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git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@11095 91177308-0d34-0410-b5e6-96231b3b80d8
521 lines
26 KiB
C++
521 lines
26 KiB
C++
//===- X86InstrInfo.td - Describe the X86 Instruction Set -------*- C++ -*-===//
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//
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// The LLVM Compiler Infrastructure
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//
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// This file was developed by the LLVM research group and is distributed under
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// the University of Illinois Open Source License. See LICENSE.TXT for details.
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//
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//===----------------------------------------------------------------------===//
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//
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// This file describes the X86 instruction set, defining the instructions, and
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// properties of the instructions which are needed for code generation, machine
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// code emission, and analysis.
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//
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//===----------------------------------------------------------------------===//
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// Format specifies the encoding used by the instruction. This is part of the
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// ad-hoc solution used to emit machine instruction encodings by our machine
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// code emitter.
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class Format<bits<5> val> {
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bits<5> Value = val;
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}
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def Pseudo : Format<0>; def RawFrm : Format<1>;
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def AddRegFrm : Format<2>; def MRMDestReg : Format<3>;
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def MRMDestMem : Format<4>; def MRMSrcReg : Format<5>;
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def MRMSrcMem : Format<6>;
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def MRMS0r : Format<16>; def MRMS1r : Format<17>; def MRMS2r : Format<18>;
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def MRMS3r : Format<19>; def MRMS4r : Format<20>; def MRMS5r : Format<21>;
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def MRMS6r : Format<22>; def MRMS7r : Format<23>;
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def MRMS0m : Format<24>; def MRMS1m : Format<25>; def MRMS2m : Format<26>;
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def MRMS3m : Format<27>; def MRMS4m : Format<28>; def MRMS5m : Format<29>;
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def MRMS6m : Format<30>; def MRMS7m : Format<31>;
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// ArgType - This specifies the argument type used by an instruction. This is
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// part of the ad-hoc solution used to emit machine instruction encodings by our
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// machine code emitter.
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class ArgType<bits<3> val> {
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bits<3> Value = val;
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}
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def NoArg : ArgType<0>;
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def Arg8 : ArgType<1>;
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def Arg16 : ArgType<2>;
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def Arg32 : ArgType<3>;
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def Arg64 : ArgType<4>; // 64 bit int argument for FILD64
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def ArgF32 : ArgType<5>;
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def ArgF64 : ArgType<6>;
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def ArgF80 : ArgType<6>;
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// FPFormat - This specifies what form this FP instruction has. This is used by
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// the Floating-Point stackifier pass.
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class FPFormat<bits<3> val> {
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bits<3> Value = val;
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}
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def NotFP : FPFormat<0>;
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def ZeroArgFP : FPFormat<1>;
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def OneArgFP : FPFormat<2>;
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def OneArgFPRW : FPFormat<3>;
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def TwoArgFP : FPFormat<4>;
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def SpecialFP : FPFormat<5>;
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class X86Inst<string nam, bits<8> opcod, Format f, ArgType a> : Instruction {
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let Namespace = "X86";
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let Name = nam;
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bits<8> Opcode = opcod;
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Format Form = f;
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bits<5> FormBits = Form.Value;
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ArgType Type = a;
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bits<3> TypeBits = Type.Value;
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// Attributes specific to X86 instructions...
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bit hasOpSizePrefix = 0; // Does this inst have a 0x66 prefix?
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bit printImplicitUses = 0; // Should we print implicit uses of this inst?
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bits<4> Prefix = 0; // Which prefix byte does this inst have?
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FPFormat FPForm; // What flavor of FP instruction is this?
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bits<3> FPFormBits = 0;
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}
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class Imp<list<Register> uses, list<Register> defs> {
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list<Register> Uses = uses;
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list<Register> Defs = defs;
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}
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class Pattern<dag P> {
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dag Pattern = P;
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}
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// Prefix byte classes which are used to indicate to the ad-hoc machine code
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// emitter that various prefix bytes are required.
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class OpSize { bit hasOpSizePrefix = 1; }
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class TB { bits<4> Prefix = 1; }
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class D8 { bits<4> Prefix = 2; }
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class D9 { bits<4> Prefix = 3; }
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class DA { bits<4> Prefix = 4; }
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class DB { bits<4> Prefix = 5; }
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class DC { bits<4> Prefix = 6; }
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class DD { bits<4> Prefix = 7; }
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class DE { bits<4> Prefix = 8; }
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class DF { bits<4> Prefix = 9; }
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//===----------------------------------------------------------------------===//
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// Instruction list...
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//
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def PHI : X86Inst<"PHI", 0, Pseudo, NoArg>; // PHI node...
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def NOOP : X86Inst<"nop", 0x90, RawFrm, NoArg>; // nop
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def ADJCALLSTACKDOWN : X86Inst<"ADJCALLSTACKDOWN", 0, Pseudo, NoArg>;
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def ADJCALLSTACKUP : X86Inst<"ADJCALLSTACKUP", 0, Pseudo, NoArg>;
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def IMPLICIT_USE : X86Inst<"IMPLICIT_USE", 0, Pseudo, NoArg>;
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def IMPLICIT_DEF : X86Inst<"IMPLICIT_DEF", 0, Pseudo, NoArg>;
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let isTerminator = 1 in
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let Defs = [FP0, FP1, FP2, FP3, FP4, FP5, FP6] in
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def FP_REG_KILL : X86Inst<"FP_REG_KILL", 0, Pseudo, NoArg>;
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//===----------------------------------------------------------------------===//
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// Control Flow Instructions...
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//
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// Return instruction...
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let isTerminator = 1, isReturn = 1 in
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def RET : X86Inst<"ret", 0xC3, RawFrm, NoArg>, Pattern<(retvoid)>;
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// All branches are RawFrm, Void, Branch, and Terminators
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let isBranch = 1, isTerminator = 1 in
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class IBr<string name, bits<8> opcode> : X86Inst<name, opcode, RawFrm, NoArg>;
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def JMP : IBr<"jmp", 0xE9>, Pattern<(br basicblock)>;
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def JB : IBr<"jb" , 0x82>, TB;
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def JAE : IBr<"jae", 0x83>, TB;
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def JE : IBr<"je" , 0x84>, TB, Pattern<(isVoid (unspec1 basicblock))>;
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def JNE : IBr<"jne", 0x85>, TB;
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def JBE : IBr<"jbe", 0x86>, TB;
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def JA : IBr<"ja" , 0x87>, TB;
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def JS : IBr<"js" , 0x88>, TB;
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def JNS : IBr<"jns", 0x89>, TB;
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def JL : IBr<"jl" , 0x8C>, TB;
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def JGE : IBr<"jge", 0x8D>, TB;
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def JLE : IBr<"jle", 0x8E>, TB;
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def JG : IBr<"jg" , 0x8F>, TB;
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//===----------------------------------------------------------------------===//
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// Call Instructions...
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//
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let isCall = 1 in
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// All calls clobber the non-callee saved registers...
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let Defs = [EAX, ECX, EDX, FP0, FP1, FP2, FP3, FP4, FP5, FP6] in {
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def CALLpcrel32 : X86Inst<"call", 0xE8, RawFrm, NoArg>;
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def CALLr32 : X86Inst<"call", 0xFF, MRMS2r, Arg32>;
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def CALLm32 : X86Inst<"call", 0xFF, MRMS2m, Arg32>;
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}
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//===----------------------------------------------------------------------===//
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// Miscellaneous Instructions...
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//
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def LEAVE : X86Inst<"leave", 0xC9, RawFrm, NoArg>, Imp<[EBP], [EBP]>;
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let isTwoAddress = 1 in // R32 = bswap R32
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def BSWAPr32 : X86Inst<"bswap", 0xC8, AddRegFrm, Arg32>, TB;
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def XCHGrr8 : X86Inst<"xchg", 0x86, MRMDestReg, Arg8>; // xchg R8, R8
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def XCHGrr16 : X86Inst<"xchg", 0x87, MRMDestReg, Arg16>, OpSize;// xchg R16, R16
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def XCHGrr32 : X86Inst<"xchg", 0x87, MRMDestReg, Arg32>; // xchg R32, R32
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def LEAr16 : X86Inst<"lea", 0x8D, MRMSrcMem, Arg16>, OpSize; // R16 = lea [mem]
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def LEAr32 : X86Inst<"lea", 0x8D, MRMSrcMem, Arg32>; // R32 = lea [mem]
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//===----------------------------------------------------------------------===//
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// Move Instructions...
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//
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def MOVrr8 : X86Inst<"mov", 0x88, MRMDestReg, Arg8>, Pattern<(set R8 , R8 )>;
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def MOVrr16 : X86Inst<"mov", 0x89, MRMDestReg, Arg16>, OpSize, Pattern<(set R16, R16)>;
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def MOVrr32 : X86Inst<"mov", 0x89, MRMDestReg, Arg32>, Pattern<(set R32, R32)>;
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def MOVir8 : X86Inst<"mov", 0xB0, AddRegFrm , Arg8>, Pattern<(set R8 , imm )>;
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def MOVir16 : X86Inst<"mov", 0xB8, AddRegFrm , Arg16>, OpSize, Pattern<(set R16, imm)>;
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def MOVir32 : X86Inst<"mov", 0xB8, AddRegFrm , Arg32>, Pattern<(set R32, imm)>;
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def MOVim8 : X86Inst<"mov", 0xC6, MRMS0m , Arg8>; // [mem] = imm8
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def MOVim16 : X86Inst<"mov", 0xC7, MRMS0m , Arg16>, OpSize; // [mem] = imm16
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def MOVim32 : X86Inst<"mov", 0xC7, MRMS0m , Arg32>; // [mem] = imm32
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def MOVmr8 : X86Inst<"mov", 0x8A, MRMSrcMem , Arg8>; // R8 = [mem]
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def MOVmr16 : X86Inst<"mov", 0x8B, MRMSrcMem , Arg16>, OpSize, // R16 = [mem]
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Pattern<(set R16, (load (plus R32, (plus (times imm, R32), imm))))>;
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def MOVmr32 : X86Inst<"mov", 0x8B, MRMSrcMem , Arg32>, // R32 = [mem]
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Pattern<(set R32, (load (plus R32, (plus (times imm, R32), imm))))>;
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def MOVrm8 : X86Inst<"mov", 0x88, MRMDestMem, Arg8>; // [mem] = R8
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def MOVrm16 : X86Inst<"mov", 0x89, MRMDestMem, Arg16>, OpSize; // [mem] = R16
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def MOVrm32 : X86Inst<"mov", 0x89, MRMDestMem, Arg32>; // [mem] = R32
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//===----------------------------------------------------------------------===//
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// Fixed-Register Multiplication and Division Instructions...
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//
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// Extra precision multiplication
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def MULr8 : X86Inst<"mul", 0xF6, MRMS4r, Arg8 >, Imp<[AL],[AX]>; // AL,AH = AL*R8
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def MULr16 : X86Inst<"mul", 0xF7, MRMS4r, Arg16>, Imp<[AX],[AX,DX]>, OpSize; // AX,DX = AX*R16
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def MULr32 : X86Inst<"mul", 0xF7, MRMS4r, Arg32>, Imp<[EAX],[EAX,EDX]>; // EAX,EDX = EAX*R32
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// unsigned division/remainder
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def DIVr8 : X86Inst<"div", 0xF6, MRMS6r, Arg8 >, Imp<[AX],[AX]>; // AX/r8 = AL,AH
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def DIVr16 : X86Inst<"div", 0xF7, MRMS6r, Arg16>, Imp<[AX,DX],[AX,DX]>, OpSize; // DX:AX/r16 = AX,DX
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def DIVr32 : X86Inst<"div", 0xF7, MRMS6r, Arg32>, Imp<[EAX,EDX],[EAX,EDX]>; // EDX:EAX/r32 = EAX,EDX
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// signed division/remainder
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def IDIVr8 : X86Inst<"idiv",0xF6, MRMS7r, Arg8 >, Imp<[AX],[AX]>; // AX/r8 = AL,AH
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def IDIVr16: X86Inst<"idiv",0xF7, MRMS7r, Arg16>, Imp<[AX,DX],[AX,DX]>, OpSize; // DX:AX/r16 = AX,DX
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def IDIVr32: X86Inst<"idiv",0xF7, MRMS7r, Arg32>, Imp<[EAX,EDX],[EAX,EDX]>; // EDX:EAX/r32 = EAX,EDX
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// Sign-extenders for division
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def CBW : X86Inst<"cbw", 0x98, RawFrm, Arg8 >, Imp<[AL],[AH]>; // AX = signext(AL)
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def CWD : X86Inst<"cwd", 0x99, RawFrm, Arg8 >, Imp<[AX],[DX]>; // DX:AX = signext(AX)
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def CDQ : X86Inst<"cdq", 0x99, RawFrm, Arg8 >, Imp<[EAX],[EDX]>; // EDX:EAX = signext(EAX)
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//===----------------------------------------------------------------------===//
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// Two address Instructions...
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//
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let isTwoAddress = 1 in { // Define some helper classes to make defs shorter.
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class I2A8 <string n, bits<8> o, Format F> : X86Inst<n, o, F, Arg8>;
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class I2A16<string n, bits<8> o, Format F> : X86Inst<n, o, F, Arg16>;
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class I2A32<string n, bits<8> o, Format F> : X86Inst<n, o, F, Arg32>;
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}
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// unary instructions
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def NEGr8 : I2A8 <"neg", 0xF6, MRMS3r>; // R8 = -R8 = 0-R8
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def NEGr16 : I2A16<"neg", 0xF7, MRMS3r>, OpSize; // R16 = -R16 = 0-R16
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def NEGr32 : I2A32<"neg", 0xF7, MRMS3r>; // R32 = -R32 = 0-R32
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def NOTr8 : I2A8 <"not", 0xF6, MRMS2r>; // R8 = ~R8 = R8^-1
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def NOTr16 : I2A16<"not", 0xF7, MRMS2r>, OpSize; // R16 = ~R16 = R16^-1
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def NOTr32 : I2A32<"not", 0xF7, MRMS2r>; // R32 = ~R32 = R32^-1
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def INCr8 : I2A8 <"inc", 0xFE, MRMS0r>; // R8 = R8 +1
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def INCr16 : I2A16<"inc", 0xFF, MRMS0r>, OpSize; // R16 = R16+1
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def INCr32 : I2A32<"inc", 0xFF, MRMS0r>; // R32 = R32+1
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def DECr8 : I2A8 <"dec", 0xFE, MRMS1r>; // R8 = R8 -1
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def DECr16 : I2A16<"dec", 0xFF, MRMS1r>, OpSize; // R16 = R16-1
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def DECr32 : I2A32<"dec", 0xFF, MRMS1r>; // R32 = R32-1
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// Arithmetic...
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def ADDrr8 : I2A8 <"add", 0x00, MRMDestReg>, Pattern<(set R8 , (plus R8 , R8 ))>;
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def ADDrr16 : I2A16<"add", 0x01, MRMDestReg>, OpSize, Pattern<(set R16, (plus R16, R16))>;
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def ADDrr32 : I2A32<"add", 0x01, MRMDestReg>, Pattern<(set R32, (plus R32, R32))>;
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def ADDri8 : I2A8 <"add", 0x80, MRMS0r >, Pattern<(set R8 , (plus R8 , imm))>;
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def ADDri16 : I2A16<"add", 0x81, MRMS0r >, OpSize, Pattern<(set R16, (plus R16, imm))>;
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def ADDri32 : I2A32<"add", 0x81, MRMS0r >, Pattern<(set R32, (plus R32, imm))>;
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def ADDri16b : I2A8 <"add", 0x83, MRMS0r >, OpSize; // ADDri with sign extended 8 bit imm
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def ADDri32b : I2A8 <"add", 0x83, MRMS0r >;
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def ADCrr32 : I2A32<"adc", 0x11, MRMDestReg>; // R32 += imm32+Carry
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def SUBrr8 : I2A8 <"sub", 0x28, MRMDestReg>, Pattern<(set R8 , (minus R8 , R8 ))>;
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def SUBrr16 : I2A16<"sub", 0x29, MRMDestReg>, OpSize, Pattern<(set R16, (minus R16, R16))>;
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def SUBrr32 : I2A32<"sub", 0x29, MRMDestReg>, Pattern<(set R32, (minus R32, R32))>;
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def SUBri8 : I2A8 <"sub", 0x80, MRMS5r >, Pattern<(set R8 , (minus R8 , imm))>;
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def SUBri16 : I2A16<"sub", 0x81, MRMS5r >, OpSize, Pattern<(set R16, (minus R16, imm))>;
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def SUBri32 : I2A32<"sub", 0x81, MRMS5r >, Pattern<(set R32, (minus R32, imm))>;
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def SUBri16b : I2A8 <"sub", 0x83, MRMS5r >, OpSize;
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def SUBri32b : I2A8 <"sub", 0x83, MRMS5r >;
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def SBBrr32 : I2A32<"sbb", 0x19, MRMDestReg>; // R32 -= R32+Carry
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def IMULrr16 : I2A16<"imul", 0xAF, MRMSrcReg>, TB, OpSize, Pattern<(set R16, (times R16, R16))>;
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def IMULrr32 : I2A32<"imul", 0xAF, MRMSrcReg>, TB , Pattern<(set R32, (times R32, R32))>;
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def IMULri16 : I2A16<"imul", 0x69, MRMSrcReg>, OpSize;
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def IMULri32 : I2A32<"imul", 0x69, MRMSrcReg>;
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def IMULri16b : I2A8<"imul", 0x6B, MRMSrcReg>, OpSize;
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def IMULri32b : I2A8<"imul", 0x6B, MRMSrcReg>;
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// Logical operators...
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def ANDrr8 : I2A8 <"and", 0x20, MRMDestReg>, Pattern<(set R8 , (and R8 , R8 ))>;
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def ANDrr16 : I2A16<"and", 0x21, MRMDestReg>, OpSize, Pattern<(set R16, (and R16, R16))>;
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def ANDrr32 : I2A32<"and", 0x21, MRMDestReg>, Pattern<(set R32, (and R32, R32))>;
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def ANDri8 : I2A8 <"and", 0x80, MRMS4r >, Pattern<(set R8 , (and R8 , imm))>;
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def ANDri16 : I2A16<"and", 0x81, MRMS4r >, OpSize, Pattern<(set R16, (and R16, imm))>;
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def ANDri32 : I2A32<"and", 0x81, MRMS4r >, Pattern<(set R32, (and R32, imm))>;
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def ANDri16b : I2A8 <"and", 0x83, MRMS4r >, OpSize;
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def ANDri32b : I2A8 <"and", 0x83, MRMS4r >;
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def ORrr8 : I2A8 <"or" , 0x08, MRMDestReg>, Pattern<(set R8 , (or R8 , R8 ))>;
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def ORrr16 : I2A16<"or" , 0x09, MRMDestReg>, OpSize, Pattern<(set R16, (or R16, R16))>;
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def ORrr32 : I2A32<"or" , 0x09, MRMDestReg>, Pattern<(set R32, (or R32, R32))>;
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def ORri8 : I2A8 <"or" , 0x80, MRMS1r >, Pattern<(set R8 , (or R8 , imm))>;
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def ORri16 : I2A16<"or" , 0x81, MRMS1r >, OpSize, Pattern<(set R16, (or R16, imm))>;
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def ORri32 : I2A32<"or" , 0x81, MRMS1r >, Pattern<(set R32, (or R32, imm))>;
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def ORri16b : I2A8 <"or" , 0x83, MRMS1r >, OpSize;
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def ORri32b : I2A8 <"or" , 0x83, MRMS1r >;
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def XORrr8 : I2A8 <"xor", 0x30, MRMDestReg>, Pattern<(set R8 , (xor R8 , R8 ))>;
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def XORrr16 : I2A16<"xor", 0x31, MRMDestReg>, OpSize, Pattern<(set R16, (xor R16, R16))>;
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def XORrr32 : I2A32<"xor", 0x31, MRMDestReg>, Pattern<(set R32, (xor R32, R32))>;
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def XORri8 : I2A8 <"xor", 0x80, MRMS6r >, Pattern<(set R8 , (xor R8 , imm))>;
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def XORri16 : I2A16<"xor", 0x81, MRMS6r >, OpSize, Pattern<(set R16, (xor R16, imm))>;
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def XORri32 : I2A32<"xor", 0x81, MRMS6r >, Pattern<(set R32, (xor R32, imm))>;
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def XORri16b : I2A8 <"xor", 0x83, MRMS6r >, OpSize;
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def XORri32b : I2A8 <"xor", 0x83, MRMS6r >;
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// Test instructions are just like AND, except they don't generate a result.
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def TESTrr8 : X86Inst<"test", 0x84, MRMDestReg, Arg8 >; // flags = R8 & R8
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def TESTrr16 : X86Inst<"test", 0x85, MRMDestReg, Arg16>, OpSize; // flags = R16 & R16
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def TESTrr32 : X86Inst<"test", 0x85, MRMDestReg, Arg32>; // flags = R32 & R32
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def TESTri8 : X86Inst<"test", 0xF6, MRMS0r , Arg8 >; // flags = R8 & imm8
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def TESTri16 : X86Inst<"test", 0xF7, MRMS0r , Arg16>, OpSize; // flags = R16 & imm16
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def TESTri32 : X86Inst<"test", 0xF7, MRMS0r , Arg32>; // flags = R32 & imm32
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// Shift instructions
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class UsesCL { list<Register> Uses = [CL]; bit printImplicitUses = 1; }
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def SHLrr8 : I2A8 <"shl", 0xD2, MRMS4r > , UsesCL; // R8 <<= cl
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def SHLrr16 : I2A8 <"shl", 0xD3, MRMS4r >, OpSize, UsesCL; // R16 <<= cl
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def SHLrr32 : I2A8 <"shl", 0xD3, MRMS4r > , UsesCL; // R32 <<= cl
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def SHLir8 : I2A8 <"shl", 0xC0, MRMS4r >; // R8 <<= imm8
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def SHLir16 : I2A8 <"shl", 0xC1, MRMS4r >, OpSize; // R16 <<= imm16
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def SHLir32 : I2A8 <"shl", 0xC1, MRMS4r >; // R32 <<= imm32
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def SHRrr8 : I2A8 <"shr", 0xD2, MRMS5r > , UsesCL; // R8 >>= cl
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def SHRrr16 : I2A8 <"shr", 0xD3, MRMS5r >, OpSize, UsesCL; // R16 >>= cl
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def SHRrr32 : I2A8 <"shr", 0xD3, MRMS5r > , UsesCL; // R32 >>= cl
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def SHRir8 : I2A8 <"shr", 0xC0, MRMS5r >; // R8 >>= imm8
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def SHRir16 : I2A8 <"shr", 0xC1, MRMS5r >, OpSize; // R16 >>= imm16
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def SHRir32 : I2A8 <"shr", 0xC1, MRMS5r >; // R32 >>= imm32
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def SARrr8 : I2A8 <"sar", 0xD2, MRMS7r > , UsesCL; // R8 >>>= cl
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def SARrr16 : I2A8 <"sar", 0xD3, MRMS7r >, OpSize, UsesCL; // R16 >>>= cl
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def SARrr32 : I2A8 <"sar", 0xD3, MRMS7r > , UsesCL; // R32 >>>= cl
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def SARir8 : I2A8 <"sar", 0xC0, MRMS7r >; // R8 >>>= imm8
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def SARir16 : I2A8 <"sar", 0xC1, MRMS7r >, OpSize; // R16 >>>= imm16
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def SARir32 : I2A8 <"sar", 0xC1, MRMS7r >; // R32 >>>= imm32
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def SHLDrr32 : I2A8 <"shld", 0xA5, MRMDestReg>, TB, UsesCL; // R32 <<= R32,R32 cl
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def SHLDir32 : I2A8 <"shld", 0xA4, MRMDestReg>, TB; // R32 <<= R32,R32 imm8
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def SHRDrr32 : I2A8 <"shrd", 0xAD, MRMDestReg>, TB, UsesCL; // R32 >>= R32,R32 cl
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def SHRDir32 : I2A8 <"shrd", 0xAC, MRMDestReg>, TB; // R32 >>= R32,R32 imm8
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// Condition code ops, incl. set if equal/not equal/...
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def SAHF : X86Inst<"sahf" , 0x9E, RawFrm, Arg8>, Imp<[AH],[]>; // flags = AH
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def SETBr : X86Inst<"setb" , 0x92, MRMS0r, Arg8>, TB; // R8 = < unsign
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def SETAEr : X86Inst<"setae", 0x93, MRMS0r, Arg8>, TB; // R8 = >= unsign
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def SETEr : X86Inst<"sete" , 0x94, MRMS0r, Arg8>, TB; // R8 = ==
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def SETNEr : X86Inst<"setne", 0x95, MRMS0r, Arg8>, TB; // R8 = !=
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def SETBEr : X86Inst<"setbe", 0x96, MRMS0r, Arg8>, TB; // R8 = <= unsign
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def SETAr : X86Inst<"seta" , 0x97, MRMS0r, Arg8>, TB; // R8 = > signed
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def SETSr : X86Inst<"sets" , 0x98, MRMS0r, Arg8>, TB; // R8 = <sign bit>
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def SETNSr : X86Inst<"setns", 0x99, MRMS0r, Arg8>, TB; // R8 = !<sign bit>
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def SETLr : X86Inst<"setl" , 0x9C, MRMS0r, Arg8>, TB; // R8 = < signed
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def SETGEr : X86Inst<"setge", 0x9D, MRMS0r, Arg8>, TB; // R8 = >= signed
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def SETLEr : X86Inst<"setle", 0x9E, MRMS0r, Arg8>, TB; // R8 = <= signed
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def SETGr : X86Inst<"setg" , 0x9F, MRMS0r, Arg8>, TB; // R8 = < signed
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// Conditional moves. These are modelled as X = cmovXX Y, Z. Eventually
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// register allocated to cmovXX XY, Z
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def CMOVErr16 : I2A16<"cmove", 0x44, MRMSrcReg>, TB, OpSize; // if ==, R16 = R16
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def CMOVNErr32: I2A32<"cmovne",0x45, MRMSrcReg>, TB; // if !=, R32 = R32
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// Integer comparisons
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def CMPrr8 : X86Inst<"cmp", 0x38, MRMDestReg, Arg8 >; // compare R8, R8
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def CMPrr16 : X86Inst<"cmp", 0x39, MRMDestReg, Arg16>, OpSize; // compare R16, R16
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def CMPrr32 : X86Inst<"cmp", 0x39, MRMDestReg, Arg32>, // compare R32, R32
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Pattern<(isVoid (unspec2 R32, R32))>;
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def CMPri8 : X86Inst<"cmp", 0x80, MRMS7r , Arg8 >; // compare R8, imm8
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def CMPri16 : X86Inst<"cmp", 0x81, MRMS7r , Arg16>, OpSize; // compare R16, imm16
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def CMPri32 : X86Inst<"cmp", 0x81, MRMS7r , Arg32>; // compare R32, imm32
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// Sign/Zero extenders
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def MOVSXr16r8 : X86Inst<"movsx", 0xBE, MRMSrcReg, Arg8>, TB, OpSize; // R16 = signext(R8)
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def MOVSXr32r8 : X86Inst<"movsx", 0xBE, MRMSrcReg, Arg8>, TB; // R32 = signext(R8)
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def MOVSXr32r16: X86Inst<"movsx", 0xBF, MRMSrcReg, Arg8>, TB; // R32 = signext(R16)
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def MOVZXr16r8 : X86Inst<"movzx", 0xB6, MRMSrcReg, Arg8>, TB, OpSize; // R16 = zeroext(R8)
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def MOVZXr32r8 : X86Inst<"movzx", 0xB6, MRMSrcReg, Arg8>, TB; // R32 = zeroext(R8)
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def MOVZXr32r16: X86Inst<"movzx", 0xB7, MRMSrcReg, Arg8>, TB; // R32 = zeroext(R16)
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//===----------------------------------------------------------------------===//
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// Floating point support
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//===----------------------------------------------------------------------===//
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// FIXME: These need to indicate mod/ref sets for FP regs... & FP 'TOP'
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// Floating point pseudo instructions...
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class FPInst<string n, bits<8> o, Format F, ArgType t, FPFormat fp>
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: X86Inst<n, o, F, t> { let FPForm = fp; let FPFormBits = FPForm.Value; }
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// Pseudo instructions for floating point. We use these pseudo instructions
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// because they can be expanded by the fp spackifier into one of many different
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// forms of instructions for doing these operations. Until the stackifier runs,
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// we prefer to be abstract.
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def FpMOV : FPInst<"FMOV", 0, Pseudo, ArgF80, SpecialFP>; // f1 = fmov f2
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def FpADD : FPInst<"FADD", 0, Pseudo, ArgF80, TwoArgFP>; // f1 = fadd f2, f3
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def FpSUB : FPInst<"FSUB", 0, Pseudo, ArgF80, TwoArgFP>; // f1 = fsub f2, f3
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def FpMUL : FPInst<"FMUL", 0, Pseudo, ArgF80, TwoArgFP>; // f1 = fmul f2, f3
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def FpDIV : FPInst<"FDIV", 0, Pseudo, ArgF80, TwoArgFP>; // f1 = fdiv f2, f3
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def FpUCOM : FPInst<"FUCOM", 0, Pseudo, ArgF80, TwoArgFP>; // FPSW = fucom f1, f2
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def FpGETRESULT : FPInst<"FGETRESULT",0, Pseudo, ArgF80, SpecialFP>; // FPR = ST(0)
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def FpSETRESULT : FPInst<"FSETRESULT",0, Pseudo, ArgF80, SpecialFP>; // ST(0) = FPR
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// Floating point loads & stores...
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def FLDrr : FPInst<"fld" , 0xC0, AddRegFrm, ArgF80, NotFP>, D9; // push(ST(i))
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def FLDr32 : FPInst<"fld" , 0xD9, MRMS0m , ArgF32, ZeroArgFP>; // load float
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def FLDr64 : FPInst<"fld" , 0xDD, MRMS0m , ArgF64, ZeroArgFP>; // load double
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def FLDr80 : FPInst<"fld" , 0xDB, MRMS5m , ArgF80, ZeroArgFP>; // load extended
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def FILDr16 : FPInst<"fild" , 0xDF, MRMS0m , Arg16 , ZeroArgFP>; // load signed short
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def FILDr32 : FPInst<"fild" , 0xDB, MRMS0m , Arg32 , ZeroArgFP>; // load signed int
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def FILDr64 : FPInst<"fild" , 0xDF, MRMS5m , Arg64 , ZeroArgFP>; // load signed long
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def FSTr32 : FPInst<"fst" , 0xD9, MRMS2m , ArgF32, OneArgFP>; // store float
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def FSTr64 : FPInst<"fst" , 0xDD, MRMS2m , ArgF64, OneArgFP>; // store double
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def FSTPr32 : FPInst<"fstp", 0xD9, MRMS3m , ArgF32, OneArgFP>; // store float, pop
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def FSTPr64 : FPInst<"fstp", 0xDD, MRMS3m , ArgF64, OneArgFP>; // store double, pop
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def FSTPr80 : FPInst<"fstp", 0xDB, MRMS7m , ArgF80, OneArgFP>; // store extended, pop
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def FSTrr : FPInst<"fst" , 0xD0, AddRegFrm, ArgF80, NotFP >, DD; // ST(i) = ST(0)
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def FSTPrr : FPInst<"fstp", 0xD8, AddRegFrm, ArgF80, NotFP >, DD; // ST(i) = ST(0), pop
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def FISTr16 : FPInst<"fist", 0xDF, MRMS2m, Arg16 , OneArgFP>; // store signed short
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def FISTr32 : FPInst<"fist", 0xDB, MRMS2m, Arg32 , OneArgFP>; // store signed int
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def FISTPr16 : FPInst<"fistp", 0xDF, MRMS3m, Arg16 , NotFP >; // store signed short, pop
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def FISTPr32 : FPInst<"fistp", 0xDB, MRMS3m, Arg32 , NotFP >; // store signed int, pop
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def FISTPr64 : FPInst<"fistpll", 0xDF, MRMS7m, Arg64 , OneArgFP>; // store signed long, pop
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def FXCH : FPInst<"fxch", 0xC8, AddRegFrm, ArgF80, NotFP>, D9; // fxch ST(i), ST(0)
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// Floating point constant loads...
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def FLD0 : FPInst<"fldz", 0xEE, RawFrm, ArgF80, ZeroArgFP>, D9;
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def FLD1 : FPInst<"fld1", 0xE8, RawFrm, ArgF80, ZeroArgFP>, D9;
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// Unary operations...
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def FCHS : FPInst<"fchs", 0xE0, RawFrm, ArgF80, OneArgFPRW>, D9; // f1 = fchs f2
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def FTST : FPInst<"ftst", 0xE4, RawFrm, ArgF80, OneArgFP>, D9; // ftst ST(0)
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// Binary arithmetic operations...
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class FPST0rInst<string n, bits<8> o>
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: X86Inst<n, o, AddRegFrm, ArgF80>, D8 {
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list<Register> Uses = [ST0];
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list<Register> Defs = [ST0];
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}
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class FPrST0Inst<string n, bits<8> o>
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: X86Inst<n, o, AddRegFrm, ArgF80>, DC {
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bit printImplicitUses = 1;
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list<Register> Uses = [ST0];
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}
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class FPrST0PInst<string n, bits<8> o>
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: X86Inst<n, o, AddRegFrm, ArgF80>, DE {
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list<Register> Uses = [ST0];
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}
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def FADDST0r : FPST0rInst <"fadd", 0xC0>;
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def FADDrST0 : FPrST0Inst <"fadd", 0xC0>;
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def FADDPrST0 : FPrST0PInst<"faddp", 0xC0>;
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def FSUBRST0r : FPST0rInst <"fsubr", 0xE8>;
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def FSUBrST0 : FPrST0Inst <"fsub", 0xE8>;
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def FSUBPrST0 : FPrST0PInst<"fsubp", 0xE8>;
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def FSUBST0r : FPST0rInst <"fsub", 0xE0>;
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def FSUBRrST0 : FPrST0Inst <"fsubr", 0xE0>;
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def FSUBRPrST0 : FPrST0PInst<"fsubrp", 0xE0>;
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def FMULST0r : FPST0rInst <"fmul", 0xC8>;
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def FMULrST0 : FPrST0Inst <"fmul", 0xC8>;
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def FMULPrST0 : FPrST0PInst<"fmulp", 0xC8>;
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def FDIVRST0r : FPST0rInst <"fdivr", 0xF8>;
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def FDIVrST0 : FPrST0Inst <"fdiv", 0xF8>;
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def FDIVPrST0 : FPrST0PInst<"fdivp", 0xF8>;
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def FDIVST0r : FPST0rInst <"fdiv", 0xF0>; // ST(0) = ST(0) / ST(i)
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def FDIVRrST0 : FPrST0Inst <"fdivr", 0xF0>; // ST(i) = ST(0) / ST(i)
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def FDIVRPrST0 : FPrST0PInst<"fdivrp", 0xF0>; // ST(i) = ST(0) / ST(i), pop
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// Floating point compares
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def FUCOMr : X86Inst<"fucom" , 0xE0, AddRegFrm, ArgF80>, DD, Imp<[ST0],[]>; // FPSW = compare ST(0) with ST(i)
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def FUCOMPr : X86Inst<"fucomp" , 0xE8, AddRegFrm, ArgF80>, DD, Imp<[ST0],[]>; // FPSW = compare ST(0) with ST(i), pop
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def FUCOMPPr : X86Inst<"fucompp", 0xE9, RawFrm , ArgF80>, DA, Imp<[ST0],[]>; // compare ST(0) with ST(1), pop, pop
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// Floating point flag ops
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def FNSTSWr8 : X86Inst<"fnstsw" , 0xE0, RawFrm , ArgF80>, DF, Imp<[],[AX]>; // AX = fp flags
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def FNSTCWm16 : X86Inst<"fnstcw" , 0xD9, MRMS7m , Arg16 >; // [mem16] = X87 control world
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def FLDCWm16 : X86Inst<"fldcw" , 0xD9, MRMS5m , Arg16 >; // X87 control world = [mem16]
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//===----------------------------------------------------------------------===//
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// Instruction Expanders
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//
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def RET_R32 : Expander<(ret R32:$reg),
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[(MOVrr32 EAX, R32:$reg),
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(RET)]>;
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// FIXME: This should eventually just be implemented by defining a frameidx as a
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// value address for a load.
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def LOAD_FI16 : Expander<(set R16:$dest, (load frameidx:$fi)),
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[(MOVmr16 R16:$dest, frameidx:$fi, 1, 0/*NoReg*/, 0)]>;
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def LOAD_FI32 : Expander<(set R32:$dest, (load frameidx:$fi)),
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[(MOVmr32 R32:$dest, frameidx:$fi, 1, 0/*NoReg*/, 0)]>;
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def LOAD_R16 : Expander<(set R16:$dest, (load R32:$src)),
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[(MOVmr16 R16:$dest, R32:$src, 1, 0/*NoReg*/, 0)]>;
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def LOAD_R32 : Expander<(set R32:$dest, (load R32:$src)),
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[(MOVmr32 R32:$dest, R32:$src, 1, 0/*NoReg*/, 0)]>;
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def BR_EQ : Expander<(brcond (seteq R32:$a1, R32:$a2),
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basicblock:$d1, basicblock:$d2),
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[(CMPrr32 R32:$a1, R32:$a2),
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(JE basicblock:$d1),
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(JMP basicblock:$d2)]>;
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