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llvm-mirror/lib/Target/ARM/ARMInstrVFP.td
David Green 684e62e531 [ARM] Remove hasSideEffects from FP converts
Whether an instruction is deemed to have side effects in determined by
whether it has a tblgen pattern that emits a single instruction.
Because of the way a lot of the the vcvt instructions are specified
either in dagtodag code or with patterns that emit multiple
instructions, they don't get marked as not having side effects.

This just marks them as not having side effects manually. It can help
especially with instruction scheduling, to not create artificial
barriers, but one of these tests also managed to produce fewer
instructions.

Differential Revision: https://reviews.llvm.org/D81639
2020-07-05 16:23:24 +01:00

2871 lines
110 KiB
TableGen

//===-- ARMInstrVFP.td - VFP support for ARM ---------------*- 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 ARM VFP instruction set.
//
//===----------------------------------------------------------------------===//
def SDT_CMPFP0 : SDTypeProfile<0, 1, [SDTCisFP<0>]>;
def SDT_VMOVDRR : SDTypeProfile<1, 2, [SDTCisVT<0, f64>, SDTCisVT<1, i32>,
SDTCisSameAs<1, 2>]>;
def SDT_VMOVRRD : SDTypeProfile<2, 1, [SDTCisVT<0, i32>, SDTCisSameAs<0, 1>,
SDTCisVT<2, f64>]>;
def SDT_VMOVSR : SDTypeProfile<1, 1, [SDTCisVT<0, f32>, SDTCisVT<1, i32>]>;
def arm_fmstat : SDNode<"ARMISD::FMSTAT", SDTNone, [SDNPInGlue, SDNPOutGlue]>;
def arm_cmpfp : SDNode<"ARMISD::CMPFP", SDT_ARMCmp, [SDNPOutGlue]>;
def arm_cmpfp0 : SDNode<"ARMISD::CMPFPw0", SDT_CMPFP0, [SDNPOutGlue]>;
def arm_cmpfpe : SDNode<"ARMISD::CMPFPE", SDT_ARMCmp, [SDNPOutGlue]>;
def arm_cmpfpe0: SDNode<"ARMISD::CMPFPEw0",SDT_CMPFP0, [SDNPOutGlue]>;
def arm_fmdrr : SDNode<"ARMISD::VMOVDRR", SDT_VMOVDRR>;
def arm_fmrrd : SDNode<"ARMISD::VMOVRRD", SDT_VMOVRRD>;
def arm_vmovsr : SDNode<"ARMISD::VMOVSR", SDT_VMOVSR>;
def SDT_VMOVhr : SDTypeProfile<1, 1, [SDTCisFP<0>, SDTCisVT<1, i32>] >;
def SDT_VMOVrh : SDTypeProfile<1, 1, [SDTCisVT<0, i32>, SDTCisFP<1>] >;
def arm_vmovhr : SDNode<"ARMISD::VMOVhr", SDT_VMOVhr>;
def arm_vmovrh : SDNode<"ARMISD::VMOVrh", SDT_VMOVrh>;
//===----------------------------------------------------------------------===//
// Operand Definitions.
//
// 8-bit floating-point immediate encodings.
def FPImmOperand : AsmOperandClass {
let Name = "FPImm";
let ParserMethod = "parseFPImm";
}
def vfp_f16imm : Operand<f16>,
PatLeaf<(f16 fpimm), [{
return ARM_AM::getFP16Imm(N->getValueAPF()) != -1;
}], SDNodeXForm<fpimm, [{
APFloat InVal = N->getValueAPF();
uint32_t enc = ARM_AM::getFP16Imm(InVal);
return CurDAG->getTargetConstant(enc, SDLoc(N), MVT::i32);
}]>> {
let PrintMethod = "printFPImmOperand";
let ParserMatchClass = FPImmOperand;
}
def vfp_f32imm_xform : SDNodeXForm<fpimm, [{
APFloat InVal = N->getValueAPF();
uint32_t enc = ARM_AM::getFP32Imm(InVal);
return CurDAG->getTargetConstant(enc, SDLoc(N), MVT::i32);
}]>;
def gi_vfp_f32imm : GICustomOperandRenderer<"renderVFPF32Imm">,
GISDNodeXFormEquiv<vfp_f32imm_xform>;
def vfp_f32imm : Operand<f32>,
PatLeaf<(f32 fpimm), [{
return ARM_AM::getFP32Imm(N->getValueAPF()) != -1;
}], vfp_f32imm_xform> {
let PrintMethod = "printFPImmOperand";
let ParserMatchClass = FPImmOperand;
let GISelPredicateCode = [{
const auto &MO = MI.getOperand(1);
if (!MO.isFPImm())
return false;
return ARM_AM::getFP32Imm(MO.getFPImm()->getValueAPF()) != -1;
}];
}
def vfp_f64imm_xform : SDNodeXForm<fpimm, [{
APFloat InVal = N->getValueAPF();
uint32_t enc = ARM_AM::getFP64Imm(InVal);
return CurDAG->getTargetConstant(enc, SDLoc(N), MVT::i32);
}]>;
def gi_vfp_f64imm : GICustomOperandRenderer<"renderVFPF64Imm">,
GISDNodeXFormEquiv<vfp_f64imm_xform>;
def vfp_f64imm : Operand<f64>,
PatLeaf<(f64 fpimm), [{
return ARM_AM::getFP64Imm(N->getValueAPF()) != -1;
}], vfp_f64imm_xform> {
let PrintMethod = "printFPImmOperand";
let ParserMatchClass = FPImmOperand;
let GISelPredicateCode = [{
const auto &MO = MI.getOperand(1);
if (!MO.isFPImm())
return false;
return ARM_AM::getFP64Imm(MO.getFPImm()->getValueAPF()) != -1;
}];
}
def alignedload16 : PatFrag<(ops node:$ptr), (load node:$ptr), [{
return cast<LoadSDNode>(N)->getAlignment() >= 2;
}]>;
def alignedload32 : PatFrag<(ops node:$ptr), (load node:$ptr), [{
return cast<LoadSDNode>(N)->getAlignment() >= 4;
}]>;
def alignedstore16 : PatFrag<(ops node:$val, node:$ptr),
(store node:$val, node:$ptr), [{
return cast<StoreSDNode>(N)->getAlignment() >= 2;
}]>;
def alignedstore32 : PatFrag<(ops node:$val, node:$ptr),
(store node:$val, node:$ptr), [{
return cast<StoreSDNode>(N)->getAlignment() >= 4;
}]>;
// The VCVT to/from fixed-point instructions encode the 'fbits' operand
// (the number of fixed bits) differently than it appears in the assembly
// source. It's encoded as "Size - fbits" where Size is the size of the
// fixed-point representation (32 or 16) and fbits is the value appearing
// in the assembly source, an integer in [0,16] or (0,32], depending on size.
def fbits32_asm_operand : AsmOperandClass { let Name = "FBits32"; }
def fbits32 : Operand<i32> {
let PrintMethod = "printFBits32";
let ParserMatchClass = fbits32_asm_operand;
}
def fbits16_asm_operand : AsmOperandClass { let Name = "FBits16"; }
def fbits16 : Operand<i32> {
let PrintMethod = "printFBits16";
let ParserMatchClass = fbits16_asm_operand;
}
//===----------------------------------------------------------------------===//
// Load / store Instructions.
//
let canFoldAsLoad = 1, isReMaterializable = 1 in {
def VLDRD : ADI5<0b1101, 0b01, (outs DPR:$Dd), (ins addrmode5:$addr),
IIC_fpLoad64, "vldr", "\t$Dd, $addr",
[(set DPR:$Dd, (f64 (alignedload32 addrmode5:$addr)))]>,
Requires<[HasFPRegs]>;
def VLDRS : ASI5<0b1101, 0b01, (outs SPR:$Sd), (ins addrmode5:$addr),
IIC_fpLoad32, "vldr", "\t$Sd, $addr",
[(set SPR:$Sd, (alignedload32 addrmode5:$addr))]>,
Requires<[HasFPRegs]> {
// Some single precision VFP instructions may be executed on both NEON and VFP
// pipelines.
let D = VFPNeonDomain;
}
let isUnpredicable = 1 in
def VLDRH : AHI5<0b1101, 0b01, (outs HPR:$Sd), (ins addrmode5fp16:$addr),
IIC_fpLoad16, "vldr", ".16\t$Sd, $addr",
[(set HPR:$Sd, (f16 (alignedload16 addrmode5fp16:$addr)))]>,
Requires<[HasFPRegs16]>;
} // End of 'let canFoldAsLoad = 1, isReMaterializable = 1 in'
def : Pat<(bf16 (alignedload16 addrmode5fp16:$addr)),
(VLDRH addrmode5fp16:$addr)> {
let Predicates = [HasFPRegs16];
}
def : Pat<(bf16 (alignedload16 addrmode3:$addr)),
(COPY_TO_REGCLASS (LDRH addrmode3:$addr), HPR)> {
let Predicates = [HasNoFPRegs16, IsARM];
}
def : Pat<(bf16 (alignedload16 t2addrmode_imm12:$addr)),
(COPY_TO_REGCLASS (t2LDRHi12 t2addrmode_imm12:$addr), HPR)> {
let Predicates = [HasNoFPRegs16, IsThumb];
}
def VSTRD : ADI5<0b1101, 0b00, (outs), (ins DPR:$Dd, addrmode5:$addr),
IIC_fpStore64, "vstr", "\t$Dd, $addr",
[(alignedstore32 (f64 DPR:$Dd), addrmode5:$addr)]>,
Requires<[HasFPRegs]>;
def VSTRS : ASI5<0b1101, 0b00, (outs), (ins SPR:$Sd, addrmode5:$addr),
IIC_fpStore32, "vstr", "\t$Sd, $addr",
[(alignedstore32 SPR:$Sd, addrmode5:$addr)]>,
Requires<[HasFPRegs]> {
// Some single precision VFP instructions may be executed on both NEON and VFP
// pipelines.
let D = VFPNeonDomain;
}
let isUnpredicable = 1 in
def VSTRH : AHI5<0b1101, 0b00, (outs), (ins HPR:$Sd, addrmode5fp16:$addr),
IIC_fpStore16, "vstr", ".16\t$Sd, $addr",
[(alignedstore16 (f16 HPR:$Sd), addrmode5fp16:$addr)]>,
Requires<[HasFPRegs16]>;
def : Pat<(alignedstore16 (bf16 HPR:$Sd), addrmode5fp16:$addr),
(VSTRH (bf16 HPR:$Sd), addrmode5fp16:$addr)> {
let Predicates = [HasFPRegs16];
}
def : Pat<(alignedstore16 (bf16 HPR:$Sd), addrmode3:$addr),
(STRH (COPY_TO_REGCLASS $Sd, GPR), addrmode3:$addr)> {
let Predicates = [HasNoFPRegs16, IsARM];
}
def : Pat<(alignedstore16 (bf16 HPR:$Sd), t2addrmode_imm12:$addr),
(t2STRHi12 (COPY_TO_REGCLASS $Sd, GPR), t2addrmode_imm12:$addr)> {
let Predicates = [HasNoFPRegs16, IsThumb];
}
//===----------------------------------------------------------------------===//
// Load / store multiple Instructions.
//
multiclass vfp_ldst_mult<string asm, bit L_bit,
InstrItinClass itin, InstrItinClass itin_upd> {
let Predicates = [HasFPRegs] in {
// Double Precision
def DIA :
AXDI4<(outs), (ins GPR:$Rn, pred:$p, dpr_reglist:$regs, variable_ops),
IndexModeNone, itin,
!strconcat(asm, "ia${p}\t$Rn, $regs"), "", []> {
let Inst{24-23} = 0b01; // Increment After
let Inst{21} = 0; // No writeback
let Inst{20} = L_bit;
}
def DIA_UPD :
AXDI4<(outs GPR:$wb), (ins GPR:$Rn, pred:$p, dpr_reglist:$regs,
variable_ops),
IndexModeUpd, itin_upd,
!strconcat(asm, "ia${p}\t$Rn!, $regs"), "$Rn = $wb", []> {
let Inst{24-23} = 0b01; // Increment After
let Inst{21} = 1; // Writeback
let Inst{20} = L_bit;
}
def DDB_UPD :
AXDI4<(outs GPR:$wb), (ins GPR:$Rn, pred:$p, dpr_reglist:$regs,
variable_ops),
IndexModeUpd, itin_upd,
!strconcat(asm, "db${p}\t$Rn!, $regs"), "$Rn = $wb", []> {
let Inst{24-23} = 0b10; // Decrement Before
let Inst{21} = 1; // Writeback
let Inst{20} = L_bit;
}
// Single Precision
def SIA :
AXSI4<(outs), (ins GPR:$Rn, pred:$p, spr_reglist:$regs, variable_ops),
IndexModeNone, itin,
!strconcat(asm, "ia${p}\t$Rn, $regs"), "", []> {
let Inst{24-23} = 0b01; // Increment After
let Inst{21} = 0; // No writeback
let Inst{20} = L_bit;
// Some single precision VFP instructions may be executed on both NEON and
// VFP pipelines.
let D = VFPNeonDomain;
}
def SIA_UPD :
AXSI4<(outs GPR:$wb), (ins GPR:$Rn, pred:$p, spr_reglist:$regs,
variable_ops),
IndexModeUpd, itin_upd,
!strconcat(asm, "ia${p}\t$Rn!, $regs"), "$Rn = $wb", []> {
let Inst{24-23} = 0b01; // Increment After
let Inst{21} = 1; // Writeback
let Inst{20} = L_bit;
// Some single precision VFP instructions may be executed on both NEON and
// VFP pipelines.
let D = VFPNeonDomain;
}
def SDB_UPD :
AXSI4<(outs GPR:$wb), (ins GPR:$Rn, pred:$p, spr_reglist:$regs,
variable_ops),
IndexModeUpd, itin_upd,
!strconcat(asm, "db${p}\t$Rn!, $regs"), "$Rn = $wb", []> {
let Inst{24-23} = 0b10; // Decrement Before
let Inst{21} = 1; // Writeback
let Inst{20} = L_bit;
// Some single precision VFP instructions may be executed on both NEON and
// VFP pipelines.
let D = VFPNeonDomain;
}
}
}
let hasSideEffects = 0 in {
let mayLoad = 1, hasExtraDefRegAllocReq = 1 in
defm VLDM : vfp_ldst_mult<"vldm", 1, IIC_fpLoad_m, IIC_fpLoad_mu>;
let mayStore = 1, hasExtraSrcRegAllocReq = 1 in
defm VSTM : vfp_ldst_mult<"vstm", 0, IIC_fpStore_m, IIC_fpStore_mu>;
} // hasSideEffects
def : MnemonicAlias<"vldm", "vldmia">;
def : MnemonicAlias<"vstm", "vstmia">;
//===----------------------------------------------------------------------===//
// Lazy load / store multiple Instructions
//
def VLLDM : AXSI4<(outs), (ins GPRnopc:$Rn, pred:$p), IndexModeNone,
NoItinerary, "vlldm${p}\t$Rn", "", []>,
Requires<[HasV8MMainline, Has8MSecExt]> {
let Inst{24-23} = 0b00;
let Inst{22} = 0;
let Inst{21} = 1;
let Inst{20} = 1;
let Inst{15-12} = 0;
let Inst{7-0} = 0;
let mayLoad = 1;
let Defs = [Q0, Q1, Q2, Q3, Q4, Q5, Q6, Q7, VPR, FPSCR, FPSCR_NZCV];
}
def VLSTM : AXSI4<(outs), (ins GPRnopc:$Rn, pred:$p), IndexModeNone,
NoItinerary, "vlstm${p}\t$Rn", "", []>,
Requires<[HasV8MMainline, Has8MSecExt]> {
let Inst{24-23} = 0b00;
let Inst{22} = 0;
let Inst{21} = 1;
let Inst{20} = 0;
let Inst{15-12} = 0;
let Inst{7-0} = 0;
let mayStore = 1;
}
def : InstAlias<"vpush${p} $r", (VSTMDDB_UPD SP, pred:$p, dpr_reglist:$r), 0>,
Requires<[HasFPRegs]>;
def : InstAlias<"vpush${p} $r", (VSTMSDB_UPD SP, pred:$p, spr_reglist:$r), 0>,
Requires<[HasFPRegs]>;
def : InstAlias<"vpop${p} $r", (VLDMDIA_UPD SP, pred:$p, dpr_reglist:$r), 0>,
Requires<[HasFPRegs]>;
def : InstAlias<"vpop${p} $r", (VLDMSIA_UPD SP, pred:$p, spr_reglist:$r), 0>,
Requires<[HasFPRegs]>;
defm : VFPDTAnyInstAlias<"vpush${p}", "$r",
(VSTMSDB_UPD SP, pred:$p, spr_reglist:$r)>;
defm : VFPDTAnyInstAlias<"vpush${p}", "$r",
(VSTMDDB_UPD SP, pred:$p, dpr_reglist:$r)>;
defm : VFPDTAnyInstAlias<"vpop${p}", "$r",
(VLDMSIA_UPD SP, pred:$p, spr_reglist:$r)>;
defm : VFPDTAnyInstAlias<"vpop${p}", "$r",
(VLDMDIA_UPD SP, pred:$p, dpr_reglist:$r)>;
// FLDMX, FSTMX - Load and store multiple unknown precision registers for
// pre-armv6 cores.
// These instruction are deprecated so we don't want them to get selected.
// However, there is no UAL syntax for them, so we keep them around for
// (dis)assembly only.
multiclass vfp_ldstx_mult<string asm, bit L_bit> {
let Predicates = [HasFPRegs], hasNoSchedulingInfo = 1 in {
// Unknown precision
def XIA :
AXXI4<(outs), (ins GPR:$Rn, pred:$p, dpr_reglist:$regs, variable_ops),
IndexModeNone, !strconcat(asm, "iax${p}\t$Rn, $regs"), "", []> {
let Inst{24-23} = 0b01; // Increment After
let Inst{21} = 0; // No writeback
let Inst{20} = L_bit;
}
def XIA_UPD :
AXXI4<(outs GPR:$wb), (ins GPR:$Rn, pred:$p, dpr_reglist:$regs, variable_ops),
IndexModeUpd, !strconcat(asm, "iax${p}\t$Rn!, $regs"), "$Rn = $wb", []> {
let Inst{24-23} = 0b01; // Increment After
let Inst{21} = 1; // Writeback
let Inst{20} = L_bit;
}
def XDB_UPD :
AXXI4<(outs GPR:$wb), (ins GPR:$Rn, pred:$p, dpr_reglist:$regs, variable_ops),
IndexModeUpd, !strconcat(asm, "dbx${p}\t$Rn!, $regs"), "$Rn = $wb", []> {
let Inst{24-23} = 0b10; // Decrement Before
let Inst{21} = 1; // Writeback
let Inst{20} = L_bit;
}
}
}
defm FLDM : vfp_ldstx_mult<"fldm", 1>;
defm FSTM : vfp_ldstx_mult<"fstm", 0>;
def : VFP2MnemonicAlias<"fldmeax", "fldmdbx">;
def : VFP2MnemonicAlias<"fldmfdx", "fldmiax">;
def : VFP2MnemonicAlias<"fstmeax", "fstmiax">;
def : VFP2MnemonicAlias<"fstmfdx", "fstmdbx">;
//===----------------------------------------------------------------------===//
// FP Binary Operations.
//
let TwoOperandAliasConstraint = "$Dn = $Dd" in
def VADDD : ADbI<0b11100, 0b11, 0, 0,
(outs DPR:$Dd), (ins DPR:$Dn, DPR:$Dm),
IIC_fpALU64, "vadd", ".f64\t$Dd, $Dn, $Dm",
[(set DPR:$Dd, (fadd DPR:$Dn, (f64 DPR:$Dm)))]>,
Sched<[WriteFPALU64]>;
let TwoOperandAliasConstraint = "$Sn = $Sd" in
def VADDS : ASbIn<0b11100, 0b11, 0, 0,
(outs SPR:$Sd), (ins SPR:$Sn, SPR:$Sm),
IIC_fpALU32, "vadd", ".f32\t$Sd, $Sn, $Sm",
[(set SPR:$Sd, (fadd SPR:$Sn, SPR:$Sm))]>,
Sched<[WriteFPALU32]> {
// Some single precision VFP instructions may be executed on both NEON and
// VFP pipelines on A8.
let D = VFPNeonA8Domain;
}
let TwoOperandAliasConstraint = "$Sn = $Sd" in
def VADDH : AHbI<0b11100, 0b11, 0, 0,
(outs HPR:$Sd), (ins HPR:$Sn, HPR:$Sm),
IIC_fpALU16, "vadd", ".f16\t$Sd, $Sn, $Sm",
[(set (f16 HPR:$Sd), (fadd (f16 HPR:$Sn), (f16 HPR:$Sm)))]>,
Sched<[WriteFPALU32]>;
let TwoOperandAliasConstraint = "$Dn = $Dd" in
def VSUBD : ADbI<0b11100, 0b11, 1, 0,
(outs DPR:$Dd), (ins DPR:$Dn, DPR:$Dm),
IIC_fpALU64, "vsub", ".f64\t$Dd, $Dn, $Dm",
[(set DPR:$Dd, (fsub DPR:$Dn, (f64 DPR:$Dm)))]>,
Sched<[WriteFPALU64]>;
let TwoOperandAliasConstraint = "$Sn = $Sd" in
def VSUBS : ASbIn<0b11100, 0b11, 1, 0,
(outs SPR:$Sd), (ins SPR:$Sn, SPR:$Sm),
IIC_fpALU32, "vsub", ".f32\t$Sd, $Sn, $Sm",
[(set SPR:$Sd, (fsub SPR:$Sn, SPR:$Sm))]>,
Sched<[WriteFPALU32]>{
// Some single precision VFP instructions may be executed on both NEON and
// VFP pipelines on A8.
let D = VFPNeonA8Domain;
}
let TwoOperandAliasConstraint = "$Sn = $Sd" in
def VSUBH : AHbI<0b11100, 0b11, 1, 0,
(outs HPR:$Sd), (ins HPR:$Sn, HPR:$Sm),
IIC_fpALU16, "vsub", ".f16\t$Sd, $Sn, $Sm",
[(set (f16 HPR:$Sd), (fsub (f16 HPR:$Sn), (f16 HPR:$Sm)))]>,
Sched<[WriteFPALU32]>;
let TwoOperandAliasConstraint = "$Dn = $Dd" in
def VDIVD : ADbI<0b11101, 0b00, 0, 0,
(outs DPR:$Dd), (ins DPR:$Dn, DPR:$Dm),
IIC_fpDIV64, "vdiv", ".f64\t$Dd, $Dn, $Dm",
[(set DPR:$Dd, (fdiv DPR:$Dn, (f64 DPR:$Dm)))]>,
Sched<[WriteFPDIV64]>;
let TwoOperandAliasConstraint = "$Sn = $Sd" in
def VDIVS : ASbI<0b11101, 0b00, 0, 0,
(outs SPR:$Sd), (ins SPR:$Sn, SPR:$Sm),
IIC_fpDIV32, "vdiv", ".f32\t$Sd, $Sn, $Sm",
[(set SPR:$Sd, (fdiv SPR:$Sn, SPR:$Sm))]>,
Sched<[WriteFPDIV32]>;
let TwoOperandAliasConstraint = "$Sn = $Sd" in
def VDIVH : AHbI<0b11101, 0b00, 0, 0,
(outs HPR:$Sd), (ins HPR:$Sn, HPR:$Sm),
IIC_fpDIV16, "vdiv", ".f16\t$Sd, $Sn, $Sm",
[(set (f16 HPR:$Sd), (fdiv (f16 HPR:$Sn), (f16 HPR:$Sm)))]>,
Sched<[WriteFPDIV32]>;
let TwoOperandAliasConstraint = "$Dn = $Dd" in
def VMULD : ADbI<0b11100, 0b10, 0, 0,
(outs DPR:$Dd), (ins DPR:$Dn, DPR:$Dm),
IIC_fpMUL64, "vmul", ".f64\t$Dd, $Dn, $Dm",
[(set DPR:$Dd, (fmul DPR:$Dn, (f64 DPR:$Dm)))]>,
Sched<[WriteFPMUL64, ReadFPMUL, ReadFPMUL]>;
let TwoOperandAliasConstraint = "$Sn = $Sd" in
def VMULS : ASbIn<0b11100, 0b10, 0, 0,
(outs SPR:$Sd), (ins SPR:$Sn, SPR:$Sm),
IIC_fpMUL32, "vmul", ".f32\t$Sd, $Sn, $Sm",
[(set SPR:$Sd, (fmul SPR:$Sn, SPR:$Sm))]>,
Sched<[WriteFPMUL32, ReadFPMUL, ReadFPMUL]> {
// Some single precision VFP instructions may be executed on both NEON and
// VFP pipelines on A8.
let D = VFPNeonA8Domain;
}
let TwoOperandAliasConstraint = "$Sn = $Sd" in
def VMULH : AHbI<0b11100, 0b10, 0, 0,
(outs HPR:$Sd), (ins HPR:$Sn, HPR:$Sm),
IIC_fpMUL16, "vmul", ".f16\t$Sd, $Sn, $Sm",
[(set (f16 HPR:$Sd), (fmul (f16 HPR:$Sn), (f16 HPR:$Sm)))]>,
Sched<[WriteFPMUL32, ReadFPMUL, ReadFPMUL]>;
def VNMULD : ADbI<0b11100, 0b10, 1, 0,
(outs DPR:$Dd), (ins DPR:$Dn, DPR:$Dm),
IIC_fpMUL64, "vnmul", ".f64\t$Dd, $Dn, $Dm",
[(set DPR:$Dd, (fneg (fmul DPR:$Dn, (f64 DPR:$Dm))))]>,
Sched<[WriteFPMUL64, ReadFPMUL, ReadFPMUL]>;
def VNMULS : ASbI<0b11100, 0b10, 1, 0,
(outs SPR:$Sd), (ins SPR:$Sn, SPR:$Sm),
IIC_fpMUL32, "vnmul", ".f32\t$Sd, $Sn, $Sm",
[(set SPR:$Sd, (fneg (fmul SPR:$Sn, SPR:$Sm)))]>,
Sched<[WriteFPMUL32, ReadFPMUL, ReadFPMUL]> {
// Some single precision VFP instructions may be executed on both NEON and
// VFP pipelines on A8.
let D = VFPNeonA8Domain;
}
def VNMULH : AHbI<0b11100, 0b10, 1, 0,
(outs HPR:$Sd), (ins HPR:$Sn, HPR:$Sm),
IIC_fpMUL16, "vnmul", ".f16\t$Sd, $Sn, $Sm",
[(set (f16 HPR:$Sd), (fneg (fmul (f16 HPR:$Sn), (f16 HPR:$Sm))))]>,
Sched<[WriteFPMUL32, ReadFPMUL, ReadFPMUL]>;
multiclass vsel_inst<string op, bits<2> opc, int CC> {
let DecoderNamespace = "VFPV8", PostEncoderMethod = "",
Uses = [CPSR], AddedComplexity = 4, isUnpredicable = 1 in {
def H : AHbInp<0b11100, opc, 0,
(outs HPR:$Sd), (ins HPR:$Sn, HPR:$Sm),
NoItinerary, !strconcat("vsel", op, ".f16\t$Sd, $Sn, $Sm"),
[(set (f16 HPR:$Sd), (ARMcmov (f16 HPR:$Sm), (f16 HPR:$Sn), CC))]>,
Requires<[HasFullFP16]>;
def S : ASbInp<0b11100, opc, 0,
(outs SPR:$Sd), (ins SPR:$Sn, SPR:$Sm),
NoItinerary, !strconcat("vsel", op, ".f32\t$Sd, $Sn, $Sm"),
[(set SPR:$Sd, (ARMcmov SPR:$Sm, SPR:$Sn, CC))]>,
Requires<[HasFPARMv8]>;
def D : ADbInp<0b11100, opc, 0,
(outs DPR:$Dd), (ins DPR:$Dn, DPR:$Dm),
NoItinerary, !strconcat("vsel", op, ".f64\t$Dd, $Dn, $Dm"),
[(set DPR:$Dd, (ARMcmov (f64 DPR:$Dm), (f64 DPR:$Dn), CC))]>,
Requires<[HasFPARMv8, HasDPVFP]>;
}
}
// The CC constants here match ARMCC::CondCodes.
defm VSELGT : vsel_inst<"gt", 0b11, 12>;
defm VSELGE : vsel_inst<"ge", 0b10, 10>;
defm VSELEQ : vsel_inst<"eq", 0b00, 0>;
defm VSELVS : vsel_inst<"vs", 0b01, 6>;
multiclass vmaxmin_inst<string op, bit opc, SDNode SD> {
let DecoderNamespace = "VFPV8", PostEncoderMethod = "",
isUnpredicable = 1 in {
def H : AHbInp<0b11101, 0b00, opc,
(outs HPR:$Sd), (ins HPR:$Sn, HPR:$Sm),
NoItinerary, !strconcat(op, ".f16\t$Sd, $Sn, $Sm"),
[(set (f16 HPR:$Sd), (SD (f16 HPR:$Sn), (f16 HPR:$Sm)))]>,
Requires<[HasFullFP16]>;
def S : ASbInp<0b11101, 0b00, opc,
(outs SPR:$Sd), (ins SPR:$Sn, SPR:$Sm),
NoItinerary, !strconcat(op, ".f32\t$Sd, $Sn, $Sm"),
[(set SPR:$Sd, (SD SPR:$Sn, SPR:$Sm))]>,
Requires<[HasFPARMv8]>;
def D : ADbInp<0b11101, 0b00, opc,
(outs DPR:$Dd), (ins DPR:$Dn, DPR:$Dm),
NoItinerary, !strconcat(op, ".f64\t$Dd, $Dn, $Dm"),
[(set DPR:$Dd, (f64 (SD (f64 DPR:$Dn), (f64 DPR:$Dm))))]>,
Requires<[HasFPARMv8, HasDPVFP]>;
}
}
defm VFP_VMAXNM : vmaxmin_inst<"vmaxnm", 0, fmaxnum>;
defm VFP_VMINNM : vmaxmin_inst<"vminnm", 1, fminnum>;
// Match reassociated forms only if not sign dependent rounding.
def : Pat<(fmul (fneg DPR:$a), (f64 DPR:$b)),
(VNMULD DPR:$a, DPR:$b)>,
Requires<[NoHonorSignDependentRounding,HasDPVFP]>;
def : Pat<(fmul (fneg SPR:$a), SPR:$b),
(VNMULS SPR:$a, SPR:$b)>, Requires<[NoHonorSignDependentRounding]>;
// These are encoded as unary instructions.
let Defs = [FPSCR_NZCV] in {
def VCMPED : ADuI<0b11101, 0b11, 0b0100, 0b11, 0,
(outs), (ins DPR:$Dd, DPR:$Dm),
IIC_fpCMP64, "vcmpe", ".f64\t$Dd, $Dm",
[(arm_cmpfpe DPR:$Dd, (f64 DPR:$Dm))]>;
def VCMPES : ASuI<0b11101, 0b11, 0b0100, 0b11, 0,
(outs), (ins SPR:$Sd, SPR:$Sm),
IIC_fpCMP32, "vcmpe", ".f32\t$Sd, $Sm",
[(arm_cmpfpe SPR:$Sd, SPR:$Sm)]> {
// Some single precision VFP instructions may be executed on both NEON and
// VFP pipelines on A8.
let D = VFPNeonA8Domain;
}
def VCMPEH : AHuI<0b11101, 0b11, 0b0100, 0b11, 0,
(outs), (ins HPR:$Sd, HPR:$Sm),
IIC_fpCMP16, "vcmpe", ".f16\t$Sd, $Sm",
[(arm_cmpfpe (f16 HPR:$Sd), (f16 HPR:$Sm))]>;
def VCMPD : ADuI<0b11101, 0b11, 0b0100, 0b01, 0,
(outs), (ins DPR:$Dd, DPR:$Dm),
IIC_fpCMP64, "vcmp", ".f64\t$Dd, $Dm",
[(arm_cmpfp DPR:$Dd, (f64 DPR:$Dm))]>;
def VCMPS : ASuI<0b11101, 0b11, 0b0100, 0b01, 0,
(outs), (ins SPR:$Sd, SPR:$Sm),
IIC_fpCMP32, "vcmp", ".f32\t$Sd, $Sm",
[(arm_cmpfp SPR:$Sd, SPR:$Sm)]> {
// Some single precision VFP instructions may be executed on both NEON and
// VFP pipelines on A8.
let D = VFPNeonA8Domain;
}
def VCMPH : AHuI<0b11101, 0b11, 0b0100, 0b01, 0,
(outs), (ins HPR:$Sd, HPR:$Sm),
IIC_fpCMP16, "vcmp", ".f16\t$Sd, $Sm",
[(arm_cmpfp (f16 HPR:$Sd), (f16 HPR:$Sm))]>;
} // Defs = [FPSCR_NZCV]
//===----------------------------------------------------------------------===//
// FP Unary Operations.
//
def VABSD : ADuI<0b11101, 0b11, 0b0000, 0b11, 0,
(outs DPR:$Dd), (ins DPR:$Dm),
IIC_fpUNA64, "vabs", ".f64\t$Dd, $Dm",
[(set DPR:$Dd, (fabs (f64 DPR:$Dm)))]>;
def VABSS : ASuIn<0b11101, 0b11, 0b0000, 0b11, 0,
(outs SPR:$Sd), (ins SPR:$Sm),
IIC_fpUNA32, "vabs", ".f32\t$Sd, $Sm",
[(set SPR:$Sd, (fabs SPR:$Sm))]> {
// Some single precision VFP instructions may be executed on both NEON and
// VFP pipelines on A8.
let D = VFPNeonA8Domain;
}
def VABSH : AHuI<0b11101, 0b11, 0b0000, 0b11, 0,
(outs HPR:$Sd), (ins HPR:$Sm),
IIC_fpUNA16, "vabs", ".f16\t$Sd, $Sm",
[(set (f16 HPR:$Sd), (fabs (f16 HPR:$Sm)))]>;
let Defs = [FPSCR_NZCV] in {
def VCMPEZD : ADuI<0b11101, 0b11, 0b0101, 0b11, 0,
(outs), (ins DPR:$Dd),
IIC_fpCMP64, "vcmpe", ".f64\t$Dd, #0",
[(arm_cmpfpe0 (f64 DPR:$Dd))]> {
let Inst{3-0} = 0b0000;
let Inst{5} = 0;
}
def VCMPEZS : ASuI<0b11101, 0b11, 0b0101, 0b11, 0,
(outs), (ins SPR:$Sd),
IIC_fpCMP32, "vcmpe", ".f32\t$Sd, #0",
[(arm_cmpfpe0 SPR:$Sd)]> {
let Inst{3-0} = 0b0000;
let Inst{5} = 0;
// Some single precision VFP instructions may be executed on both NEON and
// VFP pipelines on A8.
let D = VFPNeonA8Domain;
}
def VCMPEZH : AHuI<0b11101, 0b11, 0b0101, 0b11, 0,
(outs), (ins HPR:$Sd),
IIC_fpCMP16, "vcmpe", ".f16\t$Sd, #0",
[(arm_cmpfpe0 (f16 HPR:$Sd))]> {
let Inst{3-0} = 0b0000;
let Inst{5} = 0;
}
def VCMPZD : ADuI<0b11101, 0b11, 0b0101, 0b01, 0,
(outs), (ins DPR:$Dd),
IIC_fpCMP64, "vcmp", ".f64\t$Dd, #0",
[(arm_cmpfp0 (f64 DPR:$Dd))]> {
let Inst{3-0} = 0b0000;
let Inst{5} = 0;
}
def VCMPZS : ASuI<0b11101, 0b11, 0b0101, 0b01, 0,
(outs), (ins SPR:$Sd),
IIC_fpCMP32, "vcmp", ".f32\t$Sd, #0",
[(arm_cmpfp0 SPR:$Sd)]> {
let Inst{3-0} = 0b0000;
let Inst{5} = 0;
// Some single precision VFP instructions may be executed on both NEON and
// VFP pipelines on A8.
let D = VFPNeonA8Domain;
}
def VCMPZH : AHuI<0b11101, 0b11, 0b0101, 0b01, 0,
(outs), (ins HPR:$Sd),
IIC_fpCMP16, "vcmp", ".f16\t$Sd, #0",
[(arm_cmpfp0 (f16 HPR:$Sd))]> {
let Inst{3-0} = 0b0000;
let Inst{5} = 0;
}
} // Defs = [FPSCR_NZCV]
def VCVTDS : ASuI<0b11101, 0b11, 0b0111, 0b11, 0,
(outs DPR:$Dd), (ins SPR:$Sm),
IIC_fpCVTDS, "vcvt", ".f64.f32\t$Dd, $Sm",
[(set DPR:$Dd, (fpextend SPR:$Sm))]>,
Sched<[WriteFPCVT]> {
// Instruction operands.
bits<5> Dd;
bits<5> Sm;
// Encode instruction operands.
let Inst{3-0} = Sm{4-1};
let Inst{5} = Sm{0};
let Inst{15-12} = Dd{3-0};
let Inst{22} = Dd{4};
let Predicates = [HasVFP2, HasDPVFP];
let hasSideEffects = 0;
}
// Special case encoding: bits 11-8 is 0b1011.
def VCVTSD : VFPAI<(outs SPR:$Sd), (ins DPR:$Dm), VFPUnaryFrm,
IIC_fpCVTSD, "vcvt", ".f32.f64\t$Sd, $Dm",
[(set SPR:$Sd, (fpround DPR:$Dm))]>,
Sched<[WriteFPCVT]> {
// Instruction operands.
bits<5> Sd;
bits<5> Dm;
// Encode instruction operands.
let Inst{3-0} = Dm{3-0};
let Inst{5} = Dm{4};
let Inst{15-12} = Sd{4-1};
let Inst{22} = Sd{0};
let Inst{27-23} = 0b11101;
let Inst{21-16} = 0b110111;
let Inst{11-8} = 0b1011;
let Inst{7-6} = 0b11;
let Inst{4} = 0;
let Predicates = [HasVFP2, HasDPVFP];
let hasSideEffects = 0;
}
// Between half, single and double-precision.
let hasSideEffects = 0 in
def VCVTBHS: ASuI<0b11101, 0b11, 0b0010, 0b01, 0, (outs SPR:$Sd), (ins SPR:$Sm),
/* FIXME */ IIC_fpCVTSH, "vcvtb", ".f32.f16\t$Sd, $Sm",
[/* Intentionally left blank, see patterns below */]>,
Requires<[HasFP16]>,
Sched<[WriteFPCVT]>;
def : FP16Pat<(f32 (fpextend (f16 HPR:$Sm))),
(VCVTBHS (COPY_TO_REGCLASS (f16 HPR:$Sm), SPR))>;
def : FP16Pat<(f16_to_fp GPR:$a),
(VCVTBHS (COPY_TO_REGCLASS GPR:$a, SPR))>;
let hasSideEffects = 0 in
def VCVTBSH: ASuI<0b11101, 0b11, 0b0011, 0b01, 0, (outs SPR:$Sd), (ins SPR:$Sm),
/* FIXME */ IIC_fpCVTHS, "vcvtb", ".f16.f32\t$Sd, $Sm",
[/* Intentionally left blank, see patterns below */]>,
Requires<[HasFP16]>,
Sched<[WriteFPCVT]>;
def : FP16Pat<(f16 (fpround SPR:$Sm)),
(COPY_TO_REGCLASS (VCVTBSH SPR:$Sm), HPR)>;
def : FP16Pat<(fp_to_f16 SPR:$a),
(i32 (COPY_TO_REGCLASS (VCVTBSH SPR:$a), GPR))>;
def : FP16Pat<(insertelt (v8f16 MQPR:$src1), (f16 (fpround (f32 SPR:$src2))), imm_even:$lane),
(v8f16 (INSERT_SUBREG (v8f16 MQPR:$src1), (VCVTBSH SPR:$src2),
(SSubReg_f16_reg imm:$lane)))>;
def : FP16Pat<(insertelt (v4f16 DPR:$src1), (f16 (fpround (f32 SPR:$src2))), imm_even:$lane),
(v4f16 (INSERT_SUBREG (v4f16 DPR:$src1), (VCVTBSH SPR:$src2),
(SSubReg_f16_reg imm:$lane)))>;
let hasSideEffects = 0 in
def VCVTTHS: ASuI<0b11101, 0b11, 0b0010, 0b11, 0, (outs SPR:$Sd), (ins SPR:$Sm),
/* FIXME */ IIC_fpCVTSH, "vcvtt", ".f32.f16\t$Sd, $Sm",
[/* Intentionally left blank, see patterns below */]>,
Requires<[HasFP16]>,
Sched<[WriteFPCVT]>;
def : FP16Pat<(f32 (fpextend (extractelt (v8f16 MQPR:$src), imm_odd:$lane))),
(VCVTTHS (EXTRACT_SUBREG MQPR:$src, (SSubReg_f16_reg imm_odd:$lane)))>;
def : FP16Pat<(f32 (fpextend (extractelt (v4f16 DPR:$src), imm_odd:$lane))),
(VCVTTHS (EXTRACT_SUBREG
(v2f32 (COPY_TO_REGCLASS (v4f16 DPR:$src), DPR_VFP2)),
(SSubReg_f16_reg imm_odd:$lane)))>;
let hasSideEffects = 0 in
def VCVTTSH: ASuI<0b11101, 0b11, 0b0011, 0b11, 0, (outs SPR:$Sd), (ins SPR:$Sm),
/* FIXME */ IIC_fpCVTHS, "vcvtt", ".f16.f32\t$Sd, $Sm",
[/* Intentionally left blank, see patterns below */]>,
Requires<[HasFP16]>,
Sched<[WriteFPCVT]>;
def : FP16Pat<(insertelt (v8f16 MQPR:$src1), (f16 (fpround (f32 SPR:$src2))), imm_odd:$lane),
(v8f16 (INSERT_SUBREG (v8f16 MQPR:$src1), (VCVTTSH SPR:$src2),
(SSubReg_f16_reg imm:$lane)))>;
def : FP16Pat<(insertelt (v4f16 DPR:$src1), (f16 (fpround (f32 SPR:$src2))), imm_odd:$lane),
(v4f16 (INSERT_SUBREG (v4f16 DPR:$src1), (VCVTTSH SPR:$src2),
(SSubReg_f16_reg imm:$lane)))>;
def VCVTBHD : ADuI<0b11101, 0b11, 0b0010, 0b01, 0,
(outs DPR:$Dd), (ins SPR:$Sm),
NoItinerary, "vcvtb", ".f64.f16\t$Dd, $Sm",
[/* Intentionally left blank, see patterns below */]>,
Requires<[HasFPARMv8, HasDPVFP]>,
Sched<[WriteFPCVT]> {
// Instruction operands.
bits<5> Sm;
// Encode instruction operands.
let Inst{3-0} = Sm{4-1};
let Inst{5} = Sm{0};
let hasSideEffects = 0;
}
def : FullFP16Pat<(f64 (fpextend (f16 HPR:$Sm))),
(VCVTBHD (COPY_TO_REGCLASS (f16 HPR:$Sm), SPR))>,
Requires<[HasFPARMv8, HasDPVFP]>;
def : FP16Pat<(f64 (f16_to_fp GPR:$a)),
(VCVTBHD (COPY_TO_REGCLASS GPR:$a, SPR))>,
Requires<[HasFPARMv8, HasDPVFP]>;
def VCVTBDH : ADuI<0b11101, 0b11, 0b0011, 0b01, 0,
(outs SPR:$Sd), (ins DPR:$Dm),
NoItinerary, "vcvtb", ".f16.f64\t$Sd, $Dm",
[/* Intentionally left blank, see patterns below */]>,
Requires<[HasFPARMv8, HasDPVFP]> {
// Instruction operands.
bits<5> Sd;
bits<5> Dm;
// Encode instruction operands.
let Inst{3-0} = Dm{3-0};
let Inst{5} = Dm{4};
let Inst{15-12} = Sd{4-1};
let Inst{22} = Sd{0};
let hasSideEffects = 0;
}
def : FullFP16Pat<(f16 (fpround DPR:$Dm)),
(COPY_TO_REGCLASS (VCVTBDH DPR:$Dm), HPR)>,
Requires<[HasFPARMv8, HasDPVFP]>;
def : FP16Pat<(fp_to_f16 (f64 DPR:$a)),
(i32 (COPY_TO_REGCLASS (VCVTBDH DPR:$a), GPR))>,
Requires<[HasFPARMv8, HasDPVFP]>;
def VCVTTHD : ADuI<0b11101, 0b11, 0b0010, 0b11, 0,
(outs DPR:$Dd), (ins SPR:$Sm),
NoItinerary, "vcvtt", ".f64.f16\t$Dd, $Sm",
[]>, Requires<[HasFPARMv8, HasDPVFP]> {
// Instruction operands.
bits<5> Sm;
// Encode instruction operands.
let Inst{3-0} = Sm{4-1};
let Inst{5} = Sm{0};
let hasSideEffects = 0;
}
def VCVTTDH : ADuI<0b11101, 0b11, 0b0011, 0b11, 0,
(outs SPR:$Sd), (ins DPR:$Dm),
NoItinerary, "vcvtt", ".f16.f64\t$Sd, $Dm",
[]>, Requires<[HasFPARMv8, HasDPVFP]> {
// Instruction operands.
bits<5> Sd;
bits<5> Dm;
// Encode instruction operands.
let Inst{15-12} = Sd{4-1};
let Inst{22} = Sd{0};
let Inst{3-0} = Dm{3-0};
let Inst{5} = Dm{4};
let hasSideEffects = 0;
}
multiclass vcvt_inst<string opc, bits<2> rm,
SDPatternOperator node = null_frag> {
let PostEncoderMethod = "", DecoderNamespace = "VFPV8", hasSideEffects = 0 in {
def SH : AHuInp<0b11101, 0b11, 0b1100, 0b11, 0,
(outs SPR:$Sd), (ins HPR:$Sm),
NoItinerary, !strconcat("vcvt", opc, ".s32.f16\t$Sd, $Sm"),
[]>,
Requires<[HasFullFP16]> {
let Inst{17-16} = rm;
}
def UH : AHuInp<0b11101, 0b11, 0b1100, 0b01, 0,
(outs SPR:$Sd), (ins HPR:$Sm),
NoItinerary, !strconcat("vcvt", opc, ".u32.f16\t$Sd, $Sm"),
[]>,
Requires<[HasFullFP16]> {
let Inst{17-16} = rm;
}
def SS : ASuInp<0b11101, 0b11, 0b1100, 0b11, 0,
(outs SPR:$Sd), (ins SPR:$Sm),
NoItinerary, !strconcat("vcvt", opc, ".s32.f32\t$Sd, $Sm"),
[]>,
Requires<[HasFPARMv8]> {
let Inst{17-16} = rm;
}
def US : ASuInp<0b11101, 0b11, 0b1100, 0b01, 0,
(outs SPR:$Sd), (ins SPR:$Sm),
NoItinerary, !strconcat("vcvt", opc, ".u32.f32\t$Sd, $Sm"),
[]>,
Requires<[HasFPARMv8]> {
let Inst{17-16} = rm;
}
def SD : ASuInp<0b11101, 0b11, 0b1100, 0b11, 0,
(outs SPR:$Sd), (ins DPR:$Dm),
NoItinerary, !strconcat("vcvt", opc, ".s32.f64\t$Sd, $Dm"),
[]>,
Requires<[HasFPARMv8, HasDPVFP]> {
bits<5> Dm;
let Inst{17-16} = rm;
// Encode instruction operands.
let Inst{3-0} = Dm{3-0};
let Inst{5} = Dm{4};
let Inst{8} = 1;
}
def UD : ASuInp<0b11101, 0b11, 0b1100, 0b01, 0,
(outs SPR:$Sd), (ins DPR:$Dm),
NoItinerary, !strconcat("vcvt", opc, ".u32.f64\t$Sd, $Dm"),
[]>,
Requires<[HasFPARMv8, HasDPVFP]> {
bits<5> Dm;
let Inst{17-16} = rm;
// Encode instruction operands
let Inst{3-0} = Dm{3-0};
let Inst{5} = Dm{4};
let Inst{8} = 1;
}
}
let Predicates = [HasFPARMv8] in {
let Predicates = [HasFullFP16] in {
def : Pat<(i32 (fp_to_sint (node (f16 HPR:$a)))),
(COPY_TO_REGCLASS
(!cast<Instruction>(NAME#"SH") (f16 HPR:$a)),
GPR)>;
def : Pat<(i32 (fp_to_uint (node (f16 HPR:$a)))),
(COPY_TO_REGCLASS
(!cast<Instruction>(NAME#"UH") (f16 HPR:$a)),
GPR)>;
}
def : Pat<(i32 (fp_to_sint (node SPR:$a))),
(COPY_TO_REGCLASS
(!cast<Instruction>(NAME#"SS") SPR:$a),
GPR)>;
def : Pat<(i32 (fp_to_uint (node SPR:$a))),
(COPY_TO_REGCLASS
(!cast<Instruction>(NAME#"US") SPR:$a),
GPR)>;
}
let Predicates = [HasFPARMv8, HasDPVFP] in {
def : Pat<(i32 (fp_to_sint (node (f64 DPR:$a)))),
(COPY_TO_REGCLASS
(!cast<Instruction>(NAME#"SD") DPR:$a),
GPR)>;
def : Pat<(i32 (fp_to_uint (node (f64 DPR:$a)))),
(COPY_TO_REGCLASS
(!cast<Instruction>(NAME#"UD") DPR:$a),
GPR)>;
}
}
defm VCVTA : vcvt_inst<"a", 0b00, fround>;
defm VCVTN : vcvt_inst<"n", 0b01>;
defm VCVTP : vcvt_inst<"p", 0b10, fceil>;
defm VCVTM : vcvt_inst<"m", 0b11, ffloor>;
def VNEGD : ADuI<0b11101, 0b11, 0b0001, 0b01, 0,
(outs DPR:$Dd), (ins DPR:$Dm),
IIC_fpUNA64, "vneg", ".f64\t$Dd, $Dm",
[(set DPR:$Dd, (fneg (f64 DPR:$Dm)))]>;
def VNEGS : ASuIn<0b11101, 0b11, 0b0001, 0b01, 0,
(outs SPR:$Sd), (ins SPR:$Sm),
IIC_fpUNA32, "vneg", ".f32\t$Sd, $Sm",
[(set SPR:$Sd, (fneg SPR:$Sm))]> {
// Some single precision VFP instructions may be executed on both NEON and
// VFP pipelines on A8.
let D = VFPNeonA8Domain;
}
def VNEGH : AHuI<0b11101, 0b11, 0b0001, 0b01, 0,
(outs HPR:$Sd), (ins HPR:$Sm),
IIC_fpUNA16, "vneg", ".f16\t$Sd, $Sm",
[(set (f16 HPR:$Sd), (fneg (f16 HPR:$Sm)))]>;
multiclass vrint_inst_zrx<string opc, bit op, bit op2, SDPatternOperator node> {
def H : AHuI<0b11101, 0b11, 0b0110, 0b11, 0,
(outs HPR:$Sd), (ins HPR:$Sm),
NoItinerary, !strconcat("vrint", opc), ".f16\t$Sd, $Sm",
[(set (f16 HPR:$Sd), (node (f16 HPR:$Sm)))]>,
Requires<[HasFullFP16]> {
let Inst{7} = op2;
let Inst{16} = op;
}
def S : ASuI<0b11101, 0b11, 0b0110, 0b11, 0,
(outs SPR:$Sd), (ins SPR:$Sm),
NoItinerary, !strconcat("vrint", opc), ".f32\t$Sd, $Sm",
[(set (f32 SPR:$Sd), (node (f32 SPR:$Sm)))]>,
Requires<[HasFPARMv8]> {
let Inst{7} = op2;
let Inst{16} = op;
}
def D : ADuI<0b11101, 0b11, 0b0110, 0b11, 0,
(outs DPR:$Dd), (ins DPR:$Dm),
NoItinerary, !strconcat("vrint", opc), ".f64\t$Dd, $Dm",
[(set (f64 DPR:$Dd), (node (f64 DPR:$Dm)))]>,
Requires<[HasFPARMv8, HasDPVFP]> {
let Inst{7} = op2;
let Inst{16} = op;
}
def : InstAlias<!strconcat("vrint", opc, "$p.f16.f16\t$Sd, $Sm"),
(!cast<Instruction>(NAME#"H") SPR:$Sd, SPR:$Sm, pred:$p), 0>,
Requires<[HasFullFP16]>;
def : InstAlias<!strconcat("vrint", opc, "$p.f32.f32\t$Sd, $Sm"),
(!cast<Instruction>(NAME#"S") SPR:$Sd, SPR:$Sm, pred:$p), 0>,
Requires<[HasFPARMv8]>;
def : InstAlias<!strconcat("vrint", opc, "$p.f64.f64\t$Dd, $Dm"),
(!cast<Instruction>(NAME#"D") DPR:$Dd, DPR:$Dm, pred:$p), 0>,
Requires<[HasFPARMv8,HasDPVFP]>;
}
defm VRINTZ : vrint_inst_zrx<"z", 0, 1, ftrunc>;
defm VRINTR : vrint_inst_zrx<"r", 0, 0, fnearbyint>;
defm VRINTX : vrint_inst_zrx<"x", 1, 0, frint>;
multiclass vrint_inst_anpm<string opc, bits<2> rm,
SDPatternOperator node = null_frag> {
let PostEncoderMethod = "", DecoderNamespace = "VFPV8",
isUnpredicable = 1 in {
def H : AHuInp<0b11101, 0b11, 0b1000, 0b01, 0,
(outs HPR:$Sd), (ins HPR:$Sm),
NoItinerary, !strconcat("vrint", opc, ".f16\t$Sd, $Sm"),
[(set (f16 HPR:$Sd), (node (f16 HPR:$Sm)))]>,
Requires<[HasFullFP16]> {
let Inst{17-16} = rm;
}
def S : ASuInp<0b11101, 0b11, 0b1000, 0b01, 0,
(outs SPR:$Sd), (ins SPR:$Sm),
NoItinerary, !strconcat("vrint", opc, ".f32\t$Sd, $Sm"),
[(set (f32 SPR:$Sd), (node (f32 SPR:$Sm)))]>,
Requires<[HasFPARMv8]> {
let Inst{17-16} = rm;
}
def D : ADuInp<0b11101, 0b11, 0b1000, 0b01, 0,
(outs DPR:$Dd), (ins DPR:$Dm),
NoItinerary, !strconcat("vrint", opc, ".f64\t$Dd, $Dm"),
[(set (f64 DPR:$Dd), (node (f64 DPR:$Dm)))]>,
Requires<[HasFPARMv8, HasDPVFP]> {
let Inst{17-16} = rm;
}
}
def : InstAlias<!strconcat("vrint", opc, ".f32.f32\t$Sd, $Sm"),
(!cast<Instruction>(NAME#"S") SPR:$Sd, SPR:$Sm), 0>,
Requires<[HasFPARMv8]>;
def : InstAlias<!strconcat("vrint", opc, ".f64.f64\t$Dd, $Dm"),
(!cast<Instruction>(NAME#"D") DPR:$Dd, DPR:$Dm), 0>,
Requires<[HasFPARMv8,HasDPVFP]>;
}
defm VRINTA : vrint_inst_anpm<"a", 0b00, fround>;
defm VRINTN : vrint_inst_anpm<"n", 0b01, int_arm_neon_vrintn>;
defm VRINTP : vrint_inst_anpm<"p", 0b10, fceil>;
defm VRINTM : vrint_inst_anpm<"m", 0b11, ffloor>;
def VSQRTD : ADuI<0b11101, 0b11, 0b0001, 0b11, 0,
(outs DPR:$Dd), (ins DPR:$Dm),
IIC_fpSQRT64, "vsqrt", ".f64\t$Dd, $Dm",
[(set DPR:$Dd, (fsqrt (f64 DPR:$Dm)))]>,
Sched<[WriteFPSQRT64]>;
def VSQRTS : ASuI<0b11101, 0b11, 0b0001, 0b11, 0,
(outs SPR:$Sd), (ins SPR:$Sm),
IIC_fpSQRT32, "vsqrt", ".f32\t$Sd, $Sm",
[(set SPR:$Sd, (fsqrt SPR:$Sm))]>,
Sched<[WriteFPSQRT32]>;
def VSQRTH : AHuI<0b11101, 0b11, 0b0001, 0b11, 0,
(outs HPR:$Sd), (ins HPR:$Sm),
IIC_fpSQRT16, "vsqrt", ".f16\t$Sd, $Sm",
[(set (f16 HPR:$Sd), (fsqrt (f16 HPR:$Sm)))]>;
let hasSideEffects = 0 in {
let isMoveReg = 1 in {
def VMOVD : ADuI<0b11101, 0b11, 0b0000, 0b01, 0,
(outs DPR:$Dd), (ins DPR:$Dm),
IIC_fpUNA64, "vmov", ".f64\t$Dd, $Dm", []>,
Requires<[HasFPRegs64]>;
def VMOVS : ASuI<0b11101, 0b11, 0b0000, 0b01, 0,
(outs SPR:$Sd), (ins SPR:$Sm),
IIC_fpUNA32, "vmov", ".f32\t$Sd, $Sm", []>,
Requires<[HasFPRegs]>;
} // isMoveReg
let PostEncoderMethod = "", DecoderNamespace = "VFPV8", isUnpredicable = 1 in {
def VMOVH : ASuInp<0b11101, 0b11, 0b0000, 0b01, 0,
(outs SPR:$Sd), (ins SPR:$Sm),
IIC_fpUNA16, "vmovx.f16\t$Sd, $Sm", []>,
Requires<[HasFullFP16]>;
def VINSH : ASuInp<0b11101, 0b11, 0b0000, 0b11, 0,
(outs SPR:$Sd), (ins SPR:$Sm),
IIC_fpUNA16, "vins.f16\t$Sd, $Sm", []>,
Requires<[HasFullFP16]>;
} // PostEncoderMethod
} // hasSideEffects
//===----------------------------------------------------------------------===//
// FP <-> GPR Copies. Int <-> FP Conversions.
//
let isMoveReg = 1 in {
def VMOVRS : AVConv2I<0b11100001, 0b1010,
(outs GPR:$Rt), (ins SPR:$Sn),
IIC_fpMOVSI, "vmov", "\t$Rt, $Sn",
[(set GPR:$Rt, (bitconvert SPR:$Sn))]>,
Requires<[HasFPRegs]>,
Sched<[WriteFPMOV]> {
// Instruction operands.
bits<4> Rt;
bits<5> Sn;
// Encode instruction operands.
let Inst{19-16} = Sn{4-1};
let Inst{7} = Sn{0};
let Inst{15-12} = Rt;
let Inst{6-5} = 0b00;
let Inst{3-0} = 0b0000;
// Some single precision VFP instructions may be executed on both NEON and VFP
// pipelines.
let D = VFPNeonDomain;
}
// Bitcast i32 -> f32. NEON prefers to use VMOVDRR.
def VMOVSR : AVConv4I<0b11100000, 0b1010,
(outs SPR:$Sn), (ins GPR:$Rt),
IIC_fpMOVIS, "vmov", "\t$Sn, $Rt",
[(set SPR:$Sn, (bitconvert GPR:$Rt))]>,
Requires<[HasFPRegs, UseVMOVSR]>,
Sched<[WriteFPMOV]> {
// Instruction operands.
bits<5> Sn;
bits<4> Rt;
// Encode instruction operands.
let Inst{19-16} = Sn{4-1};
let Inst{7} = Sn{0};
let Inst{15-12} = Rt;
let Inst{6-5} = 0b00;
let Inst{3-0} = 0b0000;
// Some single precision VFP instructions may be executed on both NEON and VFP
// pipelines.
let D = VFPNeonDomain;
}
} // isMoveReg
def : Pat<(arm_vmovsr GPR:$Rt), (VMOVSR GPR:$Rt)>, Requires<[HasVFP2, UseVMOVSR]>;
let hasSideEffects = 0 in {
def VMOVRRD : AVConv3I<0b11000101, 0b1011,
(outs GPR:$Rt, GPR:$Rt2), (ins DPR:$Dm),
IIC_fpMOVDI, "vmov", "\t$Rt, $Rt2, $Dm",
[(set GPR:$Rt, GPR:$Rt2, (arm_fmrrd DPR:$Dm))]>,
Requires<[HasFPRegs]>,
Sched<[WriteFPMOV]> {
// Instruction operands.
bits<5> Dm;
bits<4> Rt;
bits<4> Rt2;
// Encode instruction operands.
let Inst{3-0} = Dm{3-0};
let Inst{5} = Dm{4};
let Inst{15-12} = Rt;
let Inst{19-16} = Rt2;
let Inst{7-6} = 0b00;
// Some single precision VFP instructions may be executed on both NEON and VFP
// pipelines.
let D = VFPNeonDomain;
// This instruction is equivalent to
// $Rt = EXTRACT_SUBREG $Dm, ssub_0
// $Rt2 = EXTRACT_SUBREG $Dm, ssub_1
let isExtractSubreg = 1;
}
def VMOVRRS : AVConv3I<0b11000101, 0b1010,
(outs GPR:$Rt, GPR:$Rt2), (ins SPR:$src1, SPR:$src2),
IIC_fpMOVDI, "vmov", "\t$Rt, $Rt2, $src1, $src2",
[/* For disassembly only; pattern left blank */]>,
Requires<[HasFPRegs]>,
Sched<[WriteFPMOV]> {
bits<5> src1;
bits<4> Rt;
bits<4> Rt2;
// Encode instruction operands.
let Inst{3-0} = src1{4-1};
let Inst{5} = src1{0};
let Inst{15-12} = Rt;
let Inst{19-16} = Rt2;
let Inst{7-6} = 0b00;
// Some single precision VFP instructions may be executed on both NEON and VFP
// pipelines.
let D = VFPNeonDomain;
let DecoderMethod = "DecodeVMOVRRS";
}
} // hasSideEffects
// FMDHR: GPR -> SPR
// FMDLR: GPR -> SPR
def VMOVDRR : AVConv5I<0b11000100, 0b1011,
(outs DPR:$Dm), (ins GPR:$Rt, GPR:$Rt2),
IIC_fpMOVID, "vmov", "\t$Dm, $Rt, $Rt2",
[(set DPR:$Dm, (arm_fmdrr GPR:$Rt, GPR:$Rt2))]>,
Requires<[HasFPRegs]>,
Sched<[WriteFPMOV]> {
// Instruction operands.
bits<5> Dm;
bits<4> Rt;
bits<4> Rt2;
// Encode instruction operands.
let Inst{3-0} = Dm{3-0};
let Inst{5} = Dm{4};
let Inst{15-12} = Rt;
let Inst{19-16} = Rt2;
let Inst{7-6} = 0b00;
// Some single precision VFP instructions may be executed on both NEON and VFP
// pipelines.
let D = VFPNeonDomain;
// This instruction is equivalent to
// $Dm = REG_SEQUENCE $Rt, ssub_0, $Rt2, ssub_1
let isRegSequence = 1;
}
// Hoist an fabs or a fneg of a value coming from integer registers
// and do the fabs/fneg on the integer value. This is never a lose
// and could enable the conversion to float to be removed completely.
def : Pat<(fabs (arm_fmdrr GPR:$Rl, GPR:$Rh)),
(VMOVDRR GPR:$Rl, (BFC GPR:$Rh, (i32 0x7FFFFFFF)))>,
Requires<[IsARM, HasV6T2]>;
def : Pat<(fabs (arm_fmdrr GPR:$Rl, GPR:$Rh)),
(VMOVDRR GPR:$Rl, (t2BFC GPR:$Rh, (i32 0x7FFFFFFF)))>,
Requires<[IsThumb2, HasV6T2]>;
def : Pat<(fneg (arm_fmdrr GPR:$Rl, GPR:$Rh)),
(VMOVDRR GPR:$Rl, (EORri GPR:$Rh, (i32 0x80000000)))>,
Requires<[IsARM]>;
def : Pat<(fneg (arm_fmdrr GPR:$Rl, GPR:$Rh)),
(VMOVDRR GPR:$Rl, (t2EORri GPR:$Rh, (i32 0x80000000)))>,
Requires<[IsThumb2]>;
let hasSideEffects = 0 in
def VMOVSRR : AVConv5I<0b11000100, 0b1010,
(outs SPR:$dst1, SPR:$dst2), (ins GPR:$src1, GPR:$src2),
IIC_fpMOVID, "vmov", "\t$dst1, $dst2, $src1, $src2",
[/* For disassembly only; pattern left blank */]>,
Requires<[HasFPRegs]>,
Sched<[WriteFPMOV]> {
// Instruction operands.
bits<5> dst1;
bits<4> src1;
bits<4> src2;
// Encode instruction operands.
let Inst{3-0} = dst1{4-1};
let Inst{5} = dst1{0};
let Inst{15-12} = src1;
let Inst{19-16} = src2;
let Inst{7-6} = 0b00;
// Some single precision VFP instructions may be executed on both NEON and VFP
// pipelines.
let D = VFPNeonDomain;
let DecoderMethod = "DecodeVMOVSRR";
}
// Move H->R, clearing top 16 bits
def VMOVRH : AVConv2I<0b11100001, 0b1001,
(outs rGPR:$Rt), (ins HPR:$Sn),
IIC_fpMOVSI, "vmov", ".f16\t$Rt, $Sn",
[]>,
Requires<[HasFPRegs16]>,
Sched<[WriteFPMOV]> {
// Instruction operands.
bits<4> Rt;
bits<5> Sn;
// Encode instruction operands.
let Inst{19-16} = Sn{4-1};
let Inst{7} = Sn{0};
let Inst{15-12} = Rt;
let Inst{6-5} = 0b00;
let Inst{3-0} = 0b0000;
let isUnpredicable = 1;
}
// Move R->H, clearing top 16 bits
def VMOVHR : AVConv4I<0b11100000, 0b1001,
(outs HPR:$Sn), (ins rGPR:$Rt),
IIC_fpMOVIS, "vmov", ".f16\t$Sn, $Rt",
[]>,
Requires<[HasFPRegs16]>,
Sched<[WriteFPMOV]> {
// Instruction operands.
bits<5> Sn;
bits<4> Rt;
// Encode instruction operands.
let Inst{19-16} = Sn{4-1};
let Inst{7} = Sn{0};
let Inst{15-12} = Rt;
let Inst{6-5} = 0b00;
let Inst{3-0} = 0b0000;
let isUnpredicable = 1;
}
def : FPRegs16Pat<(arm_vmovrh (f16 HPR:$Sn)), (VMOVRH (f16 HPR:$Sn))>;
def : FPRegs16Pat<(arm_vmovrh (bf16 HPR:$Sn)), (VMOVRH (bf16 HPR:$Sn))>;
def : FPRegs16Pat<(f16 (arm_vmovhr rGPR:$Rt)), (VMOVHR rGPR:$Rt)>;
def : FPRegs16Pat<(bf16 (arm_vmovhr rGPR:$Rt)), (VMOVHR rGPR:$Rt)>;
// FMRDH: SPR -> GPR
// FMRDL: SPR -> GPR
// FMRRS: SPR -> GPR
// FMRX: SPR system reg -> GPR
// FMSRR: GPR -> SPR
// FMXR: GPR -> VFP system reg
// Int -> FP:
class AVConv1IDs_Encode<bits<5> opcod1, bits<2> opcod2, bits<4> opcod3,
bits<4> opcod4, dag oops, dag iops,
InstrItinClass itin, string opc, string asm,
list<dag> pattern>
: AVConv1I<opcod1, opcod2, opcod3, opcod4, oops, iops, itin, opc, asm,
pattern> {
// Instruction operands.
bits<5> Dd;
bits<5> Sm;
// Encode instruction operands.
let Inst{3-0} = Sm{4-1};
let Inst{5} = Sm{0};
let Inst{15-12} = Dd{3-0};
let Inst{22} = Dd{4};
let Predicates = [HasVFP2, HasDPVFP];
let hasSideEffects = 0;
}
class AVConv1InSs_Encode<bits<5> opcod1, bits<2> opcod2, bits<4> opcod3,
bits<4> opcod4, dag oops, dag iops,InstrItinClass itin,
string opc, string asm, list<dag> pattern>
: AVConv1In<opcod1, opcod2, opcod3, opcod4, oops, iops, itin, opc, asm,
pattern> {
// Instruction operands.
bits<5> Sd;
bits<5> Sm;
// Encode instruction operands.
let Inst{3-0} = Sm{4-1};
let Inst{5} = Sm{0};
let Inst{15-12} = Sd{4-1};
let Inst{22} = Sd{0};
let hasSideEffects = 0;
}
class AVConv1IHs_Encode<bits<5> opcod1, bits<2> opcod2, bits<4> opcod3,
bits<4> opcod4, dag oops, dag iops,
InstrItinClass itin, string opc, string asm,
list<dag> pattern>
: AVConv1I<opcod1, opcod2, opcod3, opcod4, oops, iops, itin, opc, asm,
pattern> {
// Instruction operands.
bits<5> Sd;
bits<5> Sm;
// Encode instruction operands.
let Inst{3-0} = Sm{4-1};
let Inst{5} = Sm{0};
let Inst{15-12} = Sd{4-1};
let Inst{22} = Sd{0};
let Predicates = [HasFullFP16];
let hasSideEffects = 0;
}
def VSITOD : AVConv1IDs_Encode<0b11101, 0b11, 0b1000, 0b1011,
(outs DPR:$Dd), (ins SPR:$Sm),
IIC_fpCVTID, "vcvt", ".f64.s32\t$Dd, $Sm",
[]>,
Sched<[WriteFPCVT]> {
let Inst{7} = 1; // s32
}
let Predicates=[HasVFP2, HasDPVFP] in {
def : VFPPat<(f64 (sint_to_fp GPR:$a)),
(VSITOD (COPY_TO_REGCLASS GPR:$a, SPR))>;
def : VFPPat<(f64 (sint_to_fp (i32 (alignedload32 addrmode5:$a)))),
(VSITOD (VLDRS addrmode5:$a))>;
}
def VSITOS : AVConv1InSs_Encode<0b11101, 0b11, 0b1000, 0b1010,
(outs SPR:$Sd),(ins SPR:$Sm),
IIC_fpCVTIS, "vcvt", ".f32.s32\t$Sd, $Sm",
[]>,
Sched<[WriteFPCVT]> {
let Inst{7} = 1; // s32
// Some single precision VFP instructions may be executed on both NEON and
// VFP pipelines on A8.
let D = VFPNeonA8Domain;
}
def : VFPNoNEONPat<(f32 (sint_to_fp GPR:$a)),
(VSITOS (COPY_TO_REGCLASS GPR:$a, SPR))>;
def : VFPNoNEONPat<(f32 (sint_to_fp (i32 (alignedload32 addrmode5:$a)))),
(VSITOS (VLDRS addrmode5:$a))>;
def VSITOH : AVConv1IHs_Encode<0b11101, 0b11, 0b1000, 0b1001,
(outs HPR:$Sd), (ins SPR:$Sm),
IIC_fpCVTIH, "vcvt", ".f16.s32\t$Sd, $Sm",
[]>,
Sched<[WriteFPCVT]> {
let Inst{7} = 1; // s32
let isUnpredicable = 1;
}
def : VFPNoNEONPat<(f16 (sint_to_fp GPR:$a)),
(VSITOH (COPY_TO_REGCLASS GPR:$a, SPR))>;
def VUITOD : AVConv1IDs_Encode<0b11101, 0b11, 0b1000, 0b1011,
(outs DPR:$Dd), (ins SPR:$Sm),
IIC_fpCVTID, "vcvt", ".f64.u32\t$Dd, $Sm",
[]>,
Sched<[WriteFPCVT]> {
let Inst{7} = 0; // u32
}
let Predicates=[HasVFP2, HasDPVFP] in {
def : VFPPat<(f64 (uint_to_fp GPR:$a)),
(VUITOD (COPY_TO_REGCLASS GPR:$a, SPR))>;
def : VFPPat<(f64 (uint_to_fp (i32 (alignedload32 addrmode5:$a)))),
(VUITOD (VLDRS addrmode5:$a))>;
}
def VUITOS : AVConv1InSs_Encode<0b11101, 0b11, 0b1000, 0b1010,
(outs SPR:$Sd), (ins SPR:$Sm),
IIC_fpCVTIS, "vcvt", ".f32.u32\t$Sd, $Sm",
[]>,
Sched<[WriteFPCVT]> {
let Inst{7} = 0; // u32
// Some single precision VFP instructions may be executed on both NEON and
// VFP pipelines on A8.
let D = VFPNeonA8Domain;
}
def : VFPNoNEONPat<(f32 (uint_to_fp GPR:$a)),
(VUITOS (COPY_TO_REGCLASS GPR:$a, SPR))>;
def : VFPNoNEONPat<(f32 (uint_to_fp (i32 (alignedload32 addrmode5:$a)))),
(VUITOS (VLDRS addrmode5:$a))>;
def VUITOH : AVConv1IHs_Encode<0b11101, 0b11, 0b1000, 0b1001,
(outs HPR:$Sd), (ins SPR:$Sm),
IIC_fpCVTIH, "vcvt", ".f16.u32\t$Sd, $Sm",
[]>,
Sched<[WriteFPCVT]> {
let Inst{7} = 0; // u32
let isUnpredicable = 1;
}
def : VFPNoNEONPat<(f16 (uint_to_fp GPR:$a)),
(VUITOH (COPY_TO_REGCLASS GPR:$a, SPR))>;
// FP -> Int:
class AVConv1IsD_Encode<bits<5> opcod1, bits<2> opcod2, bits<4> opcod3,
bits<4> opcod4, dag oops, dag iops,
InstrItinClass itin, string opc, string asm,
list<dag> pattern>
: AVConv1I<opcod1, opcod2, opcod3, opcod4, oops, iops, itin, opc, asm,
pattern> {
// Instruction operands.
bits<5> Sd;
bits<5> Dm;
// Encode instruction operands.
let Inst{3-0} = Dm{3-0};
let Inst{5} = Dm{4};
let Inst{15-12} = Sd{4-1};
let Inst{22} = Sd{0};
let Predicates = [HasVFP2, HasDPVFP];
let hasSideEffects = 0;
}
class AVConv1InsS_Encode<bits<5> opcod1, bits<2> opcod2, bits<4> opcod3,
bits<4> opcod4, dag oops, dag iops,
InstrItinClass itin, string opc, string asm,
list<dag> pattern>
: AVConv1In<opcod1, opcod2, opcod3, opcod4, oops, iops, itin, opc, asm,
pattern> {
// Instruction operands.
bits<5> Sd;
bits<5> Sm;
// Encode instruction operands.
let Inst{3-0} = Sm{4-1};
let Inst{5} = Sm{0};
let Inst{15-12} = Sd{4-1};
let Inst{22} = Sd{0};
}
class AVConv1IsH_Encode<bits<5> opcod1, bits<2> opcod2, bits<4> opcod3,
bits<4> opcod4, dag oops, dag iops,
InstrItinClass itin, string opc, string asm,
list<dag> pattern>
: AVConv1I<opcod1, opcod2, opcod3, opcod4, oops, iops, itin, opc, asm,
pattern> {
// Instruction operands.
bits<5> Sd;
bits<5> Sm;
// Encode instruction operands.
let Inst{3-0} = Sm{4-1};
let Inst{5} = Sm{0};
let Inst{15-12} = Sd{4-1};
let Inst{22} = Sd{0};
let Predicates = [HasFullFP16];
let hasSideEffects = 0;
}
// Always set Z bit in the instruction, i.e. "round towards zero" variants.
def VTOSIZD : AVConv1IsD_Encode<0b11101, 0b11, 0b1101, 0b1011,
(outs SPR:$Sd), (ins DPR:$Dm),
IIC_fpCVTDI, "vcvt", ".s32.f64\t$Sd, $Dm",
[]>,
Sched<[WriteFPCVT]> {
let Inst{7} = 1; // Z bit
}
let Predicates=[HasVFP2, HasDPVFP] in {
def : VFPPat<(i32 (fp_to_sint (f64 DPR:$a))),
(COPY_TO_REGCLASS (VTOSIZD DPR:$a), GPR)>;
def : VFPPat<(alignedstore32 (i32 (fp_to_sint (f64 DPR:$a))), addrmode5:$ptr),
(VSTRS (VTOSIZD DPR:$a), addrmode5:$ptr)>;
}
def VTOSIZS : AVConv1InsS_Encode<0b11101, 0b11, 0b1101, 0b1010,
(outs SPR:$Sd), (ins SPR:$Sm),
IIC_fpCVTSI, "vcvt", ".s32.f32\t$Sd, $Sm",
[]>,
Sched<[WriteFPCVT]> {
let Inst{7} = 1; // Z bit
// Some single precision VFP instructions may be executed on both NEON and
// VFP pipelines on A8.
let D = VFPNeonA8Domain;
}
def : VFPNoNEONPat<(i32 (fp_to_sint SPR:$a)),
(COPY_TO_REGCLASS (VTOSIZS SPR:$a), GPR)>;
def : VFPNoNEONPat<(alignedstore32 (i32 (fp_to_sint (f32 SPR:$a))),
addrmode5:$ptr),
(VSTRS (VTOSIZS SPR:$a), addrmode5:$ptr)>;
def VTOSIZH : AVConv1IsH_Encode<0b11101, 0b11, 0b1101, 0b1001,
(outs SPR:$Sd), (ins HPR:$Sm),
IIC_fpCVTHI, "vcvt", ".s32.f16\t$Sd, $Sm",
[]>,
Sched<[WriteFPCVT]> {
let Inst{7} = 1; // Z bit
let isUnpredicable = 1;
}
def : VFPNoNEONPat<(i32 (fp_to_sint (f16 HPR:$a))),
(COPY_TO_REGCLASS (VTOSIZH (f16 HPR:$a)), GPR)>;
def VTOUIZD : AVConv1IsD_Encode<0b11101, 0b11, 0b1100, 0b1011,
(outs SPR:$Sd), (ins DPR:$Dm),
IIC_fpCVTDI, "vcvt", ".u32.f64\t$Sd, $Dm",
[]>,
Sched<[WriteFPCVT]> {
let Inst{7} = 1; // Z bit
}
let Predicates=[HasVFP2, HasDPVFP] in {
def : VFPPat<(i32 (fp_to_uint (f64 DPR:$a))),
(COPY_TO_REGCLASS (VTOUIZD DPR:$a), GPR)>;
def : VFPPat<(alignedstore32 (i32 (fp_to_uint (f64 DPR:$a))), addrmode5:$ptr),
(VSTRS (VTOUIZD DPR:$a), addrmode5:$ptr)>;
}
def VTOUIZS : AVConv1InsS_Encode<0b11101, 0b11, 0b1100, 0b1010,
(outs SPR:$Sd), (ins SPR:$Sm),
IIC_fpCVTSI, "vcvt", ".u32.f32\t$Sd, $Sm",
[]>,
Sched<[WriteFPCVT]> {
let Inst{7} = 1; // Z bit
// Some single precision VFP instructions may be executed on both NEON and
// VFP pipelines on A8.
let D = VFPNeonA8Domain;
}
def : VFPNoNEONPat<(i32 (fp_to_uint SPR:$a)),
(COPY_TO_REGCLASS (VTOUIZS SPR:$a), GPR)>;
def : VFPNoNEONPat<(alignedstore32 (i32 (fp_to_uint (f32 SPR:$a))),
addrmode5:$ptr),
(VSTRS (VTOUIZS SPR:$a), addrmode5:$ptr)>;
def VTOUIZH : AVConv1IsH_Encode<0b11101, 0b11, 0b1100, 0b1001,
(outs SPR:$Sd), (ins HPR:$Sm),
IIC_fpCVTHI, "vcvt", ".u32.f16\t$Sd, $Sm",
[]>,
Sched<[WriteFPCVT]> {
let Inst{7} = 1; // Z bit
let isUnpredicable = 1;
}
def : VFPNoNEONPat<(i32 (fp_to_uint (f16 HPR:$a))),
(COPY_TO_REGCLASS (VTOUIZH (f16 HPR:$a)), GPR)>;
// And the Z bit '0' variants, i.e. use the rounding mode specified by FPSCR.
let Uses = [FPSCR] in {
def VTOSIRD : AVConv1IsD_Encode<0b11101, 0b11, 0b1101, 0b1011,
(outs SPR:$Sd), (ins DPR:$Dm),
IIC_fpCVTDI, "vcvtr", ".s32.f64\t$Sd, $Dm",
[(set SPR:$Sd, (int_arm_vcvtr (f64 DPR:$Dm)))]>,
Sched<[WriteFPCVT]> {
let Inst{7} = 0; // Z bit
}
def VTOSIRS : AVConv1InsS_Encode<0b11101, 0b11, 0b1101, 0b1010,
(outs SPR:$Sd), (ins SPR:$Sm),
IIC_fpCVTSI, "vcvtr", ".s32.f32\t$Sd, $Sm",
[(set SPR:$Sd, (int_arm_vcvtr SPR:$Sm))]>,
Sched<[WriteFPCVT]> {
let Inst{7} = 0; // Z bit
}
def VTOSIRH : AVConv1IsH_Encode<0b11101, 0b11, 0b1101, 0b1001,
(outs SPR:$Sd), (ins SPR:$Sm),
IIC_fpCVTHI, "vcvtr", ".s32.f16\t$Sd, $Sm",
[]>,
Sched<[WriteFPCVT]> {
let Inst{7} = 0; // Z bit
let isUnpredicable = 1;
}
def VTOUIRD : AVConv1IsD_Encode<0b11101, 0b11, 0b1100, 0b1011,
(outs SPR:$Sd), (ins DPR:$Dm),
IIC_fpCVTDI, "vcvtr", ".u32.f64\t$Sd, $Dm",
[(set SPR:$Sd, (int_arm_vcvtru(f64 DPR:$Dm)))]>,
Sched<[WriteFPCVT]> {
let Inst{7} = 0; // Z bit
}
def VTOUIRS : AVConv1InsS_Encode<0b11101, 0b11, 0b1100, 0b1010,
(outs SPR:$Sd), (ins SPR:$Sm),
IIC_fpCVTSI, "vcvtr", ".u32.f32\t$Sd, $Sm",
[(set SPR:$Sd, (int_arm_vcvtru SPR:$Sm))]>,
Sched<[WriteFPCVT]> {
let Inst{7} = 0; // Z bit
}
def VTOUIRH : AVConv1IsH_Encode<0b11101, 0b11, 0b1100, 0b1001,
(outs SPR:$Sd), (ins SPR:$Sm),
IIC_fpCVTHI, "vcvtr", ".u32.f16\t$Sd, $Sm",
[]>,
Sched<[WriteFPCVT]> {
let Inst{7} = 0; // Z bit
let isUnpredicable = 1;
}
}
// v8.3-a Javascript Convert to Signed fixed-point
def VJCVT : AVConv1IsD_Encode<0b11101, 0b11, 0b1001, 0b1011,
(outs SPR:$Sd), (ins DPR:$Dm),
IIC_fpCVTDI, "vjcvt", ".s32.f64\t$Sd, $Dm",
[]>,
Requires<[HasFPARMv8, HasV8_3a]> {
let Inst{7} = 1; // Z bit
}
// Convert between floating-point and fixed-point
// Data type for fixed-point naming convention:
// S16 (U=0, sx=0) -> SH
// U16 (U=1, sx=0) -> UH
// S32 (U=0, sx=1) -> SL
// U32 (U=1, sx=1) -> UL
let Constraints = "$a = $dst" in {
// FP to Fixed-Point:
// Single Precision register
class AVConv1XInsS_Encode<bits<5> op1, bits<2> op2, bits<4> op3, bits<4> op4,
bit op5, dag oops, dag iops, InstrItinClass itin,
string opc, string asm, list<dag> pattern>
: AVConv1XI<op1, op2, op3, op4, op5, oops, iops, itin, opc, asm, pattern> {
bits<5> dst;
// if dp_operation then UInt(D:Vd) else UInt(Vd:D);
let Inst{22} = dst{0};
let Inst{15-12} = dst{4-1};
let hasSideEffects = 0;
}
// Double Precision register
class AVConv1XInsD_Encode<bits<5> op1, bits<2> op2, bits<4> op3, bits<4> op4,
bit op5, dag oops, dag iops, InstrItinClass itin,
string opc, string asm, list<dag> pattern>
: AVConv1XI<op1, op2, op3, op4, op5, oops, iops, itin, opc, asm, pattern> {
bits<5> dst;
// if dp_operation then UInt(D:Vd) else UInt(Vd:D);
let Inst{22} = dst{4};
let Inst{15-12} = dst{3-0};
let hasSideEffects = 0;
let Predicates = [HasVFP2, HasDPVFP];
}
let isUnpredicable = 1 in {
def VTOSHH : AVConv1XInsS_Encode<0b11101, 0b11, 0b1110, 0b1001, 0,
(outs SPR:$dst), (ins SPR:$a, fbits16:$fbits),
IIC_fpCVTHI, "vcvt", ".s16.f16\t$dst, $a, $fbits", []>,
Requires<[HasFullFP16]>,
Sched<[WriteFPCVT]>;
def VTOUHH : AVConv1XInsS_Encode<0b11101, 0b11, 0b1111, 0b1001, 0,
(outs SPR:$dst), (ins SPR:$a, fbits16:$fbits),
IIC_fpCVTHI, "vcvt", ".u16.f16\t$dst, $a, $fbits", []>,
Requires<[HasFullFP16]>,
Sched<[WriteFPCVT]>;
def VTOSLH : AVConv1XInsS_Encode<0b11101, 0b11, 0b1110, 0b1001, 1,
(outs SPR:$dst), (ins SPR:$a, fbits32:$fbits),
IIC_fpCVTHI, "vcvt", ".s32.f16\t$dst, $a, $fbits", []>,
Requires<[HasFullFP16]>,
Sched<[WriteFPCVT]>;
def VTOULH : AVConv1XInsS_Encode<0b11101, 0b11, 0b1111, 0b1001, 1,
(outs SPR:$dst), (ins SPR:$a, fbits32:$fbits),
IIC_fpCVTHI, "vcvt", ".u32.f16\t$dst, $a, $fbits", []>,
Requires<[HasFullFP16]>,
Sched<[WriteFPCVT]>;
} // End of 'let isUnpredicable = 1 in'
def VTOSHS : AVConv1XInsS_Encode<0b11101, 0b11, 0b1110, 0b1010, 0,
(outs SPR:$dst), (ins SPR:$a, fbits16:$fbits),
IIC_fpCVTSI, "vcvt", ".s16.f32\t$dst, $a, $fbits", []>,
Sched<[WriteFPCVT]> {
// Some single precision VFP instructions may be executed on both NEON and
// VFP pipelines on A8.
let D = VFPNeonA8Domain;
}
def VTOUHS : AVConv1XInsS_Encode<0b11101, 0b11, 0b1111, 0b1010, 0,
(outs SPR:$dst), (ins SPR:$a, fbits16:$fbits),
IIC_fpCVTSI, "vcvt", ".u16.f32\t$dst, $a, $fbits", []>,
Sched<[WriteFPCVT]> {
// Some single precision VFP instructions may be executed on both NEON and
// VFP pipelines on A8.
let D = VFPNeonA8Domain;
}
def VTOSLS : AVConv1XInsS_Encode<0b11101, 0b11, 0b1110, 0b1010, 1,
(outs SPR:$dst), (ins SPR:$a, fbits32:$fbits),
IIC_fpCVTSI, "vcvt", ".s32.f32\t$dst, $a, $fbits", []>,
Sched<[WriteFPCVT]> {
// Some single precision VFP instructions may be executed on both NEON and
// VFP pipelines on A8.
let D = VFPNeonA8Domain;
}
def VTOULS : AVConv1XInsS_Encode<0b11101, 0b11, 0b1111, 0b1010, 1,
(outs SPR:$dst), (ins SPR:$a, fbits32:$fbits),
IIC_fpCVTSI, "vcvt", ".u32.f32\t$dst, $a, $fbits", []>,
Sched<[WriteFPCVT]> {
// Some single precision VFP instructions may be executed on both NEON and
// VFP pipelines on A8.
let D = VFPNeonA8Domain;
}
def VTOSHD : AVConv1XInsD_Encode<0b11101, 0b11, 0b1110, 0b1011, 0,
(outs DPR:$dst), (ins DPR:$a, fbits16:$fbits),
IIC_fpCVTDI, "vcvt", ".s16.f64\t$dst, $a, $fbits", []>,
Sched<[WriteFPCVT]>;
def VTOUHD : AVConv1XInsD_Encode<0b11101, 0b11, 0b1111, 0b1011, 0,
(outs DPR:$dst), (ins DPR:$a, fbits16:$fbits),
IIC_fpCVTDI, "vcvt", ".u16.f64\t$dst, $a, $fbits", []>,
Sched<[WriteFPCVT]>;
def VTOSLD : AVConv1XInsD_Encode<0b11101, 0b11, 0b1110, 0b1011, 1,
(outs DPR:$dst), (ins DPR:$a, fbits32:$fbits),
IIC_fpCVTDI, "vcvt", ".s32.f64\t$dst, $a, $fbits", []>,
Sched<[WriteFPCVT]>;
def VTOULD : AVConv1XInsD_Encode<0b11101, 0b11, 0b1111, 0b1011, 1,
(outs DPR:$dst), (ins DPR:$a, fbits32:$fbits),
IIC_fpCVTDI, "vcvt", ".u32.f64\t$dst, $a, $fbits", []>,
Sched<[WriteFPCVT]>;
// Fixed-Point to FP:
let isUnpredicable = 1 in {
def VSHTOH : AVConv1XInsS_Encode<0b11101, 0b11, 0b1010, 0b1001, 0,
(outs SPR:$dst), (ins SPR:$a, fbits16:$fbits),
IIC_fpCVTIH, "vcvt", ".f16.s16\t$dst, $a, $fbits", []>,
Requires<[HasFullFP16]>,
Sched<[WriteFPCVT]>;
def VUHTOH : AVConv1XInsS_Encode<0b11101, 0b11, 0b1011, 0b1001, 0,
(outs SPR:$dst), (ins SPR:$a, fbits16:$fbits),
IIC_fpCVTIH, "vcvt", ".f16.u16\t$dst, $a, $fbits", []>,
Requires<[HasFullFP16]>,
Sched<[WriteFPCVT]>;
def VSLTOH : AVConv1XInsS_Encode<0b11101, 0b11, 0b1010, 0b1001, 1,
(outs SPR:$dst), (ins SPR:$a, fbits32:$fbits),
IIC_fpCVTIH, "vcvt", ".f16.s32\t$dst, $a, $fbits", []>,
Requires<[HasFullFP16]>,
Sched<[WriteFPCVT]>;
def VULTOH : AVConv1XInsS_Encode<0b11101, 0b11, 0b1011, 0b1001, 1,
(outs SPR:$dst), (ins SPR:$a, fbits32:$fbits),
IIC_fpCVTIH, "vcvt", ".f16.u32\t$dst, $a, $fbits", []>,
Requires<[HasFullFP16]>,
Sched<[WriteFPCVT]>;
} // End of 'let isUnpredicable = 1 in'
def VSHTOS : AVConv1XInsS_Encode<0b11101, 0b11, 0b1010, 0b1010, 0,
(outs SPR:$dst), (ins SPR:$a, fbits16:$fbits),
IIC_fpCVTIS, "vcvt", ".f32.s16\t$dst, $a, $fbits", []>,
Sched<[WriteFPCVT]> {
// Some single precision VFP instructions may be executed on both NEON and
// VFP pipelines on A8.
let D = VFPNeonA8Domain;
}
def VUHTOS : AVConv1XInsS_Encode<0b11101, 0b11, 0b1011, 0b1010, 0,
(outs SPR:$dst), (ins SPR:$a, fbits16:$fbits),
IIC_fpCVTIS, "vcvt", ".f32.u16\t$dst, $a, $fbits", []>,
Sched<[WriteFPCVT]> {
// Some single precision VFP instructions may be executed on both NEON and
// VFP pipelines on A8.
let D = VFPNeonA8Domain;
}
def VSLTOS : AVConv1XInsS_Encode<0b11101, 0b11, 0b1010, 0b1010, 1,
(outs SPR:$dst), (ins SPR:$a, fbits32:$fbits),
IIC_fpCVTIS, "vcvt", ".f32.s32\t$dst, $a, $fbits", []>,
Sched<[WriteFPCVT]> {
// Some single precision VFP instructions may be executed on both NEON and
// VFP pipelines on A8.
let D = VFPNeonA8Domain;
}
def VULTOS : AVConv1XInsS_Encode<0b11101, 0b11, 0b1011, 0b1010, 1,
(outs SPR:$dst), (ins SPR:$a, fbits32:$fbits),
IIC_fpCVTIS, "vcvt", ".f32.u32\t$dst, $a, $fbits", []>,
Sched<[WriteFPCVT]> {
// Some single precision VFP instructions may be executed on both NEON and
// VFP pipelines on A8.
let D = VFPNeonA8Domain;
}
def VSHTOD : AVConv1XInsD_Encode<0b11101, 0b11, 0b1010, 0b1011, 0,
(outs DPR:$dst), (ins DPR:$a, fbits16:$fbits),
IIC_fpCVTID, "vcvt", ".f64.s16\t$dst, $a, $fbits", []>,
Sched<[WriteFPCVT]>;
def VUHTOD : AVConv1XInsD_Encode<0b11101, 0b11, 0b1011, 0b1011, 0,
(outs DPR:$dst), (ins DPR:$a, fbits16:$fbits),
IIC_fpCVTID, "vcvt", ".f64.u16\t$dst, $a, $fbits", []>,
Sched<[WriteFPCVT]>;
def VSLTOD : AVConv1XInsD_Encode<0b11101, 0b11, 0b1010, 0b1011, 1,
(outs DPR:$dst), (ins DPR:$a, fbits32:$fbits),
IIC_fpCVTID, "vcvt", ".f64.s32\t$dst, $a, $fbits", []>,
Sched<[WriteFPCVT]>;
def VULTOD : AVConv1XInsD_Encode<0b11101, 0b11, 0b1011, 0b1011, 1,
(outs DPR:$dst), (ins DPR:$a, fbits32:$fbits),
IIC_fpCVTID, "vcvt", ".f64.u32\t$dst, $a, $fbits", []>,
Sched<[WriteFPCVT]>;
} // End of 'let Constraints = "$a = $dst" in'
// BFloat16 - Single precision, unary, predicated
class BF16_VCVT<string opc, bits<2> op7_6>
: VFPAI<(outs SPR:$Sd), (ins SPR:$dst, SPR:$Sm),
VFPUnaryFrm, NoItinerary,
opc, ".bf16.f32\t$Sd, $Sm", []>,
RegConstraint<"$dst = $Sd">,
Requires<[HasBF16]>,
Sched<[]> {
bits<5> Sd;
bits<5> Sm;
// Encode instruction operands.
let Inst{3-0} = Sm{4-1};
let Inst{5} = Sm{0};
let Inst{15-12} = Sd{4-1};
let Inst{22} = Sd{0};
let Inst{27-23} = 0b11101; // opcode1
let Inst{21-20} = 0b11; // opcode2
let Inst{19-16} = 0b0011; // opcode3
let Inst{11-8} = 0b1001;
let Inst{7-6} = op7_6;
let Inst{4} = 0;
let DecoderNamespace = "VFPV8";
let hasSideEffects = 0;
}
def BF16_VCVTB : BF16_VCVT<"vcvtb", 0b01>;
def BF16_VCVTT : BF16_VCVT<"vcvtt", 0b11>;
//===----------------------------------------------------------------------===//
// FP Multiply-Accumulate Operations.
//
def VMLAD : ADbI<0b11100, 0b00, 0, 0,
(outs DPR:$Dd), (ins DPR:$Ddin, DPR:$Dn, DPR:$Dm),
IIC_fpMAC64, "vmla", ".f64\t$Dd, $Dn, $Dm",
[(set DPR:$Dd, (fadd_mlx (fmul_su DPR:$Dn, DPR:$Dm),
(f64 DPR:$Ddin)))]>,
RegConstraint<"$Ddin = $Dd">,
Requires<[HasVFP2,HasDPVFP,UseFPVMLx]>,
Sched<[WriteFPMAC64, ReadFPMAC, ReadFPMUL, ReadFPMUL]>;
def VMLAS : ASbIn<0b11100, 0b00, 0, 0,
(outs SPR:$Sd), (ins SPR:$Sdin, SPR:$Sn, SPR:$Sm),
IIC_fpMAC32, "vmla", ".f32\t$Sd, $Sn, $Sm",
[(set SPR:$Sd, (fadd_mlx (fmul_su SPR:$Sn, SPR:$Sm),
SPR:$Sdin))]>,
RegConstraint<"$Sdin = $Sd">,
Requires<[HasVFP2,DontUseNEONForFP,UseFPVMLx]>,
Sched<[WriteFPMAC32, ReadFPMAC, ReadFPMUL, ReadFPMUL]> {
// Some single precision VFP instructions may be executed on both NEON and
// VFP pipelines on A8.
let D = VFPNeonA8Domain;
}
def VMLAH : AHbI<0b11100, 0b00, 0, 0,
(outs HPR:$Sd), (ins HPR:$Sdin, HPR:$Sn, HPR:$Sm),
IIC_fpMAC16, "vmla", ".f16\t$Sd, $Sn, $Sm",
[(set (f16 HPR:$Sd), (fadd_mlx (fmul_su (f16 HPR:$Sn), (f16 HPR:$Sm)),
(f16 HPR:$Sdin)))]>,
RegConstraint<"$Sdin = $Sd">,
Requires<[HasFullFP16,UseFPVMLx]>;
def : Pat<(fadd_mlx DPR:$dstin, (fmul_su DPR:$a, (f64 DPR:$b))),
(VMLAD DPR:$dstin, DPR:$a, DPR:$b)>,
Requires<[HasVFP2,HasDPVFP,UseFPVMLx]>;
def : Pat<(fadd_mlx SPR:$dstin, (fmul_su SPR:$a, SPR:$b)),
(VMLAS SPR:$dstin, SPR:$a, SPR:$b)>,
Requires<[HasVFP2,DontUseNEONForFP, UseFPVMLx]>;
def : Pat<(fadd_mlx HPR:$dstin, (fmul_su (f16 HPR:$a), HPR:$b)),
(VMLAH HPR:$dstin, (f16 HPR:$a), HPR:$b)>,
Requires<[HasFullFP16,DontUseNEONForFP, UseFPVMLx]>;
def VMLSD : ADbI<0b11100, 0b00, 1, 0,
(outs DPR:$Dd), (ins DPR:$Ddin, DPR:$Dn, DPR:$Dm),
IIC_fpMAC64, "vmls", ".f64\t$Dd, $Dn, $Dm",
[(set DPR:$Dd, (fadd_mlx (fneg (fmul_su DPR:$Dn,DPR:$Dm)),
(f64 DPR:$Ddin)))]>,
RegConstraint<"$Ddin = $Dd">,
Requires<[HasVFP2,HasDPVFP,UseFPVMLx]>,
Sched<[WriteFPMAC64, ReadFPMAC, ReadFPMUL, ReadFPMUL]>;
def VMLSS : ASbIn<0b11100, 0b00, 1, 0,
(outs SPR:$Sd), (ins SPR:$Sdin, SPR:$Sn, SPR:$Sm),
IIC_fpMAC32, "vmls", ".f32\t$Sd, $Sn, $Sm",
[(set SPR:$Sd, (fadd_mlx (fneg (fmul_su SPR:$Sn, SPR:$Sm)),
SPR:$Sdin))]>,
RegConstraint<"$Sdin = $Sd">,
Requires<[HasVFP2,DontUseNEONForFP,UseFPVMLx]>,
Sched<[WriteFPMAC32, ReadFPMAC, ReadFPMUL, ReadFPMUL]> {
// Some single precision VFP instructions may be executed on both NEON and
// VFP pipelines on A8.
let D = VFPNeonA8Domain;
}
def VMLSH : AHbI<0b11100, 0b00, 1, 0,
(outs HPR:$Sd), (ins HPR:$Sdin, HPR:$Sn, HPR:$Sm),
IIC_fpMAC16, "vmls", ".f16\t$Sd, $Sn, $Sm",
[(set (f16 HPR:$Sd), (fadd_mlx (fneg (fmul_su (f16 HPR:$Sn), (f16 HPR:$Sm))),
(f16 HPR:$Sdin)))]>,
RegConstraint<"$Sdin = $Sd">,
Requires<[HasFullFP16,UseFPVMLx]>;
def : Pat<(fsub_mlx DPR:$dstin, (fmul_su DPR:$a, (f64 DPR:$b))),
(VMLSD DPR:$dstin, DPR:$a, DPR:$b)>,
Requires<[HasVFP2,HasDPVFP,UseFPVMLx]>;
def : Pat<(fsub_mlx SPR:$dstin, (fmul_su SPR:$a, SPR:$b)),
(VMLSS SPR:$dstin, SPR:$a, SPR:$b)>,
Requires<[HasVFP2,DontUseNEONForFP,UseFPVMLx]>;
def : Pat<(fsub_mlx HPR:$dstin, (fmul_su (f16 HPR:$a), HPR:$b)),
(VMLSH HPR:$dstin, (f16 HPR:$a), HPR:$b)>,
Requires<[HasFullFP16,DontUseNEONForFP,UseFPVMLx]>;
def VNMLAD : ADbI<0b11100, 0b01, 1, 0,
(outs DPR:$Dd), (ins DPR:$Ddin, DPR:$Dn, DPR:$Dm),
IIC_fpMAC64, "vnmla", ".f64\t$Dd, $Dn, $Dm",
[(set DPR:$Dd,(fsub_mlx (fneg (fmul_su DPR:$Dn,DPR:$Dm)),
(f64 DPR:$Ddin)))]>,
RegConstraint<"$Ddin = $Dd">,
Requires<[HasVFP2,HasDPVFP,UseFPVMLx]>,
Sched<[WriteFPMAC64, ReadFPMAC, ReadFPMUL, ReadFPMUL]>;
def VNMLAS : ASbI<0b11100, 0b01, 1, 0,
(outs SPR:$Sd), (ins SPR:$Sdin, SPR:$Sn, SPR:$Sm),
IIC_fpMAC32, "vnmla", ".f32\t$Sd, $Sn, $Sm",
[(set SPR:$Sd, (fsub_mlx (fneg (fmul_su SPR:$Sn, SPR:$Sm)),
SPR:$Sdin))]>,
RegConstraint<"$Sdin = $Sd">,
Requires<[HasVFP2,DontUseNEONForFP,UseFPVMLx]>,
Sched<[WriteFPMAC32, ReadFPMAC, ReadFPMUL, ReadFPMUL]> {
// Some single precision VFP instructions may be executed on both NEON and
// VFP pipelines on A8.
let D = VFPNeonA8Domain;
}
def VNMLAH : AHbI<0b11100, 0b01, 1, 0,
(outs HPR:$Sd), (ins HPR:$Sdin, HPR:$Sn, HPR:$Sm),
IIC_fpMAC16, "vnmla", ".f16\t$Sd, $Sn, $Sm",
[(set (f16 HPR:$Sd), (fsub_mlx (fneg (fmul_su (f16 HPR:$Sn), (f16 HPR:$Sm))),
(f16 HPR:$Sdin)))]>,
RegConstraint<"$Sdin = $Sd">,
Requires<[HasFullFP16,UseFPVMLx]>;
// (-(a * b) - dst) -> -(dst + (a * b))
def : Pat<(fsub_mlx (fneg (fmul_su DPR:$a, (f64 DPR:$b))), DPR:$dstin),
(VNMLAD DPR:$dstin, DPR:$a, DPR:$b)>,
Requires<[HasVFP2,HasDPVFP,UseFPVMLx]>;
def : Pat<(fsub_mlx (fneg (fmul_su SPR:$a, SPR:$b)), SPR:$dstin),
(VNMLAS SPR:$dstin, SPR:$a, SPR:$b)>,
Requires<[HasVFP2,DontUseNEONForFP,UseFPVMLx]>;
def : Pat<(fsub_mlx (fneg (fmul_su (f16 HPR:$a), HPR:$b)), HPR:$dstin),
(VNMLAH HPR:$dstin, (f16 HPR:$a), HPR:$b)>,
Requires<[HasFullFP16,DontUseNEONForFP,UseFPVMLx]>;
// (-dst - (a * b)) -> -(dst + (a * b))
def : Pat<(fsub_mlx (fneg DPR:$dstin), (fmul_su DPR:$a, (f64 DPR:$b))),
(VNMLAD DPR:$dstin, DPR:$a, DPR:$b)>,
Requires<[HasVFP2,HasDPVFP,UseFPVMLx]>;
def : Pat<(fsub_mlx (fneg SPR:$dstin), (fmul_su SPR:$a, SPR:$b)),
(VNMLAS SPR:$dstin, SPR:$a, SPR:$b)>,
Requires<[HasVFP2,DontUseNEONForFP,UseFPVMLx]>;
def : Pat<(fsub_mlx (fneg HPR:$dstin), (fmul_su (f16 HPR:$a), HPR:$b)),
(VNMLAH HPR:$dstin, (f16 HPR:$a), HPR:$b)>,
Requires<[HasFullFP16,DontUseNEONForFP,UseFPVMLx]>;
def VNMLSD : ADbI<0b11100, 0b01, 0, 0,
(outs DPR:$Dd), (ins DPR:$Ddin, DPR:$Dn, DPR:$Dm),
IIC_fpMAC64, "vnmls", ".f64\t$Dd, $Dn, $Dm",
[(set DPR:$Dd, (fsub_mlx (fmul_su DPR:$Dn, DPR:$Dm),
(f64 DPR:$Ddin)))]>,
RegConstraint<"$Ddin = $Dd">,
Requires<[HasVFP2,HasDPVFP,UseFPVMLx]>,
Sched<[WriteFPMAC64, ReadFPMAC, ReadFPMUL, ReadFPMUL]>;
def VNMLSS : ASbI<0b11100, 0b01, 0, 0,
(outs SPR:$Sd), (ins SPR:$Sdin, SPR:$Sn, SPR:$Sm),
IIC_fpMAC32, "vnmls", ".f32\t$Sd, $Sn, $Sm",
[(set SPR:$Sd, (fsub_mlx (fmul_su SPR:$Sn, SPR:$Sm), SPR:$Sdin))]>,
RegConstraint<"$Sdin = $Sd">,
Requires<[HasVFP2,DontUseNEONForFP,UseFPVMLx]>,
Sched<[WriteFPMAC32, ReadFPMAC, ReadFPMUL, ReadFPMUL]> {
// Some single precision VFP instructions may be executed on both NEON and
// VFP pipelines on A8.
let D = VFPNeonA8Domain;
}
def VNMLSH : AHbI<0b11100, 0b01, 0, 0,
(outs HPR:$Sd), (ins HPR:$Sdin, HPR:$Sn, HPR:$Sm),
IIC_fpMAC16, "vnmls", ".f16\t$Sd, $Sn, $Sm",
[(set (f16 HPR:$Sd), (fsub_mlx (fmul_su (f16 HPR:$Sn), (f16 HPR:$Sm)), (f16 HPR:$Sdin)))]>,
RegConstraint<"$Sdin = $Sd">,
Requires<[HasFullFP16,UseFPVMLx]>;
def : Pat<(fsub_mlx (fmul_su DPR:$a, (f64 DPR:$b)), DPR:$dstin),
(VNMLSD DPR:$dstin, DPR:$a, DPR:$b)>,
Requires<[HasVFP2,HasDPVFP,UseFPVMLx]>;
def : Pat<(fsub_mlx (fmul_su SPR:$a, SPR:$b), SPR:$dstin),
(VNMLSS SPR:$dstin, SPR:$a, SPR:$b)>,
Requires<[HasVFP2,DontUseNEONForFP,UseFPVMLx]>;
def : Pat<(fsub_mlx (fmul_su (f16 HPR:$a), HPR:$b), HPR:$dstin),
(VNMLSH HPR:$dstin, (f16 HPR:$a), HPR:$b)>,
Requires<[HasFullFP16,DontUseNEONForFP,UseFPVMLx]>;
//===----------------------------------------------------------------------===//
// Fused FP Multiply-Accumulate Operations.
//
def VFMAD : ADbI<0b11101, 0b10, 0, 0,
(outs DPR:$Dd), (ins DPR:$Ddin, DPR:$Dn, DPR:$Dm),
IIC_fpFMAC64, "vfma", ".f64\t$Dd, $Dn, $Dm",
[(set DPR:$Dd, (fadd_mlx (fmul_su DPR:$Dn, DPR:$Dm),
(f64 DPR:$Ddin)))]>,
RegConstraint<"$Ddin = $Dd">,
Requires<[HasVFP4,HasDPVFP,UseFusedMAC]>,
Sched<[WriteFPMAC64, ReadFPMAC, ReadFPMUL, ReadFPMUL]>;
def VFMAS : ASbIn<0b11101, 0b10, 0, 0,
(outs SPR:$Sd), (ins SPR:$Sdin, SPR:$Sn, SPR:$Sm),
IIC_fpFMAC32, "vfma", ".f32\t$Sd, $Sn, $Sm",
[(set SPR:$Sd, (fadd_mlx (fmul_su SPR:$Sn, SPR:$Sm),
SPR:$Sdin))]>,
RegConstraint<"$Sdin = $Sd">,
Requires<[HasVFP4,DontUseNEONForFP,UseFusedMAC]>,
Sched<[WriteFPMAC32, ReadFPMAC, ReadFPMUL, ReadFPMUL]> {
// Some single precision VFP instructions may be executed on both NEON and
// VFP pipelines.
}
def VFMAH : AHbI<0b11101, 0b10, 0, 0,
(outs HPR:$Sd), (ins HPR:$Sdin, HPR:$Sn, HPR:$Sm),
IIC_fpFMAC16, "vfma", ".f16\t$Sd, $Sn, $Sm",
[(set (f16 HPR:$Sd), (fadd_mlx (fmul_su (f16 HPR:$Sn), (f16 HPR:$Sm)),
(f16 HPR:$Sdin)))]>,
RegConstraint<"$Sdin = $Sd">,
Requires<[HasFullFP16,UseFusedMAC]>,
Sched<[WriteFPMAC32, ReadFPMAC, ReadFPMUL, ReadFPMUL]>;
def : Pat<(fadd_mlx DPR:$dstin, (fmul_su DPR:$a, (f64 DPR:$b))),
(VFMAD DPR:$dstin, DPR:$a, DPR:$b)>,
Requires<[HasVFP4,HasDPVFP,UseFusedMAC]>;
def : Pat<(fadd_mlx SPR:$dstin, (fmul_su SPR:$a, SPR:$b)),
(VFMAS SPR:$dstin, SPR:$a, SPR:$b)>,
Requires<[HasVFP4,DontUseNEONForFP,UseFusedMAC]>;
def : Pat<(fadd_mlx HPR:$dstin, (fmul_su (f16 HPR:$a), HPR:$b)),
(VFMAH HPR:$dstin, (f16 HPR:$a), HPR:$b)>,
Requires<[HasFullFP16,DontUseNEONForFP,UseFusedMAC]>;
// Match @llvm.fma.* intrinsics
// (fma x, y, z) -> (vfms z, x, y)
def : Pat<(f64 (fma DPR:$Dn, DPR:$Dm, DPR:$Ddin)),
(VFMAD DPR:$Ddin, DPR:$Dn, DPR:$Dm)>,
Requires<[HasVFP4,HasDPVFP]>;
def : Pat<(f32 (fma SPR:$Sn, SPR:$Sm, SPR:$Sdin)),
(VFMAS SPR:$Sdin, SPR:$Sn, SPR:$Sm)>,
Requires<[HasVFP4]>;
def : Pat<(f16 (fma HPR:$Sn, HPR:$Sm, (f16 HPR:$Sdin))),
(VFMAH (f16 HPR:$Sdin), (f16 HPR:$Sn), (f16 HPR:$Sm))>,
Requires<[HasFullFP16]>;
def VFMSD : ADbI<0b11101, 0b10, 1, 0,
(outs DPR:$Dd), (ins DPR:$Ddin, DPR:$Dn, DPR:$Dm),
IIC_fpFMAC64, "vfms", ".f64\t$Dd, $Dn, $Dm",
[(set DPR:$Dd, (fadd_mlx (fneg (fmul_su DPR:$Dn,DPR:$Dm)),
(f64 DPR:$Ddin)))]>,
RegConstraint<"$Ddin = $Dd">,
Requires<[HasVFP4,HasDPVFP,UseFusedMAC]>,
Sched<[WriteFPMAC64, ReadFPMAC, ReadFPMUL, ReadFPMUL]>;
def VFMSS : ASbIn<0b11101, 0b10, 1, 0,
(outs SPR:$Sd), (ins SPR:$Sdin, SPR:$Sn, SPR:$Sm),
IIC_fpFMAC32, "vfms", ".f32\t$Sd, $Sn, $Sm",
[(set SPR:$Sd, (fadd_mlx (fneg (fmul_su SPR:$Sn, SPR:$Sm)),
SPR:$Sdin))]>,
RegConstraint<"$Sdin = $Sd">,
Requires<[HasVFP4,DontUseNEONForFP,UseFusedMAC]>,
Sched<[WriteFPMAC32, ReadFPMAC, ReadFPMUL, ReadFPMUL]> {
// Some single precision VFP instructions may be executed on both NEON and
// VFP pipelines.
}
def VFMSH : AHbI<0b11101, 0b10, 1, 0,
(outs HPR:$Sd), (ins HPR:$Sdin, HPR:$Sn, HPR:$Sm),
IIC_fpFMAC16, "vfms", ".f16\t$Sd, $Sn, $Sm",
[(set (f16 HPR:$Sd), (fadd_mlx (fneg (fmul_su (f16 HPR:$Sn), (f16 HPR:$Sm))),
(f16 HPR:$Sdin)))]>,
RegConstraint<"$Sdin = $Sd">,
Requires<[HasFullFP16,UseFusedMAC]>,
Sched<[WriteFPMAC32, ReadFPMAC, ReadFPMUL, ReadFPMUL]>;
def : Pat<(fsub_mlx DPR:$dstin, (fmul_su DPR:$a, (f64 DPR:$b))),
(VFMSD DPR:$dstin, DPR:$a, DPR:$b)>,
Requires<[HasVFP4,HasDPVFP,UseFusedMAC]>;
def : Pat<(fsub_mlx SPR:$dstin, (fmul_su SPR:$a, SPR:$b)),
(VFMSS SPR:$dstin, SPR:$a, SPR:$b)>,
Requires<[HasVFP4,DontUseNEONForFP,UseFusedMAC]>;
def : Pat<(fsub_mlx HPR:$dstin, (fmul_su (f16 HPR:$a), HPR:$b)),
(VFMSH HPR:$dstin, (f16 HPR:$a), HPR:$b)>,
Requires<[HasFullFP16,DontUseNEONForFP,UseFusedMAC]>;
// Match @llvm.fma.* intrinsics
// (fma (fneg x), y, z) -> (vfms z, x, y)
def : Pat<(f64 (fma (fneg DPR:$Dn), DPR:$Dm, DPR:$Ddin)),
(VFMSD DPR:$Ddin, DPR:$Dn, DPR:$Dm)>,
Requires<[HasVFP4,HasDPVFP]>;
def : Pat<(f32 (fma (fneg SPR:$Sn), SPR:$Sm, SPR:$Sdin)),
(VFMSS SPR:$Sdin, SPR:$Sn, SPR:$Sm)>,
Requires<[HasVFP4]>;
def : Pat<(f16 (fma (fneg (f16 HPR:$Sn)), (f16 HPR:$Sm), (f16 HPR:$Sdin))),
(VFMSH (f16 HPR:$Sdin), (f16 HPR:$Sn), (f16 HPR:$Sm))>,
Requires<[HasFullFP16]>;
// (fma x, (fneg y), z) -> (vfms z, x, y)
def : Pat<(f64 (fma DPR:$Dn, (fneg DPR:$Dm), DPR:$Ddin)),
(VFMSD DPR:$Ddin, DPR:$Dn, DPR:$Dm)>,
Requires<[HasVFP4,HasDPVFP]>;
def : Pat<(f32 (fma SPR:$Sn, (fneg SPR:$Sm), SPR:$Sdin)),
(VFMSS SPR:$Sdin, SPR:$Sn, SPR:$Sm)>,
Requires<[HasVFP4]>;
def : Pat<(f16 (fma (f16 HPR:$Sn), (fneg (f16 HPR:$Sm)), (f16 HPR:$Sdin))),
(VFMSH (f16 HPR:$Sdin), (f16 HPR:$Sn), (f16 HPR:$Sm))>,
Requires<[HasFullFP16]>;
def VFNMAD : ADbI<0b11101, 0b01, 1, 0,
(outs DPR:$Dd), (ins DPR:$Ddin, DPR:$Dn, DPR:$Dm),
IIC_fpFMAC64, "vfnma", ".f64\t$Dd, $Dn, $Dm",
[(set DPR:$Dd,(fsub_mlx (fneg (fmul_su DPR:$Dn,DPR:$Dm)),
(f64 DPR:$Ddin)))]>,
RegConstraint<"$Ddin = $Dd">,
Requires<[HasVFP4,HasDPVFP,UseFusedMAC]>,
Sched<[WriteFPMAC64, ReadFPMAC, ReadFPMUL, ReadFPMUL]>;
def VFNMAS : ASbI<0b11101, 0b01, 1, 0,
(outs SPR:$Sd), (ins SPR:$Sdin, SPR:$Sn, SPR:$Sm),
IIC_fpFMAC32, "vfnma", ".f32\t$Sd, $Sn, $Sm",
[(set SPR:$Sd, (fsub_mlx (fneg (fmul_su SPR:$Sn, SPR:$Sm)),
SPR:$Sdin))]>,
RegConstraint<"$Sdin = $Sd">,
Requires<[HasVFP4,DontUseNEONForFP,UseFusedMAC]>,
Sched<[WriteFPMAC32, ReadFPMAC, ReadFPMUL, ReadFPMUL]> {
// Some single precision VFP instructions may be executed on both NEON and
// VFP pipelines.
}
def VFNMAH : AHbI<0b11101, 0b01, 1, 0,
(outs HPR:$Sd), (ins HPR:$Sdin, HPR:$Sn, HPR:$Sm),
IIC_fpFMAC16, "vfnma", ".f16\t$Sd, $Sn, $Sm",
[(set (f16 HPR:$Sd), (fsub_mlx (fneg (fmul_su (f16 HPR:$Sn), (f16 HPR:$Sm))),
(f16 HPR:$Sdin)))]>,
RegConstraint<"$Sdin = $Sd">,
Requires<[HasFullFP16,UseFusedMAC]>,
Sched<[WriteFPMAC32, ReadFPMAC, ReadFPMUL, ReadFPMUL]>;
def : Pat<(fsub_mlx (fneg (fmul_su DPR:$a, (f64 DPR:$b))), DPR:$dstin),
(VFNMAD DPR:$dstin, DPR:$a, DPR:$b)>,
Requires<[HasVFP4,HasDPVFP,UseFusedMAC]>;
def : Pat<(fsub_mlx (fneg (fmul_su SPR:$a, SPR:$b)), SPR:$dstin),
(VFNMAS SPR:$dstin, SPR:$a, SPR:$b)>,
Requires<[HasVFP4,DontUseNEONForFP,UseFusedMAC]>;
// Match @llvm.fma.* intrinsics
// (fneg (fma x, y, z)) -> (vfnma z, x, y)
def : Pat<(fneg (fma (f64 DPR:$Dn), (f64 DPR:$Dm), (f64 DPR:$Ddin))),
(VFNMAD DPR:$Ddin, DPR:$Dn, DPR:$Dm)>,
Requires<[HasVFP4,HasDPVFP]>;
def : Pat<(fneg (fma (f32 SPR:$Sn), (f32 SPR:$Sm), (f32 SPR:$Sdin))),
(VFNMAS SPR:$Sdin, SPR:$Sn, SPR:$Sm)>,
Requires<[HasVFP4]>;
def : Pat<(fneg (fma (f16 HPR:$Sn), (f16 HPR:$Sm), (f16 (f16 HPR:$Sdin)))),
(VFNMAH (f16 HPR:$Sdin), (f16 HPR:$Sn), (f16 HPR:$Sm))>,
Requires<[HasFullFP16]>;
// (fma (fneg x), y, (fneg z)) -> (vfnma z, x, y)
def : Pat<(f64 (fma (fneg DPR:$Dn), DPR:$Dm, (fneg DPR:$Ddin))),
(VFNMAD DPR:$Ddin, DPR:$Dn, DPR:$Dm)>,
Requires<[HasVFP4,HasDPVFP]>;
def : Pat<(f32 (fma (fneg SPR:$Sn), SPR:$Sm, (fneg SPR:$Sdin))),
(VFNMAS SPR:$Sdin, SPR:$Sn, SPR:$Sm)>,
Requires<[HasVFP4]>;
def : Pat<(f16 (fma (fneg (f16 HPR:$Sn)), (f16 HPR:$Sm), (fneg (f16 HPR:$Sdin)))),
(VFNMAH (f16 HPR:$Sdin), (f16 HPR:$Sn), (f16 HPR:$Sm))>,
Requires<[HasFullFP16]>;
def VFNMSD : ADbI<0b11101, 0b01, 0, 0,
(outs DPR:$Dd), (ins DPR:$Ddin, DPR:$Dn, DPR:$Dm),
IIC_fpFMAC64, "vfnms", ".f64\t$Dd, $Dn, $Dm",
[(set DPR:$Dd, (fsub_mlx (fmul_su DPR:$Dn, DPR:$Dm),
(f64 DPR:$Ddin)))]>,
RegConstraint<"$Ddin = $Dd">,
Requires<[HasVFP4,HasDPVFP,UseFusedMAC]>,
Sched<[WriteFPMAC64, ReadFPMAC, ReadFPMUL, ReadFPMUL]>;
def VFNMSS : ASbI<0b11101, 0b01, 0, 0,
(outs SPR:$Sd), (ins SPR:$Sdin, SPR:$Sn, SPR:$Sm),
IIC_fpFMAC32, "vfnms", ".f32\t$Sd, $Sn, $Sm",
[(set SPR:$Sd, (fsub_mlx (fmul_su SPR:$Sn, SPR:$Sm), SPR:$Sdin))]>,
RegConstraint<"$Sdin = $Sd">,
Requires<[HasVFP4,DontUseNEONForFP,UseFusedMAC]>,
Sched<[WriteFPMAC32, ReadFPMAC, ReadFPMUL, ReadFPMUL]> {
// Some single precision VFP instructions may be executed on both NEON and
// VFP pipelines.
}
def VFNMSH : AHbI<0b11101, 0b01, 0, 0,
(outs HPR:$Sd), (ins HPR:$Sdin, HPR:$Sn, HPR:$Sm),
IIC_fpFMAC16, "vfnms", ".f16\t$Sd, $Sn, $Sm",
[(set (f16 HPR:$Sd), (fsub_mlx (fmul_su (f16 HPR:$Sn), (f16 HPR:$Sm)), (f16 HPR:$Sdin)))]>,
RegConstraint<"$Sdin = $Sd">,
Requires<[HasFullFP16,UseFusedMAC]>,
Sched<[WriteFPMAC32, ReadFPMAC, ReadFPMUL, ReadFPMUL]>;
def : Pat<(fsub_mlx (fmul_su DPR:$a, (f64 DPR:$b)), DPR:$dstin),
(VFNMSD DPR:$dstin, DPR:$a, DPR:$b)>,
Requires<[HasVFP4,HasDPVFP,UseFusedMAC]>;
def : Pat<(fsub_mlx (fmul_su SPR:$a, SPR:$b), SPR:$dstin),
(VFNMSS SPR:$dstin, SPR:$a, SPR:$b)>,
Requires<[HasVFP4,DontUseNEONForFP,UseFusedMAC]>;
// Match @llvm.fma.* intrinsics
// (fma x, y, (fneg z)) -> (vfnms z, x, y))
def : Pat<(f64 (fma DPR:$Dn, DPR:$Dm, (fneg DPR:$Ddin))),
(VFNMSD DPR:$Ddin, DPR:$Dn, DPR:$Dm)>,
Requires<[HasVFP4,HasDPVFP]>;
def : Pat<(f32 (fma SPR:$Sn, SPR:$Sm, (fneg SPR:$Sdin))),
(VFNMSS SPR:$Sdin, SPR:$Sn, SPR:$Sm)>,
Requires<[HasVFP4]>;
def : Pat<(f16 (fma (f16 HPR:$Sn), (f16 HPR:$Sm), (fneg (f16 HPR:$Sdin)))),
(VFNMSH (f16 HPR:$Sdin), (f16 HPR:$Sn), (f16 HPR:$Sm))>,
Requires<[HasFullFP16]>;
// (fneg (fma (fneg x), y, z)) -> (vfnms z, x, y)
def : Pat<(fneg (f64 (fma (fneg DPR:$Dn), DPR:$Dm, DPR:$Ddin))),
(VFNMSD DPR:$Ddin, DPR:$Dn, DPR:$Dm)>,
Requires<[HasVFP4,HasDPVFP]>;
def : Pat<(fneg (f32 (fma (fneg SPR:$Sn), SPR:$Sm, SPR:$Sdin))),
(VFNMSS SPR:$Sdin, SPR:$Sn, SPR:$Sm)>,
Requires<[HasVFP4]>;
def : Pat<(fneg (f16 (fma (fneg (f16 HPR:$Sn)), (f16 HPR:$Sm), (f16 HPR:$Sdin)))),
(VFNMSH (f16 HPR:$Sdin), (f16 HPR:$Sn), (f16 HPR:$Sm))>,
Requires<[HasFullFP16]>;
// (fneg (fma x, (fneg y), z) -> (vfnms z, x, y)
def : Pat<(fneg (f64 (fma DPR:$Dn, (fneg DPR:$Dm), DPR:$Ddin))),
(VFNMSD DPR:$Ddin, DPR:$Dn, DPR:$Dm)>,
Requires<[HasVFP4,HasDPVFP]>;
def : Pat<(fneg (f32 (fma SPR:$Sn, (fneg SPR:$Sm), SPR:$Sdin))),
(VFNMSS SPR:$Sdin, SPR:$Sn, SPR:$Sm)>,
Requires<[HasVFP4]>;
def : Pat<(fneg (f16 (fma (f16 HPR:$Sn), (fneg (f16 HPR:$Sm)), (f16 HPR:$Sdin)))),
(VFNMSH (f16 HPR:$Sdin), (f16 HPR:$Sn), (f16 HPR:$Sm))>,
Requires<[HasFullFP16]>;
//===----------------------------------------------------------------------===//
// FP Conditional moves.
//
let hasSideEffects = 0 in {
def VMOVDcc : PseudoInst<(outs DPR:$Dd), (ins DPR:$Dn, DPR:$Dm, cmovpred:$p),
IIC_fpUNA64,
[(set (f64 DPR:$Dd),
(ARMcmov DPR:$Dn, DPR:$Dm, cmovpred:$p))]>,
RegConstraint<"$Dn = $Dd">, Requires<[HasFPRegs64]>;
def VMOVScc : PseudoInst<(outs SPR:$Sd), (ins SPR:$Sn, SPR:$Sm, cmovpred:$p),
IIC_fpUNA32,
[(set (f32 SPR:$Sd),
(ARMcmov SPR:$Sn, SPR:$Sm, cmovpred:$p))]>,
RegConstraint<"$Sn = $Sd">, Requires<[HasFPRegs]>;
def VMOVHcc : PseudoInst<(outs HPR:$Sd), (ins HPR:$Sn, HPR:$Sm, cmovpred:$p),
IIC_fpUNA16,
[(set (f16 HPR:$Sd),
(ARMcmov (f16 HPR:$Sn), (f16 HPR:$Sm), cmovpred:$p))]>,
RegConstraint<"$Sd = $Sn">, Requires<[HasFPRegs]>;
} // hasSideEffects
//===----------------------------------------------------------------------===//
// Move from VFP System Register to ARM core register.
//
class MovFromVFP<bits<4> opc19_16, dag oops, dag iops, string opc, string asm,
list<dag> pattern>:
VFPAI<oops, iops, VFPMiscFrm, IIC_fpSTAT, opc, asm, pattern> {
// Instruction operand.
bits<4> Rt;
let Inst{27-20} = 0b11101111;
let Inst{19-16} = opc19_16;
let Inst{15-12} = Rt;
let Inst{11-8} = 0b1010;
let Inst{7} = 0;
let Inst{6-5} = 0b00;
let Inst{4} = 1;
let Inst{3-0} = 0b0000;
let Unpredictable{7-5} = 0b111;
let Unpredictable{3-0} = 0b1111;
}
let DecoderMethod = "DecodeForVMRSandVMSR" in {
// APSR is the application level alias of CPSR. This FPSCR N, Z, C, V flags
// to APSR.
let Defs = [CPSR], Uses = [FPSCR_NZCV], Predicates = [HasFPRegs],
Rt = 0b1111 /* apsr_nzcv */ in
def FMSTAT : MovFromVFP<0b0001 /* fpscr */, (outs), (ins),
"vmrs", "\tAPSR_nzcv, fpscr", [(arm_fmstat)]>;
// Application level FPSCR -> GPR
let hasSideEffects = 1, Uses = [FPSCR], Predicates = [HasFPRegs] in
def VMRS : MovFromVFP<0b0001 /* fpscr */, (outs GPRnopc:$Rt), (ins),
"vmrs", "\t$Rt, fpscr",
[(set GPRnopc:$Rt, (int_arm_get_fpscr))]>;
// System level FPEXC, FPSID -> GPR
let Uses = [FPSCR] in {
def VMRS_FPEXC : MovFromVFP<0b1000 /* fpexc */, (outs GPRnopc:$Rt), (ins),
"vmrs", "\t$Rt, fpexc", []>;
def VMRS_FPSID : MovFromVFP<0b0000 /* fpsid */, (outs GPRnopc:$Rt), (ins),
"vmrs", "\t$Rt, fpsid", []>;
def VMRS_MVFR0 : MovFromVFP<0b0111 /* mvfr0 */, (outs GPRnopc:$Rt), (ins),
"vmrs", "\t$Rt, mvfr0", []>;
def VMRS_MVFR1 : MovFromVFP<0b0110 /* mvfr1 */, (outs GPRnopc:$Rt), (ins),
"vmrs", "\t$Rt, mvfr1", []>;
let Predicates = [HasFPARMv8] in {
def VMRS_MVFR2 : MovFromVFP<0b0101 /* mvfr2 */, (outs GPRnopc:$Rt), (ins),
"vmrs", "\t$Rt, mvfr2", []>;
}
def VMRS_FPINST : MovFromVFP<0b1001 /* fpinst */, (outs GPRnopc:$Rt), (ins),
"vmrs", "\t$Rt, fpinst", []>;
def VMRS_FPINST2 : MovFromVFP<0b1010 /* fpinst2 */, (outs GPRnopc:$Rt),
(ins), "vmrs", "\t$Rt, fpinst2", []>;
let Predicates = [HasV8_1MMainline, HasFPRegs] in {
// System level FPSCR_NZCVQC -> GPR
def VMRS_FPSCR_NZCVQC
: MovFromVFP<0b0010 /* fpscr_nzcvqc */,
(outs GPR:$Rt), (ins cl_FPSCR_NZCV:$fpscr_in),
"vmrs", "\t$Rt, fpscr_nzcvqc", []>;
}
}
let Predicates = [HasV8_1MMainline, Has8MSecExt] in {
// System level FPSCR -> GPR, with context saving for security extensions
def VMRS_FPCXTNS : MovFromVFP<0b1110 /* fpcxtns */, (outs GPR:$Rt), (ins),
"vmrs", "\t$Rt, fpcxtns", []>;
}
let Predicates = [HasV8_1MMainline, Has8MSecExt] in {
// System level FPSCR -> GPR, with context saving for security extensions
def VMRS_FPCXTS : MovFromVFP<0b1111 /* fpcxts */, (outs GPR:$Rt), (ins),
"vmrs", "\t$Rt, fpcxts", []>;
}
let Predicates = [HasV8_1MMainline, HasMVEInt] in {
// System level VPR/P0 -> GPR
let Uses = [VPR] in
def VMRS_VPR : MovFromVFP<0b1100 /* vpr */, (outs GPR:$Rt), (ins),
"vmrs", "\t$Rt, vpr", []>;
def VMRS_P0 : MovFromVFP<0b1101 /* p0 */, (outs GPR:$Rt), (ins VCCR:$cond),
"vmrs", "\t$Rt, p0", []>;
}
}
//===----------------------------------------------------------------------===//
// Move from ARM core register to VFP System Register.
//
class MovToVFP<bits<4> opc19_16, dag oops, dag iops, string opc, string asm,
list<dag> pattern>:
VFPAI<oops, iops, VFPMiscFrm, IIC_fpSTAT, opc, asm, pattern> {
// Instruction operand.
bits<4> Rt;
let Inst{27-20} = 0b11101110;
let Inst{19-16} = opc19_16;
let Inst{15-12} = Rt;
let Inst{11-8} = 0b1010;
let Inst{7} = 0;
let Inst{6-5} = 0b00;
let Inst{4} = 1;
let Inst{3-0} = 0b0000;
let Predicates = [HasVFP2];
let Unpredictable{7-5} = 0b111;
let Unpredictable{3-0} = 0b1111;
}
let DecoderMethod = "DecodeForVMRSandVMSR" in {
let Defs = [FPSCR] in {
let Predicates = [HasFPRegs] in
// Application level GPR -> FPSCR
def VMSR : MovToVFP<0b0001 /* fpscr */, (outs), (ins GPRnopc:$Rt),
"vmsr", "\tfpscr, $Rt",
[(int_arm_set_fpscr GPRnopc:$Rt)]>;
// System level GPR -> FPEXC
def VMSR_FPEXC : MovToVFP<0b1000 /* fpexc */, (outs), (ins GPRnopc:$Rt),
"vmsr", "\tfpexc, $Rt", []>;
// System level GPR -> FPSID
def VMSR_FPSID : MovToVFP<0b0000 /* fpsid */, (outs), (ins GPRnopc:$Rt),
"vmsr", "\tfpsid, $Rt", []>;
def VMSR_FPINST : MovToVFP<0b1001 /* fpinst */, (outs), (ins GPRnopc:$Rt),
"vmsr", "\tfpinst, $Rt", []>;
def VMSR_FPINST2 : MovToVFP<0b1010 /* fpinst2 */, (outs), (ins GPRnopc:$Rt),
"vmsr", "\tfpinst2, $Rt", []>;
}
let Predicates = [HasV8_1MMainline, Has8MSecExt] in {
// System level GPR -> FPSCR with context saving for security extensions
def VMSR_FPCXTNS : MovToVFP<0b1110 /* fpcxtns */, (outs), (ins GPR:$Rt),
"vmsr", "\tfpcxtns, $Rt", []>;
}
let Predicates = [HasV8_1MMainline, Has8MSecExt] in {
// System level GPR -> FPSCR with context saving for security extensions
def VMSR_FPCXTS : MovToVFP<0b1111 /* fpcxts */, (outs), (ins GPR:$Rt),
"vmsr", "\tfpcxts, $Rt", []>;
}
let Predicates = [HasV8_1MMainline, HasFPRegs] in {
// System level GPR -> FPSCR_NZCVQC
def VMSR_FPSCR_NZCVQC
: MovToVFP<0b0010 /* fpscr_nzcvqc */,
(outs cl_FPSCR_NZCV:$fpscr_out), (ins GPR:$Rt),
"vmsr", "\tfpscr_nzcvqc, $Rt", []>;
}
let Predicates = [HasV8_1MMainline, HasMVEInt] in {
// System level GPR -> VPR/P0
let Defs = [VPR] in
def VMSR_VPR : MovToVFP<0b1100 /* vpr */, (outs), (ins GPR:$Rt),
"vmsr", "\tvpr, $Rt", []>;
def VMSR_P0 : MovToVFP<0b1101 /* p0 */, (outs VCCR:$cond), (ins GPR:$Rt),
"vmsr", "\tp0, $Rt", []>;
}
}
//===----------------------------------------------------------------------===//
// Misc.
//
// Materialize FP immediates. VFP3 only.
let isReMaterializable = 1 in {
def FCONSTD : VFPAI<(outs DPR:$Dd), (ins vfp_f64imm:$imm),
VFPMiscFrm, IIC_fpUNA64,
"vmov", ".f64\t$Dd, $imm",
[(set DPR:$Dd, vfp_f64imm:$imm)]>,
Requires<[HasVFP3,HasDPVFP]> {
bits<5> Dd;
bits<8> imm;
let Inst{27-23} = 0b11101;
let Inst{22} = Dd{4};
let Inst{21-20} = 0b11;
let Inst{19-16} = imm{7-4};
let Inst{15-12} = Dd{3-0};
let Inst{11-9} = 0b101;
let Inst{8} = 1; // Double precision.
let Inst{7-4} = 0b0000;
let Inst{3-0} = imm{3-0};
}
def FCONSTS : VFPAI<(outs SPR:$Sd), (ins vfp_f32imm:$imm),
VFPMiscFrm, IIC_fpUNA32,
"vmov", ".f32\t$Sd, $imm",
[(set SPR:$Sd, vfp_f32imm:$imm)]>, Requires<[HasVFP3]> {
bits<5> Sd;
bits<8> imm;
let Inst{27-23} = 0b11101;
let Inst{22} = Sd{0};
let Inst{21-20} = 0b11;
let Inst{19-16} = imm{7-4};
let Inst{15-12} = Sd{4-1};
let Inst{11-9} = 0b101;
let Inst{8} = 0; // Single precision.
let Inst{7-4} = 0b0000;
let Inst{3-0} = imm{3-0};
}
def FCONSTH : VFPAI<(outs HPR:$Sd), (ins vfp_f16imm:$imm),
VFPMiscFrm, IIC_fpUNA16,
"vmov", ".f16\t$Sd, $imm",
[(set (f16 HPR:$Sd), vfp_f16imm:$imm)]>,
Requires<[HasFullFP16]> {
bits<5> Sd;
bits<8> imm;
let Inst{27-23} = 0b11101;
let Inst{22} = Sd{0};
let Inst{21-20} = 0b11;
let Inst{19-16} = imm{7-4};
let Inst{15-12} = Sd{4-1};
let Inst{11-8} = 0b1001; // Half precision
let Inst{7-4} = 0b0000;
let Inst{3-0} = imm{3-0};
let isUnpredicable = 1;
}
}
//===----------------------------------------------------------------------===//
// Assembler aliases.
//
// A few mnemonic aliases for pre-unifixed syntax. We don't guarantee to
// support them all, but supporting at least some of the basics is
// good to be friendly.
def : VFP2MnemonicAlias<"flds", "vldr">;
def : VFP2MnemonicAlias<"fldd", "vldr">;
def : VFP2MnemonicAlias<"fmrs", "vmov">;
def : VFP2MnemonicAlias<"fmsr", "vmov">;
def : VFP2MnemonicAlias<"fsqrts", "vsqrt">;
def : VFP2MnemonicAlias<"fsqrtd", "vsqrt">;
def : VFP2MnemonicAlias<"fadds", "vadd.f32">;
def : VFP2MnemonicAlias<"faddd", "vadd.f64">;
def : VFP2MnemonicAlias<"fmrdd", "vmov">;
def : VFP2MnemonicAlias<"fmrds", "vmov">;
def : VFP2MnemonicAlias<"fmrrd", "vmov">;
def : VFP2MnemonicAlias<"fmdrr", "vmov">;
def : VFP2MnemonicAlias<"fmuls", "vmul.f32">;
def : VFP2MnemonicAlias<"fmuld", "vmul.f64">;
def : VFP2MnemonicAlias<"fnegs", "vneg.f32">;
def : VFP2MnemonicAlias<"fnegd", "vneg.f64">;
def : VFP2MnemonicAlias<"ftosizd", "vcvt.s32.f64">;
def : VFP2MnemonicAlias<"ftosid", "vcvtr.s32.f64">;
def : VFP2MnemonicAlias<"ftosizs", "vcvt.s32.f32">;
def : VFP2MnemonicAlias<"ftosis", "vcvtr.s32.f32">;
def : VFP2MnemonicAlias<"ftouizd", "vcvt.u32.f64">;
def : VFP2MnemonicAlias<"ftouid", "vcvtr.u32.f64">;
def : VFP2MnemonicAlias<"ftouizs", "vcvt.u32.f32">;
def : VFP2MnemonicAlias<"ftouis", "vcvtr.u32.f32">;
def : VFP2MnemonicAlias<"fsitod", "vcvt.f64.s32">;
def : VFP2MnemonicAlias<"fsitos", "vcvt.f32.s32">;
def : VFP2MnemonicAlias<"fuitod", "vcvt.f64.u32">;
def : VFP2MnemonicAlias<"fuitos", "vcvt.f32.u32">;
def : VFP2MnemonicAlias<"fsts", "vstr">;
def : VFP2MnemonicAlias<"fstd", "vstr">;
def : VFP2MnemonicAlias<"fmacd", "vmla.f64">;
def : VFP2MnemonicAlias<"fmacs", "vmla.f32">;
def : VFP2MnemonicAlias<"fcpys", "vmov.f32">;
def : VFP2MnemonicAlias<"fcpyd", "vmov.f64">;
def : VFP2MnemonicAlias<"fcmps", "vcmp.f32">;
def : VFP2MnemonicAlias<"fcmpd", "vcmp.f64">;
def : VFP2MnemonicAlias<"fdivs", "vdiv.f32">;
def : VFP2MnemonicAlias<"fdivd", "vdiv.f64">;
def : VFP2MnemonicAlias<"fmrx", "vmrs">;
def : VFP2MnemonicAlias<"fmxr", "vmsr">;
// Be friendly and accept the old form of zero-compare
def : VFP2DPInstAlias<"fcmpzd${p} $val", (VCMPZD DPR:$val, pred:$p)>;
def : VFP2InstAlias<"fcmpzs${p} $val", (VCMPZS SPR:$val, pred:$p)>;
def : InstAlias<"fmstat${p}", (FMSTAT pred:$p), 0>, Requires<[HasFPRegs]>;
def : VFP2InstAlias<"fadds${p} $Sd, $Sn, $Sm",
(VADDS SPR:$Sd, SPR:$Sn, SPR:$Sm, pred:$p)>;
def : VFP2DPInstAlias<"faddd${p} $Dd, $Dn, $Dm",
(VADDD DPR:$Dd, DPR:$Dn, DPR:$Dm, pred:$p)>;
def : VFP2InstAlias<"fsubs${p} $Sd, $Sn, $Sm",
(VSUBS SPR:$Sd, SPR:$Sn, SPR:$Sm, pred:$p)>;
def : VFP2DPInstAlias<"fsubd${p} $Dd, $Dn, $Dm",
(VSUBD DPR:$Dd, DPR:$Dn, DPR:$Dm, pred:$p)>;
// No need for the size suffix on VSQRT. It's implied by the register classes.
def : VFP2InstAlias<"vsqrt${p} $Sd, $Sm", (VSQRTS SPR:$Sd, SPR:$Sm, pred:$p)>;
def : VFP2DPInstAlias<"vsqrt${p} $Dd, $Dm", (VSQRTD DPR:$Dd, DPR:$Dm, pred:$p)>;
// VLDR/VSTR accept an optional type suffix.
def : VFP2InstAlias<"vldr${p}.32 $Sd, $addr",
(VLDRS SPR:$Sd, addrmode5:$addr, pred:$p)>;
def : VFP2InstAlias<"vstr${p}.32 $Sd, $addr",
(VSTRS SPR:$Sd, addrmode5:$addr, pred:$p)>;
def : VFP2InstAlias<"vldr${p}.64 $Dd, $addr",
(VLDRD DPR:$Dd, addrmode5:$addr, pred:$p)>;
def : VFP2InstAlias<"vstr${p}.64 $Dd, $addr",
(VSTRD DPR:$Dd, addrmode5:$addr, pred:$p)>;
// VMOV can accept optional 32-bit or less data type suffix suffix.
def : VFP2InstAlias<"vmov${p}.8 $Rt, $Sn",
(VMOVRS GPR:$Rt, SPR:$Sn, pred:$p)>;
def : VFP2InstAlias<"vmov${p}.16 $Rt, $Sn",
(VMOVRS GPR:$Rt, SPR:$Sn, pred:$p)>;
def : VFP2InstAlias<"vmov${p}.32 $Rt, $Sn",
(VMOVRS GPR:$Rt, SPR:$Sn, pred:$p)>;
def : VFP2InstAlias<"vmov${p}.8 $Sn, $Rt",
(VMOVSR SPR:$Sn, GPR:$Rt, pred:$p)>;
def : VFP2InstAlias<"vmov${p}.16 $Sn, $Rt",
(VMOVSR SPR:$Sn, GPR:$Rt, pred:$p)>;
def : VFP2InstAlias<"vmov${p}.32 $Sn, $Rt",
(VMOVSR SPR:$Sn, GPR:$Rt, pred:$p)>;
def : VFP2InstAlias<"vmov${p}.f64 $Rt, $Rt2, $Dn",
(VMOVRRD GPR:$Rt, GPR:$Rt2, DPR:$Dn, pred:$p)>;
def : VFP2InstAlias<"vmov${p}.f64 $Dn, $Rt, $Rt2",
(VMOVDRR DPR:$Dn, GPR:$Rt, GPR:$Rt2, pred:$p)>;
// VMOVS doesn't need the .f32 to disambiguate from the NEON encoding the way
// VMOVD does.
def : VFP2InstAlias<"vmov${p} $Sd, $Sm",
(VMOVS SPR:$Sd, SPR:$Sm, pred:$p)>;
// FCONSTD/FCONSTS alias for vmov.f64/vmov.f32
// These aliases provide added functionality over vmov.f instructions by
// allowing users to write assembly containing encoded floating point constants
// (e.g. #0x70 vs #1.0). Without these alises there is no way for the
// assembler to accept encoded fp constants (but the equivalent fp-literal is
// accepted directly by vmovf).
def : VFP3InstAlias<"fconstd${p} $Dd, $val",
(FCONSTD DPR:$Dd, vfp_f64imm:$val, pred:$p)>;
def : VFP3InstAlias<"fconsts${p} $Sd, $val",
(FCONSTS SPR:$Sd, vfp_f32imm:$val, pred:$p)>;
def VSCCLRMD : VFPXI<(outs), (ins pred:$p, fp_dreglist_with_vpr:$regs, variable_ops),
AddrModeNone, 4, IndexModeNone, VFPMiscFrm, NoItinerary,
"vscclrm{$p}\t$regs", "", []>, Sched<[]> {
bits<13> regs;
let Inst{31-23} = 0b111011001;
let Inst{22} = regs{12};
let Inst{21-16} = 0b011111;
let Inst{15-12} = regs{11-8};
let Inst{11-8} = 0b1011;
let Inst{7-1} = regs{7-1};
let Inst{0} = 0;
let DecoderMethod = "DecodeVSCCLRM";
list<Predicate> Predicates = [HasV8_1MMainline, Has8MSecExt];
}
def VSCCLRMS : VFPXI<(outs), (ins pred:$p, fp_sreglist_with_vpr:$regs, variable_ops),
AddrModeNone, 4, IndexModeNone, VFPMiscFrm, NoItinerary,
"vscclrm{$p}\t$regs", "", []>, Sched<[]> {
bits<13> regs;
let Inst{31-23} = 0b111011001;
let Inst{22} = regs{8};
let Inst{21-16} = 0b011111;
let Inst{15-12} = regs{12-9};
let Inst{11-8} = 0b1010;
let Inst{7-0} = regs{7-0};
let DecoderMethod = "DecodeVSCCLRM";
list<Predicate> Predicates = [HasV8_1MMainline, Has8MSecExt];
}
//===----------------------------------------------------------------------===//
// Store VFP System Register to memory.
//
class vfp_vstrldr<bit opc, bit P, bit W, bits<4> SysReg, string sysreg,
dag oops, dag iops, IndexMode im, string Dest, string cstr>
: VFPI<oops, iops, AddrModeT2_i7s4, 4, im, VFPLdStFrm, IIC_fpSTAT,
!if(opc,"vldr","vstr"), !strconcat("\t", sysreg, ", ", Dest), cstr, []>,
Sched<[]> {
bits<12> addr;
let Inst{27-25} = 0b110;
let Inst{24} = P;
let Inst{23} = addr{7};
let Inst{22} = SysReg{3};
let Inst{21} = W;
let Inst{20} = opc;
let Inst{19-16} = addr{11-8};
let Inst{15-13} = SysReg{2-0};
let Inst{12-7} = 0b011111;
let Inst{6-0} = addr{6-0};
list<Predicate> Predicates = [HasFPRegs, HasV8_1MMainline];
let mayLoad = opc;
let mayStore = !if(opc, 0b0, 0b1);
let hasSideEffects = 1;
}
multiclass vfp_vstrldr_sysreg<bit opc, bits<4> SysReg, string sysreg,
dag oops=(outs), dag iops=(ins)> {
def _off :
vfp_vstrldr<opc, 1, 0, SysReg, sysreg,
oops, !con(iops, (ins t2addrmode_imm7s4:$addr)),
IndexModePost, "$addr", "" > {
let DecoderMethod = "DecodeVSTRVLDR_SYSREG<false>";
}
def _pre :
vfp_vstrldr<opc, 1, 1, SysReg, sysreg,
!con(oops, (outs GPRnopc:$wb)),
!con(iops, (ins t2addrmode_imm7s4_pre:$addr)),
IndexModePre, "$addr!", "$addr.base = $wb"> {
let DecoderMethod = "DecodeVSTRVLDR_SYSREG<true>";
}
def _post :
vfp_vstrldr<opc, 0, 1, SysReg, sysreg,
!con(oops, (outs GPRnopc:$wb)),
!con(iops, (ins t2_addr_offset_none:$Rn,
t2am_imm7s4_offset:$addr)),
IndexModePost, "$Rn$addr", "$Rn.base = $wb"> {
bits<4> Rn;
let Inst{19-16} = Rn{3-0};
let DecoderMethod = "DecodeVSTRVLDR_SYSREG<true>";
}
}
let Defs = [FPSCR] in {
defm VSTR_FPSCR : vfp_vstrldr_sysreg<0b0,0b0001, "fpscr">;
defm VSTR_FPSCR_NZCVQC : vfp_vstrldr_sysreg<0b0,0b0010, "fpscr_nzcvqc">;
let Predicates = [HasV8_1MMainline, Has8MSecExt] in {
defm VSTR_FPCXTNS : vfp_vstrldr_sysreg<0b0,0b1110, "fpcxtns">;
defm VSTR_FPCXTS : vfp_vstrldr_sysreg<0b0,0b1111, "fpcxts">;
}
}
let Predicates = [HasV8_1MMainline, HasMVEInt] in {
let Uses = [VPR] in {
defm VSTR_VPR : vfp_vstrldr_sysreg<0b0,0b1100, "vpr">;
}
defm VSTR_P0 : vfp_vstrldr_sysreg<0b0,0b1101, "p0",
(outs), (ins VCCR:$P0)>;
}
let Uses = [FPSCR] in {
defm VLDR_FPSCR : vfp_vstrldr_sysreg<0b1,0b0001, "fpscr">;
defm VLDR_FPSCR_NZCVQC : vfp_vstrldr_sysreg<0b1,0b0010, "fpscr_nzcvqc">;
let Predicates = [HasV8_1MMainline, Has8MSecExt] in {
defm VLDR_FPCXTNS : vfp_vstrldr_sysreg<0b1,0b1110, "fpcxtns">;
defm VLDR_FPCXTS : vfp_vstrldr_sysreg<0b1,0b1111, "fpcxts">;
}
}
let Predicates = [HasV8_1MMainline, HasMVEInt] in {
let Defs = [VPR] in {
defm VLDR_VPR : vfp_vstrldr_sysreg<0b1,0b1100, "vpr">;
}
defm VLDR_P0 : vfp_vstrldr_sysreg<0b1,0b1101, "p0",
(outs VCCR:$P0), (ins)>;
}