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//===-- VOPInstructions.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
//
//===----------------------------------------------------------------------===//
// dummies for outer let
class LetDummies {
bit TRANS;
bit ReadsModeReg;
bit mayRaiseFPException;
bit isCommutable;
bit isConvertibleToThreeAddress;
bit isMoveImm;
bit isReMaterializable;
bit isAsCheapAsAMove;
bit VOPAsmPrefer32Bit;
bit FPDPRounding;
Predicate SubtargetPredicate;
string Constraints;
string DisableEncoding;
list<SchedReadWrite> SchedRW;
list<Register> Uses;
list<Register> Defs;
}
class VOP <string opName> {
string OpName = opName;
}
class VOPAnyCommon <dag outs, dag ins, string asm, list<dag> pattern> :
InstSI <outs, ins, asm, pattern> {
let mayLoad = 0;
let mayStore = 0;
let hasSideEffects = 0;
let UseNamedOperandTable = 1;
let VALU = 1;
let Uses = !if(ReadsModeReg, [MODE, EXEC], [EXEC]);
}
class VOP_Pseudo <string opName, string suffix, VOPProfile P, dag outs, dag ins,
string asm, list<dag> pattern> :
InstSI <outs, ins, asm, pattern>,
VOP <opName>,
SIMCInstr <opName#suffix, SIEncodingFamily.NONE> {
let isPseudo = 1;
let isCodeGenOnly = 1;
let UseNamedOperandTable = 1;
string Mnemonic = opName;
VOPProfile Pfl = P;
string AsmOperands;
}
class VOP3Common <dag outs, dag ins, string asm = "",
list<dag> pattern = [], bit HasMods = 0> :
VOPAnyCommon <outs, ins, asm, pattern> {
// Using complex patterns gives VOP3 patterns a very high complexity rating,
// but standalone patterns are almost always preferred, so we need to adjust the
// priority lower. The goal is to use a high number to reduce complexity to
// zero (or less than zero).
let AddedComplexity = -1000;
let VOP3 = 1;
let AsmVariantName = AMDGPUAsmVariants.VOP3;
let AsmMatchConverter = !if(HasMods, "cvtVOP3", "");
let isCodeGenOnly = 0;
int Size = 8;
// Because SGPRs may be allowed if there are multiple operands, we
// need a post-isel hook to insert copies in order to avoid
// violating constant bus requirements.
let hasPostISelHook = 1;
}
class VOP3_Pseudo <string opName, VOPProfile P, list<dag> pattern = [],
bit isVOP3P = 0, bit isVop3OpSel = 0> :
VOP_Pseudo <opName, "_e64", P, P.Outs64,
!if(isVop3OpSel,
P.InsVOP3OpSel,
!if(!and(isVOP3P, P.IsPacked), P.InsVOP3P, P.Ins64)),
"", pattern> {
let VOP3_OPSEL = isVop3OpSel;
let IsPacked = P.IsPacked;
let IsMAI = P.IsMAI;
let AsmOperands = !if(isVop3OpSel,
P.AsmVOP3OpSel,
!if(!and(isVOP3P, P.IsPacked), P.AsmVOP3P, P.Asm64));
let Size = 8;
let mayLoad = 0;
let mayStore = 0;
let hasSideEffects = 0;
// Because SGPRs may be allowed if there are multiple operands, we
// need a post-isel hook to insert copies in order to avoid
// violating constant bus requirements.
let hasPostISelHook = 1;
// Using complex patterns gives VOP3 patterns a very high complexity rating,
// but standalone patterns are almost always preferred, so we need to adjust the
// priority lower. The goal is to use a high number to reduce complexity to
// zero (or less than zero).
let AddedComplexity = -1000;
let VOP3 = 1;
let VALU = 1;
let FPClamp = P.HasFPClamp;
let IntClamp = P.HasIntClamp;
let ClampLo = P.HasClampLo;
let ClampHi = P.HasClampHi;
let ReadsModeReg = !or(isFloatType<P.DstVT>.ret, isFloatType<P.Src0VT>.ret);
let mayRaiseFPException = ReadsModeReg;
let Uses = !if(ReadsModeReg, [MODE, EXEC], [EXEC]);
let AsmVariantName = AMDGPUAsmVariants.VOP3;
let AsmMatchConverter =
!if(isVOP3P,
"cvtVOP3P",
!if(!or(P.HasModifiers, P.HasOMod, P.HasIntClamp),
"cvtVOP3",
""));
}
class VOP3P_Pseudo <string opName, VOPProfile P, list<dag> pattern = []> :
VOP3_Pseudo<opName, P, pattern, 1> {
let VOP3P = 1;
}
class VOP_Real<VOP_Pseudo ps> {
Instruction Opcode = !cast<Instruction>(NAME);
bit IsSingle = ps.Pfl.IsSingle;
}
class VOP3_Real <VOP_Pseudo ps, int EncodingFamily> :
VOP_Real <ps>,
InstSI <ps.OutOperandList, ps.InOperandList, ps.Mnemonic # ps.AsmOperands, []>,
SIMCInstr <ps.PseudoInstr, EncodingFamily> {
let VALU = 1;
let VOP3 = 1;
let isPseudo = 0;
let isCodeGenOnly = 0;
let UseNamedOperandTable = 1;
let Constraints = ps.Constraints;
let DisableEncoding = ps.DisableEncoding;
// copy relevant pseudo op flags
let SubtargetPredicate = ps.SubtargetPredicate;
let OtherPredicates = ps.OtherPredicates;
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;
VOPProfile Pfl = ps.Pfl;
}
// XXX - Is there any reason to distinguish this from regular VOP3
// here?
class VOP3P_Real<VOP_Pseudo ps, int EncodingFamily> :
VOP3_Real<ps, EncodingFamily>;
class VOP3a<VOPProfile P> : Enc64 {
bits<4> src0_modifiers;
bits<9> src0;
bits<3> src1_modifiers;
bits<9> src1;
bits<3> src2_modifiers;
bits<9> src2;
bits<1> clamp;
bits<2> omod;
let Inst{8} = !if(P.HasSrc0Mods, src0_modifiers{1}, 0);
let Inst{9} = !if(P.HasSrc1Mods, src1_modifiers{1}, 0);
let Inst{10} = !if(P.HasSrc2Mods, src2_modifiers{1}, 0);
let Inst{31-26} = 0x34; //encoding
let Inst{40-32} = !if(P.HasSrc0, src0, 0);
let Inst{49-41} = !if(P.HasSrc1, src1, 0);
let Inst{58-50} = !if(P.HasSrc2, src2, 0);
let Inst{60-59} = !if(P.HasOMod, omod, 0);
let Inst{61} = !if(P.HasSrc0Mods, src0_modifiers{0}, 0);
let Inst{62} = !if(P.HasSrc1Mods, src1_modifiers{0}, 0);
let Inst{63} = !if(P.HasSrc2Mods, src2_modifiers{0}, 0);
}
class VOP3a_gfx6_gfx7<bits<9> op, VOPProfile p> : VOP3a<p> {
let Inst{11} = !if(p.HasClamp, clamp{0}, 0);
let Inst{25-17} = op;
}
class VOP3a_gfx10<bits<10> op, VOPProfile p> : VOP3a<p> {
let Inst{15} = !if(p.HasClamp, clamp{0}, 0);
let Inst{25-16} = op;
let Inst{31-26} = 0x35;
}
class VOP3a_vi <bits<10> op, VOPProfile P> : VOP3a<P> {
let Inst{25-16} = op;
let Inst{15} = !if(P.HasClamp, clamp{0}, 0);
}
class VOP3e_gfx6_gfx7<bits<9> op, VOPProfile p> : VOP3a_gfx6_gfx7<op, p> {
bits<8> vdst;
let Inst{7-0} = !if(p.EmitDst, vdst{7-0}, 0);
}
class VOP3e_gfx10<bits<10> op, VOPProfile p> : VOP3a_gfx10<op, p> {
bits<8> vdst;
let Inst{7-0} = !if(p.EmitDst, vdst{7-0}, 0);
}
class VOP3e_vi <bits<10> op, VOPProfile P> : VOP3a_vi <op, P> {
bits<8> vdst;
let Inst{7-0} = !if(P.EmitDst, vdst{7-0}, 0);
}
class VOP3OpSel_gfx9 <bits<10> op, VOPProfile P> : VOP3e_vi <op, P> {
let Inst{11} = !if(P.HasSrc0, src0_modifiers{2}, 0);
let Inst{12} = !if(P.HasSrc1, src1_modifiers{2}, 0);
let Inst{13} = !if(P.HasSrc2, src2_modifiers{2}, 0);
let Inst{14} = !if(P.HasDst, src0_modifiers{3}, 0);
}
class VOP3OpSel_gfx10<bits<10> op, VOPProfile p> : VOP3e_gfx10<op, p> {
let Inst{11} = !if(p.HasSrc0, src0_modifiers{2}, 0);
let Inst{12} = !if(p.HasSrc1, src1_modifiers{2}, 0);
let Inst{13} = !if(p.HasSrc2, src2_modifiers{2}, 0);
let Inst{14} = !if(p.HasDst, src0_modifiers{3}, 0);
}
// NB: For V_INTERP* opcodes, src0 is encoded as src1 and vice versa
class VOP3Interp_vi <bits<10> op, VOPProfile P> : VOP3e_vi <op, P> {
bits<2> attrchan;
bits<6> attr;
bits<1> high;
let Inst{8} = 0; // No modifiers for src0
let Inst{61} = 0;
let Inst{9} = !if(P.HasSrc0Mods, src0_modifiers{1}, 0);
let Inst{62} = !if(P.HasSrc0Mods, src0_modifiers{0}, 0);
let Inst{37-32} = attr;
let Inst{39-38} = attrchan;
let Inst{40} = !if(P.HasHigh, high, 0);
let Inst{49-41} = src0;
}
class VOP3Interp_gfx10<bits<10> op, VOPProfile p> : VOP3e_gfx10<op, p> {
bits<6> attr;
bits<2> attrchan;
bits<1> high;
let Inst{8} = 0;
let Inst{9} = !if(p.HasSrc0Mods, src0_modifiers{1}, 0);
let Inst{37-32} = attr;
let Inst{39-38} = attrchan;
let Inst{40} = !if(p.HasHigh, high, 0);
let Inst{49-41} = src0;
let Inst{61} = 0;
let Inst{62} = !if(p.HasSrc0Mods, src0_modifiers{0}, 0);
}
class VOP3be <VOPProfile P> : Enc64 {
bits<8> vdst;
bits<2> src0_modifiers;
bits<9> src0;
bits<2> src1_modifiers;
bits<9> src1;
bits<2> src2_modifiers;
bits<9> src2;
bits<7> sdst;
bits<2> omod;
let Inst{7-0} = vdst;
let Inst{14-8} = sdst;
let Inst{31-26} = 0x34; //encoding
let Inst{40-32} = !if(P.HasSrc0, src0, 0);
let Inst{49-41} = !if(P.HasSrc1, src1, 0);
let Inst{58-50} = !if(P.HasSrc2, src2, 0);
let Inst{60-59} = !if(P.HasOMod, omod, 0);
let Inst{61} = !if(P.HasSrc0Mods, src0_modifiers{0}, 0);
let Inst{62} = !if(P.HasSrc1Mods, src1_modifiers{0}, 0);
let Inst{63} = !if(P.HasSrc2Mods, src2_modifiers{0}, 0);
}
class VOP3Pe <bits<7> op, VOPProfile P> : Enc64 {
bits<8> vdst;
// neg, neg_hi, op_sel put in srcN_modifiers
bits<4> src0_modifiers;
bits<9> src0;
bits<4> src1_modifiers;
bits<9> src1;
bits<4> src2_modifiers;
bits<9> src2;
bits<1> clamp;
let Inst{7-0} = vdst;
let Inst{8} = !if(P.HasSrc0Mods, src0_modifiers{1}, 0); // neg_hi src0
let Inst{9} = !if(P.HasSrc1Mods, src1_modifiers{1}, 0); // neg_hi src1
let Inst{10} = !if(P.HasSrc2Mods, src2_modifiers{1}, 0); // neg_hi src2
let Inst{11} = !if(!and(P.HasSrc0, P.HasOpSel), src0_modifiers{2}, 0); // op_sel(0)
let Inst{12} = !if(!and(P.HasSrc1, P.HasOpSel), src1_modifiers{2}, 0); // op_sel(1)
let Inst{13} = !if(!and(P.HasSrc2, P.HasOpSel), src2_modifiers{2}, 0); // op_sel(2)
let Inst{14} = !if(!and(P.HasSrc2, P.HasOpSel), src2_modifiers{3}, ?); // op_sel_hi(2)
let Inst{15} = !if(P.HasClamp, clamp{0}, 0);
let Inst{22-16} = op;
let Inst{31-23} = 0x1a7; //encoding
let Inst{40-32} = !if(P.HasSrc0, src0, 0);
let Inst{49-41} = !if(P.HasSrc1, src1, 0);
let Inst{58-50} = !if(P.HasSrc2, src2, 0);
let Inst{59} = !if(!and(P.HasSrc0, P.HasOpSel), src0_modifiers{3}, ?); // op_sel_hi(0)
let Inst{60} = !if(!and(P.HasSrc1, P.HasOpSel), src1_modifiers{3}, ?); // op_sel_hi(1)
let Inst{61} = !if(P.HasSrc0Mods, src0_modifiers{0}, 0); // neg (lo)
let Inst{62} = !if(P.HasSrc1Mods, src1_modifiers{0}, 0); // neg (lo)
let Inst{63} = !if(P.HasSrc2Mods, src2_modifiers{0}, 0); // neg (lo)
}
class VOP3Pe_MAI <bits<7> op, VOPProfile P, bit acc_cd = 0> : Enc64 {
bits<8> vdst;
bits<10> src0;
bits<10> src1;
bits<9> src2;
bits<3> blgp;
bits<3> cbsz;
bits<4> abid;
let Inst{7-0} = vdst;
let Inst{10-8} = !if(P.HasSrc1, cbsz, 0);
let Inst{14-11} = !if(P.HasSrc1, abid, 0);
let Inst{15} = acc_cd;
let Inst{22-16} = op;
let Inst{31-23} = 0x1a7; //encoding
let Inst{40-32} = !if(P.HasSrc0, src0{8-0}, 0);
let Inst{49-41} = !if(P.HasSrc1, src1{8-0}, 0);
let Inst{58-50} = !if(P.HasSrc2, src2, 0);
let Inst{59} = !if(P.HasSrc0, src0{9}, 0); // acc(0)
let Inst{60} = !if(P.HasSrc1, src1{9}, 0); // acc(1)
let Inst{63-61} = !if(P.HasSrc1, blgp, 0);
}
class VOP3Pe_gfx10 <bits<7> op, VOPProfile P> : VOP3Pe<op, P> {
let Inst{31-23} = 0x198; //encoding
}
class VOP3be_gfx6_gfx7<bits<9> op, VOPProfile p> : VOP3be<p> {
let Inst{25-17} = op;
}
class VOP3be_gfx10<bits<10> op, VOPProfile p> : VOP3be<p> {
bits<1> clamp;
let Inst{15} = !if(p.HasClamp, clamp{0}, 0);
let Inst{25-16} = op;
let Inst{31-26} = 0x35;
}
class VOP3be_vi <bits<10> op, VOPProfile P> : VOP3be<P> {
bits<1> clamp;
let Inst{25-16} = op;
let Inst{15} = !if(P.HasClamp, clamp{0}, 0);
}
def SDWA {
// sdwa_sel
int BYTE_0 = 0;
int BYTE_1 = 1;
int BYTE_2 = 2;
int BYTE_3 = 3;
int WORD_0 = 4;
int WORD_1 = 5;
int DWORD = 6;
// dst_unused
int UNUSED_PAD = 0;
int UNUSED_SEXT = 1;
int UNUSED_PRESERVE = 2;
}
class VOP_SDWAe<VOPProfile P> : Enc64 {
bits<8> src0;
bits<3> src0_sel;
bits<2> src0_modifiers; // float: {abs,neg}, int {sext}
bits<3> src1_sel;
bits<2> src1_modifiers;
bits<3> dst_sel;
bits<2> dst_unused;
bits<1> clamp;
let Inst{39-32} = !if(P.HasSrc0, src0{7-0}, 0);
let Inst{42-40} = !if(P.EmitDstSel, dst_sel{2-0}, ?);
let Inst{44-43} = !if(P.EmitDstSel, dst_unused{1-0}, ?);
let Inst{45} = !if(P.HasSDWAClamp, clamp{0}, 0);
let Inst{50-48} = !if(P.HasSrc0, src0_sel{2-0}, 0);
let Inst{51} = !if(P.HasSrc0IntMods, src0_modifiers{0}, 0);
let Inst{53-52} = !if(P.HasSrc0FloatMods, src0_modifiers{1-0}, 0);
let Inst{58-56} = !if(P.HasSrc1, src1_sel{2-0}, 0);
let Inst{59} = !if(P.HasSrc1IntMods, src1_modifiers{0}, 0);
let Inst{61-60} = !if(P.HasSrc1FloatMods, src1_modifiers{1-0}, 0);
}
// GFX9 adds two features to SDWA:
// 1. Add 3 fields to the SDWA microcode word: S0, S1 and OMOD.
// a. S0 and S1 indicate that source 0 and 1 respectively are SGPRs rather
// than VGPRs (at most 1 can be an SGPR);
// b. OMOD is the standard output modifier (result *2, *4, /2)
// 2. Add a new version of the SDWA microcode word for VOPC: SDWAB. This
// replaces OMOD and the dest fields with SD and SDST (SGPR destination)
// field.
// a. When SD=1, the SDST is used as the destination for the compare result;
// b. When SD=0, VCC is used.
//
// In GFX9, V_MAC_F16, V_MAC_F32 opcodes cannot be used with SDWA
// gfx9 SDWA basic encoding
class VOP_SDWA9e<VOPProfile P> : Enc64 {
bits<9> src0; // {src0_sgpr{0}, src0{7-0}}
bits<3> src0_sel;
bits<2> src0_modifiers; // float: {abs,neg}, int {sext}
bits<3> src1_sel;
bits<2> src1_modifiers;
bits<1> src1_sgpr;
let Inst{39-32} = !if(P.HasSrc0, src0{7-0}, 0);
let Inst{50-48} = !if(P.HasSrc0, src0_sel{2-0}, 0);
let Inst{51} = !if(P.HasSrc0IntMods, src0_modifiers{0}, 0);
let Inst{53-52} = !if(P.HasSrc0FloatMods, src0_modifiers{1-0}, 0);
let Inst{55} = !if(P.HasSrc0, src0{8}, 0);
let Inst{58-56} = !if(P.HasSrc1, src1_sel{2-0}, 0);
let Inst{59} = !if(P.HasSrc1IntMods, src1_modifiers{0}, 0);
let Inst{61-60} = !if(P.HasSrc1FloatMods, src1_modifiers{1-0}, 0);
let Inst{63} = 0; // src1_sgpr - should be specified in subclass
}
// gfx9 SDWA-A
class VOP_SDWA9Ae<VOPProfile P> : VOP_SDWA9e<P> {
bits<3> dst_sel;
bits<2> dst_unused;
bits<1> clamp;
bits<2> omod;
let Inst{42-40} = !if(P.EmitDstSel, dst_sel{2-0}, ?);
let Inst{44-43} = !if(P.EmitDstSel, dst_unused{1-0}, ?);
let Inst{45} = !if(P.HasSDWAClamp, clamp{0}, 0);
let Inst{47-46} = !if(P.HasSDWAOMod, omod{1-0}, 0);
}
// gfx9 SDWA-B
class VOP_SDWA9Be<VOPProfile P> : VOP_SDWA9e<P> {
bits<8> sdst; // {vcc_sdst{0}, sdst{6-0}}
let Inst{46-40} = !if(P.EmitDst, sdst{6-0}, ?);
let Inst{47} = !if(P.EmitDst, sdst{7}, 0);
}
class VOP_SDWA_Pseudo <string opName, VOPProfile P, list<dag> pattern=[]> :
InstSI <P.OutsSDWA, P.InsSDWA, "", pattern>,
VOP <opName>,
SIMCInstr <opName#"_sdwa", SIEncodingFamily.NONE> {
let isPseudo = 1;
let isCodeGenOnly = 1;
let UseNamedOperandTable = 1;
string Mnemonic = opName;
string AsmOperands = P.AsmSDWA;
string AsmOperands9 = P.AsmSDWA9;
let Size = 8;
let mayLoad = 0;
let mayStore = 0;
let hasSideEffects = 0;
let VALU = 1;
let SDWA = 1;
let ReadsModeReg = !or(isFloatType<P.DstVT>.ret, isFloatType<P.Src0VT>.ret);
let mayRaiseFPException = ReadsModeReg;
let Uses = !if(ReadsModeReg, [MODE, EXEC], [EXEC]);
let SubtargetPredicate = HasSDWA;
let AssemblerPredicate = HasSDWA;
let AsmVariantName = !if(P.HasExtSDWA, AMDGPUAsmVariants.SDWA,
AMDGPUAsmVariants.Disable);
let DecoderNamespace = "SDWA";
VOPProfile Pfl = P;
}
class VOP_SDWA_Real <VOP_SDWA_Pseudo ps> :
InstSI <ps.OutOperandList, ps.InOperandList, ps.Mnemonic # ps.AsmOperands, []>,
SIMCInstr <ps.PseudoInstr, SIEncodingFamily.SDWA> {
let VALU = 1;
let SDWA = 1;
let isPseudo = 0;
let isCodeGenOnly = 0;
let Defs = ps.Defs;
let Uses = ps.Uses;
let hasSideEffects = ps.hasSideEffects;
let Constraints = ps.Constraints;
let DisableEncoding = ps.DisableEncoding;
// Copy relevant pseudo op flags
let SubtargetPredicate = ps.SubtargetPredicate;
let AssemblerPredicate = ps.AssemblerPredicate;
let AsmMatchConverter = ps.AsmMatchConverter;
let AsmVariantName = ps.AsmVariantName;
let UseNamedOperandTable = ps.UseNamedOperandTable;
let DecoderNamespace = ps.DecoderNamespace;
let Constraints = ps.Constraints;
let DisableEncoding = ps.DisableEncoding;
let TSFlags = ps.TSFlags;
let SchedRW = ps.SchedRW;
let mayLoad = ps.mayLoad;
let mayStore = ps.mayStore;
let TRANS = ps.TRANS;
}
class Base_VOP_SDWA9_Real <VOP_SDWA_Pseudo ps> :
InstSI <ps.OutOperandList, ps.InOperandList, ps.Mnemonic # ps.AsmOperands9, []> {
let VALU = 1;
let SDWA = 1;
let isPseudo = 0;
let isCodeGenOnly = 0;
let Defs = ps.Defs;
let Uses = ps.Uses;
let hasSideEffects = ps.hasSideEffects;
let Constraints = ps.Constraints;
let DisableEncoding = ps.DisableEncoding;
let SubtargetPredicate = HasSDWA9;
let AssemblerPredicate = HasSDWA9;
let AsmVariantName = !if(ps.Pfl.HasExtSDWA9, AMDGPUAsmVariants.SDWA9,
AMDGPUAsmVariants.Disable);
let DecoderNamespace = "SDWA9";
// Copy relevant pseudo op flags
let AsmMatchConverter = ps.AsmMatchConverter;
let UseNamedOperandTable = ps.UseNamedOperandTable;
let Constraints = ps.Constraints;
let DisableEncoding = ps.DisableEncoding;
let TSFlags = ps.TSFlags;
let SchedRW = ps.SchedRW;
let mayLoad = ps.mayLoad;
let mayStore = ps.mayStore;
let TRANS = ps.TRANS;
}
class VOP_SDWA9_Real <VOP_SDWA_Pseudo ps> :
Base_VOP_SDWA9_Real <ps >,
SIMCInstr <ps.PseudoInstr, SIEncodingFamily.SDWA9>;
class Base_VOP_SDWA10_Real<VOP_SDWA_Pseudo ps> : Base_VOP_SDWA9_Real<ps> {
let SubtargetPredicate = HasSDWA10;
let AssemblerPredicate = HasSDWA10;
let DecoderNamespace = "SDWA10";
}
class VOP_SDWA10_Real<VOP_SDWA_Pseudo ps> :
Base_VOP_SDWA10_Real<ps>, SIMCInstr<ps.PseudoInstr, SIEncodingFamily.SDWA10>;
class VOP_DPPe<VOPProfile P, bit IsDPP16=0> : Enc64 {
bits<2> src0_modifiers;
bits<8> src0;
bits<2> src1_modifiers;
bits<9> dpp_ctrl;
bits<1> bound_ctrl;
bits<4> bank_mask;
bits<4> row_mask;
bit fi;
let Inst{39-32} = !if(P.HasSrc0, src0{7-0}, 0);
let Inst{48-40} = dpp_ctrl;
let Inst{50} = !if(IsDPP16, fi, ?);
let Inst{51} = bound_ctrl;
let Inst{52} = !if(P.HasSrc0Mods, src0_modifiers{0}, 0); // src0_neg
let Inst{53} = !if(P.HasSrc0Mods, src0_modifiers{1}, 0); // src0_abs
let Inst{54} = !if(P.HasSrc1Mods, src1_modifiers{0}, 0); // src1_neg
let Inst{55} = !if(P.HasSrc1Mods, src1_modifiers{1}, 0); // src1_abs
let Inst{59-56} = bank_mask;
let Inst{63-60} = row_mask;
}
class VOP_DPP_Pseudo <string OpName, VOPProfile P, list<dag> pattern=[]> :
InstSI <P.OutsDPP, P.InsDPP, OpName#P.AsmDPP, pattern>,
VOP <OpName>,
SIMCInstr <OpName#"_dpp", SIEncodingFamily.NONE> {
let isPseudo = 1;
let isCodeGenOnly = 1;
let mayLoad = 0;
let mayStore = 0;
let hasSideEffects = 0;
let UseNamedOperandTable = 1;
let VALU = 1;
let DPP = 1;
let Size = 8;
let ReadsModeReg = !or(isFloatType<P.DstVT>.ret, isFloatType<P.Src0VT>.ret);
let mayRaiseFPException = ReadsModeReg;
let Uses = !if(ReadsModeReg, [MODE, EXEC], [EXEC]);
let isConvergent = 1;
string Mnemonic = OpName;
string AsmOperands = P.AsmDPP;
let AsmMatchConverter = !if(P.HasModifiers, "cvtDPP", "");
let SubtargetPredicate = !if(P.HasExt64BitDPP, Has64BitDPP, HasDPP);
let AssemblerPredicate = !if(P.HasExt64BitDPP, Has64BitDPP, HasDPP);
let AsmVariantName = !if(P.HasExtDPP, AMDGPUAsmVariants.DPP,
AMDGPUAsmVariants.Disable);
let Constraints = !if(P.NumSrcArgs, P.TieRegDPP # " = $vdst", "");
let DisableEncoding = !if(P.NumSrcArgs, P.TieRegDPP, "");
let DecoderNamespace = "DPP";
VOPProfile Pfl = P;
}
class VOP_DPP_Real <VOP_DPP_Pseudo ps, int EncodingFamily> :
InstSI <ps.OutOperandList, ps.InOperandList, ps.Mnemonic # ps.AsmOperands, []>,
SIMCInstr <ps.PseudoInstr, EncodingFamily> {
let VALU = 1;
let DPP = 1;
let isPseudo = 0;
let isCodeGenOnly = 0;
let Defs = ps.Defs;
let Uses = ps.Uses;
let hasSideEffects = ps.hasSideEffects;
let Constraints = ps.Constraints;
let DisableEncoding = ps.DisableEncoding;
// Copy relevant pseudo op flags
let isConvergent = ps.isConvergent;
let SubtargetPredicate = ps.SubtargetPredicate;
let AssemblerPredicate = ps.AssemblerPredicate;
let AsmMatchConverter = ps.AsmMatchConverter;
let AsmVariantName = ps.AsmVariantName;
let UseNamedOperandTable = ps.UseNamedOperandTable;
let DecoderNamespace = ps.DecoderNamespace;
let Constraints = ps.Constraints;
let DisableEncoding = ps.DisableEncoding;
let TSFlags = ps.TSFlags;
let SchedRW = ps.SchedRW;
let mayLoad = ps.mayLoad;
let mayStore = ps.mayStore;
let TRANS = ps.TRANS;
}
class VOP_DPP <string OpName, VOPProfile P, bit IsDPP16,
dag InsDPP = !if(IsDPP16, P.InsDPP16, P.InsDPP),
string AsmDPP = !if(IsDPP16, P.AsmDPP16, P.AsmDPP)> :
InstSI <P.OutsDPP, InsDPP, OpName#AsmDPP, []>,
VOP_DPPe<P, IsDPP16> {
let mayLoad = 0;
let mayStore = 0;
let hasSideEffects = 0;
let UseNamedOperandTable = 1;
let VALU = 1;
let DPP = 1;
let Size = 8;
let AsmMatchConverter = !if(P.HasModifiers, "cvtDPP", "");
let SubtargetPredicate = !if(P.HasExt64BitDPP, Has64BitDPP, HasDPP);
let AssemblerPredicate = !if(P.HasExt64BitDPP, Has64BitDPP, HasDPP);
let AsmVariantName = !if(P.HasExtDPP, AMDGPUAsmVariants.DPP,
AMDGPUAsmVariants.Disable);
let Constraints = !if(P.NumSrcArgs, P.TieRegDPP # " = $vdst", "");
let DisableEncoding = !if(P.NumSrcArgs, P.TieRegDPP, "");
let DecoderNamespace = "DPP";
}
class VOP_DPP8e<VOPProfile P> : Enc64 {
bits<8> src0;
bits<24> dpp8;
bits<9> fi;
let Inst{39-32} = !if(P.HasSrc0, src0{7-0}, 0);
let Inst{63-40} = dpp8{23-0};
}
class VOP_DPP8<string OpName, VOPProfile P> :
InstSI<P.OutsDPP8, P.InsDPP8, OpName#P.AsmDPP8, []>,
VOP_DPP8e<P> {
let mayLoad = 0;
let mayStore = 0;
let hasSideEffects = 0;
let UseNamedOperandTable = 1;
let VALU = 1;
let DPP = 1;
let Size = 8;
let AsmMatchConverter = "cvtDPP8";
let SubtargetPredicate = HasDPP8;
let AssemblerPredicate = HasDPP8;
let AsmVariantName = !if(P.HasExt, AMDGPUAsmVariants.DPP,
AMDGPUAsmVariants.Disable);
let Constraints = !if(P.NumSrcArgs, P.TieRegDPP # " = $vdst", "");
let DisableEncoding = !if(P.NumSrcArgs, P.TieRegDPP, "");
}
def DPP8Mode {
int FI_0 = 0xE9;
int FI_1 = 0xEA;
}
class getNumNodeArgs<SDPatternOperator Op> {
SDNode N = !cast<SDNode>(Op);
SDTypeProfile TP = N.TypeProfile;
int ret = TP.NumOperands;
}
class getDivergentFrag<SDPatternOperator Op> {
assert !or(!isa<SDNode>(Op), !isa<PatFrags>(Op)), "Expected SDNode or PatFrags";
int NumSrcArgs = !if(!isa<SDNode>(Op), getNumNodeArgs<Op>.ret,
!size(!cast<PatFrags>(Op).Operands));
PatFrag ret = PatFrag <
!if(!eq(NumSrcArgs, 1),
(ops node:$src0),
!if(!eq(NumSrcArgs, 2),
(ops node:$src0, node:$src1),
(ops node:$src0, node:$src1, node:$src2))),
!if(!eq(NumSrcArgs, 1),
(Op $src0),
!if(!eq(NumSrcArgs, 2),
(Op $src0, $src1),
(Op $src0, $src1, $src2))),
[{ return N->isDivergent(); }]
>;
}
class VOPPatGen<SDPatternOperator Op, VOPProfile P> {
PatFrag Operator = getDivergentFrag < Op >.ret;
dag Ins = !foreach(tmp, P.Ins32, !subst(ins, Operator,
!subst(P.Src0RC32, P.Src0VT,
!subst(P.Src1RC32, P.Src1VT, tmp))));
dag Outs = !foreach(tmp, P.Outs32, !subst(outs, set,
!subst(P.DstRC, P.DstVT, tmp)));
list<dag> ret = [!con(Outs, (set Ins))];
}
class VOPPatOrNull<SDPatternOperator Op, VOPProfile P> {
list<dag> ret = !if(!ne(P.NeedPatGen,PatGenMode.NoPattern), VOPPatGen<Op, P>.ret, []);
}
class DivergentFragOrOp<SDPatternOperator Op, VOPProfile P> {
SDPatternOperator ret = !if(!eq(P.NeedPatGen,PatGenMode.Pattern),
!if(!isa<SDNode>(Op), getDivergentFrag<Op>.ret, Op), Op);
}
class getVSrcOp<ValueType vt> {
RegisterOperand ret = !if(!eq(vt.Size, 32), VSrc_b32, VSrc_b16);
}
// Class for binary integer operations with the clamp bit set for saturation
// TODO: Add sub with negated inline constant pattern.
class VOPBinOpClampPat<SDPatternOperator node, Instruction inst, ValueType vt> :
GCNPat<(node vt:$src0, vt:$src1),
(inst getVSrcOp<vt>.ret:$src0, getVSrcOp<vt>.ret:$src1,
DSTCLAMP.ENABLE)
>;
include "VOPCInstructions.td"
include "VOP1Instructions.td"
include "VOP2Instructions.td"
include "VOP3Instructions.td"
include "VOP3PInstructions.td"
class VOPInfoTable <string Format> : GenericTable {
let FilterClass = Format # "_Real";
let CppTypeName = "VOPInfo";
let Fields = ["Opcode", "IsSingle"];
let PrimaryKey = ["Opcode"];
let PrimaryKeyName = "get" # Format # "OpcodeHelper";
}
def VOP1InfoTable : VOPInfoTable<"VOP1">;
def VOP2InfoTable : VOPInfoTable<"VOP2">;
def VOP3InfoTable : VOPInfoTable<"VOP3">;