//==- AArch64SchedCortexA510.td - ARM Cortex-A510 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-A510 processor. // //===----------------------------------------------------------------------===// // ===---------------------------------------------------------------------===// // The following definitions describe the per-operand machine model. // This works with MachineScheduler. See MCSchedModel.h for details. // Cortex-A510 machine model for scheduling and other instruction cost heuristics. def CortexA510Model : SchedMachineModel { let MicroOpBufferSize = 0; // The Cortex-A510 is an in-order processor let IssueWidth = 3; // It dual-issues under most circumstances let LoadLatency = 3; // Cycles for loads to access the cache. // Most loads have a latency of 2, but some have higher latencies. // 3 seems to be a good tradeoff let PostRAScheduler = 1; // Enable PostRA scheduler pass. let CompleteModel = 0; // Covers instructions applicable to Cortex-A510. // FIXME: Remove when all errors have been fixed. let FullInstRWOverlapCheck = 0; } //===----------------------------------------------------------------------===// // Subtarget-specific SchedWrite types let SchedModel = CortexA510Model in { //===----------------------------------------------------------------------===// // Define each kind of processor resource and number available. // Modeling each pipeline as a ProcResource using the BufferSize = 0 since the // Cortex-A510 is in-order. let BufferSize = 0 in { def CortexA510UnitALU0 : ProcResource<1>; // Int ALU0 def CortexA510UnitALU12 : ProcResource<2>; // Int ALU1 & ALU2 def CortexA510UnitMAC : ProcResource<1>; // Int MAC, 64-bi wide def CortexA510UnitDiv : ProcResource<1>; // Int Division, not pipelined // There are 2 LS pipes, 1 for Load/Store; 1 for Store only def CortexA510UnitLdSt : ProcResource<1>; // Load/Store shared pipe def CortexA510UnitLd1 : ProcResource<1>; // Load pipe def CortexA510UnitB : ProcResource<1>; // Branch def CortexA510UnitPAC : ProcResource<1>; // Pointer Authentication (PAC) pipe // 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 CortexA510UnitVALU0 : ProcResource<1>; // SIMD/FP/SVE ALU0 def CortexA510UnitVALU1 : ProcResource<1>; // SIMD/FP/SVE ALU0 def CortexA510UnitVMAC : ProcResource<2>; // SIMD/FP/SVE MAC def CortexA510UnitVMC : ProcResource<1>; // SIMD/FP/SVE multicycle instrs (e.g Div, SQRT, cryptography) } def CortexA510UnitLd : ProcResGroup<[CortexA510UnitLdSt, CortexA510UnitLd1]>; def CortexA510UnitVALU : ProcResGroup<[CortexA510UnitVALU0, CortexA510UnitVALU1]>; def CortexA510UnitALU : ProcResGroup<[CortexA510UnitALU0, CortexA510UnitALU12]>; // These latencies are modeled without taking into account forwarding paths // (the software optimisation guide lists latencies taking into account // typical forwarding paths). def : WriteRes { let Latency = 1; } // MOVN, MOVZ def : WriteRes { let Latency = 1; } // ALU def : WriteRes { let Latency = 2; } // ALU of Shifted-Reg def : WriteRes { let Latency = 2; } // ALU of Extended-Reg def : WriteRes { let Latency = 2; } // EXTR from a reg pair def : WriteRes { let Latency = 2; } // Shift/Scale // MAC def : WriteRes { let Latency = 3; } // 32-bit Multiply def : WriteRes { let Latency = 5; let ReleaseAtCycles = [2];} // 64-bit Multiply // Div def : WriteRes { let Latency = 8; let ReleaseAtCycles = [8]; } def : WriteRes { let Latency = 16; let ReleaseAtCycles = [16]; } //===----------------------------------------------------------------------===// // Define customized scheduler read/write types specific to the Cortex A510 //===----------------------------------------------------------------------===// class CortexA510Write : SchedWriteRes<[res]> { let Latency = n; } class CortexA510MCWrite : SchedWriteRes<[res]> { let Latency = n; let ReleaseAtCycles = [m]; let BeginGroup = 1; } class CortexA510MC_RC0Write : SchedWriteRes<[res]> { let Latency = n; let BeginGroup = 1; } //===----------------------------------------------------------------------===// // Define generic 2 micro-op types def A510Write_10cyc_1VMAC_1VALU : SchedWriteRes<[CortexA510UnitVALU, CortexA510UnitVMAC]> { let Latency = 10; let NumMicroOps = 2; } def A510Write_15cyc_1VMAC_1VALU : SchedWriteRes<[CortexA510UnitVALU, CortexA510UnitVMAC]> { let Latency = 15; let NumMicroOps = 2; } class A510Write_PAC_B : SchedWriteRes<[CortexA510UnitPAC, CortexA510UnitB]> { let Latency = lat; let NumMicroOps = 2; } // Load def : WriteRes { let Latency = 2; } def : WriteRes { let Latency = 2; } def : WriteRes { let Latency = 2; } def CortexA510WriteVLD1 : SchedWriteRes<[CortexA510UnitLd]> { let Latency = 3; } def CortexA510WriteVLD1SI : SchedWriteRes<[CortexA510UnitLd]> { let Latency = 3; let SingleIssue = 1; } def CortexA510WriteVLD2 : SchedWriteRes<[CortexA510UnitLd]> { let Latency = 4; let ReleaseAtCycles = [2]; } def CortexA510WriteVLD3 : SchedWriteRes<[CortexA510UnitLd]> { let Latency = 5; let ReleaseAtCycles = [3]; } def CortexA510WriteVLD4 : SchedWriteRes<[CortexA510UnitLd]> { let Latency = 6; let ReleaseAtCycles = [4]; } def CortexA510WriteVLD6 : SchedWriteRes<[CortexA510UnitLd]> { let Latency = 5; let ReleaseAtCycles = [3]; } def CortexA510WriteVLD8 : SchedWriteRes<[CortexA510UnitLd]> { let Latency = 6; let ReleaseAtCycles = [4]; } def CortexA510WriteLDP1 : SchedWriteRes<[CortexA510UnitLd]> { let Latency = 3; } def CortexA510WriteLDP2 : SchedWriteRes<[CortexA510UnitLd]> { let Latency = 3; } def CortexA510WriteLDP4 : SchedWriteRes<[CortexA510UnitLd]> { let Latency = 3; } // Pre/Post Indexing - Performed as part of address generation def : WriteRes { let Latency = 0; } // Store let RetireOOO = 1 in { def : WriteRes { let Latency = 1; } def : WriteRes { let Latency = 1; } def : WriteRes { let Latency = 1; } } def : WriteRes { let Latency = 3; } // Vector Store - Similar to vector loads, can take 1-3 cycles to issue. def : WriteRes { let Latency = 5; let ReleaseAtCycles = [2];} def CortexA510WriteVST1 : SchedWriteRes<[CortexA510UnitLdSt]> { let Latency = 4; } def CortexA510WriteVST2 : SchedWriteRes<[CortexA510UnitLdSt]> { let Latency = 5; let ReleaseAtCycles = [2]; } def CortexA510WriteVST3 : SchedWriteRes<[CortexA510UnitLdSt]> { let Latency = 5; let ReleaseAtCycles = [3]; } def CortexA510WriteVST4 : SchedWriteRes<[CortexA510UnitLdSt]> { let Latency = 5; let ReleaseAtCycles = [4]; } def : WriteRes { let Unsupported = 1; } // Branch def : WriteRes; def : WriteRes; def : WriteRes; def : WriteRes; def : WriteRes; // 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 { let Latency = 4; } def : WriteRes { let Latency = 3; } def : WriteRes { let Latency = 4; } def : WriteRes { let Latency = 3; } def : WriteRes { let Latency = 3; } class CortexA510VSt : SchedWriteRes<[CortexA510UnitLdSt]> { let RetireOOO = 1; let ReleaseAtCycles = [n]; } def CortexA510VSt0 : SchedWriteRes<[CortexA510UnitLdSt]> { let RetireOOO = 1; } def : SchedAlias>; def : SchedAlias>; // FP ALU specific new schedwrite definitions def CortexA510WriteFPALU_F3 : SchedWriteRes<[CortexA510UnitVALU]> { let Latency = 3;} def CortexA510WriteFPALU_F4 : SchedWriteRes<[CortexA510UnitVALU]> { let Latency = 4;} // FP Mul, Div, Sqrt. Div/Sqrt are not pipelined def : WriteRes { let Latency = 4; } let RetireOOO = 1 in { def : WriteRes { let Latency = 22; let ReleaseAtCycles = [29]; } def CortexA510WriteVMAC : SchedWriteRes<[CortexA510UnitVMAC]> { let Latency = 4; } def CortexA510WriteFDivHP : SchedWriteRes<[CortexA510UnitVMC]> { let Latency = 8; let ReleaseAtCycles = [5]; } def CortexA510WriteFDivSP : SchedWriteRes<[CortexA510UnitVMC]> { let Latency = 13; let ReleaseAtCycles = [10]; } def CortexA510WriteFDivDP : SchedWriteRes<[CortexA510UnitVMC]> { let Latency = 22; let ReleaseAtCycles = [19]; } def CortexA510WriteFSqrtHP : SchedWriteRes<[CortexA510UnitVMC]> { let Latency = 8; let ReleaseAtCycles = [5]; } def CortexA510WriteFSqrtSP : SchedWriteRes<[CortexA510UnitVMC]> { let Latency = 12; let ReleaseAtCycles = [9]; } def CortexA510WriteFSqrtDP : SchedWriteRes<[CortexA510UnitVMC]> { let Latency = 22; let ReleaseAtCycles = [19]; } } //===----------------------------------------------------------------------===// // Subtarget-specific SchedRead types. def : ReadAdvance; def : ReadAdvance; def : ReadAdvance; def : ReadAdvance; def : ReadAdvance; def : ReadAdvance; def : ReadAdvance; // MUL def : ReadAdvance; def : ReadAdvance; // Div def : ReadAdvance; //===----------------------------------------------------------------------===// // Subtarget-specific InstRWs. def A510WriteISReg : SchedWriteVariant<[ SchedVar, SchedVar]>; def : InstRW<[A510WriteISReg], (instregex ".*rs$")>; def : InstRW<[WriteIS], (instrs RBITWr, RBITXr)>; // Pointer Authentication Instructions (v8.3 PAC) // ----------------------------------------------------------------------------- // Authenticate data address // Authenticate instruction address // Compute pointer authentication code for data address // Compute pointer authentication code, using generic key // Compute pointer authentication code for instruction address def : InstRW<[CortexA510Write<5, CortexA510UnitPAC>], (instregex "^AUT", "^PAC")>; // Branch and link, register, with pointer authentication // Branch, register, with pointer authentication // Branch, return, with pointer authentication def : InstRW<[A510Write_PAC_B<1>], (instrs BLRAA, BLRAAZ, BLRAB, BLRABZ, BRAA, BRAAZ, BRAB, BRABZ, RETAA, RETAB, ERETAA, ERETAB)>; // Load register, with pointer authentication def : InstRW<[CortexA510Write<2, CortexA510UnitPAC>], (instregex "^LDRA[AB](indexed|writeback)")>; // Strip pointer authentication code def : InstRW<[CortexA510Write<5, CortexA510UnitPAC>], (instrs XPACD, XPACI, XPACLRI)>; //--- // Miscellaneous //--- def : InstRW<[CortexA510WriteVLD1SI,CortexA510WriteLDP1], (instregex "LDPS?Wi")>; def : InstRW<[CortexA510WriteVLD1,CortexA510WriteLDP1], (instregex "LDPSi")>; def : InstRW<[CortexA510WriteVLD1,CortexA510WriteLDP2], (instregex "LDP(X|D)i")>; def : InstRW<[CortexA510WriteVLD1,CortexA510WriteLDP4], (instregex "LDPQi")>; def : InstRW<[WriteAdr, CortexA510WriteVLD1SI,CortexA510WriteLDP1], (instregex "LDPS?W(pre|post)")>; def : InstRW<[WriteAdr, CortexA510WriteVLD1,CortexA510WriteLDP1], (instregex "LDPS(pre|post)")>; def : InstRW<[WriteAdr, CortexA510WriteVLD1,CortexA510WriteLDP2], (instregex "LDP(X|D)(pre|post)")>; def : InstRW<[WriteAdr, CortexA510WriteVLD1,CortexA510WriteLDP4], (instregex "LDPQ(pre|post)")>; def : InstRW<[WriteI], (instrs COPY)>; //--- // Vector Loads - 128-bit per cycle //--- // 1-element structures def : InstRW<[CortexA510WriteVLD1], (instregex "LD1i(8|16|32|64)$")>; // single element def : InstRW<[CortexA510WriteVLD1], (instregex "LD1Rv(8b|4h|2s|1d|16b|8h|4s|2d)$")>; // replicate def : InstRW<[CortexA510WriteVLD1], (instregex "LD1Onev(8b|4h|2s|1d)$")>; def : InstRW<[CortexA510WriteVLD1], (instregex "LD1Onev(16b|8h|4s|2d)$")>; def : InstRW<[CortexA510WriteVLD1], (instregex "LD1Twov(8b|4h|2s|1d)$")>; // multiple structures def : InstRW<[CortexA510WriteVLD1], (instregex "LD1Twov(16b|8h|4s|2d)$")>; def : InstRW<[CortexA510WriteVLD2], (instregex "LD1Threev(8b|4h|2s|1d)$")>; def : InstRW<[CortexA510WriteVLD2], (instregex "LD1Threev(16b|8h|4s|2d)$")>; def : InstRW<[CortexA510WriteVLD2], (instregex "LD1Fourv(8b|4h|2s|1d)$")>; def : InstRW<[CortexA510WriteVLD2], (instregex "LD1Fourv(16b|8h|4s|2d)$")>; def : InstRW<[WriteAdr, CortexA510WriteVLD1], (instregex "LD1i(8|16|32|64)_POST$")>; def : InstRW<[WriteAdr, CortexA510WriteVLD1], (instregex "LD1Rv(8b|4h|2s|1d|16b|8h|4s|2d)_POST$")>; def : InstRW<[WriteAdr, CortexA510WriteVLD1], (instregex "LD1Onev(8b|4h|2s|1d)_POST$")>; def : InstRW<[WriteAdr, CortexA510WriteVLD2], (instregex "LD1Onev(16b|8h|4s|2d)_POST$")>; def : InstRW<[WriteAdr, CortexA510WriteVLD2], (instregex "LD1Twov(8b|4h|2s|1d)_POST$")>; def : InstRW<[WriteAdr, CortexA510WriteVLD2], (instregex "LD1Twov(16b|8h|4s|2d)_POST$")>; def : InstRW<[WriteAdr, CortexA510WriteVLD2], (instregex "LD1Threev(8b|4h|2s|1d)_POST$")>; def : InstRW<[WriteAdr, CortexA510WriteVLD2], (instregex "LD1Threev(16b|8h|4s|2d)_POST$")>; def : InstRW<[WriteAdr, CortexA510WriteVLD2], (instregex "LD1Fourv(8b|4h|2s|1d)_POST$")>; def : InstRW<[WriteAdr, CortexA510WriteVLD2], (instregex "LD1Fourv(16b|8h|4s|2d)_POST$")>; // 2-element structures def : InstRW<[CortexA510WriteVLD2], (instregex "LD2i(8|16|32|64)$")>; def : InstRW<[CortexA510WriteVLD2], (instregex "LD2Rv(8b|4h|2s|1d|16b|8h|4s|2d)$")>; def : InstRW<[CortexA510WriteVLD2], (instregex "LD2Twov(8b|4h|2s)$")>; def : InstRW<[CortexA510WriteVLD4], (instregex "LD2Twov(16b|8h|4s|2d)$")>; def : InstRW<[WriteAdr, CortexA510WriteVLD2], (instregex "LD2i(8|16|32|64)(_POST)?$")>; def : InstRW<[WriteAdr, CortexA510WriteVLD2], (instregex "LD2Rv(8b|4h|2s|1d|16b|8h|4s|2d)(_POST)?$")>; def : InstRW<[WriteAdr, CortexA510WriteVLD2], (instregex "LD2Twov(8b|4h|2s)(_POST)?$")>; def : InstRW<[WriteAdr, CortexA510WriteVLD4], (instregex "LD2Twov(16b|8h|4s|2d)(_POST)?$")>; // 3-element structures def : InstRW<[CortexA510WriteVLD2], (instregex "LD3i(8|16|32|64)$")>; def : InstRW<[CortexA510WriteVLD2], (instregex "LD3Rv(8b|4h|2s|1d|16b|8h|4s|2d)$")>; def : InstRW<[CortexA510WriteVLD3], (instregex "LD3Threev(8b|4h|2s|1d)$")>; def : InstRW<[CortexA510WriteVLD6], (instregex "LD3Threev(16b|8h|4s|2d)$")>; def : InstRW<[WriteAdr, CortexA510WriteVLD2], (instregex "LD3i(8|16|32|64)_POST$")>; def : InstRW<[WriteAdr, CortexA510WriteVLD2], (instregex "LD3Rv(8b|4h|2s|1d|16b|8h|4s|2d)_POST$")>; def : InstRW<[WriteAdr, CortexA510WriteVLD3], (instregex "LD3Threev(8b|4h|2s|1d)_POST$")>; def : InstRW<[WriteAdr, CortexA510WriteVLD6], (instregex "LD3Threev(16b|8h|4s|2d)_POST$")>; // 4-element structures def : InstRW<[CortexA510WriteVLD2], (instregex "LD4i(8|16|32|64)$")>; // load single 4-el structure to one lane of 4 regs. def : InstRW<[CortexA510WriteVLD2], (instregex "LD4Rv(8b|4h|2s|1d|16b|8h|4s|2d)$")>; // load single 4-el structure, replicate to all lanes of 4 regs. def : InstRW<[CortexA510WriteVLD4], (instregex "LD4Fourv(8b|4h|2s|1d)$")>; // load multiple 4-el structures to 4 regs. def : InstRW<[CortexA510WriteVLD8], (instregex "LD4Fourv(16b|8h|4s|2d)$")>; def : InstRW<[WriteAdr, CortexA510WriteVLD2], (instregex "LD4i(8|16|32|64)_POST$")>; def : InstRW<[WriteAdr, CortexA510WriteVLD2], (instregex "LD4Rv(8b|4h|2s|1d|16b|8h|4s|2d)_POST$")>; def : InstRW<[WriteAdr, CortexA510WriteVLD4], (instregex "LD4Fourv(8b|4h|2s|1d)_POST$")>; def : InstRW<[WriteAdr, CortexA510WriteVLD8], (instregex "LD4Fourv(16b|8h|4s|2d)_POST$")>; //--- // Vector Stores //--- def : InstRW<[CortexA510WriteVST1], (instregex "ST1i(8|16|32|64)$")>; def : InstRW<[CortexA510WriteVST1], (instregex "ST1Onev(8b|4h|2s|1d|16b|8h|4s|2d)$")>; def : InstRW<[CortexA510WriteVST1], (instregex "ST1Twov(8b|4h|2s|1d|16b|8h|4s|2d)$")>; def : InstRW<[CortexA510WriteVST2], (instregex "ST1Threev(8b|4h|2s|1d|16b|8h|4s|2d)$")>; def : InstRW<[CortexA510WriteVST4], (instregex "ST1Fourv(8b|4h|2s|1d|16b|8h|4s|2d)$")>; def : InstRW<[WriteAdr, CortexA510WriteVST1], (instregex "ST1i(8|16|32|64)_POST$")>; def : InstRW<[WriteAdr, CortexA510WriteVST1], (instregex "ST1Onev(8b|4h|2s|1d|16b|8h|4s|2d)_POST$")>; def : InstRW<[WriteAdr, CortexA510WriteVST1], (instregex "ST1Twov(8b|4h|2s|1d|16b|8h|4s|2d)_POST$")>; def : InstRW<[WriteAdr, CortexA510WriteVST2], (instregex "ST1Threev(8b|4h|2s|1d|16b|8h|4s|2d)_POST$")>; def : InstRW<[WriteAdr, CortexA510WriteVST4], (instregex "ST1Fourv(8b|4h|2s|1d|16b|8h|4s|2d)_POST$")>; def : InstRW<[CortexA510WriteVST2], (instregex "ST2i(8|16|32|64)$")>; def : InstRW<[CortexA510WriteVST2], (instregex "ST2Twov(8b|4h|2s)$")>; def : InstRW<[CortexA510WriteVST4], (instregex "ST2Twov(16b|8h|4s|2d)$")>; def : InstRW<[WriteAdr, CortexA510WriteVST2], (instregex "ST2i(8|16|32|64)_POST$")>; def : InstRW<[WriteAdr, CortexA510WriteVST2], (instregex "ST2Twov(8b|4h|2s)_POST$")>; def : InstRW<[WriteAdr, CortexA510WriteVST4], (instregex "ST2Twov(16b|8h|4s|2d)_POST$")>; def : InstRW<[CortexA510WriteVST2], (instregex "ST3i(8|16|32|64)$")>; def : InstRW<[CortexA510WriteVST4], (instregex "ST3Threev(8b|4h|2s|1d|16b|8h|4s|2d)$")>; def : InstRW<[WriteAdr, CortexA510WriteVST2], (instregex "ST3i(8|16|32|64)_POST$")>; def : InstRW<[WriteAdr, CortexA510WriteVST4], (instregex "ST3Threev(8b|4h|2s|1d|2d|16b|8h|4s|4d)_POST$")>; def : InstRW<[CortexA510WriteVST2], (instregex "ST4i(8|16|32|64)$")>; def : InstRW<[CortexA510WriteVST4], (instregex "ST4Fourv(8b|4h|2s|1d|16b|8h|4s|2d)$")>; def : InstRW<[WriteAdr, CortexA510WriteVST2], (instregex "ST4i(8|16|32|64)_POST$")>; def : InstRW<[WriteAdr, CortexA510WriteVST4], (instregex "ST4Fourv(8b|4h|2s|1d|16b|8h|4s|2d)_POST$")>; //--- // Floating Point Conversions, MAC, DIV, SQRT //--- def : InstRW<[CortexA510WriteFPALU_F3], (instregex "^DUP(v2i64|v4i32|v8i16|v16i8)")>; def : InstRW<[CortexA510WriteFPALU_F4], (instregex "^XTN")>; def : InstRW<[CortexA510WriteFPALU_F4], (instregex "^FCVT[ALMNPZ][SU](S|U)?(W|X)")>; def : InstRW<[CortexA510WriteFPALU_F4], (instregex "^FCVT(X)?[ALMNPXZ](S|U|N)?v")>; def : InstRW<[CortexA510WriteFPALU_F4], (instregex "^(S|U)CVTF(S|U)(W|X)(H|S|D)")>; def : InstRW<[CortexA510WriteFPALU_F4], (instregex "^(S|U)CVTF(h|s|d)")>; def : InstRW<[CortexA510WriteFPALU_F4], (instregex "^(S|U)CVTFv")>; def : InstRW<[CortexA510WriteVMAC], (instregex "^FN?M(ADD|SUB).*")>; def : InstRW<[CortexA510WriteVMAC], (instregex "^FML(A|S)v.*")>; def : InstRW<[CortexA510WriteFDivHP], (instrs FDIVHrr)>; def : InstRW<[CortexA510WriteFDivSP], (instrs FDIVSrr)>; def : InstRW<[CortexA510WriteFDivDP], (instrs FDIVDrr)>; def : InstRW<[CortexA510WriteFDivHP], (instregex "^FDIVv.*16$")>; def : InstRW<[CortexA510WriteFDivSP], (instregex "^FDIVv.*32$")>; def : InstRW<[CortexA510WriteFDivDP], (instregex "^FDIVv.*64$")>; def : InstRW<[CortexA510WriteFSqrtHP], (instregex "^.*SQRT.*16$")>; def : InstRW<[CortexA510WriteFSqrtSP], (instregex "^.*SQRT.*32$")>; def : InstRW<[CortexA510WriteFSqrtDP], (instregex "^.*SQRT.*64$")>; def : InstRW<[CortexA510WriteFPALU_F3], (instrs FCSELHrrr, FCSELSrrr, FCSELDrrr)>; // 4.15. Advanced SIMD integer instructions // ASIMD absolute diff def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "[SU]ABDv(2i32|4i16|8i8)")>; def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "[SU]ABDv(16i8|4i32|8i16)")>; // ASIMD absolute diff accum def : InstRW<[CortexA510Write<6, CortexA510UnitVALU>], (instregex "[SU]ABAL?v")>; // ASIMD absolute diff long def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "[SU]ABDLv")>; // ASIMD arith #1 def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "(ADD|SUB|NEG)v", "[SU]R?HADDv", "[SU]HSUBv")>; // ASIMD arith #2 def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "ABSv(1i64|2i32|4i16|8i8)$", "[SU]ADDLPv(2i32_v1i64|4i16_v2i32|8i8_v4i16)$", "ADDPv(2i32|4i16|8i8)$")>; def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "([SU]QADD|[SU]QSUB|SQNEG|SUQADD|USQADD)v(1i16|1i32|1i64|1i8|2i32|4i16|8i8)$")>; def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "ABSv(2i64|4i32|8i16|16i8)$", "[SU]ADDLPv(16i8_v8i16|4i32_v2i64|8i16_v4i32)$", "ADDPv(16i8|2i64|4i32|8i16)$")>; def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "([SU]QADD|[SU]QSUB|SQNEG|SUQADD|USQADD)v(16i8|2i64|4i32|8i16)$")>; // ASIMD arith #3 def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "SADDLv", "UADDLv", "SADDWv", "UADDWv", "SSUBLv", "USUBLv", "SSUBWv", "USUBWv")>; def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "ADDHNv", "SUBHNv")>; // ASIMD arith #5 def : InstRW<[CortexA510Write<8, CortexA510UnitVALU>], (instregex "RADDHNv", "RSUBHNv")>; // ASIMD arith, reduce def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "ADDVv")>; def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "SADDLVv", "UADDLVv")>; // ASIMD compare #1 def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "CM(EQ|GE|GT|HI|HS|LE|LT)v(1i64|2i32|4i16|8i8)")>; def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "CM(EQ|GE|GT|HI|HS|LE|LT)v(2i64|4i32|8i16|16i8)")>; // ASIMD compare #2 def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "CMTSTv(1i64|2i32|4i16|8i8)")>; def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "CMTSTv(2i64|4i32|8i16|16i8)")>; // ASIMD logical $1 def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "(AND|EOR|NOT|ORN)v8i8", "(ORR|BIC)v(2i32|4i16|8i8)$", "MVNIv(2i|2s|4i16)")>; def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "(AND|EOR|NOT|ORN)v16i8", "(ORR|BIC)v(16i8|4i32|8i16)$", "MVNIv(4i32|4s|8i16)")>; // ASIMD max/min, basic def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "[SU](MIN|MAX)P?v(2i32|4i16|8i8)")>; def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "[SU](MIN|MAX)P?v(16i8|4i132|8i16)")>; // SIMD max/min, reduce def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "[SU](MAX|MIN)Vv")>; // ASIMD multiply, by element def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "MULv(2i32|4i16|4i32|8i16)_indexed$", "SQR?DMULHv(1i16|1i32|2i32|4i16|4i32|8i16)_indexed$")>; // ASIMD multiply def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instrs PMULv8i8)>; def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instrs PMULv16i8)>; // ASIMD multiply accumulate def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "ML[AS]v(2i32|4i16|8i8)$")>; def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "ML[AS]v(16i8|4i32|8i16)$")>; def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "ML[AS]v(2i32|4i16|4i32|8i16)_indexed$")>; // ASIMD multiply accumulate half def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "SQRDML[AS]H[vi]")>; // ASIMD multiply accumulate long def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "[SU]ML[AS]Lv")>; // ASIMD multiply accumulate long #2 def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "SQDML[AS]L[iv]")>; // ASIMD dot product def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "[SU]DOTv8i8")>; def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "[SU]DOTv16i8")>; // ASIMD dot product, by scalar def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "[SU]DOTlanev")>; // ASIMD multiply long def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "[SU]MULLv", "SQDMULL[iv]")>; // ASIMD polynomial (8x8) multiply long def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instrs PMULLv8i8, PMULLv16i8)>; // ASIMD pairwise add and accumulate def : InstRW<[CortexA510MCWrite<7, 2, CortexA510UnitVALU>], (instregex "[SU]ADALPv")>; // ASIMD shift accumulate def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "[SU]SRA(d|v2i32|v4i16|v8i8)")>; def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "[SU]SRAv(16i8|2i64|4i32|8i16)")>; // ASIMD shift accumulate #2 def : InstRW<[CortexA510MCWrite<7, 2, CortexA510UnitVALU>], (instregex "[SU]RSRA[vd]")>; // ASIMD shift by immed def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "SHLd$", "SHLv", "SLId$", "SRId$", "[SU]SHR[vd]", "SHRNv")>; // ASIMD shift by immed // SXTL and UXTL are aliases for SHLL def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "[US]?SHLLv")>; // ASIMD shift by immed #2 def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "[SU]RSHR(d|v2i32|v4i16|v8i8)", "[SU]RSHRv(16i8|2i64|4i32|8i16)")>; def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "RSHRNv(2i32|4i16|8i8)", "RSHRNv(16i8|4i32|8i16)")>; // ASIMD shift by register def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "[SU]SHLv(1i64|2i32|4i16|8i8)")>; def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "[SU]SHLv(2i64|4i32|8i16|16i8)")>; // ASIMD shift by register #2 def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "[SU]RSHLv(1i64|2i32|4i16|8i8)")>; def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "[SU]RSHLv(2i64|4i32|8i16|16i8)")>; def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "[SU]QSHLv(1i64|2i32|4i16|8i8)")>; def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "[SU]QSHLv(2i64|4i32|8i16|16i8)")>; def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "[SU]QRSHLv(1i64|2i32|4i16|8i8)")>; def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "[SU]QRSHLv(2i64|4i32|8i16|16i8)")>; // Cryptography extensions // ----------------------------------------------------------------------------- // Crypto AES ops def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "^AES[DE]rr$", "^AESI?MCrr")>; // Crypto polynomial (64x64) multiply long def : InstRW<[CortexA510MCWrite<4, 0, CortexA510UnitVMC>], (instrs PMULLv1i64, PMULLv2i64)>; // Crypto SHA1 hash acceleration op // Crypto SHA1 schedule acceleration ops def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "^SHA1(H|SU0|SU1)")>; // Crypto SHA1 hash acceleration ops // Crypto SHA256 hash acceleration ops def : InstRW<[CortexA510MCWrite<4, 0, CortexA510UnitVMC>], (instregex "^SHA1[CMP]", "^SHA256H2?")>; // Crypto SHA256 schedule acceleration ops def : InstRW<[CortexA510MCWrite<4, 0, CortexA510UnitVMC>], (instregex "^SHA256SU[01]")>; // Crypto SHA512 hash acceleration ops def : InstRW<[CortexA510MCWrite<9, 0, CortexA510UnitVMC>], (instregex "^SHA512(H|H2|SU0|SU1)")>; // Crypto SHA3 ops def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instrs BCAX, EOR3)>; def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instrs XAR)>; def : InstRW<[CortexA510MCWrite<9, 0, CortexA510UnitVMC>], (instrs RAX1)>; // Crypto SM3 ops def : InstRW<[CortexA510MCWrite<9, 0, CortexA510UnitVMC>], (instregex "^SM3PARTW[12]$", "^SM3SS1$", "^SM3TT[12][AB]$")>; // Crypto SM4 ops def : InstRW<[CortexA510MCWrite<9, 0, CortexA510UnitVMC>], (instrs SM4E, SM4ENCKEY)>; // CRC // ----------------------------------------------------------------------------- def : InstRW<[CortexA510MCWrite<2, 0, CortexA510UnitMAC>], (instregex "^CRC32")>; // SVE Predicate instructions // Loop control, based on predicate def : InstRW<[CortexA510Write<2, CortexA510UnitVALU0>], (instrs BRKA_PPmP, BRKA_PPzP, BRKB_PPmP, BRKB_PPzP)>; // Loop control, based on predicate and flag setting def : InstRW<[CortexA510Write<2, CortexA510UnitVALU0>], (instrs BRKAS_PPzP, BRKBS_PPzP)>; // Loop control, propagating def : InstRW<[CortexA510Write<2, CortexA510UnitVALU0>], (instrs BRKN_PPzP, BRKPA_PPzPP, BRKPB_PPzPP)>; // Loop control, propagating and flag setting def : InstRW<[CortexA510Write<2, CortexA510UnitVALU0>], (instrs BRKNS_PPzP)>; def : InstRW<[CortexA510Write<4, CortexA510UnitVALU0>], (instrs BRKPAS_PPzPP, BRKPBS_PPzPP)>; // Loop control, based on GPR def : InstRW<[CortexA510Write<2, CortexA510UnitVALU0>], (instregex "^WHILE(GE|GT|HI|HS|LE|LO|LS|LT)_P(WW|XX)_[BHSD]")>; def : InstRW<[CortexA510Write<2, CortexA510UnitVALU0>], (instregex "^WHILE(RW|WR)_PXX_[BHSD]")>; // Loop terminate def : InstRW<[CortexA510Write<1, CortexA510UnitALU>], (instregex "^CTERM(EQ|NE)_(WW|XX)")>; // Predicate counting scalar def : InstRW<[CortexA510Write<1, CortexA510UnitALU>], (instrs ADDPL_XXI, ADDVL_XXI, RDVLI_XI)>; def : InstRW<[CortexA510Write<1, CortexA510UnitALU>], (instregex "^CNT[BHWD]_XPiI")>; def : InstRW<[CortexA510Write<3, CortexA510UnitALU>], (instregex "^(INC|DEC)[BHWD]_XPiI")>; def : InstRW<[CortexA510Write<4, CortexA510UnitALU>], (instregex "^(SQINC|SQDEC|UQINC|UQDEC)[BHWD]_[XW]Pi(Wd)?I")>; // Predicate counting scalar, active predicate def : InstRW<[CortexA510Write<4, CortexA510UnitVALU0>], (instregex "^CNTP_XPP_[BHSD]")>; def : InstRW<[CortexA510Write<4, CortexA510UnitVALU0>], (instregex "^(DEC|INC)P_XP_[BHSD]")>; def : InstRW<[CortexA510Write<9, CortexA510UnitVALU0>], (instregex "^(SQDEC|SQINC|UQDEC|UQINC)P_XP_[BHSD]", "^(UQDEC|UQINC)P_WP_[BHSD]", "^(SQDEC|SQINC|UQDEC|UQINC)P_XPWd_[BHSD]")>; // Predicate counting vector, active predicate def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^(DEC|INC|SQDEC|SQINC|UQDEC|UQINC)P_ZP_[HSD]")>; // Predicate logical def : InstRW<[CortexA510Write<2, CortexA510UnitVALU0>], (instregex "^(AND|BIC|EOR|NAND|NOR|ORN|ORR)_PPzPP")>; // Predicate logical, flag setting def : InstRW<[CortexA510Write<2, CortexA510UnitVALU0>], (instregex "^(ANDS|BICS|EORS|NANDS|NORS|ORNS|ORRS)_PPzPP")>; // Predicate reverse def : InstRW<[CortexA510Write<2, CortexA510UnitVALU0>], (instregex "^REV_PP_[BHSD]")>; // Predicate select def : InstRW<[CortexA510Write<2, CortexA510UnitVALU0>], (instrs SEL_PPPP)>; // Predicate set def : InstRW<[CortexA510Write<2, CortexA510UnitVALU0>], (instregex "^PFALSE", "^PTRUE_[BHSD]")>; // Predicate set/initialize, set flags def : InstRW<[CortexA510Write<2, CortexA510UnitVALU0>], (instregex "^PTRUES_[BHSD]")>; // Predicate find first/next def : InstRW<[CortexA510Write<2, CortexA510UnitVALU0>], (instregex "^PFIRST_B", "^PNEXT_[BHSD]")>; // Predicate test def : InstRW<[CortexA510Write<2, CortexA510UnitVALU0>], (instrs PTEST_PP)>; // Predicate transpose def : InstRW<[CortexA510Write<2, CortexA510UnitVALU0>], (instregex "^TRN[12]_PPP_[BHSDQ]")>; // Predicate unpack and widen def : InstRW<[CortexA510Write<2, CortexA510UnitVALU0>], (instrs PUNPKHI_PP, PUNPKLO_PP)>; // Predicate zip/unzip def : InstRW<[CortexA510Write<2, CortexA510UnitVALU0>], (instregex "^(ZIP|UZP)[12]_PPP_[BHSDQ]")>; // SVE integer instructions // ----------------------------------------------------------------------------- // Arithmetic, absolute diff def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "^[SU]ABD_(ZPmZ|ZPZZ)_[BHSD]")>; // Arithmetic, absolute diff accum def : InstRW<[CortexA510MCWrite<6, 2, CortexA510UnitVALU>], (instregex "^[SU]ABA_ZZZ_[BHSD]")>; // Arithmetic, absolute diff accum long def : InstRW<[CortexA510MCWrite<6, 2, CortexA510UnitVALU>], (instregex "^[SU]ABAL[TB]_ZZZ_[HSD]")>; // Arithmetic, absolute diff long def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "^[SU]ABDL[TB]_ZZZ_[HSD]")>; // Arithmetic, basic def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "^(ABS|CNOT|NEG)_ZPmZ_[BHSD]", "^(ADD|SUB|SUBR)_ZPmZ_[BHSD]", "^(ADD|SUB|SUBR)_ZPZZ_[BHSD]", "^(ADD|SUB)_ZZZ_[BHSD]", "^(ADD|SUB|SUBR)_ZI_[BHSD]", "^ADR_[SU]XTW_ZZZ_D_[0123]", "^ADR_LSL_ZZZ_[SD]_[0123]", "^[SU]H(ADD|SUB|SUBR)_ZPmZ_[BHSD]")>; def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^[SU](ADD|SUB)[LW][BT]_ZZZ_[HSD]", "^SADDLBT_ZZZ_[HSD]", "^SSUBL(BT|TB)_ZZZ_[HSD]")>; // Arithmetic, complex def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^SQ(ABS|NEG)_ZPmZ_[BHSD]", "^SQ(ADD|SUB|SUBR)_ZPmZ_?[BHSD]", "^[SU]Q(ADD|SUB)_ZZZ_[BHSD]", "^[SU]Q(ADD|SUB)_ZI_[BHSD]", "^(SRH|SUQ|UQ|USQ|URH)ADD_ZPmZ_[BHSD]", "^(UQSUB|UQSUBR)_ZPmZ_[BHSD]")>; def : InstRW<[CortexA510Write<8, CortexA510UnitVALU>], (instregex "^R?(ADD|SUB)HN[BT]_ZZZ_[BHS]")>; // Arithmetic, large integer def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^(AD|SB)CL[BT]_ZZZ_[SD]")>; // Arithmetic, pairwise add def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "^ADDP_ZPmZ_[BHSD]")>; // Arithmetic, pairwise add and accum long def : InstRW<[CortexA510MCWrite<7, 2, CortexA510UnitVALU>], (instregex "^[SU]ADALP_ZPmZ_[HSD]")>; // Arithmetic, shift def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "^(ASR|LSL|LSR)_WIDE_ZPmZ_[BHS]", "^(ASR|LSL|LSR)_WIDE_ZZZ_[BHS]", "^(ASR|LSL|LSR)_ZPmI_[BHSD]", "^(ASR|LSL|LSR)_ZPZI_[BHSD]", "^(ASR|LSL|LSR)_ZPmZ_[BHSD]", "^(ASR|LSL|LSR)_ZPZZ_[BHSD]", "^(ASR|LSL|LSR)_ZZI_[BHSD]", "^(ASRR|LSLR|LSRR)_ZPmZ_[BHSD]")>; // Arithmetic, shift right for divide def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^ASRD_ZPmI_[BHSD]", "^ASRD_ZPZI_[BHSD]")>; // Arithmetic, shift and accumulate def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^(SSRA|USRA)_ZZI_[BHSD]")>; def : InstRW<[CortexA510MCWrite<7, 2, CortexA510UnitVALU>], (instregex "^(SRSRA|URSRA)_ZZI_[BHSD]")>; // Arithmetic, shift by immediate // Arithmetic, shift by immediate and insert def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "^(SHRNB|SHRNT|SSHLLB|SSHLLT|USHLLB|USHLLT|SLI|SRI)_ZZI_[BHSD]")>; // Arithmetic, shift complex def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^(SQ)?RSHRU?N[BT]_ZZI_[BHS]", "^(SQRSHL|SQRSHLR|SQSHL|SQSHLR|UQRSHL|UQRSHLR|UQSHL|UQSHLR)_(ZPmZ|ZPZZ)_[BHSD]", "^(SQSHL|SQSHLU|UQSHL)_(ZPmI|ZPZI)_[BHSD]", "^SQSHRU?N[BT]_ZZI_[BHS]", "^UQR?SHRN[BT]_ZZI_[BHS]")>; // Arithmetic, shift rounding def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^(SRSHL|SRSHR|SRSHLR|URSHL|URSHLR|URSHR)_(ZPmZ|ZPZZ|ZPZI)_[BHSD]", "^[SU]RSHR_ZPmI_[BHSD]")>; // Bit manipulation def : InstRW<[CortexA510MCWrite<14, 13, CortexA510UnitVMC>], (instregex "^(BDEP|BEXT|BGRP)_ZZZ_B")>; def : InstRW<[CortexA510MCWrite<22, 21, CortexA510UnitVMC>], (instregex "^(BDEP|BEXT|BGRP)_ZZZ_H")>; def : InstRW<[CortexA510MCWrite<38, 37, CortexA510UnitVMC>], (instregex "^(BDEP|BEXT|BGRP)_ZZZ_S")>; def : InstRW<[CortexA510MCWrite<70, 69, CortexA510UnitVMC>], (instregex "^(BDEP|BEXT|BGRP)_ZZZ_D")>; // Bitwise select def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "^(BSL|BSL1N|BSL2N|NBSL)_ZZZZ")>; // Count/reverse bits def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "^(CLS|CLZ|RBIT)_ZPmZ_[BHSD]")>; def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "^CNT_ZPmZ_[BH]")>; def : InstRW<[CortexA510Write<8, CortexA510UnitVALU>], (instregex "^CNT_ZPmZ_S")>; def : InstRW<[CortexA510Write<12, CortexA510UnitVALU>], (instregex "^CNT_ZPmZ_D")>; // Broadcast logical bitmask immediate to vector def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instrs DUPM_ZI)>; // Compare and set flags def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^CMP(EQ|GE|GT|HI|HS|LE|LO|LS|LT|NE)_PPzZ[IZ]_[BHSD]", "^CMP(EQ|GE|GT|HI|HS|LE|LO|LS|LT|NE)_WIDE_PPzZZ_[BHS]")>; // Complex add def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "^CADD_ZZI_[BHSD]")>; def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^SQCADD_ZZI_[BHSD]")>; // Complex dot product 8-bit element def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instrs CDOT_ZZZ_S, CDOT_ZZZI_S)>; // Complex dot product 16-bit element def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instrs CDOT_ZZZ_D, CDOT_ZZZI_D)>; // Complex multiply-add B, H, S element size def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instregex "^CMLA_ZZZ_[BHS]", "^CMLA_ZZZI_[HS]")>; // Complex multiply-add D element size def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instrs CMLA_ZZZ_D)>; // Conditional extract operations, scalar form def : InstRW<[CortexA510MCWrite<8, 2, CortexA510UnitVALU>], (instregex "^CLAST[AB]_RPZ_[BHSD]")>; // Conditional extract operations, SIMD&FP scalar and vector forms def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^CLAST[AB]_[VZ]PZ_[BHSD]", "^COMPACT_ZPZ_[SD]", "^SPLICE_ZPZZ?_[BHSD]")>; // Convert to floating point, 64b to float or convert to double def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^[SU]CVTF_ZPmZ_Dto[SD]")>; // Convert to floating point, 64b to half def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^[SU]CVTF_ZPmZ_DtoH")>; // Convert to floating point, 32b to single or half def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^[SU]CVTF_ZPmZ_Sto[HS]")>; // Convert to floating point, 32b to double def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^[SU]CVTF_ZPmZ_StoD")>; // Convert to floating point, 16b to half def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^[SU]CVTF_ZPmZ_HtoH")>; // Copy, scalar def : InstRW<[CortexA510Write<3, CortexA510UnitVALU0>],(instregex "^CPY_ZPmR_[BHSD]")>; // Copy, scalar SIMD&FP or imm def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "^CPY_ZPm[IV]_[BHSD]", "^CPY_ZPzI_[BHSD]")>; // Divides, 32 bit def : InstRW<[CortexA510MCWrite<15, 12, CortexA510UnitVMC>], (instregex "^[SU]DIVR?_(ZPmZ|ZPZZ)_S")>; // Divides, 64 bit def : InstRW<[CortexA510MCWrite<26, 23, CortexA510UnitVMC>], (instregex "^[SU]DIVR?_(ZPmZ|ZPZZ)_D")>; // Dot product, 8 bit def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instregex "^[SU]DOT_ZZZI?_S")>; // Dot product, 8 bit, using signed and unsigned integers def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instrs SUDOT_ZZZI, USDOT_ZZZI, USDOT_ZZZ)>; // Dot product, 16 bit def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instregex "^[SU]DOT_ZZZI?_D")>; // Duplicate, immediate and indexed form def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "^DUP_ZI_[BHSD]", "^DUP_ZZI_[BHSDQ]")>; // Duplicate, scalar form def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "^DUP_ZR_[BHSD]")>; // Extend, sign or zero def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "^[SU]XTB_ZPmZ_[HSD]", "^[SU]XTH_ZPmZ_[SD]", "^[SU]XTW_ZPmZ_[D]")>; // Extract def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instrs EXT_ZZI, EXT_ZZI_B)>; // Extract narrow saturating def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^[SU]QXTN[BT]_ZZ_[BHS]", "^SQXTUN[BT]_ZZ_[BHS]")>; // Extract/insert operation, SIMD and FP scalar form def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^LAST[AB]_VPZ_[BHSD]", "^INSR_ZV_[BHSD]")>; // Extract/insert operation, scalar def : InstRW<[CortexA510MCWrite<8, 2, CortexA510UnitVALU0>], (instregex "^LAST[AB]_RPZ_[BHSD]", "^INSR_ZR_[BHSD]")>; // Histogram operations def : InstRW<[CortexA510MCWrite<8, 2, CortexA510UnitVALU0>], (instregex "^HISTCNT_ZPzZZ_[SD]", "^HISTSEG_ZZZ")>; // Horizontal operations, B, H, S form, immediate operands only def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instregex "^INDEX_II_[BHS]")>; // Horizontal operations, B, H, S form, scalar, immediate operands/ scalar // operands only / immediate, scalar operands def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instregex "^INDEX_(IR|RI|RR)_[BHS]")>; // Horizontal operations, D form, immediate operands only def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instrs INDEX_II_D)>; // Horizontal operations, D form, scalar, immediate operands)/ scalar operands // only / immediate, scalar operands def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instregex "^INDEX_(IR|RI|RR)_D")>; // Logical def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "^(AND|EOR|ORR)_ZI", "^(AND|BIC|EOR|EOR|ORR)_ZZZ", "^(AND|BIC|EOR|NOT|ORR)_ZPmZ_[BHSD]", "^(AND|BIC|EOR|NOT|ORR)_ZPZZ_[BHSD]")>; def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^EOR(BT|TB)_ZZZ_[BHSD]")>; // Max/min, basic and pairwise def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "^[SU](MAX|MIN)_ZI_[BHSD]", "^[SU](MAX|MIN)P?_(ZPmZ|ZPZZ)_[BHSD]")>; // Matching operations def : InstRW<[CortexA510MCWrite<7, 2, CortexA510UnitVALU>], (instregex "^N?MATCH_PPzZZ_[BH]")>; // Matrix multiply-accumulate def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instrs SMMLA_ZZZ, UMMLA_ZZZ, USMMLA_ZZZ)>; // Move prefix def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "^MOVPRFX_ZP[mz]Z_[BHSD]", "^MOVPRFX_ZZ")>; // Multiply, B, H, S element size def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instregex "^MUL_(ZI|ZPmZ|ZZZI|ZZZ|ZPZZ)_[BHS]", "^[SU]MULH_(ZPmZ|ZZZ|ZPZZ)_[BHS]")>; // Multiply, D element size def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instregex "^MUL_(ZI|ZPmZ|ZZZI|ZZZ|ZPZZ)_D", "^[SU]MULH_(ZPmZ|ZZZ|ZPZZ)_D")>; // Multiply long def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instregex "^[SU]MULL[BT]_ZZZI_[SD]", "^[SU]MULL[BT]_ZZZ_[HSD]")>; // Multiply accumulate, B, H, S element size def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instregex "^ML[AS]_(ZZZI|ZPZZZ)_[BHS]", "^(ML[AS]|MAD|MSB)_ZPmZZ_[BHS]")>; // Multiply accumulate, D element size def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instregex "^ML[AS]_(ZZZI|ZPZZZ)_D", "^(ML[AS]|MAD|MSB)_ZPmZZ_D")>; // Multiply accumulate long def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instregex "^[SU]ML[AS]L[BT]_ZZZ_[HSD]", "^[SU]ML[AS]L[BT]_ZZZI_[SD]")>; // Multiply accumulate saturating doubling long regular def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instregex "^SQDML[AS](LB|LT|LBT)_ZZZ_[HSD]", "^SQDML[AS](LB|LT)_ZZZI_[SD]")>; // Multiply saturating doubling high, B, H, S element size def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instregex "^SQDMULH_ZZZ_[BHS]", "^SQDMULH_ZZZI_[HS]")>; // Multiply saturating doubling high, D element size def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instrs SQDMULH_ZZZ_D, SQDMULH_ZZZI_D)>; // Multiply saturating doubling long def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instregex "^SQDMULL[BT]_ZZZ_[HSD]", "^SQDMULL[BT]_ZZZI_[SD]")>; // Multiply saturating rounding doubling regular/complex accumulate, B, H, S // element size def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instregex "^SQRDML[AS]H_ZZZ_[BHS]", "^SQRDCMLAH_ZZZ_[BHS]", "^SQRDML[AS]H_ZZZI_[HS]", "^SQRDCMLAH_ZZZI_[HS]")>; // Multiply saturating rounding doubling regular/complex accumulate, D element // size def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instregex "^SQRDML[AS]H_ZZZI?_D", "^SQRDCMLAH_ZZZ_D")>; // Multiply saturating rounding doubling regular/complex, B, H, S element size def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instregex "^SQRDMULH_ZZZ_[BHS]", "^SQRDMULH_ZZZI_[HS]")>; // Multiply saturating rounding doubling regular/complex, D element size def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instregex "^SQRDMULH_ZZZI?_D")>; // Multiply/multiply long, (8x8) polynomial def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^PMUL_ZZZ_B")>; def : InstRW<[CortexA510Write<9, CortexA510UnitVMC>], (instregex "^PMULL[BT]_ZZZ_[HDQ]")>; // Predicate counting vector def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "^(DEC|INC)[HWD]_ZPiI")>; def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^(SQDEC|SQINC|UQDEC|UQINC)[HWD]_ZPiI")>; // Reciprocal estimate def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instregex "^URECPE_ZPmZ_S", "^URSQRTE_ZPmZ_S")>; // Reduction, arithmetic, B form def : InstRW<[CortexA510Write<4, CortexA510UnitVALU0>], (instregex "^[SU](ADD|MAX|MIN)V_VPZ_B")>; // Reduction, arithmetic, H form def : InstRW<[CortexA510Write<4, CortexA510UnitVALU0>], (instregex "^[SU](ADD|MAX|MIN)V_VPZ_H")>; // Reduction, arithmetic, S form def : InstRW<[CortexA510Write<4, CortexA510UnitVALU0>], (instregex "^[SU](ADD|MAX|MIN)V_VPZ_S")>; // Reduction, arithmetic, D form def : InstRW<[CortexA510Write<4, CortexA510UnitVALU0>], (instregex "^[SU](ADD|MAX|MIN)V_VPZ_D")>; // Reduction, logical def : InstRW<[CortexA510Write<4, CortexA510UnitVALU0>], (instregex "^(ANDV|EORV|ORV)_VPZ_[BHSD]")>; // Reverse, vector def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "^REV_ZZ_[BHSD]", "^REVB_ZPmZ_[HSD]", "^REVH_ZPmZ_[SD]", "^REVW_ZPmZ_D")>; // Select, vector form def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "^SEL_ZPZZ_[BHSD]")>; // Table lookup def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^TBL_ZZZZ?_[BHSD]")>; // Table lookup extension def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^TBX_ZZZ_[BHSD]")>; // Transpose, vector form def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "^TRN[12]_ZZZ_[BHSDQ]")>; // Unpack and extend def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^[SU]UNPK(HI|LO)_ZZ_[HSD]")>; // Zip/unzip def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "^(UZP|ZIP)[12]_ZZZ_[BHSDQ]")>; // SVE floating-point instructions // ----------------------------------------------------------------------------- // Floating point absolute value/difference def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^FAB[SD]_ZPmZ_[HSD]", "^FAB[SD]_ZPZZ_[HSD]")>; // Floating point arithmetic def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^F(ADD|SUB)_(ZPm[IZ]|ZZZ|ZPZI|ZPZZ)_[HSD]", "^FADDP_ZPmZZ_[HSD]", "^FNEG_ZPmZ_[HSD]", "^FSUBR_(ZPm[IZ]|ZPZ[IZ])_[HSD]")>; // Floating point associative add, F16 def : InstRW<[CortexA510MCWrite<32, 29, CortexA510UnitVALU>], (instrs FADDA_VPZ_H)>; // Floating point associative add, F32 def : InstRW<[CortexA510MCWrite<16, 13, CortexA510UnitVALU>], (instrs FADDA_VPZ_S)>; // Floating point associative add, F64 def : InstRW<[CortexA510MCWrite<8, 5, CortexA510UnitVALU>], (instrs FADDA_VPZ_D)>; // Floating point compare def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^FACG[ET]_PPzZZ_[HSD]", "^FCM(EQ|GE|GT|NE)_PPzZ[0Z]_[HSD]", "^FCM(LE|LT)_PPzZ0_[HSD]", "^FCMUO_PPzZZ_[HSD]")>; // Floating point complex add def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^FCADD_ZPmZ_[HSD]")>; // Floating point complex multiply add def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instregex "^FCMLA_ZPmZZ_[HSD]", "^FCMLA_ZZZI_[HS]")>; // Floating point convert, long or narrow (F16 to F32 or F32 to F16) def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^FCVT_ZPmZ_(HtoS|StoH)", "^FCVTLT_ZPmZ_HtoS", "^FCVTNT_ZPmZ_StoH")>; // Floating point convert, long or narrow (F16 to F64, F32 to F64, F64 to F32 // or F64 to F16) def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^FCVT_ZPmZ_(HtoD|StoD|DtoS|DtoH)", "^FCVTLT_ZPmZ_StoD", "^FCVTNT_ZPmZ_DtoS")>; // Floating point convert, round to odd def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^FCVTX_ZPmZ_DtoS", "FCVTXNT_ZPmZ_DtoS")>; // Floating point base2 log, F16 def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instregex "^FLOGB_(ZPmZ|ZPZZ)_H")>; // Floating point base2 log, F32 def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instregex "^FLOGB_(ZPmZ|ZPZZ)_S")>; // Floating point base2 log, F64 def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instregex "^FLOGB_(ZPmZ|ZPZZ)_D")>; // Floating point convert to integer, F16 def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^FCVTZ[SU]_ZPmZ_HtoH")>; // Floating point convert to integer, F32 def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^FCVTZ[SU]_ZPmZ_(HtoS|StoS)")>; // Floating point convert to integer, F64 def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^FCVTZ[SU]_ZPmZ_(HtoD|StoD|DtoS|DtoD)")>; // Floating point copy def : InstRW<[CortexA510Write<3, CortexA510UnitVALU0>], (instregex "^FCPY_ZPmI_[HSD]", "^FDUP_ZI_[HSD]")>; // Floating point divide, F16 def : InstRW<[CortexA510MCWrite<8, 5, CortexA510UnitVMC>], (instregex "^FDIVR?_(ZPmZ|ZPZZ)_H")>; // Floating point divide, F32 def : InstRW<[CortexA510MCWrite<13, 10, CortexA510UnitVMC>], (instregex "^FDIVR?_(ZPmZ|ZPZZ)_S")>; // Floating point divide, F64 def : InstRW<[CortexA510MCWrite<22, 19, CortexA510UnitVMC>], (instregex "^FDIVR?_(ZPmZ|ZPZZ)_D")>; // Floating point min/max pairwise def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^F(MAX|MIN)(NM)?P_ZPmZZ_[HSD]")>; // Floating point min/max def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^F(MAX|MIN)(NM)?_(ZPm[IZ]|ZPZZ|ZPZI)_[HSD]")>; // Floating point multiply def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instregex "^(FSCALE|FMULX)_(ZPmZ|ZPZZ)_[HSD]", "^FMUL_(ZPm[IZ]|ZZZI?|ZPZI|ZPZZ)_[HSD]")>; // Floating point multiply accumulate def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instregex "^FML[AS]_(ZPmZZ|ZZZI|ZPZZZ)_[HSD]", "^(FMAD|FNMAD|FNML[AS]|FN?MSB)_(ZPmZZ|ZPZZZ)_[HSD]")>; // Floating point multiply add/sub accumulate long def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instregex "^FML[AS]L[BT]_ZZZI?_SHH")>; // Floating point reciprocal estimate, F16 def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instregex "^FRECPE_ZZ_H", "^FRECPX_ZPmZ_H", "^FRSQRTE_ZZ_H")>; // Floating point reciprocal estimate, F32 def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instregex "^FRECPE_ZZ_S", "^FRECPX_ZPmZ_S", "^FRSQRTE_ZZ_S")>; // Floating point reciprocal estimate, F64 def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>],(instregex "^FRECPE_ZZ_D", "^FRECPX_ZPmZ_D", "^FRSQRTE_ZZ_D")>; // Floating point reciprocal step def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instregex "^F(RECPS|RSQRTS)_ZZZ_[HSD]")>; // Floating point reduction, F16 def : InstRW<[CortexA510Write<4, CortexA510UnitVALU0>], (instregex "^(FMAXNMV|FMAXV|FMINNMV|FMINV)_VPZ_[HSD]")>; // Floating point reduction, F32 def : InstRW<[CortexA510MCWrite<12, 11, CortexA510UnitVALU0>], (instregex "^FADDV_VPZ_H")>; def : InstRW<[CortexA510MCWrite<8, 5, CortexA510UnitVALU0>], (instregex "^FADDV_VPZ_S")>; def : InstRW<[CortexA510Write<4, CortexA510UnitVALU0>], (instregex "^FADDV_VPZ_D")>; // Floating point round to integral, F16 def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^FRINT[AIMNPXZ]_ZPmZ_H")>; // Floating point round to integral, F32 def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^FRINT[AIMNPXZ]_ZPmZ_S")>; // Floating point round to integral, F64 def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^FRINT[AIMNPXZ]_ZPmZ_D")>; // Floating point square root, F16 def : InstRW<[CortexA510MCWrite<8, 5, CortexA510UnitVMC>], (instregex "^FSQRT_ZPmZ_H")>; // Floating point square root, F32 def : InstRW<[CortexA510MCWrite<12, 9, CortexA510UnitVMC>], (instregex "^FSQRT_ZPmZ_S")>; // Floating point square root, F64 def : InstRW<[CortexA510MCWrite<22, 19, CortexA510UnitVMC>], (instregex "^FSQRT_ZPmZ_D")>; // Floating point trigonometric exponentiation def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instregex "^FEXPA_ZZ_[HSD]")>; // Floating point trigonometric multiply add def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instregex "^FTMAD_ZZI_[HSD]")>; // Floating point trigonometric, miscellaneous def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instregex "^FTSMUL_ZZZ_[HSD]")>; def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "^FTSSEL_ZZZ_[HSD]")>; // SVE BFloat16 (BF16) instructions // ----------------------------------------------------------------------------- // Convert, F32 to BF16 def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instrs BFCVT_ZPmZ, BFCVTNT_ZPmZ)>; // Dot product def : InstRW<[A510Write_10cyc_1VMAC_1VALU], (instrs BFDOT_ZZI, BFDOT_ZZZ)>; // Matrix multiply accumulate def : InstRW<[A510Write_15cyc_1VMAC_1VALU], (instrs BFMMLA_ZZZ)>; // Multiply accumulate long def : InstRW<[CortexA510Write<4, CortexA510UnitVMAC>], (instregex "^BFMLAL[BT]_ZZZ(I)?")>; // SVE Load instructions // ----------------------------------------------------------------------------- // Load vector def : InstRW<[CortexA510Write<3, CortexA510UnitLd>], (instrs LDR_ZXI)>; // Load predicate def : InstRW<[CortexA510Write<3, CortexA510UnitLdSt>], (instrs LDR_PXI)>; // Contiguous load, scalar + imm def : InstRW<[CortexA510Write<3, CortexA510UnitLd>], (instregex "^LD1[BHWD]_IMM$", "^LD1S?B_[HSD]_IMM$", "^LD1S?H_[SD]_IMM$", "^LD1S?W_D_IMM$" )>; // Contiguous load, scalar + scalar def : InstRW<[CortexA510Write<3, CortexA510UnitLd>], (instregex "^LD1[BHWD]$", "^LD1S?B_[HSD]$", "^LD1S?H_[SD]$", "^LD1S?W_D$" )>; // Contiguous load broadcast, scalar + imm def : InstRW<[CortexA510Write<3, CortexA510UnitLd>], (instregex "^LD1R[BHWD]_IMM$", "^LD1RSW_IMM$", "^LD1RS?B_[HSD]_IMM$", "^LD1RS?H_[SD]_IMM$", "^LD1RS?W_D_IMM$", "^LD1RQ_[BHWD]_IMM$")>; // Contiguous load broadcast, scalar + scalar def : InstRW<[CortexA510Write<3, CortexA510UnitLdSt>], (instregex "^LD1RQ_[BHWD]$")>; // Non temporal load, scalar + imm def : InstRW<[CortexA510Write<3, CortexA510UnitLdSt>], (instregex "^LDNT1[BHWD]_ZRI$")>; // Non temporal load, scalar + scalar def : InstRW<[CortexA510Write<3, CortexA510UnitLdSt>], (instregex "^LDNT1[BHWD]_ZRR$")>; // Non temporal gather load, vector + scalar 32-bit element size def : InstRW<[CortexA510MCWrite<9, 9, CortexA510UnitLdSt>], (instregex "^LDNT1[BHW]_ZZR_S$", "^LDNT1S[BH]_ZZR_S$")>; // Non temporal gather load, vector + scalar 64-bit element size def : InstRW<[CortexA510MCWrite<7, 7, CortexA510UnitLdSt>], (instregex "^LDNT1S?[BHW]_ZZR_D$")>; def : InstRW<[CortexA510MCWrite<7, 7, CortexA510UnitLdSt>], (instrs LDNT1D_ZZR_D)>; // Contiguous first faulting load, scalar + scalar def : InstRW<[CortexA510Write<3, CortexA510UnitLd>], (instregex "^LDFF1[BHWD]$", "^LDFF1S?B_[HSD]$", "^LDFF1S?H_[SD]$", "^LDFF1S?W_D$")>; // Contiguous non faulting load, scalar + imm def : InstRW<[CortexA510Write<3, CortexA510UnitLd>], (instregex "^LDNF1[BHWD]_IMM$", "^LDNF1S?B_[HSD]_IMM$", "^LDNF1S?H_[SD]_IMM$", "^LDNF1S?W_D_IMM$")>; // Contiguous Load two structures to two vectors, scalar + imm def : InstRW<[CortexA510MCWrite<3, 1, CortexA510UnitLdSt>], (instregex "^LD2[BHWD]_IMM$")>; // Contiguous Load two structures to two vectors, scalar + scalar def : InstRW<[CortexA510MCWrite<3, 2, CortexA510UnitLdSt>], (instregex "^LD2[BHWD]$")>; // Contiguous Load three structures to three vectors, scalar + imm def : InstRW<[CortexA510MCWrite<5, 3, CortexA510UnitLdSt>], (instregex "^LD3[BHWD]_IMM$")>; // Contiguous Load three structures to three vectors, scalar + scalar def : InstRW<[CortexA510MCWrite<5, 3, CortexA510UnitLdSt>], (instregex "^LD3[BHWD]$")>; // Contiguous Load four structures to four vectors, scalar + imm def : InstRW<[CortexA510MCWrite<5, 3, CortexA510UnitLdSt>], (instregex "^LD4[BHWD]_IMM$")>; // Contiguous Load four structures to four vectors, scalar + scalar def : InstRW<[CortexA510MCWrite<5, 3, CortexA510UnitLdSt>], (instregex "^LD4[BHWD]$")>; // Gather load, vector + imm, 32-bit element size def : InstRW<[CortexA510MCWrite<9, 9, CortexA510UnitLdSt>], (instregex "^GLD(FF)?1S?[BH]_S_IMM$", "^GLD(FF)?1W_IMM$")>; // Gather load, vector + imm, 64-bit element size def : InstRW<[CortexA510MCWrite<7, 7, CortexA510UnitLdSt>], (instregex "^GLD(FF)?1S?[BHW]_D_IMM$", "^GLD(FF)?1D_IMM$")>; // Gather load, 64-bit element size def : InstRW<[CortexA510MCWrite<7, 7, CortexA510UnitLdSt>], (instregex "^GLD(FF)?1S?[BHW]_D_[SU]XTW(_SCALED)?$", "^GLD(FF)?1S?[BHW]_D(_SCALED)?$", "^GLD(FF)?1D_[SU]XTW(_SCALED)?$", "^GLD(FF)?1D(_SCALED)?$")>; // Gather load, 32-bit scaled offset def : InstRW<[CortexA510MCWrite<7, 7, CortexA510UnitLd>], (instregex "^GLD(FF)?1S?[HW]_S_[SU]XTW_SCALED$", "^GLD(FF)?1W_[SU]XTW_SCALED")>; // Gather load, 32-bit unpacked unscaled offset def : InstRW<[CortexA510MCWrite<7, 7, CortexA510UnitLd>], (instregex "^GLD(FF)?1S?[BH]_S_[SU]XTW$", "^GLD(FF)?1W_[SU]XTW$")>; def : InstRW<[CortexA510Write<0, CortexA510UnitVALU>], (instregex "^PRF(B|H|W|D).*")>; // SVE Store instructions // ----------------------------------------------------------------------------- // Store from predicate reg def : InstRW<[CortexA510VSt0], (instrs STR_PXI)>; // Store from vector reg def : InstRW<[CortexA510VSt0], (instrs STR_ZXI)>; // Contiguous store, scalar + imm def : InstRW<[CortexA510VSt0], (instregex "^ST1[BHWD]_IMM$", "^ST1B_[HSD]_IMM$", "^ST1H_[SD]_IMM$", "^ST1W_D_IMM$")>; // Contiguous store, scalar + scalar def : InstRW<[CortexA510VSt0], (instregex "^ST1H(_[SD])?$")>; def : InstRW<[CortexA510VSt0], (instregex "^ST1[BWD]$", "^ST1B_[HSD]$", "^ST1W_D$")>; // Contiguous store two structures from two vectors, scalar + imm def : InstRW<[CortexA510VSt<11>], (instregex "^ST2[BHWD]_IMM$")>; // Contiguous store two structures from two vectors, scalar + scalar def : InstRW<[CortexA510VSt<11>], (instrs ST2H)>; // Contiguous store two structures from two vectors, scalar + scalar def : InstRW<[CortexA510VSt<11>], (instregex "^ST2[BWD]$")>; // Contiguous store three structures from three vectors, scalar + imm def : InstRW<[CortexA510VSt<25>], (instregex "^ST3[BHW]_IMM$")>; def : InstRW<[CortexA510VSt<14>], (instregex "^ST3D_IMM$")>; // Contiguous store three structures from three vectors, scalar + scalar def : InstRW<[CortexA510VSt<25>], (instregex "^ST3[BHW]$")>; def : InstRW<[CortexA510VSt<14>], (instregex "^ST3D$")>; // Contiguous store four structures from four vectors, scalar + imm def : InstRW<[CortexA510VSt<50>], (instregex "^ST4[BHW]_IMM$")>; def : InstRW<[CortexA510VSt<25>], (instregex "^ST4D_IMM$")>; // Contiguous store four structures from four vectors, scalar + scalar def : InstRW<[CortexA510VSt<50>], (instregex "^ST4[BHW]$")>; // Contiguous store four structures from four vectors, scalar + scalar def : InstRW<[CortexA510VSt<25>], (instregex "^ST4D$")>; // Non temporal store, scalar + imm def : InstRW<[CortexA510VSt0], (instregex "^STNT1[BHWD]_ZRI$")>; // Non temporal store, scalar + scalar def : InstRW<[CortexA510VSt0], (instrs STNT1H_ZRR)>; def : InstRW<[CortexA510VSt0], (instregex "^STNT1[BWD]_ZRR$")>; // Scatter non temporal store, vector + scalar 32-bit element size def : InstRW<[CortexA510VSt<9>], (instregex "^STNT1[BHW]_ZZR_S")>; // Scatter non temporal store, vector + scalar 64-bit element size def : InstRW<[CortexA510VSt<7>], (instregex "^STNT1[BHWD]_ZZR_D")>; // Scatter store vector + imm 32-bit element size def : InstRW<[CortexA510VSt<9>], (instregex "^SST1[BH]_S_IMM$", "^SST1W_IMM$")>; // Scatter store vector + imm 64-bit element size def : InstRW<[CortexA510VSt<7>], (instregex "^SST1[BHW]_D_IMM$", "^SST1D_IMM$")>; // Scatter store, 32-bit scaled offset def : InstRW<[CortexA510VSt<8>], (instregex "^SST1(H_S|W)_[SU]XTW_SCALED$")>; // Scatter store, 32-bit unpacked unscaled offset def : InstRW<[CortexA510VSt<8>], (instregex "^SST1[BHW]_D_[SU]XTW$", "^SST1D_[SU]XTW$")>; // Scatter store, 32-bit unpacked scaled offset def : InstRW<[CortexA510VSt<8>], (instregex "^SST1[HW]_D_[SU]XTW_SCALED$", "^SST1D_[SU]XTW_SCALED$")>; // Scatter store, 32-bit unscaled offset def : InstRW<[CortexA510VSt<8>], (instregex "^SST1[BH]_S_[SU]XTW$", "^SST1W_[SU]XTW$")>; // Scatter store, 64-bit scaled offset def : InstRW<[CortexA510VSt<8>], (instregex "^SST1[HW]_D_SCALED$", "^SST1D_SCALED$")>; // Scatter store, 64-bit unscaled offset def : InstRW<[CortexA510VSt<8>], (instregex "^SST1[BHW]_D$", "^SST1D$")>; // SVE Miscellaneous instructions // ----------------------------------------------------------------------------- // Read first fault register, unpredicated def : InstRW<[CortexA510Write<1, CortexA510UnitALU>], (instrs RDFFR_P)>; // Read first fault register, predicated def : InstRW<[CortexA510Write<3, CortexA510UnitALU0>], (instrs RDFFR_PPz)>; // Read first fault register and set flags def : InstRW<[CortexA510Write<3, CortexA510UnitALU0>], (instrs RDFFRS_PPz)>; // Set first fault register // Write to first fault register def : InstRW<[CortexA510Write<1, CortexA510UnitALU>], (instrs SETFFR, WRFFR)>; // SVE Cryptographic instructions // ----------------------------------------------------------------------------- // Crypto AES ops def : InstRW<[CortexA510Write<3, CortexA510UnitVALU>], (instregex "^AES[DE]_ZZZ_B$", "^AESI?MC_ZZ_B$")>; // Crypto SHA3 ops def : InstRW<[CortexA510Write<4, CortexA510UnitVALU>], (instregex "^(BCAX|EOR3)_ZZZZ$", "^XAR_ZZZI_[BHSD]$")>; def : InstRW<[CortexA510MC_RC0Write<9, CortexA510UnitVMC>], (instregex "^RAX1_ZZZ_D$")>; // Crypto SM4 ops def : InstRW<[CortexA510MC_RC0Write<9, CortexA510UnitVMC>], (instregex "^SM4E(KEY)?_ZZZ_S$")>; }