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1eb67a4f84
Previously, only regular AArch64 instructions were annotated with SchedRW lists. This patch does the same for NEON enabling these instructions to be scheduled by the MIScheduler. Additionally, store operations are now modeled and a few SchedRW lists were updated for bug fixes (e.g. multiple def operands). Reviewers: apazos, mcrosier, atrick Patch by Dave Estes <cestes@codeaurora.org>! git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@204505 91177308-0d34-0410-b5e6-96231b3b80d8
145 lines
6.0 KiB
TableGen
145 lines
6.0 KiB
TableGen
//=- AArch64ScheduleA53.td - ARM Cortex-A53 Scheduling Definitions -*- tablegen -*-=//
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//
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// The LLVM Compiler Infrastructure
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//
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// This file is distributed under the University of Illinois Open Source
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// License. See LICENSE.TXT for details.
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//
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//===----------------------------------------------------------------------===//
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//
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// This file defines the itinerary class data for the ARM Cortex A53 processors.
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//
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//===----------------------------------------------------------------------===//
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// ===---------------------------------------------------------------------===//
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// The following definitions describe the simpler per-operand machine model.
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// This works with MachineScheduler. See MCSchedModel.h for details.
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// Cortex-A53 machine model for scheduling and other instruction cost heuristics.
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def CortexA53Model : SchedMachineModel {
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let IssueWidth = 2; // 2 micro-ops are dispatched per cycle.
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let MinLatency = 1 ; // OperandCycles are interpreted as MinLatency.
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let LoadLatency = 2; // Optimistic load latency assuming bypass.
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// This is overriden by OperandCycles if the
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// Itineraries are queried instead.
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let MispredictPenalty = 9; // Based on "Cortex-A53 Software Optimisation
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// Specification - Instruction Timings"
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// v 1.0 Spreadsheet
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}
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//===----------------------------------------------------------------------===//
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// Define each kind of processor resource and number available.
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// Modeling each pipeline as a ProcResource using the default BufferSize = -1.
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// Cortex-A53 is in-order and therefore should be using BufferSize = 0. The
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// current configuration performs better with the basic latencies provided so
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// far. Will revisit BufferSize once the latency information is more accurate.
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let SchedModel = CortexA53Model in {
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def A53UnitALU : ProcResource<2>; // Int ALU
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def A53UnitMAC : ProcResource<1>; // Int MAC
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def A53UnitDiv : ProcResource<1>; // Int Division
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def A53UnitLdSt : ProcResource<1>; // Load/Store
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def A53UnitB : ProcResource<1>; // Branch
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def A53UnitFPALU : ProcResource<1>; // FP ALU
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def A53UnitFPMDS : ProcResource<1>; // FP Mult/Div/Sqrt
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//===----------------------------------------------------------------------===//
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// Subtarget-specific SchedWrite types which both map the ProcResources and
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// set the latency.
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// Issue - Every instruction must consume an A53WriteIssue. Optionally,
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// instructions that cannot be dual-issued will also include the
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// A53WriteIssue2nd in their SchedRW list. That second WriteRes will
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// ensure that a second issue slot is consumed.
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def A53WriteIssue : SchedWriteRes<[]>;
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def A53WriteIssue2nd : SchedWriteRes<[]> { let Latency = 0; }
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// ALU - These are reduced to 1 despite a true latency of 4 in order to easily
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// model forwarding logic. Once forwarding is properly modelled, then
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// they'll be corrected.
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def : WriteRes<WriteALU, [A53UnitALU]> { let Latency = 1; }
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def : WriteRes<WriteALUs, [A53UnitALU]> { let Latency = 1; }
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def : WriteRes<WriteCMP, [A53UnitALU]> { let Latency = 1; }
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// MAC
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def : WriteRes<WriteMAC, [A53UnitMAC]> { let Latency = 4; }
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// Div
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def : WriteRes<WriteDiv, [A53UnitDiv]> { let Latency = 4; }
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// Load - Note: Vector loads take 1-5 cycles to issue. For the WriteVecLd below,
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// choosing the median of 3 which makes the latency 6. May model this more
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// carefully in the future.
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def : WriteRes<WriteLd, [A53UnitLdSt]> { let Latency = 4; }
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def : WriteRes<WritePreLd, [A53UnitLdSt]> { let Latency = 4; }
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def : WriteRes<WriteVecLd, [A53UnitLdSt]> { let Latency = 6; }
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// Store - Note: Vector stores take 1-3 cycles to issue. For the ReadVecSt below,
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// choosing the median of 2 which makes the latency 5. May model this more
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// carefully in the future.
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def : WriteRes<WriteSt, [A53UnitLdSt]> { let Latency = 4; }
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def : WriteRes<WriteVecSt, [A53UnitLdSt]> { let Latency = 5; }
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// Branch
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def : WriteRes<WriteBr, [A53UnitB]>;
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def : WriteRes<WriteBrL, [A53UnitB]>;
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// FP ALU
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def : WriteRes<WriteFPALU, [A53UnitFPALU]> {let Latency = 6; }
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// FP MAC, Mul, Div, Sqrt
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// Using Double Precision numbers for now as a worst case. Additionally, not
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// modeling the exact hazard but instead treating the whole pipe as a hazard.
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// As an example VMUL, VMLA, and others are actually pipelined. VDIV and VSQRT
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// have a total latency of 33 and 32 respectively but only a hazard of 29 and
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// 28 (double-prescion example).
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def : WriteRes<WriteFPMAC, [A53UnitFPMDS]> { let Latency = 10; }
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def : WriteRes<WriteFPMul, [A53UnitFPMDS]> { let Latency = 6; }
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def : WriteRes<WriteFPDiv, [A53UnitFPMDS]> { let Latency = 33;
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let ResourceCycles = [29]; }
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def : WriteRes<WriteFPSqrt, [A53UnitFPMDS]> { let Latency = 32;
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let ResourceCycles = [28]; }
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//===----------------------------------------------------------------------===//
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// Subtarget-specific SchedRead types.
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// No forwarding defined for ReadALU yet.
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def : ReadAdvance<ReadALU, 0>;
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// No forwarding defined for ReadCMP yet.
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def : ReadAdvance<ReadCMP, 0>;
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// No forwarding defined for ReadBr yet.
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def : ReadAdvance<ReadBr, 0>;
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// No forwarding defined for ReadMAC yet.
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def : ReadAdvance<ReadMAC, 0>;
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// No forwarding defined for ReadDiv yet.
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def : ReadAdvance<ReadDiv, 0>;
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// No forwarding defined for ReadLd, ReadPreLd, ReadVecLd yet.
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def : ReadAdvance<ReadLd, 0>;
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def : ReadAdvance<ReadPreLd, 0>;
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def : ReadAdvance<ReadVecLd, 0>;
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// No forwarding defined for ReadSt and ReadVecSt yet.
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def : ReadAdvance<ReadSt, 0>;
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def : ReadAdvance<ReadVecSt, 0>;
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// No forwarding defined for ReadFPALU yet.
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def : ReadAdvance<ReadFPALU, 0>;
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// No forwarding defined for ReadFPMAC/Mul/Div/Sqrt yet.
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def : ReadAdvance<ReadFPMAC, 0>;
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def : ReadAdvance<ReadFPMul, 0>;
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def : ReadAdvance<ReadFPDiv, 0>;
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def : ReadAdvance<ReadFPSqrt, 0>;
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}
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