llvm/lib/Target/AArch64/AArch64SchedA55.td - llvm-project - Git at Google

 //==- AArch64SchedCortexA55.td - ARM Cortex-A55 Scheduling Definitions -*- 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 defines the machine model for the ARM Cortex-A55 processors.
 //
 //===----------------------------------------------------------------------===//

 // ===---------------------------------------------------------------------===//
 // The following definitions describe the per-operand machine model.
 // This works with MachineScheduler. See MCSchedModel.h for details.

 // Cortex-A55 machine model for scheduling and other instruction cost heuristics.
 def CortexA55Model : SchedMachineModel {
   let MicroOpBufferSize = 0;  // The Cortex-A55 is an in-order processor
   let IssueWidth = 2;         // It dual-issues under most circumstances
   let LoadLatency = 4;        // Cycles for loads to access the cache. The
                               // optimisation guide shows that most loads have
                               // a latency of 3, but some have a latency of 4
                               // or 5. Setting it 4 looked to be good trade-off.
   let MispredictPenalty = 8;  // A branch direction mispredict.
   let PostRAScheduler = 1;    // Enable PostRA scheduler pass.
   let CompleteModel = 0;      // Covers instructions applicable to Cortex-A55.

   list<Predicate> UnsupportedFeatures = [HasSVE];

   // FIXME: Remove when all errors have been fixed.
   let FullInstRWOverlapCheck = 0;
 }

 //===----------------------------------------------------------------------===//
 // Define each kind of processor resource and number available.

 // Modeling each pipeline as a ProcResource using the BufferSize = 0 since the
 // Cortex-A55 is in-order.

 def CortexA55UnitALU    : ProcResource<2> { let BufferSize = 0; } // Int ALU
 def CortexA55UnitMAC    : ProcResource<1> { let BufferSize = 0; } // Int MAC, 64-bi wide
 def CortexA55UnitDiv    : ProcResource<1> { let BufferSize = 0; } // Int Division, not pipelined
 def CortexA55UnitLd     : ProcResource<1> { let BufferSize = 0; } // Load pipe
 def CortexA55UnitSt     : ProcResource<1> { let BufferSize = 0; } // Store pipe
 def CortexA55UnitB      : ProcResource<1> { let BufferSize = 0; } // Branch

 // The FP DIV/SQRT instructions execute totally differently from the FP ALU
 // instructions, which can mostly be dual-issued; that's why for now we model
 // them with 2 resources.
 def CortexA55UnitFPALU  : ProcResource<2> { let BufferSize = 0; } // FP ALU
 def CortexA55UnitFPMAC  : ProcResource<2> { let BufferSize = 0; } // FP MAC
 def CortexA55UnitFPDIV  : ProcResource<1> { let BufferSize = 0; } // FP Div/SQRT, 64/128

 //===----------------------------------------------------------------------===//
 // Subtarget-specific SchedWrite types

 let SchedModel = CortexA55Model in {

 // These latencies are modeled without taking into account forwarding paths
 // (the software optimisation guide lists latencies taking into account
 // typical forwarding paths).
 def : WriteRes<WriteImm, [CortexA55UnitALU]> { let Latency = 3; }    // MOVN, MOVZ
 def : WriteRes<WriteI, [CortexA55UnitALU]> { let Latency = 3; }      // ALU
 def : WriteRes<WriteISReg, [CortexA55UnitALU]> { let Latency = 3; }  // ALU of Shifted-Reg
 def : WriteRes<WriteIEReg, [CortexA55UnitALU]> { let Latency = 3; }  // ALU of Extended-Reg
 def : WriteRes<WriteExtr, [CortexA55UnitALU]> { let Latency = 3; }   // EXTR from a reg pair
 def : WriteRes<WriteIS, [CortexA55UnitALU]> { let Latency = 3; }     // Shift/Scale

 // MAC
 def : WriteRes<WriteIM32, [CortexA55UnitMAC]> { let Latency = 4; }   // 32-bit Multiply
 def : WriteRes<WriteIM64, [CortexA55UnitMAC]> { let Latency = 4; }   // 64-bit Multiply

 // Div
 def : WriteRes<WriteID32, [CortexA55UnitDiv]> {
   let Latency = 8; let ResourceCycles = [8];
 }
 def : WriteRes<WriteID64, [CortexA55UnitDiv]> {
   let Latency = 8; let ResourceCycles = [8];
 }

 // Load
 def : WriteRes<WriteLD, [CortexA55UnitLd]> { let Latency = 3; }
 def : WriteRes<WriteLDIdx, [CortexA55UnitLd]> { let Latency = 4; }
 def : WriteRes<WriteLDHi, [CortexA55UnitLd]> { let Latency = 5; }

 // Vector Load - Vector loads take 1-5 cycles to issue. For the WriteVecLd
 //               below, choosing the median of 3 which makes the latency 6.
 // An extra cycle is needed to get the swizzling right.
 def : WriteRes<WriteVLD, [CortexA55UnitLd]> { let Latency = 6;
                                            let ResourceCycles = [3]; }
 def CortexA55WriteVLD1 : SchedWriteRes<[CortexA55UnitLd]> { let Latency = 4; }
 def CortexA55WriteVLD1SI : SchedWriteRes<[CortexA55UnitLd]> { let Latency = 4; let SingleIssue = 1; }
 def CortexA55WriteVLD2 : SchedWriteRes<[CortexA55UnitLd]> { let Latency = 5;
                                                   let ResourceCycles = [2]; }
 def CortexA55WriteVLD3 : SchedWriteRes<[CortexA55UnitLd]> { let Latency = 6;
                                                   let ResourceCycles = [3]; }
 def CortexA55WriteVLD4 : SchedWriteRes<[CortexA55UnitLd]> { let Latency = 7;
                                                   let ResourceCycles = [4]; }
 def CortexA55WriteVLD5 : SchedWriteRes<[CortexA55UnitLd]> { let Latency = 8;
                                                   let ResourceCycles = [5]; }
 def CortexA55WriteVLD6 : SchedWriteRes<[CortexA55UnitLd]> { let Latency = 9;
                                                   let ResourceCycles = [6]; }
 def CortexA55WriteVLD7 : SchedWriteRes<[CortexA55UnitLd]> { let Latency = 10;
                                                   let ResourceCycles = [7]; }
 def CortexA55WriteVLD8 : SchedWriteRes<[CortexA55UnitLd]> { let Latency = 11;
                                                   let ResourceCycles = [8]; }

 def CortexA55WriteLDP1 : SchedWriteRes<[]> { let Latency = 4; }
 def CortexA55WriteLDP2 : SchedWriteRes<[CortexA55UnitLd]> { let Latency = 5; }
 def CortexA55WriteLDP4 : SchedWriteRes<[CortexA55UnitLd, CortexA55UnitLd, CortexA55UnitLd, CortexA55UnitLd, CortexA55UnitLd]> { let Latency = 6; }

 // Pre/Post Indexing - Performed as part of address generation
 def : WriteRes<WriteAdr, []> { let Latency = 0; }

 // Store
 let RetireOOO = 1 in {
 def : WriteRes<WriteST, [CortexA55UnitSt]> { let Latency = 1; }
 def : WriteRes<WriteSTP, [CortexA55UnitSt]> { let Latency = 1; }
 def : WriteRes<WriteSTIdx, [CortexA55UnitSt]> { let Latency = 1; }
 }
 def : WriteRes<WriteSTX, [CortexA55UnitSt]> { let Latency = 4; }

 // Vector Store - Similar to vector loads, can take 1-3 cycles to issue.
 def : WriteRes<WriteVST, [CortexA55UnitSt]> { let Latency = 5;
                                           let ResourceCycles = [2];}
 def CortexA55WriteVST1 : SchedWriteRes<[CortexA55UnitSt]> { let Latency = 4; }
 def CortexA55WriteVST2 : SchedWriteRes<[CortexA55UnitSt]> { let Latency = 5;
                                                   let ResourceCycles = [2]; }
 def CortexA55WriteVST3 : SchedWriteRes<[CortexA55UnitSt]> { let Latency = 6;
                                                   let ResourceCycles = [3]; }
 def CortexA55WriteVST4 : SchedWriteRes<[CortexA55UnitSt]> { let Latency = 5;
                                                   let ResourceCycles = [4]; }

 def : WriteRes<WriteAtomic, []> { let Unsupported = 1; }

 // Branch
 def : WriteRes<WriteBr, [CortexA55UnitB]>;
 def : WriteRes<WriteBrReg, [CortexA55UnitB]>;
 def : WriteRes<WriteSys, [CortexA55UnitB]>;
 def : WriteRes<WriteBarrier, [CortexA55UnitB]>;
 def : WriteRes<WriteHint, [CortexA55UnitB]>;

 // FP ALU
 //   As WriteF result is produced in F5 and it can be mostly forwarded
 //   to consumer at F1, the effectively latency is set as 4.
 def : WriteRes<WriteF, [CortexA55UnitFPALU]> { let Latency = 4; }
 def : WriteRes<WriteFCmp, [CortexA55UnitFPALU]> { let Latency = 3; }
 def : WriteRes<WriteFCvt, [CortexA55UnitFPALU]> { let Latency = 4; }
 def : WriteRes<WriteFCopy, [CortexA55UnitFPALU]> { let Latency = 3; }
 def : WriteRes<WriteFImm, [CortexA55UnitFPALU]> { let Latency = 3; }
 def : WriteRes<WriteVd, [CortexA55UnitFPALU]> { let Latency = 4; }
 def : WriteRes<WriteVq, [CortexA55UnitFPALU,CortexA55UnitFPALU]> { let Latency = 4; let BeginGroup = 1; }

 // FP ALU specific new schedwrite definitions
 def CortexA55WriteFPALU_F2 : SchedWriteRes<[CortexA55UnitFPALU]> { let Latency = 2;}
 def CortexA55WriteFPALU_F3 : SchedWriteRes<[CortexA55UnitFPALU]> { let Latency = 3;}
 def CortexA55WriteFPALU_F4 : SchedWriteRes<[CortexA55UnitFPALU]> { let Latency = 4;}
 def CortexA55WriteFPALU_F5 : SchedWriteRes<[CortexA55UnitFPALU]> { let Latency = 5;}

 // FP Mul, Div, Sqrt. Div/Sqrt are not pipelined
 def : WriteRes<WriteFMul, [CortexA55UnitFPMAC]> { let Latency = 4; }

 let RetireOOO = 1 in {
 def : WriteRes<WriteFDiv, [CortexA55UnitFPDIV]> { let Latency = 22;
                                             let ResourceCycles = [29]; }
 def CortexA55WriteFMAC : SchedWriteRes<[CortexA55UnitFPMAC]> { let Latency = 4; }
 def CortexA55WriteFDivHP : SchedWriteRes<[CortexA55UnitFPDIV]> { let Latency = 8;
                                                      let ResourceCycles = [5]; }
 def CortexA55WriteFDivSP : SchedWriteRes<[CortexA55UnitFPDIV]> { let Latency = 13;
                                                      let ResourceCycles = [10]; }
 def CortexA55WriteFDivDP : SchedWriteRes<[CortexA55UnitFPDIV]> { let Latency = 22;
                                                      let ResourceCycles = [19]; }
 def CortexA55WriteFSqrtHP : SchedWriteRes<[CortexA55UnitFPDIV]> { let Latency = 8;
                                                       let ResourceCycles = [5]; }
 def CortexA55WriteFSqrtSP : SchedWriteRes<[CortexA55UnitFPDIV]> { let Latency = 12;
                                                       let ResourceCycles = [9]; }
 def CortexA55WriteFSqrtDP : SchedWriteRes<[CortexA55UnitFPDIV]> { let Latency = 22;
                                                       let ResourceCycles = [19]; }
 }
 //===----------------------------------------------------------------------===//
 // Subtarget-specific SchedRead types.

 def : ReadAdvance<ReadVLD, 0>;
 def : ReadAdvance<ReadExtrHi, 1>;
 def : ReadAdvance<ReadAdrBase, 1>;
 def : ReadAdvance<ReadST, 1>;

 // ALU - ALU input operands are generally needed in EX1. An operand produced in
 //       in say EX2 can be forwarded for consumption to ALU in EX1, thereby
 //       allowing back-to-back ALU operations such as add. If an operand requires
 //       a shift, it will, however, be required in ISS stage.
 def : ReadAdvance<ReadI, 2, [WriteImm,WriteI,
                              WriteISReg, WriteIEReg,WriteIS,
                              WriteID32,WriteID64,
                              WriteIM32,WriteIM64]>;
 // Shifted operand
 def CortexA55ReadShifted : SchedReadAdvance<1, [WriteImm,WriteI,
                                           WriteISReg, WriteIEReg,WriteIS,
                                           WriteID32,WriteID64,
                                           WriteIM32,WriteIM64]>;
 def CortexA55ReadNotShifted : SchedReadAdvance<2, [WriteImm,WriteI,
                                              WriteISReg, WriteIEReg,WriteIS,
                                              WriteID32,WriteID64,
                                              WriteIM32,WriteIM64]>;
 def CortexA55ReadISReg : SchedReadVariant<[
         SchedVar<RegShiftedPred, [CortexA55ReadShifted]>,
         SchedVar<NoSchedPred, [CortexA55ReadNotShifted]>]>;
 def : SchedAlias<ReadISReg, CortexA55ReadISReg>;

 def CortexA55ReadIEReg : SchedReadVariant<[
         SchedVar<RegExtendedPred, [CortexA55ReadShifted]>,
         SchedVar<NoSchedPred, [CortexA55ReadNotShifted]>]>;
 def : SchedAlias<ReadIEReg, CortexA55ReadIEReg>;

 // MUL
 def : ReadAdvance<ReadIM, 1, [WriteImm,WriteI,
                               WriteISReg, WriteIEReg,WriteIS,
                               WriteID32,WriteID64,
                               WriteIM32,WriteIM64]>;
 def : ReadAdvance<ReadIMA, 2, [WriteImm,WriteI,
                                WriteISReg, WriteIEReg,WriteIS,
                                WriteID32,WriteID64,
                                WriteIM32,WriteIM64]>;

 // Div
 def : ReadAdvance<ReadID, 1, [WriteImm,WriteI,
                               WriteISReg, WriteIEReg,WriteIS,
                               WriteID32,WriteID64,
                               WriteIM32,WriteIM64]>;

 //===----------------------------------------------------------------------===//
 // Subtarget-specific InstRWs.

 //---
 // Miscellaneous
 //---
 def : InstRW<[CortexA55WriteVLD1SI,CortexA55WriteLDP1], (instregex "LDPS?W")>;
 def : InstRW<[CortexA55WriteVLD1,CortexA55WriteLDP1], (instregex "LDPS[^W]")>;
 def : InstRW<[CortexA55WriteVLD1,CortexA55WriteLDP2], (instregex "LDP(X|D)")>;
 def : InstRW<[CortexA55WriteVLD1,CortexA55WriteLDP4], (instregex "LDPQ")>;
 def : InstRW<[WriteI], (instrs COPY)>;
 //---
 // Vector Loads - 64-bit per cycle
 //---
 //   1-element structures
 def : InstRW<[CortexA55WriteVLD1], (instregex "LD1i(8|16|32|64)$")>;                // single element
 def : InstRW<[CortexA55WriteVLD1], (instregex "LD1Rv(8b|4h|2s|1d|16b|8h|4s|2d)$")>; // replicate
 def : InstRW<[CortexA55WriteVLD1], (instregex "LD1Onev(8b|4h|2s|1d)$")>;
 def : InstRW<[CortexA55WriteVLD2], (instregex "LD1Onev(16b|8h|4s|2d)$")>;
 def : InstRW<[CortexA55WriteVLD2], (instregex "LD1Twov(8b|4h|2s|1d)$")>; // multiple structures
 def : InstRW<[CortexA55WriteVLD4], (instregex "LD1Twov(16b|8h|4s|2d)$")>;
 def : InstRW<[CortexA55WriteVLD3], (instregex "LD1Threev(8b|4h|2s|1d)$")>;
 def : InstRW<[CortexA55WriteVLD6], (instregex "LD1Threev(16b|8h|4s|2d)$")>;
 def : InstRW<[CortexA55WriteVLD4], (instregex "LD1Fourv(8b|4h|2s|1d)$")>;
 def : InstRW<[CortexA55WriteVLD8], (instregex "LD1Fourv(16b|8h|4s|2d)$")>;

 def : InstRW<[CortexA55WriteVLD1, WriteAdr], (instregex "LD1i(8|16|32|64)_POST$")>;
 def : InstRW<[CortexA55WriteVLD1, WriteAdr], (instregex "LD1Rv(8b|4h|2s|1d|16b|8h|4s|2d)_POST$")>;
 def : InstRW<[CortexA55WriteVLD1, WriteAdr], (instregex "LD1Onev(8b|4h|2s|1d)_POST$")>;
 def : InstRW<[CortexA55WriteVLD2, WriteAdr], (instregex "LD1Onev(16b|8h|4s|2d)_POST$")>;
 def : InstRW<[CortexA55WriteVLD2, WriteAdr], (instregex "LD1Twov(8b|4h|2s|1d)_POST$")>;
 def : InstRW<[CortexA55WriteVLD4, WriteAdr], (instregex "LD1Twov(16b|8h|4s|2d)_POST$")>;
 def : InstRW<[CortexA55WriteVLD3, WriteAdr], (instregex "LD1Threev(8b|4h|2s|1d)_POST$")>;
 def : InstRW<[CortexA55WriteVLD6, WriteAdr], (instregex "LD1Threev(16b|8h|4s|2d)_POST$")>;
 def : InstRW<[CortexA55WriteVLD4, WriteAdr], (instregex "LD1Fourv(8b|4h|2s|1d)_POST$")>;
 def : InstRW<[CortexA55WriteVLD8, WriteAdr], (instregex "LD1Fourv(16b|8h|4s|2d)_POST$")>;

 //    2-element structures
 def : InstRW<[CortexA55WriteVLD2], (instregex "LD2i(8|16|32|64)$")>;
 def : InstRW<[CortexA55WriteVLD2], (instregex "LD2Rv(8b|4h|2s|1d|16b|8h|4s|2d)$")>;
 def : InstRW<[CortexA55WriteVLD2], (instregex "LD2Twov(8b|4h|2s)$")>;
 def : InstRW<[CortexA55WriteVLD4], (instregex "LD2Twov(16b|8h|4s|2d)$")>;

 def : InstRW<[CortexA55WriteVLD2, WriteAdr], (instregex "LD2i(8|16|32|64)(_POST)?$")>;
 def : InstRW<[CortexA55WriteVLD2, WriteAdr], (instregex "LD2Rv(8b|4h|2s|1d|16b|8h|4s|2d)(_POST)?$")>;
 def : InstRW<[CortexA55WriteVLD2, WriteAdr], (instregex "LD2Twov(8b|4h|2s)(_POST)?$")>;
 def : InstRW<[CortexA55WriteVLD4, WriteAdr], (instregex "LD2Twov(16b|8h|4s|2d)(_POST)?$")>;

 //    3-element structures
 def : InstRW<[CortexA55WriteVLD2], (instregex "LD3i(8|16|32|64)$")>;
 def : InstRW<[CortexA55WriteVLD2], (instregex "LD3Rv(8b|4h|2s|1d|16b|8h|4s|2d)$")>;
 def : InstRW<[CortexA55WriteVLD3], (instregex "LD3Threev(8b|4h|2s|1d)$")>;
 def : InstRW<[CortexA55WriteVLD6], (instregex "LD3Threev(16b|8h|4s|2d)$")>;

 def : InstRW<[CortexA55WriteVLD2, WriteAdr], (instregex "LD3i(8|16|32|64)_POST$")>;
 def : InstRW<[CortexA55WriteVLD2, WriteAdr], (instregex "LD3Rv(8b|4h|2s|1d|16b|8h|4s|2d)_POST$")>;
 def : InstRW<[CortexA55WriteVLD3, WriteAdr], (instregex "LD3Threev(8b|4h|2s|1d)_POST$")>;
 def : InstRW<[CortexA55WriteVLD6, WriteAdr], (instregex "LD3Threev(16b|8h|4s|2d)_POST$")>;

 //    4-element structures
 def : InstRW<[CortexA55WriteVLD2], (instregex "LD4i(8|16|32|64)$")>;                // load single 4-el structure to one lane of 4 regs.
 def : InstRW<[CortexA55WriteVLD2], (instregex "LD4Rv(8b|4h|2s|1d|16b|8h|4s|2d)$")>; // load single 4-el structure, replicate to all lanes of 4 regs.
 def : InstRW<[CortexA55WriteVLD4], (instregex "LD4Fourv(8b|4h|2s|1d)$")>;           // load multiple 4-el structures to 4 regs.
 def : InstRW<[CortexA55WriteVLD8], (instregex "LD4Fourv(16b|8h|4s|2d)$")>;

 def : InstRW<[CortexA55WriteVLD2, WriteAdr], (instregex "LD4i(8|16|32|64)_POST$")>;
 def : InstRW<[CortexA55WriteVLD2, WriteAdr], (instregex "LD4Rv(8b|4h|2s|1d|16b|8h|4s|2d)_POST$")>;
 def : InstRW<[CortexA55WriteVLD4, WriteAdr], (instregex "LD4Fourv(8b|4h|2s|1d)_POST$")>;
 def : InstRW<[CortexA55WriteVLD8, WriteAdr], (instregex "LD4Fourv(16b|8h|4s|2d)_POST$")>;

 //---
 // Vector Stores
 //---
 def : InstRW<[CortexA55WriteVST1], (instregex "ST1i(8|16|32|64)$")>;
 def : InstRW<[CortexA55WriteVST1], (instregex "ST1Onev(8b|4h|2s|1d|16b|8h|4s|2d)$")>;
 def : InstRW<[CortexA55WriteVST1], (instregex "ST1Twov(8b|4h|2s|1d|16b|8h|4s|2d)$")>;
 def : InstRW<[CortexA55WriteVST2], (instregex "ST1Threev(8b|4h|2s|1d|16b|8h|4s|2d)$")>;
 def : InstRW<[CortexA55WriteVST4], (instregex "ST1Fourv(8b|4h|2s|1d|16b|8h|4s|2d)$")>;
 def : InstRW<[CortexA55WriteVST1, WriteAdr], (instregex "ST1i(8|16|32|64)_POST$")>;
 def : InstRW<[CortexA55WriteVST1, WriteAdr], (instregex "ST1Onev(8b|4h|2s|1d|16b|8h|4s|2d)_POST$")>;
 def : InstRW<[CortexA55WriteVST1, WriteAdr], (instregex "ST1Twov(8b|4h|2s|1d|16b|8h|4s|2d)_POST$")>;
 def : InstRW<[CortexA55WriteVST2, WriteAdr], (instregex "ST1Threev(8b|4h|2s|1d|16b|8h|4s|2d)_POST$")>;
 def : InstRW<[CortexA55WriteVST4, WriteAdr], (instregex "ST1Fourv(8b|4h|2s|1d|16b|8h|4s|2d)_POST$")>;

 def : InstRW<[CortexA55WriteVST2], (instregex "ST2i(8|16|32|64)$")>;
 def : InstRW<[CortexA55WriteVST2], (instregex "ST2Twov(8b|4h|2s)$")>;
 def : InstRW<[CortexA55WriteVST4], (instregex "ST2Twov(16b|8h|4s|2d)$")>;
 def : InstRW<[CortexA55WriteVST2, WriteAdr], (instregex "ST2i(8|16|32|64)_POST$")>;
 def : InstRW<[CortexA55WriteVST2, WriteAdr], (instregex "ST2Twov(8b|4h|2s)_POST$")>;
 def : InstRW<[CortexA55WriteVST4, WriteAdr], (instregex "ST2Twov(16b|8h|4s|2d)_POST$")>;

 def : InstRW<[CortexA55WriteVST2], (instregex "ST3i(8|16|32|64)$")>;
 def : InstRW<[CortexA55WriteVST4], (instregex "ST3Threev(8b|4h|2s|1d|16b|8h|4s|2d)$")>;
 def : InstRW<[CortexA55WriteVST2, WriteAdr], (instregex "ST3i(8|16|32|64)_POST$")>;
 def : InstRW<[CortexA55WriteVST4, WriteAdr], (instregex "ST3Threev(8b|4h|2s|1d|2d|16b|8h|4s|4d)_POST$")>;

 def : InstRW<[CortexA55WriteVST2], (instregex "ST4i(8|16|32|64)$")>;
 def : InstRW<[CortexA55WriteVST4], (instregex "ST4Fourv(8b|4h|2s|1d|16b|8h|4s|2d)$")>;
 def : InstRW<[CortexA55WriteVST2, WriteAdr], (instregex "ST4i(8|16|32|64)_POST$")>;
 def : InstRW<[CortexA55WriteVST4, WriteAdr], (instregex "ST4Fourv(8b|4h|2s|1d|16b|8h|4s|2d)_POST$")>;

 //---
 // Floating Point Conversions, MAC, DIV, SQRT
 //---
 def : InstRW<[CortexA55WriteFPALU_F2], (instregex "^DUP(v2i64|v4i32|v8i16|v16i8)")>;
 def : InstRW<[CortexA55WriteFPALU_F2], (instregex "^XTN")>;
 def : InstRW<[CortexA55WriteFPALU_F3], (instregex "^FCVT[ALMNPZ][SU](S|U)?(W|X)")>;
 def : InstRW<[CortexA55WriteFPALU_F4], (instregex "^FCVT(X)?[ALMNPXZ](S|U|N)?v")>;

 def : InstRW<[CortexA55WriteFPALU_F4], (instregex "^(S|U)CVTF(S|U)(W|X)(H|S|D)")>;
 def : InstRW<[CortexA55WriteFPALU_F4], (instregex "^(S|U)CVTF(h|s|d)")>;
 def : InstRW<[CortexA55WriteFPALU_F4], (instregex "^(S|U)CVTFv")>;

 def : InstRW<[CortexA55WriteFMAC], (instregex "^FN?M(ADD|SUB).*")>;
 def : InstRW<[CortexA55WriteFMAC], (instregex "^FML(A|S).*")>;
 def : InstRW<[CortexA55WriteFDivHP], (instrs FDIVHrr)>;
 def : InstRW<[CortexA55WriteFDivSP], (instrs FDIVSrr)>;
 def : InstRW<[CortexA55WriteFDivDP], (instrs FDIVDrr)>;
 def : InstRW<[CortexA55WriteFDivHP], (instregex "^FDIVv.*16$")>;
 def : InstRW<[CortexA55WriteFDivSP], (instregex "^FDIVv.*32$")>;
 def : InstRW<[CortexA55WriteFDivDP], (instregex "^FDIVv.*64$")>;
 def : InstRW<[CortexA55WriteFSqrtHP], (instregex "^.*SQRT.*16$")>;
 def : InstRW<[CortexA55WriteFSqrtSP], (instregex "^.*SQRT.*32$")>;
 def : InstRW<[CortexA55WriteFSqrtDP], (instregex "^.*SQRT.*64$")>;

 }
	//==- AArch64SchedCortexA55.td - ARM Cortex-A55 Scheduling Definitions -- 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 defines the machine model for the ARM Cortex-A55 processors.
	//
	//===----------------------------------------------------------------------===//

	// ===---------------------------------------------------------------------===//
	// The following definitions describe the per-operand machine model.
	// This works with MachineScheduler. See MCSchedModel.h for details.

	// Cortex-A55 machine model for scheduling and other instruction cost heuristics.
	def CortexA55Model : SchedMachineModel {
	let MicroOpBufferSize = 0; // The Cortex-A55 is an in-order processor
	let IssueWidth = 2; // It dual-issues under most circumstances
	let LoadLatency = 4; // Cycles for loads to access the cache. The
	// optimisation guide shows that most loads have
	// a latency of 3, but some have a latency of 4
	// or 5. Setting it 4 looked to be good trade-off.
	let MispredictPenalty = 8; // A branch direction mispredict.
	let PostRAScheduler = 1; // Enable PostRA scheduler pass.
	let CompleteModel = 0; // Covers instructions applicable to Cortex-A55.

	list<Predicate> UnsupportedFeatures = [HasSVE];

	// FIXME: Remove when all errors have been fixed.
	let FullInstRWOverlapCheck = 0;
	}

	//===----------------------------------------------------------------------===//
	// Define each kind of processor resource and number available.

	// Modeling each pipeline as a ProcResource using the BufferSize = 0 since the
	// Cortex-A55 is in-order.

	def CortexA55UnitALU : ProcResource<2> { let BufferSize = 0; } // Int ALU
	def CortexA55UnitMAC : ProcResource<1> { let BufferSize = 0; } // Int MAC, 64-bi wide
	def CortexA55UnitDiv : ProcResource<1> { let BufferSize = 0; } // Int Division, not pipelined
	def CortexA55UnitLd : ProcResource<1> { let BufferSize = 0; } // Load pipe
	def CortexA55UnitSt : ProcResource<1> { let BufferSize = 0; } // Store pipe
	def CortexA55UnitB : ProcResource<1> { let BufferSize = 0; } // Branch

	// The FP DIV/SQRT instructions execute totally differently from the FP ALU
	// instructions, which can mostly be dual-issued; that's why for now we model
	// them with 2 resources.
	def CortexA55UnitFPALU : ProcResource<2> { let BufferSize = 0; } // FP ALU
	def CortexA55UnitFPMAC : ProcResource<2> { let BufferSize = 0; } // FP MAC
	def CortexA55UnitFPDIV : ProcResource<1> { let BufferSize = 0; } // FP Div/SQRT, 64/128

	//===----------------------------------------------------------------------===//
	// Subtarget-specific SchedWrite types

	let SchedModel = CortexA55Model in {

	// These latencies are modeled without taking into account forwarding paths
	// (the software optimisation guide lists latencies taking into account
	// typical forwarding paths).
	def : WriteRes<WriteImm, [CortexA55UnitALU]> { let Latency = 3; } // MOVN, MOVZ
	def : WriteRes<WriteI, [CortexA55UnitALU]> { let Latency = 3; } // ALU
	def : WriteRes<WriteISReg, [CortexA55UnitALU]> { let Latency = 3; } // ALU of Shifted-Reg
	def : WriteRes<WriteIEReg, [CortexA55UnitALU]> { let Latency = 3; } // ALU of Extended-Reg
	def : WriteRes<WriteExtr, [CortexA55UnitALU]> { let Latency = 3; } // EXTR from a reg pair
	def : WriteRes<WriteIS, [CortexA55UnitALU]> { let Latency = 3; } // Shift/Scale

	// MAC
	def : WriteRes<WriteIM32, [CortexA55UnitMAC]> { let Latency = 4; } // 32-bit Multiply
	def : WriteRes<WriteIM64, [CortexA55UnitMAC]> { let Latency = 4; } // 64-bit Multiply

	// Div
	def : WriteRes<WriteID32, [CortexA55UnitDiv]> {
	let Latency = 8; let ResourceCycles = [8];
	}
	def : WriteRes<WriteID64, [CortexA55UnitDiv]> {
	let Latency = 8; let ResourceCycles = [8];
	}

	// Load
	def : WriteRes<WriteLD, [CortexA55UnitLd]> { let Latency = 3; }
	def : WriteRes<WriteLDIdx, [CortexA55UnitLd]> { let Latency = 4; }
	def : WriteRes<WriteLDHi, [CortexA55UnitLd]> { let Latency = 5; }

	// Vector Load - Vector loads take 1-5 cycles to issue. For the WriteVecLd
	// below, choosing the median of 3 which makes the latency 6.
	// An extra cycle is needed to get the swizzling right.
	def : WriteRes<WriteVLD, [CortexA55UnitLd]> { let Latency = 6;
	let ResourceCycles = [3]; }
	def CortexA55WriteVLD1 : SchedWriteRes<[CortexA55UnitLd]> { let Latency = 4; }
	def CortexA55WriteVLD1SI : SchedWriteRes<[CortexA55UnitLd]> { let Latency = 4; let SingleIssue = 1; }
	def CortexA55WriteVLD2 : SchedWriteRes<[CortexA55UnitLd]> { let Latency = 5;
	let ResourceCycles = [2]; }
	def CortexA55WriteVLD3 : SchedWriteRes<[CortexA55UnitLd]> { let Latency = 6;
	let ResourceCycles = [3]; }
	def CortexA55WriteVLD4 : SchedWriteRes<[CortexA55UnitLd]> { let Latency = 7;
	let ResourceCycles = [4]; }
	def CortexA55WriteVLD5 : SchedWriteRes<[CortexA55UnitLd]> { let Latency = 8;
	let ResourceCycles = [5]; }
	def CortexA55WriteVLD6 : SchedWriteRes<[CortexA55UnitLd]> { let Latency = 9;
	let ResourceCycles = [6]; }
	def CortexA55WriteVLD7 : SchedWriteRes<[CortexA55UnitLd]> { let Latency = 10;
	let ResourceCycles = [7]; }
	def CortexA55WriteVLD8 : SchedWriteRes<[CortexA55UnitLd]> { let Latency = 11;
	let ResourceCycles = [8]; }

	def CortexA55WriteLDP1 : SchedWriteRes<[]> { let Latency = 4; }
	def CortexA55WriteLDP2 : SchedWriteRes<[CortexA55UnitLd]> { let Latency = 5; }
	def CortexA55WriteLDP4 : SchedWriteRes<[CortexA55UnitLd, CortexA55UnitLd, CortexA55UnitLd, CortexA55UnitLd, CortexA55UnitLd]> { let Latency = 6; }

	// Pre/Post Indexing - Performed as part of address generation
	def : WriteRes<WriteAdr, []> { let Latency = 0; }

	// Store
	let RetireOOO = 1 in {
	def : WriteRes<WriteST, [CortexA55UnitSt]> { let Latency = 1; }
	def : WriteRes<WriteSTP, [CortexA55UnitSt]> { let Latency = 1; }
	def : WriteRes<WriteSTIdx, [CortexA55UnitSt]> { let Latency = 1; }
	}
	def : WriteRes<WriteSTX, [CortexA55UnitSt]> { let Latency = 4; }

	// Vector Store - Similar to vector loads, can take 1-3 cycles to issue.
	def : WriteRes<WriteVST, [CortexA55UnitSt]> { let Latency = 5;
	let ResourceCycles = [2];}
	def CortexA55WriteVST1 : SchedWriteRes<[CortexA55UnitSt]> { let Latency = 4; }
	def CortexA55WriteVST2 : SchedWriteRes<[CortexA55UnitSt]> { let Latency = 5;
	let ResourceCycles = [2]; }
	def CortexA55WriteVST3 : SchedWriteRes<[CortexA55UnitSt]> { let Latency = 6;
	let ResourceCycles = [3]; }
	def CortexA55WriteVST4 : SchedWriteRes<[CortexA55UnitSt]> { let Latency = 5;
	let ResourceCycles = [4]; }

	def : WriteRes<WriteAtomic, []> { let Unsupported = 1; }

	// Branch
	def : WriteRes<WriteBr, [CortexA55UnitB]>;
	def : WriteRes<WriteBrReg, [CortexA55UnitB]>;
	def : WriteRes<WriteSys, [CortexA55UnitB]>;
	def : WriteRes<WriteBarrier, [CortexA55UnitB]>;
	def : WriteRes<WriteHint, [CortexA55UnitB]>;

	// FP ALU
	// As WriteF result is produced in F5 and it can be mostly forwarded
	// to consumer at F1, the effectively latency is set as 4.
	def : WriteRes<WriteF, [CortexA55UnitFPALU]> { let Latency = 4; }
	def : WriteRes<WriteFCmp, [CortexA55UnitFPALU]> { let Latency = 3; }
	def : WriteRes<WriteFCvt, [CortexA55UnitFPALU]> { let Latency = 4; }
	def : WriteRes<WriteFCopy, [CortexA55UnitFPALU]> { let Latency = 3; }
	def : WriteRes<WriteFImm, [CortexA55UnitFPALU]> { let Latency = 3; }
	def : WriteRes<WriteVd, [CortexA55UnitFPALU]> { let Latency = 4; }
	def : WriteRes<WriteVq, [CortexA55UnitFPALU,CortexA55UnitFPALU]> { let Latency = 4; let BeginGroup = 1; }

	// FP ALU specific new schedwrite definitions
	def CortexA55WriteFPALU_F2 : SchedWriteRes<[CortexA55UnitFPALU]> { let Latency = 2;}
	def CortexA55WriteFPALU_F3 : SchedWriteRes<[CortexA55UnitFPALU]> { let Latency = 3;}
	def CortexA55WriteFPALU_F4 : SchedWriteRes<[CortexA55UnitFPALU]> { let Latency = 4;}
	def CortexA55WriteFPALU_F5 : SchedWriteRes<[CortexA55UnitFPALU]> { let Latency = 5;}

	// FP Mul, Div, Sqrt. Div/Sqrt are not pipelined
	def : WriteRes<WriteFMul, [CortexA55UnitFPMAC]> { let Latency = 4; }

	let RetireOOO = 1 in {
	def : WriteRes<WriteFDiv, [CortexA55UnitFPDIV]> { let Latency = 22;
	let ResourceCycles = [29]; }
	def CortexA55WriteFMAC : SchedWriteRes<[CortexA55UnitFPMAC]> { let Latency = 4; }
	def CortexA55WriteFDivHP : SchedWriteRes<[CortexA55UnitFPDIV]> { let Latency = 8;
	let ResourceCycles = [5]; }
	def CortexA55WriteFDivSP : SchedWriteRes<[CortexA55UnitFPDIV]> { let Latency = 13;
	let ResourceCycles = [10]; }
	def CortexA55WriteFDivDP : SchedWriteRes<[CortexA55UnitFPDIV]> { let Latency = 22;
	let ResourceCycles = [19]; }
	def CortexA55WriteFSqrtHP : SchedWriteRes<[CortexA55UnitFPDIV]> { let Latency = 8;
	let ResourceCycles = [5]; }
	def CortexA55WriteFSqrtSP : SchedWriteRes<[CortexA55UnitFPDIV]> { let Latency = 12;
	let ResourceCycles = [9]; }
	def CortexA55WriteFSqrtDP : SchedWriteRes<[CortexA55UnitFPDIV]> { let Latency = 22;
	let ResourceCycles = [19]; }
	}
	//===----------------------------------------------------------------------===//
	// Subtarget-specific SchedRead types.

	def : ReadAdvance<ReadVLD, 0>;
	def : ReadAdvance<ReadExtrHi, 1>;
	def : ReadAdvance<ReadAdrBase, 1>;
	def : ReadAdvance<ReadST, 1>;

	// ALU - ALU input operands are generally needed in EX1. An operand produced in
	// in say EX2 can be forwarded for consumption to ALU in EX1, thereby
	// allowing back-to-back ALU operations such as add. If an operand requires
	// a shift, it will, however, be required in ISS stage.
	def : ReadAdvance<ReadI, 2, [WriteImm,WriteI,
	WriteISReg, WriteIEReg,WriteIS,
	WriteID32,WriteID64,
	WriteIM32,WriteIM64]>;
	// Shifted operand
	def CortexA55ReadShifted : SchedReadAdvance<1, [WriteImm,WriteI,
	WriteISReg, WriteIEReg,WriteIS,
	WriteID32,WriteID64,
	WriteIM32,WriteIM64]>;
	def CortexA55ReadNotShifted : SchedReadAdvance<2, [WriteImm,WriteI,
	WriteISReg, WriteIEReg,WriteIS,
	WriteID32,WriteID64,
	WriteIM32,WriteIM64]>;
	def CortexA55ReadISReg : SchedReadVariant<[
	SchedVar<RegShiftedPred, [CortexA55ReadShifted]>,
	SchedVar<NoSchedPred, [CortexA55ReadNotShifted]>]>;
	def : SchedAlias<ReadISReg, CortexA55ReadISReg>;

	def CortexA55ReadIEReg : SchedReadVariant<[
	SchedVar<RegExtendedPred, [CortexA55ReadShifted]>,
	SchedVar<NoSchedPred, [CortexA55ReadNotShifted]>]>;
	def : SchedAlias<ReadIEReg, CortexA55ReadIEReg>;

	// MUL
	def : ReadAdvance<ReadIM, 1, [WriteImm,WriteI,
	WriteISReg, WriteIEReg,WriteIS,
	WriteID32,WriteID64,
	WriteIM32,WriteIM64]>;
	def : ReadAdvance<ReadIMA, 2, [WriteImm,WriteI,
	WriteISReg, WriteIEReg,WriteIS,
	WriteID32,WriteID64,
	WriteIM32,WriteIM64]>;

	// Div
	def : ReadAdvance<ReadID, 1, [WriteImm,WriteI,
	WriteISReg, WriteIEReg,WriteIS,
	WriteID32,WriteID64,
	WriteIM32,WriteIM64]>;

	//===----------------------------------------------------------------------===//
	// Subtarget-specific InstRWs.

	//---
	// Miscellaneous
	//---
	def : InstRW<[CortexA55WriteVLD1SI,CortexA55WriteLDP1], (instregex "LDPS?W")>;
	def : InstRW<[CortexA55WriteVLD1,CortexA55WriteLDP1], (instregex "LDPS[^W]")>;
	def : InstRW<[CortexA55WriteVLD1,CortexA55WriteLDP2], (instregex "LDP(X\|D)")>;
	def : InstRW<[CortexA55WriteVLD1,CortexA55WriteLDP4], (instregex "LDPQ")>;
	def : InstRW<[WriteI], (instrs COPY)>;
	//---
	// Vector Loads - 64-bit per cycle
	//---
	// 1-element structures
	def : InstRW<[CortexA55WriteVLD1], (instregex "LD1i(8\|16\|32\|64)$")>; // single element
	def : InstRW<[CortexA55WriteVLD1], (instregex "LD1Rv(8b\|4h\|2s\|1d\|16b\|8h\|4s\|2d)$")>; // replicate
	def : InstRW<[CortexA55WriteVLD1], (instregex "LD1Onev(8b\|4h\|2s\|1d)$")>;
	def : InstRW<[CortexA55WriteVLD2], (instregex "LD1Onev(16b\|8h\|4s\|2d)$")>;
	def : InstRW<[CortexA55WriteVLD2], (instregex "LD1Twov(8b\|4h\|2s\|1d)$")>; // multiple structures
	def : InstRW<[CortexA55WriteVLD4], (instregex "LD1Twov(16b\|8h\|4s\|2d)$")>;
	def : InstRW<[CortexA55WriteVLD3], (instregex "LD1Threev(8b\|4h\|2s\|1d)$")>;
	def : InstRW<[CortexA55WriteVLD6], (instregex "LD1Threev(16b\|8h\|4s\|2d)$")>;
	def : InstRW<[CortexA55WriteVLD4], (instregex "LD1Fourv(8b\|4h\|2s\|1d)$")>;
	def : InstRW<[CortexA55WriteVLD8], (instregex "LD1Fourv(16b\|8h\|4s\|2d)$")>;

	def : InstRW<[CortexA55WriteVLD1, WriteAdr], (instregex "LD1i(8\|16\|32\|64)_POST$")>;
	def : InstRW<[CortexA55WriteVLD1, WriteAdr], (instregex "LD1Rv(8b\|4h\|2s\|1d\|16b\|8h\|4s\|2d)_POST$")>;
	def : InstRW<[CortexA55WriteVLD1, WriteAdr], (instregex "LD1Onev(8b\|4h\|2s\|1d)_POST$")>;
	def : InstRW<[CortexA55WriteVLD2, WriteAdr], (instregex "LD1Onev(16b\|8h\|4s\|2d)_POST$")>;
	def : InstRW<[CortexA55WriteVLD2, WriteAdr], (instregex "LD1Twov(8b\|4h\|2s\|1d)_POST$")>;
	def : InstRW<[CortexA55WriteVLD4, WriteAdr], (instregex "LD1Twov(16b\|8h\|4s\|2d)_POST$")>;
	def : InstRW<[CortexA55WriteVLD3, WriteAdr], (instregex "LD1Threev(8b\|4h\|2s\|1d)_POST$")>;
	def : InstRW<[CortexA55WriteVLD6, WriteAdr], (instregex "LD1Threev(16b\|8h\|4s\|2d)_POST$")>;
	def : InstRW<[CortexA55WriteVLD4, WriteAdr], (instregex "LD1Fourv(8b\|4h\|2s\|1d)_POST$")>;
	def : InstRW<[CortexA55WriteVLD8, WriteAdr], (instregex "LD1Fourv(16b\|8h\|4s\|2d)_POST$")>;

	// 2-element structures
	def : InstRW<[CortexA55WriteVLD2], (instregex "LD2i(8\|16\|32\|64)$")>;
	def : InstRW<[CortexA55WriteVLD2], (instregex "LD2Rv(8b\|4h\|2s\|1d\|16b\|8h\|4s\|2d)$")>;
	def : InstRW<[CortexA55WriteVLD2], (instregex "LD2Twov(8b\|4h\|2s)$")>;
	def : InstRW<[CortexA55WriteVLD4], (instregex "LD2Twov(16b\|8h\|4s\|2d)$")>;

	def : InstRW<[CortexA55WriteVLD2, WriteAdr], (instregex "LD2i(8\|16\|32\|64)(_POST)?$")>;
	def : InstRW<[CortexA55WriteVLD2, WriteAdr], (instregex "LD2Rv(8b\|4h\|2s\|1d\|16b\|8h\|4s\|2d)(_POST)?$")>;
	def : InstRW<[CortexA55WriteVLD2, WriteAdr], (instregex "LD2Twov(8b\|4h\|2s)(_POST)?$")>;
	def : InstRW<[CortexA55WriteVLD4, WriteAdr], (instregex "LD2Twov(16b\|8h\|4s\|2d)(_POST)?$")>;

	// 3-element structures
	def : InstRW<[CortexA55WriteVLD2], (instregex "LD3i(8\|16\|32\|64)$")>;
	def : InstRW<[CortexA55WriteVLD2], (instregex "LD3Rv(8b\|4h\|2s\|1d\|16b\|8h\|4s\|2d)$")>;
	def : InstRW<[CortexA55WriteVLD3], (instregex "LD3Threev(8b\|4h\|2s\|1d)$")>;
	def : InstRW<[CortexA55WriteVLD6], (instregex "LD3Threev(16b\|8h\|4s\|2d)$")>;

	def : InstRW<[CortexA55WriteVLD2, WriteAdr], (instregex "LD3i(8\|16\|32\|64)_POST$")>;
	def : InstRW<[CortexA55WriteVLD2, WriteAdr], (instregex "LD3Rv(8b\|4h\|2s\|1d\|16b\|8h\|4s\|2d)_POST$")>;
	def : InstRW<[CortexA55WriteVLD3, WriteAdr], (instregex "LD3Threev(8b\|4h\|2s\|1d)_POST$")>;
	def : InstRW<[CortexA55WriteVLD6, WriteAdr], (instregex "LD3Threev(16b\|8h\|4s\|2d)_POST$")>;

	// 4-element structures
	def : InstRW<[CortexA55WriteVLD2], (instregex "LD4i(8\|16\|32\|64)$")>; // load single 4-el structure to one lane of 4 regs.
	def : InstRW<[CortexA55WriteVLD2], (instregex "LD4Rv(8b\|4h\|2s\|1d\|16b\|8h\|4s\|2d)$")>; // load single 4-el structure, replicate to all lanes of 4 regs.
	def : InstRW<[CortexA55WriteVLD4], (instregex "LD4Fourv(8b\|4h\|2s\|1d)$")>; // load multiple 4-el structures to 4 regs.
	def : InstRW<[CortexA55WriteVLD8], (instregex "LD4Fourv(16b\|8h\|4s\|2d)$")>;

	def : InstRW<[CortexA55WriteVLD2, WriteAdr], (instregex "LD4i(8\|16\|32\|64)_POST$")>;
	def : InstRW<[CortexA55WriteVLD2, WriteAdr], (instregex "LD4Rv(8b\|4h\|2s\|1d\|16b\|8h\|4s\|2d)_POST$")>;
	def : InstRW<[CortexA55WriteVLD4, WriteAdr], (instregex "LD4Fourv(8b\|4h\|2s\|1d)_POST$")>;
	def : InstRW<[CortexA55WriteVLD8, WriteAdr], (instregex "LD4Fourv(16b\|8h\|4s\|2d)_POST$")>;

	//---
	// Vector Stores
	//---
	def : InstRW<[CortexA55WriteVST1], (instregex "ST1i(8\|16\|32\|64)$")>;
	def : InstRW<[CortexA55WriteVST1], (instregex "ST1Onev(8b\|4h\|2s\|1d\|16b\|8h\|4s\|2d)$")>;
	def : InstRW<[CortexA55WriteVST1], (instregex "ST1Twov(8b\|4h\|2s\|1d\|16b\|8h\|4s\|2d)$")>;
	def : InstRW<[CortexA55WriteVST2], (instregex "ST1Threev(8b\|4h\|2s\|1d\|16b\|8h\|4s\|2d)$")>;
	def : InstRW<[CortexA55WriteVST4], (instregex "ST1Fourv(8b\|4h\|2s\|1d\|16b\|8h\|4s\|2d)$")>;
	def : InstRW<[CortexA55WriteVST1, WriteAdr], (instregex "ST1i(8\|16\|32\|64)_POST$")>;
	def : InstRW<[CortexA55WriteVST1, WriteAdr], (instregex "ST1Onev(8b\|4h\|2s\|1d\|16b\|8h\|4s\|2d)_POST$")>;
	def : InstRW<[CortexA55WriteVST1, WriteAdr], (instregex "ST1Twov(8b\|4h\|2s\|1d\|16b\|8h\|4s\|2d)_POST$")>;
	def : InstRW<[CortexA55WriteVST2, WriteAdr], (instregex "ST1Threev(8b\|4h\|2s\|1d\|16b\|8h\|4s\|2d)_POST$")>;
	def : InstRW<[CortexA55WriteVST4, WriteAdr], (instregex "ST1Fourv(8b\|4h\|2s\|1d\|16b\|8h\|4s\|2d)_POST$")>;

	def : InstRW<[CortexA55WriteVST2], (instregex "ST2i(8\|16\|32\|64)$")>;
	def : InstRW<[CortexA55WriteVST2], (instregex "ST2Twov(8b\|4h\|2s)$")>;
	def : InstRW<[CortexA55WriteVST4], (instregex "ST2Twov(16b\|8h\|4s\|2d)$")>;
	def : InstRW<[CortexA55WriteVST2, WriteAdr], (instregex "ST2i(8\|16\|32\|64)_POST$")>;
	def : InstRW<[CortexA55WriteVST2, WriteAdr], (instregex "ST2Twov(8b\|4h\|2s)_POST$")>;
	def : InstRW<[CortexA55WriteVST4, WriteAdr], (instregex "ST2Twov(16b\|8h\|4s\|2d)_POST$")>;

	def : InstRW<[CortexA55WriteVST2], (instregex "ST3i(8\|16\|32\|64)$")>;
	def : InstRW<[CortexA55WriteVST4], (instregex "ST3Threev(8b\|4h\|2s\|1d\|16b\|8h\|4s\|2d)$")>;
	def : InstRW<[CortexA55WriteVST2, WriteAdr], (instregex "ST3i(8\|16\|32\|64)_POST$")>;
	def : InstRW<[CortexA55WriteVST4, WriteAdr], (instregex "ST3Threev(8b\|4h\|2s\|1d\|2d\|16b\|8h\|4s\|4d)_POST$")>;

	def : InstRW<[CortexA55WriteVST2], (instregex "ST4i(8\|16\|32\|64)$")>;
	def : InstRW<[CortexA55WriteVST4], (instregex "ST4Fourv(8b\|4h\|2s\|1d\|16b\|8h\|4s\|2d)$")>;
	def : InstRW<[CortexA55WriteVST2, WriteAdr], (instregex "ST4i(8\|16\|32\|64)_POST$")>;
	def : InstRW<[CortexA55WriteVST4, WriteAdr], (instregex "ST4Fourv(8b\|4h\|2s\|1d\|16b\|8h\|4s\|2d)_POST$")>;

	//---
	// Floating Point Conversions, MAC, DIV, SQRT
	//---
	def : InstRW<[CortexA55WriteFPALU_F2], (instregex "^DUP(v2i64\|v4i32\|v8i16\|v16i8)")>;
	def : InstRW<[CortexA55WriteFPALU_F2], (instregex "^XTN")>;
	def : InstRW<[CortexA55WriteFPALU_F3], (instregex "^FCVT[ALMNPZ][SU](S\|U)?(W\|X)")>;
	def : InstRW<[CortexA55WriteFPALU_F4], (instregex "^FCVT(X)?[ALMNPXZ](S\|U\|N)?v")>;

	def : InstRW<[CortexA55WriteFPALU_F4], (instregex "^(S\|U)CVTF(S\|U)(W\|X)(H\|S\|D)")>;
	def : InstRW<[CortexA55WriteFPALU_F4], (instregex "^(S\|U)CVTF(h\|s\|d)")>;
	def : InstRW<[CortexA55WriteFPALU_F4], (instregex "^(S\|U)CVTFv")>;

	def : InstRW<[CortexA55WriteFMAC], (instregex "^FN?M(ADD\|SUB).*")>;
	def : InstRW<[CortexA55WriteFMAC], (instregex "^FML(A\|S).*")>;
	def : InstRW<[CortexA55WriteFDivHP], (instrs FDIVHrr)>;
	def : InstRW<[CortexA55WriteFDivSP], (instrs FDIVSrr)>;
	def : InstRW<[CortexA55WriteFDivDP], (instrs FDIVDrr)>;
	def : InstRW<[CortexA55WriteFDivHP], (instregex "^FDIVv.*16$")>;
	def : InstRW<[CortexA55WriteFDivSP], (instregex "^FDIVv.*32$")>;
	def : InstRW<[CortexA55WriteFDivDP], (instregex "^FDIVv.*64$")>;
	def : InstRW<[CortexA55WriteFSqrtHP], (instregex "^.SQRT.16$")>;
	def : InstRW<[CortexA55WriteFSqrtSP], (instregex "^.SQRT.32$")>;
	def : InstRW<[CortexA55WriteFSqrtDP], (instregex "^.SQRT.64$")>;

	}