llvm/lib/Target/RISCV/RISCVInstrFormats.td - llvm-project - Git at Google

 //===-- RISCVInstrFormats.td - RISCV Instruction Formats ---*- tablegen -*-===//
 //
 // 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
 //
 //===----------------------------------------------------------------------===//

 //===----------------------------------------------------------------------===//
 //
 //  These instruction format definitions are structured to match the
 //  description in the RISC-V User-Level ISA specification as closely as
 //  possible. For instance, the specification describes instructions with the
 //  MSB (31st bit) on the left and the LSB (0th bit) on the right. This is
 //  reflected in the order of parameters to each instruction class.
 //
 //  One area of divergence is in the description of immediates. The
 //  specification describes immediate encoding in terms of bit-slicing
 //  operations on the logical value represented. The immediate argument to
 //  these instruction formats instead represents the bit sequence that will be
 //  inserted into the instruction. e.g. although JAL's immediate is logically
 //  a 21-bit value (where the LSB is always zero), we describe it as an imm20
 //  to match how it is encoded.
 //
 //===----------------------------------------------------------------------===//

 // Format specifies the encoding used by the instruction. This is used by
 // RISCVMCCodeEmitter to determine which form of fixup to use. These
 // definitions must be kept in-sync with RISCVBaseInfo.h.
 class InstFormat<bits<5> val> {
   bits<5> Value = val;
 }
 def InstFormatPseudo : InstFormat<0>;
 def InstFormatR      : InstFormat<1>;
 def InstFormatR4     : InstFormat<2>;
 def InstFormatI      : InstFormat<3>;
 def InstFormatS      : InstFormat<4>;
 def InstFormatB      : InstFormat<5>;
 def InstFormatU      : InstFormat<6>;
 def InstFormatJ      : InstFormat<7>;
 def InstFormatCR     : InstFormat<8>;
 def InstFormatCI     : InstFormat<9>;
 def InstFormatCSS    : InstFormat<10>;
 def InstFormatCIW    : InstFormat<11>;
 def InstFormatCL     : InstFormat<12>;
 def InstFormatCS     : InstFormat<13>;
 def InstFormatCA     : InstFormat<14>;
 def InstFormatCB     : InstFormat<15>;
 def InstFormatCJ     : InstFormat<16>;
 def InstFormatOther  : InstFormat<17>;

 class RISCVVConstraint<bits<3> val> {
   bits<3> Value = val;
 }
 def NoConstraint  : RISCVVConstraint<0b000>;
 def VS2Constraint : RISCVVConstraint<0b001>;
 def VS1Constraint : RISCVVConstraint<0b010>;
 def VMConstraint  : RISCVVConstraint<0b100>;

 // Illegal instructions:
 //
 // * The destination vector register group for a masked vector instruction
 // cannot overlap the source mask register (v0), unless the destination vector
 // register is being written with a mask value (e.g., comparisons) or the
 // scalar result of a reduction.
 //
 // * Widening: The destination EEW is greater than the source EEW, the source
 // EMUL is at least 1. The destination vector register group cannot overlap
 // with the source vector register groups besides the highest-numbered part of
 // the destination register group.
 //
 // * Narrowing: The destination EEW is smaller than the source EEW. The
 // destination vector register group cannot overlap with the source vector
 // register groups besides the lowest-numbered part of the source register
 // group.
 //
 // * vmsbf.m/vmsif.m/vmsof.m: The destination register cannot overlap the
 // source register and, if masked, cannot overlap the mask register ('v0').
 //
 // * viota: The destination register cannot overlap the source register and,
 // if masked, cannot overlap the mask register ('v0').
 //
 // * v[f]slide[1]up: The destination vector register group for vslideup cannot
 // overlap the source vector register group.
 //
 // * vrgather: The destination vector register group cannot overlap with the
 // source vector register groups.
 //
 // * vcompress: The destination vector register group cannot overlap the
 // source vector register group or the source mask register
 def WidenV       : RISCVVConstraint<!or(VS2Constraint.Value,
                                         VS1Constraint.Value,
                                         VMConstraint.Value)>;
 def WidenW       : RISCVVConstraint<!or(VS1Constraint.Value,
                                         VMConstraint.Value)>;
 def WidenCvt     : RISCVVConstraint<!or(VS2Constraint.Value,
                                         VMConstraint.Value)>;
 def Iota         : RISCVVConstraint<!or(VS2Constraint.Value,
                                         VMConstraint.Value)>;
 def SlideUp      : RISCVVConstraint<!or(VS2Constraint.Value,
                                         VMConstraint.Value)>;
 def Vrgather     : RISCVVConstraint<!or(VS2Constraint.Value,
                                         VS1Constraint.Value,
                                         VMConstraint.Value)>;
 def Vcompress    : RISCVVConstraint<!or(VS2Constraint.Value,
                                         VS1Constraint.Value)>;

 // The following opcode names match those given in Table 19.1 in the
 // RISC-V User-level ISA specification ("RISC-V base opcode map").
 class RISCVOpcode<bits<7> val> {
   bits<7> Value = val;
 }
 def OPC_LOAD      : RISCVOpcode<0b0000011>;
 def OPC_LOAD_FP   : RISCVOpcode<0b0000111>;
 def OPC_MISC_MEM  : RISCVOpcode<0b0001111>;
 def OPC_OP_IMM    : RISCVOpcode<0b0010011>;
 def OPC_AUIPC     : RISCVOpcode<0b0010111>;
 def OPC_OP_IMM_32 : RISCVOpcode<0b0011011>;
 def OPC_STORE     : RISCVOpcode<0b0100011>;
 def OPC_STORE_FP  : RISCVOpcode<0b0100111>;
 def OPC_AMO       : RISCVOpcode<0b0101111>;
 def OPC_OP        : RISCVOpcode<0b0110011>;
 def OPC_LUI       : RISCVOpcode<0b0110111>;
 def OPC_OP_32     : RISCVOpcode<0b0111011>;
 def OPC_MADD      : RISCVOpcode<0b1000011>;
 def OPC_MSUB      : RISCVOpcode<0b1000111>;
 def OPC_NMSUB     : RISCVOpcode<0b1001011>;
 def OPC_NMADD     : RISCVOpcode<0b1001111>;
 def OPC_OP_FP     : RISCVOpcode<0b1010011>;
 def OPC_OP_V      : RISCVOpcode<0b1010111>;
 def OPC_BRANCH    : RISCVOpcode<0b1100011>;
 def OPC_JALR      : RISCVOpcode<0b1100111>;
 def OPC_JAL       : RISCVOpcode<0b1101111>;
 def OPC_SYSTEM    : RISCVOpcode<0b1110011>;

 class RVInst<dag outs, dag ins, string opcodestr, string argstr,
              list<dag> pattern, InstFormat format>
     : Instruction {
   field bits<32> Inst;
   // SoftFail is a field the disassembler can use to provide a way for
   // instructions to not match without killing the whole decode process. It is
   // mainly used for ARM, but Tablegen expects this field to exist or it fails
   // to build the decode table.
   field bits<32> SoftFail = 0;
   let Size = 4;

   bits<7> Opcode = 0;

   let Inst{6-0} = Opcode;

   let Namespace = "RISCV";

   dag OutOperandList = outs;
   dag InOperandList = ins;
   let AsmString = opcodestr # "\t" # argstr;
   let Pattern = pattern;

   let TSFlags{4-0} = format.Value;

   // Defaults
   RISCVVConstraint RVVConstraint = NoConstraint;
   let TSFlags{7-5} = RVVConstraint.Value;

   bits<3> VLMul = 0;
   let TSFlags{10-8} = VLMul;

   bit HasDummyMask = 0;
   let TSFlags{11} = HasDummyMask;

   bit ForceTailAgnostic = false;
   let TSFlags{12} = ForceTailAgnostic;

   bit HasMergeOp = 0;
   let TSFlags{13} = HasMergeOp;

   bit HasSEWOp = 0;
   let TSFlags{14} = HasSEWOp;

   bit HasVLOp = 0;
   let TSFlags{15} = HasVLOp;

   bit HasVecPolicyOp = 0;
   let TSFlags{16} = HasVecPolicyOp;

   bit IsRVVWideningReduction = 0;
   let TSFlags{17} =  IsRVVWideningReduction;
 }

 // Pseudo instructions
 class Pseudo<dag outs, dag ins, list<dag> pattern, string opcodestr = "", string argstr = "">
     : RVInst<outs, ins, opcodestr, argstr, pattern, InstFormatPseudo>,
       Sched<[]> {
   let isPseudo = 1;
   let isCodeGenOnly = 1;
 }

 // Pseudo load instructions.
 class PseudoLoad<string opcodestr, RegisterClass rdty = GPR>
     : Pseudo<(outs rdty:$rd), (ins bare_symbol:$addr), [], opcodestr, "$rd, $addr"> {
   let hasSideEffects = 0;
   let mayLoad = 1;
   let mayStore = 0;
   let isCodeGenOnly = 0;
   let isAsmParserOnly = 1;
 }

 class PseudoFloatLoad<string opcodestr, RegisterClass rdty = GPR>
     : Pseudo<(outs GPR:$tmp, rdty:$rd), (ins bare_symbol:$addr), [], opcodestr, "$rd, $addr, $tmp"> {
   let hasSideEffects = 0;
   let mayLoad = 1;
   let mayStore = 0;
   let isCodeGenOnly = 0;
   let isAsmParserOnly = 1;
 }

 // Pseudo store instructions.
 class PseudoStore<string opcodestr, RegisterClass rsty = GPR>
     : Pseudo<(outs GPR:$tmp), (ins rsty:$rs, bare_symbol:$addr), [], opcodestr, "$rs, $addr, $tmp"> {
   let hasSideEffects = 0;
   let mayLoad = 0;
   let mayStore = 1;
   let isCodeGenOnly = 0;
   let isAsmParserOnly = 1;
 }

 // Instruction formats are listed in the order they appear in the RISC-V
 // instruction set manual (R, I, S, B, U, J) with sub-formats (e.g. RVInstR4,
 // RVInstRAtomic) sorted alphabetically.

 class RVInstR<bits<7> funct7, bits<3> funct3, RISCVOpcode opcode, dag outs,
               dag ins, string opcodestr, string argstr>
     : RVInst<outs, ins, opcodestr, argstr, [], InstFormatR> {
   bits<5> rs2;
   bits<5> rs1;
   bits<5> rd;

   let Inst{31-25} = funct7;
   let Inst{24-20} = rs2;
   let Inst{19-15} = rs1;
   let Inst{14-12} = funct3;
   let Inst{11-7} = rd;
   let Opcode = opcode.Value;
 }

 class RVInstR4<bits<2> funct2, bits<3> funct3, RISCVOpcode opcode, dag outs,
                dag ins, string opcodestr, string argstr>
     : RVInst<outs, ins, opcodestr, argstr, [], InstFormatR4> {
   bits<5> rs3;
   bits<5> rs2;
   bits<5> rs1;
   bits<5> rd;

   let Inst{31-27} = rs3;
   let Inst{26-25} = funct2;
   let Inst{24-20} = rs2;
   let Inst{19-15} = rs1;
   let Inst{14-12} = funct3;
   let Inst{11-7} = rd;
   let Opcode = opcode.Value;
 }

 class RVInstR4Frm<bits<2> funct2, RISCVOpcode opcode, dag outs, dag ins,
                   string opcodestr, string argstr>
     : RVInst<outs, ins, opcodestr, argstr, [], InstFormatR4> {
   bits<5> rs3;
   bits<5> rs2;
   bits<5> rs1;
   bits<3> funct3;
   bits<5> rd;

   let Inst{31-27} = rs3;
   let Inst{26-25} = funct2;
   let Inst{24-20} = rs2;
   let Inst{19-15} = rs1;
   let Inst{14-12} = funct3;
   let Inst{11-7} = rd;
   let Opcode = opcode.Value;
 }

 class RVInstRAtomic<bits<5> funct5, bit aq, bit rl, bits<3> funct3,
                     RISCVOpcode opcode, dag outs, dag ins, string opcodestr,
                     string argstr>
     : RVInst<outs, ins, opcodestr, argstr, [], InstFormatR> {
   bits<5> rs2;
   bits<5> rs1;
   bits<5> rd;

   let Inst{31-27} = funct5;
   let Inst{26} = aq;
   let Inst{25} = rl;
   let Inst{24-20} = rs2;
   let Inst{19-15} = rs1;
   let Inst{14-12} = funct3;
   let Inst{11-7} = rd;
   let Opcode = opcode.Value;
 }

 class RVInstRFrm<bits<7> funct7, RISCVOpcode opcode, dag outs, dag ins,
                  string opcodestr, string argstr>
     : RVInst<outs, ins, opcodestr, argstr, [], InstFormatR> {
   bits<5> rs2;
   bits<5> rs1;
   bits<3> funct3;
   bits<5> rd;

   let Inst{31-25} = funct7;
   let Inst{24-20} = rs2;
   let Inst{19-15} = rs1;
   let Inst{14-12} = funct3;
   let Inst{11-7} = rd;
   let Opcode = opcode.Value;
 }

 class RVInstI<bits<3> funct3, RISCVOpcode opcode, dag outs, dag ins,
               string opcodestr, string argstr>
     : RVInst<outs, ins, opcodestr, argstr, [], InstFormatI> {
   bits<12> imm12;
   bits<5> rs1;
   bits<5> rd;

   let Inst{31-20} = imm12;
   let Inst{19-15} = rs1;
   let Inst{14-12} = funct3;
   let Inst{11-7} = rd;
   let Opcode = opcode.Value;
 }

 class RVInstIShift<bits<5> imm11_7, bits<3> funct3, RISCVOpcode opcode,
                    dag outs, dag ins, string opcodestr, string argstr>
     : RVInst<outs, ins, opcodestr, argstr, [], InstFormatI> {
   bits<6> shamt;
   bits<5> rs1;
   bits<5> rd;

   let Inst{31-27} = imm11_7;
   let Inst{26} = 0;
   let Inst{25-20} = shamt;
   let Inst{19-15} = rs1;
   let Inst{14-12} = funct3;
   let Inst{11-7} = rd;
   let Opcode = opcode.Value;
 }

 class RVInstIShiftW<bits<7> imm11_5, bits<3> funct3, RISCVOpcode opcode,
                     dag outs, dag ins, string opcodestr, string argstr>
     : RVInst<outs, ins, opcodestr, argstr, [], InstFormatI> {
   bits<5> shamt;
   bits<5> rs1;
   bits<5> rd;

   let Inst{31-25} = imm11_5;
   let Inst{24-20} = shamt;
   let Inst{19-15} = rs1;
   let Inst{14-12} = funct3;
   let Inst{11-7} = rd;
   let Opcode = opcode.Value;
 }

 class RVInstS<bits<3> funct3, RISCVOpcode opcode, dag outs, dag ins,
               string opcodestr, string argstr>
     : RVInst<outs, ins, opcodestr, argstr, [], InstFormatS> {
   bits<12> imm12;
   bits<5> rs2;
   bits<5> rs1;

   let Inst{31-25} = imm12{11-5};
   let Inst{24-20} = rs2;
   let Inst{19-15} = rs1;
   let Inst{14-12} = funct3;
   let Inst{11-7} = imm12{4-0};
   let Opcode = opcode.Value;
 }

 class RVInstB<bits<3> funct3, RISCVOpcode opcode, dag outs, dag ins,
               string opcodestr, string argstr>
     : RVInst<outs, ins, opcodestr, argstr, [], InstFormatB> {
   bits<12> imm12;
   bits<5> rs2;
   bits<5> rs1;

   let Inst{31} = imm12{11};
   let Inst{30-25} = imm12{9-4};
   let Inst{24-20} = rs2;
   let Inst{19-15} = rs1;
   let Inst{14-12} = funct3;
   let Inst{11-8} = imm12{3-0};
   let Inst{7} = imm12{10};
   let Opcode = opcode.Value;
 }

 class RVInstU<RISCVOpcode opcode, dag outs, dag ins, string opcodestr,
               string argstr>
     : RVInst<outs, ins, opcodestr, argstr, [], InstFormatU> {
   bits<20> imm20;
   bits<5> rd;

   let Inst{31-12} = imm20;
   let Inst{11-7} = rd;
   let Opcode = opcode.Value;
 }

 class RVInstJ<RISCVOpcode opcode, dag outs, dag ins, string opcodestr,
               string argstr>
     : RVInst<outs, ins, opcodestr, argstr, [], InstFormatJ> {
   bits<20> imm20;
   bits<5> rd;

   let Inst{31} = imm20{19};
   let Inst{30-21} = imm20{9-0};
   let Inst{20} = imm20{10};
   let Inst{19-12} = imm20{18-11};
   let Inst{11-7} = rd;
   let Opcode = opcode.Value;
 }

 //===----------------------------------------------------------------------===//
 // Instruction classes for .insn directives
 //===----------------------------------------------------------------------===//

 class DirectiveInsnR<dag outs, dag ins, string argstr>
   : RVInst<outs, ins, "", "", [], InstFormatR> {
   bits<7> opcode;
   bits<7> funct7;
   bits<3> funct3;

   bits<5> rs2;
   bits<5> rs1;
   bits<5> rd;

   let Inst{31-25} = funct7;
   let Inst{24-20} = rs2;
   let Inst{19-15} = rs1;
   let Inst{14-12} = funct3;
   let Inst{11-7} = rd;
   let Opcode = opcode;

   let AsmString = ".insn r " # argstr;
 }

 class DirectiveInsnR4<dag outs, dag ins, string argstr>
   : RVInst<outs, ins, "", "", [], InstFormatR4> {
   bits<7> opcode;
   bits<2> funct2;
   bits<3> funct3;

   bits<5> rs3;
   bits<5> rs2;
   bits<5> rs1;
   bits<5> rd;

   let Inst{31-27} = rs3;
   let Inst{26-25} = funct2;
   let Inst{24-20} = rs2;
   let Inst{19-15} = rs1;
   let Inst{14-12} = funct3;
   let Inst{11-7} = rd;
   let Opcode = opcode;

   let AsmString = ".insn r4 " # argstr;
 }

 class DirectiveInsnI<dag outs, dag ins, string argstr>
   : RVInst<outs, ins, "", "", [], InstFormatI> {
   bits<7> opcode;
   bits<3> funct3;

   bits<12> imm12;
   bits<5> rs1;
   bits<5> rd;

   let Inst{31-20} = imm12;
   let Inst{19-15} = rs1;
   let Inst{14-12} = funct3;
   let Inst{11-7} = rd;
   let Opcode = opcode;

   let AsmString = ".insn i " # argstr;
 }

 class DirectiveInsnS<dag outs, dag ins, string argstr>
   : RVInst<outs, ins, "", "", [], InstFormatS> {
   bits<7> opcode;
   bits<3> funct3;

   bits<12> imm12;
   bits<5> rs2;
   bits<5> rs1;

   let Inst{31-25} = imm12{11-5};
   let Inst{24-20} = rs2;
   let Inst{19-15} = rs1;
   let Inst{14-12} = funct3;
   let Inst{11-7} = imm12{4-0};
   let Opcode = opcode;

   let AsmString = ".insn s " # argstr;
 }

 class DirectiveInsnB<dag outs, dag ins, string argstr>
   : RVInst<outs, ins, "", "", [], InstFormatB> {
   bits<7> opcode;
   bits<3> funct3;

   bits<12> imm12;
   bits<5> rs2;
   bits<5> rs1;

   let Inst{31} = imm12{11};
   let Inst{30-25} = imm12{9-4};
   let Inst{24-20} = rs2;
   let Inst{19-15} = rs1;
   let Inst{14-12} = funct3;
   let Inst{11-8} = imm12{3-0};
   let Inst{7} = imm12{10};
   let Opcode = opcode;

   let AsmString = ".insn b " # argstr;
 }

 class DirectiveInsnU<dag outs, dag ins, string argstr>
   : RVInst<outs, ins, "", "", [], InstFormatU> {
   bits<7> opcode;

   bits<20> imm20;
   bits<5> rd;

   let Inst{31-12} = imm20;
   let Inst{11-7} = rd;
   let Opcode = opcode;

   let AsmString = ".insn u " # argstr;
 }

 class DirectiveInsnJ<dag outs, dag ins, string argstr>
   : RVInst<outs, ins, "", "", [], InstFormatJ> {
   bits<7> opcode;

   bits<20> imm20;
   bits<5> rd;

   let Inst{31-12} = imm20;
   let Inst{11-7} = rd;
   let Opcode = opcode;

   let AsmString = ".insn j " # argstr;
 }
	//===-- RISCVInstrFormats.td - RISCV Instruction Formats ---- tablegen --===//
	//
	// 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
	//
	//===----------------------------------------------------------------------===//

	//===----------------------------------------------------------------------===//
	//
	// These instruction format definitions are structured to match the
	// description in the RISC-V User-Level ISA specification as closely as
	// possible. For instance, the specification describes instructions with the
	// MSB (31st bit) on the left and the LSB (0th bit) on the right. This is
	// reflected in the order of parameters to each instruction class.
	//
	// One area of divergence is in the description of immediates. The
	// specification describes immediate encoding in terms of bit-slicing
	// operations on the logical value represented. The immediate argument to
	// these instruction formats instead represents the bit sequence that will be
	// inserted into the instruction. e.g. although JAL's immediate is logically
	// a 21-bit value (where the LSB is always zero), we describe it as an imm20
	// to match how it is encoded.
	//
	//===----------------------------------------------------------------------===//

	// Format specifies the encoding used by the instruction. This is used by
	// RISCVMCCodeEmitter to determine which form of fixup to use. These
	// definitions must be kept in-sync with RISCVBaseInfo.h.
	class InstFormat<bits<5> val> {
	bits<5> Value = val;
	}
	def InstFormatPseudo : InstFormat<0>;
	def InstFormatR : InstFormat<1>;
	def InstFormatR4 : InstFormat<2>;
	def InstFormatI : InstFormat<3>;
	def InstFormatS : InstFormat<4>;
	def InstFormatB : InstFormat<5>;
	def InstFormatU : InstFormat<6>;
	def InstFormatJ : InstFormat<7>;
	def InstFormatCR : InstFormat<8>;
	def InstFormatCI : InstFormat<9>;
	def InstFormatCSS : InstFormat<10>;
	def InstFormatCIW : InstFormat<11>;
	def InstFormatCL : InstFormat<12>;
	def InstFormatCS : InstFormat<13>;
	def InstFormatCA : InstFormat<14>;
	def InstFormatCB : InstFormat<15>;
	def InstFormatCJ : InstFormat<16>;
	def InstFormatOther : InstFormat<17>;

	class RISCVVConstraint<bits<3> val> {
	bits<3> Value = val;
	}
	def NoConstraint : RISCVVConstraint<0b000>;
	def VS2Constraint : RISCVVConstraint<0b001>;
	def VS1Constraint : RISCVVConstraint<0b010>;
	def VMConstraint : RISCVVConstraint<0b100>;

	// Illegal instructions:
	//
	// * The destination vector register group for a masked vector instruction
	// cannot overlap the source mask register (v0), unless the destination vector
	// register is being written with a mask value (e.g., comparisons) or the
	// scalar result of a reduction.
	//
	// * Widening: The destination EEW is greater than the source EEW, the source
	// EMUL is at least 1. The destination vector register group cannot overlap
	// with the source vector register groups besides the highest-numbered part of
	// the destination register group.
	//
	// * Narrowing: The destination EEW is smaller than the source EEW. The
	// destination vector register group cannot overlap with the source vector
	// register groups besides the lowest-numbered part of the source register
	// group.
	//
	// * vmsbf.m/vmsif.m/vmsof.m: The destination register cannot overlap the
	// source register and, if masked, cannot overlap the mask register ('v0').
	//
	// * viota: The destination register cannot overlap the source register and,
	// if masked, cannot overlap the mask register ('v0').
	//
	// * v[f]slide[1]up: The destination vector register group for vslideup cannot
	// overlap the source vector register group.
	//
	// * vrgather: The destination vector register group cannot overlap with the
	// source vector register groups.
	//
	// * vcompress: The destination vector register group cannot overlap the
	// source vector register group or the source mask register
	def WidenV : RISCVVConstraint<!or(VS2Constraint.Value,
	VS1Constraint.Value,
	VMConstraint.Value)>;
	def WidenW : RISCVVConstraint<!or(VS1Constraint.Value,
	VMConstraint.Value)>;
	def WidenCvt : RISCVVConstraint<!or(VS2Constraint.Value,
	VMConstraint.Value)>;
	def Iota : RISCVVConstraint<!or(VS2Constraint.Value,
	VMConstraint.Value)>;
	def SlideUp : RISCVVConstraint<!or(VS2Constraint.Value,
	VMConstraint.Value)>;
	def Vrgather : RISCVVConstraint<!or(VS2Constraint.Value,
	VS1Constraint.Value,
	VMConstraint.Value)>;
	def Vcompress : RISCVVConstraint<!or(VS2Constraint.Value,
	VS1Constraint.Value)>;

	// The following opcode names match those given in Table 19.1 in the
	// RISC-V User-level ISA specification ("RISC-V base opcode map").
	class RISCVOpcode<bits<7> val> {
	bits<7> Value = val;
	}
	def OPC_LOAD : RISCVOpcode<0b0000011>;
	def OPC_LOAD_FP : RISCVOpcode<0b0000111>;
	def OPC_MISC_MEM : RISCVOpcode<0b0001111>;
	def OPC_OP_IMM : RISCVOpcode<0b0010011>;
	def OPC_AUIPC : RISCVOpcode<0b0010111>;
	def OPC_OP_IMM_32 : RISCVOpcode<0b0011011>;
	def OPC_STORE : RISCVOpcode<0b0100011>;
	def OPC_STORE_FP : RISCVOpcode<0b0100111>;
	def OPC_AMO : RISCVOpcode<0b0101111>;
	def OPC_OP : RISCVOpcode<0b0110011>;
	def OPC_LUI : RISCVOpcode<0b0110111>;
	def OPC_OP_32 : RISCVOpcode<0b0111011>;
	def OPC_MADD : RISCVOpcode<0b1000011>;
	def OPC_MSUB : RISCVOpcode<0b1000111>;
	def OPC_NMSUB : RISCVOpcode<0b1001011>;
	def OPC_NMADD : RISCVOpcode<0b1001111>;
	def OPC_OP_FP : RISCVOpcode<0b1010011>;
	def OPC_OP_V : RISCVOpcode<0b1010111>;
	def OPC_BRANCH : RISCVOpcode<0b1100011>;
	def OPC_JALR : RISCVOpcode<0b1100111>;
	def OPC_JAL : RISCVOpcode<0b1101111>;
	def OPC_SYSTEM : RISCVOpcode<0b1110011>;

	class RVInst<dag outs, dag ins, string opcodestr, string argstr,
	list<dag> pattern, InstFormat format>
	: Instruction {
	field bits<32> Inst;
	// SoftFail is a field the disassembler can use to provide a way for
	// instructions to not match without killing the whole decode process. It is
	// mainly used for ARM, but Tablegen expects this field to exist or it fails
	// to build the decode table.
	field bits<32> SoftFail = 0;
	let Size = 4;

	bits<7> Opcode = 0;

	let Inst{6-0} = Opcode;

	let Namespace = "RISCV";

	dag OutOperandList = outs;
	dag InOperandList = ins;
	let AsmString = opcodestr # "\t" # argstr;
	let Pattern = pattern;

	let TSFlags{4-0} = format.Value;

	// Defaults
	RISCVVConstraint RVVConstraint = NoConstraint;
	let TSFlags{7-5} = RVVConstraint.Value;

	bits<3> VLMul = 0;
	let TSFlags{10-8} = VLMul;

	bit HasDummyMask = 0;
	let TSFlags{11} = HasDummyMask;

	bit ForceTailAgnostic = false;
	let TSFlags{12} = ForceTailAgnostic;

	bit HasMergeOp = 0;
	let TSFlags{13} = HasMergeOp;

	bit HasSEWOp = 0;
	let TSFlags{14} = HasSEWOp;

	bit HasVLOp = 0;
	let TSFlags{15} = HasVLOp;

	bit HasVecPolicyOp = 0;
	let TSFlags{16} = HasVecPolicyOp;

	bit IsRVVWideningReduction = 0;
	let TSFlags{17} = IsRVVWideningReduction;
	}

	// Pseudo instructions
	class Pseudo<dag outs, dag ins, list<dag> pattern, string opcodestr = "", string argstr = "">
	: RVInst<outs, ins, opcodestr, argstr, pattern, InstFormatPseudo>,
	Sched<[]> {
	let isPseudo = 1;
	let isCodeGenOnly = 1;
	}

	// Pseudo load instructions.
	class PseudoLoad<string opcodestr, RegisterClass rdty = GPR>
	: Pseudo<(outs rdty:$rd), (ins bare_symbol:$addr), [], opcodestr, "$rd, $addr"> {
	let hasSideEffects = 0;
	let mayLoad = 1;
	let mayStore = 0;
	let isCodeGenOnly = 0;
	let isAsmParserOnly = 1;
	}

	class PseudoFloatLoad<string opcodestr, RegisterClass rdty = GPR>
	: Pseudo<(outs GPR:$tmp, rdty:$rd), (ins bare_symbol:$addr), [], opcodestr, "$rd, $addr, $tmp"> {
	let hasSideEffects = 0;
	let mayLoad = 1;
	let mayStore = 0;
	let isCodeGenOnly = 0;
	let isAsmParserOnly = 1;
	}

	// Pseudo store instructions.
	class PseudoStore<string opcodestr, RegisterClass rsty = GPR>
	: Pseudo<(outs GPR:$tmp), (ins rsty:$rs, bare_symbol:$addr), [], opcodestr, "$rs, $addr, $tmp"> {
	let hasSideEffects = 0;
	let mayLoad = 0;
	let mayStore = 1;
	let isCodeGenOnly = 0;
	let isAsmParserOnly = 1;
	}

	// Instruction formats are listed in the order they appear in the RISC-V
	// instruction set manual (R, I, S, B, U, J) with sub-formats (e.g. RVInstR4,
	// RVInstRAtomic) sorted alphabetically.

	class RVInstR<bits<7> funct7, bits<3> funct3, RISCVOpcode opcode, dag outs,
	dag ins, string opcodestr, string argstr>
	: RVInst<outs, ins, opcodestr, argstr, [], InstFormatR> {
	bits<5> rs2;
	bits<5> rs1;
	bits<5> rd;

	let Inst{31-25} = funct7;
	let Inst{24-20} = rs2;
	let Inst{19-15} = rs1;
	let Inst{14-12} = funct3;
	let Inst{11-7} = rd;
	let Opcode = opcode.Value;
	}

	class RVInstR4<bits<2> funct2, bits<3> funct3, RISCVOpcode opcode, dag outs,
	dag ins, string opcodestr, string argstr>
	: RVInst<outs, ins, opcodestr, argstr, [], InstFormatR4> {
	bits<5> rs3;
	bits<5> rs2;
	bits<5> rs1;
	bits<5> rd;

	let Inst{31-27} = rs3;
	let Inst{26-25} = funct2;
	let Inst{24-20} = rs2;
	let Inst{19-15} = rs1;
	let Inst{14-12} = funct3;
	let Inst{11-7} = rd;
	let Opcode = opcode.Value;
	}

	class RVInstR4Frm<bits<2> funct2, RISCVOpcode opcode, dag outs, dag ins,
	string opcodestr, string argstr>
	: RVInst<outs, ins, opcodestr, argstr, [], InstFormatR4> {
	bits<5> rs3;
	bits<5> rs2;
	bits<5> rs1;
	bits<3> funct3;
	bits<5> rd;

	let Inst{31-27} = rs3;
	let Inst{26-25} = funct2;
	let Inst{24-20} = rs2;
	let Inst{19-15} = rs1;
	let Inst{14-12} = funct3;
	let Inst{11-7} = rd;
	let Opcode = opcode.Value;
	}

	class RVInstRAtomic<bits<5> funct5, bit aq, bit rl, bits<3> funct3,
	RISCVOpcode opcode, dag outs, dag ins, string opcodestr,
	string argstr>
	: RVInst<outs, ins, opcodestr, argstr, [], InstFormatR> {
	bits<5> rs2;
	bits<5> rs1;
	bits<5> rd;

	let Inst{31-27} = funct5;
	let Inst{26} = aq;
	let Inst{25} = rl;
	let Inst{24-20} = rs2;
	let Inst{19-15} = rs1;
	let Inst{14-12} = funct3;
	let Inst{11-7} = rd;
	let Opcode = opcode.Value;
	}

	class RVInstRFrm<bits<7> funct7, RISCVOpcode opcode, dag outs, dag ins,
	string opcodestr, string argstr>
	: RVInst<outs, ins, opcodestr, argstr, [], InstFormatR> {
	bits<5> rs2;
	bits<5> rs1;
	bits<3> funct3;
	bits<5> rd;

	let Inst{31-25} = funct7;
	let Inst{24-20} = rs2;
	let Inst{19-15} = rs1;
	let Inst{14-12} = funct3;
	let Inst{11-7} = rd;
	let Opcode = opcode.Value;
	}

	class RVInstI<bits<3> funct3, RISCVOpcode opcode, dag outs, dag ins,
	string opcodestr, string argstr>
	: RVInst<outs, ins, opcodestr, argstr, [], InstFormatI> {
	bits<12> imm12;
	bits<5> rs1;
	bits<5> rd;

	let Inst{31-20} = imm12;
	let Inst{19-15} = rs1;
	let Inst{14-12} = funct3;
	let Inst{11-7} = rd;
	let Opcode = opcode.Value;
	}

	class RVInstIShift<bits<5> imm11_7, bits<3> funct3, RISCVOpcode opcode,
	dag outs, dag ins, string opcodestr, string argstr>
	: RVInst<outs, ins, opcodestr, argstr, [], InstFormatI> {
	bits<6> shamt;
	bits<5> rs1;
	bits<5> rd;

	let Inst{31-27} = imm11_7;
	let Inst{26} = 0;
	let Inst{25-20} = shamt;
	let Inst{19-15} = rs1;
	let Inst{14-12} = funct3;
	let Inst{11-7} = rd;
	let Opcode = opcode.Value;
	}

	class RVInstIShiftW<bits<7> imm11_5, bits<3> funct3, RISCVOpcode opcode,
	dag outs, dag ins, string opcodestr, string argstr>
	: RVInst<outs, ins, opcodestr, argstr, [], InstFormatI> {
	bits<5> shamt;
	bits<5> rs1;
	bits<5> rd;

	let Inst{31-25} = imm11_5;
	let Inst{24-20} = shamt;
	let Inst{19-15} = rs1;
	let Inst{14-12} = funct3;
	let Inst{11-7} = rd;
	let Opcode = opcode.Value;
	}

	class RVInstS<bits<3> funct3, RISCVOpcode opcode, dag outs, dag ins,
	string opcodestr, string argstr>
	: RVInst<outs, ins, opcodestr, argstr, [], InstFormatS> {
	bits<12> imm12;
	bits<5> rs2;
	bits<5> rs1;

	let Inst{31-25} = imm12{11-5};
	let Inst{24-20} = rs2;
	let Inst{19-15} = rs1;
	let Inst{14-12} = funct3;
	let Inst{11-7} = imm12{4-0};
	let Opcode = opcode.Value;
	}

	class RVInstB<bits<3> funct3, RISCVOpcode opcode, dag outs, dag ins,
	string opcodestr, string argstr>
	: RVInst<outs, ins, opcodestr, argstr, [], InstFormatB> {
	bits<12> imm12;
	bits<5> rs2;
	bits<5> rs1;

	let Inst{31} = imm12{11};
	let Inst{30-25} = imm12{9-4};
	let Inst{24-20} = rs2;
	let Inst{19-15} = rs1;
	let Inst{14-12} = funct3;
	let Inst{11-8} = imm12{3-0};
	let Inst{7} = imm12{10};
	let Opcode = opcode.Value;
	}

	class RVInstU<RISCVOpcode opcode, dag outs, dag ins, string opcodestr,
	string argstr>
	: RVInst<outs, ins, opcodestr, argstr, [], InstFormatU> {
	bits<20> imm20;
	bits<5> rd;

	let Inst{31-12} = imm20;
	let Inst{11-7} = rd;
	let Opcode = opcode.Value;
	}

	class RVInstJ<RISCVOpcode opcode, dag outs, dag ins, string opcodestr,
	string argstr>
	: RVInst<outs, ins, opcodestr, argstr, [], InstFormatJ> {
	bits<20> imm20;
	bits<5> rd;

	let Inst{31} = imm20{19};
	let Inst{30-21} = imm20{9-0};
	let Inst{20} = imm20{10};
	let Inst{19-12} = imm20{18-11};
	let Inst{11-7} = rd;
	let Opcode = opcode.Value;
	}

	//===----------------------------------------------------------------------===//
	// Instruction classes for .insn directives
	//===----------------------------------------------------------------------===//

	class DirectiveInsnR<dag outs, dag ins, string argstr>
	: RVInst<outs, ins, "", "", [], InstFormatR> {
	bits<7> opcode;
	bits<7> funct7;
	bits<3> funct3;

	bits<5> rs2;
	bits<5> rs1;
	bits<5> rd;

	let Inst{31-25} = funct7;
	let Inst{24-20} = rs2;
	let Inst{19-15} = rs1;
	let Inst{14-12} = funct3;
	let Inst{11-7} = rd;
	let Opcode = opcode;

	let AsmString = ".insn r " # argstr;
	}

	class DirectiveInsnR4<dag outs, dag ins, string argstr>
	: RVInst<outs, ins, "", "", [], InstFormatR4> {
	bits<7> opcode;
	bits<2> funct2;
	bits<3> funct3;

	bits<5> rs3;
	bits<5> rs2;
	bits<5> rs1;
	bits<5> rd;

	let Inst{31-27} = rs3;
	let Inst{26-25} = funct2;
	let Inst{24-20} = rs2;
	let Inst{19-15} = rs1;
	let Inst{14-12} = funct3;
	let Inst{11-7} = rd;
	let Opcode = opcode;

	let AsmString = ".insn r4 " # argstr;
	}

	class DirectiveInsnI<dag outs, dag ins, string argstr>
	: RVInst<outs, ins, "", "", [], InstFormatI> {
	bits<7> opcode;
	bits<3> funct3;

	bits<12> imm12;
	bits<5> rs1;
	bits<5> rd;

	let Inst{31-20} = imm12;
	let Inst{19-15} = rs1;
	let Inst{14-12} = funct3;
	let Inst{11-7} = rd;
	let Opcode = opcode;

	let AsmString = ".insn i " # argstr;
	}

	class DirectiveInsnS<dag outs, dag ins, string argstr>
	: RVInst<outs, ins, "", "", [], InstFormatS> {
	bits<7> opcode;
	bits<3> funct3;

	bits<12> imm12;
	bits<5> rs2;
	bits<5> rs1;

	let Inst{31-25} = imm12{11-5};
	let Inst{24-20} = rs2;
	let Inst{19-15} = rs1;
	let Inst{14-12} = funct3;
	let Inst{11-7} = imm12{4-0};
	let Opcode = opcode;

	let AsmString = ".insn s " # argstr;
	}

	class DirectiveInsnB<dag outs, dag ins, string argstr>
	: RVInst<outs, ins, "", "", [], InstFormatB> {
	bits<7> opcode;
	bits<3> funct3;

	bits<12> imm12;
	bits<5> rs2;
	bits<5> rs1;

	let Inst{31} = imm12{11};
	let Inst{30-25} = imm12{9-4};
	let Inst{24-20} = rs2;
	let Inst{19-15} = rs1;
	let Inst{14-12} = funct3;
	let Inst{11-8} = imm12{3-0};
	let Inst{7} = imm12{10};
	let Opcode = opcode;

	let AsmString = ".insn b " # argstr;
	}

	class DirectiveInsnU<dag outs, dag ins, string argstr>
	: RVInst<outs, ins, "", "", [], InstFormatU> {
	bits<7> opcode;

	bits<20> imm20;
	bits<5> rd;

	let Inst{31-12} = imm20;
	let Inst{11-7} = rd;
	let Opcode = opcode;

	let AsmString = ".insn u " # argstr;
	}

	class DirectiveInsnJ<dag outs, dag ins, string argstr>
	: RVInst<outs, ins, "", "", [], InstFormatJ> {
	bits<7> opcode;

	bits<20> imm20;
	bits<5> rd;

	let Inst{31-12} = imm20;
	let Inst{11-7} = rd;
	let Opcode = opcode;

	let AsmString = ".insn j " # argstr;
	}