llvm/lib/Target/CSKY/CSKYInstrInfo16Instr.td - llvm-project - Git at Google

 //===-- CSKYInstrInfo16Instr.td - CSKY 16-bit Instruction --*- 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
 //
 //===----------------------------------------------------------------------===//
 //
 // This file describes the CSKY 16-bit instructions in TableGen format.
 //
 //===----------------------------------------------------------------------===//

 //===----------------------------------------------------------------------===//
 // CSKY specific DAG Nodes.
 //===----------------------------------------------------------------------===//

 // Target-dependent nodes.
 def CSKY_NIE : SDNode<"CSKYISD::NIE", SDTNone,
     [SDNPHasChain, SDNPOptInGlue]>;
 def CSKY_NIR : SDNode<"CSKYISD::NIR", SDTNone,
     [SDNPHasChain, SDNPOptInGlue]>;

 //===----------------------------------------------------------------------===//
 // Operand and SDNode transformation definitions.
 //===----------------------------------------------------------------------===//

 def br_symbol_16bit : Operand<iPTR> {
   let EncoderMethod =
     "getBranchSymbolOpValue<CSKY::fixup_csky_pcrel_imm10_scale2>";
   let ParserMatchClass = CSKYSymbol;
   let DecoderMethod = "decodeSImmOperand<10, 1>";
   let PrintMethod = "printCSKYSymbolOperand";
   let OperandType = "OPERAND_PCREL";
 }

 def SPOperand : AsmOperandClass {
   let Name = "SPOperand";
   let RenderMethod = "addRegOperands";
   let DiagnosticType = !strconcat("Invalid", Name);
 }

 def SPOp : RegisterOperand<GPR> {
  let ParserMatchClass = SPOperand;
 }

 def constpool_symbol_16bit : Operand<iPTR> {
   let ParserMatchClass = Constpool;
   let EncoderMethod =
     "getConstpoolSymbolOpValue<CSKY::fixup_csky_pcrel_uimm7_scale4>";
   let DecoderMethod = "decodeLRW16Imm8";
   let PrintMethod = "printConstpool";
   let OperandType = "OPERAND_PCREL";
 }

 //===----------------------------------------------------------------------===//
 // Instruction Formats
 //===----------------------------------------------------------------------===//

 include "CSKYInstrFormats16Instr.td"

 //===----------------------------------------------------------------------===//
 // Instruction definitions.
 //===----------------------------------------------------------------------===//

 //===----------------------------------------------------------------------===//
 // Basic ALU instructions.
 //===----------------------------------------------------------------------===//

 let isCommutable = 1, isAdd = 1 in
   def ADDU16 : R16_XYZ<0, "addu16", add>;
 let Pattern = [(set mGPR:$rz, (sub mGPR:$rx, mGPR:$ry))] in
   def SUBU16 : R16_XYZ<1, "subu16", sub>;

 let isCommutable = 1, isAdd = 1 in
   def ADDC16 : R16_XZ_BINOP_C<0b1000, 0b01, "addc16">;
 def SUBC16 : R16_XZ_BINOP_C<0b1000, 0b11, "subc16">;

 let isCommutable = 1 in {
   let isAdd = 1 in
   def ADDU16XZ : R16_XZ_BINOP<0b1000, 0b00, "addu16", BinOpFrag<(add node:$LHS, node:$RHS)>>;
   def AND16 : R16_XZ_BINOP<0b1010, 0b00, "and16", BinOpFrag<(and node:$LHS, node:$RHS)>>;
   def OR16 : R16_XZ_BINOP<0b1011, 0b00, "or16", BinOpFrag<(or node:$LHS, node:$RHS)>>;
   def XOR16 : R16_XZ_BINOP<0b1011, 0b01, "xor16", BinOpFrag<(xor node:$LHS, node:$RHS)>>;
   def NOR16 : R16_XZ_BINOP<0b1011, 0b10, "nor16", BinOpFrag<(not (or node:$LHS, node:$RHS))>>;
   let isCodeGenOnly = 1 in
   def NOT16 : R16_XZ_UNOP<0b1011, 0b10, "not16">;
   def MULT16 :  R16_XZ_BINOP<0b1111, 0b00, "mult16", BinOpFrag<(mul node:$LHS, node:$RHS)>>;
 }
 def SUBU16XZ : R16_XZ_BINOP<0b1000, 0b10, "subu16", BinOpFrag<(sub node:$LHS, node:$RHS)>>;
 def ANDN16 : R16_XZ_BINOP<0b1010, 0b01, "andn16", BinOpFrag<(and node:$LHS, (not node:$RHS))>>;
 def LSL16 : R16_XZ_BINOP<0b1100, 0b00, "lsl16", BinOpFrag<(shl node:$LHS, node:$RHS)>>;
 def LSR16 : R16_XZ_BINOP<0b1100, 0b01, "lsr16", BinOpFrag<(srl node:$LHS, node:$RHS)>>;
 def ASR16 : R16_XZ_BINOP<0b1100, 0b10, "asr16", BinOpFrag<(sra node:$LHS, node:$RHS)>>;
 def ROTL16 : R16_XZ_BINOP<0b1100, 0b11, "rotl16", BinOpFrag<(rotl node:$LHS, (and node:$RHS, 0x1f))>>;

 def MULSH16 : R16_XZ_BINOP_NOPat<0b1111, 0b01, "mulsh16">;

 def ZEXTB16 : R16_XZ_UNOP<0b1101, 0b00, "zextb16">;
 def ZEXTH16 : R16_XZ_UNOP<0b1101, 0b01, "zexth16">;
 def SEXTB16 : R16_XZ_UNOP<0b1101, 0b10, "sextb16">;
 def SEXTH16 : R16_XZ_UNOP<0b1101, 0b11, "sexth16">;

 let Constraints = "$rZ = $rz", isReMaterializable = 1, isAsCheapAsAMove = 1 in {
   let isAdd = 1, Pattern = [(set mGPR:$rz, (add mGPR:$rZ, oimm8:$imm8))] in
   def ADDI16 : I16_Z_8<0b100, (ins mGPR:$rZ, oimm8:$imm8), "addi16\t$rz, $imm8">;
   let Pattern = [(set mGPR:$rz, (sub mGPR:$rZ, oimm8:$imm8))] in
   def SUBI16 : I16_Z_8<0b101, (ins mGPR:$rZ, oimm8:$imm8), "subi16\t$rz, $imm8">;
 }

 let isAdd = 1 in
 def ADDI16ZSP : I16_Z_8<0b011, (ins SPOp:$sp, uimm8_2:$imm8),
                         "addi16\t$rz, $sp, $imm8">;

 let isAdd = 1 in
 def ADDI16SPSP : I16_SP_IMM7<0b000,"addi16">;
 def SUBI16SPSP : I16_SP_IMM7<0b001,"subi16">;

 let isReMaterializable = 1, isAsCheapAsAMove = 1 in {
   def LSLI16 : I16_XZ_IMM5<0, "lsli16", shl>;
   def LSRI16 : I16_XZ_IMM5<1, "lsri16", srl>;
   def ASRI16 : I16_XZ_IMM5<2, "asri16", sra>;
 }

 let isAdd = 1 in
 def ADDI16XZ : I16_XZ_IMM3<0b10, "addi16", add>;
 def SUBI16XZ : I16_XZ_IMM3<0b11, "subi16", sub>;

 let Size = 4 in
 def NEG16 : CSKYPseudo<(outs mGPR:$rd), (ins mGPR:$rx), "neg16 $rd, $rx", []>;

 let Size = 4 in
 def RSUBI16 : CSKYPseudo<(outs mGPR:$rd),
   (ins mGPR:$rx, uimm8:$imm8), "rsubi16 $rd, $rx, $imm8", []>;

 //===----------------------------------------------------------------------===//
 // Load & Store instructions.
 //===----------------------------------------------------------------------===//

 def LD16B : I16_XZ_LDST<AddrMode16B, 0b000, "ld16.b",
   (outs mGPR:$rz), (ins mGPR:$rx, uimm5:$imm)>;
 def LD16H : I16_XZ_LDST<AddrMode16H, 0b001, "ld16.h",
   (outs mGPR:$rz), (ins mGPR:$rx, uimm5_1:$imm)>;
 def LD16W : I16_XZ_LDST<AddrMode16W, 0b010, "ld16.w",
   (outs mGPR:$rz), (ins mGPR:$rx, uimm5_2:$imm)>;
 def ST16B : I16_XZ_LDST<AddrMode16B, 0b100, "st16.b",
   (outs), (ins mGPR:$rz, mGPR:$rx, uimm5:$imm)>;
 def ST16H : I16_XZ_LDST<AddrMode16H, 0b101, "st16.h",
   (outs), (ins mGPR:$rz, mGPR:$rx, uimm5_1:$imm)>;
 def ST16W : I16_XZ_LDST<AddrMode16W, 0b110, "st16.w",
   (outs), (ins mGPR:$rz, mGPR:$rx, uimm5_2:$imm)>;

 def LD16WSP : I16_ZSP_LDST<AddrMode16W, 0b011, "ld16.w",
   (outs mGPR:$rz), (ins SPOp:$sp, uimm8_2:$addr)>;
 def ST16WSP : I16_ZSP_LDST<AddrMode16W, 0b111, "st16.w",
   (outs), (ins mGPR:$rz, SPOp:$sp, uimm8_2:$addr)>;

 //===----------------------------------------------------------------------===//
 // Compare instructions.
 //===----------------------------------------------------------------------===//

 def CMPHS16 : R16_XY_CMP<0, "cmphs16">;
 def CMPLT16 : R16_XY_CMP<1, "cmplt16">;
 let isCommutable = 1 in
 def CMPNE16 : R16_XY_CMP<2, "cmpne16">;


 def CMPHSI16 : I16_X_CMP<0, "cmphsi16", oimm5>;
 def CMPLTI16 : I16_X_CMP<1, "cmplti16", oimm5>;
 def CMPLEI16 : CSKYPseudo<(outs CARRY:$ca), (ins mGPR:$rx, uimm5:$imm5),
     "cmplei16\t$rx, $imm5", []>;
 def CMPNEI16 : I16_X_CMP<2, "cmpnei16", uimm5>;

 //===----------------------------------------------------------------------===//
 // Data move instructions.
 //===----------------------------------------------------------------------===//


 def MOVI16 : I16_Z_8<0b110, (ins uimm8:$imm8), "movi16\t$rz, $imm8"> {
   let isReMaterializable = 1;
   let isAsCheapAsAMove = 1;
   let isMoveImm = 1;
   let Pattern = [(set mGPR:$rz, uimm8:$imm8)];
 }

 def MOV16 : CSKY16Inst<AddrModeNone, (outs sGPR:$rz), (ins sGPR:$rx),
                        "mov16\t$rz, $rx", []> {
   bits<4> rz;
   bits<4> rx;
   let Inst{15,14} = 0b01;
   let Inst{13 - 10} = 0b1011;
   let Inst{9 - 6} = rz;
   let Inst{5 - 2} = rx;
   let Inst{1,0} = 0b11;
 }

 // MVC16 is not in "cskyv2 instructions reference manul"
 def MVCV16 : CSKY16Inst<AddrModeNone,
   (outs sGPR:$rz), (ins CARRY:$ca), "mvcv16\t$rz", []> {
   bits<4> rz;
   let Inst{15,14} = 0b01;
   let Inst{13 - 10} = 0b1001;
   let Inst{9 - 6} = rz;
   let Inst{5 - 2} = 0;
   let Inst{1,0} = 0b11;
 }


 //===----------------------------------------------------------------------===//
 // Branch and call instructions.
 //===----------------------------------------------------------------------===//

 let isBranch = 1, isTerminator = 1 in {
   let isBarrier = 1, isPredicable = 1 in
     def BR16 : J16<1, "br16", (ins br_symbol_16bit:$offset)>;

   def BT16 : J16_B<2, "bt16">;
   def BF16 : J16_B<3, "bf16">;
 }

 def JMP16 : R16_X_J<0b11100000, 0b00, "jmp16"> {
   let isBranch = 1;
   let isTerminator = 1;
   let isBarrier = 1;
   let isIndirectBranch = 1;
   let Pattern = [(brind sGPR:$rx)];
 }

 def JSR16 : R16_X_J<0b11101111, 0b01, "jsr16"> {
   let isCall = 1;
   let Defs = [ R15 ];
 }

 def RTS16 : CSKY16Inst<AddrModeNone, (outs), (ins), "rts16", [(CSKY_RET)]> {
   let isTerminator = 1;
   let isReturn = 1;
   let isBarrier = 1;
   let Inst = 0b0111100000111100;
   let Uses = [R15];
   let isCodeGenOnly = 1;
 }

 def JMPIX16 :  CSKY16Inst<AddrModeNone, (outs),
   (ins mGPR:$rx, uimm2_jmpix:$indeximm2), "jmpix16\t$rx, $indeximm2", []> {
   bits<3> rx;
   bits<2> indeximm2;
   let Inst{15,14} = 0b00;
   let Inst{13 - 11} = 0b111;
   let Inst{10 - 8} = rx;
   let Inst{7 - 2} = 0b111000;
   let Inst{1,0} = indeximm2;
   let Predicates = [HasJAVA];
   let Uses = [R30];
 }

 //===----------------------------------------------------------------------===//
 // Symbol address instructions.
 //===----------------------------------------------------------------------===//

 def LRW16 : CSKY16Inst<AddrModeNone, (outs mGPR:$rz),
   (ins constpool_symbol_16bit:$label), "lrw16\t$rz, $label", []> {
   bits<3> rz;
   bits<8> label;
   let Inst{15 - 13} = 0b000;
   let Inst{12} = label{7};
   let Inst{11,10} = 0b00;
   let Inst{9,8} = label{6,5};
   let Inst{7 - 5} = rz;
   let Inst{4 - 0} = label{4-0};
   let mayLoad = 1;
   let mayStore = 0;
 }

 def LRW16_Gen : CSKY16Inst<AddrModeNone, (outs mGPR:$rz),
   (ins bare_symbol:$src, constpool_symbol_16bit:$label),
   "lrw16\t$rz, $label", []> {
   bits<3> rz;
   bits<8> label;
   let Inst{15 - 13} = 0b000;
   let Inst{12} = label{7};
   let Inst{11,10} = 0b00;
   let Inst{9,8} = label{6,5};
   let Inst{7 - 5} = rz;
   let Inst{4 - 0} = label{4-0};
   let mayLoad = 1;
   let mayStore = 0;
   let isCodeGenOnly = 1;
 }


 //===----------------------------------------------------------------------===//
 // Other operation instructions.
 //===----------------------------------------------------------------------===//

 def REVB16 :  R16_XZ_UNOP<0b1110, 0b10, "revb16">;
 def REVH16 :  R16_XZ_UNOP<0b1110, 0b11, "revh16">;

 let isCodeGenOnly = 1 in
 def SETC16 : CSKY16Inst<AddrModeNone,
   (outs CARRY:$ca), (ins), "setc16", []> {
   let Inst{15, 14} = 0b01;
   let Inst{13 - 10} = 0b1001;
   let Inst{9 - 6} = 0;
   let Inst{5 - 2} = 0;
   let Inst{1, 0} = 0;
   let isCompare = 1;
 }

 let isCodeGenOnly = 1 in
 def CLRC16 : CSKY16Inst<AddrModeNone,
   (outs CARRY:$ca), (ins), "clrc16", []> {
   let Inst{15, 14} = 0b01;
   let Inst{13 - 10} = 0b1001;
   let Inst{9 - 6} = 0;
   let Inst{5 - 2} = 0;
   let Inst{1, 0} = 2;
   let isCompare = 1;
 }

 let Constraints = "$rZ = $rz" in {
   def BCLRI16 : I16_Z_5<0b100, (outs mGPR:$rz), (ins mGPR:$rZ, uimm5:$imm5),
                         "bclri16">;
   def BSETI16 : I16_Z_5<0b101, (outs mGPR:$rz), (ins mGPR:$rZ, uimm5:$imm5),
                         "bseti16">;
 }

 let Predicates = [HasBTST16] in
   def BTSTI16 : I16_Z_5<0b110, (outs CARRY:$ca), (ins mGPR:$rz, uimm5:$imm5),
                         "btsti16">;

 def TST16 : CSKY16Inst<AddrModeNone, (outs CARRY:$ca), (ins sGPR:$rx, sGPR:$ry),
                         "tst16\t$rx, $ry", []> {
   bits<4> ry;
   bits<4> rx;
   let Inst{15,14} = 0b01;
   let Inst{13 - 10} = 0b1010;
   let Inst{9 - 6} = ry;
   let Inst{5 - 2} = rx;
   let Inst{1,0} = 0b10;
   let isCompare = 1;
 }

 def TSTNBZ16 : CSKY16Inst<AddrModeNone, (outs CARRY:$ca), (ins sGPR:$rx),
                           "tstnbz16\t$rx", []> {
   bits<4> rx;
   let Inst{15,14} = 0b01;
   let Inst{13 - 10} = 0b1010;
   let Inst{9 - 6} = 0b0000;
   let Inst{5 - 2} = rx;
   let Inst{1,0} = 0b11;
   let isCompare = 1;
 }

 //===----------------------------------------------------------------------===//
 // Special instructions.
 //===----------------------------------------------------------------------===//

 def BKPT : CSKY16Inst<AddrModeNone, (outs), (ins), "bkpt", []> {
   let Inst = 0;
 }

 let mayStore = 1 in {
 def BPUSHH : I16_BPushPop<0b00010100111, 0, (outs), (ins mGPR:$rz), "bpush.h $rz">;
 def BPUSHW : I16_BPushPop<0b00010100111, 0b10, (outs), (ins mGPR:$rz), "bpush.w $rz">;
 }

 let mayLoad = 1 in {
 def BPOPH : I16_BPushPop<0b00010100101, 0, (outs mGPR:$rz), (ins),  "bpop.h $rz">;
 def BPOPW : I16_BPushPop<0b00010100101, 0b10, (outs mGPR:$rz), (ins), "bpop.w $rz">;
 }

 def NIE : CSKY16Inst<AddrModeNone, (outs), (ins), "nie", [(CSKY_NIE)]> {
   let Inst = 0b0001010001100000;
 }

 let isBarrier = 1, isReturn = 1, isTerminator = 1 in
 def NIR : CSKY16Inst<AddrModeNone, (outs), (ins), "nir", [(CSKY_NIR)]> {
   let Inst = 0b0001010001100001;
 }

 def IPUSH16 : CSKY16Inst<AddrModeNone, (outs), (ins), "ipush16", []> {
   let Inst{15- 5} = 0b00010100011;
   let Inst{4-0} = 0b00010;
   let Predicates = [iHasE1];
   let Defs  = [R14];
   let Uses  = [R14, R0, R1, R2, R3, R12, R13];
   let mayStore = 1;
 }

 def IPOP16 : CSKY16Inst<AddrModeNone, (outs), (ins), "ipop16", []> {
   let Inst{15- 5} = 0b00010100011;
   let Inst{4-0} = 0b00011;
   let Predicates = [iHasE1];
   let Defs  = [R14, R0, R1, R2, R3, R12, R13];
   let Uses  = [R14];
   let mayLoad = 1;
 }

 def PUSH16 : CSKY16Inst<AddrModeNone, (outs),
   (ins reglist:$regs, variable_ops), "push16 $regs", []> {
   bits<5> regs;

   let Inst{15- 5} = 0b00010100110;
   let Inst{4-0} = regs;
   let Predicates = [iHasE1];
   let Defs  = [R14];
   let Uses  = [R14];
   let mayStore = 1;
 }

 def POP16 : CSKY16Inst<AddrModeNone, (outs),
   (ins reglist:$regs, variable_ops), "pop16 $regs", []> {
   bits<5> regs;

   let Inst{15- 5} = 0b00010100100;
   let Inst{4-0} = regs;
   let Predicates = [iHasE1];
   let Defs  = [R14];
   let Uses  = [R14];
   let mayLoad = 1;
 }

 //===----------------------------------------------------------------------===//
 // CSKYPseudo
 //===----------------------------------------------------------------------===//

 let usesCustomInserter = 1 in  {
   def ISEL16 : CSKYPseudo<(outs sGPR:$dst),
     (ins CARRY:$cond, sGPR:$src1, sGPR:$src2),
     "!isel16\t$dst, $src1, src2",
     [(set sGPR:$dst, (select CARRY:$cond, sGPR:$src1, sGPR:$src2))]>;
 }

 class JBranchPseudo<dag out, dag ins, string opstr> :
   CSKYPseudo<out, ins, opstr, []> {
   let isBranch = 1;
   let isTerminator = 1;
   let isIndirectBranch = 1;
   let mayLoad = 1;
   let Size = 2;
 }

 let isBarrier = 1 in
 def JBR16 : JBranchPseudo<(outs),
   (ins br_symbol_16bit:$src1), "jbr16\t$src1">;
 def JBT16 : JBranchPseudo<(outs),
   (ins CARRY:$ca, br_symbol_16bit:$src1), "jbt16\t$src1">;
 def JBF16 : JBranchPseudo<(outs),
   (ins CARRY:$ca, br_symbol_16bit:$src1), "jbf16\t$src1">;

 let mayLoad = 1, Size = 2, isCodeGenOnly = 0 in
 def PseudoLRW16 : CSKYPseudo<(outs mGPR:$rz),
   (ins bare_symbol:$src), "lrw16 $rz, $src", []>;
	//===-- CSKYInstrInfo16Instr.td - CSKY 16-bit Instruction --- 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
	//
	//===----------------------------------------------------------------------===//
	//
	// This file describes the CSKY 16-bit instructions in TableGen format.
	//
	//===----------------------------------------------------------------------===//

	//===----------------------------------------------------------------------===//
	// CSKY specific DAG Nodes.
	//===----------------------------------------------------------------------===//

	// Target-dependent nodes.
	def CSKY_NIE : SDNode<"CSKYISD::NIE", SDTNone,
	[SDNPHasChain, SDNPOptInGlue]>;
	def CSKY_NIR : SDNode<"CSKYISD::NIR", SDTNone,
	[SDNPHasChain, SDNPOptInGlue]>;

	//===----------------------------------------------------------------------===//
	// Operand and SDNode transformation definitions.
	//===----------------------------------------------------------------------===//

	def br_symbol_16bit : Operand<iPTR> {
	let EncoderMethod =
	"getBranchSymbolOpValue<CSKY::fixup_csky_pcrel_imm10_scale2>";
	let ParserMatchClass = CSKYSymbol;
	let DecoderMethod = "decodeSImmOperand<10, 1>";
	let PrintMethod = "printCSKYSymbolOperand";
	let OperandType = "OPERAND_PCREL";
	}

	def SPOperand : AsmOperandClass {
	let Name = "SPOperand";
	let RenderMethod = "addRegOperands";
	let DiagnosticType = !strconcat("Invalid", Name);
	}

	def SPOp : RegisterOperand<GPR> {
	let ParserMatchClass = SPOperand;
	}

	def constpool_symbol_16bit : Operand<iPTR> {
	let ParserMatchClass = Constpool;
	let EncoderMethod =
	"getConstpoolSymbolOpValue<CSKY::fixup_csky_pcrel_uimm7_scale4>";
	let DecoderMethod = "decodeLRW16Imm8";
	let PrintMethod = "printConstpool";
	let OperandType = "OPERAND_PCREL";
	}

	//===----------------------------------------------------------------------===//
	// Instruction Formats
	//===----------------------------------------------------------------------===//

	include "CSKYInstrFormats16Instr.td"

	//===----------------------------------------------------------------------===//
	// Instruction definitions.
	//===----------------------------------------------------------------------===//

	//===----------------------------------------------------------------------===//
	// Basic ALU instructions.
	//===----------------------------------------------------------------------===//

	let isCommutable = 1, isAdd = 1 in
	def ADDU16 : R16_XYZ<0, "addu16", add>;
	let Pattern = [(set mGPR:$rz, (sub mGPR:$rx, mGPR:$ry))] in
	def SUBU16 : R16_XYZ<1, "subu16", sub>;

	let isCommutable = 1, isAdd = 1 in
	def ADDC16 : R16_XZ_BINOP_C<0b1000, 0b01, "addc16">;
	def SUBC16 : R16_XZ_BINOP_C<0b1000, 0b11, "subc16">;

	let isCommutable = 1 in {
	let isAdd = 1 in
	def ADDU16XZ : R16_XZ_BINOP<0b1000, 0b00, "addu16", BinOpFrag<(add node:$LHS, node:$RHS)>>;
	def AND16 : R16_XZ_BINOP<0b1010, 0b00, "and16", BinOpFrag<(and node:$LHS, node:$RHS)>>;
	def OR16 : R16_XZ_BINOP<0b1011, 0b00, "or16", BinOpFrag<(or node:$LHS, node:$RHS)>>;
	def XOR16 : R16_XZ_BINOP<0b1011, 0b01, "xor16", BinOpFrag<(xor node:$LHS, node:$RHS)>>;
	def NOR16 : R16_XZ_BINOP<0b1011, 0b10, "nor16", BinOpFrag<(not (or node:$LHS, node:$RHS))>>;
	let isCodeGenOnly = 1 in
	def NOT16 : R16_XZ_UNOP<0b1011, 0b10, "not16">;
	def MULT16 : R16_XZ_BINOP<0b1111, 0b00, "mult16", BinOpFrag<(mul node:$LHS, node:$RHS)>>;
	}
	def SUBU16XZ : R16_XZ_BINOP<0b1000, 0b10, "subu16", BinOpFrag<(sub node:$LHS, node:$RHS)>>;
	def ANDN16 : R16_XZ_BINOP<0b1010, 0b01, "andn16", BinOpFrag<(and node:$LHS, (not node:$RHS))>>;
	def LSL16 : R16_XZ_BINOP<0b1100, 0b00, "lsl16", BinOpFrag<(shl node:$LHS, node:$RHS)>>;
	def LSR16 : R16_XZ_BINOP<0b1100, 0b01, "lsr16", BinOpFrag<(srl node:$LHS, node:$RHS)>>;
	def ASR16 : R16_XZ_BINOP<0b1100, 0b10, "asr16", BinOpFrag<(sra node:$LHS, node:$RHS)>>;
	def ROTL16 : R16_XZ_BINOP<0b1100, 0b11, "rotl16", BinOpFrag<(rotl node:$LHS, (and node:$RHS, 0x1f))>>;

	def MULSH16 : R16_XZ_BINOP_NOPat<0b1111, 0b01, "mulsh16">;

	def ZEXTB16 : R16_XZ_UNOP<0b1101, 0b00, "zextb16">;
	def ZEXTH16 : R16_XZ_UNOP<0b1101, 0b01, "zexth16">;
	def SEXTB16 : R16_XZ_UNOP<0b1101, 0b10, "sextb16">;
	def SEXTH16 : R16_XZ_UNOP<0b1101, 0b11, "sexth16">;

	let Constraints = "$rZ = $rz", isReMaterializable = 1, isAsCheapAsAMove = 1 in {
	let isAdd = 1, Pattern = [(set mGPR:$rz, (add mGPR:$rZ, oimm8:$imm8))] in
	def ADDI16 : I16_Z_8<0b100, (ins mGPR:$rZ, oimm8:$imm8), "addi16\t$rz, $imm8">;
	let Pattern = [(set mGPR:$rz, (sub mGPR:$rZ, oimm8:$imm8))] in
	def SUBI16 : I16_Z_8<0b101, (ins mGPR:$rZ, oimm8:$imm8), "subi16\t$rz, $imm8">;
	}

	let isAdd = 1 in
	def ADDI16ZSP : I16_Z_8<0b011, (ins SPOp:$sp, uimm8_2:$imm8),
	"addi16\t$rz, $sp, $imm8">;

	let isAdd = 1 in
	def ADDI16SPSP : I16_SP_IMM7<0b000,"addi16">;
	def SUBI16SPSP : I16_SP_IMM7<0b001,"subi16">;

	let isReMaterializable = 1, isAsCheapAsAMove = 1 in {
	def LSLI16 : I16_XZ_IMM5<0, "lsli16", shl>;
	def LSRI16 : I16_XZ_IMM5<1, "lsri16", srl>;
	def ASRI16 : I16_XZ_IMM5<2, "asri16", sra>;
	}

	let isAdd = 1 in
	def ADDI16XZ : I16_XZ_IMM3<0b10, "addi16", add>;
	def SUBI16XZ : I16_XZ_IMM3<0b11, "subi16", sub>;

	let Size = 4 in
	def NEG16 : CSKYPseudo<(outs mGPR:$rd), (ins mGPR:$rx), "neg16 $rd, $rx", []>;

	let Size = 4 in
	def RSUBI16 : CSKYPseudo<(outs mGPR:$rd),
	(ins mGPR:$rx, uimm8:$imm8), "rsubi16 $rd, $rx, $imm8", []>;

	//===----------------------------------------------------------------------===//
	// Load & Store instructions.
	//===----------------------------------------------------------------------===//

	def LD16B : I16_XZ_LDST<AddrMode16B, 0b000, "ld16.b",
	(outs mGPR:$rz), (ins mGPR:$rx, uimm5:$imm)>;
	def LD16H : I16_XZ_LDST<AddrMode16H, 0b001, "ld16.h",
	(outs mGPR:$rz), (ins mGPR:$rx, uimm5_1:$imm)>;
	def LD16W : I16_XZ_LDST<AddrMode16W, 0b010, "ld16.w",
	(outs mGPR:$rz), (ins mGPR:$rx, uimm5_2:$imm)>;
	def ST16B : I16_XZ_LDST<AddrMode16B, 0b100, "st16.b",
	(outs), (ins mGPR:$rz, mGPR:$rx, uimm5:$imm)>;
	def ST16H : I16_XZ_LDST<AddrMode16H, 0b101, "st16.h",
	(outs), (ins mGPR:$rz, mGPR:$rx, uimm5_1:$imm)>;
	def ST16W : I16_XZ_LDST<AddrMode16W, 0b110, "st16.w",
	(outs), (ins mGPR:$rz, mGPR:$rx, uimm5_2:$imm)>;

	def LD16WSP : I16_ZSP_LDST<AddrMode16W, 0b011, "ld16.w",
	(outs mGPR:$rz), (ins SPOp:$sp, uimm8_2:$addr)>;
	def ST16WSP : I16_ZSP_LDST<AddrMode16W, 0b111, "st16.w",
	(outs), (ins mGPR:$rz, SPOp:$sp, uimm8_2:$addr)>;

	//===----------------------------------------------------------------------===//
	// Compare instructions.
	//===----------------------------------------------------------------------===//

	def CMPHS16 : R16_XY_CMP<0, "cmphs16">;
	def CMPLT16 : R16_XY_CMP<1, "cmplt16">;
	let isCommutable = 1 in
	def CMPNE16 : R16_XY_CMP<2, "cmpne16">;


	def CMPHSI16 : I16_X_CMP<0, "cmphsi16", oimm5>;
	def CMPLTI16 : I16_X_CMP<1, "cmplti16", oimm5>;
	def CMPLEI16 : CSKYPseudo<(outs CARRY:$ca), (ins mGPR:$rx, uimm5:$imm5),
	"cmplei16\t$rx, $imm5", []>;
	def CMPNEI16 : I16_X_CMP<2, "cmpnei16", uimm5>;

	//===----------------------------------------------------------------------===//
	// Data move instructions.
	//===----------------------------------------------------------------------===//


	def MOVI16 : I16_Z_8<0b110, (ins uimm8:$imm8), "movi16\t$rz, $imm8"> {
	let isReMaterializable = 1;
	let isAsCheapAsAMove = 1;
	let isMoveImm = 1;
	let Pattern = [(set mGPR:$rz, uimm8:$imm8)];
	}

	def MOV16 : CSKY16Inst<AddrModeNone, (outs sGPR:$rz), (ins sGPR:$rx),
	"mov16\t$rz, $rx", []> {
	bits<4> rz;
	bits<4> rx;
	let Inst{15,14} = 0b01;
	let Inst{13 - 10} = 0b1011;
	let Inst{9 - 6} = rz;
	let Inst{5 - 2} = rx;
	let Inst{1,0} = 0b11;
	}

	// MVC16 is not in "cskyv2 instructions reference manul"
	def MVCV16 : CSKY16Inst<AddrModeNone,
	(outs sGPR:$rz), (ins CARRY:$ca), "mvcv16\t$rz", []> {
	bits<4> rz;
	let Inst{15,14} = 0b01;
	let Inst{13 - 10} = 0b1001;
	let Inst{9 - 6} = rz;
	let Inst{5 - 2} = 0;
	let Inst{1,0} = 0b11;
	}


	//===----------------------------------------------------------------------===//
	// Branch and call instructions.
	//===----------------------------------------------------------------------===//

	let isBranch = 1, isTerminator = 1 in {
	let isBarrier = 1, isPredicable = 1 in
	def BR16 : J16<1, "br16", (ins br_symbol_16bit:$offset)>;

	def BT16 : J16_B<2, "bt16">;
	def BF16 : J16_B<3, "bf16">;
	}

	def JMP16 : R16_X_J<0b11100000, 0b00, "jmp16"> {
	let isBranch = 1;
	let isTerminator = 1;
	let isBarrier = 1;
	let isIndirectBranch = 1;
	let Pattern = [(brind sGPR:$rx)];
	}

	def JSR16 : R16_X_J<0b11101111, 0b01, "jsr16"> {
	let isCall = 1;
	let Defs = [ R15 ];
	}

	def RTS16 : CSKY16Inst<AddrModeNone, (outs), (ins), "rts16", [(CSKY_RET)]> {
	let isTerminator = 1;
	let isReturn = 1;
	let isBarrier = 1;
	let Inst = 0b0111100000111100;
	let Uses = [R15];
	let isCodeGenOnly = 1;
	}

	def JMPIX16 : CSKY16Inst<AddrModeNone, (outs),
	(ins mGPR:$rx, uimm2_jmpix:$indeximm2), "jmpix16\t$rx, $indeximm2", []> {
	bits<3> rx;
	bits<2> indeximm2;
	let Inst{15,14} = 0b00;
	let Inst{13 - 11} = 0b111;
	let Inst{10 - 8} = rx;
	let Inst{7 - 2} = 0b111000;
	let Inst{1,0} = indeximm2;
	let Predicates = [HasJAVA];
	let Uses = [R30];
	}

	//===----------------------------------------------------------------------===//
	// Symbol address instructions.
	//===----------------------------------------------------------------------===//

	def LRW16 : CSKY16Inst<AddrModeNone, (outs mGPR:$rz),
	(ins constpool_symbol_16bit:$label), "lrw16\t$rz, $label", []> {
	bits<3> rz;
	bits<8> label;
	let Inst{15 - 13} = 0b000;
	let Inst{12} = label{7};
	let Inst{11,10} = 0b00;
	let Inst{9,8} = label{6,5};
	let Inst{7 - 5} = rz;
	let Inst{4 - 0} = label{4-0};
	let mayLoad = 1;
	let mayStore = 0;
	}

	def LRW16_Gen : CSKY16Inst<AddrModeNone, (outs mGPR:$rz),
	(ins bare_symbol:$src, constpool_symbol_16bit:$label),
	"lrw16\t$rz, $label", []> {
	bits<3> rz;
	bits<8> label;
	let Inst{15 - 13} = 0b000;
	let Inst{12} = label{7};
	let Inst{11,10} = 0b00;
	let Inst{9,8} = label{6,5};
	let Inst{7 - 5} = rz;
	let Inst{4 - 0} = label{4-0};
	let mayLoad = 1;
	let mayStore = 0;
	let isCodeGenOnly = 1;
	}


	//===----------------------------------------------------------------------===//
	// Other operation instructions.
	//===----------------------------------------------------------------------===//

	def REVB16 : R16_XZ_UNOP<0b1110, 0b10, "revb16">;
	def REVH16 : R16_XZ_UNOP<0b1110, 0b11, "revh16">;

	let isCodeGenOnly = 1 in
	def SETC16 : CSKY16Inst<AddrModeNone,
	(outs CARRY:$ca), (ins), "setc16", []> {
	let Inst{15, 14} = 0b01;
	let Inst{13 - 10} = 0b1001;
	let Inst{9 - 6} = 0;
	let Inst{5 - 2} = 0;
	let Inst{1, 0} = 0;
	let isCompare = 1;
	}

	let isCodeGenOnly = 1 in
	def CLRC16 : CSKY16Inst<AddrModeNone,
	(outs CARRY:$ca), (ins), "clrc16", []> {
	let Inst{15, 14} = 0b01;
	let Inst{13 - 10} = 0b1001;
	let Inst{9 - 6} = 0;
	let Inst{5 - 2} = 0;
	let Inst{1, 0} = 2;
	let isCompare = 1;
	}

	let Constraints = "$rZ = $rz" in {
	def BCLRI16 : I16_Z_5<0b100, (outs mGPR:$rz), (ins mGPR:$rZ, uimm5:$imm5),
	"bclri16">;
	def BSETI16 : I16_Z_5<0b101, (outs mGPR:$rz), (ins mGPR:$rZ, uimm5:$imm5),
	"bseti16">;
	}

	let Predicates = [HasBTST16] in
	def BTSTI16 : I16_Z_5<0b110, (outs CARRY:$ca), (ins mGPR:$rz, uimm5:$imm5),
	"btsti16">;

	def TST16 : CSKY16Inst<AddrModeNone, (outs CARRY:$ca), (ins sGPR:$rx, sGPR:$ry),
	"tst16\t$rx, $ry", []> {
	bits<4> ry;
	bits<4> rx;
	let Inst{15,14} = 0b01;
	let Inst{13 - 10} = 0b1010;
	let Inst{9 - 6} = ry;
	let Inst{5 - 2} = rx;
	let Inst{1,0} = 0b10;
	let isCompare = 1;
	}

	def TSTNBZ16 : CSKY16Inst<AddrModeNone, (outs CARRY:$ca), (ins sGPR:$rx),
	"tstnbz16\t$rx", []> {
	bits<4> rx;
	let Inst{15,14} = 0b01;
	let Inst{13 - 10} = 0b1010;
	let Inst{9 - 6} = 0b0000;
	let Inst{5 - 2} = rx;
	let Inst{1,0} = 0b11;
	let isCompare = 1;
	}

	//===----------------------------------------------------------------------===//
	// Special instructions.
	//===----------------------------------------------------------------------===//

	def BKPT : CSKY16Inst<AddrModeNone, (outs), (ins), "bkpt", []> {
	let Inst = 0;
	}

	let mayStore = 1 in {
	def BPUSHH : I16_BPushPop<0b00010100111, 0, (outs), (ins mGPR:$rz), "bpush.h $rz">;
	def BPUSHW : I16_BPushPop<0b00010100111, 0b10, (outs), (ins mGPR:$rz), "bpush.w $rz">;
	}

	let mayLoad = 1 in {
	def BPOPH : I16_BPushPop<0b00010100101, 0, (outs mGPR:$rz), (ins), "bpop.h $rz">;
	def BPOPW : I16_BPushPop<0b00010100101, 0b10, (outs mGPR:$rz), (ins), "bpop.w $rz">;
	}

	def NIE : CSKY16Inst<AddrModeNone, (outs), (ins), "nie", [(CSKY_NIE)]> {
	let Inst = 0b0001010001100000;
	}

	let isBarrier = 1, isReturn = 1, isTerminator = 1 in
	def NIR : CSKY16Inst<AddrModeNone, (outs), (ins), "nir", [(CSKY_NIR)]> {
	let Inst = 0b0001010001100001;
	}

	def IPUSH16 : CSKY16Inst<AddrModeNone, (outs), (ins), "ipush16", []> {
	let Inst{15- 5} = 0b00010100011;
	let Inst{4-0} = 0b00010;
	let Predicates = [iHasE1];
	let Defs = [R14];
	let Uses = [R14, R0, R1, R2, R3, R12, R13];
	let mayStore = 1;
	}

	def IPOP16 : CSKY16Inst<AddrModeNone, (outs), (ins), "ipop16", []> {
	let Inst{15- 5} = 0b00010100011;
	let Inst{4-0} = 0b00011;
	let Predicates = [iHasE1];
	let Defs = [R14, R0, R1, R2, R3, R12, R13];
	let Uses = [R14];
	let mayLoad = 1;
	}

	def PUSH16 : CSKY16Inst<AddrModeNone, (outs),
	(ins reglist:$regs, variable_ops), "push16 $regs", []> {
	bits<5> regs;

	let Inst{15- 5} = 0b00010100110;
	let Inst{4-0} = regs;
	let Predicates = [iHasE1];
	let Defs = [R14];
	let Uses = [R14];
	let mayStore = 1;
	}

	def POP16 : CSKY16Inst<AddrModeNone, (outs),
	(ins reglist:$regs, variable_ops), "pop16 $regs", []> {
	bits<5> regs;

	let Inst{15- 5} = 0b00010100100;
	let Inst{4-0} = regs;
	let Predicates = [iHasE1];
	let Defs = [R14];
	let Uses = [R14];
	let mayLoad = 1;
	}

	//===----------------------------------------------------------------------===//
	// CSKYPseudo
	//===----------------------------------------------------------------------===//

	let usesCustomInserter = 1 in {
	def ISEL16 : CSKYPseudo<(outs sGPR:$dst),
	(ins CARRY:$cond, sGPR:$src1, sGPR:$src2),
	"!isel16\t$dst, $src1, src2",
	[(set sGPR:$dst, (select CARRY:$cond, sGPR:$src1, sGPR:$src2))]>;
	}

	class JBranchPseudo<dag out, dag ins, string opstr> :
	CSKYPseudo<out, ins, opstr, []> {
	let isBranch = 1;
	let isTerminator = 1;
	let isIndirectBranch = 1;
	let mayLoad = 1;
	let Size = 2;
	}

	let isBarrier = 1 in
	def JBR16 : JBranchPseudo<(outs),
	(ins br_symbol_16bit:$src1), "jbr16\t$src1">;
	def JBT16 : JBranchPseudo<(outs),
	(ins CARRY:$ca, br_symbol_16bit:$src1), "jbt16\t$src1">;
	def JBF16 : JBranchPseudo<(outs),
	(ins CARRY:$ca, br_symbol_16bit:$src1), "jbf16\t$src1">;

	let mayLoad = 1, Size = 2, isCodeGenOnly = 0 in
	def PseudoLRW16 : CSKYPseudo<(outs mGPR:$rz),
	(ins bare_symbol:$src), "lrw16 $rz, $src", []>;