//=-- LoongArchInstrInfoD.td - Double-Precision Float instr -*- 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 basic double-precision floating-point instructions. // //===----------------------------------------------------------------------===// //===----------------------------------------------------------------------===// // Instructions //===----------------------------------------------------------------------===// let Predicates = [HasBasicD] in { // Arithmetic Operation Instructions def FADD_D : FP_ALU_3R<0b00000001000000010, "fadd.d", FPR64>; def FSUB_D : FP_ALU_3R<0b00000001000000110, "fsub.d", FPR64>; def FMUL_D : FP_ALU_3R<0b00000001000001010, "fmul.d", FPR64>; def FDIV_D : FP_ALU_3R<0b00000001000001110, "fdiv.d", FPR64>; def FMADD_D : FP_ALU_4R<0b000010000010, "fmadd.d", FPR64>; def FMSUB_D : FP_ALU_4R<0b000010000110, "fmsub.d", FPR64>; def FNMADD_D : FP_ALU_4R<0b000010001010, "fnmadd.d", FPR64>; def FNMSUB_D : FP_ALU_4R<0b000010001110, "fnmsub.d", FPR64>; def FMAX_D : FP_ALU_3R<0b00000001000010010, "fmax.d", FPR64>; def FMIN_D : FP_ALU_3R<0b00000001000010110, "fmin.d", FPR64>; def FMAXA_D : FP_ALU_3R<0b00000001000011010, "fmaxa.d", FPR64>; def FMINA_D : FP_ALU_3R<0b00000001000011110, "fmina.d", FPR64>; def FABS_D : FP_ALU_2R<0b0000000100010100000010, "fabs.d", FPR64>; def FNEG_D : FP_ALU_2R<0b0000000100010100000110, "fneg.d", FPR64>; def FSQRT_D : FP_ALU_2R<0b0000000100010100010010, "fsqrt.d", FPR64>; def FRECIP_D : FP_ALU_2R<0b0000000100010100010110, "frecip.d", FPR64>; def FRSQRT_D : FP_ALU_2R<0b0000000100010100011010, "frsqrt.d", FPR64>; def FSCALEB_D : FP_ALU_3R<0b00000001000100010, "fscaleb.d", FPR64>; def FLOGB_D : FP_ALU_2R<0b0000000100010100001010, "flogb.d", FPR64>; def FCOPYSIGN_D : FP_ALU_3R<0b00000001000100110, "fcopysign.d", FPR64>; def FCLASS_D : FP_ALU_2R<0b0000000100010100001110, "fclass.d", FPR64>; // Comparison Instructions def FCMP_CAF_D : FP_CMP; def FCMP_CUN_D : FP_CMP; def FCMP_CEQ_D : FP_CMP; def FCMP_CUEQ_D : FP_CMP; def FCMP_CLT_D : FP_CMP; def FCMP_CULT_D : FP_CMP; def FCMP_CLE_D : FP_CMP; def FCMP_CULE_D : FP_CMP; def FCMP_CNE_D : FP_CMP; def FCMP_COR_D : FP_CMP; def FCMP_CUNE_D : FP_CMP; def FCMP_SAF_D : FP_CMP; def FCMP_SUN_D : FP_CMP; def FCMP_SEQ_D : FP_CMP; def FCMP_SUEQ_D : FP_CMP; def FCMP_SLT_D : FP_CMP; def FCMP_SULT_D : FP_CMP; def FCMP_SLE_D : FP_CMP; def FCMP_SULE_D : FP_CMP; def FCMP_SNE_D : FP_CMP; def FCMP_SOR_D : FP_CMP; def FCMP_SUNE_D : FP_CMP; // Conversion Instructions def FFINT_S_L : FP_CONV<0b0000000100011101000110, "ffint.s.l", FPR32, FPR64>; def FTINT_L_S : FP_CONV<0b0000000100011011001001, "ftint.l.s", FPR64, FPR32>; def FTINTRM_L_S : FP_CONV<0b0000000100011010001001, "ftintrm.l.s", FPR64, FPR32>; def FTINTRP_L_S : FP_CONV<0b0000000100011010011001, "ftintrp.l.s", FPR64, FPR32>; def FTINTRZ_L_S : FP_CONV<0b0000000100011010101001, "ftintrz.l.s", FPR64, FPR32>; def FTINTRNE_L_S : FP_CONV<0b0000000100011010111001, "ftintrne.l.s", FPR64, FPR32>; def FCVT_S_D : FP_CONV<0b0000000100011001000110, "fcvt.s.d", FPR32, FPR64>; def FCVT_D_S : FP_CONV<0b0000000100011001001001, "fcvt.d.s", FPR64, FPR32>; def FFINT_D_W : FP_CONV<0b0000000100011101001000, "ffint.d.w", FPR64, FPR32>; def FFINT_D_L : FP_CONV<0b0000000100011101001010, "ffint.d.l", FPR64, FPR64>; def FTINT_W_D : FP_CONV<0b0000000100011011000010, "ftint.w.d", FPR32, FPR64>; def FTINT_L_D : FP_CONV<0b0000000100011011001010, "ftint.l.d", FPR64, FPR64>; def FTINTRM_W_D : FP_CONV<0b0000000100011010000010, "ftintrm.w.d", FPR32, FPR64>; def FTINTRM_L_D : FP_CONV<0b0000000100011010001010, "ftintrm.l.d", FPR64, FPR64>; def FTINTRP_W_D : FP_CONV<0b0000000100011010010010, "ftintrp.w.d", FPR32, FPR64>; def FTINTRP_L_D : FP_CONV<0b0000000100011010011010, "ftintrp.l.d", FPR64, FPR64>; def FTINTRZ_W_D : FP_CONV<0b0000000100011010100010, "ftintrz.w.d", FPR32, FPR64>; def FTINTRZ_L_D : FP_CONV<0b0000000100011010101010, "ftintrz.l.d", FPR64, FPR64>; def FTINTRNE_W_D : FP_CONV<0b0000000100011010110010, "ftintrne.w.d", FPR32, FPR64>; def FTINTRNE_L_D : FP_CONV<0b0000000100011010111010, "ftintrne.l.d", FPR64, FPR64>; def FRINT_D : FP_CONV<0b0000000100011110010010, "frint.d", FPR64, FPR64>; // Move Instructions def FMOV_D : FP_MOV<0b0000000100010100100110, "fmov.d", FPR64, FPR64>; def MOVFRH2GR_S : FP_MOV<0b0000000100010100101111, "movfrh2gr.s", GPR, FPR64>; let isCodeGenOnly = 1 in { def MOVFR2GR_S_64 : FP_MOV<0b0000000100010100101101, "movfr2gr.s", GPR, FPR64>; def FSEL_D : FP_SEL<0b00001101000000, "fsel", FPR64>; } // isCodeGenOnly = 1 let Constraints = "$dst = $out" in { def MOVGR2FRH_W : FPFmtMOV<0b0000000100010100101011, (outs FPR64:$out), (ins FPR64:$dst, GPR:$src), "movgr2frh.w", "$dst, $src">; } // Constraints = "$dst = $out" // Common Memory Access Instructions def FLD_D : FP_LOAD_2RI12<0b0010101110, "fld.d", FPR64>; def FST_D : FP_STORE_2RI12<0b0010101111, "fst.d", FPR64>; def FLDX_D : FP_LOAD_3R<0b00111000001101000, "fldx.d", FPR64>; def FSTX_D : FP_STORE_3R<0b00111000001111000, "fstx.d", FPR64>; // Bound Check Memory Access Instructions def FLDGT_D : FP_LOAD_3R<0b00111000011101001, "fldgt.d", FPR64>; def FLDLE_D : FP_LOAD_3R<0b00111000011101011, "fldle.d", FPR64>; def FSTGT_D : FP_STORE_3R<0b00111000011101101, "fstgt.d", FPR64>; def FSTLE_D : FP_STORE_3R<0b00111000011101111, "fstle.d", FPR64>; } // Predicates = [HasBasicD] // Instructions only available on LA64 let Predicates = [HasBasicD, IsLA64] in { def MOVGR2FR_D : FP_MOV<0b0000000100010100101010, "movgr2fr.d", FPR64, GPR>; def MOVFR2GR_D : FP_MOV<0b0000000100010100101110, "movfr2gr.d", GPR, FPR64>; } // Predicates = [HasBasicD, IsLA64] // Instructions only available on LA32 let Predicates = [HasBasicD, IsLA32], isCodeGenOnly = 1 in { def MOVGR2FR_W_64 : FP_MOV<0b0000000100010100101001, "movgr2fr.w", FPR64, GPR>; } // Predicates = [HasBasicD, IsLA32], isCodeGenOnly = 1 //===----------------------------------------------------------------------===// // Pseudo-instructions and codegen patterns //===----------------------------------------------------------------------===// let Predicates = [HasBasicD] in { /// Float arithmetic operations def : PatFprFpr; def : PatFprFpr; def : PatFprFpr; def : PatFprFpr; def : PatFpr; /// Setcc // Match non-signaling comparison // TODO: Change setcc to any_fsetcc after call is supported because // we need to call llvm.experimental.constrained.fcmp.f64 in testcase. // See RISCV float-fcmp-strict.ll for reference. // SETOGT/SETOGE/SETUGT/SETUGE will expand into SETOLT/SETOLE/SETULT/SETULE. def : PatFPSetcc; def : PatFPSetcc; def : PatFPSetcc; def : PatFPSetcc; def : PatFPSetcc; def : PatFPSetcc; def : PatFPSetcc; def : PatFPSetcc; def : PatFPSetcc; def : PatFPSetcc; def : PatFPSetcc; // TODO: Match signaling comparison strict_fsetccs with FCMP_S*_D instructions. /// Select def : Pat<(select GPR:$cc, FPR64:$fk, FPR64:$fj), (FSEL_D FPR64:$fj, FPR64:$fk, (MOVGR2CF GPR:$cc))>; /// Selectcc def : PatFPSelectcc; def : PatFPSelectcc; def : PatFPSelectcc; def : PatFPSelectcc; def : PatFPSelectcc; def : PatFPSelectcc; def : PatFPSelectcc; def : PatFPSelectcc; def : PatFPSelectcc; def : PatFPSelectcc; /// Loads defm : LdPat; /// Stores defm : StPat; /// FP conversion operations def : Pat<(loongarch_ftint FPR64:$src), (FTINTRZ_W_D FPR64:$src)>; def : Pat<(f64 (loongarch_ftint FPR64:$src)), (FTINTRZ_L_D FPR64:$src)>; def : Pat<(loongarch_ftint FPR32:$src), (FTINTRZ_L_S FPR32:$src)>; // f64 -> f32 def : Pat<(f32 (fpround FPR64:$src)), (FCVT_S_D FPR64:$src)>; // f32 -> f64 def : Pat<(f64 (fpextend FPR32:$src)), (FCVT_D_S FPR32:$src)>; } // Predicates = [HasBasicD] /// Floating point constants let Predicates = [HasBasicD, IsLA64] in { def : Pat<(f64 fpimm0), (MOVGR2FR_D R0)>; def : Pat<(f64 fpimm0neg), (FNEG_D (MOVGR2FR_D R0))>; def : Pat<(f64 fpimm1), (FFINT_D_L (MOVGR2FR_D (ADDI_D R0, 1)))>; // Convert int to FP def : Pat<(f64 (sint_to_fp (i64 (sexti32 (i64 GPR:$src))))), (FFINT_D_W (MOVGR2FR_W GPR:$src))>; def : Pat<(f64 (sint_to_fp GPR:$src)), (FFINT_D_L (MOVGR2FR_D GPR:$src))>; def : Pat<(f64 (uint_to_fp (i64 (zexti32 (i64 GPR:$src))))), (FFINT_D_W (MOVGR2FR_W GPR:$src))>; def : Pat<(bitconvert GPR:$src), (MOVGR2FR_D GPR:$src)>; // Convert FP to int def : Pat<(bitconvert FPR64:$src), (MOVFR2GR_D FPR64:$src)>; } // Predicates = [HasBasicD, IsLA64] let Predicates = [HasBasicD, IsLA32] in { def : Pat<(f64 fpimm0), (MOVGR2FRH_W (MOVGR2FR_W_64 R0), R0)>; def : Pat<(f64 fpimm0neg), (FNEG_D (MOVGR2FRH_W (MOVGR2FR_W_64 R0), R0))>; def : Pat<(f64 fpimm1), (FCVT_D_S (FFINT_S_W (MOVGR2FR_W (ADDI_W R0, 1))))>; // Convert int to FP def : Pat<(f64 (sint_to_fp (i32 GPR:$src))), (FFINT_D_W (MOVGR2FR_W GPR:$src))>; } // Predicates = [HasBasicD, IsLA32]