third_party/llvm-16.0/llvm/lib/Target/Xtensa/XtensaInstrInfo.td - SwiftShader - Git at Google

 //===- XtensaInstrInfo.td - Target Description for Xtensa -*- tablegen -*--===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // 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
 //
 //===----------------------------------------------------------------------===//
 //
 // This file describes the Xtensa instructions in TableGen format.
 //
 //===----------------------------------------------------------------------===//

 include "XtensaInstrFormats.td"
 include "XtensaOperands.td"

 //===----------------------------------------------------------------------===//
 // Arithmetic & Logical instructions
 //===----------------------------------------------------------------------===//

 class ArithLogic_RRR<bits<4> oper2, bits<4> oper1, string instrAsm,
       SDPatternOperator opNode, bit isComm = 0>
   : RRR_Inst<0x00, oper1, oper2, (outs AR:$r), (ins AR:$s, AR:$t),
              instrAsm#"\t$r, $s, $t",
             [(set AR:$r, (opNode AR:$s, AR:$t))]> {
   let isCommutable = isComm;
   let isReMaterializable = 0;
 }

 def ADD : ArithLogic_RRR<0x08, 0x00, "add", add, 1>;
 def SUB : ArithLogic_RRR<0x0C, 0x00, "sub", sub>;
 def AND : ArithLogic_RRR<0x01, 0x00, "and", and, 1>;
 def OR  : ArithLogic_RRR<0x02, 0x00, "or", or, 1>;
 def XOR : ArithLogic_RRR<0x03, 0x00, "xor", xor, 1>;

 class ADDX<bits<4> oper, string instrAsm, list<dag> pattern>
   : RRR_Inst<0x00, 0x00, oper, (outs AR:$r), (ins AR:$s, AR:$t),
              instrAsm#"\t$r, $s, $t", pattern>;

 def ADDX2 : ADDX<0x09, "addx2", [(set AR:$r, (add AR:$t, (shl AR:$s, (i32 1))))]>;
 def ADDX4 : ADDX<0x0A, "addx4", [(set AR:$r, (add AR:$t, (shl AR:$s, (i32 2))))]>;
 def ADDX8 : ADDX<0x0B, "addx8", [(set AR:$r, (add AR:$t, (shl AR:$s, (i32 3))))]>;

 class SUBX<bits<4> oper, string instrAsm, list<dag> pattern>
   : RRR_Inst<0x00, 0x00, oper, (outs AR:$r), (ins AR:$s, AR:$t),
              instrAsm#"\t$r, $s, $t", pattern>;

 def SUBX2 : SUBX<0x0D, "subx2", [(set AR:$r, (sub (shl AR:$s, (i32 1)), AR:$t))]>;
 def SUBX4 : SUBX<0x0E, "subx4", [(set AR:$r, (sub (shl AR:$s, (i32 2)), AR:$t))]>;
 def SUBX8 : SUBX<0x0F, "subx8", [(set AR:$r, (sub (shl AR:$s, (i32 3)), AR:$t))]>;

 def ABS : RRR_Inst<0x00, 0x00, 0x06, (outs AR:$r), (ins AR:$t),
                   "abs\t$r, $t", []> {
   let s = 0x1;
 }

 def ADDI : RRI8_Inst<0x02, (outs AR:$t), (ins AR:$s, imm8:$imm8),
                     "addi\t$t, $s, $imm8",
                     [(set AR:$t, (add AR:$s, imm8:$imm8))]> {
   let r = 0x0C;
 }

 def ADDMI : RRI8_Inst<0x02, (outs AR:$t), (ins AR:$s, imm8_sh8:$imm_sh8),
                      "addmi\t$t, $s, $imm_sh8",
                      [(set AR:$t, (add AR:$s, imm8_sh8:$imm_sh8))]> {
   bits<16> imm_sh8;

   let r = 0x0D;
   let imm8 = imm_sh8{15-8};
 }

 def NEG : RRR_Inst<0x00, 0x00, 0x06, (outs AR:$r), (ins AR:$t),
                   "neg\t$r, $t",
                   [(set AR:$r, (ineg AR:$t))]> {
   let s = 0x00;
 }

 //===----------------------------------------------------------------------===//
 // Move instructions
 //===----------------------------------------------------------------------===//
 def MOVI : RRI8_Inst<0x02, (outs AR:$t), (ins imm12m:$imm),
                     "movi\t$t, $imm",
                     [(set AR:$t, imm12m:$imm)]> {
   bits<12> imm;

   let imm8{7-0} = imm{7-0};
   let s{3-0} = imm{11-8};
   let r = 0xa;
 }

 def MOVEQZ : RRR_Inst<0x00, 0x03, 0x08, (outs AR:$r), (ins AR:$s, AR:$t),
                      "moveqz\t$r, $s, $t", []>;
 def MOVNEZ : RRR_Inst<0x00, 0x03, 0x09, (outs AR:$r), (ins AR:$s, AR:$t),
                      "movnez\t$r, $s, $t", []>;
 def MOVLTZ : RRR_Inst<0x00, 0x03, 0x0A, (outs AR:$r), (ins AR:$s, AR:$t),
                      "movltz\t$r, $s, $t", []>;
 def MOVGEZ : RRR_Inst<0x00, 0x03, 0x0B, (outs AR:$r), (ins AR:$s, AR:$t),
                      "movgez\t$r, $s, $t", []>;

 //===----------------------------------------------------------------------===//
 // Shift instructions
 //===----------------------------------------------------------------------===//

 let Uses = [SAR] in {
   def SLL : RRR_Inst<0x00, 0x01, 0x0A, (outs AR:$r), (ins AR:$s),
                     "sll\t$r, $s", []> {
     let t = 0x00;
   }

   def SRA : RRR_Inst<0x00, 0x01, 0x0B, (outs AR:$r), (ins AR:$t),
                     "sra\t$r, $t", []> {
     let s = 0x00;
   }

   def SRC : RRR_Inst<0x00, 0x01, 0x08, (outs AR:$r), (ins AR:$s, AR:$t),
                     "src\t$r, $s, $t", []>;

   def SRL : RRR_Inst<0x00, 0x01, 0x09, (outs AR:$r), (ins AR:$t),
                     "srl\t$r, $t", []> {
     let s = 0x00;
   }
 }

 let Defs = [SAR] in {
   def SSL : RRR_Inst<0x00, 0x00, 0x04, (outs), (ins AR:$s),
                     "ssl\t$s", []> {
     let r = 0x01;
     let t = 0x00;
   }

   def SSR : RRR_Inst<0x00, 0x00, 0x04, (outs), (ins AR:$s),
                     "ssr\t$s", []> {
     let r = 0x00;
     let t = 0x00;
   }
 }

 def EXTUI : RRR_Inst<0x00, 0x04, 0x00, (outs AR:$r), (ins AR:$t, uimm5:$imm1, imm1_16:$imm2),
                     "extui\t$r, $t, $imm1, $imm2", []> {
   bits<5> imm1;
   bits<4> imm2;

   let s = imm1{3-0};
   let Inst{16} = imm1{4};
   let Inst{23-20} = imm2;
 }

 def SRAI : RRR_Inst<0x00, 0x01, 0x02, (outs AR:$r), (ins AR:$t, uimm5:$sa),
                    "srai\t$r, $t, $sa",
                    [(set AR:$r, (sra AR:$t, uimm5:$sa))]> {
   bits<5> sa;

   let Inst{20} = sa{4};
   let s = sa{3-0};
 }

 def SRLI : RRR_Inst<0x00, 0x01, 0x04, (outs AR:$r), (ins AR:$t, uimm4:$sa),
                    "srli\t$r, $t, $sa",
                    [(set AR:$r, (srl AR:$t, uimm4:$sa))]> {
   bits<4> sa;

   let s = sa;
 }

 def SLLI : RRR_Inst<0x00, 0x01, 0x00, (outs AR:$r), (ins AR:$s, shimm1_31:$sa),
                    "slli\t$r, $s, $sa",
                    [(set AR:$r, (shl AR:$s, shimm1_31:$sa))]> {
   bits<5> sa;

   let Inst{20} = sa{4};
   let t = sa{3-0};
 }

 def SSA8L : RRR_Inst<0x00, 0x00, 0x04, (outs), (ins AR:$s),
                     "ssa8l\t$s", []> {
   let r = 0x2;
   let t = 0x0;
 }

 def SSAI : RRR_Inst<0x00, 0x00, 0x04, (outs), (ins uimm5:$imm),
                    "ssai\t$imm", []> {
   bits<5> imm;

   let r = 0x04;
   let s = imm{3-0};
   let t{3-1} = 0;
   let t{0} = imm{4};
 }

 //===----------------------------------------------------------------------===//
 // Load and store instructions
 //===----------------------------------------------------------------------===//

 // Load instructions
 let mayLoad = 1 in {

   class Load_RRI8<bits<4> oper, string instrAsm, SDPatternOperator opNode,
         ComplexPattern addrOp, Operand memOp>
 	  : RRI8_Inst<0x02, (outs AR:$t), (ins memOp:$addr),
                 instrAsm#"\t$t, $addr",
                [(set AR:$t, (opNode addrOp:$addr))]> {
     bits<12> addr;

     let r = oper;
     let imm8{7-0} = addr{11-4};
     let s{3-0} = addr{3-0};
   }
 }

 def L8UI  : Load_RRI8<0x00, "l8ui", zextloadi8, addr_ish1, mem8>;
 def L16SI : Load_RRI8<0x09, "l16si", sextloadi16, addr_ish2, mem16>;
 def L16UI : Load_RRI8<0x01, "l16ui", zextloadi16, addr_ish2, mem16>;
 def L32I  : Load_RRI8<0x02, "l32i", load, addr_ish4, mem32>;

 // Store instructions
 let mayStore = 1 in {
   class Store_II8<bits<4> oper, string instrAsm, SDPatternOperator opNode,
         ComplexPattern addrOp, Operand memOp>
 	  : RRI8_Inst<0x02, (outs), (ins AR:$t, memOp:$addr),
                 instrAsm#"\t$t, $addr",
                [(opNode AR:$t, addrOp:$addr)]> {
     bits<12> addr;

     let r = oper;
     let imm8{7-0} = addr{11-4};
     let s{3-0} = addr{3-0};
   }
 }

 def S8I  : Store_II8<0x04, "s8i", truncstorei8, addr_ish1, mem8>;
 def S16I : Store_II8<0x05, "s16i", truncstorei16, addr_ish2, mem16>;
 def S32I : Store_II8<0x06, "s32i", store, addr_ish4, mem32>;

 def L32R : RI16_Inst<0x01, (outs AR:$t), (ins L32Rtarget:$label),
                     "l32r\t$t, $label", []> {
   bits<16> label;
   let imm16 = label;
 }

 //===----------------------------------------------------------------------===//
 // Conditional branch instructions
 //===----------------------------------------------------------------------===//
 let isBranch = 1, isTerminator = 1 in {
   class Branch_RR<bits<4> oper, string instrAsm, CondCode CC>
       : RRI8_Inst<0x07, (outs),
                  (ins AR:$s, AR:$t, brtarget:$target),
                   instrAsm#"\t$s, $t, $target",
                  [(brcc CC, AR:$s, AR:$t,  bb:$target)]> {
     bits<8> target;

     let r = oper;
     let imm8 = target;
   }

   class Branch_RI<bits<4> oper, string instrAsm, CondCode CC>
       : RRI8_Inst<0x06, (outs),
                  (ins AR:$s, b4const:$imm, brtarget:$target),
                   instrAsm#"\t$s, $imm, $target",
                  [(brcc CC, AR:$s, b4const:$imm,  bb:$target)]> {
     bits<4> imm;
     bits<8> target;

     let t = oper;
     let r = imm;
     let imm8 = target;
   }

   class Branch_RIU<bits<4> oper, string instrAsm, CondCode CC>
     : RRI8_Inst<0x06, (outs),
                (ins AR:$s, b4constu:$imm, brtarget:$target),
                 instrAsm#"\t$s, $imm, $target",
                [(brcc CC, AR:$s, b4constu:$imm,  bb:$target)]> {
     bits<4> imm;
     bits<8> target;

     let t = oper;
     let r = imm;
     let imm8 = target;
   }

   class Branch_RZ<bits<2> n, bits<2> m, string instrAsm, CondCode CC>
     : BRI12_Inst<0x06, n, m, (outs),
                 (ins AR:$s, brtarget:$target),
                  instrAsm#"\t$s, $target",
                 [(brcc CC, AR:$s, (i32 0),  bb:$target)]> {
     bits<12> target;

     let imm12 = target;
   }
 }

 def BEQ   : Branch_RR<0x01, "beq", SETEQ>;
 def BNE   : Branch_RR<0x09, "bne", SETNE>;
 def BGE   : Branch_RR<0x0A, "bge", SETGE>;
 def BLT   : Branch_RR<0x02, "blt", SETLT>;
 def BGEU  : Branch_RR<0x0B, "bgeu", SETUGE>;
 def BLTU  : Branch_RR<0x03, "bltu", SETULT>;

 def BEQI  : Branch_RI<0x02, "beqi", SETEQ>;
 def BNEI  : Branch_RI<0x06, "bnei", SETNE>;
 def BGEI  : Branch_RI<0x0E, "bgei", SETGE>;
 def BLTI  : Branch_RI<0x0A, "blti", SETLT>;
 def BGEUI : Branch_RIU<0x0F, "bgeui", SETUGE>;
 def BLTUI : Branch_RIU<0x0B, "bltui", SETULT>;

 def BEQZ  : Branch_RZ<0x01, 0x00, "beqz", SETEQ>;
 def BNEZ  : Branch_RZ<0x01, 0x01, "bnez", SETNE>;
 def BGEZ  : Branch_RZ<0x01, 0x03, "bgez", SETGE>;
 def BLTZ  : Branch_RZ<0x01, 0x02, "bltz", SETLT>;

 def BALL : RRI8_Inst<0x07, (outs),
                     (ins AR:$s, AR:$t, brtarget:$target),
                     "ball\t$s, $t, $target", []> {
   bits<8> target;

   let r = 0x04;
   let imm8 = target;
 }

 def BANY : RRI8_Inst<0x07, (outs),
                     (ins AR:$s, AR:$t, brtarget:$target),
                     "bany\t$s, $t, $target", []> {
   bits<8> target;

   let r = 0x08;
   let imm8 = target;
 }

 def BBC : RRI8_Inst<0x07, (outs),
                    (ins AR:$s, AR:$t, brtarget:$target),
                    "bbc\t$s, $t, $target", []> {
   bits<8> target;

   let r = 0x05;
   let imm8 = target;
 }

 def BBS : RRI8_Inst<0x07, (outs),
                    (ins AR:$s, AR:$t, brtarget:$target),
                    "bbs\t$s, $t, $target", []> {
   bits<8> target;

   let r = 0x0d;
   let imm8 = target;
 }

 def BNALL : RRI8_Inst<0x07, (outs),
                     (ins AR:$s, AR:$t, brtarget:$target),
                     "bnall\t$s, $t, $target", []> {
   bits<8> target;

   let r = 0x0c;
   let imm8 = target;
 }

 def BNONE : RRI8_Inst<0x07, (outs),
                      (ins AR:$s, AR:$t, brtarget:$target),
                      "bnone\t$s, $t, $target", []> {
   bits<8> target;

   let r = 0x00;
   let imm8 = target;
 }

 def BBCI : RRI8_Inst<0x07, (outs),
                     (ins AR:$s, uimm5:$imm, brtarget:$target),
                     "bbci\t$s, $imm, $target", []> {
   bits<8> target;
   bits<5> imm;

   let r{3-1} = 0x3;
   let r{0} = imm{4};
   let t{3-0} = imm{3-0};
   let imm8 = target;
 }

 def BBSI : RRI8_Inst<0x07, (outs),
                     (ins AR:$s, uimm5:$imm, brtarget:$target),
                     "bbsi\t$s, $imm, $target", []> {
   bits<8> target;
   bits<5> imm;

   let r{3-1} = 0x7;
   let r{0} = imm{4};
   let t{3-0} = imm{3-0};
   let imm8 = target;
 }

 //===----------------------------------------------------------------------===//
 // Call and jump instructions
 //===----------------------------------------------------------------------===//

 let isBranch = 1, isTerminator = 1, isBarrier = 1 in {
   def J : CALL_Inst<0x06, (outs), (ins jumptarget:$offset),
                    "j\t$offset",
                    [(br bb:$offset)]> {
     let n = 0x0;
   }

   def JX : CALLX_Inst<0x00, 0x00, 0x00, (outs), (ins AR:$s),
                      "jx\t$s",
                      [(brind AR:$s)]> {
     let m = 0x2;
     let n = 0x2;
     let r = 0;
     let isIndirectBranch = 1;
   }
 }

 let isCall = 1, Defs = [A0] in {
   def CALL0 : CALL_Inst<0x05, (outs), (ins pcrel32call:$offset),
                        "call0\t$offset", []> {
     let n = 0;
   }

   def CALLX0 : CALLX_Inst<0x00, 0x00, 0x00, (outs), (ins AR:$s),
                          "callx0\t$s", []> {
     let m = 0x3;
     let n = 0x0;
     let r = 0;
   }
 }

 let isReturn = 1, isTerminator = 1,
     isBarrier = 1, Uses = [A0] in {

   def RET : CALLX_Inst<0x00, 0x00, 0x00, (outs), (ins),
                       "ret", []> {
     let m = 0x2;
     let n = 0x0;
     let s = 0;
     let r = 0;
   }
 }

 //===----------------------------------------------------------------------===//
 // Mem barrier instructions
 //===----------------------------------------------------------------------===//

 def MEMW :  RRR_Inst<0x00, 0x00, 0x00, (outs), (ins),
                     "memw", []> {
   let r = 0x2;
   let t = 0x0c;
   let s = 0x0;
 }

 def EXTW : RRR_Inst<0x00, 0x00, 0x00, (outs), (ins),
                    "extw", []> {
   let r = 0x2;
   let s = 0x0;
   let t = 0xd;
   let hasSideEffects = 1;
 }

 //===----------------------------------------------------------------------===//
 // Processor control instructions
 //===----------------------------------------------------------------------===//

 def DSYNC : RRR_Inst<0x00, 0x00, 0x00, (outs), (ins),
                     "dsync", []> {
   let r = 0x2;
   let s = 0x0;
   let t = 0x3;
   let hasSideEffects = 1;
 }

 def ISYNC : RRR_Inst<0x00, 0x00, 0x00, (outs), (ins),
                     "isync", []> {
   let r = 0x2;
   let s = 0x0;
   let t = 0x0;
   let hasSideEffects = 1;
 }

 def RSYNC : RRR_Inst<0x00, 0x00, 0x00, (outs), (ins),
                     "rsync", []> {
   let r = 0x2;
   let s = 0x0;
   let t = 0x1;
   let hasSideEffects = 1;
 }

 def ESYNC : RRR_Inst<0x00, 0x00, 0x00, (outs), (ins),
                     "esync", []> {
   let r = 0x2;
   let s = 0x0;
   let t = 0x2;
   let hasSideEffects = 1;
 }

 def NOP : RRR_Inst<0x00, 0x00, 0x00, (outs), (ins),
                   "nop", []> {
   let r = 0x02;
   let s = 0x00;
   let t = 0x0f;
 }

 def WSR : RSR_Inst<0x00, 0x03, 0x01, (outs SR:$sr), (ins AR:$t),
                   "wsr\t$t, $sr", []>;

 def RSR : RSR_Inst<0x00, 0x03, 0x00, (outs AR:$t), (ins SR:$sr),
                   "rsr\t$t, $sr", []>;

 def XSR : RSR_Inst<0x00, 0x01, 0x06, (outs AR:$ard, SR:$srd), (ins AR:$t, SR:$sr),
                   "xsr\t$t, $sr", []> {
   let Constraints = "$ard = $t, $srd = $sr";
 }
	//===- XtensaInstrInfo.td - Target Description for Xtensa -- tablegen ---===//
	//
	// The LLVM Compiler Infrastructure
	//
	// 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
	//
	//===----------------------------------------------------------------------===//
	//
	// This file describes the Xtensa instructions in TableGen format.
	//
	//===----------------------------------------------------------------------===//

	include "XtensaInstrFormats.td"
	include "XtensaOperands.td"

	//===----------------------------------------------------------------------===//
	// Arithmetic & Logical instructions
	//===----------------------------------------------------------------------===//

	class ArithLogic_RRR<bits<4> oper2, bits<4> oper1, string instrAsm,
	SDPatternOperator opNode, bit isComm = 0>
	: RRR_Inst<0x00, oper1, oper2, (outs AR:$r), (ins AR:$s, AR:$t),
	instrAsm#"\t$r, $s, $t",
	[(set AR:$r, (opNode AR:$s, AR:$t))]> {
	let isCommutable = isComm;
	let isReMaterializable = 0;
	}

	def ADD : ArithLogic_RRR<0x08, 0x00, "add", add, 1>;
	def SUB : ArithLogic_RRR<0x0C, 0x00, "sub", sub>;
	def AND : ArithLogic_RRR<0x01, 0x00, "and", and, 1>;
	def OR : ArithLogic_RRR<0x02, 0x00, "or", or, 1>;
	def XOR : ArithLogic_RRR<0x03, 0x00, "xor", xor, 1>;

	class ADDX<bits<4> oper, string instrAsm, list<dag> pattern>
	: RRR_Inst<0x00, 0x00, oper, (outs AR:$r), (ins AR:$s, AR:$t),
	instrAsm#"\t$r, $s, $t", pattern>;

	def ADDX2 : ADDX<0x09, "addx2", [(set AR:$r, (add AR:$t, (shl AR:$s, (i32 1))))]>;
	def ADDX4 : ADDX<0x0A, "addx4", [(set AR:$r, (add AR:$t, (shl AR:$s, (i32 2))))]>;
	def ADDX8 : ADDX<0x0B, "addx8", [(set AR:$r, (add AR:$t, (shl AR:$s, (i32 3))))]>;

	class SUBX<bits<4> oper, string instrAsm, list<dag> pattern>
	: RRR_Inst<0x00, 0x00, oper, (outs AR:$r), (ins AR:$s, AR:$t),
	instrAsm#"\t$r, $s, $t", pattern>;

	def SUBX2 : SUBX<0x0D, "subx2", [(set AR:$r, (sub (shl AR:$s, (i32 1)), AR:$t))]>;
	def SUBX4 : SUBX<0x0E, "subx4", [(set AR:$r, (sub (shl AR:$s, (i32 2)), AR:$t))]>;
	def SUBX8 : SUBX<0x0F, "subx8", [(set AR:$r, (sub (shl AR:$s, (i32 3)), AR:$t))]>;

	def ABS : RRR_Inst<0x00, 0x00, 0x06, (outs AR:$r), (ins AR:$t),
	"abs\t$r, $t", []> {
	let s = 0x1;
	}

	def ADDI : RRI8_Inst<0x02, (outs AR:$t), (ins AR:$s, imm8:$imm8),
	"addi\t$t, $s, $imm8",
	[(set AR:$t, (add AR:$s, imm8:$imm8))]> {
	let r = 0x0C;
	}

	def ADDMI : RRI8_Inst<0x02, (outs AR:$t), (ins AR:$s, imm8_sh8:$imm_sh8),
	"addmi\t$t, $s, $imm_sh8",
	[(set AR:$t, (add AR:$s, imm8_sh8:$imm_sh8))]> {
	bits<16> imm_sh8;

	let r = 0x0D;
	let imm8 = imm_sh8{15-8};
	}

	def NEG : RRR_Inst<0x00, 0x00, 0x06, (outs AR:$r), (ins AR:$t),
	"neg\t$r, $t",
	[(set AR:$r, (ineg AR:$t))]> {
	let s = 0x00;
	}

	//===----------------------------------------------------------------------===//
	// Move instructions
	//===----------------------------------------------------------------------===//
	def MOVI : RRI8_Inst<0x02, (outs AR:$t), (ins imm12m:$imm),
	"movi\t$t, $imm",
	[(set AR:$t, imm12m:$imm)]> {
	bits<12> imm;

	let imm8{7-0} = imm{7-0};
	let s{3-0} = imm{11-8};
	let r = 0xa;
	}

	def MOVEQZ : RRR_Inst<0x00, 0x03, 0x08, (outs AR:$r), (ins AR:$s, AR:$t),
	"moveqz\t$r, $s, $t", []>;
	def MOVNEZ : RRR_Inst<0x00, 0x03, 0x09, (outs AR:$r), (ins AR:$s, AR:$t),
	"movnez\t$r, $s, $t", []>;
	def MOVLTZ : RRR_Inst<0x00, 0x03, 0x0A, (outs AR:$r), (ins AR:$s, AR:$t),
	"movltz\t$r, $s, $t", []>;
	def MOVGEZ : RRR_Inst<0x00, 0x03, 0x0B, (outs AR:$r), (ins AR:$s, AR:$t),
	"movgez\t$r, $s, $t", []>;

	//===----------------------------------------------------------------------===//
	// Shift instructions
	//===----------------------------------------------------------------------===//

	let Uses = [SAR] in {
	def SLL : RRR_Inst<0x00, 0x01, 0x0A, (outs AR:$r), (ins AR:$s),
	"sll\t$r, $s", []> {
	let t = 0x00;
	}

	def SRA : RRR_Inst<0x00, 0x01, 0x0B, (outs AR:$r), (ins AR:$t),
	"sra\t$r, $t", []> {
	let s = 0x00;
	}

	def SRC : RRR_Inst<0x00, 0x01, 0x08, (outs AR:$r), (ins AR:$s, AR:$t),
	"src\t$r, $s, $t", []>;

	def SRL : RRR_Inst<0x00, 0x01, 0x09, (outs AR:$r), (ins AR:$t),
	"srl\t$r, $t", []> {
	let s = 0x00;
	}
	}

	let Defs = [SAR] in {
	def SSL : RRR_Inst<0x00, 0x00, 0x04, (outs), (ins AR:$s),
	"ssl\t$s", []> {
	let r = 0x01;
	let t = 0x00;
	}

	def SSR : RRR_Inst<0x00, 0x00, 0x04, (outs), (ins AR:$s),
	"ssr\t$s", []> {
	let r = 0x00;
	let t = 0x00;
	}
	}

	def EXTUI : RRR_Inst<0x00, 0x04, 0x00, (outs AR:$r), (ins AR:$t, uimm5:$imm1, imm1_16:$imm2),
	"extui\t$r, $t, $imm1, $imm2", []> {
	bits<5> imm1;
	bits<4> imm2;

	let s = imm1{3-0};
	let Inst{16} = imm1{4};
	let Inst{23-20} = imm2;
	}

	def SRAI : RRR_Inst<0x00, 0x01, 0x02, (outs AR:$r), (ins AR:$t, uimm5:$sa),
	"srai\t$r, $t, $sa",
	[(set AR:$r, (sra AR:$t, uimm5:$sa))]> {
	bits<5> sa;

	let Inst{20} = sa{4};
	let s = sa{3-0};
	}

	def SRLI : RRR_Inst<0x00, 0x01, 0x04, (outs AR:$r), (ins AR:$t, uimm4:$sa),
	"srli\t$r, $t, $sa",
	[(set AR:$r, (srl AR:$t, uimm4:$sa))]> {
	bits<4> sa;

	let s = sa;
	}

	def SLLI : RRR_Inst<0x00, 0x01, 0x00, (outs AR:$r), (ins AR:$s, shimm1_31:$sa),
	"slli\t$r, $s, $sa",
	[(set AR:$r, (shl AR:$s, shimm1_31:$sa))]> {
	bits<5> sa;

	let Inst{20} = sa{4};
	let t = sa{3-0};
	}

	def SSA8L : RRR_Inst<0x00, 0x00, 0x04, (outs), (ins AR:$s),
	"ssa8l\t$s", []> {
	let r = 0x2;
	let t = 0x0;
	}

	def SSAI : RRR_Inst<0x00, 0x00, 0x04, (outs), (ins uimm5:$imm),
	"ssai\t$imm", []> {
	bits<5> imm;

	let r = 0x04;
	let s = imm{3-0};
	let t{3-1} = 0;
	let t{0} = imm{4};
	}

	//===----------------------------------------------------------------------===//
	// Load and store instructions
	//===----------------------------------------------------------------------===//

	// Load instructions
	let mayLoad = 1 in {

	class Load_RRI8<bits<4> oper, string instrAsm, SDPatternOperator opNode,
	ComplexPattern addrOp, Operand memOp>
	: RRI8_Inst<0x02, (outs AR:$t), (ins memOp:$addr),
	instrAsm#"\t$t, $addr",
	[(set AR:$t, (opNode addrOp:$addr))]> {
	bits<12> addr;

	let r = oper;
	let imm8{7-0} = addr{11-4};
	let s{3-0} = addr{3-0};
	}
	}

	def L8UI : Load_RRI8<0x00, "l8ui", zextloadi8, addr_ish1, mem8>;
	def L16SI : Load_RRI8<0x09, "l16si", sextloadi16, addr_ish2, mem16>;
	def L16UI : Load_RRI8<0x01, "l16ui", zextloadi16, addr_ish2, mem16>;
	def L32I : Load_RRI8<0x02, "l32i", load, addr_ish4, mem32>;

	// Store instructions
	let mayStore = 1 in {
	class Store_II8<bits<4> oper, string instrAsm, SDPatternOperator opNode,
	ComplexPattern addrOp, Operand memOp>
	: RRI8_Inst<0x02, (outs), (ins AR:$t, memOp:$addr),
	instrAsm#"\t$t, $addr",
	[(opNode AR:$t, addrOp:$addr)]> {
	bits<12> addr;

	let r = oper;
	let imm8{7-0} = addr{11-4};
	let s{3-0} = addr{3-0};
	}
	}

	def S8I : Store_II8<0x04, "s8i", truncstorei8, addr_ish1, mem8>;
	def S16I : Store_II8<0x05, "s16i", truncstorei16, addr_ish2, mem16>;
	def S32I : Store_II8<0x06, "s32i", store, addr_ish4, mem32>;

	def L32R : RI16_Inst<0x01, (outs AR:$t), (ins L32Rtarget:$label),
	"l32r\t$t, $label", []> {
	bits<16> label;
	let imm16 = label;
	}

	//===----------------------------------------------------------------------===//
	// Conditional branch instructions
	//===----------------------------------------------------------------------===//
	let isBranch = 1, isTerminator = 1 in {
	class Branch_RR<bits<4> oper, string instrAsm, CondCode CC>
	: RRI8_Inst<0x07, (outs),
	(ins AR:$s, AR:$t, brtarget:$target),
	instrAsm#"\t$s, $t, $target",
	[(brcc CC, AR:$s, AR:$t, bb:$target)]> {
	bits<8> target;

	let r = oper;
	let imm8 = target;
	}

	class Branch_RI<bits<4> oper, string instrAsm, CondCode CC>
	: RRI8_Inst<0x06, (outs),
	(ins AR:$s, b4const:$imm, brtarget:$target),
	instrAsm#"\t$s, $imm, $target",
	[(brcc CC, AR:$s, b4const:$imm, bb:$target)]> {
	bits<4> imm;
	bits<8> target;

	let t = oper;
	let r = imm;
	let imm8 = target;
	}

	class Branch_RIU<bits<4> oper, string instrAsm, CondCode CC>
	: RRI8_Inst<0x06, (outs),
	(ins AR:$s, b4constu:$imm, brtarget:$target),
	instrAsm#"\t$s, $imm, $target",
	[(brcc CC, AR:$s, b4constu:$imm, bb:$target)]> {
	bits<4> imm;
	bits<8> target;

	let t = oper;
	let r = imm;
	let imm8 = target;
	}

	class Branch_RZ<bits<2> n, bits<2> m, string instrAsm, CondCode CC>
	: BRI12_Inst<0x06, n, m, (outs),
	(ins AR:$s, brtarget:$target),
	instrAsm#"\t$s, $target",
	[(brcc CC, AR:$s, (i32 0), bb:$target)]> {
	bits<12> target;

	let imm12 = target;
	}
	}

	def BEQ : Branch_RR<0x01, "beq", SETEQ>;
	def BNE : Branch_RR<0x09, "bne", SETNE>;
	def BGE : Branch_RR<0x0A, "bge", SETGE>;
	def BLT : Branch_RR<0x02, "blt", SETLT>;
	def BGEU : Branch_RR<0x0B, "bgeu", SETUGE>;
	def BLTU : Branch_RR<0x03, "bltu", SETULT>;

	def BEQI : Branch_RI<0x02, "beqi", SETEQ>;
	def BNEI : Branch_RI<0x06, "bnei", SETNE>;
	def BGEI : Branch_RI<0x0E, "bgei", SETGE>;
	def BLTI : Branch_RI<0x0A, "blti", SETLT>;
	def BGEUI : Branch_RIU<0x0F, "bgeui", SETUGE>;
	def BLTUI : Branch_RIU<0x0B, "bltui", SETULT>;

	def BEQZ : Branch_RZ<0x01, 0x00, "beqz", SETEQ>;
	def BNEZ : Branch_RZ<0x01, 0x01, "bnez", SETNE>;
	def BGEZ : Branch_RZ<0x01, 0x03, "bgez", SETGE>;
	def BLTZ : Branch_RZ<0x01, 0x02, "bltz", SETLT>;

	def BALL : RRI8_Inst<0x07, (outs),
	(ins AR:$s, AR:$t, brtarget:$target),
	"ball\t$s, $t, $target", []> {
	bits<8> target;

	let r = 0x04;
	let imm8 = target;
	}

	def BANY : RRI8_Inst<0x07, (outs),
	(ins AR:$s, AR:$t, brtarget:$target),
	"bany\t$s, $t, $target", []> {
	bits<8> target;

	let r = 0x08;
	let imm8 = target;
	}

	def BBC : RRI8_Inst<0x07, (outs),
	(ins AR:$s, AR:$t, brtarget:$target),
	"bbc\t$s, $t, $target", []> {
	bits<8> target;

	let r = 0x05;
	let imm8 = target;
	}

	def BBS : RRI8_Inst<0x07, (outs),
	(ins AR:$s, AR:$t, brtarget:$target),
	"bbs\t$s, $t, $target", []> {
	bits<8> target;

	let r = 0x0d;
	let imm8 = target;
	}

	def BNALL : RRI8_Inst<0x07, (outs),
	(ins AR:$s, AR:$t, brtarget:$target),
	"bnall\t$s, $t, $target", []> {
	bits<8> target;

	let r = 0x0c;
	let imm8 = target;
	}

	def BNONE : RRI8_Inst<0x07, (outs),
	(ins AR:$s, AR:$t, brtarget:$target),
	"bnone\t$s, $t, $target", []> {
	bits<8> target;

	let r = 0x00;
	let imm8 = target;
	}

	def BBCI : RRI8_Inst<0x07, (outs),
	(ins AR:$s, uimm5:$imm, brtarget:$target),
	"bbci\t$s, $imm, $target", []> {
	bits<8> target;
	bits<5> imm;

	let r{3-1} = 0x3;
	let r{0} = imm{4};
	let t{3-0} = imm{3-0};
	let imm8 = target;
	}

	def BBSI : RRI8_Inst<0x07, (outs),
	(ins AR:$s, uimm5:$imm, brtarget:$target),
	"bbsi\t$s, $imm, $target", []> {
	bits<8> target;
	bits<5> imm;

	let r{3-1} = 0x7;
	let r{0} = imm{4};
	let t{3-0} = imm{3-0};
	let imm8 = target;
	}

	//===----------------------------------------------------------------------===//
	// Call and jump instructions
	//===----------------------------------------------------------------------===//

	let isBranch = 1, isTerminator = 1, isBarrier = 1 in {
	def J : CALL_Inst<0x06, (outs), (ins jumptarget:$offset),
	"j\t$offset",
	[(br bb:$offset)]> {
	let n = 0x0;
	}

	def JX : CALLX_Inst<0x00, 0x00, 0x00, (outs), (ins AR:$s),
	"jx\t$s",
	[(brind AR:$s)]> {
	let m = 0x2;
	let n = 0x2;
	let r = 0;
	let isIndirectBranch = 1;
	}
	}

	let isCall = 1, Defs = [A0] in {
	def CALL0 : CALL_Inst<0x05, (outs), (ins pcrel32call:$offset),
	"call0\t$offset", []> {
	let n = 0;
	}

	def CALLX0 : CALLX_Inst<0x00, 0x00, 0x00, (outs), (ins AR:$s),
	"callx0\t$s", []> {
	let m = 0x3;
	let n = 0x0;
	let r = 0;
	}
	}

	let isReturn = 1, isTerminator = 1,
	isBarrier = 1, Uses = [A0] in {

	def RET : CALLX_Inst<0x00, 0x00, 0x00, (outs), (ins),
	"ret", []> {
	let m = 0x2;
	let n = 0x0;
	let s = 0;
	let r = 0;
	}
	}

	//===----------------------------------------------------------------------===//
	// Mem barrier instructions
	//===----------------------------------------------------------------------===//

	def MEMW : RRR_Inst<0x00, 0x00, 0x00, (outs), (ins),
	"memw", []> {
	let r = 0x2;
	let t = 0x0c;
	let s = 0x0;
	}

	def EXTW : RRR_Inst<0x00, 0x00, 0x00, (outs), (ins),
	"extw", []> {
	let r = 0x2;
	let s = 0x0;
	let t = 0xd;
	let hasSideEffects = 1;
	}

	//===----------------------------------------------------------------------===//
	// Processor control instructions
	//===----------------------------------------------------------------------===//

	def DSYNC : RRR_Inst<0x00, 0x00, 0x00, (outs), (ins),
	"dsync", []> {
	let r = 0x2;
	let s = 0x0;
	let t = 0x3;
	let hasSideEffects = 1;
	}

	def ISYNC : RRR_Inst<0x00, 0x00, 0x00, (outs), (ins),
	"isync", []> {
	let r = 0x2;
	let s = 0x0;
	let t = 0x0;
	let hasSideEffects = 1;
	}

	def RSYNC : RRR_Inst<0x00, 0x00, 0x00, (outs), (ins),
	"rsync", []> {
	let r = 0x2;
	let s = 0x0;
	let t = 0x1;
	let hasSideEffects = 1;
	}

	def ESYNC : RRR_Inst<0x00, 0x00, 0x00, (outs), (ins),
	"esync", []> {
	let r = 0x2;
	let s = 0x0;
	let t = 0x2;
	let hasSideEffects = 1;
	}

	def NOP : RRR_Inst<0x00, 0x00, 0x00, (outs), (ins),
	"nop", []> {
	let r = 0x02;
	let s = 0x00;
	let t = 0x0f;
	}

	def WSR : RSR_Inst<0x00, 0x03, 0x01, (outs SR:$sr), (ins AR:$t),
	"wsr\t$t, $sr", []>;

	def RSR : RSR_Inst<0x00, 0x03, 0x00, (outs AR:$t), (ins SR:$sr),
	"rsr\t$t, $sr", []>;

	def XSR : RSR_Inst<0x00, 0x01, 0x06, (outs AR:$ard, SR:$srd), (ins AR:$t, SR:$sr),
	"xsr\t$t, $sr", []> {
	let Constraints = "$ard = $t, $srd = $sr";
	}