//===-- BUFInstructions.td - Buffer 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 MUBUFAddr32 : ComplexPattern; def MUBUFAddr64 : ComplexPattern; def MUBUFAddr64Atomic : ComplexPattern; def MUBUFScratchOffen : ComplexPattern; def MUBUFScratchOffset : ComplexPattern; def MUBUFOffset : ComplexPattern; def MUBUFOffsetNoGLC : ComplexPattern; def MUBUFOffsetAtomic : ComplexPattern; def BUFAddrKind { int Offset = 0; int OffEn = 1; int IdxEn = 2; int BothEn = 3; int Addr64 = 4; } class getAddrName { string ret = !if(!eq(addrKind, BUFAddrKind.Offset), "offset", !if(!eq(addrKind, BUFAddrKind.OffEn), "offen", !if(!eq(addrKind, BUFAddrKind.IdxEn), "idxen", !if(!eq(addrKind, BUFAddrKind.BothEn), "bothen", !if(!eq(addrKind, BUFAddrKind.Addr64), "addr64", ""))))); } class MUBUFAddr64Table { bit IsAddr64 = is_addr64; string OpName = Name; } class MUBUFLdsTable { bit IsLds = is_lds; string OpName = Name; } class MTBUFAddr64Table { bit IsAddr64 = is_addr64; string OpName = Name; } //===----------------------------------------------------------------------===// // MTBUF classes //===----------------------------------------------------------------------===// class MTBUFGetBaseOpcode { string ret = !subst("FORMAT_XY", "FORMAT_X", !subst("FORMAT_XYZ", "FORMAT_X", !subst("FORMAT_XYZW", "FORMAT_X", Op))); } class getMTBUFElements { int ret = 1; } class MTBUF_Pseudo pattern=[]> : InstSI, SIMCInstr { let isPseudo = 1; let isCodeGenOnly = 1; let Size = 8; let UseNamedOperandTable = 1; string Mnemonic = opName; string AsmOperands = asmOps; Instruction Opcode = !cast(NAME); Instruction BaseOpcode = !cast(MTBUFGetBaseOpcode.ret); let VM_CNT = 1; let EXP_CNT = 1; let MTBUF = 1; let Uses = [EXEC]; let hasSideEffects = 0; let SchedRW = [WriteVMEM]; let AsmMatchConverter = "cvtMtbuf"; bits<1> offen = 0; bits<1> idxen = 0; bits<1> addr64 = 0; bits<1> has_vdata = 1; bits<1> has_vaddr = 1; bits<1> has_glc = 1; bits<1> has_dlc = 1; bits<1> glc_value = 0; // the value for glc if no such operand bits<1> dlc_value = 0; // the value for dlc if no such operand bits<1> has_srsrc = 1; bits<1> has_soffset = 1; bits<1> has_offset = 1; bits<1> has_slc = 1; bits<1> has_tfe = 1; bits<4> elements = 0; } class MTBUF_Real : InstSI { let isPseudo = 0; let isCodeGenOnly = 0; // copy relevant pseudo op flags let UseNamedOperandTable = ps.UseNamedOperandTable; let SubtargetPredicate = ps.SubtargetPredicate; let AsmMatchConverter = ps.AsmMatchConverter; let Constraints = ps.Constraints; let DisableEncoding = ps.DisableEncoding; let TSFlags = ps.TSFlags; bits<12> offset; bits<1> glc; bits<1> dlc; bits<7> format; bits<8> vaddr; bits<8> vdata; bits<7> srsrc; bits<1> slc; bits<1> tfe; bits<8> soffset; bits<4> dfmt = format{3-0}; bits<3> nfmt = format{6-4}; } class getMTBUFInsDA vdataList, list vaddrList=[]> { RegisterClass vdataClass = !if(!empty(vdataList), ?, !head(vdataList)); RegisterClass vaddrClass = !if(!empty(vaddrList), ?, !head(vaddrList)); dag InsNoData = !if(!empty(vaddrList), (ins SReg_128:$srsrc, SCSrc_b32:$soffset, offset:$offset, FORMAT:$format, GLC:$glc, SLC:$slc, TFE:$tfe, DLC:$dlc, SWZ:$swz), (ins vaddrClass:$vaddr, SReg_128:$srsrc, SCSrc_b32:$soffset, offset:$offset, FORMAT:$format, GLC:$glc, SLC:$slc, TFE:$tfe, DLC:$dlc, SWZ:$swz) ); dag InsData = !if(!empty(vaddrList), (ins vdataClass:$vdata, SReg_128:$srsrc, SCSrc_b32:$soffset, offset:$offset, FORMAT:$format, GLC:$glc, SLC:$slc, TFE:$tfe, DLC:$dlc, SWZ:$swz), (ins vdataClass:$vdata, vaddrClass:$vaddr, SReg_128:$srsrc, SCSrc_b32:$soffset, offset:$offset, FORMAT:$format, GLC:$glc, SLC:$slc, TFE:$tfe, DLC:$dlc, SWZ:$swz) ); dag ret = !if(!empty(vdataList), InsNoData, InsData); } class getMTBUFIns vdataList=[]> { dag ret = !if(!eq(addrKind, BUFAddrKind.Offset), getMTBUFInsDA.ret, !if(!eq(addrKind, BUFAddrKind.OffEn), getMTBUFInsDA.ret, !if(!eq(addrKind, BUFAddrKind.IdxEn), getMTBUFInsDA.ret, !if(!eq(addrKind, BUFAddrKind.BothEn), getMTBUFInsDA.ret, !if(!eq(addrKind, BUFAddrKind.Addr64), getMTBUFInsDA.ret, (ins)))))); } class getMTBUFAsmOps { string Pfx = !if(!eq(addrKind, BUFAddrKind.Offset), "off, $srsrc,$format $soffset", !if(!eq(addrKind, BUFAddrKind.OffEn), "$vaddr, $srsrc,$format $soffset offen", !if(!eq(addrKind, BUFAddrKind.IdxEn), "$vaddr, $srsrc,$format $soffset idxen", !if(!eq(addrKind, BUFAddrKind.BothEn), "$vaddr, $srsrc,$format $soffset idxen offen", !if(!eq(addrKind, BUFAddrKind.Addr64), "$vaddr, $srsrc,$format $soffset addr64", ""))))); string ret = Pfx # "$offset"; } class MTBUF_SetupAddr { bits<1> offen = !or(!eq(addrKind, BUFAddrKind.OffEn), !eq(addrKind, BUFAddrKind.BothEn)); bits<1> idxen = !or(!eq(addrKind, BUFAddrKind.IdxEn), !eq(addrKind, BUFAddrKind.BothEn)); bits<1> addr64 = !eq(addrKind, BUFAddrKind.Addr64); bits<1> has_vaddr = !ne(addrKind, BUFAddrKind.Offset); } class MTBUF_Load_Pseudo pattern=[], // Workaround bug bz30254 int addrKindCopy = addrKind> : MTBUF_Pseudo.ret, " $vdata, " # getMTBUFAsmOps.ret # "$glc$slc$tfe$dlc$swz", pattern>, MTBUF_SetupAddr { let PseudoInstr = opName # "_" # getAddrName.ret; let mayLoad = 1; let mayStore = 0; let elements = elems; } multiclass MTBUF_Pseudo_Loads { def _OFFSET : MTBUF_Load_Pseudo , MTBUFAddr64Table<0, NAME>; def _ADDR64 : MTBUF_Load_Pseudo , MTBUFAddr64Table<1, NAME>; def _OFFEN : MTBUF_Load_Pseudo ; def _IDXEN : MTBUF_Load_Pseudo ; def _BOTHEN : MTBUF_Load_Pseudo ; let DisableWQM = 1 in { def _OFFSET_exact : MTBUF_Load_Pseudo ; def _OFFEN_exact : MTBUF_Load_Pseudo ; def _IDXEN_exact : MTBUF_Load_Pseudo ; def _BOTHEN_exact : MTBUF_Load_Pseudo ; } } class MTBUF_Store_Pseudo pattern=[], // Workaround bug bz30254 int addrKindCopy = addrKind, RegisterClass vdataClassCopy = vdataClass> : MTBUF_Pseudo.ret, " $vdata, " # getMTBUFAsmOps.ret # "$glc$slc$tfe$dlc$swz", pattern>, MTBUF_SetupAddr { let PseudoInstr = opName # "_" # getAddrName.ret; let mayLoad = 0; let mayStore = 1; let elements = elems; } multiclass MTBUF_Pseudo_Stores { def _OFFSET : MTBUF_Store_Pseudo , MTBUFAddr64Table<0, NAME>; def _ADDR64 : MTBUF_Store_Pseudo , MTBUFAddr64Table<1, NAME>; def _OFFEN : MTBUF_Store_Pseudo ; def _IDXEN : MTBUF_Store_Pseudo ; def _BOTHEN : MTBUF_Store_Pseudo ; let DisableWQM = 1 in { def _OFFSET_exact : MTBUF_Store_Pseudo ; def _OFFEN_exact : MTBUF_Store_Pseudo ; def _IDXEN_exact : MTBUF_Store_Pseudo ; def _BOTHEN_exact : MTBUF_Store_Pseudo ; } } //===----------------------------------------------------------------------===// // MUBUF classes //===----------------------------------------------------------------------===// class MUBUFGetBaseOpcode { string ret = !subst("DWORDX2", "DWORD", !subst("DWORDX3", "DWORD", !subst("DWORDX4", "DWORD", Op))); } class MUBUF_Pseudo pattern=[]> : InstSI, SIMCInstr { let isPseudo = 1; let isCodeGenOnly = 1; let Size = 8; let UseNamedOperandTable = 1; string Mnemonic = opName; string AsmOperands = asmOps; Instruction Opcode = !cast(NAME); Instruction BaseOpcode = !cast(MUBUFGetBaseOpcode.ret); let VM_CNT = 1; let EXP_CNT = 1; let MUBUF = 1; let Uses = [EXEC]; let hasSideEffects = 0; let SchedRW = [WriteVMEM]; let AsmMatchConverter = "cvtMubuf"; bits<1> offen = 0; bits<1> idxen = 0; bits<1> addr64 = 0; bits<1> lds = 0; bits<1> has_vdata = 1; bits<1> has_vaddr = 1; bits<1> has_glc = 1; bits<1> has_dlc = 1; bits<1> glc_value = 0; // the value for glc if no such operand bits<1> dlc_value = 0; // the value for dlc if no such operand bits<1> has_srsrc = 1; bits<1> has_soffset = 1; bits<1> has_offset = 1; bits<1> has_slc = 1; bits<1> has_tfe = 1; bits<4> elements = 0; } class MUBUF_Real : InstSI { let isPseudo = 0; let isCodeGenOnly = 0; // copy relevant pseudo op flags let SubtargetPredicate = ps.SubtargetPredicate; let AsmMatchConverter = ps.AsmMatchConverter; let Constraints = ps.Constraints; let DisableEncoding = ps.DisableEncoding; let TSFlags = ps.TSFlags; bits<12> offset; bits<1> glc; bits<1> dlc; bits<8> vaddr; bits<8> vdata; bits<7> srsrc; bits<1> slc; bits<1> tfe; bits<8> soffset; } // For cache invalidation instructions. class MUBUF_Invalidate : MUBUF_Pseudo { let AsmMatchConverter = ""; let hasSideEffects = 1; let mayLoad = 0; let mayStore = 0; // Set everything to 0. let offen = 0; let idxen = 0; let addr64 = 0; let has_vdata = 0; let has_vaddr = 0; let has_glc = 0; let has_dlc = 0; let glc_value = 0; let dlc_value = 0; let has_srsrc = 0; let has_soffset = 0; let has_offset = 0; let has_slc = 0; let has_tfe = 0; } class getMUBUFInsDA vdataList, list vaddrList=[], bit isLds = 0> { RegisterClass vdataClass = !if(!empty(vdataList), ?, !head(vdataList)); RegisterClass vaddrClass = !if(!empty(vaddrList), ?, !head(vaddrList)); dag InsNoData = !if(!empty(vaddrList), (ins SReg_128:$srsrc, SCSrc_b32:$soffset, offset:$offset, GLC:$glc, SLC:$slc), (ins vaddrClass:$vaddr, SReg_128:$srsrc, SCSrc_b32:$soffset, offset:$offset, GLC:$glc, SLC:$slc) ); dag InsData = !if(!empty(vaddrList), (ins vdataClass:$vdata, SReg_128:$srsrc, SCSrc_b32:$soffset, offset:$offset, GLC:$glc, SLC:$slc), (ins vdataClass:$vdata, vaddrClass:$vaddr, SReg_128:$srsrc, SCSrc_b32:$soffset, offset:$offset, GLC:$glc, SLC:$slc) ); dag ret = !con( !if(!empty(vdataList), InsNoData, InsData), !if(isLds, (ins DLC:$dlc, SWZ:$swz), (ins TFE:$tfe, DLC:$dlc,SWZ:$swz)) ); } class getMUBUFElements { // eq does not support ValueType for some reason. string vtAsStr = !cast(vt); int ret = !if(!eq(vtAsStr, "f16"), 1, !if(!eq(vtAsStr, "v2f16"), 2, !if(!eq(vtAsStr, "v3f16"), 3, !if(!eq(vtAsStr, "v4f16"), 4, !if(!eq(vt.Size, 32), 1, !if(!eq(vt.Size, 64), 2, !if(!eq(vt.Size, 96), 3, !if(!eq(vt.Size, 128), 4, 0) ) ) ) ) ) ) ); } class getMUBUFIns vdataList=[], bit isLds = 0> { dag ret = !if(!eq(addrKind, BUFAddrKind.Offset), getMUBUFInsDA.ret, !if(!eq(addrKind, BUFAddrKind.OffEn), getMUBUFInsDA.ret, !if(!eq(addrKind, BUFAddrKind.IdxEn), getMUBUFInsDA.ret, !if(!eq(addrKind, BUFAddrKind.BothEn), getMUBUFInsDA.ret, !if(!eq(addrKind, BUFAddrKind.Addr64), getMUBUFInsDA.ret, (ins)))))); } class getMUBUFAsmOps { string Pfx = !if(!eq(addrKind, BUFAddrKind.Offset), "off, $srsrc, $soffset", !if(!eq(addrKind, BUFAddrKind.OffEn), "$vaddr, $srsrc, $soffset offen", !if(!eq(addrKind, BUFAddrKind.IdxEn), "$vaddr, $srsrc, $soffset idxen", !if(!eq(addrKind, BUFAddrKind.BothEn), "$vaddr, $srsrc, $soffset idxen offen", !if(!eq(addrKind, BUFAddrKind.Addr64), "$vaddr, $srsrc, $soffset addr64", ""))))); string ret = Pfx # "$offset"; } class MUBUF_SetupAddr { bits<1> offen = !or(!eq(addrKind, BUFAddrKind.OffEn), !eq(addrKind, BUFAddrKind.BothEn)); bits<1> idxen = !or(!eq(addrKind, BUFAddrKind.IdxEn), !eq(addrKind, BUFAddrKind.BothEn)); bits<1> addr64 = !eq(addrKind, BUFAddrKind.Addr64); bits<1> has_vaddr = !ne(addrKind, BUFAddrKind.Offset); } class MUBUF_Load_Pseudo pattern=[], // Workaround bug bz30254 int addrKindCopy = addrKind> : MUBUF_Pseudo.ret:$vdata), !con(getMUBUFIns.ret, !if(HasTiedDest, (ins getVregSrcForVT.ret:$vdata_in), (ins))), " $vdata, " # getMUBUFAsmOps.ret # "$glc$slc" # !if(isLds, " lds", "$tfe") # "$dlc" # "$swz", pattern>, MUBUF_SetupAddr { let PseudoInstr = opName # !if(isLds, "_lds", "") # "_" # getAddrName.ret; let AsmMatchConverter = !if(isLds, "cvtMubufLds", "cvtMubuf"); let Constraints = !if(HasTiedDest, "$vdata = $vdata_in", ""); let mayLoad = 1; let mayStore = 0; let maybeAtomic = 1; let Uses = !if(isLds, [EXEC, M0], [EXEC]); let has_tfe = !not(isLds); let lds = isLds; let elements = getMUBUFElements.ret; } class MUBUF_Offset_Load_Pat : Pat < (load_vt (ld (MUBUFOffset v4i32:$srsrc, i32:$soffset, i16:$offset, i1:$glc, i1:$slc, i1:$tfe, i1:$dlc, i1:$swz))), (load_vt (inst v4i32:$srsrc, i32:$soffset, i16:$offset, i1:$glc, i1:$slc, i1:$tfe, i1:$dlc, i1:$swz)) >; class MUBUF_Addr64_Load_Pat : Pat < (load_vt (ld (MUBUFAddr64 v4i32:$srsrc, i64:$vaddr, i32:$soffset, i16:$offset, i1:$glc, i1:$slc, i1:$tfe, i1:$dlc, i1:$swz))), (load_vt (inst i64:$vaddr, v4i32:$srsrc, i32:$soffset, i16:$offset, i1:$glc, i1:$slc, i1:$tfe, i1:$dlc, i1:$swz)) >; multiclass MUBUF_Pseudo_Load_Pats { def : MUBUF_Offset_Load_Pat(BaseInst#"_OFFSET"), load_vt, ld>; def : MUBUF_Addr64_Load_Pat(BaseInst#"_ADDR64"), load_vt, ld>; } // FIXME: tfe can't be an operand because it requires a separate // opcode because it needs an N+1 register class dest register. multiclass MUBUF_Pseudo_Loads { defvar legal_load_vt = !if(!eq(!cast(load_vt), !cast(v3f16)), v4f16, load_vt); def _OFFSET : MUBUF_Load_Pseudo , MUBUFAddr64Table<0, NAME # !if(isLds, "_LDS", "")>; def _ADDR64 : MUBUF_Load_Pseudo , MUBUFAddr64Table<1, NAME # !if(isLds, "_LDS", "")>; def _OFFEN : MUBUF_Load_Pseudo ; def _IDXEN : MUBUF_Load_Pseudo ; def _BOTHEN : MUBUF_Load_Pseudo ; let DisableWQM = 1 in { def _OFFSET_exact : MUBUF_Load_Pseudo ; def _OFFEN_exact : MUBUF_Load_Pseudo ; def _IDXEN_exact : MUBUF_Load_Pseudo ; def _BOTHEN_exact : MUBUF_Load_Pseudo ; } } multiclass MUBUF_Pseudo_Loads_Lds { defm NAME : MUBUF_Pseudo_Loads; defm _LDS : MUBUF_Pseudo_Loads; } class MUBUF_Store_Pseudo pattern=[], // Workaround bug bz30254 int addrKindCopy = addrKind> : MUBUF_Pseudo.ret]>.ret, " $vdata, " # getMUBUFAsmOps.ret # "$glc$slc$tfe$dlc$swz", pattern>, MUBUF_SetupAddr { let PseudoInstr = opName # "_" # getAddrName.ret; let mayLoad = 0; let mayStore = 1; let maybeAtomic = 1; let elements = getMUBUFElements.ret; } multiclass MUBUF_Pseudo_Stores { defvar legal_store_vt = !if(!eq(!cast(store_vt), !cast(v3f16)), v4f16, store_vt); def _OFFSET : MUBUF_Store_Pseudo , MUBUFAddr64Table<0, NAME>; def _ADDR64 : MUBUF_Store_Pseudo , MUBUFAddr64Table<1, NAME>; def _OFFEN : MUBUF_Store_Pseudo ; def _IDXEN : MUBUF_Store_Pseudo ; def _BOTHEN : MUBUF_Store_Pseudo ; let DisableWQM = 1 in { def _OFFSET_exact : MUBUF_Store_Pseudo ; def _OFFEN_exact : MUBUF_Store_Pseudo ; def _IDXEN_exact : MUBUF_Store_Pseudo ; def _BOTHEN_exact : MUBUF_Store_Pseudo ; } } class MUBUF_Pseudo_Store_Lds : MUBUF_Pseudo { let mayLoad = 0; let mayStore = 1; let maybeAtomic = 1; let has_vdata = 0; let has_vaddr = 0; let has_tfe = 0; let lds = 1; let Uses = [EXEC, M0]; let AsmMatchConverter = "cvtMubufLds"; } class getMUBUFAtomicInsDA vaddrList=[]> { RegisterClass vaddrClass = !if(!empty(vaddrList), ?, !head(vaddrList)); dag ret = !if(vdata_in, !if(!empty(vaddrList), (ins vdataClass:$vdata_in, SReg_128:$srsrc, SCSrc_b32:$soffset, offset:$offset, SLC:$slc), (ins vdataClass:$vdata_in, vaddrClass:$vaddr, SReg_128:$srsrc, SCSrc_b32:$soffset, offset:$offset, SLC:$slc) ), !if(!empty(vaddrList), (ins vdataClass:$vdata, SReg_128:$srsrc, SCSrc_b32:$soffset, offset:$offset, SLC:$slc), (ins vdataClass:$vdata, vaddrClass:$vaddr, SReg_128:$srsrc, SCSrc_b32:$soffset, offset:$offset, SLC:$slc) )); } class getMUBUFAtomicIns { dag ret = !if(!eq(addrKind, BUFAddrKind.Offset), getMUBUFAtomicInsDA.ret, !if(!eq(addrKind, BUFAddrKind.OffEn), getMUBUFAtomicInsDA.ret, !if(!eq(addrKind, BUFAddrKind.IdxEn), getMUBUFAtomicInsDA.ret, !if(!eq(addrKind, BUFAddrKind.BothEn), getMUBUFAtomicInsDA.ret, !if(!eq(addrKind, BUFAddrKind.Addr64), getMUBUFAtomicInsDA.ret, (ins)))))); } class MUBUF_Atomic_Pseudo pattern=[], // Workaround bug bz30254 int addrKindCopy = addrKind> : MUBUF_Pseudo, MUBUF_SetupAddr { let mayStore = 1; let mayLoad = 1; let hasPostISelHook = 1; let hasSideEffects = 1; let DisableWQM = 1; let has_glc = 0; let has_dlc = 0; let has_tfe = 0; let maybeAtomic = 1; } class MUBUF_AtomicNoRet_Pseudo pattern=[], // Workaround bug bz30254 int addrKindCopy = addrKind, RegisterClass vdataClassCopy = vdataClass> : MUBUF_Atomic_Pseudo.ret, " $vdata, " # getMUBUFAsmOps.ret # "$slc", pattern>, AtomicNoRet.ret, 0> { let PseudoInstr = opName # "_" # getAddrName.ret; let glc_value = 0; let dlc_value = 0; let AsmMatchConverter = "cvtMubufAtomic"; } class MUBUF_AtomicRet_Pseudo pattern=[], // Workaround bug bz30254 int addrKindCopy = addrKind, RegisterClass vdataClassCopy = vdataClass> : MUBUF_Atomic_Pseudo.ret, " $vdata, " # getMUBUFAsmOps.ret # " glc$slc", pattern>, AtomicNoRet.ret, 1> { let PseudoInstr = opName # "_rtn_" # getAddrName.ret; let glc_value = 1; let dlc_value = 0; let Constraints = "$vdata = $vdata_in"; let DisableEncoding = "$vdata_in"; let AsmMatchConverter = "cvtMubufAtomicReturn"; } multiclass MUBUF_Pseudo_Atomics_NO_RTN .ret> { let FPAtomic = isFP in def _OFFSET : MUBUF_AtomicNoRet_Pseudo , MUBUFAddr64Table <0, NAME>; let FPAtomic = isFP in def _ADDR64 : MUBUF_AtomicNoRet_Pseudo , MUBUFAddr64Table <1, NAME>; let FPAtomic = isFP in def _OFFEN : MUBUF_AtomicNoRet_Pseudo ; let FPAtomic = isFP in def _IDXEN : MUBUF_AtomicNoRet_Pseudo ; let FPAtomic = isFP in def _BOTHEN : MUBUF_AtomicNoRet_Pseudo ; } multiclass MUBUF_Pseudo_Atomics_RTN .ret> { let FPAtomic = isFP in def _OFFSET_RTN : MUBUF_AtomicRet_Pseudo , MUBUFAddr64Table <0, NAME # "_RTN">; let FPAtomic = isFP in def _ADDR64_RTN : MUBUF_AtomicRet_Pseudo , MUBUFAddr64Table <1, NAME # "_RTN">; let FPAtomic = isFP in def _OFFEN_RTN : MUBUF_AtomicRet_Pseudo ; let FPAtomic = isFP in def _IDXEN_RTN : MUBUF_AtomicRet_Pseudo ; let FPAtomic = isFP in def _BOTHEN_RTN : MUBUF_AtomicRet_Pseudo ; } multiclass MUBUF_Pseudo_Atomics : MUBUF_Pseudo_Atomics_NO_RTN, MUBUF_Pseudo_Atomics_RTN; //===----------------------------------------------------------------------===// // MUBUF Instructions //===----------------------------------------------------------------------===// defm BUFFER_LOAD_FORMAT_X : MUBUF_Pseudo_Loads_Lds < "buffer_load_format_x", f32 >; defm BUFFER_LOAD_FORMAT_XY : MUBUF_Pseudo_Loads < "buffer_load_format_xy", v2f32 >; defm BUFFER_LOAD_FORMAT_XYZ : MUBUF_Pseudo_Loads < "buffer_load_format_xyz", v3f32 >; defm BUFFER_LOAD_FORMAT_XYZW : MUBUF_Pseudo_Loads < "buffer_load_format_xyzw", v4f32 >; defm BUFFER_STORE_FORMAT_X : MUBUF_Pseudo_Stores < "buffer_store_format_x", f32 >; defm BUFFER_STORE_FORMAT_XY : MUBUF_Pseudo_Stores < "buffer_store_format_xy", v2f32 >; defm BUFFER_STORE_FORMAT_XYZ : MUBUF_Pseudo_Stores < "buffer_store_format_xyz", v3f32 >; defm BUFFER_STORE_FORMAT_XYZW : MUBUF_Pseudo_Stores < "buffer_store_format_xyzw", v4f32 >; let SubtargetPredicate = HasUnpackedD16VMem, D16Buf = 1 in { defm BUFFER_LOAD_FORMAT_D16_X_gfx80 : MUBUF_Pseudo_Loads < "buffer_load_format_d16_x", i32 >; defm BUFFER_LOAD_FORMAT_D16_XY_gfx80 : MUBUF_Pseudo_Loads < "buffer_load_format_d16_xy", v2i32 >; defm BUFFER_LOAD_FORMAT_D16_XYZ_gfx80 : MUBUF_Pseudo_Loads < "buffer_load_format_d16_xyz", v3i32 >; defm BUFFER_LOAD_FORMAT_D16_XYZW_gfx80 : MUBUF_Pseudo_Loads < "buffer_load_format_d16_xyzw", v4i32 >; defm BUFFER_STORE_FORMAT_D16_X_gfx80 : MUBUF_Pseudo_Stores < "buffer_store_format_d16_x", i32 >; defm BUFFER_STORE_FORMAT_D16_XY_gfx80 : MUBUF_Pseudo_Stores < "buffer_store_format_d16_xy", v2i32 >; defm BUFFER_STORE_FORMAT_D16_XYZ_gfx80 : MUBUF_Pseudo_Stores < "buffer_store_format_d16_xyz", v3i32 >; defm BUFFER_STORE_FORMAT_D16_XYZW_gfx80 : MUBUF_Pseudo_Stores < "buffer_store_format_d16_xyzw", v4i32 >; } // End HasUnpackedD16VMem. let SubtargetPredicate = HasPackedD16VMem, D16Buf = 1 in { defm BUFFER_LOAD_FORMAT_D16_X : MUBUF_Pseudo_Loads < "buffer_load_format_d16_x", f16 >; defm BUFFER_LOAD_FORMAT_D16_XY : MUBUF_Pseudo_Loads < "buffer_load_format_d16_xy", v2f16 >; defm BUFFER_LOAD_FORMAT_D16_XYZ : MUBUF_Pseudo_Loads < "buffer_load_format_d16_xyz", v3f16 >; defm BUFFER_LOAD_FORMAT_D16_XYZW : MUBUF_Pseudo_Loads < "buffer_load_format_d16_xyzw", v4f16 >; defm BUFFER_STORE_FORMAT_D16_X : MUBUF_Pseudo_Stores < "buffer_store_format_d16_x", f16 >; defm BUFFER_STORE_FORMAT_D16_XY : MUBUF_Pseudo_Stores < "buffer_store_format_d16_xy", v2f16 >; defm BUFFER_STORE_FORMAT_D16_XYZ : MUBUF_Pseudo_Stores < "buffer_store_format_d16_xyz", v3f16 >; defm BUFFER_STORE_FORMAT_D16_XYZW : MUBUF_Pseudo_Stores < "buffer_store_format_d16_xyzw", v4f16 >; } // End HasPackedD16VMem. defm BUFFER_LOAD_UBYTE : MUBUF_Pseudo_Loads_Lds < "buffer_load_ubyte", i32 >; defm BUFFER_LOAD_SBYTE : MUBUF_Pseudo_Loads_Lds < "buffer_load_sbyte", i32 >; defm BUFFER_LOAD_USHORT : MUBUF_Pseudo_Loads_Lds < "buffer_load_ushort", i32 >; defm BUFFER_LOAD_SSHORT : MUBUF_Pseudo_Loads_Lds < "buffer_load_sshort", i32 >; defm BUFFER_LOAD_DWORD : MUBUF_Pseudo_Loads_Lds < "buffer_load_dword", i32 >; defm BUFFER_LOAD_DWORDX2 : MUBUF_Pseudo_Loads < "buffer_load_dwordx2", v2i32 >; defm BUFFER_LOAD_DWORDX3 : MUBUF_Pseudo_Loads < "buffer_load_dwordx3", v3i32 >; defm BUFFER_LOAD_DWORDX4 : MUBUF_Pseudo_Loads < "buffer_load_dwordx4", v4i32 >; defm : MUBUF_Pseudo_Load_Pats<"BUFFER_LOAD_UBYTE", i32, extloadi8_global>; defm : MUBUF_Pseudo_Load_Pats<"BUFFER_LOAD_UBYTE", i32, zextloadi8_global>; defm : MUBUF_Pseudo_Load_Pats<"BUFFER_LOAD_SBYTE", i32, sextloadi8_global>; defm : MUBUF_Pseudo_Load_Pats<"BUFFER_LOAD_USHORT", i32, extloadi16_global>; defm : MUBUF_Pseudo_Load_Pats<"BUFFER_LOAD_USHORT", i32, zextloadi16_global>; defm : MUBUF_Pseudo_Load_Pats<"BUFFER_LOAD_SSHORT", i32, sextloadi16_global>; defm : MUBUF_Pseudo_Load_Pats<"BUFFER_LOAD_DWORD", i32, load_global>; defm : MUBUF_Pseudo_Load_Pats<"BUFFER_LOAD_DWORDX2", v2i32, load_global>; defm : MUBUF_Pseudo_Load_Pats<"BUFFER_LOAD_DWORDX3", v3i32, load_global>; defm : MUBUF_Pseudo_Load_Pats<"BUFFER_LOAD_DWORDX4", v4i32, load_global>; // This is not described in AMD documentation, // but 'lds' versions of these opcodes are available // in at least GFX8+ chips. See Bug 37653. let SubtargetPredicate = isGFX8GFX9 in { defm BUFFER_LOAD_DWORDX2_LDS : MUBUF_Pseudo_Loads < "buffer_load_dwordx2", v2i32, null_frag, 0, 1 >; defm BUFFER_LOAD_DWORDX3_LDS : MUBUF_Pseudo_Loads < "buffer_load_dwordx3", v3i32, null_frag, 0, 1 >; defm BUFFER_LOAD_DWORDX4_LDS : MUBUF_Pseudo_Loads < "buffer_load_dwordx4", v4i32, null_frag, 0, 1 >; } defm BUFFER_STORE_BYTE : MUBUF_Pseudo_Stores < "buffer_store_byte", i32, truncstorei8_global >; defm BUFFER_STORE_SHORT : MUBUF_Pseudo_Stores < "buffer_store_short", i32, truncstorei16_global >; defm BUFFER_STORE_DWORD : MUBUF_Pseudo_Stores < "buffer_store_dword", i32, store_global >; defm BUFFER_STORE_DWORDX2 : MUBUF_Pseudo_Stores < "buffer_store_dwordx2", v2i32, store_global >; defm BUFFER_STORE_DWORDX3 : MUBUF_Pseudo_Stores < "buffer_store_dwordx3", v3i32, store_global >; defm BUFFER_STORE_DWORDX4 : MUBUF_Pseudo_Stores < "buffer_store_dwordx4", v4i32, store_global >; defm BUFFER_ATOMIC_SWAP : MUBUF_Pseudo_Atomics < "buffer_atomic_swap", VGPR_32, i32, atomic_swap_global_32 >; defm BUFFER_ATOMIC_CMPSWAP : MUBUF_Pseudo_Atomics < "buffer_atomic_cmpswap", VReg_64, v2i32, null_frag >; defm BUFFER_ATOMIC_ADD : MUBUF_Pseudo_Atomics < "buffer_atomic_add", VGPR_32, i32, atomic_load_add_global_32 >; defm BUFFER_ATOMIC_SUB : MUBUF_Pseudo_Atomics < "buffer_atomic_sub", VGPR_32, i32, atomic_load_sub_global_32 >; defm BUFFER_ATOMIC_SMIN : MUBUF_Pseudo_Atomics < "buffer_atomic_smin", VGPR_32, i32, atomic_load_min_global_32 >; defm BUFFER_ATOMIC_UMIN : MUBUF_Pseudo_Atomics < "buffer_atomic_umin", VGPR_32, i32, atomic_load_umin_global_32 >; defm BUFFER_ATOMIC_SMAX : MUBUF_Pseudo_Atomics < "buffer_atomic_smax", VGPR_32, i32, atomic_load_max_global_32 >; defm BUFFER_ATOMIC_UMAX : MUBUF_Pseudo_Atomics < "buffer_atomic_umax", VGPR_32, i32, atomic_load_umax_global_32 >; defm BUFFER_ATOMIC_AND : MUBUF_Pseudo_Atomics < "buffer_atomic_and", VGPR_32, i32, atomic_load_and_global_32 >; defm BUFFER_ATOMIC_OR : MUBUF_Pseudo_Atomics < "buffer_atomic_or", VGPR_32, i32, atomic_load_or_global_32 >; defm BUFFER_ATOMIC_XOR : MUBUF_Pseudo_Atomics < "buffer_atomic_xor", VGPR_32, i32, atomic_load_xor_global_32 >; defm BUFFER_ATOMIC_INC : MUBUF_Pseudo_Atomics < "buffer_atomic_inc", VGPR_32, i32, atomic_inc_global_32 >; defm BUFFER_ATOMIC_DEC : MUBUF_Pseudo_Atomics < "buffer_atomic_dec", VGPR_32, i32, atomic_dec_global_32 >; defm BUFFER_ATOMIC_SWAP_X2 : MUBUF_Pseudo_Atomics < "buffer_atomic_swap_x2", VReg_64, i64, atomic_swap_global_64 >; defm BUFFER_ATOMIC_CMPSWAP_X2 : MUBUF_Pseudo_Atomics < "buffer_atomic_cmpswap_x2", VReg_128, v2i64, null_frag >; defm BUFFER_ATOMIC_ADD_X2 : MUBUF_Pseudo_Atomics < "buffer_atomic_add_x2", VReg_64, i64, atomic_load_add_global_64 >; defm BUFFER_ATOMIC_SUB_X2 : MUBUF_Pseudo_Atomics < "buffer_atomic_sub_x2", VReg_64, i64, atomic_load_sub_global_64 >; defm BUFFER_ATOMIC_SMIN_X2 : MUBUF_Pseudo_Atomics < "buffer_atomic_smin_x2", VReg_64, i64, atomic_load_min_global_64 >; defm BUFFER_ATOMIC_UMIN_X2 : MUBUF_Pseudo_Atomics < "buffer_atomic_umin_x2", VReg_64, i64, atomic_load_umin_global_64 >; defm BUFFER_ATOMIC_SMAX_X2 : MUBUF_Pseudo_Atomics < "buffer_atomic_smax_x2", VReg_64, i64, atomic_load_max_global_64 >; defm BUFFER_ATOMIC_UMAX_X2 : MUBUF_Pseudo_Atomics < "buffer_atomic_umax_x2", VReg_64, i64, atomic_load_umax_global_64 >; defm BUFFER_ATOMIC_AND_X2 : MUBUF_Pseudo_Atomics < "buffer_atomic_and_x2", VReg_64, i64, atomic_load_and_global_64 >; defm BUFFER_ATOMIC_OR_X2 : MUBUF_Pseudo_Atomics < "buffer_atomic_or_x2", VReg_64, i64, atomic_load_or_global_64 >; defm BUFFER_ATOMIC_XOR_X2 : MUBUF_Pseudo_Atomics < "buffer_atomic_xor_x2", VReg_64, i64, atomic_load_xor_global_64 >; defm BUFFER_ATOMIC_INC_X2 : MUBUF_Pseudo_Atomics < "buffer_atomic_inc_x2", VReg_64, i64, atomic_inc_global_64 >; defm BUFFER_ATOMIC_DEC_X2 : MUBUF_Pseudo_Atomics < "buffer_atomic_dec_x2", VReg_64, i64, atomic_dec_global_64 >; let SubtargetPredicate = HasGFX10_BEncoding in defm BUFFER_ATOMIC_CSUB : MUBUF_Pseudo_Atomics_RTN < "buffer_atomic_csub", VGPR_32, i32, int_amdgcn_global_atomic_csub >; let SubtargetPredicate = isGFX8GFX9 in { def BUFFER_STORE_LDS_DWORD : MUBUF_Pseudo_Store_Lds <"buffer_store_lds_dword">; } let SubtargetPredicate = isGFX6 in { // isn't on CI & VI /* defm BUFFER_ATOMIC_RSUB : MUBUF_Pseudo_Atomics <"buffer_atomic_rsub">; defm BUFFER_ATOMIC_RSUB_X2 : MUBUF_Pseudo_Atomics <"buffer_atomic_rsub_x2">; */ def BUFFER_WBINVL1_SC : MUBUF_Invalidate <"buffer_wbinvl1_sc", int_amdgcn_buffer_wbinvl1_sc>; } let SubtargetPredicate = isGFX6GFX7GFX10 in { defm BUFFER_ATOMIC_FCMPSWAP : MUBUF_Pseudo_Atomics < "buffer_atomic_fcmpswap", VReg_64, v2f32, null_frag >; defm BUFFER_ATOMIC_FMIN : MUBUF_Pseudo_Atomics < "buffer_atomic_fmin", VGPR_32, f32, null_frag >; defm BUFFER_ATOMIC_FMAX : MUBUF_Pseudo_Atomics < "buffer_atomic_fmax", VGPR_32, f32, null_frag >; defm BUFFER_ATOMIC_FCMPSWAP_X2 : MUBUF_Pseudo_Atomics < "buffer_atomic_fcmpswap_x2", VReg_128, v2f64, null_frag >; defm BUFFER_ATOMIC_FMIN_X2 : MUBUF_Pseudo_Atomics < "buffer_atomic_fmin_x2", VReg_64, f64, null_frag >; defm BUFFER_ATOMIC_FMAX_X2 : MUBUF_Pseudo_Atomics < "buffer_atomic_fmax_x2", VReg_64, f64, null_frag >; } let SubtargetPredicate = HasD16LoadStore in { defm BUFFER_LOAD_UBYTE_D16 : MUBUF_Pseudo_Loads < "buffer_load_ubyte_d16", i32, null_frag, 1 >; defm BUFFER_LOAD_UBYTE_D16_HI : MUBUF_Pseudo_Loads < "buffer_load_ubyte_d16_hi", i32, null_frag, 1 >; defm BUFFER_LOAD_SBYTE_D16 : MUBUF_Pseudo_Loads < "buffer_load_sbyte_d16", i32, null_frag, 1 >; defm BUFFER_LOAD_SBYTE_D16_HI : MUBUF_Pseudo_Loads < "buffer_load_sbyte_d16_hi", i32, null_frag, 1 >; defm BUFFER_LOAD_SHORT_D16 : MUBUF_Pseudo_Loads < "buffer_load_short_d16", i32, null_frag, 1 >; defm BUFFER_LOAD_SHORT_D16_HI : MUBUF_Pseudo_Loads < "buffer_load_short_d16_hi", i32, null_frag, 1 >; defm BUFFER_STORE_BYTE_D16_HI : MUBUF_Pseudo_Stores < "buffer_store_byte_d16_hi", i32 >; defm BUFFER_STORE_SHORT_D16_HI : MUBUF_Pseudo_Stores < "buffer_store_short_d16_hi", i32 >; defm BUFFER_LOAD_FORMAT_D16_HI_X : MUBUF_Pseudo_Loads < "buffer_load_format_d16_hi_x", i32 >; defm BUFFER_STORE_FORMAT_D16_HI_X : MUBUF_Pseudo_Stores < "buffer_store_format_d16_hi_x", i32 >; } // End HasD16LoadStore def BUFFER_WBINVL1 : MUBUF_Invalidate <"buffer_wbinvl1", int_amdgcn_buffer_wbinvl1>; let SubtargetPredicate = HasAtomicFaddInsts in { defm BUFFER_ATOMIC_ADD_F32 : MUBUF_Pseudo_Atomics_NO_RTN < "buffer_atomic_add_f32", VGPR_32, f32, atomic_load_fadd_global_noret_32 >; defm BUFFER_ATOMIC_PK_ADD_F16 : MUBUF_Pseudo_Atomics_NO_RTN < "buffer_atomic_pk_add_f16", VGPR_32, v2f16, atomic_load_fadd_v2f16_global_noret_32 >; } // End SubtargetPredicate = HasAtomicFaddInsts //===----------------------------------------------------------------------===// // MTBUF Instructions //===----------------------------------------------------------------------===// defm TBUFFER_LOAD_FORMAT_X : MTBUF_Pseudo_Loads <"tbuffer_load_format_x", VGPR_32, 1>; defm TBUFFER_LOAD_FORMAT_XY : MTBUF_Pseudo_Loads <"tbuffer_load_format_xy", VReg_64, 2>; defm TBUFFER_LOAD_FORMAT_XYZ : MTBUF_Pseudo_Loads <"tbuffer_load_format_xyz", VReg_96, 3>; defm TBUFFER_LOAD_FORMAT_XYZW : MTBUF_Pseudo_Loads <"tbuffer_load_format_xyzw", VReg_128, 4>; defm TBUFFER_STORE_FORMAT_X : MTBUF_Pseudo_Stores <"tbuffer_store_format_x", VGPR_32, 1>; defm TBUFFER_STORE_FORMAT_XY : MTBUF_Pseudo_Stores <"tbuffer_store_format_xy", VReg_64, 2>; defm TBUFFER_STORE_FORMAT_XYZ : MTBUF_Pseudo_Stores <"tbuffer_store_format_xyz", VReg_96, 3>; defm TBUFFER_STORE_FORMAT_XYZW : MTBUF_Pseudo_Stores <"tbuffer_store_format_xyzw", VReg_128, 4>; let SubtargetPredicate = HasUnpackedD16VMem, D16Buf = 1 in { defm TBUFFER_LOAD_FORMAT_D16_X_gfx80 : MTBUF_Pseudo_Loads <"tbuffer_load_format_d16_x", VGPR_32, 1>; defm TBUFFER_LOAD_FORMAT_D16_XY_gfx80 : MTBUF_Pseudo_Loads <"tbuffer_load_format_d16_xy", VReg_64, 2>; defm TBUFFER_LOAD_FORMAT_D16_XYZ_gfx80 : MTBUF_Pseudo_Loads <"tbuffer_load_format_d16_xyz", VReg_96, 3>; defm TBUFFER_LOAD_FORMAT_D16_XYZW_gfx80 : MTBUF_Pseudo_Loads <"tbuffer_load_format_d16_xyzw", VReg_128, 4>; defm TBUFFER_STORE_FORMAT_D16_X_gfx80 : MTBUF_Pseudo_Stores <"tbuffer_store_format_d16_x", VGPR_32, 1>; defm TBUFFER_STORE_FORMAT_D16_XY_gfx80 : MTBUF_Pseudo_Stores <"tbuffer_store_format_d16_xy", VReg_64, 2>; defm TBUFFER_STORE_FORMAT_D16_XYZ_gfx80 : MTBUF_Pseudo_Stores <"tbuffer_store_format_d16_xyz", VReg_96, 3>; defm TBUFFER_STORE_FORMAT_D16_XYZW_gfx80 : MTBUF_Pseudo_Stores <"tbuffer_store_format_d16_xyzw", VReg_128, 4>; } // End HasUnpackedD16VMem. let SubtargetPredicate = HasPackedD16VMem, D16Buf = 1 in { defm TBUFFER_LOAD_FORMAT_D16_X : MTBUF_Pseudo_Loads <"tbuffer_load_format_d16_x", VGPR_32, 1>; defm TBUFFER_LOAD_FORMAT_D16_XY : MTBUF_Pseudo_Loads <"tbuffer_load_format_d16_xy", VGPR_32, 2>; defm TBUFFER_LOAD_FORMAT_D16_XYZ : MTBUF_Pseudo_Loads <"tbuffer_load_format_d16_xyz", VReg_64, 3>; defm TBUFFER_LOAD_FORMAT_D16_XYZW : MTBUF_Pseudo_Loads <"tbuffer_load_format_d16_xyzw", VReg_64, 4>; defm TBUFFER_STORE_FORMAT_D16_X : MTBUF_Pseudo_Stores <"tbuffer_store_format_d16_x", VGPR_32, 1>; defm TBUFFER_STORE_FORMAT_D16_XY : MTBUF_Pseudo_Stores <"tbuffer_store_format_d16_xy", VGPR_32, 2>; defm TBUFFER_STORE_FORMAT_D16_XYZ : MTBUF_Pseudo_Stores <"tbuffer_store_format_d16_xyz", VReg_64, 3>; defm TBUFFER_STORE_FORMAT_D16_XYZW : MTBUF_Pseudo_Stores <"tbuffer_store_format_d16_xyzw", VReg_64, 4>; } // End HasPackedD16VMem. let SubtargetPredicate = isGFX7Plus in { //===----------------------------------------------------------------------===// // Instruction definitions for CI and newer. //===----------------------------------------------------------------------===// def BUFFER_WBINVL1_VOL : MUBUF_Invalidate <"buffer_wbinvl1_vol", int_amdgcn_buffer_wbinvl1_vol>; } // End let SubtargetPredicate = isGFX7Plus let SubtargetPredicate = isGFX10Plus in { def BUFFER_GL0_INV : MUBUF_Invalidate<"buffer_gl0_inv">; def BUFFER_GL1_INV : MUBUF_Invalidate<"buffer_gl1_inv">; } // End SubtargetPredicate = isGFX10Plus //===----------------------------------------------------------------------===// // MUBUF Patterns //===----------------------------------------------------------------------===// //===----------------------------------------------------------------------===// // buffer_load/store_format patterns //===----------------------------------------------------------------------===// multiclass MUBUF_LoadIntrinsicPat { defvar st = !if(!eq(!cast(memoryVt), !cast(vt)), name, mubuf_intrinsic_load); def : GCNPat< (vt (st v4i32:$rsrc, 0, 0, i32:$soffset, timm:$offset, timm:$auxiliary, 0)), (!cast(opcode # _OFFSET) SReg_128:$rsrc, SCSrc_b32:$soffset, (as_i16timm $offset), (extract_glc $auxiliary), (extract_slc $auxiliary), 0, (extract_dlc $auxiliary), (extract_swz $auxiliary)) >; def : GCNPat< (vt (st v4i32:$rsrc, 0, i32:$voffset, i32:$soffset, timm:$offset, timm:$auxiliary, 0)), (!cast(opcode # _OFFEN) VGPR_32:$voffset, SReg_128:$rsrc, SCSrc_b32:$soffset, (as_i16timm $offset), (extract_glc $auxiliary), (extract_slc $auxiliary), 0, (extract_dlc $auxiliary), (extract_swz $auxiliary)) >; def : GCNPat< (vt (st v4i32:$rsrc, i32:$vindex, 0, i32:$soffset, timm:$offset, timm:$auxiliary, timm)), (!cast(opcode # _IDXEN) VGPR_32:$vindex, SReg_128:$rsrc, SCSrc_b32:$soffset, (as_i16timm $offset), (extract_glc $auxiliary), (extract_slc $auxiliary), 0, (extract_dlc $auxiliary), (extract_swz $auxiliary)) >; def : GCNPat< (vt (st v4i32:$rsrc, i32:$vindex, i32:$voffset, i32:$soffset, timm:$offset, timm:$auxiliary, timm)), (!cast(opcode # _BOTHEN) (REG_SEQUENCE VReg_64, VGPR_32:$vindex, sub0, VGPR_32:$voffset, sub1), SReg_128:$rsrc, SCSrc_b32:$soffset, (as_i16timm $offset), (extract_glc $auxiliary), (extract_slc $auxiliary), 0, (extract_dlc $auxiliary), (extract_swz $auxiliary)) >; } defm : MUBUF_LoadIntrinsicPat; defm : MUBUF_LoadIntrinsicPat; defm : MUBUF_LoadIntrinsicPat; defm : MUBUF_LoadIntrinsicPat; defm : MUBUF_LoadIntrinsicPat; defm : MUBUF_LoadIntrinsicPat; defm : MUBUF_LoadIntrinsicPat; defm : MUBUF_LoadIntrinsicPat; let SubtargetPredicate = HasUnpackedD16VMem in { defm : MUBUF_LoadIntrinsicPat; defm : MUBUF_LoadIntrinsicPat; defm : MUBUF_LoadIntrinsicPat; defm : MUBUF_LoadIntrinsicPat; defm : MUBUF_LoadIntrinsicPat; defm : MUBUF_LoadIntrinsicPat; } // End HasUnpackedD16VMem. let SubtargetPredicate = HasPackedD16VMem in { defm : MUBUF_LoadIntrinsicPat; defm : MUBUF_LoadIntrinsicPat; defm : MUBUF_LoadIntrinsicPat; defm : MUBUF_LoadIntrinsicPat; defm : MUBUF_LoadIntrinsicPat; defm : MUBUF_LoadIntrinsicPat; defm : MUBUF_LoadIntrinsicPat; defm : MUBUF_LoadIntrinsicPat; defm : MUBUF_LoadIntrinsicPat; } // End HasPackedD16VMem. defm : MUBUF_LoadIntrinsicPat; defm : MUBUF_LoadIntrinsicPat; defm : MUBUF_LoadIntrinsicPat; defm : MUBUF_LoadIntrinsicPat; defm : MUBUF_LoadIntrinsicPat; defm : MUBUF_LoadIntrinsicPat; defm : MUBUF_LoadIntrinsicPat; defm : MUBUF_LoadIntrinsicPat; defm : MUBUF_LoadIntrinsicPat; defm : MUBUF_LoadIntrinsicPat; defm : MUBUF_LoadIntrinsicPat; defm : MUBUF_LoadIntrinsicPat; defm : MUBUF_LoadIntrinsicPat; defm : MUBUF_LoadIntrinsicPat; defm : MUBUF_LoadIntrinsicPat; defm : MUBUF_LoadIntrinsicPat; multiclass MUBUF_StoreIntrinsicPat { defvar st = !if(!eq(!cast(memoryVt), !cast(vt)), name, mubuf_intrinsic_store); def : GCNPat< (st vt:$vdata, v4i32:$rsrc, 0, 0, i32:$soffset, timm:$offset, timm:$auxiliary, 0), (!cast(opcode # _OFFSET_exact) getVregSrcForVT.ret:$vdata, SReg_128:$rsrc, SCSrc_b32:$soffset, (as_i16timm $offset), (extract_glc $auxiliary), (extract_slc $auxiliary), 0, (extract_dlc $auxiliary), (extract_swz $auxiliary)) >; def : GCNPat< (st vt:$vdata, v4i32:$rsrc, 0, i32:$voffset, i32:$soffset, timm:$offset, timm:$auxiliary, 0), (!cast(opcode # _OFFEN_exact) getVregSrcForVT.ret:$vdata, VGPR_32:$voffset, SReg_128:$rsrc, SCSrc_b32:$soffset, (as_i16timm $offset), (extract_glc $auxiliary), (extract_slc $auxiliary), 0, (extract_dlc $auxiliary), (extract_swz $auxiliary)) >; def : GCNPat< (st vt:$vdata, v4i32:$rsrc, i32:$vindex, 0, i32:$soffset, timm:$offset, timm:$auxiliary, timm), (!cast(opcode # _IDXEN_exact) getVregSrcForVT.ret:$vdata, VGPR_32:$vindex, SReg_128:$rsrc, SCSrc_b32:$soffset, (as_i16timm $offset), (extract_glc $auxiliary), (extract_slc $auxiliary), 0, (extract_dlc $auxiliary), (extract_swz $auxiliary)) >; def : GCNPat< (st vt:$vdata, v4i32:$rsrc, i32:$vindex, i32:$voffset, i32:$soffset, timm:$offset, timm:$auxiliary, timm), (!cast(opcode # _BOTHEN_exact) getVregSrcForVT.ret:$vdata, (REG_SEQUENCE VReg_64, VGPR_32:$vindex, sub0, VGPR_32:$voffset, sub1), SReg_128:$rsrc, SCSrc_b32:$soffset, (as_i16timm $offset), (extract_glc $auxiliary), (extract_slc $auxiliary), 0, (extract_dlc $auxiliary), (extract_swz $auxiliary)) >; } defm : MUBUF_StoreIntrinsicPat; defm : MUBUF_StoreIntrinsicPat; defm : MUBUF_StoreIntrinsicPat; defm : MUBUF_StoreIntrinsicPat; defm : MUBUF_StoreIntrinsicPat; defm : MUBUF_StoreIntrinsicPat; defm : MUBUF_StoreIntrinsicPat; defm : MUBUF_StoreIntrinsicPat; let SubtargetPredicate = HasUnpackedD16VMem in { defm : MUBUF_StoreIntrinsicPat; defm : MUBUF_StoreIntrinsicPat; defm : MUBUF_StoreIntrinsicPat; defm : MUBUF_StoreIntrinsicPat; defm : MUBUF_StoreIntrinsicPat; defm : MUBUF_StoreIntrinsicPat; } // End HasUnpackedD16VMem. let SubtargetPredicate = HasPackedD16VMem in { defm : MUBUF_StoreIntrinsicPat; defm : MUBUF_StoreIntrinsicPat; defm : MUBUF_StoreIntrinsicPat; defm : MUBUF_StoreIntrinsicPat; defm : MUBUF_StoreIntrinsicPat; defm : MUBUF_StoreIntrinsicPat; defm : MUBUF_StoreIntrinsicPat; defm : MUBUF_StoreIntrinsicPat; defm : MUBUF_StoreIntrinsicPat; } // End HasPackedD16VMem. defm : MUBUF_StoreIntrinsicPat; defm : MUBUF_StoreIntrinsicPat; defm : MUBUF_StoreIntrinsicPat; defm : MUBUF_StoreIntrinsicPat; defm : MUBUF_StoreIntrinsicPat; defm : MUBUF_StoreIntrinsicPat; defm : MUBUF_StoreIntrinsicPat; defm : MUBUF_StoreIntrinsicPat; defm : MUBUF_StoreIntrinsicPat; defm : MUBUF_StoreIntrinsicPat; defm : MUBUF_StoreIntrinsicPat; defm : MUBUF_StoreIntrinsicPat; defm : MUBUF_StoreIntrinsicPat; defm : MUBUF_StoreIntrinsicPat; //===----------------------------------------------------------------------===// // buffer_atomic patterns //===----------------------------------------------------------------------===// multiclass BufferAtomicPatterns { def : GCNPat< (vt (name vt:$vdata_in, v4i32:$rsrc, 0, 0, i32:$soffset, timm:$offset, timm:$cachepolicy, 0)), (!cast(opcode # _OFFSET_RTN) getVregSrcForVT.ret:$vdata_in, SReg_128:$rsrc, SCSrc_b32:$soffset, (as_i16timm $offset), (extract_slc $cachepolicy)) >; def : GCNPat< (vt (name vt:$vdata_in, v4i32:$rsrc, i32:$vindex, 0, i32:$soffset, timm:$offset, timm:$cachepolicy, timm)), (!cast(opcode # _IDXEN_RTN) getVregSrcForVT.ret:$vdata_in, VGPR_32:$vindex, SReg_128:$rsrc, SCSrc_b32:$soffset, (as_i16timm $offset), (extract_slc $cachepolicy)) >; def : GCNPat< (vt (name vt:$vdata_in, v4i32:$rsrc, 0, i32:$voffset, i32:$soffset, timm:$offset, timm:$cachepolicy, 0)), (!cast(opcode # _OFFEN_RTN) getVregSrcForVT.ret:$vdata_in, VGPR_32:$voffset, SReg_128:$rsrc, SCSrc_b32:$soffset, (as_i16timm $offset), (extract_slc $cachepolicy)) >; def : GCNPat< (vt (name vt:$vdata_in, v4i32:$rsrc, i32:$vindex, i32:$voffset, i32:$soffset, timm:$offset, timm:$cachepolicy, timm)), (!cast(opcode # _BOTHEN_RTN) getVregSrcForVT.ret:$vdata_in, (REG_SEQUENCE VReg_64, VGPR_32:$vindex, sub0, VGPR_32:$voffset, sub1), SReg_128:$rsrc, SCSrc_b32:$soffset, (as_i16timm $offset), (extract_slc $cachepolicy)) >; } defm : BufferAtomicPatterns; defm : BufferAtomicPatterns; defm : BufferAtomicPatterns; defm : BufferAtomicPatterns; defm : BufferAtomicPatterns; defm : BufferAtomicPatterns; defm : BufferAtomicPatterns; defm : BufferAtomicPatterns; defm : BufferAtomicPatterns; defm : BufferAtomicPatterns; defm : BufferAtomicPatterns; defm : BufferAtomicPatterns; defm : BufferAtomicPatterns; defm : BufferAtomicPatterns; defm : BufferAtomicPatterns; defm : BufferAtomicPatterns; defm : BufferAtomicPatterns; defm : BufferAtomicPatterns; defm : BufferAtomicPatterns; defm : BufferAtomicPatterns; defm : BufferAtomicPatterns; defm : BufferAtomicPatterns; defm : BufferAtomicPatterns; defm : BufferAtomicPatterns; defm : BufferAtomicPatterns; defm : BufferAtomicPatterns; class NoUseBufferAtomic : PatFrag < (ops node:$src0, node:$src1, node:$src2, node:$src3, node:$src4, node:$src5, node:$src6, node:$src7), (vt (Op $src0, $src1, $src2, $src3, $src4, $src5, $src6, $src7)), [{ return SDValue(N, 0).use_empty(); }]> { let GISelPredicateCode = [{ return MRI.use_nodbg_empty(MI.getOperand(0).getReg()); }]; } multiclass BufferAtomicPatterns_NO_RTN { def : GCNPat< (NoUseBufferAtomic vt:$vdata_in, v4i32:$rsrc, 0, 0, i32:$soffset, timm:$offset, timm:$cachepolicy, 0), (!cast(opcode # _OFFSET) getVregSrcForVT.ret:$vdata_in, SReg_128:$rsrc, SCSrc_b32:$soffset, (as_i16timm $offset), (extract_slc $cachepolicy)) >; def : GCNPat< (NoUseBufferAtomic vt:$vdata_in, v4i32:$rsrc, i32:$vindex, 0, i32:$soffset, timm:$offset, timm:$cachepolicy, timm), (!cast(opcode # _IDXEN) getVregSrcForVT.ret:$vdata_in, VGPR_32:$vindex, SReg_128:$rsrc, SCSrc_b32:$soffset, (as_i16timm $offset), (extract_slc $cachepolicy)) >; def : GCNPat< (NoUseBufferAtomic vt:$vdata_in, v4i32:$rsrc, 0, i32:$voffset, i32:$soffset, timm:$offset, timm:$cachepolicy, 0), (!cast(opcode # _OFFEN) getVregSrcForVT.ret:$vdata_in, VGPR_32:$voffset, SReg_128:$rsrc, SCSrc_b32:$soffset, (as_i16timm $offset), (extract_slc $cachepolicy)) >; def : GCNPat< (NoUseBufferAtomic vt:$vdata_in, v4i32:$rsrc, i32:$vindex, i32:$voffset, i32:$soffset, timm:$offset, timm:$cachepolicy, timm), (!cast(opcode # _BOTHEN) getVregSrcForVT.ret:$vdata_in, (REG_SEQUENCE VReg_64, VGPR_32:$vindex, sub0, VGPR_32:$voffset, sub1), SReg_128:$rsrc, SCSrc_b32:$soffset, (as_i16timm $offset), (extract_slc $cachepolicy)) >; } let SubtargetPredicate = HasAtomicFaddInsts in { defm : BufferAtomicPatterns_NO_RTN; defm : BufferAtomicPatterns_NO_RTN; } def : GCNPat< (SIbuffer_atomic_cmpswap i32:$data, i32:$cmp, v4i32:$rsrc, 0, 0, i32:$soffset, timm:$offset, timm:$cachepolicy, 0), (EXTRACT_SUBREG (BUFFER_ATOMIC_CMPSWAP_OFFSET_RTN (REG_SEQUENCE VReg_64, VGPR_32:$data, sub0, VGPR_32:$cmp, sub1), SReg_128:$rsrc, SCSrc_b32:$soffset, (as_i16timm $offset), (extract_slc $cachepolicy)), sub0) >; def : GCNPat< (SIbuffer_atomic_cmpswap i32:$data, i32:$cmp, v4i32:$rsrc, i32:$vindex, 0, i32:$soffset, timm:$offset, timm:$cachepolicy, timm), (EXTRACT_SUBREG (BUFFER_ATOMIC_CMPSWAP_IDXEN_RTN (REG_SEQUENCE VReg_64, VGPR_32:$data, sub0, VGPR_32:$cmp, sub1), VGPR_32:$vindex, SReg_128:$rsrc, SCSrc_b32:$soffset, (as_i16timm $offset), (extract_slc $cachepolicy)), sub0) >; def : GCNPat< (SIbuffer_atomic_cmpswap i32:$data, i32:$cmp, v4i32:$rsrc, 0, i32:$voffset, i32:$soffset, timm:$offset, timm:$cachepolicy, 0), (EXTRACT_SUBREG (BUFFER_ATOMIC_CMPSWAP_OFFEN_RTN (REG_SEQUENCE VReg_64, VGPR_32:$data, sub0, VGPR_32:$cmp, sub1), VGPR_32:$voffset, SReg_128:$rsrc, SCSrc_b32:$soffset, (as_i16timm $offset), (extract_slc $cachepolicy)), sub0) >; def : GCNPat< (SIbuffer_atomic_cmpswap i32:$data, i32:$cmp, v4i32:$rsrc, i32:$vindex, i32:$voffset, i32:$soffset, timm:$offset, timm:$cachepolicy, timm), (EXTRACT_SUBREG (BUFFER_ATOMIC_CMPSWAP_BOTHEN_RTN (REG_SEQUENCE VReg_64, VGPR_32:$data, sub0, VGPR_32:$cmp, sub1), (REG_SEQUENCE VReg_64, VGPR_32:$vindex, sub0, VGPR_32:$voffset, sub1), SReg_128:$rsrc, SCSrc_b32:$soffset, (as_i16timm $offset), (extract_slc $cachepolicy)), sub0) >; class MUBUFLoad_PatternADDR64 : GCNPat < (vt (constant_ld (MUBUFAddr64 v4i32:$srsrc, i64:$vaddr, i32:$soffset, i16:$offset, i1:$glc, i1:$slc, i1:$tfe, i1:$dlc, i1:$swz))), (Instr_ADDR64 $vaddr, $srsrc, $soffset, $offset, $glc, $slc, $tfe, $dlc, $swz) >; multiclass MUBUFLoad_Atomic_Pattern { def : GCNPat < (vt (atomic_ld (MUBUFAddr64 v4i32:$srsrc, i64:$vaddr, i32:$soffset, i16:$offset, i1:$slc))), (Instr_ADDR64 $vaddr, $srsrc, $soffset, $offset, 0, $slc, 0, 0, 0) >; def : GCNPat < (vt (atomic_ld (MUBUFOffsetNoGLC v4i32:$rsrc, i32:$soffset, i16:$offset))), (Instr_OFFSET $rsrc, $soffset, (as_i16imm $offset), 0, 0, 0, 0, 0) >; } let SubtargetPredicate = isGFX6GFX7 in { def : MUBUFLoad_PatternADDR64 ; def : MUBUFLoad_PatternADDR64 ; def : MUBUFLoad_PatternADDR64 ; def : MUBUFLoad_PatternADDR64 ; def : MUBUFLoad_PatternADDR64 ; def : MUBUFLoad_PatternADDR64 ; defm : MUBUFLoad_Atomic_Pattern ; defm : MUBUFLoad_Atomic_Pattern ; } // End SubtargetPredicate = isGFX6GFX7 multiclass MUBUFLoad_Pattern { def : GCNPat < (vt (ld (MUBUFOffset v4i32:$srsrc, i32:$soffset, i16:$offset, i1:$glc, i1:$slc, i1:$tfe, i1:$dlc, i1:$swz))), (Instr_OFFSET $srsrc, $soffset, $offset, $glc, $slc, $tfe, $dlc, $swz) >; } let OtherPredicates = [Has16BitInsts] in { defm : MUBUFLoad_Pattern ; defm : MUBUFLoad_Pattern ; defm : MUBUFLoad_Pattern ; defm : MUBUFLoad_Pattern ; defm : MUBUFLoad_Pattern ; defm : MUBUFLoad_Pattern ; defm : MUBUFLoad_Pattern ; } // End OtherPredicates = [Has16BitInsts] multiclass MUBUFScratchLoadPat { def : GCNPat < (vt (ld (MUBUFScratchOffen v4i32:$srsrc, i32:$vaddr, i32:$soffset, u16imm:$offset))), (InstrOffen $vaddr, $srsrc, $soffset, $offset, 0, 0, 0, 0, 0) >; def : GCNPat < (vt (ld (MUBUFScratchOffset v4i32:$srsrc, i32:$soffset, u16imm:$offset))), (InstrOffset $srsrc, $soffset, $offset, 0, 0, 0, 0, 0) >; } // XXX - Is it possible to have a complex pattern in a PatFrag? multiclass MUBUFScratchLoadPat_D16 { def : GCNPat < (ld_frag (MUBUFScratchOffen v4i32:$srsrc, i32:$vaddr, i32:$soffset, u16imm:$offset), vt:$in), (InstrOffen $vaddr, $srsrc, $soffset, $offset, 0, 0, 0, 0, 0, $in) >; def : GCNPat < (ld_frag (MUBUFScratchOffset v4i32:$srsrc, i32:$soffset, u16imm:$offset), vt:$in), (InstrOffset $srsrc, $soffset, $offset, 0, 0, 0, 0, 0, $in) >; } defm : MUBUFScratchLoadPat ; defm : MUBUFScratchLoadPat ; defm : MUBUFScratchLoadPat ; defm : MUBUFScratchLoadPat ; defm : MUBUFScratchLoadPat ; defm : MUBUFScratchLoadPat ; defm : MUBUFScratchLoadPat ; defm : MUBUFScratchLoadPat ; defm : MUBUFScratchLoadPat ; defm : MUBUFScratchLoadPat ; foreach vt = Reg32Types.types in { defm : MUBUFScratchLoadPat ; } defm : MUBUFScratchLoadPat ; defm : MUBUFScratchLoadPat ; defm : MUBUFScratchLoadPat ; let OtherPredicates = [D16PreservesUnusedBits] in { defm : MUBUFScratchLoadPat_D16; defm : MUBUFScratchLoadPat_D16; defm : MUBUFScratchLoadPat_D16; defm : MUBUFScratchLoadPat_D16; defm : MUBUFScratchLoadPat_D16; defm : MUBUFScratchLoadPat_D16; defm : MUBUFScratchLoadPat_D16; defm : MUBUFScratchLoadPat_D16; defm : MUBUFScratchLoadPat_D16; defm : MUBUFScratchLoadPat_D16; defm : MUBUFScratchLoadPat_D16; defm : MUBUFScratchLoadPat_D16; } multiclass MUBUFStore_Atomic_Pattern { // Store follows atomic op convention so address is first def : GCNPat < (atomic_st (MUBUFAddr64 v4i32:$srsrc, i64:$vaddr, i32:$soffset, i16:$offset, i1:$slc), vt:$val), (Instr_ADDR64 $val, $vaddr, $srsrc, $soffset, $offset, 0, $slc, 0, 0, 0) >; def : GCNPat < (atomic_st (MUBUFOffsetNoGLC v4i32:$rsrc, i32:$soffset, i16:$offset), vt:$val), (Instr_OFFSET $val, $rsrc, $soffset, (as_i16imm $offset), 0, 0, 0, 0, 0) >; } let SubtargetPredicate = isGFX6GFX7 in { defm : MUBUFStore_Atomic_Pattern ; defm : MUBUFStore_Atomic_Pattern ; } // End Predicates = isGFX6GFX7 multiclass MUBUFStore_Pattern { def : GCNPat < (st vt:$vdata, (MUBUFOffset v4i32:$srsrc, i32:$soffset, i16:$offset, i1:$glc, i1:$slc, i1:$tfe, i1:$dlc, i1:$swz)), (Instr_OFFSET $vdata, $srsrc, $soffset, $offset, $glc, $slc, $tfe, $dlc, $swz) >; } defm : MUBUFStore_Pattern ; defm : MUBUFStore_Pattern ; multiclass MUBUFScratchStorePat { def : GCNPat < (st vt:$value, (MUBUFScratchOffen v4i32:$srsrc, i32:$vaddr, i32:$soffset, u16imm:$offset)), (InstrOffen rc:$value, $vaddr, $srsrc, $soffset, $offset, 0, 0, 0, 0, 0) >; def : GCNPat < (st vt:$value, (MUBUFScratchOffset v4i32:$srsrc, i32:$soffset, u16imm:$offset)), (InstrOffset rc:$value, $srsrc, $soffset, $offset, 0, 0, 0, 0, 0) >; } defm : MUBUFScratchStorePat ; defm : MUBUFScratchStorePat ; defm : MUBUFScratchStorePat ; defm : MUBUFScratchStorePat ; foreach vt = Reg32Types.types in { defm : MUBUFScratchStorePat ; } defm : MUBUFScratchStorePat ; defm : MUBUFScratchStorePat ; defm : MUBUFScratchStorePat ; let OtherPredicates = [D16PreservesUnusedBits] in { // Hiding the extract high pattern in the PatFrag seems to not // automatically increase the complexity. let AddedComplexity = 1 in { defm : MUBUFScratchStorePat ; defm : MUBUFScratchStorePat ; } } //===----------------------------------------------------------------------===// // MTBUF Patterns //===----------------------------------------------------------------------===// //===----------------------------------------------------------------------===// // tbuffer_load/store_format patterns //===----------------------------------------------------------------------===// multiclass MTBUF_LoadIntrinsicPat { defvar st = !if(!eq(!cast(memoryVt), !cast(vt)), name, mtbuf_intrinsic_load); def : GCNPat< (vt (st v4i32:$rsrc, 0, 0, i32:$soffset, timm:$offset, timm:$format, timm:$auxiliary, 0)), (!cast(opcode # _OFFSET) SReg_128:$rsrc, SCSrc_b32:$soffset, (as_i16timm $offset), (as_i8timm $format), (extract_glc $auxiliary), (extract_slc $auxiliary), 0, (extract_dlc $auxiliary), (extract_swz $auxiliary)) >; def : GCNPat< (vt (st v4i32:$rsrc, i32:$vindex, 0, i32:$soffset, timm:$offset, timm:$format, timm:$auxiliary, timm)), (!cast(opcode # _IDXEN) VGPR_32:$vindex, SReg_128:$rsrc, SCSrc_b32:$soffset, (as_i16timm $offset), (as_i8timm $format), (extract_glc $auxiliary), (extract_slc $auxiliary), 0, (extract_dlc $auxiliary), (extract_swz $auxiliary)) >; def : GCNPat< (vt (st v4i32:$rsrc, 0, i32:$voffset, i32:$soffset, timm:$offset, timm:$format, timm:$auxiliary, 0)), (!cast(opcode # _OFFEN) VGPR_32:$voffset, SReg_128:$rsrc, SCSrc_b32:$soffset, (as_i16timm $offset), (as_i8timm $format), (extract_glc $auxiliary), (extract_slc $auxiliary), 0, (extract_dlc $auxiliary), (extract_swz $auxiliary)) >; def : GCNPat< (vt (st v4i32:$rsrc, i32:$vindex, i32:$voffset, i32:$soffset, timm:$offset, timm:$format, timm:$auxiliary, timm)), (!cast(opcode # _BOTHEN) (REG_SEQUENCE VReg_64, VGPR_32:$vindex, sub0, VGPR_32:$voffset, sub1), SReg_128:$rsrc, SCSrc_b32:$soffset, (as_i16timm $offset), (as_i8timm $format), (extract_glc $auxiliary), (extract_slc $auxiliary), 0, (extract_dlc $auxiliary), (extract_swz $auxiliary)) >; } defm : MTBUF_LoadIntrinsicPat; defm : MTBUF_LoadIntrinsicPat; defm : MTBUF_LoadIntrinsicPat; defm : MTBUF_LoadIntrinsicPat; defm : MTBUF_LoadIntrinsicPat; defm : MTBUF_LoadIntrinsicPat; defm : MTBUF_LoadIntrinsicPat; defm : MTBUF_LoadIntrinsicPat; let SubtargetPredicate = HasUnpackedD16VMem in { defm : MTBUF_LoadIntrinsicPat; defm : MTBUF_LoadIntrinsicPat; defm : MTBUF_LoadIntrinsicPat; defm : MTBUF_LoadIntrinsicPat; defm : MTBUF_LoadIntrinsicPat; } // End HasUnpackedD16VMem. let SubtargetPredicate = HasPackedD16VMem in { defm : MTBUF_LoadIntrinsicPat; defm : MTBUF_LoadIntrinsicPat; defm : MTBUF_LoadIntrinsicPat; defm : MTBUF_LoadIntrinsicPat; defm : MTBUF_LoadIntrinsicPat; } // End HasPackedD16VMem. multiclass MTBUF_StoreIntrinsicPat { defvar st = !if(!eq(!cast(memoryVt), !cast(vt)), name, mtbuf_intrinsic_store); def : GCNPat< (st vt:$vdata, v4i32:$rsrc, 0, 0, i32:$soffset, timm:$offset, timm:$format, timm:$auxiliary, 0), (!cast(opcode # _OFFSET_exact) getVregSrcForVT.ret:$vdata, SReg_128:$rsrc, SCSrc_b32:$soffset, (as_i16timm $offset), (as_i8timm $format), (extract_glc $auxiliary), (extract_slc $auxiliary), 0, (extract_dlc $auxiliary), (extract_swz $auxiliary)) >; def : GCNPat< (st vt:$vdata, v4i32:$rsrc, i32:$vindex, 0, i32:$soffset, timm:$offset, timm:$format, timm:$auxiliary, timm), (!cast(opcode # _IDXEN_exact) getVregSrcForVT.ret:$vdata, VGPR_32:$vindex, SReg_128:$rsrc, SCSrc_b32:$soffset, (as_i16timm $offset), (as_i8timm $format), (extract_glc $auxiliary), (extract_slc $auxiliary), 0, (extract_dlc $auxiliary), (extract_swz $auxiliary)) >; def : GCNPat< (st vt:$vdata, v4i32:$rsrc, 0, i32:$voffset, i32:$soffset, timm:$offset, timm:$format, timm:$auxiliary, 0), (!cast(opcode # _OFFEN_exact) getVregSrcForVT.ret:$vdata, VGPR_32:$voffset, SReg_128:$rsrc, SCSrc_b32:$soffset, (as_i16timm $offset), (as_i8timm $format), (extract_glc $auxiliary), (extract_slc $auxiliary), 0, (extract_dlc $auxiliary), (extract_swz $auxiliary)) >; def : GCNPat< (st vt:$vdata, v4i32:$rsrc, i32:$vindex, i32:$voffset, i32:$soffset, timm:$offset, timm:$format, timm:$auxiliary, timm), (!cast(opcode # _BOTHEN_exact) getVregSrcForVT.ret:$vdata, (REG_SEQUENCE VReg_64, VGPR_32:$vindex, sub0, VGPR_32:$voffset, sub1), SReg_128:$rsrc, SCSrc_b32:$soffset, (as_i16timm $offset), (as_i8timm $format), (extract_glc $auxiliary), (extract_slc $auxiliary), 0, (extract_dlc $auxiliary), (extract_swz $auxiliary)) >; } defm : MTBUF_StoreIntrinsicPat; defm : MTBUF_StoreIntrinsicPat; defm : MTBUF_StoreIntrinsicPat; defm : MTBUF_StoreIntrinsicPat; defm : MTBUF_StoreIntrinsicPat; defm : MTBUF_StoreIntrinsicPat; defm : MTBUF_StoreIntrinsicPat; defm : MTBUF_StoreIntrinsicPat; let SubtargetPredicate = HasUnpackedD16VMem in { defm : MTBUF_StoreIntrinsicPat; defm : MTBUF_StoreIntrinsicPat; defm : MTBUF_StoreIntrinsicPat; defm : MTBUF_StoreIntrinsicPat; defm : MTBUF_StoreIntrinsicPat; } // End HasUnpackedD16VMem. let SubtargetPredicate = HasPackedD16VMem in { defm : MTBUF_StoreIntrinsicPat; defm : MTBUF_StoreIntrinsicPat; defm : MTBUF_StoreIntrinsicPat; defm : MTBUF_StoreIntrinsicPat; defm : MTBUF_StoreIntrinsicPat; } // End HasPackedD16VMem. //===----------------------------------------------------------------------===// // Target-specific instruction encodings. //===----------------------------------------------------------------------===// //===----------------------------------------------------------------------===// // Base ENC_MUBUF for GFX6, GFX7, GFX10. //===----------------------------------------------------------------------===// class Base_MUBUF_Real_gfx6_gfx7_gfx10 op, MUBUF_Pseudo ps, int ef> : MUBUF_Real, Enc64, SIMCInstr { let Inst{11-0} = !if(ps.has_offset, offset, ?); let Inst{12} = ps.offen; let Inst{13} = ps.idxen; let Inst{14} = !if(ps.has_glc, glc, ps.glc_value); let Inst{16} = ps.lds; let Inst{24-18} = op; let Inst{31-26} = 0x38; let Inst{39-32} = !if(ps.has_vaddr, vaddr, ?); let Inst{47-40} = !if(ps.has_vdata, vdata, ?); let Inst{52-48} = !if(ps.has_srsrc, srsrc{6-2}, ?); let Inst{54} = !if(ps.has_slc, slc, ?); let Inst{55} = !if(ps.has_tfe, tfe, ?); let Inst{63-56} = !if(ps.has_soffset, soffset, ?); } class MUBUF_Real_gfx10 op, MUBUF_Pseudo ps> : Base_MUBUF_Real_gfx6_gfx7_gfx10 { let Inst{15} = !if(ps.has_dlc, dlc, ps.dlc_value); let Inst{25} = op{7}; } class MUBUF_Real_gfx6_gfx7 op, MUBUF_Pseudo ps> : Base_MUBUF_Real_gfx6_gfx7_gfx10 { let Inst{15} = ps.addr64; } //===----------------------------------------------------------------------===// // MUBUF - GFX10. //===----------------------------------------------------------------------===// let AssemblerPredicate = isGFX10Plus, DecoderNamespace = "GFX10" in { multiclass MUBUF_Real_gfx10_with_name op, string opName, string asmName> { def _gfx10 : MUBUF_Real_gfx10(opName)> { MUBUF_Pseudo ps = !cast(opName); let AsmString = asmName # ps.AsmOperands; } } multiclass MUBUF_Real_AllAddr_gfx10 op> { def _BOTHEN_gfx10 : MUBUF_Real_gfx10(NAME#"_BOTHEN")>; def _IDXEN_gfx10 : MUBUF_Real_gfx10(NAME#"_IDXEN")>; def _OFFEN_gfx10 : MUBUF_Real_gfx10(NAME#"_OFFEN")>; def _OFFSET_gfx10 : MUBUF_Real_gfx10(NAME#"_OFFSET")>; } multiclass MUBUF_Real_AllAddr_Lds_gfx10 op> { def _OFFSET_gfx10 : MUBUF_Real_gfx10(NAME#"_OFFSET")>, MUBUFLdsTable<0, NAME # "_OFFSET_gfx10">; def _OFFEN_gfx10 : MUBUF_Real_gfx10(NAME#"_OFFEN")>, MUBUFLdsTable<0, NAME # "_OFFEN_gfx10">; def _IDXEN_gfx10 : MUBUF_Real_gfx10(NAME#"_IDXEN")>, MUBUFLdsTable<0, NAME # "_IDXEN_gfx10">; def _BOTHEN_gfx10 : MUBUF_Real_gfx10(NAME#"_BOTHEN")>, MUBUFLdsTable<0, NAME # "_BOTHEN_gfx10">; def _LDS_OFFSET_gfx10 : MUBUF_Real_gfx10(NAME#"_LDS_OFFSET")>, MUBUFLdsTable<1, NAME # "_OFFSET_gfx10">; def _LDS_OFFEN_gfx10 : MUBUF_Real_gfx10(NAME#"_LDS_OFFEN")>, MUBUFLdsTable<1, NAME # "_OFFEN_gfx10">; def _LDS_IDXEN_gfx10 : MUBUF_Real_gfx10(NAME#"_LDS_IDXEN")>, MUBUFLdsTable<1, NAME # "_IDXEN_gfx10">; def _LDS_BOTHEN_gfx10 : MUBUF_Real_gfx10(NAME#"_LDS_BOTHEN")>, MUBUFLdsTable<1, NAME # "_BOTHEN_gfx10">; } multiclass MUBUF_Real_Atomics_RTN_gfx10 op> { def _BOTHEN_RTN_gfx10 : MUBUF_Real_gfx10(NAME#"_BOTHEN_RTN")>; def _IDXEN_RTN_gfx10 : MUBUF_Real_gfx10(NAME#"_IDXEN_RTN")>; def _OFFEN_RTN_gfx10 : MUBUF_Real_gfx10(NAME#"_OFFEN_RTN")>; def _OFFSET_RTN_gfx10 : MUBUF_Real_gfx10(NAME#"_OFFSET_RTN")>; } multiclass MUBUF_Real_Atomics_gfx10 op> : MUBUF_Real_AllAddr_gfx10, MUBUF_Real_Atomics_RTN_gfx10; } // End AssemblerPredicate = isGFX10Plus, DecoderNamespace = "GFX10" defm BUFFER_STORE_BYTE_D16_HI : MUBUF_Real_AllAddr_gfx10<0x019>; defm BUFFER_STORE_SHORT_D16_HI : MUBUF_Real_AllAddr_gfx10<0x01b>; defm BUFFER_LOAD_UBYTE_D16 : MUBUF_Real_AllAddr_gfx10<0x020>; defm BUFFER_LOAD_UBYTE_D16_HI : MUBUF_Real_AllAddr_gfx10<0x021>; defm BUFFER_LOAD_SBYTE_D16 : MUBUF_Real_AllAddr_gfx10<0x022>; defm BUFFER_LOAD_SBYTE_D16_HI : MUBUF_Real_AllAddr_gfx10<0x023>; defm BUFFER_LOAD_SHORT_D16 : MUBUF_Real_AllAddr_gfx10<0x024>; defm BUFFER_LOAD_SHORT_D16_HI : MUBUF_Real_AllAddr_gfx10<0x025>; // FIXME-GFX10: Add following instructions: //defm BUFFER_LOAD_FORMAT_D16_HI_X : MUBUF_Real_AllAddr_gfx10<0x026>; //defm BUFFER_STORE_FORMAT_D16_HI_X : MUBUF_Real_AllAddr_gfx10<0x027>; defm BUFFER_LOAD_FORMAT_D16_X : MUBUF_Real_AllAddr_gfx10<0x080>; defm BUFFER_LOAD_FORMAT_D16_XY : MUBUF_Real_AllAddr_gfx10<0x081>; defm BUFFER_LOAD_FORMAT_D16_XYZ : MUBUF_Real_AllAddr_gfx10<0x082>; defm BUFFER_LOAD_FORMAT_D16_XYZW : MUBUF_Real_AllAddr_gfx10<0x083>; defm BUFFER_STORE_FORMAT_D16_X : MUBUF_Real_AllAddr_gfx10<0x084>; defm BUFFER_STORE_FORMAT_D16_XY : MUBUF_Real_AllAddr_gfx10<0x085>; defm BUFFER_STORE_FORMAT_D16_XYZ : MUBUF_Real_AllAddr_gfx10<0x086>; defm BUFFER_STORE_FORMAT_D16_XYZW : MUBUF_Real_AllAddr_gfx10<0x087>; def BUFFER_GL0_INV_gfx10 : MUBUF_Real_gfx10<0x071, BUFFER_GL0_INV>; def BUFFER_GL1_INV_gfx10 : MUBUF_Real_gfx10<0x072, BUFFER_GL1_INV>; //===----------------------------------------------------------------------===// // MUBUF - GFX6, GFX7, GFX10. //===----------------------------------------------------------------------===// let AssemblerPredicate = isGFX6, DecoderNamespace = "GFX6" in { multiclass MUBUF_Real_gfx6 op> { def _gfx6 : MUBUF_Real_gfx6_gfx7(NAME)>; } } // End AssemblerPredicate = isGFX6, DecoderNamespace = "GFX6" let AssemblerPredicate = isGFX7Only, DecoderNamespace = "GFX7" in { multiclass MUBUF_Real_gfx7 op> { def _gfx7 : MUBUF_Real_gfx6_gfx7(NAME)>; } } // End AssemblerPredicate = isGFX7Only, DecoderNamespace = "GFX7" let AssemblerPredicate = isGFX6GFX7, DecoderNamespace = "GFX6GFX7" in { multiclass MUBUF_Real_AllAddr_gfx6_gfx7 op> { def _ADDR64_gfx6_gfx7 : MUBUF_Real_gfx6_gfx7(NAME#"_ADDR64")>; def _BOTHEN_gfx6_gfx7 : MUBUF_Real_gfx6_gfx7(NAME#"_BOTHEN")>; def _IDXEN_gfx6_gfx7 : MUBUF_Real_gfx6_gfx7(NAME#"_IDXEN")>; def _OFFEN_gfx6_gfx7 : MUBUF_Real_gfx6_gfx7(NAME#"_OFFEN")>; def _OFFSET_gfx6_gfx7 : MUBUF_Real_gfx6_gfx7(NAME#"_OFFSET")>; } multiclass MUBUF_Real_AllAddr_Lds_gfx6_gfx7 op> { def _OFFSET_gfx6_gfx7 : MUBUF_Real_gfx6_gfx7(NAME#"_OFFSET")>, MUBUFLdsTable<0, NAME # "_OFFSET_gfx6_gfx7">; def _ADDR64_gfx6_gfx7 : MUBUF_Real_gfx6_gfx7(NAME#"_ADDR64")>, MUBUFLdsTable<0, NAME # "_ADDR64_gfx6_gfx7">; def _OFFEN_gfx6_gfx7 : MUBUF_Real_gfx6_gfx7(NAME#"_OFFEN")>, MUBUFLdsTable<0, NAME # "_OFFEN_gfx6_gfx7">; def _IDXEN_gfx6_gfx7 : MUBUF_Real_gfx6_gfx7(NAME#"_IDXEN")>, MUBUFLdsTable<0, NAME # "_IDXEN_gfx6_gfx7">; def _BOTHEN_gfx6_gfx7 : MUBUF_Real_gfx6_gfx7(NAME#"_BOTHEN")>, MUBUFLdsTable<0, NAME # "_BOTHEN_gfx6_gfx7">; def _LDS_OFFSET_gfx6_gfx7 : MUBUF_Real_gfx6_gfx7(NAME#"_LDS_OFFSET")>, MUBUFLdsTable<1, NAME # "_OFFSET_gfx6_gfx7">; def _LDS_ADDR64_gfx6_gfx7 : MUBUF_Real_gfx6_gfx7(NAME#"_LDS_ADDR64")>, MUBUFLdsTable<1, NAME # "_ADDR64_gfx6_gfx7">; def _LDS_OFFEN_gfx6_gfx7 : MUBUF_Real_gfx6_gfx7(NAME#"_LDS_OFFEN")>, MUBUFLdsTable<1, NAME # "_OFFEN_gfx6_gfx7">; def _LDS_IDXEN_gfx6_gfx7 : MUBUF_Real_gfx6_gfx7(NAME#"_LDS_IDXEN")>, MUBUFLdsTable<1, NAME # "_IDXEN_gfx6_gfx7">; def _LDS_BOTHEN_gfx6_gfx7 : MUBUF_Real_gfx6_gfx7(NAME#"_LDS_BOTHEN")>, MUBUFLdsTable<1, NAME # "_BOTHEN_gfx6_gfx7">; } multiclass MUBUF_Real_Atomics_gfx6_gfx7 op> : MUBUF_Real_AllAddr_gfx6_gfx7 { def _ADDR64_RTN_gfx6_gfx7 : MUBUF_Real_gfx6_gfx7(NAME#"_ADDR64_RTN")>; def _BOTHEN_RTN_gfx6_gfx7 : MUBUF_Real_gfx6_gfx7(NAME#"_BOTHEN_RTN")>; def _IDXEN_RTN_gfx6_gfx7 : MUBUF_Real_gfx6_gfx7(NAME#"_IDXEN_RTN")>; def _OFFEN_RTN_gfx6_gfx7 : MUBUF_Real_gfx6_gfx7(NAME#"_OFFEN_RTN")>; def _OFFSET_RTN_gfx6_gfx7 : MUBUF_Real_gfx6_gfx7(NAME#"_OFFSET_RTN")>; } } // End AssemblerPredicate = isGFX6GFX7, DecoderNamespace = "GFX6GFX7" multiclass MUBUF_Real_AllAddr_gfx6_gfx7_gfx10 op> : MUBUF_Real_AllAddr_gfx6_gfx7, MUBUF_Real_AllAddr_gfx10; multiclass MUBUF_Real_AllAddr_Lds_gfx6_gfx7_gfx10 op> : MUBUF_Real_AllAddr_Lds_gfx6_gfx7, MUBUF_Real_AllAddr_Lds_gfx10; multiclass MUBUF_Real_Atomics_gfx6_gfx7_gfx10 op> : MUBUF_Real_Atomics_gfx6_gfx7, MUBUF_Real_Atomics_gfx10; // FIXME-GFX6: Following instructions are available only on GFX6. //defm BUFFER_ATOMIC_RSUB : MUBUF_Real_Atomics_gfx6 <0x034>; //defm BUFFER_ATOMIC_RSUB_X2 : MUBUF_Real_Atomics_gfx6 <0x054>; defm BUFFER_LOAD_FORMAT_X : MUBUF_Real_AllAddr_Lds_gfx6_gfx7_gfx10<0x000>; defm BUFFER_LOAD_FORMAT_XY : MUBUF_Real_AllAddr_gfx6_gfx7_gfx10<0x001>; defm BUFFER_LOAD_FORMAT_XYZ : MUBUF_Real_AllAddr_gfx6_gfx7_gfx10<0x002>; defm BUFFER_LOAD_FORMAT_XYZW : MUBUF_Real_AllAddr_gfx6_gfx7_gfx10<0x003>; defm BUFFER_STORE_FORMAT_X : MUBUF_Real_AllAddr_gfx6_gfx7_gfx10<0x004>; defm BUFFER_STORE_FORMAT_XY : MUBUF_Real_AllAddr_gfx6_gfx7_gfx10<0x005>; defm BUFFER_STORE_FORMAT_XYZ : MUBUF_Real_AllAddr_gfx6_gfx7_gfx10<0x006>; defm BUFFER_STORE_FORMAT_XYZW : MUBUF_Real_AllAddr_gfx6_gfx7_gfx10<0x007>; defm BUFFER_LOAD_UBYTE : MUBUF_Real_AllAddr_Lds_gfx6_gfx7_gfx10<0x008>; defm BUFFER_LOAD_SBYTE : MUBUF_Real_AllAddr_Lds_gfx6_gfx7_gfx10<0x009>; defm BUFFER_LOAD_USHORT : MUBUF_Real_AllAddr_Lds_gfx6_gfx7_gfx10<0x00a>; defm BUFFER_LOAD_SSHORT : MUBUF_Real_AllAddr_Lds_gfx6_gfx7_gfx10<0x00b>; defm BUFFER_LOAD_DWORD : MUBUF_Real_AllAddr_Lds_gfx6_gfx7_gfx10<0x00c>; defm BUFFER_LOAD_DWORDX2 : MUBUF_Real_AllAddr_gfx6_gfx7_gfx10<0x00d>; defm BUFFER_LOAD_DWORDX4 : MUBUF_Real_AllAddr_gfx6_gfx7_gfx10<0x00e>; defm BUFFER_LOAD_DWORDX3 : MUBUF_Real_AllAddr_gfx6_gfx7_gfx10<0x00f>; defm BUFFER_STORE_BYTE : MUBUF_Real_AllAddr_gfx6_gfx7_gfx10<0x018>; defm BUFFER_STORE_SHORT : MUBUF_Real_AllAddr_gfx6_gfx7_gfx10<0x01a>; defm BUFFER_STORE_DWORD : MUBUF_Real_AllAddr_gfx6_gfx7_gfx10<0x01c>; defm BUFFER_STORE_DWORDX2 : MUBUF_Real_AllAddr_gfx6_gfx7_gfx10<0x01d>; defm BUFFER_STORE_DWORDX4 : MUBUF_Real_AllAddr_gfx6_gfx7_gfx10<0x01e>; defm BUFFER_STORE_DWORDX3 : MUBUF_Real_AllAddr_gfx6_gfx7_gfx10<0x01f>; defm BUFFER_ATOMIC_SWAP : MUBUF_Real_Atomics_gfx6_gfx7_gfx10<0x030>; defm BUFFER_ATOMIC_CMPSWAP : MUBUF_Real_Atomics_gfx6_gfx7_gfx10<0x031>; defm BUFFER_ATOMIC_ADD : MUBUF_Real_Atomics_gfx6_gfx7_gfx10<0x032>; defm BUFFER_ATOMIC_SUB : MUBUF_Real_Atomics_gfx6_gfx7_gfx10<0x033>; defm BUFFER_ATOMIC_SMIN : MUBUF_Real_Atomics_gfx6_gfx7_gfx10<0x035>; defm BUFFER_ATOMIC_UMIN : MUBUF_Real_Atomics_gfx6_gfx7_gfx10<0x036>; defm BUFFER_ATOMIC_SMAX : MUBUF_Real_Atomics_gfx6_gfx7_gfx10<0x037>; defm BUFFER_ATOMIC_UMAX : MUBUF_Real_Atomics_gfx6_gfx7_gfx10<0x038>; defm BUFFER_ATOMIC_AND : MUBUF_Real_Atomics_gfx6_gfx7_gfx10<0x039>; defm BUFFER_ATOMIC_OR : MUBUF_Real_Atomics_gfx6_gfx7_gfx10<0x03a>; defm BUFFER_ATOMIC_XOR : MUBUF_Real_Atomics_gfx6_gfx7_gfx10<0x03b>; defm BUFFER_ATOMIC_INC : MUBUF_Real_Atomics_gfx6_gfx7_gfx10<0x03c>; defm BUFFER_ATOMIC_DEC : MUBUF_Real_Atomics_gfx6_gfx7_gfx10<0x03d>; defm BUFFER_ATOMIC_FCMPSWAP : MUBUF_Real_Atomics_gfx6_gfx7_gfx10<0x03e>; defm BUFFER_ATOMIC_FMIN : MUBUF_Real_Atomics_gfx6_gfx7_gfx10<0x03f>; defm BUFFER_ATOMIC_FMAX : MUBUF_Real_Atomics_gfx6_gfx7_gfx10<0x040>; defm BUFFER_ATOMIC_SWAP_X2 : MUBUF_Real_Atomics_gfx6_gfx7_gfx10<0x050>; defm BUFFER_ATOMIC_CMPSWAP_X2 : MUBUF_Real_Atomics_gfx6_gfx7_gfx10<0x051>; defm BUFFER_ATOMIC_ADD_X2 : MUBUF_Real_Atomics_gfx6_gfx7_gfx10<0x052>; defm BUFFER_ATOMIC_SUB_X2 : MUBUF_Real_Atomics_gfx6_gfx7_gfx10<0x053>; defm BUFFER_ATOMIC_SMIN_X2 : MUBUF_Real_Atomics_gfx6_gfx7_gfx10<0x055>; defm BUFFER_ATOMIC_UMIN_X2 : MUBUF_Real_Atomics_gfx6_gfx7_gfx10<0x056>; defm BUFFER_ATOMIC_SMAX_X2 : MUBUF_Real_Atomics_gfx6_gfx7_gfx10<0x057>; defm BUFFER_ATOMIC_UMAX_X2 : MUBUF_Real_Atomics_gfx6_gfx7_gfx10<0x058>; defm BUFFER_ATOMIC_AND_X2 : MUBUF_Real_Atomics_gfx6_gfx7_gfx10<0x059>; defm BUFFER_ATOMIC_OR_X2 : MUBUF_Real_Atomics_gfx6_gfx7_gfx10<0x05a>; defm BUFFER_ATOMIC_XOR_X2 : MUBUF_Real_Atomics_gfx6_gfx7_gfx10<0x05b>; defm BUFFER_ATOMIC_INC_X2 : MUBUF_Real_Atomics_gfx6_gfx7_gfx10<0x05c>; defm BUFFER_ATOMIC_DEC_X2 : MUBUF_Real_Atomics_gfx6_gfx7_gfx10<0x05d>; // FIXME-GFX7: Need to handle hazard for BUFFER_ATOMIC_FCMPSWAP_X2 on GFX7. defm BUFFER_ATOMIC_FCMPSWAP_X2 : MUBUF_Real_Atomics_gfx6_gfx7_gfx10<0x05e>; defm BUFFER_ATOMIC_FMIN_X2 : MUBUF_Real_Atomics_gfx6_gfx7_gfx10<0x05f>; defm BUFFER_ATOMIC_FMAX_X2 : MUBUF_Real_Atomics_gfx6_gfx7_gfx10<0x060>; defm BUFFER_ATOMIC_CSUB : MUBUF_Real_Atomics_RTN_gfx10<0x034>; defm BUFFER_WBINVL1_SC : MUBUF_Real_gfx6<0x070>; defm BUFFER_WBINVL1_VOL : MUBUF_Real_gfx7<0x070>; def BUFFER_WBINVL1_gfx6_gfx7 : MUBUF_Real_gfx6_gfx7<0x071, BUFFER_WBINVL1>; //===----------------------------------------------------------------------===// // Base ENC_MTBUF for GFX6, GFX7, GFX10. //===----------------------------------------------------------------------===// class Base_MTBUF_Real_gfx6_gfx7_gfx10 op, MTBUF_Pseudo ps, int ef> : MTBUF_Real, Enc64, SIMCInstr { let Inst{11-0} = !if(ps.has_offset, offset, ?); let Inst{12} = ps.offen; let Inst{13} = ps.idxen; let Inst{14} = !if(ps.has_glc, glc, ps.glc_value); let Inst{18-16} = op; let Inst{31-26} = 0x3a; //encoding let Inst{39-32} = !if(ps.has_vaddr, vaddr, ?); let Inst{47-40} = !if(ps.has_vdata, vdata, ?); let Inst{52-48} = !if(ps.has_srsrc, srsrc{6-2}, ?); let Inst{54} = !if(ps.has_slc, slc, ?); let Inst{55} = !if(ps.has_tfe, tfe, ?); let Inst{63-56} = !if(ps.has_soffset, soffset, ?); } //===----------------------------------------------------------------------===// // MTBUF - GFX10. //===----------------------------------------------------------------------===// class MTBUF_Real_gfx10 op, MTBUF_Pseudo ps> : Base_MTBUF_Real_gfx6_gfx7_gfx10 { let Inst{15} = !if(ps.has_dlc, dlc, ps.dlc_value); let Inst{25-19} = format; let Inst{53} = op{3}; } let AssemblerPredicate = isGFX10Plus, DecoderNamespace = "GFX10" in { multiclass MTBUF_Real_AllAddr_gfx10 op> { def _BOTHEN_gfx10 : MTBUF_Real_gfx10(NAME#"_BOTHEN")>; def _IDXEN_gfx10 : MTBUF_Real_gfx10(NAME#"_IDXEN")>; def _OFFEN_gfx10 : MTBUF_Real_gfx10(NAME#"_OFFEN")>; def _OFFSET_gfx10 : MTBUF_Real_gfx10(NAME#"_OFFSET")>; } } // End AssemblerPredicate = isGFX10Plus, DecoderNamespace = "GFX10" defm TBUFFER_LOAD_FORMAT_D16_X : MTBUF_Real_AllAddr_gfx10<0x008>; defm TBUFFER_LOAD_FORMAT_D16_XY : MTBUF_Real_AllAddr_gfx10<0x009>; defm TBUFFER_LOAD_FORMAT_D16_XYZ : MTBUF_Real_AllAddr_gfx10<0x00a>; defm TBUFFER_LOAD_FORMAT_D16_XYZW : MTBUF_Real_AllAddr_gfx10<0x00b>; defm TBUFFER_STORE_FORMAT_D16_X : MTBUF_Real_AllAddr_gfx10<0x00c>; defm TBUFFER_STORE_FORMAT_D16_XY : MTBUF_Real_AllAddr_gfx10<0x00d>; defm TBUFFER_STORE_FORMAT_D16_XYZ : MTBUF_Real_AllAddr_gfx10<0x00e>; defm TBUFFER_STORE_FORMAT_D16_XYZW : MTBUF_Real_AllAddr_gfx10<0x00f>; //===----------------------------------------------------------------------===// // MTBUF - GFX6, GFX7, GFX10. //===----------------------------------------------------------------------===// class MTBUF_Real_gfx6_gfx7 op, MTBUF_Pseudo ps> : Base_MTBUF_Real_gfx6_gfx7_gfx10 { let Inst{15} = ps.addr64; let Inst{22-19} = dfmt; let Inst{25-23} = nfmt; } let AssemblerPredicate = isGFX6GFX7, DecoderNamespace = "GFX6GFX7" in { multiclass MTBUF_Real_AllAddr_gfx6_gfx7 op> { def _ADDR64_gfx6_gfx7 : MTBUF_Real_gfx6_gfx7(NAME#"_ADDR64")>; def _BOTHEN_gfx6_gfx7 : MTBUF_Real_gfx6_gfx7(NAME#"_BOTHEN")>; def _IDXEN_gfx6_gfx7 : MTBUF_Real_gfx6_gfx7(NAME#"_IDXEN")>; def _OFFEN_gfx6_gfx7 : MTBUF_Real_gfx6_gfx7(NAME#"_OFFEN")>; def _OFFSET_gfx6_gfx7 : MTBUF_Real_gfx6_gfx7(NAME#"_OFFSET")>; } } // End AssemblerPredicate = isGFX6GFX7, DecoderNamespace = "GFX6GFX7" multiclass MTBUF_Real_AllAddr_gfx6_gfx7_gfx10 op> : MTBUF_Real_AllAddr_gfx6_gfx7, MTBUF_Real_AllAddr_gfx10; defm TBUFFER_LOAD_FORMAT_X : MTBUF_Real_AllAddr_gfx6_gfx7_gfx10<0x000>; defm TBUFFER_LOAD_FORMAT_XY : MTBUF_Real_AllAddr_gfx6_gfx7_gfx10<0x001>; defm TBUFFER_LOAD_FORMAT_XYZ : MTBUF_Real_AllAddr_gfx6_gfx7_gfx10<0x002>; defm TBUFFER_LOAD_FORMAT_XYZW : MTBUF_Real_AllAddr_gfx6_gfx7_gfx10<0x003>; defm TBUFFER_STORE_FORMAT_X : MTBUF_Real_AllAddr_gfx6_gfx7_gfx10<0x004>; defm TBUFFER_STORE_FORMAT_XY : MTBUF_Real_AllAddr_gfx6_gfx7_gfx10<0x005>; defm TBUFFER_STORE_FORMAT_XYZ : MTBUF_Real_AllAddr_gfx6_gfx7_gfx10<0x006>; defm TBUFFER_STORE_FORMAT_XYZW : MTBUF_Real_AllAddr_gfx6_gfx7_gfx10<0x007>; //===----------------------------------------------------------------------===// // GFX8, GFX9 (VI). //===----------------------------------------------------------------------===// class MUBUF_Real_vi op, MUBUF_Pseudo ps> : MUBUF_Real, Enc64, SIMCInstr { let AssemblerPredicate = isGFX8GFX9; let DecoderNamespace = "GFX8"; let Inst{11-0} = !if(ps.has_offset, offset, ?); let Inst{12} = ps.offen; let Inst{13} = ps.idxen; let Inst{14} = !if(ps.has_glc, glc, ps.glc_value); let Inst{16} = ps.lds; let Inst{17} = !if(ps.has_slc, slc, ?); let Inst{24-18} = op; let Inst{31-26} = 0x38; //encoding let Inst{39-32} = !if(ps.has_vaddr, vaddr, ?); let Inst{47-40} = !if(ps.has_vdata, vdata, ?); let Inst{52-48} = !if(ps.has_srsrc, srsrc{6-2}, ?); let Inst{55} = !if(ps.has_tfe, tfe, ?); let Inst{63-56} = !if(ps.has_soffset, soffset, ?); } multiclass MUBUF_Real_AllAddr_vi op> { def _OFFSET_vi : MUBUF_Real_vi (NAME#"_OFFSET")>; def _OFFEN_vi : MUBUF_Real_vi (NAME#"_OFFEN")>; def _IDXEN_vi : MUBUF_Real_vi (NAME#"_IDXEN")>; def _BOTHEN_vi : MUBUF_Real_vi (NAME#"_BOTHEN")>; } multiclass MUBUF_Real_AllAddr_Lds_vi op> { def _OFFSET_vi : MUBUF_Real_vi (NAME#"_OFFSET")>, MUBUFLdsTable<0, NAME # "_OFFSET_vi">; def _OFFEN_vi : MUBUF_Real_vi (NAME#"_OFFEN")>, MUBUFLdsTable<0, NAME # "_OFFEN_vi">; def _IDXEN_vi : MUBUF_Real_vi (NAME#"_IDXEN")>, MUBUFLdsTable<0, NAME # "_IDXEN_vi">; def _BOTHEN_vi : MUBUF_Real_vi (NAME#"_BOTHEN")>, MUBUFLdsTable<0, NAME # "_BOTHEN_vi">; def _LDS_OFFSET_vi : MUBUF_Real_vi (NAME#"_LDS_OFFSET")>, MUBUFLdsTable<1, NAME # "_OFFSET_vi">; def _LDS_OFFEN_vi : MUBUF_Real_vi (NAME#"_LDS_OFFEN")>, MUBUFLdsTable<1, NAME # "_OFFEN_vi">; def _LDS_IDXEN_vi : MUBUF_Real_vi (NAME#"_LDS_IDXEN")>, MUBUFLdsTable<1, NAME # "_IDXEN_vi">; def _LDS_BOTHEN_vi : MUBUF_Real_vi (NAME#"_LDS_BOTHEN")>, MUBUFLdsTable<1, NAME # "_BOTHEN_vi">; } class MUBUF_Real_gfx80 op, MUBUF_Pseudo ps> : MUBUF_Real, Enc64, SIMCInstr { let AssemblerPredicate=HasUnpackedD16VMem; let DecoderNamespace="GFX80_UNPACKED"; let Inst{11-0} = !if(ps.has_offset, offset, ?); let Inst{12} = ps.offen; let Inst{13} = ps.idxen; let Inst{14} = !if(ps.has_glc, glc, ps.glc_value); let Inst{16} = ps.lds; let Inst{17} = !if(ps.has_slc, slc, ?); let Inst{24-18} = op; let Inst{31-26} = 0x38; //encoding let Inst{39-32} = !if(ps.has_vaddr, vaddr, ?); let Inst{47-40} = !if(ps.has_vdata, vdata, ?); let Inst{52-48} = !if(ps.has_srsrc, srsrc{6-2}, ?); let Inst{55} = !if(ps.has_tfe, tfe, ?); let Inst{63-56} = !if(ps.has_soffset, soffset, ?); } multiclass MUBUF_Real_AllAddr_gfx80 op> { def _OFFSET_gfx80 : MUBUF_Real_gfx80 (NAME#"_OFFSET")>; def _OFFEN_gfx80 : MUBUF_Real_gfx80 (NAME#"_OFFEN")>; def _IDXEN_gfx80 : MUBUF_Real_gfx80 (NAME#"_IDXEN")>; def _BOTHEN_gfx80 : MUBUF_Real_gfx80 (NAME#"_BOTHEN")>; } multiclass MUBUF_Real_Atomic_vi op> : MUBUF_Real_AllAddr_vi { def _OFFSET_RTN_vi : MUBUF_Real_vi (NAME#"_OFFSET_RTN")>; def _OFFEN_RTN_vi : MUBUF_Real_vi (NAME#"_OFFEN_RTN")>; def _IDXEN_RTN_vi : MUBUF_Real_vi (NAME#"_IDXEN_RTN")>; def _BOTHEN_RTN_vi : MUBUF_Real_vi (NAME#"_BOTHEN_RTN")>; } defm BUFFER_LOAD_FORMAT_X : MUBUF_Real_AllAddr_Lds_vi <0x00>; defm BUFFER_LOAD_FORMAT_XY : MUBUF_Real_AllAddr_vi <0x01>; defm BUFFER_LOAD_FORMAT_XYZ : MUBUF_Real_AllAddr_vi <0x02>; defm BUFFER_LOAD_FORMAT_XYZW : MUBUF_Real_AllAddr_vi <0x03>; defm BUFFER_STORE_FORMAT_X : MUBUF_Real_AllAddr_vi <0x04>; defm BUFFER_STORE_FORMAT_XY : MUBUF_Real_AllAddr_vi <0x05>; defm BUFFER_STORE_FORMAT_XYZ : MUBUF_Real_AllAddr_vi <0x06>; defm BUFFER_STORE_FORMAT_XYZW : MUBUF_Real_AllAddr_vi <0x07>; let SubtargetPredicate = HasUnpackedD16VMem in { defm BUFFER_LOAD_FORMAT_D16_X_gfx80 : MUBUF_Real_AllAddr_gfx80 <0x08>; defm BUFFER_LOAD_FORMAT_D16_XY_gfx80 : MUBUF_Real_AllAddr_gfx80 <0x09>; defm BUFFER_LOAD_FORMAT_D16_XYZ_gfx80 : MUBUF_Real_AllAddr_gfx80 <0x0a>; defm BUFFER_LOAD_FORMAT_D16_XYZW_gfx80 : MUBUF_Real_AllAddr_gfx80 <0x0b>; defm BUFFER_STORE_FORMAT_D16_X_gfx80 : MUBUF_Real_AllAddr_gfx80 <0x0c>; defm BUFFER_STORE_FORMAT_D16_XY_gfx80 : MUBUF_Real_AllAddr_gfx80 <0x0d>; defm BUFFER_STORE_FORMAT_D16_XYZ_gfx80 : MUBUF_Real_AllAddr_gfx80 <0x0e>; defm BUFFER_STORE_FORMAT_D16_XYZW_gfx80 : MUBUF_Real_AllAddr_gfx80 <0x0f>; } // End HasUnpackedD16VMem. let SubtargetPredicate = HasPackedD16VMem in { defm BUFFER_LOAD_FORMAT_D16_X : MUBUF_Real_AllAddr_vi <0x08>; defm BUFFER_LOAD_FORMAT_D16_XY : MUBUF_Real_AllAddr_vi <0x09>; defm BUFFER_LOAD_FORMAT_D16_XYZ : MUBUF_Real_AllAddr_vi <0x0a>; defm BUFFER_LOAD_FORMAT_D16_XYZW : MUBUF_Real_AllAddr_vi <0x0b>; defm BUFFER_STORE_FORMAT_D16_X : MUBUF_Real_AllAddr_vi <0x0c>; defm BUFFER_STORE_FORMAT_D16_XY : MUBUF_Real_AllAddr_vi <0x0d>; defm BUFFER_STORE_FORMAT_D16_XYZ : MUBUF_Real_AllAddr_vi <0x0e>; defm BUFFER_STORE_FORMAT_D16_XYZW : MUBUF_Real_AllAddr_vi <0x0f>; } // End HasPackedD16VMem. defm BUFFER_LOAD_UBYTE : MUBUF_Real_AllAddr_Lds_vi <0x10>; defm BUFFER_LOAD_SBYTE : MUBUF_Real_AllAddr_Lds_vi <0x11>; defm BUFFER_LOAD_USHORT : MUBUF_Real_AllAddr_Lds_vi <0x12>; defm BUFFER_LOAD_SSHORT : MUBUF_Real_AllAddr_Lds_vi <0x13>; defm BUFFER_LOAD_DWORD : MUBUF_Real_AllAddr_Lds_vi <0x14>; defm BUFFER_LOAD_DWORDX2 : MUBUF_Real_AllAddr_Lds_vi <0x15>; defm BUFFER_LOAD_DWORDX3 : MUBUF_Real_AllAddr_Lds_vi <0x16>; defm BUFFER_LOAD_DWORDX4 : MUBUF_Real_AllAddr_Lds_vi <0x17>; defm BUFFER_STORE_BYTE : MUBUF_Real_AllAddr_vi <0x18>; defm BUFFER_STORE_BYTE_D16_HI : MUBUF_Real_AllAddr_vi <0x19>; defm BUFFER_STORE_SHORT : MUBUF_Real_AllAddr_vi <0x1a>; defm BUFFER_STORE_SHORT_D16_HI : MUBUF_Real_AllAddr_vi <0x1b>; defm BUFFER_STORE_DWORD : MUBUF_Real_AllAddr_vi <0x1c>; defm BUFFER_STORE_DWORDX2 : MUBUF_Real_AllAddr_vi <0x1d>; defm BUFFER_STORE_DWORDX3 : MUBUF_Real_AllAddr_vi <0x1e>; defm BUFFER_STORE_DWORDX4 : MUBUF_Real_AllAddr_vi <0x1f>; defm BUFFER_LOAD_UBYTE_D16 : MUBUF_Real_AllAddr_vi <0x20>; defm BUFFER_LOAD_UBYTE_D16_HI : MUBUF_Real_AllAddr_vi <0x21>; defm BUFFER_LOAD_SBYTE_D16 : MUBUF_Real_AllAddr_vi <0x22>; defm BUFFER_LOAD_SBYTE_D16_HI : MUBUF_Real_AllAddr_vi <0x23>; defm BUFFER_LOAD_SHORT_D16 : MUBUF_Real_AllAddr_vi <0x24>; defm BUFFER_LOAD_SHORT_D16_HI : MUBUF_Real_AllAddr_vi <0x25>; defm BUFFER_LOAD_FORMAT_D16_HI_X : MUBUF_Real_AllAddr_vi <0x26>; defm BUFFER_STORE_FORMAT_D16_HI_X : MUBUF_Real_AllAddr_vi <0x27>; defm BUFFER_ATOMIC_SWAP : MUBUF_Real_Atomic_vi <0x40>; defm BUFFER_ATOMIC_CMPSWAP : MUBUF_Real_Atomic_vi <0x41>; defm BUFFER_ATOMIC_ADD : MUBUF_Real_Atomic_vi <0x42>; defm BUFFER_ATOMIC_SUB : MUBUF_Real_Atomic_vi <0x43>; defm BUFFER_ATOMIC_SMIN : MUBUF_Real_Atomic_vi <0x44>; defm BUFFER_ATOMIC_UMIN : MUBUF_Real_Atomic_vi <0x45>; defm BUFFER_ATOMIC_SMAX : MUBUF_Real_Atomic_vi <0x46>; defm BUFFER_ATOMIC_UMAX : MUBUF_Real_Atomic_vi <0x47>; defm BUFFER_ATOMIC_AND : MUBUF_Real_Atomic_vi <0x48>; defm BUFFER_ATOMIC_OR : MUBUF_Real_Atomic_vi <0x49>; defm BUFFER_ATOMIC_XOR : MUBUF_Real_Atomic_vi <0x4a>; defm BUFFER_ATOMIC_INC : MUBUF_Real_Atomic_vi <0x4b>; defm BUFFER_ATOMIC_DEC : MUBUF_Real_Atomic_vi <0x4c>; defm BUFFER_ATOMIC_SWAP_X2 : MUBUF_Real_Atomic_vi <0x60>; defm BUFFER_ATOMIC_CMPSWAP_X2 : MUBUF_Real_Atomic_vi <0x61>; defm BUFFER_ATOMIC_ADD_X2 : MUBUF_Real_Atomic_vi <0x62>; defm BUFFER_ATOMIC_SUB_X2 : MUBUF_Real_Atomic_vi <0x63>; defm BUFFER_ATOMIC_SMIN_X2 : MUBUF_Real_Atomic_vi <0x64>; defm BUFFER_ATOMIC_UMIN_X2 : MUBUF_Real_Atomic_vi <0x65>; defm BUFFER_ATOMIC_SMAX_X2 : MUBUF_Real_Atomic_vi <0x66>; defm BUFFER_ATOMIC_UMAX_X2 : MUBUF_Real_Atomic_vi <0x67>; defm BUFFER_ATOMIC_AND_X2 : MUBUF_Real_Atomic_vi <0x68>; defm BUFFER_ATOMIC_OR_X2 : MUBUF_Real_Atomic_vi <0x69>; defm BUFFER_ATOMIC_XOR_X2 : MUBUF_Real_Atomic_vi <0x6a>; defm BUFFER_ATOMIC_INC_X2 : MUBUF_Real_Atomic_vi <0x6b>; defm BUFFER_ATOMIC_DEC_X2 : MUBUF_Real_Atomic_vi <0x6c>; def BUFFER_STORE_LDS_DWORD_vi : MUBUF_Real_vi <0x3d, BUFFER_STORE_LDS_DWORD>; def BUFFER_WBINVL1_vi : MUBUF_Real_vi <0x3e, BUFFER_WBINVL1>; def BUFFER_WBINVL1_VOL_vi : MUBUF_Real_vi <0x3f, BUFFER_WBINVL1_VOL>; let SubtargetPredicate = HasAtomicFaddInsts in { defm BUFFER_ATOMIC_ADD_F32 : MUBUF_Real_AllAddr_vi <0x4d>; defm BUFFER_ATOMIC_PK_ADD_F16 : MUBUF_Real_AllAddr_vi <0x4e>; } // End SubtargetPredicate = HasAtomicFaddInsts class MTBUF_Real_vi op, MTBUF_Pseudo ps> : MTBUF_Real, Enc64, SIMCInstr { let AssemblerPredicate = isGFX8GFX9; let DecoderNamespace = "GFX8"; let Inst{11-0} = !if(ps.has_offset, offset, ?); let Inst{12} = ps.offen; let Inst{13} = ps.idxen; let Inst{14} = !if(ps.has_glc, glc, ps.glc_value); let Inst{18-15} = op; let Inst{22-19} = dfmt; let Inst{25-23} = nfmt; let Inst{31-26} = 0x3a; //encoding let Inst{39-32} = !if(ps.has_vaddr, vaddr, ?); let Inst{47-40} = !if(ps.has_vdata, vdata, ?); let Inst{52-48} = !if(ps.has_srsrc, srsrc{6-2}, ?); let Inst{54} = !if(ps.has_slc, slc, ?); let Inst{55} = !if(ps.has_tfe, tfe, ?); let Inst{63-56} = !if(ps.has_soffset, soffset, ?); } multiclass MTBUF_Real_AllAddr_vi op> { def _OFFSET_vi : MTBUF_Real_vi (NAME#"_OFFSET")>; def _OFFEN_vi : MTBUF_Real_vi (NAME#"_OFFEN")>; def _IDXEN_vi : MTBUF_Real_vi (NAME#"_IDXEN")>; def _BOTHEN_vi : MTBUF_Real_vi (NAME#"_BOTHEN")>; } class MTBUF_Real_gfx80 op, MTBUF_Pseudo ps> : MTBUF_Real, Enc64, SIMCInstr { let AssemblerPredicate=HasUnpackedD16VMem; let DecoderNamespace="GFX80_UNPACKED"; let Inst{11-0} = !if(ps.has_offset, offset, ?); let Inst{12} = ps.offen; let Inst{13} = ps.idxen; let Inst{14} = !if(ps.has_glc, glc, ps.glc_value); let Inst{18-15} = op; let Inst{22-19} = dfmt; let Inst{25-23} = nfmt; let Inst{31-26} = 0x3a; //encoding let Inst{39-32} = !if(ps.has_vaddr, vaddr, ?); let Inst{47-40} = !if(ps.has_vdata, vdata, ?); let Inst{52-48} = !if(ps.has_srsrc, srsrc{6-2}, ?); let Inst{54} = !if(ps.has_slc, slc, ?); let Inst{55} = !if(ps.has_tfe, tfe, ?); let Inst{63-56} = !if(ps.has_soffset, soffset, ?); } multiclass MTBUF_Real_AllAddr_gfx80 op> { def _OFFSET_gfx80 : MTBUF_Real_gfx80 (NAME#"_OFFSET")>; def _OFFEN_gfx80 : MTBUF_Real_gfx80 (NAME#"_OFFEN")>; def _IDXEN_gfx80 : MTBUF_Real_gfx80 (NAME#"_IDXEN")>; def _BOTHEN_gfx80 : MTBUF_Real_gfx80 (NAME#"_BOTHEN")>; } defm TBUFFER_LOAD_FORMAT_X : MTBUF_Real_AllAddr_vi <0x00>; defm TBUFFER_LOAD_FORMAT_XY : MTBUF_Real_AllAddr_vi <0x01>; defm TBUFFER_LOAD_FORMAT_XYZ : MTBUF_Real_AllAddr_vi <0x02>; defm TBUFFER_LOAD_FORMAT_XYZW : MTBUF_Real_AllAddr_vi <0x03>; defm TBUFFER_STORE_FORMAT_X : MTBUF_Real_AllAddr_vi <0x04>; defm TBUFFER_STORE_FORMAT_XY : MTBUF_Real_AllAddr_vi <0x05>; defm TBUFFER_STORE_FORMAT_XYZ : MTBUF_Real_AllAddr_vi <0x06>; defm TBUFFER_STORE_FORMAT_XYZW : MTBUF_Real_AllAddr_vi <0x07>; let SubtargetPredicate = HasUnpackedD16VMem in { defm TBUFFER_LOAD_FORMAT_D16_X_gfx80 : MTBUF_Real_AllAddr_gfx80 <0x08>; defm TBUFFER_LOAD_FORMAT_D16_XY_gfx80 : MTBUF_Real_AllAddr_gfx80 <0x09>; defm TBUFFER_LOAD_FORMAT_D16_XYZ_gfx80 : MTBUF_Real_AllAddr_gfx80 <0x0a>; defm TBUFFER_LOAD_FORMAT_D16_XYZW_gfx80 : MTBUF_Real_AllAddr_gfx80 <0x0b>; defm TBUFFER_STORE_FORMAT_D16_X_gfx80 : MTBUF_Real_AllAddr_gfx80 <0x0c>; defm TBUFFER_STORE_FORMAT_D16_XY_gfx80 : MTBUF_Real_AllAddr_gfx80 <0x0d>; defm TBUFFER_STORE_FORMAT_D16_XYZ_gfx80 : MTBUF_Real_AllAddr_gfx80 <0x0e>; defm TBUFFER_STORE_FORMAT_D16_XYZW_gfx80 : MTBUF_Real_AllAddr_gfx80 <0x0f>; } // End HasUnpackedD16VMem. let SubtargetPredicate = HasPackedD16VMem in { defm TBUFFER_LOAD_FORMAT_D16_X : MTBUF_Real_AllAddr_vi <0x08>; defm TBUFFER_LOAD_FORMAT_D16_XY : MTBUF_Real_AllAddr_vi <0x09>; defm TBUFFER_LOAD_FORMAT_D16_XYZ : MTBUF_Real_AllAddr_vi <0x0a>; defm TBUFFER_LOAD_FORMAT_D16_XYZW : MTBUF_Real_AllAddr_vi <0x0b>; defm TBUFFER_STORE_FORMAT_D16_X : MTBUF_Real_AllAddr_vi <0x0c>; defm TBUFFER_STORE_FORMAT_D16_XY : MTBUF_Real_AllAddr_vi <0x0d>; defm TBUFFER_STORE_FORMAT_D16_XYZ : MTBUF_Real_AllAddr_vi <0x0e>; defm TBUFFER_STORE_FORMAT_D16_XYZW : MTBUF_Real_AllAddr_vi <0x0f>; } // End HasUnpackedD16VMem. def MUBUFInfoTable : GenericTable { let FilterClass = "MUBUF_Pseudo"; let CppTypeName = "MUBUFInfo"; let Fields = ["Opcode", "BaseOpcode", "elements", "has_vaddr", "has_srsrc", "has_soffset"]; let PrimaryKey = ["Opcode"]; let PrimaryKeyName = "getMUBUFOpcodeHelper"; } def getMUBUFInfoFromOpcode : SearchIndex { let Table = MUBUFInfoTable; let Key = ["Opcode"]; } def getMUBUFInfoFromBaseOpcodeAndElements : SearchIndex { let Table = MUBUFInfoTable; let Key = ["BaseOpcode", "elements"]; } def MTBUFInfoTable : GenericTable { let FilterClass = "MTBUF_Pseudo"; let CppTypeName = "MTBUFInfo"; let Fields = ["Opcode", "BaseOpcode", "elements", "has_vaddr", "has_srsrc", "has_soffset"]; let PrimaryKey = ["Opcode"]; let PrimaryKeyName = "getMTBUFOpcodeHelper"; } def getMTBUFInfoFromOpcode : SearchIndex { let Table = MTBUFInfoTable; let Key = ["Opcode"]; } def getMTBUFInfoFromBaseOpcodeAndElements : SearchIndex { let Table = MTBUFInfoTable; let Key = ["BaseOpcode", "elements"]; }