//==- X86InstrFPStack.td - Describe the X86 Instruction Set -------*- C++ -*-=// // // The LLVM Compiler Infrastructure // // This file was developed by the Evan Cheng and is distributed under // the University of Illinois Open Source License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file describes the X86 x87 FPU instruction set, defining the // instructions, and properties of the instructions which are needed for code // generation, machine code emission, and analysis. // //===----------------------------------------------------------------------===// //===----------------------------------------------------------------------===// // FPStack specific DAG Nodes. //===----------------------------------------------------------------------===// def SDTX86FpGet : SDTypeProfile<1, 0, [SDTCisFP<0>]>; def SDTX86FpSet : SDTypeProfile<0, 1, [SDTCisFP<0>]>; def SDTX86Fld : SDTypeProfile<1, 2, [SDTCisFP<0>, SDTCisPtrTy<1>, SDTCisVT<2, OtherVT>]>; def SDTX86Fst : SDTypeProfile<0, 3, [SDTCisFP<0>, SDTCisPtrTy<1>, SDTCisVT<2, OtherVT>]>; def SDTX86Fild : SDTypeProfile<1, 2, [SDTCisFP<0>, SDTCisPtrTy<1>, SDTCisVT<2, OtherVT>]>; def SDTX86FpToIMem : SDTypeProfile<0, 2, [SDTCisFP<0>, SDTCisPtrTy<1>]>; def X86fpget : SDNode<"X86ISD::FP_GET_RESULT", SDTX86FpGet, [SDNPHasChain, SDNPInFlag, SDNPOutFlag]>; def X86fpset : SDNode<"X86ISD::FP_SET_RESULT", SDTX86FpSet, [SDNPHasChain, SDNPOutFlag]>; def X86fld : SDNode<"X86ISD::FLD", SDTX86Fld, [SDNPHasChain]>; def X86fst : SDNode<"X86ISD::FST", SDTX86Fst, [SDNPHasChain, SDNPInFlag]>; def X86fild : SDNode<"X86ISD::FILD", SDTX86Fild, [SDNPHasChain]>; def X86fildflag : SDNode<"X86ISD::FILD_FLAG",SDTX86Fild, [SDNPHasChain, SDNPOutFlag]>; def X86fp_to_i16mem : SDNode<"X86ISD::FP_TO_INT16_IN_MEM", SDTX86FpToIMem, [SDNPHasChain]>; def X86fp_to_i32mem : SDNode<"X86ISD::FP_TO_INT32_IN_MEM", SDTX86FpToIMem, [SDNPHasChain]>; def X86fp_to_i64mem : SDNode<"X86ISD::FP_TO_INT64_IN_MEM", SDTX86FpToIMem, [SDNPHasChain]>; //===----------------------------------------------------------------------===// // FPStack pattern fragments //===----------------------------------------------------------------------===// def fpimm0 : PatLeaf<(fpimm), [{ return N->isExactlyValue(+0.0); }]>; def fpimmneg0 : PatLeaf<(fpimm), [{ return N->isExactlyValue(-0.0); }]>; def fpimm1 : PatLeaf<(fpimm), [{ return N->isExactlyValue(+1.0); }]>; def fpimmneg1 : PatLeaf<(fpimm), [{ return N->isExactlyValue(-1.0); }]>; // Some 'special' instructions let usesCustomDAGSchedInserter = 1 in { // Expanded by the scheduler. def FP32_TO_INT16_IN_MEM : I<0, Pseudo, (outs), (ins i16mem:$dst, RFP32:$src), "#FP32_TO_INT16_IN_MEM PSEUDO!", [(X86fp_to_i16mem RFP32:$src, addr:$dst)]>; def FP32_TO_INT32_IN_MEM : I<0, Pseudo, (outs), (ins i32mem:$dst, RFP32:$src), "#FP32_TO_INT32_IN_MEM PSEUDO!", [(X86fp_to_i32mem RFP32:$src, addr:$dst)]>; def FP32_TO_INT64_IN_MEM : I<0, Pseudo, (outs), (ins i64mem:$dst, RFP32:$src), "#FP32_TO_INT64_IN_MEM PSEUDO!", [(X86fp_to_i64mem RFP32:$src, addr:$dst)]>; def FP64_TO_INT16_IN_MEM : I<0, Pseudo, (outs), (ins i16mem:$dst, RFP64:$src), "#FP64_TO_INT16_IN_MEM PSEUDO!", [(X86fp_to_i16mem RFP64:$src, addr:$dst)]>; def FP64_TO_INT32_IN_MEM : I<0, Pseudo, (outs), (ins i32mem:$dst, RFP64:$src), "#FP64_TO_INT32_IN_MEM PSEUDO!", [(X86fp_to_i32mem RFP64:$src, addr:$dst)]>; def FP64_TO_INT64_IN_MEM : I<0, Pseudo, (outs), (ins i64mem:$dst, RFP64:$src), "#FP64_TO_INT64_IN_MEM PSEUDO!", [(X86fp_to_i64mem RFP64:$src, addr:$dst)]>; } let isTerminator = 1 in let Defs = [FP0, FP1, FP2, FP3, FP4, FP5, FP6] in def FP_REG_KILL : I<0, Pseudo, (outs), (ins), "#FP_REG_KILL", []>; // All FP Stack operations are represented with three instructions here. The // first two instructions, generated by the instruction selector, uses "RFP32" // or "RFP64" registers: traditional register files to reference 32-bit or // 64-bit floating point values. These sizes apply to the values, not the // registers, which are always 64 bits; RFP32 and RFP64 can be copied to // each other without losing information. These instructions are all psuedo // instructions and use the "_Fp" suffix. // In some cases there are additional variants with a mixture of 32-bit and // 64-bit registers. // The second instruction is defined with FPI, which is the actual instruction // emitted by the assembler. These use "RST" registers, although frequently // the actual register(s) used are implicit. These are always 64-bits. // The FP stackifier pass converts one to the other after register allocation // occurs. // // Note that the FpI instruction should have instruction selection info (e.g. // a pattern) and the FPI instruction should have emission info (e.g. opcode // encoding and asm printing info). // FPI - Floating Point Instruction template. class FPI o, Format F, dag outs, dag ins, string asm> : I {} // FpI_ - Floating Point Psuedo Instruction template. Not Predicated. class FpI_ pattern> : X86Inst<0, Pseudo, NoImm, outs, ins, ""> { let FPForm = fp; let FPFormBits = FPForm.Value; let Pattern = pattern; } // Random Pseudo Instructions. def FpGETRESULT32 : FpI_<(outs RFP32:$dst), (ins), SpecialFP, [(set RFP32:$dst, X86fpget)]>; // FPR = ST(0) def FpGETRESULT64 : FpI_<(outs RFP64:$dst), (ins), SpecialFP, [(set RFP64:$dst, X86fpget)]>; // FPR = ST(0) let noResults = 1 in { def FpSETRESULT32 : FpI_<(outs), (ins RFP32:$src), SpecialFP, [(X86fpset RFP32:$src)]>, Imp<[], [ST0]>;// ST(0) = FPR def FpSETRESULT64 : FpI_<(outs), (ins RFP64:$src), SpecialFP, [(X86fpset RFP64:$src)]>, Imp<[], [ST0]>;// ST(0) = FPR } // FpI - Floating Point Psuedo Instruction template. Predicated on FPStack. class FpI pattern> : FpI_, Requires<[FPStack]>; // Register copies. Just copies, the 64->32 version does not truncate. def MOV_Fp3232 : FpI<(outs RFP32:$dst), (ins RFP32:$src), SpecialFP, []>; def MOV_Fp3264 : FpI<(outs RFP64:$dst), (ins RFP32:$src), SpecialFP, []>; def MOV_Fp6432 : FpI<(outs RFP32:$dst), (ins RFP64:$src), SpecialFP, []>; def MOV_Fp6464 : FpI<(outs RFP64:$dst), (ins RFP64:$src), SpecialFP, []>; // Factoring for arithmetic. multiclass FPBinary_rr { // Register op register -> register // These are separated out because they have no reversed form. def _Fp32 : FpI<(outs RFP32:$dst), (ins RFP32:$src1, RFP32:$src2), TwoArgFP, [(set RFP32:$dst, (OpNode RFP32:$src1, RFP32:$src2))]>; def _Fp64 : FpI<(outs RFP64:$dst), (ins RFP64:$src1, RFP64:$src2), TwoArgFP, [(set RFP64:$dst, (OpNode RFP64:$src1, RFP64:$src2))]>; } // The FopST0 series are not included here because of the irregularities // in where the 'r' goes in assembly output. multiclass FPBinary { // ST(0) = ST(0) + [mem] def _Fp32m : FpI<(outs RFP32:$dst), (ins RFP32:$src1, f32mem:$src2), OneArgFPRW, [(set RFP32:$dst, (OpNode RFP32:$src1, (loadf32 addr:$src2)))]>; def _Fp64m : FpI<(outs RFP64:$dst), (ins RFP64:$src1, f64mem:$src2), OneArgFPRW, [(set RFP64:$dst, (OpNode RFP64:$src1, (loadf64 addr:$src2)))]>; def _Fp64m32: FpI<(outs RFP64:$dst), (ins RFP64:$src1, f32mem:$src2), OneArgFPRW, [(set RFP64:$dst, (OpNode RFP64:$src1, (extloadf32 addr:$src2)))]>; def _F32m : FPI<0xD8, fp, (outs), (ins f32mem:$src), !strconcat("f", !strconcat(asmstring, "{s} $src"))>; def _F64m : FPI<0xDC, fp, (outs), (ins f64mem:$src), !strconcat("f", !strconcat(asmstring, "{l} $src"))>; // ST(0) = ST(0) + [memint] def _FpI16m32 : FpI<(outs RFP32:$dst), (ins RFP32:$src1, i16mem:$src2), OneArgFPRW, [(set RFP32:$dst, (OpNode RFP32:$src1, (X86fild addr:$src2, i16)))]>; def _FpI32m32 : FpI<(outs RFP32:$dst), (ins RFP32:$src1, i32mem:$src2), OneArgFPRW, [(set RFP32:$dst, (OpNode RFP32:$src1, (X86fild addr:$src2, i32)))]>; def _FpI16m64 : FpI<(outs RFP64:$dst), (ins RFP64:$src1, i16mem:$src2), OneArgFPRW, [(set RFP64:$dst, (OpNode RFP64:$src1, (X86fild addr:$src2, i16)))]>; def _FpI32m64 : FpI<(outs RFP64:$dst), (ins RFP64:$src1, i32mem:$src2), OneArgFPRW, [(set RFP64:$dst, (OpNode RFP64:$src1, (X86fild addr:$src2, i32)))]>; def _FI16m : FPI<0xDE, fp, (outs), (ins i16mem:$src), !strconcat("fi", !strconcat(asmstring, "{s} $src"))>; def _FI32m : FPI<0xDA, fp, (outs), (ins i32mem:$src), !strconcat("fi", !strconcat(asmstring, "{l} $src"))>; } defm ADD : FPBinary_rr; defm SUB : FPBinary_rr; defm MUL : FPBinary_rr; defm DIV : FPBinary_rr; defm ADD : FPBinary; defm SUB : FPBinary; defm SUBR: FPBinary; defm MUL : FPBinary; defm DIV : FPBinary; defm DIVR: FPBinary; class FPST0rInst o, string asm> : FPI, D8; class FPrST0Inst o, string asm> : FPI, DC; class FPrST0PInst o, string asm> : FPI, DE; // NOTE: GAS and apparently all other AT&T style assemblers have a broken notion // of some of the 'reverse' forms of the fsub and fdiv instructions. As such, // we have to put some 'r's in and take them out of weird places. def ADD_FST0r : FPST0rInst <0xC0, "fadd $op">; def ADD_FrST0 : FPrST0Inst <0xC0, "fadd {%st(0), $op|$op, %ST(0)}">; def ADD_FPrST0 : FPrST0PInst<0xC0, "faddp $op">; def SUBR_FST0r : FPST0rInst <0xE8, "fsubr $op">; def SUB_FrST0 : FPrST0Inst <0xE8, "fsub{r} {%st(0), $op|$op, %ST(0)}">; def SUB_FPrST0 : FPrST0PInst<0xE8, "fsub{r}p $op">; def SUB_FST0r : FPST0rInst <0xE0, "fsub $op">; def SUBR_FrST0 : FPrST0Inst <0xE0, "fsub{|r} {%st(0), $op|$op, %ST(0)}">; def SUBR_FPrST0 : FPrST0PInst<0xE0, "fsub{|r}p $op">; def MUL_FST0r : FPST0rInst <0xC8, "fmul $op">; def MUL_FrST0 : FPrST0Inst <0xC8, "fmul {%st(0), $op|$op, %ST(0)}">; def MUL_FPrST0 : FPrST0PInst<0xC8, "fmulp $op">; def DIVR_FST0r : FPST0rInst <0xF8, "fdivr $op">; def DIV_FrST0 : FPrST0Inst <0xF8, "fdiv{r} {%st(0), $op|$op, %ST(0)}">; def DIV_FPrST0 : FPrST0PInst<0xF8, "fdiv{r}p $op">; def DIV_FST0r : FPST0rInst <0xF0, "fdiv $op">; def DIVR_FrST0 : FPrST0Inst <0xF0, "fdiv{|r} {%st(0), $op|$op, %ST(0)}">; def DIVR_FPrST0 : FPrST0PInst<0xF0, "fdiv{|r}p $op">; // Unary operations. multiclass FPUnary opcode, string asmstring> { def _Fp32 : FpI<(outs RFP32:$dst), (ins RFP32:$src), OneArgFPRW, [(set RFP32:$dst, (OpNode RFP32:$src))]>; def _Fp64 : FpI<(outs RFP64:$dst), (ins RFP64:$src), OneArgFPRW, [(set RFP64:$dst, (OpNode RFP64:$src))]>; def _F : FPI, D9; } defm CHS : FPUnary; defm ABS : FPUnary; defm SQRT: FPUnary; defm SIN : FPUnary; defm COS : FPUnary; def TST_Fp32 : FpI<(outs), (ins RFP32:$src), OneArgFP, []>; def TST_Fp64 : FpI<(outs), (ins RFP64:$src), OneArgFP, []>; def TST_F : FPI<0xE4, RawFrm, (outs), (ins), "ftst">, D9; // Floating point cmovs. multiclass FPCMov { def _Fp32 : FpI<(outs RFP32:$dst), (ins RFP32:$src1, RFP32:$src2), CondMovFP, [(set RFP32:$dst, (X86cmov RFP32:$src1, RFP32:$src2, cc))]>; def _Fp64 : FpI<(outs RFP64:$dst), (ins RFP64:$src1, RFP64:$src2), CondMovFP, [(set RFP64:$dst, (X86cmov RFP64:$src1, RFP64:$src2, cc))]>; } let isTwoAddress = 1 in { defm CMOVB : FPCMov; defm CMOVBE : FPCMov; defm CMOVE : FPCMov; defm CMOVP : FPCMov; defm CMOVNB : FPCMov; defm CMOVNBE: FPCMov; defm CMOVNE : FPCMov; defm CMOVNP : FPCMov; } // These are not factored because there's no clean way to pass DA/DB. def CMOVB_F : FPI<0xC0, AddRegFrm, (outs RST:$op), (ins), "fcmovb {$op, %st(0)|%ST(0), $op}">, DA; def CMOVBE_F : FPI<0xD0, AddRegFrm, (outs RST:$op), (ins), "fcmovbe {$op, %st(0)|%ST(0), $op}">, DA; def CMOVE_F : FPI<0xC8, AddRegFrm, (outs RST:$op), (ins), "fcmove {$op, %st(0)|%ST(0), $op}">, DA; def CMOVP_F : FPI<0xD8, AddRegFrm, (outs RST:$op), (ins), "fcmovu {$op, %st(0)|%ST(0), $op}">, DA; def CMOVNB_F : FPI<0xC0, AddRegFrm, (outs RST:$op), (ins), "fcmovnb {$op, %st(0)|%ST(0), $op}">, DB; def CMOVNBE_F: FPI<0xD0, AddRegFrm, (outs RST:$op), (ins), "fcmovnbe {$op, %st(0)|%ST(0), $op}">, DB; def CMOVNE_F : FPI<0xC8, AddRegFrm, (outs RST:$op), (ins), "fcmovne {$op, %st(0)|%ST(0), $op}">, DB; def CMOVNP_F : FPI<0xD8, AddRegFrm, (outs RST:$op), (ins), "fcmovnu {$op, %st(0)|%ST(0), $op}">, DB; // Floating point loads & stores. def LD_Fp32m : FpI<(outs RFP32:$dst), (ins f32mem:$src), ZeroArgFP, [(set RFP32:$dst, (loadf32 addr:$src))]>; def LD_Fp64m : FpI<(outs RFP64:$dst), (ins f64mem:$src), ZeroArgFP, [(set RFP64:$dst, (loadf64 addr:$src))]>; def ILD_Fp16m32: FpI<(outs RFP32:$dst), (ins i16mem:$src), ZeroArgFP, [(set RFP32:$dst, (X86fild addr:$src, i16))]>; def ILD_Fp32m32: FpI<(outs RFP32:$dst), (ins i32mem:$src), ZeroArgFP, [(set RFP32:$dst, (X86fild addr:$src, i32))]>; def ILD_Fp64m32: FpI<(outs RFP32:$dst), (ins i64mem:$src), ZeroArgFP, [(set RFP32:$dst, (X86fild addr:$src, i64))]>; def ILD_Fp16m64: FpI<(outs RFP64:$dst), (ins i16mem:$src), ZeroArgFP, [(set RFP64:$dst, (X86fild addr:$src, i16))]>; def ILD_Fp32m64: FpI<(outs RFP64:$dst), (ins i32mem:$src), ZeroArgFP, [(set RFP64:$dst, (X86fild addr:$src, i32))]>; def ILD_Fp64m64: FpI<(outs RFP64:$dst), (ins i64mem:$src), ZeroArgFP, [(set RFP64:$dst, (X86fild addr:$src, i64))]>; def ST_Fp32m : FpI<(outs), (ins f32mem:$op, RFP32:$src), OneArgFP, [(store RFP32:$src, addr:$op)]>; def ST_Fp64m32 : FpI<(outs), (ins f32mem:$op, RFP64:$src), OneArgFP, [(truncstoref32 RFP64:$src, addr:$op)]>; def ST_Fp64m : FpI<(outs), (ins f64mem:$op, RFP64:$src), OneArgFP, [(store RFP64:$src, addr:$op)]>; def ST_FpP32m : FpI<(outs), (ins f32mem:$op, RFP32:$src), OneArgFP, []>; def ST_FpP64m32 : FpI<(outs), (ins f32mem:$op, RFP64:$src), OneArgFP, []>; def ST_FpP64m : FpI<(outs), (ins f64mem:$op, RFP64:$src), OneArgFP, []>; def IST_Fp16m32 : FpI<(outs), (ins i16mem:$op, RFP32:$src), OneArgFP, []>; def IST_Fp32m32 : FpI<(outs), (ins i32mem:$op, RFP32:$src), OneArgFP, []>; def IST_Fp64m32 : FpI<(outs), (ins i64mem:$op, RFP32:$src), OneArgFP, []>; def IST_Fp16m64 : FpI<(outs), (ins i16mem:$op, RFP64:$src), OneArgFP, []>; def IST_Fp32m64 : FpI<(outs), (ins i32mem:$op, RFP64:$src), OneArgFP, []>; def IST_Fp64m64 : FpI<(outs), (ins i64mem:$op, RFP64:$src), OneArgFP, []>; def LD_F32m : FPI<0xD9, MRM0m, (outs), (ins f32mem:$src), "fld{s} $src">; def LD_F64m : FPI<0xDD, MRM0m, (outs), (ins f64mem:$src), "fld{l} $src">; def ILD_F16m : FPI<0xDF, MRM0m, (outs), (ins i16mem:$src), "fild{s} $src">; def ILD_F32m : FPI<0xDB, MRM0m, (outs), (ins i32mem:$src), "fild{l} $src">; def ILD_F64m : FPI<0xDF, MRM5m, (outs), (ins i64mem:$src), "fild{ll} $src">; def ST_F32m : FPI<0xD9, MRM2m, (outs), (ins f32mem:$dst), "fst{s} $dst">; def ST_F64m : FPI<0xDD, MRM2m, (outs), (ins f64mem:$dst), "fst{l} $dst">; def ST_FP32m : FPI<0xD9, MRM3m, (outs), (ins f32mem:$dst), "fstp{s} $dst">; def ST_FP64m : FPI<0xDD, MRM3m, (outs), (ins f64mem:$dst), "fstp{l} $dst">; def IST_F16m : FPI<0xDF, MRM2m, (outs), (ins i16mem:$dst), "fist{s} $dst">; def IST_F32m : FPI<0xDB, MRM2m, (outs), (ins i32mem:$dst), "fist{l} $dst">; def IST_FP16m : FPI<0xDF, MRM3m, (outs), (ins i16mem:$dst), "fistp{s} $dst">; def IST_FP32m : FPI<0xDB, MRM3m, (outs), (ins i32mem:$dst), "fistp{l} $dst">; def IST_FP64m : FPI<0xDF, MRM7m, (outs), (ins i64mem:$dst), "fistp{ll} $dst">; // FISTTP requires SSE3 even though it's a FPStack op. def ISTT_Fp16m32 : FpI_<(outs), (ins i16mem:$op, RFP32:$src), OneArgFP, [(X86fp_to_i16mem RFP32:$src, addr:$op)]>, Requires<[HasSSE3]>; def ISTT_Fp32m32 : FpI_<(outs), (ins i32mem:$op, RFP32:$src), OneArgFP, [(X86fp_to_i32mem RFP32:$src, addr:$op)]>, Requires<[HasSSE3]>; def ISTT_Fp64m32 : FpI_<(outs), (ins i64mem:$op, RFP32:$src), OneArgFP, [(X86fp_to_i64mem RFP32:$src, addr:$op)]>, Requires<[HasSSE3]>; def ISTT_Fp16m64 : FpI_<(outs), (ins i16mem:$op, RFP64:$src), OneArgFP, [(X86fp_to_i16mem RFP64:$src, addr:$op)]>, Requires<[HasSSE3]>; def ISTT_Fp32m64 : FpI_<(outs), (ins i32mem:$op, RFP64:$src), OneArgFP, [(X86fp_to_i32mem RFP64:$src, addr:$op)]>, Requires<[HasSSE3]>; def ISTT_Fp64m64 : FpI_<(outs), (ins i64mem:$op, RFP64:$src), OneArgFP, [(X86fp_to_i64mem RFP64:$src, addr:$op)]>, Requires<[HasSSE3]>; def ISTT_FP16m : FPI<0xDF, MRM1m, (outs), (ins i16mem:$dst), "fisttp{s} $dst">; def ISTT_FP32m : FPI<0xDB, MRM1m, (outs), (ins i32mem:$dst), "fisttp{l} $dst">; def ISTT_FP64m : FPI<0xDD, MRM1m, (outs), (ins i64mem:$dst), "fisttp{ll} $dst">; // FP Stack manipulation instructions. def LD_Frr : FPI<0xC0, AddRegFrm, (outs), (ins RST:$op), "fld $op">, D9; def ST_Frr : FPI<0xD0, AddRegFrm, (outs), (ins RST:$op), "fst $op">, DD; def ST_FPrr : FPI<0xD8, AddRegFrm, (outs), (ins RST:$op), "fstp $op">, DD; def XCH_F : FPI<0xC8, AddRegFrm, (outs), (ins RST:$op), "fxch $op">, D9; // Floating point constant loads. let isReMaterializable = 1 in { def LD_Fp032 : FpI<(outs RFP32:$dst), (ins), ZeroArgFP, [(set RFP32:$dst, fpimm0)]>; def LD_Fp132 : FpI<(outs RFP32:$dst), (ins), ZeroArgFP, [(set RFP32:$dst, fpimm1)]>; def LD_Fp064 : FpI<(outs RFP64:$dst), (ins), ZeroArgFP, [(set RFP64:$dst, fpimm0)]>; def LD_Fp164 : FpI<(outs RFP64:$dst), (ins), ZeroArgFP, [(set RFP64:$dst, fpimm1)]>; } def LD_F0 : FPI<0xEE, RawFrm, (outs), (ins), "fldz">, D9; def LD_F1 : FPI<0xE8, RawFrm, (outs), (ins), "fld1">, D9; // Floating point compares. def UCOM_Fpr32 : FpI<(outs), (ins RFP32:$lhs, RFP32:$rhs), CompareFP, []>; // FPSW = cmp ST(0) with ST(i) def UCOM_FpIr32: FpI<(outs), (ins RFP32:$lhs, RFP32:$rhs), CompareFP, [(X86cmp RFP32:$lhs, RFP32:$rhs)]>; // CC = ST(0) cmp ST(i) def UCOM_Fpr64 : FpI<(outs), (ins RFP64:$lhs, RFP64:$rhs), CompareFP, []>; // FPSW = cmp ST(0) with ST(i) def UCOM_FpIr64: FpI<(outs), (ins RFP64:$lhs, RFP64:$rhs), CompareFP, [(X86cmp RFP64:$lhs, RFP64:$rhs)]>; // CC = ST(0) cmp ST(i) def UCOM_Fr : FPI<0xE0, AddRegFrm, // FPSW = cmp ST(0) with ST(i) (outs), (ins RST:$reg), "fucom $reg">, DD, Imp<[ST0],[]>; def UCOM_FPr : FPI<0xE8, AddRegFrm, // FPSW = cmp ST(0) with ST(i), pop (outs), (ins RST:$reg), "fucomp $reg">, DD, Imp<[ST0],[]>; def UCOM_FPPr : FPI<0xE9, RawFrm, // cmp ST(0) with ST(1), pop, pop (outs), (ins), "fucompp">, DA, Imp<[ST0],[]>; def UCOM_FIr : FPI<0xE8, AddRegFrm, // CC = cmp ST(0) with ST(i) (outs), (ins RST:$reg), "fucomi {$reg, %st(0)|%ST(0), $reg}">, DB, Imp<[ST0],[]>; def UCOM_FIPr : FPI<0xE8, AddRegFrm, // CC = cmp ST(0) with ST(i), pop (outs), (ins RST:$reg), "fucomip {$reg, %st(0)|%ST(0), $reg}">, DF, Imp<[ST0],[]>; // Floating point flag ops. def FNSTSW8r : I<0xE0, RawFrm, // AX = fp flags (outs), (ins), "fnstsw", []>, DF, Imp<[],[AX]>; def FNSTCW16m : I<0xD9, MRM7m, // [mem16] = X87 control world (outs), (ins i16mem:$dst), "fnstcw $dst", []>; def FLDCW16m : I<0xD9, MRM5m, // X87 control world = [mem16] (outs), (ins i16mem:$dst), "fldcw $dst", []>; //===----------------------------------------------------------------------===// // Non-Instruction Patterns //===----------------------------------------------------------------------===// // Required for RET of f32 / f64 values. def : Pat<(X86fld addr:$src, f32), (LD_Fp32m addr:$src)>; def : Pat<(X86fld addr:$src, f64), (LD_Fp64m addr:$src)>; // Required for CALL which return f32 / f64 values. def : Pat<(X86fst RFP32:$src, addr:$op, f32), (ST_Fp32m addr:$op, RFP32:$src)>; def : Pat<(X86fst RFP64:$src, addr:$op, f32), (ST_Fp64m32 addr:$op, RFP64:$src)>; def : Pat<(X86fst RFP64:$src, addr:$op, f64), (ST_Fp64m addr:$op, RFP64:$src)>; // Floating point constant -0.0 and -1.0 def : Pat<(f32 fpimmneg0), (CHS_Fp32 (LD_Fp032))>, Requires<[FPStack]>; def : Pat<(f32 fpimmneg1), (CHS_Fp32 (LD_Fp132))>, Requires<[FPStack]>; def : Pat<(f64 fpimmneg0), (CHS_Fp64 (LD_Fp064))>, Requires<[FPStack]>; def : Pat<(f64 fpimmneg1), (CHS_Fp64 (LD_Fp164))>, Requires<[FPStack]>; // Used to conv. i64 to f64 since there isn't a SSE version. def : Pat<(X86fildflag addr:$src, i64), (ILD_Fp64m64 addr:$src)>; def : Pat<(extloadf32 addr:$src), (MOV_Fp3264 (LD_Fp32m addr:$src))>, Requires<[FPStack]>; def : Pat<(fextend RFP32:$src), (MOV_Fp3264 RFP32:$src)>, Requires<[FPStack]>;