llvm/lib/Target/AMDGPU/VOP1Instructions.td - llvm-project - Git at Google

 //===-- VOP1Instructions.td - Vector 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
 //
 //===----------------------------------------------------------------------===//

 //===----------------------------------------------------------------------===//
 // VOP1 Classes
 //===----------------------------------------------------------------------===//

 class VOP1e <bits<8> op, VOPProfile P> : Enc32 {
   bits<8> vdst;
   bits<9> src0;

   let Inst{8-0}   = !if(P.HasSrc0, src0{8-0}, ?);
   let Inst{16-9}  = op;
   let Inst{24-17} = !if(P.EmitDst, vdst{7-0}, 0);
   let Inst{31-25} = 0x3f; //encoding
 }

 class VOP1_SDWAe <bits<8> op, VOPProfile P> : VOP_SDWAe <P> {
   bits<8> vdst;

   let Inst{8-0}   = 0xf9; // sdwa
   let Inst{16-9}  = op;
   let Inst{24-17} = !if(P.EmitDst, vdst{7-0}, 0);
   let Inst{31-25} = 0x3f; // encoding
 }

 class VOP1_SDWA9Ae <bits<8> op, VOPProfile P> : VOP_SDWA9Ae <P> {
   bits<8> vdst;

   let Inst{8-0}   = 0xf9; // sdwa
   let Inst{16-9}  = op;
   let Inst{24-17} = !if(P.EmitDst, vdst{7-0}, 0);
   let Inst{31-25} = 0x3f; // encoding
 }

 class VOP1_Pseudo <string opName, VOPProfile P, list<dag> pattern=[], bit VOP1Only = 0> :
   VOP_Pseudo <opName, !if(VOP1Only, "", "_e32"), P, P.Outs32, P.Ins32, "", pattern> {

   let AsmOperands = P.Asm32;

   let Size = 4;
   let mayLoad = 0;
   let mayStore = 0;
   let hasSideEffects = 0;

   let ReadsModeReg = !or(isFloatType<P.DstVT>.ret, isFloatType<P.Src0VT>.ret);

   let mayRaiseFPException = ReadsModeReg;

   let VOP1 = 1;
   let VALU = 1;
   let Uses = !if(ReadsModeReg, [MODE, EXEC], [EXEC]);

   let AsmVariantName = AMDGPUAsmVariants.Default;
 }

 class VOP1_Real <VOP1_Pseudo ps, int EncodingFamily> :
   VOP_Real <ps>,
   InstSI <ps.OutOperandList, ps.InOperandList, ps.Mnemonic # ps.AsmOperands, []>,
   SIMCInstr <ps.PseudoInstr, EncodingFamily> {

   let VALU = 1;
   let VOP1 = 1;
   let isPseudo = 0;
   let isCodeGenOnly = 0;

   let Constraints     = ps.Constraints;
   let DisableEncoding = ps.DisableEncoding;

   // copy relevant pseudo op flags
   let SubtargetPredicate = ps.SubtargetPredicate;
   let AsmMatchConverter  = ps.AsmMatchConverter;
   let AsmVariantName     = ps.AsmVariantName;
   let Constraints        = ps.Constraints;
   let DisableEncoding    = ps.DisableEncoding;
   let TSFlags            = ps.TSFlags;
   let UseNamedOperandTable = ps.UseNamedOperandTable;
   let Uses                 = ps.Uses;
   let Defs                 = ps.Defs;
   let SchedRW              = ps.SchedRW;
   let mayLoad              = ps.mayLoad;
   let mayStore             = ps.mayStore;
   let TRANS                = ps.TRANS;
 }

 class VOP1_SDWA_Pseudo <string OpName, VOPProfile P, list<dag> pattern=[]> :
   VOP_SDWA_Pseudo <OpName, P, pattern> {
   let AsmMatchConverter = "cvtSdwaVOP1";
 }

 class VOP1_DPP_Pseudo <string OpName, VOPProfile P, list<dag> pattern=[]> :
   VOP_DPP_Pseudo <OpName, P, pattern> {
 }

 class getVOP1Pat64 <SDPatternOperator node, VOPProfile P> : LetDummies {
   list<dag> ret =
     !if(P.HasModifiers,
         [(set P.DstVT:$vdst, (node (P.Src0VT (VOP3Mods P.Src0VT:$src0, i32:$src0_modifiers))))],
         !if(P.HasOMod,
             [(set P.DstVT:$vdst, (node (P.Src0VT (VOP3OMods P.Src0VT:$src0,
                                                   i1:$clamp, i32:$omod))))],
             [(set P.DstVT:$vdst, (node P.Src0VT:$src0))]
         )
     );
 }

 multiclass VOP1Inst <string opName, VOPProfile P,
                      SDPatternOperator node = null_frag> {
   // We only want to set this on the basic, non-SDWA or DPP forms.
   defvar should_mov_imm = !eq(opName, "v_mov_b32");

   let isMoveImm = should_mov_imm in {
     def _e32 : VOP1_Pseudo <opName, P>;
     def _e64 : VOP3_Pseudo <opName, P, getVOP1Pat64<node, P>.ret>;
   }

   foreach _ = BoolToList<P.HasExtSDWA>.ret in
     def _sdwa : VOP1_SDWA_Pseudo <opName, P>;

   foreach _ = BoolToList<P.HasExtDPP>.ret in
     def _dpp : VOP1_DPP_Pseudo <opName, P>;

   def : MnemonicAlias<opName#"_e32", opName>, LetDummies;
   def : MnemonicAlias<opName#"_e64", opName>, LetDummies;

   foreach _ = BoolToList<P.HasExtSDWA>.ret in
     def : MnemonicAlias<opName#"_sdwa", opName>, LetDummies;

   foreach _ = BoolToList<P.HasExtDPP>.ret in
     def : MnemonicAlias<opName#"_dpp", opName>, LetDummies;
 }

 // Special profile for instructions which have clamp
 // and output modifiers (but have no input modifiers)
 class VOPProfileI2F<ValueType dstVt, ValueType srcVt> :
   VOPProfile<[dstVt, srcVt, untyped, untyped]> {

   let Ins64 = (ins Src0RC64:$src0, clampmod:$clamp, omod:$omod);
   let Asm64 = "$vdst, $src0$clamp$omod";

   let HasModifiers = 0;
   let HasClamp = 1;
 }

 def VOP1_F64_I32 : VOPProfileI2F <f64, i32>;
 def VOP1_F32_I32 : VOPProfileI2F <f32, i32>;
 def VOP1_F16_I16 : VOPProfileI2F <f16, i16>;

 class VOP_SPECIAL_OMOD_PROF<ValueType dstVt, ValueType srcVt> :
   VOPProfile<[dstVt, srcVt, untyped, untyped]> {

   let HasOMod = 1;
 }
 def VOP_I32_F32_SPECIAL_OMOD : VOP_SPECIAL_OMOD_PROF<i32, f32>;
 def VOP_I32_F64_SPECIAL_OMOD : VOP_SPECIAL_OMOD_PROF<i32, f64>;
 def VOP_I16_F16_SPECIAL_OMOD : VOP_SPECIAL_OMOD_PROF<i16, f16>;

 //===----------------------------------------------------------------------===//
 // VOP1 Instructions
 //===----------------------------------------------------------------------===//

 let VOPAsmPrefer32Bit = 1 in {
 defm V_NOP : VOP1Inst <"v_nop", VOP_NONE>;
 }

 let isReMaterializable = 1, isAsCheapAsAMove = 1 in {
 defm V_MOV_B32 : VOP1Inst <"v_mov_b32", VOP_I32_I32>;
 } // End isMoveImm = 1

 // FIXME: Specify SchedRW for READFIRSTLANE_B32
 // TODO: Make profile for this, there is VOP3 encoding also
 def V_READFIRSTLANE_B32 :
   InstSI <(outs SReg_32:$vdst),
     (ins VRegOrLds_32:$src0),
     "v_readfirstlane_b32 $vdst, $src0",
     [(set i32:$vdst, (int_amdgcn_readfirstlane (i32 VRegOrLds_32:$src0)))]>,
   Enc32 {

   let isCodeGenOnly = 0;
   let UseNamedOperandTable = 1;

   let Size = 4;
   let mayLoad = 0;
   let mayStore = 0;
   let hasSideEffects = 0;

   let VOP1 = 1;
   let VALU = 1;
   let Uses = [EXEC];
   let isConvergent = 1;

   bits<8> vdst;
   bits<9> src0;

   let Inst{8-0}   = src0;
   let Inst{16-9}  = 0x2;
   let Inst{24-17} = vdst;
   let Inst{31-25} = 0x3f; //encoding
 }

 let isReMaterializable = 1 in {
 let SchedRW = [WriteDoubleCvt] in {
 // OMod clears exceptions when set in this instruction
 defm V_CVT_I32_F64 : VOP1Inst <"v_cvt_i32_f64", VOP_I32_F64_SPECIAL_OMOD,  fp_to_sint>;

 let mayRaiseFPException = 0 in {
 defm V_CVT_F64_I32 : VOP1Inst <"v_cvt_f64_i32", VOP1_F64_I32, sint_to_fp>;
 }

 defm V_CVT_F32_F64 : VOP1Inst <"v_cvt_f32_f64", VOP_F32_F64,  fpround>;
 defm V_CVT_F64_F32 : VOP1Inst <"v_cvt_f64_f32", VOP_F64_F32,  fpextend>;
 // OMod clears exceptions when set in this instruction
 defm V_CVT_U32_F64 : VOP1Inst <"v_cvt_u32_f64", VOP_I32_F64_SPECIAL_OMOD,  fp_to_uint>;

 let mayRaiseFPException = 0 in {
 defm V_CVT_F64_U32 : VOP1Inst <"v_cvt_f64_u32", VOP1_F64_I32, uint_to_fp>;
 }

 } // End SchedRW = [WriteDoubleCvt]

 let SchedRW = [WriteFloatCvt] in {

 // XXX: Does this really not raise exceptions? The manual claims the
 // 16-bit ones can.
 let mayRaiseFPException = 0 in {
 defm V_CVT_F32_I32 : VOP1Inst <"v_cvt_f32_i32", VOP1_F32_I32, sint_to_fp>;
 defm V_CVT_F32_U32 : VOP1Inst <"v_cvt_f32_u32", VOP1_F32_I32, uint_to_fp>;
 }

 // OMod clears exceptions when set in these 2 instructions
 defm V_CVT_U32_F32 : VOP1Inst <"v_cvt_u32_f32", VOP_I32_F32_SPECIAL_OMOD, fp_to_uint>;
 defm V_CVT_I32_F32 : VOP1Inst <"v_cvt_i32_f32", VOP_I32_F32_SPECIAL_OMOD, fp_to_sint>;
 let FPDPRounding = 1, isReMaterializable = 0 in {
 defm V_CVT_F16_F32 : VOP1Inst <"v_cvt_f16_f32", VOP_F16_F32, fpround>;
 } // End FPDPRounding = 1, isReMaterializable = 0

 defm V_CVT_F32_F16 : VOP1Inst <"v_cvt_f32_f16", VOP_F32_F16, fpextend>;

 let ReadsModeReg = 0, mayRaiseFPException = 0 in {
 defm V_CVT_RPI_I32_F32 : VOP1Inst <"v_cvt_rpi_i32_f32", VOP_I32_F32, cvt_rpi_i32_f32>;
 defm V_CVT_FLR_I32_F32 : VOP1Inst <"v_cvt_flr_i32_f32", VOP_I32_F32, cvt_flr_i32_f32>;
 defm V_CVT_OFF_F32_I4 : VOP1Inst  <"v_cvt_off_f32_i4", VOP1_F32_I32>;
 } // End ReadsModeReg = 0, mayRaiseFPException = 0
 } // End SchedRW = [WriteFloatCvt]

 let ReadsModeReg = 0, mayRaiseFPException = 0 in {
 defm V_CVT_F32_UBYTE0 : VOP1Inst <"v_cvt_f32_ubyte0", VOP1_F32_I32, AMDGPUcvt_f32_ubyte0>;
 defm V_CVT_F32_UBYTE1 : VOP1Inst <"v_cvt_f32_ubyte1", VOP1_F32_I32, AMDGPUcvt_f32_ubyte1>;
 defm V_CVT_F32_UBYTE2 : VOP1Inst <"v_cvt_f32_ubyte2", VOP1_F32_I32, AMDGPUcvt_f32_ubyte2>;
 defm V_CVT_F32_UBYTE3 : VOP1Inst <"v_cvt_f32_ubyte3", VOP1_F32_I32, AMDGPUcvt_f32_ubyte3>;
 } // ReadsModeReg = 0, mayRaiseFPException = 0

 defm V_FRACT_F32 : VOP1Inst <"v_fract_f32", VOP_F32_F32, AMDGPUfract>;
 defm V_TRUNC_F32 : VOP1Inst <"v_trunc_f32", VOP_F32_F32, ftrunc>;
 defm V_CEIL_F32 : VOP1Inst <"v_ceil_f32", VOP_F32_F32, fceil>;
 defm V_RNDNE_F32 : VOP1Inst <"v_rndne_f32", VOP_F32_F32, frint>;
 defm V_FLOOR_F32 : VOP1Inst <"v_floor_f32", VOP_F32_F32, ffloor>;

 let TRANS = 1, SchedRW = [WriteTrans32] in {
 defm V_EXP_F32 : VOP1Inst <"v_exp_f32", VOP_F32_F32, fexp2>;
 defm V_LOG_F32 : VOP1Inst <"v_log_f32", VOP_F32_F32, flog2>;
 defm V_RCP_F32 : VOP1Inst <"v_rcp_f32", VOP_F32_F32, AMDGPUrcp>;
 defm V_RCP_IFLAG_F32 : VOP1Inst <"v_rcp_iflag_f32", VOP_F32_F32, AMDGPUrcp_iflag>;
 defm V_RSQ_F32 : VOP1Inst <"v_rsq_f32", VOP_F32_F32, AMDGPUrsq>;
 defm V_SQRT_F32 : VOP1Inst <"v_sqrt_f32", VOP_F32_F32, any_amdgcn_sqrt>;
 } // End TRANS = 1, SchedRW = [WriteTrans32]

 let TRANS = 1, SchedRW = [WriteTrans64] in {
 defm V_RCP_F64 : VOP1Inst <"v_rcp_f64", VOP_F64_F64, AMDGPUrcp>;
 defm V_RSQ_F64 : VOP1Inst <"v_rsq_f64", VOP_F64_F64, AMDGPUrsq>;
 defm V_SQRT_F64 : VOP1Inst <"v_sqrt_f64", VOP_F64_F64, any_amdgcn_sqrt>;
 } // End TRANS = 1, SchedRW = [WriteTrans64]

 let TRANS = 1, SchedRW = [WriteTrans32] in {
 defm V_SIN_F32 : VOP1Inst <"v_sin_f32", VOP_F32_F32, AMDGPUsin>;
 defm V_COS_F32 : VOP1Inst <"v_cos_f32", VOP_F32_F32, AMDGPUcos>;
 } // End TRANS = 1, SchedRW = [WriteTrans32]

 defm V_NOT_B32 : VOP1Inst <"v_not_b32", VOP_I32_I32>;
 defm V_BFREV_B32 : VOP1Inst <"v_bfrev_b32", VOP_I32_I32, bitreverse>;
 defm V_FFBH_U32 : VOP1Inst <"v_ffbh_u32", VOP_I32_I32, AMDGPUffbh_u32>;
 defm V_FFBL_B32 : VOP1Inst <"v_ffbl_b32", VOP_I32_I32, AMDGPUffbl_b32>;
 defm V_FFBH_I32 : VOP1Inst <"v_ffbh_i32", VOP_I32_I32, AMDGPUffbh_i32>;

 let SchedRW = [WriteDoubleAdd] in {
 defm V_FREXP_EXP_I32_F64 : VOP1Inst <"v_frexp_exp_i32_f64", VOP_I32_F64_SPECIAL_OMOD, int_amdgcn_frexp_exp>;
 defm V_FREXP_MANT_F64 : VOP1Inst <"v_frexp_mant_f64", VOP_F64_F64, int_amdgcn_frexp_mant>;
 let FPDPRounding = 1 in {
 defm V_FRACT_F64 : VOP1Inst <"v_fract_f64", VOP_F64_F64, AMDGPUfract>;
 } // End FPDPRounding = 1
 } // End SchedRW = [WriteDoubleAdd]

 defm V_FREXP_EXP_I32_F32 : VOP1Inst <"v_frexp_exp_i32_f32", VOP_I32_F32, int_amdgcn_frexp_exp>;
 defm V_FREXP_MANT_F32 : VOP1Inst <"v_frexp_mant_f32", VOP_F32_F32, int_amdgcn_frexp_mant>;
 } // End isReMaterializable = 1

 let VOPAsmPrefer32Bit = 1 in {
 defm V_CLREXCP : VOP1Inst <"v_clrexcp", VOP_NO_EXT<VOP_NONE>>;
 }

 // Restrict src0 to be VGPR
 def VOP_MOVRELS : VOPProfile<[i32, i32, untyped, untyped]> {
   let Src0RC32 = VRegSrc_32;
   let Src0RC64 = VRegSrc_32;
 }

 // Special case because there are no true output operands.  Hack vdst
 // to be a src operand. The custom inserter must add a tied implicit
 // def and use of the super register since there seems to be no way to
 // add an implicit def of a virtual register in tablegen.
 class VOP_MOVREL<RegisterOperand Src1RC> : VOPProfile<[untyped, i32, untyped, untyped]> {
   let Src0RC32 = VOPDstOperand<VGPR_32>;
   let Src0RC64 = VOPDstOperand<VGPR_32>;

   let Outs = (outs);
   let Ins32 = (ins Src0RC32:$vdst, Src1RC:$src0);
   let Ins64 = (ins Src0RC64:$vdst, Src1RC:$src0);
   let Asm32 = getAsm32<1, 1>.ret;
   let Asm64 = getAsm64<1, 1, 0, 0, 1>.ret;

   let OutsSDWA = (outs Src0RC32:$vdst);
   let InsSDWA = (ins Src0ModSDWA:$src0_modifiers, Src0SDWA:$src0,
                      clampmod:$clamp, dst_sel:$dst_sel, dst_unused:$dst_unused,
                      src0_sel:$src0_sel);
   let AsmSDWA9 = getAsmSDWA9<1, 0, 1>.ret;

   let OutsDPP = (outs Src0RC32:$vdst);
   let InsDPP16 = (ins Src0RC32:$old, Src0RC32:$src0,
                       dpp_ctrl:$dpp_ctrl, row_mask:$row_mask,
                       bank_mask:$bank_mask, bound_ctrl:$bound_ctrl, FI:$fi);
   let AsmDPP16 = getAsmDPP16<1, 1, 0>.ret;

   let OutsDPP8 = (outs Src0RC32:$vdst);
   let InsDPP8 = (ins Src0RC32:$old, Src0RC32:$src0, dpp8:$dpp8, FI:$fi);
   let AsmDPP8 = getAsmDPP8<1, 1, 0>.ret;

   let HasDst = 0;
   let EmitDst = 1; // force vdst emission
 }

 def VOP_MOVRELD : VOP_MOVREL<VSrc_b32>;
 def VOP_MOVRELSD : VOP_MOVREL<VRegSrc_32>;

 let SubtargetPredicate = HasMovrel, Uses = [M0, EXEC] in {
  // v_movreld_b32 is a special case because the destination output
  // register is really a source. It isn't actually read (but may be
  // written), and is only to provide the base register to start
  // indexing from. Tablegen seems to not let you define an implicit
  // virtual register output for the super register being written into,
  // so this must have an implicit def of the register added to it.
 defm V_MOVRELD_B32 : VOP1Inst <"v_movreld_b32", VOP_MOVRELD>;
 defm V_MOVRELS_B32 : VOP1Inst <"v_movrels_b32", VOP_MOVRELS>;
 defm V_MOVRELSD_B32 : VOP1Inst <"v_movrelsd_b32", VOP_MOVRELSD>;
 } // End Uses = [M0, EXEC]

 let isReMaterializable = 1 in {
 let SubtargetPredicate = isGFX6GFX7 in {
   let TRANS = 1, SchedRW = [WriteTrans32] in {
     defm V_LOG_CLAMP_F32 :
       VOP1Inst<"v_log_clamp_f32", VOP_F32_F32, int_amdgcn_log_clamp>;
     defm V_RCP_CLAMP_F32 :
       VOP1Inst<"v_rcp_clamp_f32", VOP_F32_F32>;
     defm V_RCP_LEGACY_F32 :
       VOP1Inst<"v_rcp_legacy_f32", VOP_F32_F32, AMDGPUrcp_legacy>;
     defm V_RSQ_CLAMP_F32 :
       VOP1Inst<"v_rsq_clamp_f32", VOP_F32_F32, AMDGPUrsq_clamp>;
     defm V_RSQ_LEGACY_F32 :
       VOP1Inst<"v_rsq_legacy_f32", VOP_F32_F32, int_amdgcn_rsq_legacy>;
   } // End TRANS = 1, SchedRW = [WriteTrans32]

   let SchedRW = [WriteTrans64] in {
     defm V_RCP_CLAMP_F64 :
       VOP1Inst<"v_rcp_clamp_f64", VOP_F64_F64>;
     defm V_RSQ_CLAMP_F64 :
       VOP1Inst<"v_rsq_clamp_f64", VOP_F64_F64, AMDGPUrsq_clamp>;
   } // End SchedRW = [WriteTrans64]
 } // End SubtargetPredicate = isGFX6GFX7

 let SubtargetPredicate = isGFX7GFX8GFX9 in {
   let TRANS = 1, SchedRW = [WriteTrans32] in {
     defm V_LOG_LEGACY_F32 : VOP1Inst<"v_log_legacy_f32", VOP_F32_F32>;
     defm V_EXP_LEGACY_F32 : VOP1Inst<"v_exp_legacy_f32", VOP_F32_F32>;
   } // End TRANS = 1, SchedRW = [WriteTrans32]
 } // End SubtargetPredicate = isGFX7GFX8GFX9

 let SubtargetPredicate = isGFX7Plus in {
   let SchedRW = [WriteDoubleAdd] in {
     defm V_TRUNC_F64 : VOP1Inst<"v_trunc_f64", VOP_F64_F64, ftrunc>;
     defm V_CEIL_F64  : VOP1Inst<"v_ceil_f64", VOP_F64_F64, fceil>;
     defm V_RNDNE_F64 : VOP1Inst<"v_rndne_f64", VOP_F64_F64, frint>;
     defm V_FLOOR_F64 : VOP1Inst<"v_floor_f64", VOP_F64_F64, ffloor>;
   } // End SchedRW = [WriteDoubleAdd]
 } // End SubtargetPredicate = isGFX7Plus
 } // End isReMaterializable = 1

 let SubtargetPredicate = Has16BitInsts in {

 let FPDPRounding = 1 in {
 defm V_CVT_F16_U16 : VOP1Inst <"v_cvt_f16_u16", VOP1_F16_I16, uint_to_fp>;
 defm V_CVT_F16_I16 : VOP1Inst <"v_cvt_f16_i16", VOP1_F16_I16, sint_to_fp>;
 } // End FPDPRounding = 1
 // OMod clears exceptions when set in these two instructions
 defm V_CVT_U16_F16 : VOP1Inst <"v_cvt_u16_f16", VOP_I16_F16_SPECIAL_OMOD, fp_to_uint>;
 defm V_CVT_I16_F16 : VOP1Inst <"v_cvt_i16_f16", VOP_I16_F16_SPECIAL_OMOD, fp_to_sint>;
 let TRANS = 1, SchedRW = [WriteTrans32] in {
 defm V_RCP_F16 : VOP1Inst <"v_rcp_f16", VOP_F16_F16, AMDGPUrcp>;
 defm V_SQRT_F16 : VOP1Inst <"v_sqrt_f16", VOP_F16_F16, any_amdgcn_sqrt>;
 defm V_RSQ_F16 : VOP1Inst <"v_rsq_f16", VOP_F16_F16, AMDGPUrsq>;
 defm V_LOG_F16 : VOP1Inst <"v_log_f16", VOP_F16_F16, flog2>;
 defm V_EXP_F16 : VOP1Inst <"v_exp_f16", VOP_F16_F16, fexp2>;
 defm V_SIN_F16 : VOP1Inst <"v_sin_f16", VOP_F16_F16, AMDGPUsin>;
 defm V_COS_F16 : VOP1Inst <"v_cos_f16", VOP_F16_F16, AMDGPUcos>;
 } // End TRANS = 1, SchedRW = [WriteTrans32]
 defm V_FREXP_MANT_F16 : VOP1Inst <"v_frexp_mant_f16", VOP_F16_F16, int_amdgcn_frexp_mant>;
 defm V_FREXP_EXP_I16_F16 : VOP1Inst <"v_frexp_exp_i16_f16", VOP_I16_F16_SPECIAL_OMOD, int_amdgcn_frexp_exp>;
 defm V_FLOOR_F16 : VOP1Inst <"v_floor_f16", VOP_F16_F16, ffloor>;
 defm V_CEIL_F16 : VOP1Inst <"v_ceil_f16", VOP_F16_F16, fceil>;
 defm V_TRUNC_F16 : VOP1Inst <"v_trunc_f16", VOP_F16_F16, ftrunc>;
 defm V_RNDNE_F16 : VOP1Inst <"v_rndne_f16", VOP_F16_F16, frint>;
 let FPDPRounding = 1 in {
 defm V_FRACT_F16 : VOP1Inst <"v_fract_f16", VOP_F16_F16, AMDGPUfract>;
 } // End FPDPRounding = 1

 }

 let OtherPredicates = [Has16BitInsts] in {

 def : GCNPat<
     (f32 (f16_to_fp i16:$src)),
     (V_CVT_F32_F16_e32 $src)
 >;

 def : GCNPat<
     (i16 (AMDGPUfp_to_f16 f32:$src)),
     (V_CVT_F16_F32_e32 $src)
 >;

 }

 def VOP_SWAP_I32 : VOPProfile<[i32, i32, i32, untyped]> {
   let Outs32 = (outs VGPR_32:$vdst, VGPR_32:$vdst1);
   let Ins32 = (ins VGPR_32:$src0, VGPR_32:$src1);
   let Outs64 = Outs32;
   let Asm32 = " $vdst, $src0";
   let Asm64 = "";
   let Ins64 = (ins);
 }

 let SubtargetPredicate = isGFX9Plus in {
   def V_SWAP_B32 : VOP1_Pseudo<"v_swap_b32", VOP_SWAP_I32, [], 1> {
     let Constraints = "$vdst = $src1, $vdst1 = $src0";
     let DisableEncoding = "$vdst1,$src1";
     let SchedRW = [Write64Bit, Write64Bit];
   }

   let isReMaterializable = 1 in
   defm V_SAT_PK_U8_I16    : VOP1Inst<"v_sat_pk_u8_i16", VOP_I32_I32>;

   let mayRaiseFPException = 0 in {
     defm V_CVT_NORM_I16_F16 : VOP1Inst<"v_cvt_norm_i16_f16", VOP_I16_F16_SPECIAL_OMOD>;
     defm V_CVT_NORM_U16_F16 : VOP1Inst<"v_cvt_norm_u16_f16", VOP_I16_F16_SPECIAL_OMOD>;
   } // End mayRaiseFPException = 0
 } // End SubtargetPredicate = isGFX9Plus

 let SubtargetPredicate = isGFX9Only in {
   defm V_SCREEN_PARTITION_4SE_B32 : VOP1Inst <"v_screen_partition_4se_b32", VOP_I32_I32>;
 } // End SubtargetPredicate = isGFX9Only

 let SubtargetPredicate = isGFX10Plus in {
   defm V_PIPEFLUSH        : VOP1Inst<"v_pipeflush", VOP_NONE>;

   let Uses = [M0] in {
     defm V_MOVRELSD_2_B32 :
       VOP1Inst<"v_movrelsd_2_b32", VOP_MOVRELSD>;

     def V_SWAPREL_B32 : VOP1_Pseudo<"v_swaprel_b32", VOP_SWAP_I32, [], 1> {
       let Constraints = "$vdst = $src1, $vdst1 = $src0";
       let DisableEncoding = "$vdst1,$src1";
       let SchedRW = [Write64Bit, Write64Bit];
     }
   } // End Uses = [M0]
 } // End SubtargetPredicate = isGFX10Plus

 def VOPProfileAccMov : VOP_NO_EXT<VOP_I32_I32> {
   let DstRC = RegisterOperand<AGPR_32>;
   let Src0RC32 = RegisterOperand<AGPR_32>;
   let Asm32 = " $vdst, $src0";
 }

 def V_ACCVGPR_MOV_B32 : VOP1_Pseudo<"v_accvgpr_mov_b32", VOPProfileAccMov, [], 1> {
   let SubtargetPredicate = isGFX90APlus;
   let isReMaterializable = 1;
   let isAsCheapAsAMove = 1;
 }

 //===----------------------------------------------------------------------===//
 // Target-specific instruction encodings.
 //===----------------------------------------------------------------------===//

 class VOP1_DPP<bits<8> op, VOP1_DPP_Pseudo ps, VOPProfile p = ps.Pfl, bit isDPP16 = 0> :
     VOP_DPP<ps.OpName, p, isDPP16> {
   let hasSideEffects = ps.hasSideEffects;
   let Defs = ps.Defs;
   let SchedRW = ps.SchedRW;
   let Uses = ps.Uses;
   let TRANS = ps.TRANS;

   bits<8> vdst;
   let Inst{8-0}   = 0xfa;
   let Inst{16-9}  = op;
   let Inst{24-17} = !if(p.EmitDst, vdst{7-0}, 0);
   let Inst{31-25} = 0x3f;
 }

 class VOP1_DPP16<bits<8> op, VOP1_DPP_Pseudo ps, VOPProfile p = ps.Pfl> :
     VOP1_DPP<op, ps, p, 1>,
     SIMCInstr <ps.PseudoInstr, SIEncodingFamily.GFX10> {
   let AssemblerPredicate = HasDPP16;
   let SubtargetPredicate = HasDPP16;
 }

 class VOP1_DPP8<bits<8> op, VOP1_Pseudo ps, VOPProfile p = ps.Pfl> :
     VOP_DPP8<ps.OpName, p> {
   let hasSideEffects = ps.hasSideEffects;
   let Defs = ps.Defs;
   let SchedRW = ps.SchedRW;
   let Uses = ps.Uses;

   bits<8> vdst;
   let Inst{8-0}   = fi;
   let Inst{16-9}  = op;
   let Inst{24-17} = !if(p.EmitDst, vdst{7-0}, 0);
   let Inst{31-25} = 0x3f;
 }

 //===----------------------------------------------------------------------===//
 // GFX10.
 //===----------------------------------------------------------------------===//

 let AssemblerPredicate = isGFX10Plus, DecoderNamespace = "GFX10" in {
   multiclass VOP1Only_Real_gfx10<bits<9> op> {
     def _gfx10 :
       VOP1_Real<!cast<VOP1_Pseudo>(NAME), SIEncodingFamily.GFX10>,
       VOP1e<op{7-0}, !cast<VOP1_Pseudo>(NAME).Pfl>;
   }
   multiclass VOP1_Real_e32_gfx10<bits<9> op> {
     def _e32_gfx10 :
       VOP1_Real<!cast<VOP1_Pseudo>(NAME#"_e32"), SIEncodingFamily.GFX10>,
       VOP1e<op{7-0}, !cast<VOP1_Pseudo>(NAME#"_e32").Pfl>;
   }
   multiclass VOP1_Real_e64_gfx10<bits<9> op> {
     def _e64_gfx10 :
       VOP3_Real<!cast<VOP3_Pseudo>(NAME#"_e64"), SIEncodingFamily.GFX10>,
       VOP3e_gfx10<{0, 1, 1, op{6-0}}, !cast<VOP3_Pseudo>(NAME#"_e64").Pfl>;
   }
   multiclass VOP1_Real_sdwa_gfx10<bits<9> op> {
     foreach _ = BoolToList<!cast<VOP1_Pseudo>(NAME#"_e32").Pfl.HasExtSDWA9>.ret in
     def _sdwa_gfx10 :
       VOP_SDWA10_Real<!cast<VOP1_SDWA_Pseudo>(NAME#"_sdwa")>,
       VOP1_SDWA9Ae<op{7-0}, !cast<VOP1_SDWA_Pseudo>(NAME#"_sdwa").Pfl> {
       let DecoderNamespace = "SDWA10";
     }
   }
   multiclass VOP1_Real_dpp_gfx10<bits<9> op> {
     foreach _ = BoolToList<!cast<VOP1_Pseudo>(NAME#"_e32").Pfl.HasExtDPP>.ret in
     def _dpp_gfx10 : VOP1_DPP16<op{7-0}, !cast<VOP1_DPP_Pseudo>(NAME#"_dpp")> {
       let DecoderNamespace = "SDWA10";
     }
   }
   multiclass VOP1_Real_dpp8_gfx10<bits<9> op> {
     foreach _ = BoolToList<!cast<VOP1_Pseudo>(NAME#"_e32").Pfl.HasExtDPP>.ret in
     def _dpp8_gfx10 : VOP1_DPP8<op{7-0}, !cast<VOP1_Pseudo>(NAME#"_e32")> {
       let DecoderNamespace = "DPP8";
     }
   }
 } // End AssemblerPredicate = isGFX10Plus, DecoderNamespace = "GFX10"

 multiclass VOP1_Real_gfx10<bits<9> op> :
   VOP1_Real_e32_gfx10<op>, VOP1_Real_e64_gfx10<op>,
   VOP1_Real_sdwa_gfx10<op>, VOP1_Real_dpp_gfx10<op>,
   VOP1_Real_dpp8_gfx10<op>;

 defm V_PIPEFLUSH         : VOP1_Real_gfx10<0x01b>;
 defm V_MOVRELSD_2_B32    : VOP1_Real_gfx10<0x048>;
 defm V_CVT_F16_U16       : VOP1_Real_gfx10<0x050>;
 defm V_CVT_F16_I16       : VOP1_Real_gfx10<0x051>;
 defm V_CVT_U16_F16       : VOP1_Real_gfx10<0x052>;
 defm V_CVT_I16_F16       : VOP1_Real_gfx10<0x053>;
 defm V_RCP_F16           : VOP1_Real_gfx10<0x054>;
 defm V_SQRT_F16          : VOP1_Real_gfx10<0x055>;
 defm V_RSQ_F16           : VOP1_Real_gfx10<0x056>;
 defm V_LOG_F16           : VOP1_Real_gfx10<0x057>;
 defm V_EXP_F16           : VOP1_Real_gfx10<0x058>;
 defm V_FREXP_MANT_F16    : VOP1_Real_gfx10<0x059>;
 defm V_FREXP_EXP_I16_F16 : VOP1_Real_gfx10<0x05a>;
 defm V_FLOOR_F16         : VOP1_Real_gfx10<0x05b>;
 defm V_CEIL_F16          : VOP1_Real_gfx10<0x05c>;
 defm V_TRUNC_F16         : VOP1_Real_gfx10<0x05d>;
 defm V_RNDNE_F16         : VOP1_Real_gfx10<0x05e>;
 defm V_FRACT_F16         : VOP1_Real_gfx10<0x05f>;
 defm V_SIN_F16           : VOP1_Real_gfx10<0x060>;
 defm V_COS_F16           : VOP1_Real_gfx10<0x061>;
 defm V_SAT_PK_U8_I16     : VOP1_Real_gfx10<0x062>;
 defm V_CVT_NORM_I16_F16  : VOP1_Real_gfx10<0x063>;
 defm V_CVT_NORM_U16_F16  : VOP1_Real_gfx10<0x064>;

 defm V_SWAP_B32    : VOP1Only_Real_gfx10<0x065>;
 defm V_SWAPREL_B32 : VOP1Only_Real_gfx10<0x068>;

 //===----------------------------------------------------------------------===//
 // GFX7, GFX10.
 //===----------------------------------------------------------------------===//

 let AssemblerPredicate = isGFX7Only, DecoderNamespace = "GFX7" in {
   multiclass VOP1_Real_e32_gfx7<bits<9> op> {
     def _e32_gfx7 :
       VOP1_Real<!cast<VOP1_Pseudo>(NAME#"_e32"), SIEncodingFamily.SI>,
       VOP1e<op{7-0}, !cast<VOP1_Pseudo>(NAME#"_e32").Pfl>;
   }
   multiclass VOP1_Real_e64_gfx7<bits<9> op> {
     def _e64_gfx7 :
       VOP3_Real<!cast<VOP3_Pseudo>(NAME#"_e64"), SIEncodingFamily.SI>,
       VOP3e_gfx6_gfx7<{1, 1, op{6-0}}, !cast<VOP3_Pseudo>(NAME#"_e64").Pfl>;
   }
 } // End AssemblerPredicate = isGFX7Only, DecoderNamespace = "GFX7"

 multiclass VOP1_Real_gfx7<bits<9> op> :
   VOP1_Real_e32_gfx7<op>, VOP1_Real_e64_gfx7<op>;

 multiclass VOP1_Real_gfx7_gfx10<bits<9> op> :
   VOP1_Real_gfx7<op>, VOP1_Real_gfx10<op>;

 defm V_LOG_LEGACY_F32 : VOP1_Real_gfx7<0x045>;
 defm V_EXP_LEGACY_F32 : VOP1_Real_gfx7<0x046>;

 defm V_TRUNC_F64 : VOP1_Real_gfx7_gfx10<0x017>;
 defm V_CEIL_F64  : VOP1_Real_gfx7_gfx10<0x018>;
 defm V_RNDNE_F64 : VOP1_Real_gfx7_gfx10<0x019>;
 defm V_FLOOR_F64 : VOP1_Real_gfx7_gfx10<0x01a>;

 //===----------------------------------------------------------------------===//
 // GFX6, GFX7, GFX10.
 //===----------------------------------------------------------------------===//

 let AssemblerPredicate = isGFX6GFX7, DecoderNamespace = "GFX6GFX7" in {
   multiclass VOP1_Real_e32_gfx6_gfx7<bits<9> op> {
     def _e32_gfx6_gfx7 :
       VOP1_Real<!cast<VOP1_Pseudo>(NAME#"_e32"), SIEncodingFamily.SI>,
       VOP1e<op{7-0}, !cast<VOP1_Pseudo>(NAME#"_e32").Pfl>;
   }
   multiclass VOP1_Real_e64_gfx6_gfx7<bits<9> op> {
     def _e64_gfx6_gfx7 :
       VOP3_Real<!cast<VOP3_Pseudo>(NAME#"_e64"), SIEncodingFamily.SI>,
       VOP3e_gfx6_gfx7<{1, 1, op{6-0}}, !cast<VOP3_Pseudo>(NAME#"_e64").Pfl>;
   }
 } // End AssemblerPredicate = isGFX6GFX7, DecoderNamespace = "GFX6GFX7"

 multiclass VOP1_Real_gfx6_gfx7<bits<9> op> :
   VOP1_Real_e32_gfx6_gfx7<op>, VOP1_Real_e64_gfx6_gfx7<op>;

 multiclass VOP1_Real_gfx6_gfx7_gfx10<bits<9> op> :
   VOP1_Real_gfx6_gfx7<op>, VOP1_Real_gfx10<op>;

 defm V_LOG_CLAMP_F32  : VOP1_Real_gfx6_gfx7<0x026>;
 defm V_RCP_CLAMP_F32  : VOP1_Real_gfx6_gfx7<0x028>;
 defm V_RCP_LEGACY_F32 : VOP1_Real_gfx6_gfx7<0x029>;
 defm V_RSQ_CLAMP_F32  : VOP1_Real_gfx6_gfx7<0x02c>;
 defm V_RSQ_LEGACY_F32 : VOP1_Real_gfx6_gfx7<0x02d>;
 defm V_RCP_CLAMP_F64  : VOP1_Real_gfx6_gfx7<0x030>;
 defm V_RSQ_CLAMP_F64  : VOP1_Real_gfx6_gfx7<0x032>;

 defm V_NOP               : VOP1_Real_gfx6_gfx7_gfx10<0x000>;
 defm V_MOV_B32           : VOP1_Real_gfx6_gfx7_gfx10<0x001>;
 defm V_CVT_I32_F64       : VOP1_Real_gfx6_gfx7_gfx10<0x003>;
 defm V_CVT_F64_I32       : VOP1_Real_gfx6_gfx7_gfx10<0x004>;
 defm V_CVT_F32_I32       : VOP1_Real_gfx6_gfx7_gfx10<0x005>;
 defm V_CVT_F32_U32       : VOP1_Real_gfx6_gfx7_gfx10<0x006>;
 defm V_CVT_U32_F32       : VOP1_Real_gfx6_gfx7_gfx10<0x007>;
 defm V_CVT_I32_F32       : VOP1_Real_gfx6_gfx7_gfx10<0x008>;
 defm V_CVT_F16_F32       : VOP1_Real_gfx6_gfx7_gfx10<0x00a>;
 defm V_CVT_F32_F16       : VOP1_Real_gfx6_gfx7_gfx10<0x00b>;
 defm V_CVT_RPI_I32_F32   : VOP1_Real_gfx6_gfx7_gfx10<0x00c>;
 defm V_CVT_FLR_I32_F32   : VOP1_Real_gfx6_gfx7_gfx10<0x00d>;
 defm V_CVT_OFF_F32_I4    : VOP1_Real_gfx6_gfx7_gfx10<0x00e>;
 defm V_CVT_F32_F64       : VOP1_Real_gfx6_gfx7_gfx10<0x00f>;
 defm V_CVT_F64_F32       : VOP1_Real_gfx6_gfx7_gfx10<0x010>;
 defm V_CVT_F32_UBYTE0    : VOP1_Real_gfx6_gfx7_gfx10<0x011>;
 defm V_CVT_F32_UBYTE1    : VOP1_Real_gfx6_gfx7_gfx10<0x012>;
 defm V_CVT_F32_UBYTE2    : VOP1_Real_gfx6_gfx7_gfx10<0x013>;
 defm V_CVT_F32_UBYTE3    : VOP1_Real_gfx6_gfx7_gfx10<0x014>;
 defm V_CVT_U32_F64       : VOP1_Real_gfx6_gfx7_gfx10<0x015>;
 defm V_CVT_F64_U32       : VOP1_Real_gfx6_gfx7_gfx10<0x016>;
 defm V_FRACT_F32         : VOP1_Real_gfx6_gfx7_gfx10<0x020>;
 defm V_TRUNC_F32         : VOP1_Real_gfx6_gfx7_gfx10<0x021>;
 defm V_CEIL_F32          : VOP1_Real_gfx6_gfx7_gfx10<0x022>;
 defm V_RNDNE_F32         : VOP1_Real_gfx6_gfx7_gfx10<0x023>;
 defm V_FLOOR_F32         : VOP1_Real_gfx6_gfx7_gfx10<0x024>;
 defm V_EXP_F32           : VOP1_Real_gfx6_gfx7_gfx10<0x025>;
 defm V_LOG_F32           : VOP1_Real_gfx6_gfx7_gfx10<0x027>;
 defm V_RCP_F32           : VOP1_Real_gfx6_gfx7_gfx10<0x02a>;
 defm V_RCP_IFLAG_F32     : VOP1_Real_gfx6_gfx7_gfx10<0x02b>;
 defm V_RSQ_F32           : VOP1_Real_gfx6_gfx7_gfx10<0x02e>;
 defm V_RCP_F64           : VOP1_Real_gfx6_gfx7_gfx10<0x02f>;
 defm V_RSQ_F64           : VOP1_Real_gfx6_gfx7_gfx10<0x031>;
 defm V_SQRT_F32          : VOP1_Real_gfx6_gfx7_gfx10<0x033>;
 defm V_SQRT_F64          : VOP1_Real_gfx6_gfx7_gfx10<0x034>;
 defm V_SIN_F32           : VOP1_Real_gfx6_gfx7_gfx10<0x035>;
 defm V_COS_F32           : VOP1_Real_gfx6_gfx7_gfx10<0x036>;
 defm V_NOT_B32           : VOP1_Real_gfx6_gfx7_gfx10<0x037>;
 defm V_BFREV_B32         : VOP1_Real_gfx6_gfx7_gfx10<0x038>;
 defm V_FFBH_U32          : VOP1_Real_gfx6_gfx7_gfx10<0x039>;
 defm V_FFBL_B32          : VOP1_Real_gfx6_gfx7_gfx10<0x03a>;
 defm V_FFBH_I32          : VOP1_Real_gfx6_gfx7_gfx10<0x03b>;
 defm V_FREXP_EXP_I32_F64 : VOP1_Real_gfx6_gfx7_gfx10<0x03c>;
 defm V_FREXP_MANT_F64    : VOP1_Real_gfx6_gfx7_gfx10<0x03d>;
 defm V_FRACT_F64         : VOP1_Real_gfx6_gfx7_gfx10<0x03e>;
 defm V_FREXP_EXP_I32_F32 : VOP1_Real_gfx6_gfx7_gfx10<0x03f>;
 defm V_FREXP_MANT_F32    : VOP1_Real_gfx6_gfx7_gfx10<0x040>;
 defm V_CLREXCP           : VOP1_Real_gfx6_gfx7_gfx10<0x041>;
 defm V_MOVRELD_B32       : VOP1_Real_gfx6_gfx7_gfx10<0x042>;
 defm V_MOVRELS_B32       : VOP1_Real_gfx6_gfx7_gfx10<0x043>;
 defm V_MOVRELSD_B32      : VOP1_Real_gfx6_gfx7_gfx10<0x044>;

 //===----------------------------------------------------------------------===//
 // GFX8, GFX9 (VI).
 //===----------------------------------------------------------------------===//

 class VOP1_DPPe <bits<8> op, VOP1_DPP_Pseudo ps, VOPProfile P = ps.Pfl> :
   VOP_DPPe <P> {
   bits<8> vdst;
   let Inst{8-0}   = 0xfa; // dpp
   let Inst{16-9}  = op;
   let Inst{24-17} = !if(P.EmitDst, vdst{7-0}, 0);
   let Inst{31-25} = 0x3f; //encoding
 }

 multiclass VOP1Only_Real_vi <bits<10> op> {
   let AssemblerPredicate = isGFX8GFX9, DecoderNamespace = "GFX8" in {
     def _vi :
       VOP1_Real<!cast<VOP1_Pseudo>(NAME), SIEncodingFamily.VI>,
       VOP1e<op{7-0}, !cast<VOP1_Pseudo>(NAME).Pfl>;
   }
 }

 multiclass VOP1_Real_e32e64_vi <bits<10> op> {
   let AssemblerPredicate = isGFX8GFX9, DecoderNamespace = "GFX8" in {
     def _e32_vi :
       VOP1_Real<!cast<VOP1_Pseudo>(NAME#"_e32"), SIEncodingFamily.VI>,
       VOP1e<op{7-0}, !cast<VOP1_Pseudo>(NAME#"_e32").Pfl>;
     def _e64_vi :
       VOP3_Real<!cast<VOP3_Pseudo>(NAME#"_e64"), SIEncodingFamily.VI>,
       VOP3e_vi <!add(0x140, op), !cast<VOP3_Pseudo>(NAME#"_e64").Pfl>;
   }
 }

 multiclass VOP1_Real_vi <bits<10> op> {
   defm NAME : VOP1_Real_e32e64_vi <op>;

   foreach _ = BoolToList<!cast<VOP1_Pseudo>(NAME#"_e32").Pfl.HasExtSDWA>.ret in
   def _sdwa_vi :
     VOP_SDWA_Real <!cast<VOP1_SDWA_Pseudo>(NAME#"_sdwa")>,
     VOP1_SDWAe <op{7-0}, !cast<VOP1_SDWA_Pseudo>(NAME#"_sdwa").Pfl>;

   foreach _ = BoolToList<!cast<VOP1_Pseudo>(NAME#"_e32").Pfl.HasExtSDWA9>.ret in
   def _sdwa_gfx9 :
     VOP_SDWA9_Real <!cast<VOP1_SDWA_Pseudo>(NAME#"_sdwa")>,
     VOP1_SDWA9Ae <op{7-0}, !cast<VOP1_SDWA_Pseudo>(NAME#"_sdwa").Pfl>;

   foreach _ = BoolToList<!cast<VOP1_Pseudo>(NAME#"_e32").Pfl.HasExtDPP>.ret in
     def _dpp_vi :
       VOP_DPP_Real<!cast<VOP1_DPP_Pseudo>(NAME#"_dpp"), SIEncodingFamily.VI>,
       VOP1_DPPe<op{7-0}, !cast<VOP1_DPP_Pseudo>(NAME#"_dpp")>;
 }

 defm V_NOP               : VOP1_Real_vi <0x0>;
 defm V_MOV_B32           : VOP1_Real_vi <0x1>;
 defm V_CVT_I32_F64       : VOP1_Real_vi <0x3>;
 defm V_CVT_F64_I32       : VOP1_Real_vi <0x4>;
 defm V_CVT_F32_I32       : VOP1_Real_vi <0x5>;
 defm V_CVT_F32_U32       : VOP1_Real_vi <0x6>;
 defm V_CVT_U32_F32       : VOP1_Real_vi <0x7>;
 defm V_CVT_I32_F32       : VOP1_Real_vi <0x8>;
 defm V_CVT_F16_F32       : VOP1_Real_vi <0xa>;
 defm V_CVT_F32_F16       : VOP1_Real_vi <0xb>;
 defm V_CVT_RPI_I32_F32   : VOP1_Real_vi <0xc>;
 defm V_CVT_FLR_I32_F32   : VOP1_Real_vi <0xd>;
 defm V_CVT_OFF_F32_I4    : VOP1_Real_vi <0xe>;
 defm V_CVT_F32_F64       : VOP1_Real_vi <0xf>;
 defm V_CVT_F64_F32       : VOP1_Real_vi <0x10>;
 defm V_CVT_F32_UBYTE0    : VOP1_Real_vi <0x11>;
 defm V_CVT_F32_UBYTE1    : VOP1_Real_vi <0x12>;
 defm V_CVT_F32_UBYTE2    : VOP1_Real_vi <0x13>;
 defm V_CVT_F32_UBYTE3    : VOP1_Real_vi <0x14>;
 defm V_CVT_U32_F64       : VOP1_Real_vi <0x15>;
 defm V_CVT_F64_U32       : VOP1_Real_vi <0x16>;
 defm V_FRACT_F32         : VOP1_Real_vi <0x1b>;
 defm V_TRUNC_F32         : VOP1_Real_vi <0x1c>;
 defm V_CEIL_F32          : VOP1_Real_vi <0x1d>;
 defm V_RNDNE_F32         : VOP1_Real_vi <0x1e>;
 defm V_FLOOR_F32         : VOP1_Real_vi <0x1f>;
 defm V_EXP_F32           : VOP1_Real_vi <0x20>;
 defm V_LOG_F32           : VOP1_Real_vi <0x21>;
 defm V_RCP_F32           : VOP1_Real_vi <0x22>;
 defm V_RCP_IFLAG_F32     : VOP1_Real_vi <0x23>;
 defm V_RSQ_F32           : VOP1_Real_vi <0x24>;
 defm V_RCP_F64           : VOP1_Real_vi <0x25>;
 defm V_RSQ_F64           : VOP1_Real_vi <0x26>;
 defm V_SQRT_F32          : VOP1_Real_vi <0x27>;
 defm V_SQRT_F64          : VOP1_Real_vi <0x28>;
 defm V_SIN_F32           : VOP1_Real_vi <0x29>;
 defm V_COS_F32           : VOP1_Real_vi <0x2a>;
 defm V_NOT_B32           : VOP1_Real_vi <0x2b>;
 defm V_BFREV_B32         : VOP1_Real_vi <0x2c>;
 defm V_FFBH_U32          : VOP1_Real_vi <0x2d>;
 defm V_FFBL_B32          : VOP1_Real_vi <0x2e>;
 defm V_FFBH_I32          : VOP1_Real_vi <0x2f>;
 defm V_FREXP_EXP_I32_F64 : VOP1_Real_vi <0x30>;
 defm V_FREXP_MANT_F64    : VOP1_Real_vi <0x31>;
 defm V_FRACT_F64         : VOP1_Real_vi <0x32>;
 defm V_FREXP_EXP_I32_F32 : VOP1_Real_vi <0x33>;
 defm V_FREXP_MANT_F32    : VOP1_Real_vi <0x34>;
 defm V_CLREXCP           : VOP1_Real_vi <0x35>;
 defm V_MOVRELD_B32       : VOP1_Real_e32e64_vi <0x36>;
 defm V_MOVRELS_B32       : VOP1_Real_e32e64_vi <0x37>;
 defm V_MOVRELSD_B32      : VOP1_Real_e32e64_vi <0x38>;
 defm V_TRUNC_F64         : VOP1_Real_vi <0x17>;
 defm V_CEIL_F64          : VOP1_Real_vi <0x18>;
 defm V_FLOOR_F64         : VOP1_Real_vi <0x1A>;
 defm V_RNDNE_F64         : VOP1_Real_vi <0x19>;
 defm V_LOG_LEGACY_F32    : VOP1_Real_vi <0x4c>;
 defm V_EXP_LEGACY_F32    : VOP1_Real_vi <0x4b>;
 defm V_CVT_F16_U16       : VOP1_Real_vi <0x39>;
 defm V_CVT_F16_I16       : VOP1_Real_vi <0x3a>;
 defm V_CVT_U16_F16       : VOP1_Real_vi <0x3b>;
 defm V_CVT_I16_F16       : VOP1_Real_vi <0x3c>;
 defm V_RCP_F16           : VOP1_Real_vi <0x3d>;
 defm V_SQRT_F16          : VOP1_Real_vi <0x3e>;
 defm V_RSQ_F16           : VOP1_Real_vi <0x3f>;
 defm V_LOG_F16           : VOP1_Real_vi <0x40>;
 defm V_EXP_F16           : VOP1_Real_vi <0x41>;
 defm V_FREXP_MANT_F16    : VOP1_Real_vi <0x42>;
 defm V_FREXP_EXP_I16_F16 : VOP1_Real_vi <0x43>;
 defm V_FLOOR_F16         : VOP1_Real_vi <0x44>;
 defm V_CEIL_F16          : VOP1_Real_vi <0x45>;
 defm V_TRUNC_F16         : VOP1_Real_vi <0x46>;
 defm V_RNDNE_F16         : VOP1_Real_vi <0x47>;
 defm V_FRACT_F16         : VOP1_Real_vi <0x48>;
 defm V_SIN_F16           : VOP1_Real_vi <0x49>;
 defm V_COS_F16           : VOP1_Real_vi <0x4a>;
 defm V_SWAP_B32          : VOP1Only_Real_vi <0x51>;

 defm V_SAT_PK_U8_I16     : VOP1_Real_vi<0x4f>;
 defm V_CVT_NORM_I16_F16  : VOP1_Real_vi<0x4d>;
 defm V_CVT_NORM_U16_F16  : VOP1_Real_vi<0x4e>;

 defm V_ACCVGPR_MOV_B32   : VOP1Only_Real_vi<0x52>;

 let VOP1 = 1, SubtargetPredicate = isGFX8GFX9, Uses = [EXEC, M0] in {

 // Copy of v_mov_b32 with $vdst as a use operand for use with VGPR
 // indexing mode. vdst can't be treated as a def for codegen purposes,
 // and an implicit use and def of the super register should be added.
 def V_MOV_B32_indirect_write : VPseudoInstSI<(outs),
   (ins getVALUDstForVT<i32>.ret:$vdst, getVOPSrc0ForVT<i32>.ret:$src0)>,
   PseudoInstExpansion<(V_MOV_B32_e32_vi getVALUDstForVT<i32>.ret:$vdst,
                                         getVOPSrc0ForVT<i32>.ret:$src0)>;

 // Copy of v_mov_b32 for use with VGPR indexing mode. An implicit use of the
 // super register should be added.
 def V_MOV_B32_indirect_read : VPseudoInstSI<
   (outs getVALUDstForVT<i32>.ret:$vdst),
   (ins getVOPSrc0ForVT<i32>.ret:$src0)>,
   PseudoInstExpansion<(V_MOV_B32_e32_vi getVALUDstForVT<i32>.ret:$vdst,
                                         getVOPSrc0ForVT<i32>.ret:$src0)>;

 } // End VOP1 = 1, SubtargetPredicate = isGFX8GFX9, Uses = [M0]

 let OtherPredicates = [isGFX8Plus] in {

 def : GCNPat <
   (i32 (int_amdgcn_mov_dpp i32:$src, timm:$dpp_ctrl, timm:$row_mask,
                            timm:$bank_mask, timm:$bound_ctrl)),
   (V_MOV_B32_dpp VGPR_32:$src, VGPR_32:$src, (as_i32timm $dpp_ctrl),
                        (as_i32timm $row_mask), (as_i32timm $bank_mask),
                        (as_i1timm $bound_ctrl))
 >;

 def : GCNPat <
   (i32 (int_amdgcn_update_dpp i32:$old, i32:$src, timm:$dpp_ctrl,
                               timm:$row_mask, timm:$bank_mask,
                               timm:$bound_ctrl)),
   (V_MOV_B32_dpp VGPR_32:$old, VGPR_32:$src, (as_i32timm $dpp_ctrl),
                  (as_i32timm $row_mask), (as_i32timm $bank_mask),
                  (as_i1timm $bound_ctrl))
 >;

 } // End OtherPredicates = [isGFX8Plus]

 let OtherPredicates = [isGFX8Plus] in {
 def : GCNPat<
   (i32 (anyext i16:$src)),
   (COPY $src)
 >;

 def : GCNPat<
    (i64 (anyext i16:$src)),
    (REG_SEQUENCE VReg_64,
      (i32 (COPY $src)), sub0,
      (V_MOV_B32_e32 (i32 0)), sub1)
 >;

 def : GCNPat<
   (i16 (trunc i32:$src)),
   (COPY $src)
 >;

 def : GCNPat <
   (i16 (trunc i64:$src)),
   (EXTRACT_SUBREG $src, sub0)
 >;

 } // End OtherPredicates = [isGFX8Plus]

 //===----------------------------------------------------------------------===//
 // GFX9
 //===----------------------------------------------------------------------===//

 multiclass VOP1_Real_gfx9 <bits<10> op> {
   let AssemblerPredicate = isGFX9Only, DecoderNamespace = "GFX9" in {
     defm NAME : VOP1_Real_e32e64_vi <op>;
   }

   foreach _ = BoolToList<!cast<VOP1_Pseudo>(NAME#"_e32").Pfl.HasExtSDWA9>.ret in
   def _sdwa_gfx9 :
     VOP_SDWA9_Real <!cast<VOP1_SDWA_Pseudo>(NAME#"_sdwa")>,
     VOP1_SDWA9Ae <op{7-0}, !cast<VOP1_SDWA_Pseudo>(NAME#"_sdwa").Pfl>;

   foreach _ = BoolToList<!cast<VOP1_Pseudo>(NAME#"_e32").Pfl.HasExtDPP>.ret in
     def _dpp_gfx9 :
       VOP_DPP_Real<!cast<VOP1_DPP_Pseudo>(NAME#"_dpp"), SIEncodingFamily.GFX9>,
       VOP1_DPPe<op{7-0}, !cast<VOP1_DPP_Pseudo>(NAME#"_dpp")>;

 }

 defm V_SCREEN_PARTITION_4SE_B32 : VOP1_Real_gfx9 <0x37>;

 //===----------------------------------------------------------------------===//
 // GFX10
 //===----------------------------------------------------------------------===//

 let OtherPredicates = [isGFX10Plus] in {
 def : GCNPat <
   (i32 (int_amdgcn_mov_dpp8 i32:$src, timm:$dpp8)),
   (V_MOV_B32_dpp8_gfx10 VGPR_32:$src, VGPR_32:$src,
                         (as_i32timm $dpp8), (i32 DPP8Mode.FI_0))
 >;
 } // End OtherPredicates = [isGFX10Plus]