>; defm S_PACK_HL_B32_B16 : SOP2_Real_gfx11_gfx12<0x035>; defm S_ADD_U64 : SOP2_Real_gfx12<0x053, "s_add_nc_u64">; defm S_SUB_U64 : SOP2_Real_gfx12<0x054, "s_sub_nc_u64">; defm S_MUL_U64 : SOP2_Real_gfx12<0x055>; //===----------------------------------------------------------------------===// // SOP2 - GFX1150, GFX12 //===----------------------------------------------------------------------===// multiclass SOP2_Real_FMAK_gfx12 op> { def _gfx12 : SOP2_Real64(NAME)>, Select(NAME).PseudoInstr>; } multiclass SOP2_Real_FMAK_gfx11 op> { def _gfx11 : SOP2_Real64(NAME)>, Select(NAME).PseudoInstr>; } multiclass SOP2_Real_FMAK_gfx11_gfx12 op> : SOP2_Real_FMAK_gfx11, SOP2_Real_FMAK_gfx12; defm S_ADD_F32 : SOP2_Real_gfx11_gfx12<0x040>; defm S_SUB_F32 : SOP2_Real_gfx11_gfx12<0x041>; defm S_MUL_F32 : SOP2_Real_gfx11_gfx12<0x044>; defm S_FMAAK_F32 : SOP2_Real_FMAK_gfx11_gfx12<0x045>; defm S_FMAMK_F32 : SOP2_Real_FMAK_gfx11_gfx12<0x046>; defm S_FMAC_F32 : SOP2_Real_gfx11_gfx12<0x047>; defm S_CVT_PK_RTZ_F16_F32 : SOP2_Real_gfx11_gfx12<0x048>; defm S_ADD_F16 : SOP2_Real_gfx11_gfx12<0x049>; defm S_SUB_F16 : SOP2_Real_gfx11_gfx12<0x04a>; defm S_MUL_F16 : SOP2_Real_gfx11_gfx12<0x04d>; defm S_FMAC_F16 : SOP2_Real_gfx11_gfx12<0x04e>; //===----------------------------------------------------------------------===// // SOP2 - GFX1150 //===----------------------------------------------------------------------===// multiclass SOP2_Real_gfx11_Renamed_gfx12 op, string gfx12_name> : SOP2_Real_gfx11, SOP2_Real_gfx12; defm S_MIN_F32 : SOP2_Real_gfx11_Renamed_gfx12<0x042, "s_min_num_f32">; defm S_MAX_F32 : SOP2_Real_gfx11_Renamed_gfx12<0x043, "s_max_num_f32">; defm S_MIN_F16 : SOP2_Real_gfx11_Renamed_gfx12<0x04b, "s_min_num_f16">; defm S_MAX_F16 : SOP2_Real_gfx11_Renamed_gfx12<0x04c, "s_max_num_f16">; //===----------------------------------------------------------------------===// // SOP2 - GFX10. //===----------------------------------------------------------------------===// multiclass SOP2_Real_gfx10 op> { defvar ps = !cast(NAME); def _gfx10 : SOP2_Real32, Select; } multiclass SOP2_Real_gfx10_gfx11_gfx12 op> : SOP2_Real_gfx10, SOP2_Real_gfx11_gfx12; defm S_LSHL1_ADD_U32 : SOP2_Real_gfx10<0x02e>; defm S_LSHL2_ADD_U32 : SOP2_Real_gfx10<0x02f>; defm S_LSHL3_ADD_U32 : SOP2_Real_gfx10<0x030>; defm S_LSHL4_ADD_U32 : SOP2_Real_gfx10<0x031>; defm S_PACK_LL_B32_B16 : SOP2_Real_gfx10_gfx11_gfx12<0x032>; defm S_PACK_LH_B32_B16 : SOP2_Real_gfx10_gfx11_gfx12<0x033>; defm S_PACK_HH_B32_B16 : SOP2_Real_gfx10_gfx11_gfx12<0x034>; defm S_MUL_HI_U32 : SOP2_Real_gfx10<0x035>; defm S_MUL_HI_I32 : SOP2_Real_gfx10<0x036>; //===----------------------------------------------------------------------===// // SOP2 - GFX6, GFX7. //===----------------------------------------------------------------------===// multiclass SOP2_Real_gfx6_gfx7 op> { defvar ps = !cast(NAME); def _gfx6_gfx7 : SOP2_Real32, Select_gfx6_gfx7; } multiclass SOP2_Real_gfx6_gfx7_gfx10 op> : SOP2_Real_gfx6_gfx7, SOP2_Real_gfx10; multiclass SOP2_Real_gfx6_gfx7_gfx10_gfx11_Renamed_gfx12 op, string gfx12_name> : SOP2_Real_gfx6_gfx7, SOP2_Real_gfx10, SOP2_Real_gfx11, SOP2_Real_gfx12; defm S_CBRANCH_G_FORK : SOP2_Real_gfx6_gfx7<0x02b>; defm S_ADD_U32 : SOP2_Real_gfx6_gfx7_gfx10_gfx11_Renamed_gfx12<0x000, "s_add_co_u32">; defm S_SUB_U32 : SOP2_Real_gfx6_gfx7_gfx10_gfx11_Renamed_gfx12<0x001, "s_sub_co_u32">; defm S_ADD_I32 : SOP2_Real_gfx6_gfx7_gfx10_gfx11_Renamed_gfx12<0x002, "s_add_co_i32">; defm S_SUB_I32 : SOP2_Real_gfx6_gfx7_gfx10_gfx11_Renamed_gfx12<0x003, "s_sub_co_i32">; defm S_ADDC_U32 : SOP2_Real_gfx6_gfx7_gfx10_gfx11_Renamed_gfx12<0x004, "s_add_co_ci_u32">; defm S_SUBB_U32 : SOP2_Real_gfx6_gfx7_gfx10_gfx11_Renamed_gfx12<0x005, "s_sub_co_ci_u32">; defm S_MIN_I32 : SOP2_Real_gfx6_gfx7_gfx10<0x006>; defm S_MIN_U32 : SOP2_Real_gfx6_gfx7_gfx10<0x007>; defm S_MAX_I32 : SOP2_Real_gfx6_gfx7_gfx10<0x008>; defm S_MAX_U32 : SOP2_Real_gfx6_gfx7_gfx10<0x009>; defm S_CSELECT_B32 : SOP2_Real_gfx6_gfx7_gfx10<0x00a>; defm S_CSELECT_B64 : SOP2_Real_gfx6_gfx7_gfx10<0x00b>; defm S_AND_B32 : SOP2_Real_gfx6_gfx7_gfx10<0x00e>; defm S_AND_B64 : SOP2_Real_gfx6_gfx7_gfx10<0x00f>; defm S_OR_B32 : SOP2_Real_gfx6_gfx7_gfx10<0x010>; defm S_OR_B64 : SOP2_Real_gfx6_gfx7_gfx10<0x011>; defm S_XOR_B32 : SOP2_Real_gfx6_gfx7_gfx10<0x012>; defm S_XOR_B64 : SOP2_Real_gfx6_gfx7_gfx10<0x013>; defm S_ANDN2_B32 : SOP2_Real_gfx6_gfx7_gfx10<0x014>; defm S_ANDN2_B64 : SOP2_Real_gfx6_gfx7_gfx10<0x015>; defm S_ORN2_B32 : SOP2_Real_gfx6_gfx7_gfx10<0x016>; defm S_ORN2_B64 : SOP2_Real_gfx6_gfx7_gfx10<0x017>; defm S_NAND_B32 : SOP2_Real_gfx6_gfx7_gfx10<0x018>; defm S_NAND_B64 : SOP2_Real_gfx6_gfx7_gfx10<0x019>; defm S_NOR_B32 : SOP2_Real_gfx6_gfx7_gfx10<0x01a>; defm S_NOR_B64 : SOP2_Real_gfx6_gfx7_gfx10<0x01b>; defm S_XNOR_B32 : SOP2_Real_gfx6_gfx7_gfx10<0x01c>; defm S_XNOR_B64 : SOP2_Real_gfx6_gfx7_gfx10<0x01d>; defm S_LSHL_B32 : SOP2_Real_gfx6_gfx7_gfx10<0x01e>; defm S_LSHL_B64 : SOP2_Real_gfx6_gfx7_gfx10<0x01f>; defm S_LSHR_B32 : SOP2_Real_gfx6_gfx7_gfx10<0x020>; defm S_LSHR_B64 : SOP2_Real_gfx6_gfx7_gfx10<0x021>; defm S_ASHR_I32 : SOP2_Real_gfx6_gfx7_gfx10<0x022>; defm S_ASHR_I64 : SOP2_Real_gfx6_gfx7_gfx10<0x023>; defm S_BFM_B32 : SOP2_Real_gfx6_gfx7_gfx10<0x024>; defm S_BFM_B64 : SOP2_Real_gfx6_gfx7_gfx10<0x025>; defm S_MUL_I32 : SOP2_Real_gfx6_gfx7_gfx10<0x026>; defm S_BFE_U32 : SOP2_Real_gfx6_gfx7_gfx10<0x027>; defm S_BFE_I32 : SOP2_Real_gfx6_gfx7_gfx10<0x028>; defm S_BFE_U64 : SOP2_Real_gfx6_gfx7_gfx10<0x029>; defm S_BFE_I64 : SOP2_Real_gfx6_gfx7_gfx10<0x02a>; defm S_ABSDIFF_I32 : SOP2_Real_gfx6_gfx7_gfx10<0x02c>; //===----------------------------------------------------------------------===// // SOPK - GFX11, GFX12. //===----------------------------------------------------------------------===// multiclass SOPK_Real32_gfx12 op, string name = !tolower(NAME)> { defvar ps = !cast(NAME); def _gfx12 : SOPK_Real32, Select; if !ne(ps.Mnemonic, name) then def : AMDGPUMnemonicAlias { let AssemblerPredicate = isGFX12Plus; } } multiclass SOPK_Real32_gfx11 op> { def _gfx11 : SOPK_Real32(NAME)>, Select(NAME).PseudoInstr>; } multiclass SOPK_Real64_gfx12 op> { def _gfx12 : SOPK_Real64(NAME)>, Select(NAME).PseudoInstr>; } multiclass SOPK_Real64_gfx11 op> { def _gfx11 : SOPK_Real64(NAME)>, Select(NAME).PseudoInstr>; } multiclass SOPK_Real32_gfx11_gfx12 op> : SOPK_Real32_gfx11, SOPK_Real32_gfx12; multiclass SOPK_Real64_gfx11_gfx12 op> : SOPK_Real64_gfx11, SOPK_Real64_gfx12; defm S_GETREG_B32 : SOPK_Real32_gfx11_gfx12<0x011>; defm S_SETREG_B32 : SOPK_Real32_gfx11_gfx12<0x012>; defm S_SETREG_IMM32_B32 : SOPK_Real64_gfx11_gfx12<0x013>; defm S_CALL_B64 : SOPK_Real32_gfx11_gfx12<0x014>; defm S_SUBVECTOR_LOOP_BEGIN : SOPK_Real32_gfx11<0x016>; defm S_SUBVECTOR_LOOP_END : SOPK_Real32_gfx11<0x017>; defm S_WAITCNT_VSCNT : SOPK_Real32_gfx11<0x018>; defm S_WAITCNT_VMCNT : SOPK_Real32_gfx11<0x019>; defm S_WAITCNT_EXPCNT : SOPK_Real32_gfx11<0x01a>; defm S_WAITCNT_LGKMCNT : SOPK_Real32_gfx11<0x01b>; //===----------------------------------------------------------------------===// // SOPK - GFX10. //===----------------------------------------------------------------------===// multiclass SOPK_Real32_gfx10 op> { defvar ps = !cast(NAME); def _gfx10 : SOPK_Real32, Select; } multiclass SOPK_Real64_gfx10 op> { defvar ps = !cast(NAME); def _gfx10 : SOPK_Real64, Select; } multiclass SOPK_Real32_gfx10_gfx11 op> : SOPK_Real32_gfx10, SOPK_Real32_gfx11; multiclass SOPK_Real32_gfx10_gfx11_gfx12 op> : SOPK_Real32_gfx10, SOPK_Real32_gfx11_gfx12; defm S_VERSION : SOPK_Real32_gfx10_gfx11_gfx12<0x001>; defm S_CALL_B64 : SOPK_Real32_gfx10<0x016>; defm S_WAITCNT_VSCNT : SOPK_Real32_gfx10<0x017>; defm S_WAITCNT_VMCNT : SOPK_Real32_gfx10<0x018>; defm S_WAITCNT_EXPCNT : SOPK_Real32_gfx10<0x019>; defm S_WAITCNT_LGKMCNT : SOPK_Real32_gfx10<0x01a>; defm S_SUBVECTOR_LOOP_BEGIN : SOPK_Real32_gfx10<0x01b>; defm S_SUBVECTOR_LOOP_END : SOPK_Real32_gfx10<0x01c>; //===----------------------------------------------------------------------===// // SOPK - GFX6, GFX7. //===----------------------------------------------------------------------===// multiclass SOPK_Real32_gfx6_gfx7 op> { defvar ps = !cast(NAME); def _gfx6_gfx7 : SOPK_Real32, Select_gfx6_gfx7; } multiclass SOPK_Real64_gfx6_gfx7 op> { defvar ps = !cast(NAME); def _gfx6_gfx7 : SOPK_Real64, Select_gfx6_gfx7; } multiclass SOPK_Real32_gfx6_gfx7_gfx10 op> : SOPK_Real32_gfx6_gfx7, SOPK_Real32_gfx10; multiclass SOPK_Real64_gfx6_gfx7_gfx10 op> : SOPK_Real64_gfx6_gfx7, SOPK_Real64_gfx10; multiclass SOPK_Real32_gfx6_gfx7_gfx10_gfx11 op> : SOPK_Real32_gfx6_gfx7, SOPK_Real32_gfx10_gfx11; multiclass SOPK_Real32_gfx6_gfx7_gfx10_gfx11_gfx12 op> : SOPK_Real32_gfx6_gfx7, SOPK_Real32_gfx10_gfx11_gfx12; multiclass SOPK_Real32_gfx6_gfx7_gfx10_gfx11_Renamed_gfx12 op, string gfx12_name> : SOPK_Real32_gfx6_gfx7, SOPK_Real32_gfx10, SOPK_Real32_gfx11, SOPK_Real32_gfx12; defm S_CBRANCH_I_FORK : SOPK_Real32_gfx6_gfx7<0x011>; defm S_MOVK_I32 : SOPK_Real32_gfx6_gfx7_gfx10_gfx11_gfx12<0x000>; defm S_CMOVK_I32 : SOPK_Real32_gfx6_gfx7_gfx10_gfx11_gfx12<0x002>; defm S_CMPK_EQ_I32 : SOPK_Real32_gfx6_gfx7_gfx10_gfx11<0x003>; defm S_CMPK_LG_I32 : SOPK_Real32_gfx6_gfx7_gfx10_gfx11<0x004>; defm S_CMPK_GT_I32 : SOPK_Real32_gfx6_gfx7_gfx10_gfx11<0x005>; defm S_CMPK_GE_I32 : SOPK_Real32_gfx6_gfx7_gfx10_gfx11<0x006>; defm S_CMPK_LT_I32 : SOPK_Real32_gfx6_gfx7_gfx10_gfx11<0x007>; defm S_CMPK_LE_I32 : SOPK_Real32_gfx6_gfx7_gfx10_gfx11<0x008>; defm S_CMPK_EQ_U32 : SOPK_Real32_gfx6_gfx7_gfx10_gfx11<0x009>; defm S_CMPK_LG_U32 : SOPK_Real32_gfx6_gfx7_gfx10_gfx11<0x00a>; defm S_CMPK_GT_U32 : SOPK_Real32_gfx6_gfx7_gfx10_gfx11<0x00b>; defm S_CMPK_GE_U32 : SOPK_Real32_gfx6_gfx7_gfx10_gfx11<0x00c>; defm S_CMPK_LT_U32 : SOPK_Real32_gfx6_gfx7_gfx10_gfx11<0x00d>; defm S_CMPK_LE_U32 : SOPK_Real32_gfx6_gfx7_gfx10_gfx11<0x00e>; defm S_ADDK_I32 : SOPK_Real32_gfx6_gfx7_gfx10_gfx11_Renamed_gfx12<0x00f, "s_addk_co_i32">; defm S_MULK_I32 : SOPK_Real32_gfx6_gfx7_gfx10_gfx11_gfx12<0x010>; defm S_GETREG_B32 : SOPK_Real32_gfx6_gfx7_gfx10<0x012>; defm S_SETREG_B32 : SOPK_Real32_gfx6_gfx7_gfx10<0x013>; defm S_SETREG_IMM32_B32 : SOPK_Real64_gfx6_gfx7_gfx10<0x015>; //===----------------------------------------------------------------------===// // SOPP - GFX12 only. //===----------------------------------------------------------------------===// multiclass SOPP_Real_32_gfx12 op, string name = !tolower(NAME)> { defvar ps = !cast(NAME); def _gfx12 : SOPP_Real_32, Select; if !ne(ps.Mnemonic, name) then def : AMDGPUMnemonicAlias { let AssemblerPredicate = isGFX12Plus; } } defm S_BARRIER_WAIT : SOPP_Real_32_gfx12<0x014>; defm S_BARRIER_LEAVE : SOPP_Real_32_gfx12<0x015>; defm S_WAIT_LOADCNT : SOPP_Real_32_gfx12<0x040>; defm S_WAIT_STORECNT : SOPP_Real_32_gfx12<0x041>; defm S_WAIT_SAMPLECNT : SOPP_Real_32_gfx12<0x042>; defm S_WAIT_BVHCNT : SOPP_Real_32_gfx12<0x043>; defm S_WAIT_EXPCNT : SOPP_Real_32_gfx12<0x044>; defm S_WAIT_DSCNT : SOPP_Real_32_gfx12<0x046>; defm S_WAIT_KMCNT : SOPP_Real_32_gfx12<0x047>; defm S_WAIT_LOADCNT_DSCNT : SOPP_Real_32_gfx12<0x048>; defm S_WAIT_STORECNT_DSCNT : SOPP_Real_32_gfx12<0x049>; //===----------------------------------------------------------------------===// // SOPP - GFX11, GFX12. //===----------------------------------------------------------------------===// multiclass SOPP_Real_32_gfx11 op, string name = !tolower(NAME)> { defvar ps = !cast(NAME); def _gfx11 : SOPP_Real_32, Select, SOPPRelaxTable<0, ps.KeyName, "_gfx11">; if !ne(ps.Mnemonic, name) then def : AMDGPUMnemonicAlias { let AssemblerPredicate = isGFX11Only; } } multiclass SOPP_Real_64_gfx12 op> { def _gfx12 : SOPP_Real_64(NAME), !cast(NAME).Mnemonic>, Select(NAME).PseudoInstr>, SOPPRelaxTable<1, !cast(NAME).KeyName, "_gfx12">; } multiclass SOPP_Real_64_gfx11 op> { def _gfx11 : SOPP_Real_64(NAME), !cast(NAME).Mnemonic>, Select(NAME).PseudoInstr>, SOPPRelaxTable<1, !cast(NAME).KeyName, "_gfx11">; } multiclass SOPP_Real_32_gfx11_gfx12 op> : SOPP_Real_32_gfx11, SOPP_Real_32_gfx12; multiclass SOPP_Real_32_gfx11_Renamed_gfx12 op, string gfx12_name> : SOPP_Real_32_gfx11, SOPP_Real_32_gfx12; multiclass SOPP_Real_With_Relaxation_gfx12 op> { defm "" : SOPP_Real_32_gfx12; let isCodeGenOnly = 1 in defm _pad_s_nop : SOPP_Real_64_gfx12; } multiclass SOPP_Real_With_Relaxation_gfx11 op> { defm "" : SOPP_Real_32_gfx11; let isCodeGenOnly = 1 in defm _pad_s_nop : SOPP_Real_64_gfx11; } multiclass SOPP_Real_With_Relaxation_gfx11_gfx12op> : SOPP_Real_With_Relaxation_gfx11, SOPP_Real_With_Relaxation_gfx12; defm S_SETKILL : SOPP_Real_32_gfx11_gfx12<0x001>; defm S_SETHALT : SOPP_Real_32_gfx11_gfx12<0x002>; defm S_SLEEP : SOPP_Real_32_gfx11_gfx12<0x003>; defm S_INST_PREFETCH : SOPP_Real_32_gfx11<0x004, "s_set_inst_prefetch_distance">; defm S_CLAUSE : SOPP_Real_32_gfx11_gfx12<0x005>; defm S_DELAY_ALU : SOPP_Real_32_gfx11_gfx12<0x007>; defm S_WAITCNT_DEPCTR : SOPP_Real_32_gfx11_Renamed_gfx12<0x008, "s_wait_alu">; defm S_WAITCNT : SOPP_Real_32_gfx11_gfx12<0x009>; defm S_WAIT_IDLE : SOPP_Real_32_gfx11_gfx12<0x00a>; defm S_WAIT_EVENT : SOPP_Real_32_gfx11_gfx12<0x00b>; defm S_TRAP : SOPP_Real_32_gfx11_gfx12<0x010>; defm S_ROUND_MODE : SOPP_Real_32_gfx11_gfx12<0x011>; defm S_DENORM_MODE : SOPP_Real_32_gfx11_gfx12<0x012>; defm S_BRANCH : SOPP_Real_With_Relaxation_gfx11_gfx12<0x020>; defm S_CBRANCH_SCC0 : SOPP_Real_With_Relaxation_gfx11_gfx12<0x021>; defm S_CBRANCH_SCC1 : SOPP_Real_With_Relaxation_gfx11_gfx12<0x022>; defm S_CBRANCH_VCCZ : SOPP_Real_With_Relaxation_gfx11_gfx12<0x023>; defm S_CBRANCH_VCCNZ : SOPP_Real_With_Relaxation_gfx11_gfx12<0x024>; defm S_CBRANCH_EXECZ : SOPP_Real_With_Relaxation_gfx11_gfx12<0x025>; defm S_CBRANCH_EXECNZ : SOPP_Real_With_Relaxation_gfx11_gfx12<0x026>; defm S_CBRANCH_CDBGSYS : SOPP_Real_With_Relaxation_gfx11<0x027>; defm S_CBRANCH_CDBGUSER : SOPP_Real_With_Relaxation_gfx11<0x028>; defm S_CBRANCH_CDBGSYS_OR_USER : SOPP_Real_With_Relaxation_gfx11<0x029>; defm S_CBRANCH_CDBGSYS_AND_USER : SOPP_Real_With_Relaxation_gfx11<0x02a>; defm S_ENDPGM : SOPP_Real_32_gfx11_gfx12<0x030>; defm S_ENDPGM_SAVED : SOPP_Real_32_gfx11_gfx12<0x031>; defm S_WAKEUP : SOPP_Real_32_gfx11_gfx12<0x034>; defm S_SETPRIO : SOPP_Real_32_gfx11_gfx12<0x035>; defm S_SENDMSG : SOPP_Real_32_gfx11_gfx12<0x036>; defm S_SENDMSGHALT : SOPP_Real_32_gfx11_gfx12<0x037>; defm S_INCPERFLEVEL : SOPP_Real_32_gfx11_gfx12<0x038>; defm S_DECPERFLEVEL : SOPP_Real_32_gfx11_gfx12<0x039>; defm S_TTRACEDATA : SOPP_Real_32_gfx11_gfx12<0x03a>; defm S_TTRACEDATA_IMM : SOPP_Real_32_gfx11_gfx12<0x03b>; defm S_ICACHE_INV : SOPP_Real_32_gfx11_gfx12<0x03c>; defm S_BARRIER : SOPP_Real_32_gfx11<0x03d>; //===----------------------------------------------------------------------===// // SOPP - GFX1150, GFX12. //===----------------------------------------------------------------------===// defm S_SINGLEUSE_VDST : SOPP_Real_32_gfx11_gfx12<0x013>; //===----------------------------------------------------------------------===// // SOPP - GFX6, GFX7, GFX8, GFX9, GFX10 //===----------------------------------------------------------------------===// multiclass SOPP_Real_32_gfx6_gfx7 op> { defvar ps = !cast(NAME); def _gfx6_gfx7 : SOPP_Real_32(NAME).Mnemonic>, Select_gfx6_gfx7, SOPPRelaxTable<0, ps.KeyName, "_gfx6_gfx7">; } multiclass SOPP_Real_32_gfx8_gfx9 op> { defvar ps = !cast(NAME); def _vi : SOPP_Real_32, Select_vi, SOPPRelaxTable<0, ps.KeyName, "_vi">; } multiclass SOPP_Real_32_gfx10 op> { defvar ps = !cast(NAME); def _gfx10 : SOPP_Real_32, Select, SOPPRelaxTable<0, ps.KeyName, "_gfx10">; } multiclass SOPP_Real_32_gfx8_gfx9_gfx10 op> : SOPP_Real_32_gfx8_gfx9, SOPP_Real_32_gfx10; multiclass SOPP_Real_32_gfx6_gfx7_gfx8_gfx9 op> : SOPP_Real_32_gfx6_gfx7, SOPP_Real_32_gfx8_gfx9; multiclass SOPP_Real_32_gfx6_gfx7_gfx8_gfx9_gfx10 op> : SOPP_Real_32_gfx6_gfx7_gfx8_gfx9, SOPP_Real_32_gfx10; multiclass SOPP_Real_32_gfx6_gfx7_gfx8_gfx9_gfx10_gfx11_gfx12 op> : SOPP_Real_32_gfx6_gfx7_gfx8_gfx9_gfx10, SOPP_Real_32_gfx11_gfx12; multiclass SOPP_Real_32_gfx10_gfx11_gfx12 op> : SOPP_Real_32_gfx10, SOPP_Real_32_gfx11_gfx12; //64 bit encodings, for Relaxation multiclass SOPP_Real_64_gfx6_gfx7 op> { defvar ps = !cast(NAME); def _gfx6_gfx7 : SOPP_Real_64, Select_gfx6_gfx7, SOPPRelaxTable<1, ps.KeyName, "_gfx6_gfx7">; } multiclass SOPP_Real_64_gfx8_gfx9 op> { defvar ps = !cast(NAME); def _vi : SOPP_Real_64, Select_vi, SOPPRelaxTable<1, ps.KeyName, "_vi">; } multiclass SOPP_Real_64_gfx10 op> { defvar ps = !cast(NAME); def _gfx10 : SOPP_Real_64, Select, SOPPRelaxTable<1, ps.KeyName, "_gfx10">; } multiclass SOPP_Real_64_gfx6_gfx7_gfx8_gfx9 op> : SOPP_Real_64_gfx6_gfx7, SOPP_Real_64_gfx8_gfx9; multiclass SOPP_Real_64_gfx6_gfx7_gfx8_gfx9_gfx10 op> : SOPP_Real_64_gfx6_gfx7_gfx8_gfx9, SOPP_Real_64_gfx10; //relaxation for insts with no operands not implemented multiclass SOPP_Real_With_Relaxation_gfx6_gfx7_gfx8_gfx9_gfx10 op> { defm "" : SOPP_Real_32_gfx6_gfx7_gfx8_gfx9_gfx10; let isCodeGenOnly = 1 in defm _pad_s_nop : SOPP_Real_64_gfx6_gfx7_gfx8_gfx9_gfx10; } defm S_NOP : SOPP_Real_32_gfx6_gfx7_gfx8_gfx9_gfx10_gfx11_gfx12<0x000>; defm S_ENDPGM : SOPP_Real_32_gfx6_gfx7_gfx8_gfx9_gfx10<0x001>; defm S_WAKEUP : SOPP_Real_32_gfx8_gfx9_gfx10<0x003>; defm S_BARRIER : SOPP_Real_32_gfx6_gfx7_gfx8_gfx9_gfx10<0x00a>; defm S_WAITCNT : SOPP_Real_32_gfx6_gfx7_gfx8_gfx9_gfx10<0x00c>; defm S_SETHALT : SOPP_Real_32_gfx6_gfx7_gfx8_gfx9_gfx10<0x00d>; defm S_SETKILL : SOPP_Real_32_gfx6_gfx7_gfx8_gfx9_gfx10<0x00b>; defm S_SLEEP : SOPP_Real_32_gfx6_gfx7_gfx8_gfx9_gfx10<0x00e>; defm S_SETPRIO : SOPP_Real_32_gfx6_gfx7_gfx8_gfx9_gfx10<0x00f>; defm S_SENDMSG : SOPP_Real_32_gfx6_gfx7_gfx8_gfx9_gfx10<0x010>; defm S_SENDMSGHALT : SOPP_Real_32_gfx6_gfx7_gfx8_gfx9_gfx10<0x011>; defm S_TRAP : SOPP_Real_32_gfx6_gfx7_gfx8_gfx9_gfx10<0x012>; defm S_ICACHE_INV : SOPP_Real_32_gfx6_gfx7_gfx8_gfx9_gfx10<0x013>; defm S_INCPERFLEVEL : SOPP_Real_32_gfx6_gfx7_gfx8_gfx9_gfx10<0x014>; defm S_DECPERFLEVEL : SOPP_Real_32_gfx6_gfx7_gfx8_gfx9_gfx10<0x015>; defm S_TTRACEDATA : SOPP_Real_32_gfx6_gfx7_gfx8_gfx9_gfx10<0x016>; defm S_ENDPGM_SAVED : SOPP_Real_32_gfx6_gfx7_gfx8_gfx9_gfx10<0x01B>; defm S_SET_GPR_IDX_OFF : SOPP_Real_32_gfx8_gfx9<0x01c>; defm S_SET_GPR_IDX_MODE : SOPP_Real_32_gfx8_gfx9<0x01d>; defm S_ENDPGM_ORDERED_PS_DONE : SOPP_Real_32_gfx8_gfx9_gfx10<0x01e>; defm S_CODE_END : SOPP_Real_32_gfx10_gfx11_gfx12<0x01f>; defm S_INST_PREFETCH : SOPP_Real_32_gfx10<0x020>; defm S_CLAUSE : SOPP_Real_32_gfx10<0x021>; defm S_WAIT_IDLE : SOPP_Real_32_gfx10<0x022>; defm S_WAITCNT_DEPCTR : SOPP_Real_32_gfx10<0x023>; defm S_ROUND_MODE : SOPP_Real_32_gfx10<0x024>; defm S_DENORM_MODE : SOPP_Real_32_gfx10<0x025>; defm S_TTRACEDATA_IMM : SOPP_Real_32_gfx10<0x028>; let isBranch = 1 in { defm S_BRANCH : SOPP_Real_With_Relaxation_gfx6_gfx7_gfx8_gfx9_gfx10<0x002>; defm S_CBRANCH_SCC0 : SOPP_Real_With_Relaxation_gfx6_gfx7_gfx8_gfx9_gfx10<0x004>; defm S_CBRANCH_SCC1 : SOPP_Real_With_Relaxation_gfx6_gfx7_gfx8_gfx9_gfx10<0x005>; defm S_CBRANCH_VCCZ : SOPP_Real_With_Relaxation_gfx6_gfx7_gfx8_gfx9_gfx10<0x006>; defm S_CBRANCH_VCCNZ : SOPP_Real_With_Relaxation_gfx6_gfx7_gfx8_gfx9_gfx10<0x007>; defm S_CBRANCH_EXECZ : SOPP_Real_With_Relaxation_gfx6_gfx7_gfx8_gfx9_gfx10<0x008>; defm S_CBRANCH_EXECNZ : SOPP_Real_With_Relaxation_gfx6_gfx7_gfx8_gfx9_gfx10<0x009>; defm S_CBRANCH_CDBGSYS : SOPP_Real_With_Relaxation_gfx6_gfx7_gfx8_gfx9_gfx10<0x017>; defm S_CBRANCH_CDBGUSER : SOPP_Real_With_Relaxation_gfx6_gfx7_gfx8_gfx9_gfx10<0x018>; defm S_CBRANCH_CDBGSYS_OR_USER : SOPP_Real_With_Relaxation_gfx6_gfx7_gfx8_gfx9_gfx10<0x019>; defm S_CBRANCH_CDBGSYS_AND_USER : SOPP_Real_With_Relaxation_gfx6_gfx7_gfx8_gfx9_gfx10<0x01A>; } //===----------------------------------------------------------------------===// // SOPC - GFX11, GFX12. //===----------------------------------------------------------------------===// multiclass SOPC_Real_gfx12 op> { def _gfx12 : SOPC_Real(NAME)>, Select(NAME).PseudoInstr>; } multiclass SOPC_Real_gfx11 op> { def _gfx11 : SOPC_Real(NAME)>, Select(NAME).PseudoInstr>; } multiclass SOPC_Real_gfx11_gfx12 op> : SOPC_Real_gfx11, SOPC_Real_gfx12; defm S_CMP_EQ_U64 : SOPC_Real_gfx11_gfx12<0x10>; defm S_CMP_LG_U64 : SOPC_Real_gfx11_gfx12<0x11>; //===----------------------------------------------------------------------===// // SOPC - GFX1150, GFX12 //===----------------------------------------------------------------------===// defm S_CMP_LT_F32 : SOPC_Real_gfx11_gfx12<0x41>; defm S_CMP_EQ_F32 : SOPC_Real_gfx11_gfx12<0x42>; defm S_CMP_LE_F32 : SOPC_Real_gfx11_gfx12<0x43>; defm S_CMP_GT_F32 : SOPC_Real_gfx11_gfx12<0x44>; defm S_CMP_LG_F32 : SOPC_Real_gfx11_gfx12<0x45>; defm S_CMP_GE_F32 : SOPC_Real_gfx11_gfx12<0x46>; defm S_CMP_O_F32 : SOPC_Real_gfx11_gfx12<0x47>; defm S_CMP_U_F32 : SOPC_Real_gfx11_gfx12<0x48>; defm S_CMP_NGE_F32 : SOPC_Real_gfx11_gfx12<0x49>; defm S_CMP_NLG_F32 : SOPC_Real_gfx11_gfx12<0x4a>; defm S_CMP_NGT_F32 : SOPC_Real_gfx11_gfx12<0x4b>; defm S_CMP_NLE_F32 : SOPC_Real_gfx11_gfx12<0x4c>; defm S_CMP_NEQ_F32 : SOPC_Real_gfx11_gfx12<0x4d>; defm S_CMP_NLT_F32 : SOPC_Real_gfx11_gfx12<0x4e>; defm S_CMP_LT_F16 : SOPC_Real_gfx11_gfx12<0x51>; defm S_CMP_EQ_F16 : SOPC_Real_gfx11_gfx12<0x52>; defm S_CMP_LE_F16 : SOPC_Real_gfx11_gfx12<0x53>; defm S_CMP_GT_F16 : SOPC_Real_gfx11_gfx12<0x54>; defm S_CMP_LG_F16 : SOPC_Real_gfx11_gfx12<0x55>; defm S_CMP_GE_F16 : SOPC_Real_gfx11_gfx12<0x56>; defm S_CMP_O_F16 : SOPC_Real_gfx11_gfx12<0x57>; defm S_CMP_U_F16 : SOPC_Real_gfx11_gfx12<0x58>; defm S_CMP_NGE_F16 : SOPC_Real_gfx11_gfx12<0x59>; defm S_CMP_NLG_F16 : SOPC_Real_gfx11_gfx12<0x5a>; defm S_CMP_NGT_F16 : SOPC_Real_gfx11_gfx12<0x5b>; defm S_CMP_NLE_F16 : SOPC_Real_gfx11_gfx12<0x5c>; defm S_CMP_NEQ_F16 : SOPC_Real_gfx11_gfx12<0x5d>; defm S_CMP_NLT_F16 : SOPC_Real_gfx11_gfx12<0x5e>; //===----------------------------------------------------------------------===// // SOPC - GFX6, GFX7, GFX8, GFX9, GFX10 //===----------------------------------------------------------------------===// multiclass SOPC_Real_gfx6_gfx7 op> { defvar ps = !cast(NAME); def _gfx6_gfx7 : SOPC_Real, Select_gfx6_gfx7; } multiclass SOPC_Real_gfx8_gfx9 op> { defvar ps = !cast(NAME); def _vi : SOPC_Real, Select_vi; } multiclass SOPC_Real_gfx10 op> { defvar ps = !cast(NAME); def _gfx10 : SOPC_Real, Select; } multiclass SOPC_Real_gfx8_gfx9_gfx10 op> : SOPC_Real_gfx8_gfx9, SOPC_Real_gfx10; multiclass SOPC_Real_gfx6_gfx7_gfx8_gfx9 op> : SOPC_Real_gfx6_gfx7, SOPC_Real_gfx8_gfx9; multiclass SOPC_Real_gfx6_gfx7_gfx8_gfx9_gfx10_gfx11_gfx12 op> : SOPC_Real_gfx6_gfx7_gfx8_gfx9, SOPC_Real_gfx10, SOPC_Real_gfx11, SOPC_Real_gfx12; defm S_CMP_EQ_I32 : SOPC_Real_gfx6_gfx7_gfx8_gfx9_gfx10_gfx11_gfx12<0x00>; defm S_CMP_LG_I32 : SOPC_Real_gfx6_gfx7_gfx8_gfx9_gfx10_gfx11_gfx12<0x01>; defm S_CMP_GT_I32 : SOPC_Real_gfx6_gfx7_gfx8_gfx9_gfx10_gfx11_gfx12<0x02>; defm S_CMP_GE_I32 : SOPC_Real_gfx6_gfx7_gfx8_gfx9_gfx10_gfx11_gfx12<0x03>; defm S_CMP_LT_I32 : SOPC_Real_gfx6_gfx7_gfx8_gfx9_gfx10_gfx11_gfx12<0x04>; defm S_CMP_LE_I32 : SOPC_Real_gfx6_gfx7_gfx8_gfx9_gfx10_gfx11_gfx12<0x05>; defm S_CMP_EQ_U32 : SOPC_Real_gfx6_gfx7_gfx8_gfx9_gfx10_gfx11_gfx12<0x06>; defm S_CMP_LG_U32 : SOPC_Real_gfx6_gfx7_gfx8_gfx9_gfx10_gfx11_gfx12<0x07>; defm S_CMP_GT_U32 : SOPC_Real_gfx6_gfx7_gfx8_gfx9_gfx10_gfx11_gfx12<0x08>; defm S_CMP_GE_U32 : SOPC_Real_gfx6_gfx7_gfx8_gfx9_gfx10_gfx11_gfx12<0x09>; defm S_CMP_LT_U32 : SOPC_Real_gfx6_gfx7_gfx8_gfx9_gfx10_gfx11_gfx12<0x0a>; defm S_CMP_LE_U32 : SOPC_Real_gfx6_gfx7_gfx8_gfx9_gfx10_gfx11_gfx12<0x0b>; defm S_BITCMP0_B32 : SOPC_Real_gfx6_gfx7_gfx8_gfx9_gfx10_gfx11_gfx12<0x0c>; defm S_BITCMP1_B32 : SOPC_Real_gfx6_gfx7_gfx8_gfx9_gfx10_gfx11_gfx12<0x0d>; defm S_BITCMP0_B64 : SOPC_Real_gfx6_gfx7_gfx8_gfx9_gfx10_gfx11_gfx12<0x0e>; defm S_BITCMP1_B64 : SOPC_Real_gfx6_gfx7_gfx8_gfx9_gfx10_gfx11_gfx12<0x0f>; defm S_SETVSKIP : SOPC_Real_gfx6_gfx7_gfx8_gfx9<0x10>; defm S_SET_GPR_IDX_ON : SOPC_Real_gfx8_gfx9<0x11>; defm S_CMP_EQ_U64 : SOPC_Real_gfx8_gfx9_gfx10<0x12>; defm S_CMP_LG_U64 : SOPC_Real_gfx8_gfx9_gfx10<0x13>; //===----------------------------------------------------------------------===// // GFX8 (VI), GFX9. //===----------------------------------------------------------------------===// class SOP1_Real_vi op, SOP1_Pseudo ps> : SOP1_Real, Select_vi; class SOP2_Real_vi op, SOP2_Pseudo ps> : SOP2_Real32, Select_vi; class SOPK_Real_vi op, SOPK_Pseudo ps> : SOPK_Real32, Select_vi; def S_MOV_B32_vi : SOP1_Real_vi <0x00, S_MOV_B32>; def S_MOV_B64_vi : SOP1_Real_vi <0x01, S_MOV_B64>; def S_CMOV_B32_vi : SOP1_Real_vi <0x02, S_CMOV_B32>; def S_CMOV_B64_vi : SOP1_Real_vi <0x03, S_CMOV_B64>; def S_NOT_B32_vi : SOP1_Real_vi <0x04, S_NOT_B32>; def S_NOT_B64_vi : SOP1_Real_vi <0x05, S_NOT_B64>; def S_WQM_B32_vi : SOP1_Real_vi <0x06, S_WQM_B32>; def S_WQM_B64_vi : SOP1_Real_vi <0x07, S_WQM_B64>; def S_BREV_B32_vi : SOP1_Real_vi <0x08, S_BREV_B32>; def S_BREV_B64_vi : SOP1_Real_vi <0x09, S_BREV_B64>; def S_BCNT0_I32_B32_vi : SOP1_Real_vi <0x0a, S_BCNT0_I32_B32>; def S_BCNT0_I32_B64_vi : SOP1_Real_vi <0x0b, S_BCNT0_I32_B64>; def S_BCNT1_I32_B32_vi : SOP1_Real_vi <0x0c, S_BCNT1_I32_B32>; def S_BCNT1_I32_B64_vi : SOP1_Real_vi <0x0d, S_BCNT1_I32_B64>; def S_FF0_I32_B32_vi : SOP1_Real_vi <0x0e, S_FF0_I32_B32>; def S_FF0_I32_B64_vi : SOP1_Real_vi <0x0f, S_FF0_I32_B64>; def S_FF1_I32_B32_vi : SOP1_Real_vi <0x10, S_FF1_I32_B32>; def S_FF1_I32_B64_vi : SOP1_Real_vi <0x11, S_FF1_I32_B64>; def S_FLBIT_I32_B32_vi : SOP1_Real_vi <0x12, S_FLBIT_I32_B32>; def S_FLBIT_I32_B64_vi : SOP1_Real_vi <0x13, S_FLBIT_I32_B64>; def S_FLBIT_I32_vi : SOP1_Real_vi <0x14, S_FLBIT_I32>; def S_FLBIT_I32_I64_vi : SOP1_Real_vi <0x15, S_FLBIT_I32_I64>; def S_SEXT_I32_I8_vi : SOP1_Real_vi <0x16, S_SEXT_I32_I8>; def S_SEXT_I32_I16_vi : SOP1_Real_vi <0x17, S_SEXT_I32_I16>; def S_BITSET0_B32_vi : SOP1_Real_vi <0x18, S_BITSET0_B32>; def S_BITSET0_B64_vi : SOP1_Real_vi <0x19, S_BITSET0_B64>; def S_BITSET1_B32_vi : SOP1_Real_vi <0x1a, S_BITSET1_B32>; def S_BITSET1_B64_vi : SOP1_Real_vi <0x1b, S_BITSET1_B64>; def S_GETPC_B64_vi : SOP1_Real_vi <0x1c, S_GETPC_B64>; def S_SETPC_B64_vi : SOP1_Real_vi <0x1d, S_SETPC_B64>; def S_SWAPPC_B64_vi : SOP1_Real_vi <0x1e, S_SWAPPC_B64>; def S_RFE_B64_vi : SOP1_Real_vi <0x1f, S_RFE_B64>; def S_AND_SAVEEXEC_B64_vi : SOP1_Real_vi <0x20, S_AND_SAVEEXEC_B64>; def S_OR_SAVEEXEC_B64_vi : SOP1_Real_vi <0x21, S_OR_SAVEEXEC_B64>; def S_XOR_SAVEEXEC_B64_vi : SOP1_Real_vi <0x22, S_XOR_SAVEEXEC_B64>; def S_ANDN2_SAVEEXEC_B64_vi: SOP1_Real_vi <0x23, S_ANDN2_SAVEEXEC_B64>; def S_ORN2_SAVEEXEC_B64_vi : SOP1_Real_vi <0x24, S_ORN2_SAVEEXEC_B64>; def S_NAND_SAVEEXEC_B64_vi : SOP1_Real_vi <0x25, S_NAND_SAVEEXEC_B64>; def S_NOR_SAVEEXEC_B64_vi : SOP1_Real_vi <0x26, S_NOR_SAVEEXEC_B64>; def S_XNOR_SAVEEXEC_B64_vi : SOP1_Real_vi <0x27, S_XNOR_SAVEEXEC_B64>; def S_QUADMASK_B32_vi : SOP1_Real_vi <0x28, S_QUADMASK_B32>; def S_QUADMASK_B64_vi : SOP1_Real_vi <0x29, S_QUADMASK_B64>; def S_MOVRELS_B32_vi : SOP1_Real_vi <0x2a, S_MOVRELS_B32>; def S_MOVRELS_B64_vi : SOP1_Real_vi <0x2b, S_MOVRELS_B64>; def S_MOVRELD_B32_vi : SOP1_Real_vi <0x2c, S_MOVRELD_B32>; def S_MOVRELD_B64_vi : SOP1_Real_vi <0x2d, S_MOVRELD_B64>; def S_CBRANCH_JOIN_vi : SOP1_Real_vi <0x2e, S_CBRANCH_JOIN>; def S_ABS_I32_vi : SOP1_Real_vi <0x30, S_ABS_I32>; def S_SET_GPR_IDX_IDX_vi : SOP1_Real_vi <0x32, S_SET_GPR_IDX_IDX>; def S_ADD_U32_vi : SOP2_Real_vi <0x00, S_ADD_U32>; def S_ADD_I32_vi : SOP2_Real_vi <0x02, S_ADD_I32>; def S_SUB_U32_vi : SOP2_Real_vi <0x01, S_SUB_U32>; def S_SUB_I32_vi : SOP2_Real_vi <0x03, S_SUB_I32>; def S_ADDC_U32_vi : SOP2_Real_vi <0x04, S_ADDC_U32>; def S_SUBB_U32_vi : SOP2_Real_vi <0x05, S_SUBB_U32>; def S_MIN_I32_vi : SOP2_Real_vi <0x06, S_MIN_I32>; def S_MIN_U32_vi : SOP2_Real_vi <0x07, S_MIN_U32>; def S_MAX_I32_vi : SOP2_Real_vi <0x08, S_MAX_I32>; def S_MAX_U32_vi : SOP2_Real_vi <0x09, S_MAX_U32>; def S_CSELECT_B32_vi : SOP2_Real_vi <0x0a, S_CSELECT_B32>; def S_CSELECT_B64_vi : SOP2_Real_vi <0x0b, S_CSELECT_B64>; def S_AND_B32_vi : SOP2_Real_vi <0x0c, S_AND_B32>; def S_AND_B64_vi : SOP2_Real_vi <0x0d, S_AND_B64>; def S_OR_B32_vi : SOP2_Real_vi <0x0e, S_OR_B32>; def S_OR_B64_vi : SOP2_Real_vi <0x0f, S_OR_B64>; def S_XOR_B32_vi : SOP2_Real_vi <0x10, S_XOR_B32>; def S_XOR_B64_vi : SOP2_Real_vi <0x11, S_XOR_B64>; def S_ANDN2_B32_vi : SOP2_Real_vi <0x12, S_ANDN2_B32>; def S_ANDN2_B64_vi : SOP2_Real_vi <0x13, S_ANDN2_B64>; def S_ORN2_B32_vi : SOP2_Real_vi <0x14, S_ORN2_B32>; def S_ORN2_B64_vi : SOP2_Real_vi <0x15, S_ORN2_B64>; def S_NAND_B32_vi : SOP2_Real_vi <0x16, S_NAND_B32>; def S_NAND_B64_vi : SOP2_Real_vi <0x17, S_NAND_B64>; def S_NOR_B32_vi : SOP2_Real_vi <0x18, S_NOR_B32>; def S_NOR_B64_vi : SOP2_Real_vi <0x19, S_NOR_B64>; def S_XNOR_B32_vi : SOP2_Real_vi <0x1a, S_XNOR_B32>; def S_XNOR_B64_vi : SOP2_Real_vi <0x1b, S_XNOR_B64>; def S_LSHL_B32_vi : SOP2_Real_vi <0x1c, S_LSHL_B32>; def S_LSHL_B64_vi : SOP2_Real_vi <0x1d, S_LSHL_B64>; def S_LSHR_B32_vi : SOP2_Real_vi <0x1e, S_LSHR_B32>; def S_LSHR_B64_vi : SOP2_Real_vi <0x1f, S_LSHR_B64>; def S_ASHR_I32_vi : SOP2_Real_vi <0x20, S_ASHR_I32>; def S_ASHR_I64_vi : SOP2_Real_vi <0x21, S_ASHR_I64>; def S_BFM_B32_vi : SOP2_Real_vi <0x22, S_BFM_B32>; def S_BFM_B64_vi : SOP2_Real_vi <0x23, S_BFM_B64>; def S_MUL_I32_vi : SOP2_Real_vi <0x24, S_MUL_I32>; def S_BFE_U32_vi : SOP2_Real_vi <0x25, S_BFE_U32>; def S_BFE_I32_vi : SOP2_Real_vi <0x26, S_BFE_I32>; def S_BFE_U64_vi : SOP2_Real_vi <0x27, S_BFE_U64>; def S_BFE_I64_vi : SOP2_Real_vi <0x28, S_BFE_I64>; def S_CBRANCH_G_FORK_vi : SOP2_Real_vi <0x29, S_CBRANCH_G_FORK>; def S_ABSDIFF_I32_vi : SOP2_Real_vi <0x2a, S_ABSDIFF_I32>; def S_PACK_LL_B32_B16_vi : SOP2_Real_vi <0x32, S_PACK_LL_B32_B16>; def S_PACK_LH_B32_B16_vi : SOP2_Real_vi <0x33, S_PACK_LH_B32_B16>; def S_PACK_HH_B32_B16_vi : SOP2_Real_vi <0x34, S_PACK_HH_B32_B16>; def S_RFE_RESTORE_B64_vi : SOP2_Real_vi <0x2b, S_RFE_RESTORE_B64>; def S_MOVK_I32_vi : SOPK_Real_vi <0x00, S_MOVK_I32>; def S_CMOVK_I32_vi : SOPK_Real_vi <0x01, S_CMOVK_I32>; def S_CMPK_EQ_I32_vi : SOPK_Real_vi <0x02, S_CMPK_EQ_I32>; def S_CMPK_LG_I32_vi : SOPK_Real_vi <0x03, S_CMPK_LG_I32>; def S_CMPK_GT_I32_vi : SOPK_Real_vi <0x04, S_CMPK_GT_I32>; def S_CMPK_GE_I32_vi : SOPK_Real_vi <0x05, S_CMPK_GE_I32>; def S_CMPK_LT_I32_vi : SOPK_Real_vi <0x06, S_CMPK_LT_I32>; def S_CMPK_LE_I32_vi : SOPK_Real_vi <0x07, S_CMPK_LE_I32>; def S_CMPK_EQ_U32_vi : SOPK_Real_vi <0x08, S_CMPK_EQ_U32>; def S_CMPK_LG_U32_vi : SOPK_Real_vi <0x09, S_CMPK_LG_U32>; def S_CMPK_GT_U32_vi : SOPK_Real_vi <0x0A, S_CMPK_GT_U32>; def S_CMPK_GE_U32_vi : SOPK_Real_vi <0x0B, S_CMPK_GE_U32>; def S_CMPK_LT_U32_vi : SOPK_Real_vi <0x0C, S_CMPK_LT_U32>; def S_CMPK_LE_U32_vi : SOPK_Real_vi <0x0D, S_CMPK_LE_U32>; def S_ADDK_I32_vi : SOPK_Real_vi <0x0E, S_ADDK_I32>; def S_MULK_I32_vi : SOPK_Real_vi <0x0F, S_MULK_I32>; def S_CBRANCH_I_FORK_vi : SOPK_Real_vi <0x10, S_CBRANCH_I_FORK>; def S_GETREG_B32_vi : SOPK_Real_vi <0x11, S_GETREG_B32>; def S_SETREG_B32_vi : SOPK_Real_vi <0x12, S_SETREG_B32>; //def S_GETREG_REGRD_B32_vi : SOPK_Real_vi <0x13, S_GETREG_REGRD_B32>; // see pseudo for comments def S_SETREG_IMM32_B32_vi : SOPK_Real64<0x14, S_SETREG_IMM32_B32>, Select_vi; def S_CALL_B64_vi : SOPK_Real_vi <0x15, S_CALL_B64>; //===----------------------------------------------------------------------===// // SOP1 - GFX9. //===----------------------------------------------------------------------===// def S_ANDN1_SAVEEXEC_B64_vi : SOP1_Real_vi<0x33, S_ANDN1_SAVEEXEC_B64>; def S_ORN1_SAVEEXEC_B64_vi : SOP1_Real_vi<0x34, S_ORN1_SAVEEXEC_B64>; def S_ANDN1_WREXEC_B64_vi : SOP1_Real_vi<0x35, S_ANDN1_WREXEC_B64>; def S_ANDN2_WREXEC_B64_vi : SOP1_Real_vi<0x36, S_ANDN2_WREXEC_B64>; def S_BITREPLICATE_B64_B32_vi : SOP1_Real_vi<0x37, S_BITREPLICATE_B64_B32>; //===----------------------------------------------------------------------===// // SOP2 - GFX9. //===----------------------------------------------------------------------===// def S_LSHL1_ADD_U32_vi : SOP2_Real_vi<0x2e, S_LSHL1_ADD_U32>; def S_LSHL2_ADD_U32_vi : SOP2_Real_vi<0x2f, S_LSHL2_ADD_U32>; def S_LSHL3_ADD_U32_vi : SOP2_Real_vi<0x30, S_LSHL3_ADD_U32>; def S_LSHL4_ADD_U32_vi : SOP2_Real_vi<0x31, S_LSHL4_ADD_U32>; def S_MUL_HI_U32_vi : SOP2_Real_vi<0x2c, S_MUL_HI_U32>; def S_MUL_HI_I32_vi : SOP2_Real_vi<0x2d, S_MUL_HI_I32>;