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//=- AArch64SchedNeoverseV1.td - NeoverseV1 Scheduling Model -*- 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 scheduling model for the Arm Neoverse V1 processors.
//
// References:
// - "Arm Neoverse V1 Software Optimization Guide"
// - "Arm Neoverse V1 Platform: Unleashing a new performance tier for Arm-based computing"
// https://community.arm.com/arm-community-blogs/b/architectures-and-processors-blog/posts/neoverse-v1-platform-a-new-performance-tier-for-arm
// - "Neoverse V1"
// https://en.wikichip.org/wiki/arm_holdings/microarchitectures/neoverse_v1
//
//===----------------------------------------------------------------------===//
def NeoverseV1Model : SchedMachineModel {
let IssueWidth = 15; // Maximum micro-ops dispatch rate.
let MicroOpBufferSize = 256; // Micro-op re-order buffer.
let LoadLatency = 4; // Optimistic load latency.
let MispredictPenalty = 11; // Cycles cost of branch mispredicted.
let LoopMicroOpBufferSize = 16; // NOTE: Copied from Cortex-A57.
let CompleteModel = 1;
list<Predicate> UnsupportedFeatures = !listconcat(SVE2Unsupported.F,
SMEUnsupported.F,
[HasMTE, HasCPA,
HasCSSC]);
}
//===----------------------------------------------------------------------===//
// Define each kind of processor resource and number available on Neoverse V1.
// Instructions are first fetched and then decoded into internal macro-ops
// (MOPs). From there, the MOPs proceed through register renaming and dispatch
// stages. A MOP can be split into one or more micro-ops further down the
// pipeline, after the decode stage. Once dispatched, micro-ops wait for their
// operands and issue out-of-order to one of the issue pipelines. Each issue
// pipeline can accept one micro-op per cycle.
let SchedModel = NeoverseV1Model in {
// Define the issue ports.
def V1UnitB : ProcResource<2>; // Branch 0/1
def V1UnitS : ProcResource<2>; // Integer single cycle 0/1
def V1UnitM0 : ProcResource<1>; // Integer multicycle 0
def V1UnitM1 : ProcResource<1>; // Integer multicycle 1
def V1UnitL01 : ProcResource<2>; // Load/Store 0/1
def V1UnitL2 : ProcResource<1>; // Load 2
def V1UnitD : ProcResource<2>; // Store data 0/1
def V1UnitV0 : ProcResource<1>; // FP/ASIMD 0
def V1UnitV1 : ProcResource<1>; // FP/ASIMD 1
def V1UnitV2 : ProcResource<1>; // FP/ASIMD 2
def V1UnitV3 : ProcResource<1>; // FP/ASIMD 3
def V1UnitI : ProcResGroup<[V1UnitS,
V1UnitM0, V1UnitM1]>; // Integer units
def V1UnitJ : ProcResGroup<[V1UnitS, V1UnitM0]>; // Integer 0-2 units
def V1UnitM : ProcResGroup<[V1UnitM0, V1UnitM1]>; // Integer multicycle units
def V1UnitL : ProcResGroup<[V1UnitL01, V1UnitL2]>; // Load units
def V1UnitV : ProcResGroup<[V1UnitV0, V1UnitV1,
V1UnitV2, V1UnitV3]>; // FP/ASIMD units
def V1UnitV01 : ProcResGroup<[V1UnitV0, V1UnitV1]>; // FP/ASIMD 0/1 units
def V1UnitV02 : ProcResGroup<[V1UnitV0, V1UnitV2]>; // FP/ASIMD 0/2 units
def V1UnitV13 : ProcResGroup<[V1UnitV1, V1UnitV3]>; // FP/ASIMD 1/3 units
// Define commonly used read types.
// No generic forwarding is provided for these types.
def : ReadAdvance<ReadI, 0>;
def : ReadAdvance<ReadISReg, 0>;
def : ReadAdvance<ReadIEReg, 0>;
def : ReadAdvance<ReadIM, 0>;
def : ReadAdvance<ReadIMA, 0>;
def : ReadAdvance<ReadID, 0>;
def : ReadAdvance<ReadExtrHi, 0>;
def : ReadAdvance<ReadAdrBase, 0>;
def : ReadAdvance<ReadST, 0>;
def : ReadAdvance<ReadVLD, 0>;
def : WriteRes<WriteAtomic, []> { let Unsupported = 1; }
def : WriteRes<WriteBarrier, []> { let Latency = 1; }
def : WriteRes<WriteHint, []> { let Latency = 1; }
//===----------------------------------------------------------------------===//
// Define generic 0 micro-op types
let Latency = 0, NumMicroOps = 0 in
def V1Write_0c_0Z : SchedWriteRes<[]>;
//===----------------------------------------------------------------------===//
// Define generic 1 micro-op types
def V1Write_1c_1B : SchedWriteRes<[V1UnitB]> { let Latency = 1; }
def V1Write_1c_1I : SchedWriteRes<[V1UnitI]> { let Latency = 1; }
def V1Write_1c_1J : SchedWriteRes<[V1UnitJ]> { let Latency = 1; }
def V1Write_4c_1L : SchedWriteRes<[V1UnitL]> { let Latency = 4; }
def V1Write_6c_1L : SchedWriteRes<[V1UnitL]> { let Latency = 6; }
def V1Write_1c_1L01 : SchedWriteRes<[V1UnitL01]> { let Latency = 1; }
def V1Write_4c_1L01 : SchedWriteRes<[V1UnitL01]> { let Latency = 4; }
def V1Write_6c_1L01 : SchedWriteRes<[V1UnitL01]> { let Latency = 6; }
def V1Write_2c_1M : SchedWriteRes<[V1UnitM]> { let Latency = 2; }
def V1Write_3c_1M : SchedWriteRes<[V1UnitM]> { let Latency = 3; }
def V1Write_4c_1M : SchedWriteRes<[V1UnitM]> { let Latency = 4; }
def V1Write_1c_1M0 : SchedWriteRes<[V1UnitM0]> { let Latency = 1; }
def V1Write_2c_1M0 : SchedWriteRes<[V1UnitM0]> { let Latency = 2; }
def V1Write_3c_1M0 : SchedWriteRes<[V1UnitM0]> { let Latency = 3; }
def V1Write_5c_1M0 : SchedWriteRes<[V1UnitM0]> { let Latency = 5; }
def V1Write_12c5_1M0 : SchedWriteRes<[V1UnitM0]> { let Latency = 12;
let ReleaseAtCycles = [5]; }
def V1Write_20c5_1M0 : SchedWriteRes<[V1UnitM0]> { let Latency = 20;
let ReleaseAtCycles = [5]; }
def V1Write_2c_1V : SchedWriteRes<[V1UnitV]> { let Latency = 2; }
def V1Write_3c_1V : SchedWriteRes<[V1UnitV]> { let Latency = 3; }
def V1Write_4c_1V : SchedWriteRes<[V1UnitV]> { let Latency = 4; }
def V1Write_5c_1V : SchedWriteRes<[V1UnitV]> { let Latency = 5; }
def V1Write_2c_1V0 : SchedWriteRes<[V1UnitV0]> { let Latency = 2; }
def V1Write_3c_1V0 : SchedWriteRes<[V1UnitV0]> { let Latency = 3; }
def V1Write_4c_1V0 : SchedWriteRes<[V1UnitV0]> { let Latency = 4; }
def V1Write_6c_1V0 : SchedWriteRes<[V1UnitV0]> { let Latency = 6; }
def V1Write_10c7_1V0 : SchedWriteRes<[V1UnitV0]> { let Latency = 10;
let ReleaseAtCycles = [7]; }
def V1Write_12c7_1V0 : SchedWriteRes<[V1UnitV0]> { let Latency = 12;
let ReleaseAtCycles = [7]; }
def V1Write_13c10_1V0 : SchedWriteRes<[V1UnitV0]> { let Latency = 13;
let ReleaseAtCycles = [10]; }
def V1Write_15c7_1V0 : SchedWriteRes<[V1UnitV0]> { let Latency = 15;
let ReleaseAtCycles = [7]; }
def V1Write_16c7_1V0 : SchedWriteRes<[V1UnitV0]> { let Latency = 16;
let ReleaseAtCycles = [7]; }
def V1Write_20c7_1V0 : SchedWriteRes<[V1UnitV0]> { let Latency = 20;
let ReleaseAtCycles = [7]; }
def V1Write_2c_1V01 : SchedWriteRes<[V1UnitV01]> { let Latency = 2; }
def V1Write_3c_1V01 : SchedWriteRes<[V1UnitV01]> { let Latency = 3; }
def V1Write_4c_1V01 : SchedWriteRes<[V1UnitV01]> { let Latency = 4; }
def V1Write_5c_1V01 : SchedWriteRes<[V1UnitV01]> { let Latency = 5; }
def V1Write_3c_1V02 : SchedWriteRes<[V1UnitV02]> { let Latency = 3; }
def V1Write_4c_1V02 : SchedWriteRes<[V1UnitV02]> { let Latency = 4; }
def V1Write_7c7_1V02 : SchedWriteRes<[V1UnitV02]> { let Latency = 7;
let ReleaseAtCycles = [7]; }
def V1Write_10c7_1V02 : SchedWriteRes<[V1UnitV02]> { let Latency = 10;
let ReleaseAtCycles = [7]; }
def V1Write_13c5_1V02 : SchedWriteRes<[V1UnitV02]> { let Latency = 13;
let ReleaseAtCycles = [5]; }
def V1Write_13c11_1V02 : SchedWriteRes<[V1UnitV02]> { let Latency = 13;
let ReleaseAtCycles = [11]; }
def V1Write_15c7_1V02 : SchedWriteRes<[V1UnitV02]> { let Latency = 15;
let ReleaseAtCycles = [7]; }
def V1Write_16c7_1V02 : SchedWriteRes<[V1UnitV02]> { let Latency = 16;
let ReleaseAtCycles = [7]; }
def V1Write_2c_1V1 : SchedWriteRes<[V1UnitV1]> { let Latency = 2; }
def V1Write_3c_1V1 : SchedWriteRes<[V1UnitV1]> { let Latency = 3; }
def V1Write_4c_1V1 : SchedWriteRes<[V1UnitV1]> { let Latency = 4; }
def V1Write_2c_1V13 : SchedWriteRes<[V1UnitV13]> { let Latency = 2; }
def V1Write_4c_1V13 : SchedWriteRes<[V1UnitV13]> { let Latency = 4; }
//===----------------------------------------------------------------------===//
// Define generic 2 micro-op types
let Latency = 1, NumMicroOps = 2 in
def V1Write_1c_1B_1S : SchedWriteRes<[V1UnitB, V1UnitS]>;
let Latency = 6, NumMicroOps = 2 in
def V1Write_6c_1B_1M0 : SchedWriteRes<[V1UnitB, V1UnitM0]>;
let Latency = 3, NumMicroOps = 2 in
def V1Write_3c_1I_1M : SchedWriteRes<[V1UnitI, V1UnitM]>;
let Latency = 5, NumMicroOps = 2 in
def V1Write_5c_1I_1L : SchedWriteRes<[V1UnitI, V1UnitL]>;
let Latency = 7, NumMicroOps = 2 in
def V1Write_7c_1I_1L : SchedWriteRes<[V1UnitI, V1UnitL]>;
let Latency = 6, NumMicroOps = 2 in
def V1Write_6c_2L : SchedWriteRes<[V1UnitL, V1UnitL]>;
let Latency = 6, NumMicroOps = 2 in
def V1Write_6c_1L_1M : SchedWriteRes<[V1UnitL, V1UnitM]>;
let Latency = 8, NumMicroOps = 2 in
def V1Write_8c_1L_1V : SchedWriteRes<[V1UnitL, V1UnitV]>;
let Latency = 9, NumMicroOps = 2 in
def V1Write_9c_1L_1V : SchedWriteRes<[V1UnitL, V1UnitV]>;
let Latency = 11, NumMicroOps = 2 in
def V1Write_11c_1L_1V : SchedWriteRes<[V1UnitL, V1UnitV]>;
let Latency = 1, NumMicroOps = 2 in
def V1Write_1c_1L01_1D : SchedWriteRes<[V1UnitL01, V1UnitD]>;
let Latency = 6, NumMicroOps = 2 in
def V1Write_6c_1L01_1S : SchedWriteRes<[V1UnitL01, V1UnitS]>;
let Latency = 7, NumMicroOps = 2 in
def V1Write_7c_1L01_1S : SchedWriteRes<[V1UnitL01, V1UnitS]>;
let Latency = 2, NumMicroOps = 2 in
def V1Write_2c_1L01_1V : SchedWriteRes<[V1UnitL01, V1UnitV]>;
let Latency = 4, NumMicroOps = 2 in
def V1Write_4c_1L01_1V : SchedWriteRes<[V1UnitL01, V1UnitV]>;
let Latency = 6, NumMicroOps = 2 in
def V1Write_6c_1L01_1V : SchedWriteRes<[V1UnitL01, V1UnitV]>;
let Latency = 2, NumMicroOps = 2 in
def V1Write_2c_1L01_1V01 : SchedWriteRes<[V1UnitL01, V1UnitV01]>;
let Latency = 4, NumMicroOps = 2 in
def V1Write_4c_1L01_1V01 : SchedWriteRes<[V1UnitL01, V1UnitV01]>;
let Latency = 2, NumMicroOps = 2 in
def V1Write_2c_2M0 : SchedWriteRes<[V1UnitM0, V1UnitM0]>;
let Latency = 3, NumMicroOps = 2 in
def V1Write_3c_2M0 : SchedWriteRes<[V1UnitM0, V1UnitM0]>;
let Latency = 9, NumMicroOps = 2 in
def V1Write_9c_1M0_1L : SchedWriteRes<[V1UnitM0, V1UnitL]>;
let Latency = 5, NumMicroOps = 2 in
def V1Write_5c_1M0_1V : SchedWriteRes<[V1UnitM0, V1UnitV]>;
let Latency = 4, NumMicroOps = 2 in
def V1Write_4c_1M0_1V0 : SchedWriteRes<[V1UnitM0, V1UnitV0]>;
let Latency = 7, NumMicroOps = 2 in
def V1Write_7c_1M0_1V0 : SchedWriteRes<[V1UnitM0, V1UnitV1]>;
let Latency = 5, NumMicroOps = 2 in
def V1Write_5c_1M0_1V01 : SchedWriteRes<[V1UnitM0, V1UnitV01]>;
let Latency = 6, NumMicroOps = 2 in
def V1Write_6c_1M0_1V1 : SchedWriteRes<[V1UnitM0, V1UnitV1]>;
let Latency = 9, NumMicroOps = 2 in
def V1Write_9c_1M0_1V1 : SchedWriteRes<[V1UnitM0, V1UnitV1]>;
let Latency = 4, NumMicroOps = 2 in
def V1Write_4c_2V : SchedWriteRes<[V1UnitV, V1UnitV]>;
let Latency = 8, NumMicroOps = 2 in
def V1Write_8c_1V_1V01 : SchedWriteRes<[V1UnitV, V1UnitV01]>;
let Latency = 4, NumMicroOps = 2 in
def V1Write_4c_2V0 : SchedWriteRes<[V1UnitV0, V1UnitV0]>;
let Latency = 5, NumMicroOps = 2 in
def V1Write_5c_2V0 : SchedWriteRes<[V1UnitV0, V1UnitV0]>;
let Latency = 2, NumMicroOps = 2 in
def V1Write_2c_2V01 : SchedWriteRes<[V1UnitV01, V1UnitV01]>;
let Latency = 4, NumMicroOps = 2 in
def V1Write_4c_2V01 : SchedWriteRes<[V1UnitV01, V1UnitV01]>;
let Latency = 4, NumMicroOps = 2 in
def V1Write_4c_2V02 : SchedWriteRes<[V1UnitV02, V1UnitV02]>;
let Latency = 6, NumMicroOps = 2 in
def V1Write_6c_2V02 : SchedWriteRes<[V1UnitV02, V1UnitV02]>;
let Latency = 4, NumMicroOps = 2 in
def V1Write_4c_1V13_1V : SchedWriteRes<[V1UnitV13, V1UnitV]>;
let Latency = 4, NumMicroOps = 2 in
def V1Write_4c_2V13 : SchedWriteRes<[V1UnitV13, V1UnitV13]>;
//===----------------------------------------------------------------------===//
// Define generic 3 micro-op types
let Latency = 2, NumMicroOps = 3 in
def V1Write_2c_1I_1L01_1V01 : SchedWriteRes<[V1UnitI, V1UnitL01, V1UnitV01]>;
let Latency = 7, NumMicroOps = 3 in
def V1Write_7c_2M0_1V01 : SchedWriteRes<[V1UnitM0, V1UnitM0, V1UnitV01]>;
let Latency = 8, NumMicroOps = 3 in
def V1Write_8c_1L_2V : SchedWriteRes<[V1UnitL, V1UnitV, V1UnitV]>;
let Latency = 6, NumMicroOps = 3 in
def V1Write_6c_3L : SchedWriteRes<[V1UnitL, V1UnitL, V1UnitL]>;
let Latency = 2, NumMicroOps = 3 in
def V1Write_2c_1L01_1S_1V : SchedWriteRes<[V1UnitL01, V1UnitS, V1UnitV]>;
let Latency = 4, NumMicroOps = 3 in
def V1Write_4c_1L01_1S_1V : SchedWriteRes<[V1UnitL01, V1UnitS, V1UnitV]>;
let Latency = 2, NumMicroOps = 3 in
def V1Write_2c_2L01_1V01 : SchedWriteRes<[V1UnitL01, V1UnitL01, V1UnitV01]>;
let Latency = 6, NumMicroOps = 3 in
def V1Write_6c_3V : SchedWriteRes<[V1UnitV, V1UnitV, V1UnitV]>;
let Latency = 4, NumMicroOps = 3 in
def V1Write_4c_3V01 : SchedWriteRes<[V1UnitV01, V1UnitV01, V1UnitV01]>;
let Latency = 6, NumMicroOps = 3 in
def V1Write_6c_3V01 : SchedWriteRes<[V1UnitV01, V1UnitV01, V1UnitV01]>;
let Latency = 8, NumMicroOps = 3 in
def V1Write_8c_3V01 : SchedWriteRes<[V1UnitV01, V1UnitV01, V1UnitV01]>;
//===----------------------------------------------------------------------===//
// Define generic 4 micro-op types
let Latency = 8, NumMicroOps = 4 in
def V1Write_8c_2M0_2V0 : SchedWriteRes<[V1UnitM0, V1UnitM0,
V1UnitV0, V1UnitV0]>;
let Latency = 7, NumMicroOps = 4 in
def V1Write_7c_4L : SchedWriteRes<[V1UnitL, V1UnitL, V1UnitL, V1UnitL]>;
let Latency = 8, NumMicroOps = 4 in
def V1Write_8c_2L_2V : SchedWriteRes<[V1UnitL, V1UnitL,
V1UnitV, V1UnitV]>;
let Latency = 9, NumMicroOps = 4 in
def V1Write_9c_2L_2V : SchedWriteRes<[V1UnitL, V1UnitL,
V1UnitV, V1UnitV]>;
let Latency = 11, NumMicroOps = 4 in
def V1Write_11c_2L_2V : SchedWriteRes<[V1UnitL, V1UnitL,
V1UnitV, V1UnitV]>;
let Latency = 10, NumMicroOps = 4 in
def V1Write_10c_2L01_2V : SchedWriteRes<[V1UnitL01, V1UnitL01,
V1UnitV, V1UnitV]>;
let Latency = 2, NumMicroOps = 4 in
def V1Write_2c_2L01_2V01 : SchedWriteRes<[V1UnitL01, V1UnitL01,
V1UnitV01, V1UnitV01]>;
let Latency = 4, NumMicroOps = 4 in
def V1Write_4c_2L01_2V01 : SchedWriteRes<[V1UnitL01, V1UnitL01,
V1UnitV01, V1UnitV01]>;
let Latency = 8, NumMicroOps = 4 in
def V1Write_8c_2L01_2V01 : SchedWriteRes<[V1UnitL01, V1UnitL01,
V1UnitV01, V1UnitV01]>;
let Latency = 9, NumMicroOps = 4 in
def V1Write_9c_2L01_2V01 : SchedWriteRes<[V1UnitL01, V1UnitL01,
V1UnitV01, V1UnitV01]>;
let Latency = 10, NumMicroOps = 4 in
def V1Write_10c_2L01_2V01 : SchedWriteRes<[V1UnitL01, V1UnitL01,
V1UnitV01, V1UnitV01]>;
let Latency = 10, NumMicroOps = 4 in
def V1Write_10c_1V_1V01_2V1 : SchedWriteRes<[V1UnitV, V1UnitV01,
V1UnitV1, V1UnitV1]>;
let Latency = 12, NumMicroOps = 4 in
def V1Write_12c_1V_1V01_2V1 : SchedWriteRes<[V1UnitV, V1UnitV01,
V1UnitV1, V1UnitV1]>;
let Latency = 6, NumMicroOps = 4 in
def V1Write_6c_4V0 : SchedWriteRes<[V1UnitV0, V1UnitV0,
V1UnitV0, V1UnitV0]>;
let Latency = 12, NumMicroOps = 4 in
def V1Write_12c_4V01 : SchedWriteRes<[V1UnitV01, V1UnitV01,
V1UnitV01, V1UnitV01]>;
let Latency = 6, NumMicroOps = 4 in
def V1Write_6c_4V02 : SchedWriteRes<[V1UnitV02, V1UnitV02]>;
//===----------------------------------------------------------------------===//
// Define generic 5 micro-op types
let Latency = 8, NumMicroOps = 5 in
def V1Write_8c_2L_3V : SchedWriteRes<[V1UnitL, V1UnitL,
V1UnitV, V1UnitV, V1UnitV]>;
let Latency = 14, NumMicroOps = 5 in
def V1Write_14c_1V_1V0_2V1_1V13 : SchedWriteRes<[V1UnitV,
V1UnitV0,
V1UnitV1, V1UnitV1,
V1UnitV13]>;
let Latency = 9, NumMicroOps = 5 in
def V1Write_9c_1V_4V01 : SchedWriteRes<[V1UnitV,
V1UnitV01, V1UnitV01,
V1UnitV01, V1UnitV01]>;
let Latency = 6, NumMicroOps = 5 in
def V1Write_6c_5V01 : SchedWriteRes<[V1UnitV01, V1UnitV01,
V1UnitV01, V1UnitV01, V1UnitV01]>;
//===----------------------------------------------------------------------===//
// Define generic 6 micro-op types
let Latency = 6, NumMicroOps = 6 in
def V1Write_6c_3L_3V : SchedWriteRes<[V1UnitL, V1UnitL, V1UnitL,
V1UnitV, V1UnitV, V1UnitV]>;
let Latency = 8, NumMicroOps = 6 in
def V1Write_8c_3L_3V : SchedWriteRes<[V1UnitL, V1UnitL, V1UnitL,
V1UnitV, V1UnitV, V1UnitV]>;
let Latency = 2, NumMicroOps = 6 in
def V1Write_2c_3L01_3V01 : SchedWriteRes<[V1UnitL01, V1UnitL01, V1UnitL01,
V1UnitV01, V1UnitV01, V1UnitV01]>;
let Latency = 5, NumMicroOps = 6 in
def V1Write_5c_3L01_3V01 : SchedWriteRes<[V1UnitL01, V1UnitL01, V1UnitL01,
V1UnitV01, V1UnitV01, V1UnitV01]>;
let Latency = 6, NumMicroOps = 6 in
def V1Write_6c_3L01_3V01 : SchedWriteRes<[V1UnitL01, V1UnitL01, V1UnitL01,
V1UnitV01, V1UnitV01, V1UnitV01]>;
let Latency = 11, NumMicroOps = 6 in
def V1Write_11c_3L01_3V01 : SchedWriteRes<[V1UnitL01, V1UnitL01, V1UnitL01,
V1UnitV01, V1UnitV01, V1UnitV01]>;
let Latency = 11, NumMicroOps = 6 in
def V1Write_11c_1V_5V01 : SchedWriteRes<[V1UnitV,
V1UnitV01, V1UnitV01,
V1UnitV01, V1UnitV01, V1UnitV01]>;
let Latency = 13, NumMicroOps = 6 in
def V1Write_13c_6V01 : SchedWriteRes<[V1UnitV01, V1UnitV01, V1UnitV01,
V1UnitV01, V1UnitV01, V1UnitV01]>;
//===----------------------------------------------------------------------===//
// Define generic 7 micro-op types
let Latency = 8, NumMicroOps = 7 in
def V1Write_8c_3L_4V : SchedWriteRes<[V1UnitL, V1UnitL, V1UnitL,
V1UnitV, V1UnitV, V1UnitV, V1UnitV]>;
let Latency = 8, NumMicroOps = 7 in
def V1Write_13c_3L01_1S_3V01 : SchedWriteRes<[V1UnitL01, V1UnitL01, V1UnitL01,
V1UnitS,
V1UnitV01, V1UnitV01, V1UnitV01]>;
//===----------------------------------------------------------------------===//
// Define generic 8 micro-op types
let Latency = 9, NumMicroOps = 8 in
def V1Write_9c_4L_4V : SchedWriteRes<[V1UnitL, V1UnitL,
V1UnitL, V1UnitL,
V1UnitV, V1UnitV,
V1UnitV, V1UnitV]>;
let Latency = 2, NumMicroOps = 8 in
def V1Write_2c_4L01_4V01 : SchedWriteRes<[V1UnitL01, V1UnitL01,
V1UnitL01, V1UnitL01,
V1UnitV01, V1UnitV01,
V1UnitV01, V1UnitV01]>;
let Latency = 4, NumMicroOps = 8 in
def V1Write_4c_4L01_4V01 : SchedWriteRes<[V1UnitL01, V1UnitL01,
V1UnitL01, V1UnitL01,
V1UnitV01, V1UnitV01,
V1UnitV01, V1UnitV01]>;
let Latency = 12, NumMicroOps = 8 in
def V1Write_12c_4L01_4V01 : SchedWriteRes<[V1UnitL01, V1UnitL01,
V1UnitL01, V1UnitL01,
V1UnitV01, V1UnitV01,
V1UnitV01, V1UnitV01]>;
//===----------------------------------------------------------------------===//
// Define generic 10 micro-op types
let Latency = 13, NumMicroOps = 10 in
def V1Write_13c_4L01_2S_4V01 : SchedWriteRes<[V1UnitL01, V1UnitL01,
V1UnitL01, V1UnitL01,
V1UnitS, V1UnitS,
V1UnitV01, V1UnitV01,
V1UnitV01, V1UnitV01]>;
let Latency = 7, NumMicroOps = 10 in
def V1Write_7c_5L01_5V : SchedWriteRes<[V1UnitL01, V1UnitL01,
V1UnitL01, V1UnitL01, V1UnitL01,
V1UnitV, V1UnitV,
V1UnitV, V1UnitV, V1UnitV]>;
let Latency = 11, NumMicroOps = 10 in
def V1Write_11c_10V0 : SchedWriteRes<[V1UnitV0,
V1UnitV0, V1UnitV0, V1UnitV0,
V1UnitV0, V1UnitV0, V1UnitV0,
V1UnitV0, V1UnitV0, V1UnitV0]>;
//===----------------------------------------------------------------------===//
// Define generic 12 micro-op types
let Latency = 7, NumMicroOps = 12 in
def V1Write_7c_6L01_6V01 : SchedWriteRes<[V1UnitL01, V1UnitL01, V1UnitL01,
V1UnitL01, V1UnitL01, V1UnitL01,
V1UnitV01, V1UnitV01, V1UnitV01,
V1UnitV01, V1UnitV01, V1UnitV01]>;
//===----------------------------------------------------------------------===//
// Define generic 15 micro-op types
let Latency = 7, NumMicroOps = 15 in
def V1Write_7c_5L01_5S_5V : SchedWriteRes<[V1UnitL01, V1UnitL01,
V1UnitL01, V1UnitL01, V1UnitL01,
V1UnitS, V1UnitS,
V1UnitS, V1UnitS, V1UnitS,
V1UnitV, V1UnitV,
V1UnitV, V1UnitV, V1UnitV]>;
//===----------------------------------------------------------------------===//
// Define generic 18 micro-op types
let Latency = 19, NumMicroOps = 18 in
def V1Write_11c_9L01_9V : SchedWriteRes<[V1UnitL01, V1UnitL01, V1UnitL01,
V1UnitL01, V1UnitL01, V1UnitL01,
V1UnitL01, V1UnitL01, V1UnitL01,
V1UnitV, V1UnitV, V1UnitV,
V1UnitV, V1UnitV, V1UnitV,
V1UnitV, V1UnitV, V1UnitV]>;
let Latency = 19, NumMicroOps = 18 in
def V1Write_19c_18V0 : SchedWriteRes<[V1UnitV0, V1UnitV0, V1UnitV0,
V1UnitV0, V1UnitV0, V1UnitV0,
V1UnitV0, V1UnitV0, V1UnitV0,
V1UnitV0, V1UnitV0, V1UnitV0,
V1UnitV0, V1UnitV0, V1UnitV0,
V1UnitV0, V1UnitV0, V1UnitV0]>;
//===----------------------------------------------------------------------===//
// Define generic 27 micro-op types
let Latency = 11, NumMicroOps = 27 in
def V1Write_11c_9L01_9S_9V : SchedWriteRes<[V1UnitL01, V1UnitL01, V1UnitL01,
V1UnitL01, V1UnitL01, V1UnitL01,
V1UnitL01, V1UnitL01, V1UnitL01,
V1UnitS, V1UnitS, V1UnitS,
V1UnitS, V1UnitS, V1UnitS,
V1UnitS, V1UnitS, V1UnitS,
V1UnitV, V1UnitV, V1UnitV,
V1UnitV, V1UnitV, V1UnitV,
V1UnitV, V1UnitV, V1UnitV]>;
// Miscellaneous Instructions
// -----------------------------------------------------------------------------
// COPY
def : InstRW<[V1Write_1c_1I], (instrs COPY)>;
// MSR
def : WriteRes<WriteSys, []> { let Latency = 1; }
// Branch Instructions
// -----------------------------------------------------------------------------
// Branch, immed
// Compare and branch
def : SchedAlias<WriteBr, V1Write_1c_1B>;
// Branch, register
def : SchedAlias<WriteBrReg, V1Write_1c_1B>;
// Branch and link, immed
// Branch and link, register
def : InstRW<[V1Write_1c_1B_1S], (instrs BL, BLR)>;
// Compare and branch
def : InstRW<[V1Write_1c_1B], (instregex "^[CT]BN?Z[XW]$")>;
// Arithmetic and Logical Instructions
// -----------------------------------------------------------------------------
// ALU, basic
// Conditional compare
// Conditional select
// Logical, basic
// Address generation
// Count leading
// Reverse bits/bytes
// Move immediate
def : SchedAlias<WriteI, V1Write_1c_1I>;
// ALU, basic, flagset
def : InstRW<[V1Write_1c_1J],
(instregex "^(ADD|SUB)S[WX]r[ir]$",
"^(ADC|SBC)S[WX]r$",
"^ANDS[WX]ri$",
"^(AND|BIC)S[WX]rr$")>;
// ALU, extend and shift
def : SchedAlias<WriteIEReg, V1Write_2c_1M>;
// Arithmetic, LSL shift, shift <= 4
// Arithmetic, LSR/ASR/ROR shift or LSL shift > 4
def V1WriteISReg : SchedWriteVariant<
[SchedVar<IsCheapLSL, [V1Write_1c_1I]>,
SchedVar<NoSchedPred, [V1Write_2c_1M]>]>;
def : SchedAlias<WriteISReg, V1WriteISReg>;
// Arithmetic, flagset, LSL shift, shift <= 4
// Arithmetic, flagset, LSR/ASR/ROR shift or LSL shift > 4
def V1WriteISRegS : SchedWriteVariant<
[SchedVar<IsCheapLSL, [V1Write_1c_1J]>,
SchedVar<NoSchedPred, [V1Write_2c_1M]>]>;
def : InstRW<[V1WriteISRegS],
(instregex "^(ADD|SUB)S(([WX]r[sx])|Xrx64)$")>;
// Logical, shift, no flagset
def : InstRW<[V1Write_1c_1I], (instregex "^(AND|BIC|EON|EOR|ORN|ORR)[WX]rs$")>;
// Logical, shift, flagset
def : InstRW<[V1Write_2c_1M], (instregex "^(AND|BIC)S[WX]rs$")>;
// Flag manipulation instructions
def : InstRW<[V1Write_1c_1J], (instrs SETF8, SETF16, RMIF, CFINV)>;
// Divide and multiply instructions
// -----------------------------------------------------------------------------
// Divide
def : SchedAlias<WriteID32, V1Write_12c5_1M0>;
def : SchedAlias<WriteID64, V1Write_20c5_1M0>;
// Multiply
// Multiply accumulate
// Multiply accumulate, long
// Multiply long
def V1WriteIM : SchedWriteVariant<
[SchedVar<NeoverseMULIdiomPred, [V1Write_2c_1M]>,
SchedVar<NoSchedPred, [V1Write_2c_1M0]>]>;
def : SchedAlias<WriteIM32, V1WriteIM>;
def : SchedAlias<WriteIM64, V1WriteIM>;
// Multiply high
def : InstRW<[V1Write_3c_1M, ReadIM, ReadIM], (instrs SMULHrr, UMULHrr)>;
// 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<[V1Write_5c_1M0], (instregex "^AUT",
"^PAC")>;
// Branch and link, register, with pointer authentication
// Branch, register, with pointer authentication
// Branch, return, with pointer authentication
def : InstRW<[V1Write_6c_1B_1M0], (instregex "^BL?RA[AB]Z?$",
"^E?RETA[AB]$")>;
// Load register, with pointer authentication
def : InstRW<[V1Write_9c_1M0_1L], (instregex "^LDRA[AB](indexed|writeback)")>;
// Strip pointer authentication code
def : InstRW<[V1Write_2c_1M0], (instrs XPACD, XPACI, XPACLRI)>;
// Miscellaneous data-processing instructions
// -----------------------------------------------------------------------------
// Bitfield extract, one reg
// Bitfield extract, two regs
def V1WriteExtr : SchedWriteVariant<
[SchedVar<IsRORImmIdiomPred, [V1Write_1c_1I]>,
SchedVar<NoSchedPred, [V1Write_3c_1I_1M]>]>;
def : SchedAlias<WriteExtr, V1WriteExtr>;
// Bitfield move, basic
// Variable shift
def : SchedAlias<WriteIS, V1Write_1c_1I>;
// Bitfield move, insert
def : InstRW<[V1Write_2c_1M], (instregex "^BFM[WX]ri$")>;
// Move immediate
def : SchedAlias<WriteImm, V1Write_1c_1I>;
// Load instructions
// -----------------------------------------------------------------------------
// Load register, immed offset
def : SchedAlias<WriteLD, V1Write_4c_1L>;
// Load register, immed offset, index
def : SchedAlias<WriteLDIdx, V1Write_4c_1L>;
def : SchedAlias<WriteAdr, V1Write_1c_1I>;
// Load pair, immed offset
def : SchedAlias<WriteLDHi, V1Write_4c_1L>;
def : InstRW<[V1Write_4c_1L, V1Write_0c_0Z], (instrs LDPWi, LDNPWi)>;
def : InstRW<[WriteAdr, V1Write_4c_1L, V1Write_0c_0Z],
(instrs LDPWpost, LDPWpre)>;
// Load pair, signed immed offset, signed words
def : InstRW<[V1Write_5c_1I_1L, V1Write_0c_0Z], (instrs LDPSWi)>;
// Load pair, immed post or pre-index, signed words
def : InstRW<[WriteAdr, V1Write_5c_1I_1L, V1Write_0c_0Z],
(instrs LDPSWpost, LDPSWpre)>;
// Store instructions
// -----------------------------------------------------------------------------
// Store register, immed offset
def : SchedAlias<WriteST, V1Write_1c_1L01_1D>;
// Store register, immed offset, index
def : SchedAlias<WriteSTIdx, V1Write_1c_1L01_1D>;
// Store pair, immed offset
def : SchedAlias<WriteSTP, V1Write_1c_1L01_1D>;
// FP data processing instructions
// -----------------------------------------------------------------------------
// FP absolute value
// FP arithmetic
// FP min/max
// FP negate
def : SchedAlias<WriteF, V1Write_2c_1V>;
// FP compare
def : SchedAlias<WriteFCmp, V1Write_2c_1V0>;
// FP divide
// FP square root
def : SchedAlias<WriteFDiv, V1Write_10c7_1V02>;
// FP divide, H-form
// FP square root, H-form
def : InstRW<[V1Write_7c7_1V02], (instrs FDIVHrr, FSQRTHr)>;
// FP divide, S-form
// FP square root, S-form
def : InstRW<[V1Write_10c7_1V02], (instrs FDIVSrr, FSQRTSr)>;
// FP divide, D-form
def : InstRW<[V1Write_15c7_1V02], (instrs FDIVDrr)>;
// FP square root, D-form
def : InstRW<[V1Write_16c7_1V02], (instrs FSQRTDr)>;
// FP multiply
def : SchedAlias<WriteFMul, V1Write_3c_1V>;
// FP multiply accumulate
def : InstRW<[V1Write_4c_1V], (instregex "^FN?M(ADD|SUB)[HSD]rrr$")>;
// FP round to integral
def : InstRW<[V1Write_3c_1V02], (instregex "^FRINT[AIMNPXZ][HSD]r$",
"^FRINT(32|64)[XZ][SD]r$")>;
// FP select
def : InstRW<[V1Write_2c_1V01], (instregex "^FCSEL[HSD]rrr$")>;
// FP miscellaneous instructions
// -----------------------------------------------------------------------------
// FP convert, from gen to vec reg
def : InstRW<[V1Write_3c_1M0], (instregex "^[SU]CVTF[SU][WX][HSD]ri$")>;
// FP convert, from vec to gen reg
def : InstRW<[V1Write_3c_1V0], (instregex "^FCVT[AMNPZ][SU][SU][WX][HSD]r$")>;
// FP convert, Javascript from vec to gen reg
def : InstRW<[V1Write_3c_1V0], (instrs FJCVTZS)>;
// FP convert, from vec to vec reg
def : SchedAlias<WriteFCvt, V1Write_3c_1V02>;
// FP move, immed
def : SchedAlias<WriteFImm, V1Write_2c_1V>;
// FP move, register
def : InstRW<[V1Write_2c_1V], (instrs FMOVHr, FMOVSr, FMOVDr)>;
// FP transfer, from gen to low half of vec reg
def : InstRW<[V1Write_3c_1M0], (instrs FMOVWHr, FMOVXHr, FMOVWSr, FMOVXDr)>;
// FP transfer, from gen to high half of vec reg
def : InstRW<[V1Write_5c_1M0_1V], (instrs FMOVXDHighr)>;
// FP transfer, from vec to gen reg
def : SchedAlias<WriteFCopy, V1Write_2c_1V1>;
// FP load instructions
// -----------------------------------------------------------------------------
// Load vector reg, literal, S/D/Q forms
// Load vector reg, unscaled immed
// Load vector reg, unsigned immed
def : InstRW<[V1Write_6c_1L, ReadAdrBase], (instregex "^LDR[SDQ]l$",
"^LDUR[BHSDQ]i$",
"^LDR[BHSDQ]ui$")>;
// Load vector reg, immed post-index
// Load vector reg, immed pre-index
def : InstRW<[WriteAdr, V1Write_6c_1L],
(instregex "^LDR[BHSDQ](post|pre)$")>;
// Load vector reg, register offset, basic
// Load vector reg, register offset, scale, S/D-form
// Load vector reg, register offset, extend
// Load vector reg, register offset, extend, scale, S/D-form
def : InstRW<[V1Write_6c_1L, ReadAdrBase], (instregex "^LDR[BSD]ro[WX]$")>;
// Load vector reg, register offset, scale, H/Q-form
// Load vector reg, register offset, extend, scale, H/Q-form
def : InstRW<[V1Write_7c_1I_1L, ReadAdrBase], (instregex "^LDR[HQ]ro[WX]$")>;
// Load vector pair, immed offset, S/D-form
def : InstRW<[V1Write_6c_1L, V1Write_0c_0Z], (instregex "^LDN?P[SD]i$")>;
// Load vector pair, immed offset, Q-form
def : InstRW<[V1Write_6c_1L, WriteLDHi], (instrs LDPQi, LDNPQi)>;
// Load vector pair, immed post-index, S/D-form
// Load vector pair, immed pre-index, S/D-form
def : InstRW<[WriteAdr, V1Write_6c_1L, V1Write_0c_0Z],
(instregex "^LDP[SD](pre|post)$")>;
// Load vector pair, immed post-index, Q-form
// Load vector pair, immed pre-index, Q-form
def : InstRW<[WriteAdr, V1Write_6c_1L, WriteLDHi],
(instrs LDPQpost, LDPQpre)>;
// FP store instructions
// -----------------------------------------------------------------------------
// Store vector reg, unscaled immed, B/H/S/D/Q-form
def : InstRW<[V1Write_2c_1L01_1V01], (instregex "^STUR[BHSDQ]i$")>;
// Store vector reg, immed post-index, B/H/S/D/Q-form
// Store vector reg, immed pre-index, B/H/S/D/Q-form
def : InstRW<[WriteAdr, V1Write_2c_1L01_1V01],
(instregex "^STR[BHSDQ](pre|post)$")>;
// Store vector reg, unsigned immed, B/H/S/D/Q-form
def : InstRW<[V1Write_2c_1L01_1V01], (instregex "^STR[BHSDQ]ui$")>;
// Store vector reg, register offset, basic, B/S/D-form
// Store vector reg, register offset, scale, B/S/D-form
// Store vector reg, register offset, extend, B/S/D-form
// Store vector reg, register offset, extend, scale, B/S/D-form
def : InstRW<[V1Write_2c_1L01_1V01, ReadAdrBase],
(instregex "^STR[BSD]ro[WX]$")>;
// Store vector reg, register offset, basic, H/Q-form
// Store vector reg, register offset, scale, H/Q-form
// Store vector reg, register offset, extend, H/Q-form
// Store vector reg, register offset, extend, scale, H/Q-form
def : InstRW<[V1Write_2c_1I_1L01_1V01, ReadAdrBase],
(instregex "^STR[HQ]ro[WX]$")>;
// Store vector pair, immed offset, S/D/Q-form
def : InstRW<[V1Write_2c_1L01_1V01], (instregex "^STN?P[SDQ]i$")>;
// Store vector pair, immed post-index, S/D-form
// Store vector pair, immed pre-index, S/D-form
def : InstRW<[WriteAdr, V1Write_2c_1L01_1V01],
(instregex "^STP[SD](pre|post)$")>;
// Store vector pair, immed post-index, Q-form
// Store vector pair, immed pre-index, Q-form
def : InstRW<[WriteAdr, V1Write_2c_2L01_1V01], (instrs STPQpre, STPQpost)>;
// ASIMD integer instructions
// -----------------------------------------------------------------------------
// ASIMD absolute diff
// ASIMD absolute diff long
// ASIMD arith, basic
// ASIMD arith, complex
// ASIMD arith, pair-wise
// ASIMD compare
// ASIMD logical
// ASIMD max/min, basic and pair-wise
def : SchedAlias<WriteVd, V1Write_2c_1V>;
def : SchedAlias<WriteVq, V1Write_2c_1V>;
// ASIMD absolute diff accum
// ASIMD absolute diff accum long
// ASIMD pairwise add and accumulate long
def : InstRW<[V1Write_4c_1V13], (instregex "^[SU]ABAL?v", "^[SU]ADALPv")>;
// ASIMD arith, reduce, 4H/4S
// ASIMD max/min, reduce, 4H/4S
def : InstRW<[V1Write_2c_1V13], (instregex "^(ADD|[SU]ADDL)Vv4(i16|i32)v$",
"^[SU](MAX|MIN)Vv4(i16|i32)v$")>;
// ASIMD arith, reduce, 8B/8H
// ASIMD max/min, reduce, 8B/8H
def : InstRW<[V1Write_4c_1V13_1V], (instregex "^(ADD|[SU]ADDL)Vv8(i8|i16)v$",
"^[SU](MAX|MIN)Vv8(i8|i16)v$")>;
// ASIMD arith, reduce, 16B
// ASIMD max/min, reduce, 16B
def : InstRW<[V1Write_4c_2V13], (instregex "^(ADD|[SU]ADDL)Vv16i8v$",
"[SU](MAX|MIN)Vv16i8v$")>;
// ASIMD dot product
// ASIMD dot product using signed and unsigned integers
def : InstRW<[V1Write_2c_1V], (instregex "^([SU]|SU|US)DOT(lane)?v(8|16)i8$")>;
// ASIMD matrix multiply- accumulate
def : InstRW<[V1Write_3c_1V], (instrs SMMLA, UMMLA, USMMLA)>;
// ASIMD multiply
// ASIMD multiply accumulate
// ASIMD multiply accumulate long
// ASIMD multiply accumulate high
// ASIMD multiply accumulate saturating long
def : InstRW<[V1Write_4c_1V02],
(instregex "^MUL(v[148]i16|v[124]i32)$",
"^SQR?DMULH(v[48]i16|v[24]i32)$",
"^ML[AS](v[148]i16|v[124]i32)$",
"^[SU]ML[AS]Lv",
"^SQRDML[AS]H(v[148]i16|v[124]i32)$",
"^SQDML[AS]Lv")>;
// ASIMD multiply/multiply long (8x8) polynomial
def : InstRW<[V1Write_3c_1V01], (instregex "^PMULL?v(8|16)i8$")>;
// ASIMD multiply long
def : InstRW<[V1Write_3c_1V02], (instregex "^([SU]|SQD)MULLv")>;
// ASIMD shift accumulate
// ASIMD shift by immed, complex
// ASIMD shift by register, complex
def : InstRW<[V1Write_4c_1V13],
(instregex "^[SU]R?SRAv",
"^RSHRNv", "^SQRSHRU?Nv", "^(SQSHLU?|UQSHL)[bhsd]$",
"^(SQSHLU?|UQSHL)(v8i8|v16i8|v4i16|v8i16|v2i32|v4i32|v2i64)_shift$",
"^SQSHU?RNv", "^[SU]RSHRv", "^UQR?SHRNv",
"^[SU]Q?RSHLv", "^[SU]QSHLv")>;
// ASIMD shift by immed, basic
// ASIMD shift by immed and insert, basic
// ASIMD shift by register, basic
def : InstRW<[V1Write_2c_1V13], (instregex "^SHLL?v", "^SHRNv", "^[SU]SHLLv",
"^[SU]SHRv", "^S[LR]Iv", "^[SU]SHLv")>;
// ASIMD FP instructions
// -----------------------------------------------------------------------------
// ASIMD FP absolute value/difference
// ASIMD FP arith, normal
// ASIMD FP compare
// ASIMD FP complex add
// ASIMD FP max/min, normal
// ASIMD FP max/min, pairwise
// ASIMD FP negate
// Covered by "SchedAlias (WriteV[dq]...)" above
// ASIMD FP complex multiply add
// ASIMD FP multiply accumulate
def : InstRW<[V1Write_4c_1V], (instregex "^FCADD(v[48]f16|v[24]f32|v2f64)$",
"^FML[AS]v")>;
// ASIMD FP convert, long (F16 to F32)
def : InstRW<[V1Write_4c_2V02], (instregex "^FCVTLv[48]i16$")>;
// ASIMD FP convert, long (F32 to F64)
def : InstRW<[V1Write_3c_1V02], (instregex "^FCVTLv[24]i32$")>;
// ASIMD FP convert, narrow (F32 to F16)
def : InstRW<[V1Write_4c_2V02], (instregex "^FCVTNv[48]i16$")>;
// ASIMD FP convert, narrow (F64 to F32)
def : InstRW<[V1Write_3c_1V02], (instregex "^FCVTNv[24]i32$",
"^FCVTXN(v[24]f32|v1i64)$")>;
// ASIMD FP convert, other, D-form F32 and Q-form F64
def : InstRW<[V1Write_3c_1V02], (instregex "^[FSU]CVT[AMNPZ][SU]v2f(32|64)$",
"^[SU]CVTFv2f(32|64)$")>;
// ASIMD FP convert, other, D-form F16 and Q-form F32
def : InstRW<[V1Write_4c_2V02], (instregex "^[FSU]CVT[AMNPZ][SU]v4f(16|32)$",
"^[SU]CVTFv4f(16|32)$")>;
// ASIMD FP convert, other, Q-form F16
def : InstRW<[V1Write_6c_4V02], (instregex "^[FSU]CVT[AMNPZ][SU]v8f16$",
"^[SU]CVTFv8f16$")>;
// ASIMD FP divide, D-form, F16
// ASIMD FP square root, D-form, F16
def : InstRW<[V1Write_7c7_1V02], (instrs FDIVv4f16, FSQRTv4f16)>;
// ASIMD FP divide, F32
// ASIMD FP square root, F32
def : InstRW<[V1Write_10c7_1V02], (instrs FDIVv2f32, FDIVv4f32,
FSQRTv2f32, FSQRTv4f32)>;
// ASIMD FP divide, Q-form, F16
def : InstRW<[V1Write_13c5_1V02], (instrs FDIVv8f16)>;
// ASIMD FP divide, Q-form, F64
def : InstRW<[V1Write_15c7_1V02], (instrs FDIVv2f64)>;
// ASIMD FP square root, Q-form, F16
def : InstRW<[V1Write_13c11_1V02], (instrs FSQRTv8f16)>;
// ASIMD FP square root, Q-form, F64
def : InstRW<[V1Write_16c7_1V02], (instrs FSQRTv2f64)>;
// ASIMD FP max/min, reduce, F32 and D-form F16
def : InstRW<[V1Write_4c_2V], (instregex "^F(MAX|MIN)(NM)?Vv4(i16|i32)v$")>;
// ASIMD FP max/min, reduce, Q-form F16
def : InstRW<[V1Write_6c_3V], (instregex "^F(MAX|MIN)(NM)?Vv8i16v$")>;
// ASIMD FP multiply
def : InstRW<[V1Write_3c_1V], (instregex "^FMULX?v")>;
// ASIMD FP multiply accumulate long
def : InstRW<[V1Write_5c_1V], (instregex "^FML[AS]L2?v")>;
// ASIMD FP round, D-form F32 and Q-form F64
def : InstRW<[V1Write_3c_1V02], (instregex "^FRINT[AIMNPXZ]v2f(32|64)$")>;
// ASIMD FP round, D-form F16 and Q-form F32
def : InstRW<[V1Write_4c_2V02], (instregex "^FRINT[AIMNPXZ]v4f(16|32)$")>;
// ASIMD FP round, Q-form F16
def : InstRW<[V1Write_6c_4V02], (instregex "^FRINT[AIMNPXZ]v8f16$")>;
// ASIMD BF instructions
// -----------------------------------------------------------------------------
// ASIMD convert, F32 to BF16
def : InstRW<[V1Write_4c_1V02], (instrs BFCVTN, BFCVTN2)>;
// ASIMD dot product
def : InstRW<[V1Write_4c_1V], (instregex "^BF(DOT|16DOTlane)v[48]bf16$")>;
// ASIMD matrix multiply accumulate
def : InstRW<[V1Write_5c_1V], (instrs BFMMLA)>;
// ASIMD multiply accumulate long
def : InstRW<[V1Write_4c_1V], (instregex "^BFMLAL[BT](Idx)?$")>;
// Scalar convert, F32 to BF16
def : InstRW<[V1Write_3c_1V02], (instrs BFCVT)>;
// ASIMD miscellaneous instructions
// -----------------------------------------------------------------------------
// ASIMD bit reverse
// ASIMD bitwise insert
// ASIMD count
// ASIMD duplicate, element
// ASIMD extract
// ASIMD extract narrow
// ASIMD insert, element to element
// ASIMD move, FP immed
// ASIMD move, integer immed
// ASIMD reverse
// ASIMD table lookup, 1 or 2 table regs
// ASIMD table lookup extension, 1 table reg
// ASIMD transfer, element to gen reg
// ASIMD transpose
// ASIMD unzip/zip
// Covered by "SchedAlias (WriteV[dq]...)" above
// ASIMD duplicate, gen reg
def : InstRW<[V1Write_3c_1M0],
(instregex "^DUP((v16|v8)i8|(v8|v4)i16|(v4|v2)i32|v2i64)gpr$")>;
// ASIMD extract narrow, saturating
def : InstRW<[V1Write_4c_1V13], (instregex "^[SU]QXTNv", "^SQXTUNv")>;
// ASIMD reciprocal and square root estimate, D-form U32
// ASIMD reciprocal and square root estimate, D-form F32 and F64
def : InstRW<[V1Write_3c_1V02], (instrs URECPEv2i32,
URSQRTEv2i32,
FRECPEv1i32, FRECPEv2f32, FRECPEv1i64,
FRSQRTEv1i32, FRSQRTEv2f32, FRSQRTEv1i64)>;
// ASIMD reciprocal and square root estimate, Q-form U32
// ASIMD reciprocal and square root estimate, D-form F16 and Q-form F32 and F64
def : InstRW<[V1Write_4c_1V02], (instrs URECPEv4i32,
URSQRTEv4i32,
FRECPEv1f16, FRECPEv4f16,
FRECPEv4f32, FRECPEv2f64,
FRSQRTEv1f16, FRSQRTEv4f16,
FRSQRTEv4f32, FRSQRTEv2f64)>;
// ASIMD reciprocal and square root estimate, Q-form F16
def : InstRW<[V1Write_6c_2V02], (instrs FRECPEv8f16,
FRSQRTEv8f16)>;
// ASIMD reciprocal exponent
def : InstRW<[V1Write_3c_1V02], (instrs FRECPXv1f16, FRECPXv1i32, FRECPXv1i64)>;
// ASIMD reciprocal step
def : InstRW<[V1Write_4c_1V], (instregex "^FRECPS(16|32|64)$", "^FRECPSv",
"^FRSQRTS(16|32|64)$", "^FRSQRTSv")>;
// ASIMD table lookup, 1 or 2 table regs
// ASIMD table lookup extension, 1 table reg
def : InstRW<[V1Write_2c_2V01], (instregex "^TBLv(8|16)i8(One|Two)$",
"^TBXv(8|16)i8One$")>;
// ASIMD table lookup, 3 table regs
// ASIMD table lookup extension, 2 table reg
def : InstRW<[V1Write_4c_2V01], (instrs TBLv8i8Three, TBLv16i8Three,
TBXv8i8Two, TBXv16i8Two)>;
// ASIMD table lookup, 4 table regs
def : InstRW<[V1Write_4c_3V01], (instrs TBLv8i8Four, TBLv16i8Four)>;
// ASIMD table lookup extension, 3 table reg
def : InstRW<[V1Write_6c_3V01], (instrs TBXv8i8Three, TBXv16i8Three)>;
// ASIMD table lookup extension, 4 table reg
def : InstRW<[V1Write_6c_5V01], (instrs TBXv8i8Four, TBXv16i8Four)>;
// ASIMD transfer, element to gen reg
def : InstRW<[V1Write_2c_1V], (instregex "^SMOVvi(((8|16)to(32|64))|32to64)$",
"^UMOVvi(8|16|32|64)$")>;
// ASIMD transfer, gen reg to element
def : InstRW<[V1Write_5c_1M0_1V], (instregex "^INSvi(8|16|32|64)gpr$")>;
// ASIMD load instructions
// -----------------------------------------------------------------------------
// ASIMD load, 1 element, multiple, 1 reg
def : InstRW<[V1Write_6c_1L],
(instregex "^LD1Onev(8b|16b|4h|8h|2s|4s|1d|2d)$")>;
def : InstRW<[WriteAdr, V1Write_6c_1L],
(instregex "^LD1Onev(8b|16b|4h|8h|2s|4s|1d|2d)_POST$")>;
// ASIMD load, 1 element, multiple, 2 reg
def : InstRW<[V1Write_6c_2L],
(instregex "^LD1Twov(8b|16b|4h|8h|2s|4s|1d|2d)$")>;
def : InstRW<[WriteAdr, V1Write_6c_2L],
(instregex "^LD1Twov(8b|16b|4h|8h|2s|4s|1d|2d)_POST$")>;
// ASIMD load, 1 element, multiple, 3 reg
def : InstRW<[V1Write_6c_3L],
(instregex "^LD1Threev(8b|16b|4h|8h|2s|4s|1d|2d)$")>;
def : InstRW<[WriteAdr, V1Write_6c_3L],
(instregex "^LD1Threev(8b|16b|4h|8h|2s|4s|1d|2d)_POST$")>;
// ASIMD load, 1 element, multiple, 4 reg, D-form
def : InstRW<[V1Write_6c_2L],
(instregex "^LD1Fourv(8b|4h|2s|1d)$")>;
def : InstRW<[WriteAdr, V1Write_6c_2L],
(instregex "^LD1Fourv(8b|4h|2s|1d)_POST$")>;
// ASIMD load, 1 element, multiple, 4 reg, Q-form
def : InstRW<[V1Write_7c_4L],
(instregex "^LD1Fourv(16b|8h|4s|2d)$")>;
def : InstRW<[WriteAdr, V1Write_7c_4L],
(instregex "^LD1Fourv(16b|8h|4s|2d)_POST$")>;
// ASIMD load, 1 element, one lane
// ASIMD load, 1 element, all lanes
def : InstRW<[V1Write_8c_1L_1V],
(instregex "^LD1(i|Rv)(8|16|32|64)$",
"^LD1Rv(8b|16b|4h|8h|2s|4s|1d|2d)$")>;
def : InstRW<[WriteAdr, V1Write_8c_1L_1V],
(instregex "^LD1i(8|16|32|64)_POST$",
"^LD1Rv(8b|16b|4h|8h|2s|4s|1d|2d)_POST$")>;
// ASIMD load, 2 element, multiple, D-form
def : InstRW<[V1Write_8c_1L_2V],
(instregex "^LD2Twov(8b|4h|2s)$")>;
def : InstRW<[WriteAdr, V1Write_8c_1L_2V],
(instregex "^LD2Twov(8b|4h|2s)_POST$")>;
// ASIMD load, 2 element, multiple, Q-form
def : InstRW<[V1Write_8c_2L_2V],
(instregex "^LD2Twov(16b|8h|4s|2d)$")>;
def : InstRW<[WriteAdr, V1Write_8c_2L_2V],
(instregex "^LD2Twov(16b|8h|4s|2d)_POST$")>;
// ASIMD load, 2 element, one lane
// ASIMD load, 2 element, all lanes
def : InstRW<[V1Write_8c_1L_2V],
(instregex "^LD2i(8|16|32|64)$",
"^LD2Rv(8b|16b|4h|8h|2s|4s|1d|2d)$")>;
def : InstRW<[WriteAdr, V1Write_8c_1L_2V],
(instregex "^LD2i(8|16|32|64)_POST$",
"^LD2Rv(8b|16b|4h|8h|2s|4s|1d|2d)_POST$")>;
// ASIMD load, 3 element, multiple, D-form
// ASIMD load, 3 element, one lane
// ASIMD load, 3 element, all lanes
def : InstRW<[V1Write_8c_2L_3V],
(instregex "^LD3Threev(8b|4h|2s)$",
"^LD3i(8|16|32|64)$",
"^LD3Rv(8b|16b|4h|8h|2s|4s|1d|2d)$")>;
def : InstRW<[WriteAdr, V1Write_8c_2L_3V],
(instregex "^LD3Threev(8b|4h|2s)_POST$",
"^LD3i(8|16|32|64)_POST$",
"^LD3Rv(8b|16b|4h|8h|2s|4s|1d|2d)_POST$")>;
// ASIMD load, 3 element, multiple, Q-form
def : InstRW<[V1Write_8c_3L_3V],
(instregex "^LD3Threev(16b|8h|4s|2d)$")>;
def : InstRW<[WriteAdr, V1Write_8c_3L_3V],
(instregex "^LD3Threev(16b|8h|4s|2d)_POST$")>;
// ASIMD load, 4 element, multiple, D-form
// ASIMD load, 4 element, one lane
// ASIMD load, 4 element, all lanes
def : InstRW<[V1Write_8c_3L_4V],
(instregex "^LD4Fourv(8b|4h|2s)$",
"^LD4i(8|16|32|64)$",
"^LD4Rv(8b|16b|4h|8h|2s|4s|1d|2d)$")>;
def : InstRW<[WriteAdr, V1Write_8c_3L_4V],
(instregex "^LD4Fourv(8b|4h|2s)_POST$",
"^LD4i(8|16|32|64)_POST$",
"^LD4Rv(8b|16b|4h|8h|2s|4s|1d|2d)_POST$")>;
// ASIMD load, 4 element, multiple, Q-form
def : InstRW<[V1Write_9c_4L_4V],
(instregex "^LD4Fourv(16b|8h|4s|2d)$")>;
def : InstRW<[WriteAdr, V1Write_9c_4L_4V],
(instregex "^LD4Fourv(16b|8h|4s|2d)_POST$")>;
// ASIMD store instructions
// -----------------------------------------------------------------------------
// ASIMD store, 1 element, multiple, 1 reg
// ASIMD store, 1 element, multiple, 2 reg, D-form
def : InstRW<[V1Write_2c_1L01_1V01],
(instregex "^ST1Onev(8b|16b|4h|8h|2s|4s|1d|2d)$",
"^ST1Twov(8b|4h|2s|1d)$")>;
def : InstRW<[WriteAdr, V1Write_2c_1L01_1V01],
(instregex "^ST1Onev(8b|16b|4h|8h|2s|4s|1d|2d)_POST$",
"^ST1Twov(8b|4h|2s|1d)_POST$")>;
// ASIMD store, 1 element, multiple, 2 reg, Q-form
// ASIMD store, 1 element, multiple, 3 reg, D-form
// ASIMD store, 1 element, multiple, 4 reg, D-form
def : InstRW<[V1Write_2c_2L01_2V01],
(instregex "^ST1Twov(16b|8h|4s|2d)$",
"^ST1Threev(8b|4h|2s|1d)$",
"^ST1Fourv(8b|4h|2s|1d)$")>;
def : InstRW<[WriteAdr, V1Write_2c_2L01_2V01],
(instregex "^ST1Twov(16b|8h|4s|2d)_POST$",
"^ST1Threev(8b|4h|2s|1d)_POST$",
"^ST1Fourv(8b|4h|2s|1d)_POST$")>;
// ASIMD store, 1 element, multiple, 3 reg, Q-form
def : InstRW<[V1Write_2c_3L01_3V01],
(instregex "^ST1Threev(16b|8h|4s|2d)$")>;
def : InstRW<[WriteAdr, V1Write_2c_3L01_3V01],
(instregex "^ST1Threev(16b|8h|4s|2d)_POST$")>;
// ASIMD store, 1 element, multiple, 4 reg, Q-form
def : InstRW<[V1Write_2c_4L01_4V01],
(instregex "^ST1Fourv(16b|8h|4s|2d)$")>;
def : InstRW<[WriteAdr, V1Write_2c_4L01_4V01],
(instregex "^ST1Fourv(16b|8h|4s|2d)_POST$")>;
// ASIMD store, 1 element, one lane
// ASIMD store, 2 element, multiple, D-form
// ASIMD store, 2 element, one lane
def : InstRW<[V1Write_4c_1L01_1V01],
(instregex "^ST1i(8|16|32|64)$",
"^ST2Twov(8b|4h|2s)$",
"^ST2i(8|16|32|64)$")>;
def : InstRW<[WriteAdr, V1Write_4c_1L01_1V01],
(instregex "^ST1i(8|16|32|64)_POST$",
"^ST2Twov(8b|4h|2s)_POST$",
"^ST2i(8|16|32|64)_POST$")>;
// ASIMD store, 2 element, multiple, Q-form
// ASIMD store, 3 element, multiple, D-form
// ASIMD store, 3 element, one lane
// ASIMD store, 4 element, one lane, D
def : InstRW<[V1Write_4c_2L01_2V01],
(instregex "^ST2Twov(16b|8h|4s|2d)$",
"^ST3Threev(8b|4h|2s)$",
"^ST3i(8|16|32|64)$",
"^ST4i64$")>;
def : InstRW<[WriteAdr, V1Write_4c_2L01_2V01],
(instregex "^ST2Twov(16b|8h|4s|2d)_POST$",
"^ST3Threev(8b|4h|2s)_POST$",
"^ST3i(8|16|32|64)_POST$",
"^ST4i64_POST$")>;
// ASIMD store, 3 element, multiple, Q-form
def : InstRW<[V1Write_5c_3L01_3V01],
(instregex "^ST3Threev(16b|8h|4s|2d)$")>;
def : InstRW<[WriteAdr, V1Write_5c_3L01_3V01],
(instregex "^ST3Threev(16b|8h|4s|2d)_POST$")>;
// ASIMD store, 4 element, multiple, D-form
def : InstRW<[V1Write_6c_3L01_3V01],
(instregex "^ST4Fourv(8b|4h|2s)$")>;
def : InstRW<[WriteAdr, V1Write_6c_3L01_3V01],
(instregex "^ST4Fourv(8b|4h|2s)_POST$")>;
// ASIMD store, 4 element, multiple, Q-form, B/H/S
def : InstRW<[V1Write_7c_6L01_6V01],
(instregex "^ST4Fourv(16b|8h|4s)$")>;
def : InstRW<[WriteAdr, V1Write_7c_6L01_6V01],
(instregex "^ST4Fourv(16b|8h|4s)_POST$")>;
// ASIMD store, 4 element, multiple, Q-form, D
def : InstRW<[V1Write_4c_4L01_4V01],
(instrs ST4Fourv2d)>;
def : InstRW<[WriteAdr, V1Write_4c_4L01_4V01],
(instrs ST4Fourv2d_POST)>;
// ASIMD store, 4 element, one lane, B/H/S
def : InstRW<[V1Write_6c_3L_3V],
(instregex "^ST4i(8|16|32)$")>;
def : InstRW<[WriteAdr, V1Write_6c_3L_3V],
(instregex "^ST4i(8|16|32)_POST$")>;
// Cryptography extensions
// -----------------------------------------------------------------------------
// Crypto polynomial (64x64) multiply long
// Covered by "SchedAlias (WriteV[dq]...)" above
// Crypto AES ops
def V1WriteVC : WriteSequence<[V1Write_2c_1V]>;
def V1ReadVC : SchedReadAdvance<2, [V1WriteVC]>;
def : InstRW<[V1WriteVC], (instrs AESDrr, AESErr)>;
def : InstRW<[V1Write_2c_1V, V1ReadVC], (instrs AESMCrr, AESIMCrr)>;
// Crypto SHA1 hash acceleration op
// Crypto SHA1 schedule acceleration ops
// Crypto SHA256 schedule acceleration ops
// Crypto SHA512 hash acceleration ops
// Crypto SM3 ops
def : InstRW<[V1Write_2c_1V0], (instregex "^SHA1(H|SU[01])rr$",
"^SHA256SU[01]rr$",
"^SHA512(H2?|SU[01])$",
"^SM3(PARTW(1|2SM3SS1)|TT[12][AB])$")>;
// Crypto SHA1 hash acceleration ops
// Crypto SHA256 hash acceleration ops
// Crypto SM4 ops
def : InstRW<[V1Write_4c_1V0], (instregex "^SHA1[CMP]rrr$",
"^SHA256H2?rrr$",
"^SM4E(KEY)?$")>;
// Crypto SHA3 ops
def : InstRW<[V1Write_2c_1V0], (instrs BCAX, EOR3, RAX1, XAR)>;
// CRC instruction
// -----------------------------------------------------------------------------
// CRC checksum ops
def : InstRW<[V1Write_2c_1M0], (instregex "^CRC32C?[BHWX]rr$")>;
// SVE Predicate instructions
// -----------------------------------------------------------------------------
// Loop control, based on predicate
def : InstRW<[V1Write_2c_1M0], (instregex "^BRK[AB]_PP[mz]P$")>;
def : InstRW<[V1Write_2c_1M0], (instrs BRKN_PPzP, BRKPA_PPzPP, BRKPB_PPzPP)>;
// Loop control, based on predicate and flag setting
def : InstRW<[V1Write_3c_2M0], (instrs BRKAS_PPzP, BRKBS_PPzP, BRKNS_PPzP,
BRKPAS_PPzPP, BRKPBS_PPzPP)>;
// Loop control, based on GPR
def : InstRW<[V1Write_3c_2M0], (instregex "^WHILE(LE|LO|LS|LT)_P(WW|XX)_[BHSD]$")>;
// Loop terminate
def : InstRW<[V1Write_1c_1M0], (instregex "^CTERM(EQ|NE)_(WW|XX)$")>;
// Predicate counting scalar
// Predicate counting scalar, active predicate
def : InstRW<[V1Write_2c_1M0], (instrs ADDPL_XXI, ADDVL_XXI, RDVLI_XI)>;
def : InstRW<[V1Write_2c_1M0], (instregex "^(CNT|([SU]Q)?(DEC|INC))[BHWD]_XPiI$",
"^SQ(DEC|INC)[BHWD]_XPiWdI$",
"^UQ(DEC|INC)[BHWD]_WPiI$",
"^CNTP_XPP_[BHSD]$",
"^([SU]Q)?(DEC|INC)P_XP_[BHSD]$",
"^UQ(DEC|INC)P_WP_[BHSD]$",
"^[SU]Q(DEC|INC)P_XPWd_[BHSD]$")>;
// Predicate counting vector, active predicate
def : InstRW<[V1Write_7c_2M0_1V01], (instregex "^([SU]Q)?(DEC|INC)P_ZP_[HSD]$")>;
// Predicate logical
def : InstRW<[V1Write_1c_1M0],
(instregex "^(AND|BIC|EOR|NAND|NOR|ORN|ORR)_PPzPP$")>;
// Predicate logical, flag setting
def : InstRW<[V1Write_2c_2M0],
(instregex "^(AND|BIC|EOR|NAND|NOR|ORN|ORR)S_PPzPP$")>;
// Predicate reverse
// Predicate set/initialize/find next
// Predicate transpose
// Predicate unpack and widen
// Predicate zip/unzip
def : InstRW<[V1Write_2c_1M0], (instregex "^REV_PP_[BHSD]$",
"^PFALSE$", "^PFIRST_B$",
"^PNEXT_[BHSD]$", "^PTRUE_[BHSD]$",
"^TRN[12]_PPP_[BHSDQ]$",
"^(ZIP|UZP)[12]_PPP_[BHSDQ]$")>;
// Predicate set/initialize/find next
// Predicate unpack and widen
def : InstRW<[V1Write_2c_1M0], (instrs PTEST_PP,
PUNPKHI_PP, PUNPKLO_PP)>;
// Predicate select
def : InstRW<[V1Write_1c_1M0], (instrs SEL_PPPP)>;
// Predicate set/initialize, set flags
def : InstRW<[V1Write_3c_2M0], (instregex "^PTRUES_[BHSD]$")>;
// SVE integer instructions
// -----------------------------------------------------------------------------
// Arithmetic, basic
// Logical
def : InstRW<[V1Write_2c_1V01],
(instregex "^(ABS|CNOT|NEG)_ZPmZ_[BHSD]$",
"^(ADD|SUB)_Z(I|P[mZ]Z|ZZ)_[BHSD]$",
"^ADR_[SU]XTW_ZZZ_D_[0123]$",
"^ADR_LSL_ZZZ_[SD]_[0123]$",
"^[SU]ABD_ZP[mZ]Z_[BHSD]$",
"^[SU](MAX|MIN)_Z(I|P[mZ]Z)_[BHSD]$",
"^[SU]Q(ADD|SUB)_Z(I|ZZ)_[BHSD]$",
"^SUBR_Z(I|P[mZ]Z)_[BHSD]$",
"^(AND|EOR|ORR)_ZI$",
"^(AND|BIC|EOR|EOR(BT|TB)?|ORR)_ZZZ$",
"^EOR(BT|TB)_ZZZ_[BHSD]$",
"^(AND|BIC|EOR|NOT|ORR)_ZPmZ_[BHSD]$")>;
// Arithmetic, shift
def : InstRW<[V1Write_2c_1V1],
(instregex "^(ASR|LSL|LSR)_WIDE_Z(Pm|Z)Z_[BHS]",
"^(ASR|LSL|LSR)_ZPm[IZ]_[BHSD]",
"^(ASR|LSL|LSR)_ZZI_[BHSD]",
"^(ASR|LSL|LSR)_ZPZ[IZ]_[BHSD]",
"^(ASRR|LSLR|LSRR)_ZPmZ_[BHSD]")>;
// Arithmetic, shift right for divide
def : InstRW<[V1Write_4c_1V1], (instregex "^ASRD_ZP[mZ]I_[BHSD]$")>;
// Count/reverse bits
def : InstRW<[V1Write_2c_1V01], (instregex "^(CLS|CLZ|CNT|RBIT)_ZPmZ_[BHSD]$")>;
// Broadcast logical bitmask immediate to vector
def : InstRW<[V1Write_2c_1V01], (instrs DUPM_ZI)>;
// Compare and set flags
def : InstRW<[V1Write_4c_1M0_1V0],
(instregex "^CMP(EQ|GE|GT|HI|HS|LE|LO|LS|LT|NE)_PPzZ[IZ]_[BHSD]$",
"^CMP(EQ|GE|GT|HI|HS|LE|LO|LS|LT|NE)_WIDE_PPzZZ_[BHS]$")>;
// Conditional extract operations, scalar form
def : InstRW<[V1Write_9c_1M0_1V1], (instregex "^CLAST[AB]_RPZ_[BHSD]$")>;
// Conditional extract operations, SIMD&FP scalar and vector forms
def : InstRW<[V1Write_3c_1V1], (instregex "^CLAST[AB]_[VZ]PZ_[BHSD]$",
"^COMPACT_ZPZ_[SD]$",
"^SPLICE_ZPZZ?_[BHSD]$")>;
// Convert to floating point, 64b to float or convert to double
def : InstRW<[V1Write_3c_1V0], (instregex "^[SU]CVTF_ZPmZ_Dto[HSD]",
"^[SU]CVTF_ZPmZ_StoD")>;
// Convert to floating point, 32b to single or half
def : InstRW<[V1Write_4c_2V0], (instregex "^[SU]CVTF_ZPmZ_Sto[HS]$")>;
// Convert to floating point, 16b to half
def : InstRW<[V1Write_6c_4V0], (instregex "^[SU]CVTF_ZPmZ_HtoH$")>;
// Copy, scalar
def : InstRW<[V1Write_5c_1M0_1V01], (instregex "^CPY_ZPmR_[BHSD]$")>;
// Copy, scalar SIMD&FP or imm
def : InstRW<[V1Write_2c_1V01], (instregex "^CPY_ZP([mz]I|mV)_[BHSD]$")>;
// Divides, 32 bit
def : InstRW<[V1Write_12c7_1V0], (instregex "^[SU]DIVR?_ZPmZ_S$")>;
// Divides, 64 bit
def : InstRW<[V1Write_20c7_1V0], (instregex "^[SU]DIVR?_ZPmZ_D$")>;
// Dot product, 8 bit
def : InstRW<[V1Write_3c_1V01], (instregex "^[SU]DOT_ZZZI?_S$")>;
// Dot product, 8 bit, using signed and unsigned integers
def : InstRW<[V1Write_3c_1V], (instrs SUDOT_ZZZI, USDOT_ZZZ, USDOT_ZZZI)>;
// Dot product, 16 bit
def : InstRW<[V1Write_4c_1V01], (instregex "^[SU]DOT_ZZZI?_D$")>;
// Duplicate, immediate and indexed form
def : InstRW<[V1Write_2c_1V01], (instregex "^DUP_ZI_[BHSD]$",
"^DUP_ZZI_[BHSDQ]$")>;
// Duplicate, scalar form
def : InstRW<[V1Write_3c_1M0], (instregex "^DUP_ZR_[BHSD]$")>;
// Extend, sign or zero
def : InstRW<[V1Write_2c_1V1], (instregex "^[SU]XTB_ZPmZ_[HSD]$",
"^[SU]XTH_ZPmZ_[SD]$",
"^[SU]XTW_ZPmZ_[D]$")>;
// Extract
def : InstRW<[V1Write_2c_1V01], (instrs EXT_ZZI)>;
// Extract/insert operation, SIMD and FP scalar form
def : InstRW<[V1Write_3c_1V1], (instregex "^LAST[AB]_VPZ_[BHSD]$",
"^INSR_ZV_[BHSD]$")>;
// Extract/insert operation, scalar
def : InstRW<[V1Write_6c_1M0_1V1], (instregex "^LAST[AB]_RPZ_[BHSD]$",
"^INSR_ZR_[BHSD]$")>;
// Horizontal operations, B, H, S form, imm, imm
def : InstRW<[V1Write_4c_1V0], (instregex "^INDEX_II_[BHS]$")>;
// Horizontal operations, B, H, S form, scalar, imm / scalar / imm, scalar
def : InstRW<[V1Write_7c_1M0_1V0], (instregex "^INDEX_(IR|RI|RR)_[BHS]$")>;
// Horizontal operations, D form, imm, imm
def : InstRW<[V1Write_5c_2V0], (instrs INDEX_II_D)>;
// Horizontal operations, D form, scalar, imm / scalar / imm, scalar
def : InstRW<[V1Write_8c_2M0_2V0], (instregex "^INDEX_(IR|RI|RR)_D$")>;
// Move prefix
def : InstRW<[V1Write_2c_1V01], (instregex "^MOVPRFX_ZP[mz]Z_[BHSD]$",
"^MOVPRFX_ZZ$")>;
// Matrix multiply-accumulate
def : InstRW<[V1Write_3c_1V01], (instrs SMMLA_ZZZ, UMMLA_ZZZ, USMMLA_ZZZ)>;
// Multiply, B, H, S element size
def : InstRW<[V1Write_4c_1V0], (instregex "^MUL_(ZI|ZPmZ)_[BHS]$",
"^[SU]MULH_(ZPmZ|ZZZ)_[BHS]$")>;
// Multiply, D element size
// Multiply accumulate, D element size
def : InstRW<[V1Write_5c_2V0], (instregex "^MUL_(ZI|ZPmZ)_D$",
"^[SU]MULH_ZPmZ_D$",
"^(MLA|MLS|MAD|MSB)_ZPmZZ_D$")>;
// Multiply accumulate, B, H, S element size
// NOTE: This is not specified in the SOG.
def : InstRW<[V1Write_4c_1V0], (instregex "^(ML[AS]|MAD|MSB)_ZPmZZ_[BHS]")>;
// Predicate counting vector
def : InstRW<[V1Write_2c_1V0], (instregex "^([SU]Q)?(DEC|INC)[HWD]_ZPiI$")>;
// Reduction, arithmetic, B form
def : InstRW<[V1Write_14c_1V_1V0_2V1_1V13],
(instregex "^[SU](ADD|MAX|MIN)V_VPZ_B")>;
// Reduction, arithmetic, H form
def : InstRW<[V1Write_12c_1V_1V01_2V1],
(instregex "^[SU](ADD|MAX|MIN)V_VPZ_H")>;
// Reduction, arithmetic, S form
def : InstRW<[V1Write_10c_1V_1V01_2V1],
(instregex "^[SU](ADD|MAX|MIN)V_VPZ_S")>;
// Reduction, arithmetic, D form
def : InstRW<[V1Write_8c_1V_1V01],
(instregex "^[SU](ADD|MAX|MIN)V_VPZ_D")>;
// Reduction, logical
def : InstRW<[V1Write_12c_4V01], (instregex "^(AND|EOR|OR)V_VPZ_[BHSD]$")>;
// Reverse, vector
def : InstRW<[V1Write_2c_1V01], (instregex "^REV_ZZ_[BHSD]$",
"^REVB_ZPmZ_[HSD]$",
"^REVH_ZPmZ_[SD]$",
"^REVW_ZPmZ_D$")>;
// Select, vector form
// Table lookup
// Table lookup extension
// Transpose, vector form
// Unpack and extend
// Zip/unzip
def : InstRW<[V1Write_2c_1V01], (instregex "^SEL_ZPZZ_[BHSD]$",
"^TB[LX]_ZZZ_[BHSD]$",
"^TRN[12]_ZZZ_[BHSDQ]$",
"^[SU]UNPK(HI|LO)_ZZ_[HSD]$",
"^(UZP|ZIP)[12]_ZZZ_[BHSDQ]$")>;
// SVE floating-point instructions
// -----------------------------------------------------------------------------
// Floating point absolute value/difference
// Floating point arithmetic
def : InstRW<[V1Write_2c_1V01], (instregex "^FAB[SD]_ZPmZ_[HSD]$",
"^F(ADD|SUB)_(ZPm[IZ]|ZZZ)_[HSD]$",
"^FADDP_ZPmZZ_[HSD]$",
"^FNEG_ZPmZ_[HSD]$",
"^FSUBR_ZPm[IZ]_[HSD]$")>;
// Floating point associative add, F16
def : InstRW<[V1Write_19c_18V0], (instrs FADDA_VPZ_H)>;
// Floating point associative add, F32
def : InstRW<[V1Write_11c_10V0], (instrs FADDA_VPZ_S)>;
// Floating point associative add, F64
def : InstRW<[V1Write_8c_3V01], (instrs FADDA_VPZ_D)>;
// Floating point compare
def : InstRW<[V1Write_2c_1V0], (instregex "^FAC(GE|GT)_PPzZZ_[HSD]$",
"^FCM(EQ|GE|GT|NE|UO)_PPzZZ_[HSD]$",
"^FCM(EQ|GE|GT|LE|LT|NE)_PPzZ0_[HSD]$")>;
// Floating point complex add
def : InstRW<[V1Write_3c_1V01], (instregex "^FCADD_ZPmZ_[HSD]$")>;
// Floating point complex multiply add
def : InstRW<[V1Write_5c_1V01], (instregex "^FCMLA_ZPmZZ_[HSD]$",
"^FCMLA_ZZZI_[HS]$")>;
// Floating point convert, long or narrow (F16 to F32 or F32 to F16)
// Floating point convert to integer, F32
def : InstRW<[V1Write_4c_2V0], (instregex "^FCVT_ZPmZ_(HtoS|StoH)$",
"^FCVTZ[SU]_ZPmZ_(HtoS|StoS)$")>;
// Floating point convert, long or narrow (F16 to F64, F32 to F64, F64 to F32 or F64 to F16)
// Floating point convert to integer, F64
def : InstRW<[V1Write_3c_1V0], (instregex "^FCVT_ZPmZ_(HtoD|StoD|DtoS|DtoH)$",
"^FCVTZ[SU]_ZPmZ_(HtoD|StoD|DtoS|DtoD)$")>;
// Floating point convert to integer, F16
def : InstRW<[V1Write_6c_4V0], (instregex "^FCVTZ[SU]_ZPmZ_HtoH$")>;
// Floating point copy
def : InstRW<[V1Write_2c_1V01], (instregex "^FCPY_ZPmI_[HSD]$",
"^FDUP_ZI_[HSD]$")>;
// Floating point divide, F16
def : InstRW<[V1Write_13c10_1V0], (instregex "^FDIVR?_ZPmZ_H$")>;
// Floating point divide, F32
def : InstRW<[V1Write_10c7_1V0], (instregex "^FDIVR?_ZPmZ_S$")>;
// Floating point divide, F64
def : InstRW<[V1Write_15c7_1V0], (instregex "^FDIVR?_ZPmZ_D$")>;
// Floating point min/max
def : InstRW<[V1Write_2c_1V01], (instregex "^F(MAX|MIN)(NM)?_ZPm[IZ]_[HSD]$")>;
// Floating point multiply
def : InstRW<[V1Write_3c_1V01], (instregex "^F(SCALE|MULX)_ZPmZ_[HSD]$",
"^FMUL_(ZPm[IZ]|ZZZI?)_[HSD]$")>;
// Floating point multiply accumulate
// Floating point reciprocal step
def : InstRW<[V1Write_4c_1V01], (instregex "^F(N?M(AD|SB)|N?ML[AS])_ZPmZZ_[HSD]$",
"^FML[AS]_ZZZI_[HSD]$",
"^F(RECPS|RSQRTS)_ZZZ_[HSD]$")>;
// Floating point reciprocal estimate, F16
def : InstRW<[V1Write_6c_4V0], (instrs FRECPE_ZZ_H, FRSQRTE_ZZ_H)>;
// Floating point reciprocal estimate, F32
def : InstRW<[V1Write_4c_2V0], (instrs FRECPE_ZZ_S, FRSQRTE_ZZ_S)>;
// Floating point reciprocal estimate, F64
def : InstRW<[V1Write_3c_1V0], (instrs FRECPE_ZZ_D, FRSQRTE_ZZ_D)>;
// Floating point reciprocal exponent
def : InstRW<[V1Write_3c_1V0], (instregex "^FRECPX_ZPmZ_[HSD]$")>;
// Floating point reduction, F16
def : InstRW<[V1Write_13c_6V01], (instregex "^F(ADD|((MAX|MIN)(NM)?))V_VPZ_H$")>;
// Floating point reduction, F32
def : InstRW<[V1Write_11c_1V_5V01], (instregex "^F(ADD|((MAX|MIN)(NM)?))V_VPZ_S$")>;
// Floating point reduction, F64
def : InstRW<[V1Write_9c_1V_4V01], (instregex "^F(ADD|((MAX|MIN)(NM)?))V_VPZ_D$")>;
// Floating point round to integral, F16
def : InstRW<[V1Write_6c_1V0], (instregex "^FRINT[AIMNPXZ]_ZPmZ_H$")>;
// Floating point round to integral, F32
def : InstRW<[V1Write_4c_1V0], (instregex "^FRINT[AIMNPXZ]_ZPmZ_S$")>;
// Floating point round to integral, F64
def : InstRW<[V1Write_3c_1V0], (instregex "^FRINT[AIMNPXZ]_ZPmZ_D$")>;
// Floating point square root, F16
def : InstRW<[V1Write_13c10_1V0], (instrs FSQRT_ZPmZ_H)>;
// Floating point square root, F32
def : InstRW<[V1Write_10c7_1V0], (instrs FSQRT_ZPmZ_S)>;
// Floating point square root, F64
def : InstRW<[V1Write_16c7_1V0], (instrs FSQRT_ZPmZ_D)>;
// Floating point trigonometric
def : InstRW<[V1Write_3c_1V01], (instregex "^FEXPA_ZZ_[HSD]$",
"^FTMAD_ZZI_[HSD]$",
"^FTS(MUL|SEL)_ZZZ_[HSD]$")>;
// SVE BFloat16 (BF16) instructions
// -----------------------------------------------------------------------------
// Convert, F32 to BF16
def : InstRW<[V1Write_4c_1V0], (instrs BFCVT_ZPmZ, BFCVTNT_ZPmZ)>;
// Dot product
def : InstRW<[V1Write_4c_1V01], (instrs BFDOT_ZZI, BFDOT_ZZZ)>;
// Matrix multiply accumulate
def : InstRW<[V1Write_5c_1V01], (instrs BFMMLA_ZZZ)>;
// Multiply accumulate long
def : InstRW<[V1Write_5c_1V01], (instregex "^BFMLAL[BT]_ZZZ(I)?$")>;
// SVE Load instructions
// -----------------------------------------------------------------------------
// Load vector
def : InstRW<[V1Write_6c_1L01], (instrs LDR_ZXI)>;
// Load predicate
def : InstRW<[V1Write_6c_1L_1M], (instrs LDR_PXI)>;
// Contiguous load, scalar + imm
// Contiguous load, scalar + scalar
// Contiguous load broadcast, scalar + imm
// Contiguous load broadcast, scalar + scalar
def : InstRW<[V1Write_6c_1L01], (instregex "^LD1[BHWD]_IMM$",
"^LD1S?B_[HSD]_IMM$",
"^LD1S?H_[SD]_IMM$",
"^LD1S?W_D_IMM$",
"^LD1[BWD]$",
"^LD1S?B_[HSD]$",
"^LD1S?W_D$",
"^LD1R[BHWD]_IMM$",
"^LD1RSW_IMM$",
"^LD1RS?B_[HSD]_IMM$",
"^LD1RS?H_[SD]_IMM$",
"^LD1RS?W_D_IMM$",
"^LD1RQ_[BHWD]_IMM$",
"^LD1RQ_[BWD]$")>;
def : InstRW<[V1Write_7c_1L01_1S], (instregex "^LD1H$",
"^LD1S?H_[SD]$",
"^LD1RQ_H$")>;
// Non temporal load, scalar + imm
def : InstRW<[V1Write_6c_1L01], (instregex "^LDNT1[BHWD]_ZRI$")>;
// Non temporal load, scalar + scalar
def : InstRW<[V1Write_7c_1L01_1S], (instrs LDNT1H_ZRR)>;
def : InstRW<[V1Write_6c_1L01_1S], (instregex "^LDNT1[BWD]_ZRR$")>;
// Contiguous first faulting load, scalar + scalar
def : InstRW<[V1Write_7c_1L01_1S], (instregex "^LDFF1H_REAL$",
"^LDFF1S?H_[SD]_REAL$")>;
def : InstRW<[V1Write_6c_1L01_1S], (instregex "^LDFF1[BWD]_REAL$",
"^LDFF1S?B_[HSD]_REAL$",
"^LDFF1S?W_D_REAL$")>;
// Contiguous non faulting load, scalar + imm
def : InstRW<[V1Write_6c_1L01], (instregex "^LDNF1[BHWD]_IMM_REAL$",
"^LDNF1S?B_[HSD]_IMM_REAL$",
"^LDNF1S?H_[SD]_IMM_REAL$",
"^LDNF1S?W_D_IMM_REAL$")>;
// Contiguous Load two structures to two vectors, scalar + imm
def : InstRW<[V1Write_8c_2L01_2V01], (instregex "^LD2[BHWD]_IMM$")>;
// Contiguous Load two structures to two vectors, scalar + scalar
def : InstRW<[V1Write_10c_2L01_2V01], (instrs LD2H)>;
def : InstRW<[V1Write_9c_2L01_2V01], (instregex "^LD2[BWD]$")>;
// Contiguous Load three structures to three vectors, scalar + imm
def : InstRW<[V1Write_11c_3L01_3V01], (instregex "^LD3[BHWD]_IMM$")>;
// Contiguous Load three structures to three vectors, scalar + scalar
def : InstRW<[V1Write_13c_3L01_1S_3V01], (instregex "^LD3[BHWD]$")>;
// Contiguous Load four structures to four vectors, scalar + imm
def : InstRW<[V1Write_12c_4L01_4V01], (instregex "^LD4[BHWD]_IMM$")>;
// Contiguous Load four structures to four vectors, scalar + scalar
def : InstRW<[V1Write_13c_4L01_2S_4V01], (instregex "^LD4[BHWD]$")>;
// Gather load, vector + imm, 32-bit element size
def : InstRW<[V1Write_11c_1L_1V], (instregex "^GLD(FF)?1S?[BH]_S_IMM_REAL$",
"^GLD(FF)?1W_IMM_REAL$")>;
// Gather load, vector + imm, 64-bit element size
def : InstRW<[V1Write_9c_2L_2V],
(instregex "^GLD(FF)?1S?[BHW]_D_IMM_REAL$",
"^GLD(FF)?1S?[BHW]_D_([SU]XTW_)?(SCALED_)?REAL$",
"^GLD(FF)?1D_IMM_REAL$",
"^GLD(FF)?1D_([SU]XTW_)?(SCALED_)?REAL$")>;
// Gather load, 32-bit scaled offset
def : InstRW<[V1Write_11c_2L_2V],
(instregex "^GLD(FF)?1S?[HW]_S_[SU]XTW_SCALED_REAL$",
"^GLD(FF)?1W_[SU]XTW_SCALED_REAL")>;
// Gather load, 32-bit unpacked unscaled offset
def : InstRW<[V1Write_9c_1L_1V],
(instregex "^GLD(FF)?1S?[BH]_S_[SU]XTW_REAL$",
"^GLD(FF)?1W_[SU]XTW_REAL$")>;
// Prefetch
// NOTE: This is not specified in the SOG.
def : InstRW<[V1Write_4c_1L01], (instregex "^PRF[BHWD]")>;
// SVE Store instructions
// -----------------------------------------------------------------------------
// Store from predicate reg
def : InstRW<[V1Write_1c_1L01], (instrs STR_PXI)>;
// Store from vector reg
def : InstRW<[V1Write_2c_1L01_1V], (instrs STR_ZXI)>;
// Contiguous store, scalar + imm
// Contiguous store, scalar + scalar
def : InstRW<[V1Write_2c_1L01_1V], (instregex "^ST1[BHWD]_IMM$",
"^ST1B_[HSD]_IMM$",
"^ST1H_[SD]_IMM$",
"^ST1W_D_IMM$",
"^ST1[BWD]$",
"^ST1B_[HSD]$",
"^ST1W_D$")>;
def : InstRW<[V1Write_2c_1L01_1S_1V], (instregex "^ST1H(_[SD])?$")>;
// Contiguous store two structures from two vectors, scalar + imm
// Contiguous store two structures from two vectors, scalar + scalar
def : InstRW<[V1Write_4c_1L01_1V], (instregex "^ST2[BHWD]_IMM$",
"^ST2[BWD]$")>;
def : InstRW<[V1Write_4c_1L01_1S_1V], (instrs ST2H)>;
// Contiguous store three structures from three vectors, scalar + imm
def : InstRW<[V1Write_7c_5L01_5V], (instregex "^ST3[BHWD]_IMM$")>;
// Contiguous store three structures from three vectors, scalar + scalar
def : InstRW<[V1Write_7c_5L01_5S_5V], (instregex "^ST3[BHWD]$")>;
// Contiguous store four structures from four vectors, scalar + imm
def : InstRW<[V1Write_11c_9L01_9V], (instregex "^ST4[BHWD]_IMM$")>;
// Contiguous store four structures from four vectors, scalar + scalar
def : InstRW<[V1Write_11c_9L01_9S_9V], (instregex "^ST4[BHWD]$")>;
// Non temporal store, scalar + imm
// Non temporal store, scalar + scalar
def : InstRW<[V1Write_2c_1L01_1V], (instregex "^STNT1[BHWD]_ZRI$",
"^STNT1[BWD]_ZRR$")>;
def : InstRW<[V1Write_2c_1L01_1S_1V], (instrs STNT1H_ZRR)>;
// Scatter store vector + imm 32-bit element size
// Scatter store, 32-bit scaled offset
// Scatter store, 32-bit unscaled offset
def : InstRW<[V1Write_10c_2L01_2V], (instregex "^SST1[BH]_S_IMM$",
"^SST1W_IMM$",
"^SST1(H_S|W)_[SU]XTW_SCALED$",
"^SST1[BH]_S_[SU]XTW$",
"^SST1W_[SU]XTW$")>;
// Scatter store, 32-bit unpacked unscaled offset
// Scatter store, 32-bit unpacked scaled offset
def : InstRW<[V1Write_6c_1L01_1V], (instregex "^SST1[BHW]_D_[SU]XTW$",
"^SST1D_[SU]XTW$",
"^SST1[HW]_D_[SU]XTW_SCALED$",
"^SST1D_[SU]XTW_SCALED$")>;
// Scatter store vector + imm 64-bit element size
// Scatter store, 64-bit scaled offset
// Scatter store, 64-bit unscaled offset
def : InstRW<[V1Write_6c_1L01_1V], (instregex "^SST1[BHW]_D_IMM$",
"^SST1D_IMM$",
"^SST1[HW]_D_SCALED$",
"^SST1D_SCALED$",
"^SST1[BHW]_D$",
"^SST1D$")>;
// SVE Miscellaneous instructions
// -----------------------------------------------------------------------------
// Read first fault register, unpredicated
// Set first fault register
// Write to first fault register
def : InstRW<[V1Write_2c_1M0], (instrs RDFFR_P_REAL,
SETFFR,
WRFFR)>;
// Read first fault register, predicated
def : InstRW<[V1Write_3c_2M0], (instrs RDFFR_PPz_REAL)>;
// Read first fault register and set flags
def : InstRW<[V1Write_4c_1M], (instrs RDFFRS_PPz)>;
}