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d773f533b9
Summary: GCNSchedStrategy re-uses most of GenericScheduler, it's just uses a different method to compute the excess and critical register pressure limits. It's not enabled by default, to enable it you need to pass -misched=gcn to llc. Shader DB stats: 32464 shaders in 17874 tests Totals: SGPRS: 1542846 -> 1643125 (6.50 %) VGPRS: 1005595 -> 904653 (-10.04 %) Spilled SGPRs: 29929 -> 27745 (-7.30 %) Spilled VGPRs: 334 -> 352 (5.39 %) Scratch VGPRs: 1612 -> 1624 (0.74 %) dwords per thread Code Size: 36688188 -> 37034900 (0.95 %) bytes LDS: 1913 -> 1913 (0.00 %) blocks Max Waves: 254101 -> 265125 (4.34 %) Wait states: 0 -> 0 (0.00 %) Totals from affected shaders: SGPRS: 1338220 -> 1438499 (7.49 %) VGPRS: 886221 -> 785279 (-11.39 %) Spilled SGPRs: 29869 -> 27685 (-7.31 %) Spilled VGPRs: 334 -> 352 (5.39 %) Scratch VGPRs: 1612 -> 1624 (0.74 %) dwords per thread Code Size: 34315716 -> 34662428 (1.01 %) bytes LDS: 1551 -> 1551 (0.00 %) blocks Max Waves: 188127 -> 199151 (5.86 %) Wait states: 0 -> 0 (0.00 %) Reviewers: arsenm, mareko, nhaehnle, MatzeB, atrick Subscribers: arsenm, kzhuravl, llvm-commits Differential Revision: https://reviews.llvm.org/D23688 llvm-svn: 279995
139 lines
4.1 KiB
TableGen
139 lines
4.1 KiB
TableGen
//===-- SISchedule.td - SI Scheduling definitons -------------------------===//
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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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// MachineModel definitions for Southern Islands (SI)
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//
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//===----------------------------------------------------------------------===//
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def : PredicateProlog<[{
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const SIInstrInfo *TII =
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static_cast<const SIInstrInfo*>(SchedModel->getInstrInfo());
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(void)TII;
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}]>;
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def WriteBranch : SchedWrite;
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def WriteExport : SchedWrite;
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def WriteLDS : SchedWrite;
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def WriteSALU : SchedWrite;
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def WriteSMEM : SchedWrite;
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def WriteVMEM : SchedWrite;
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def WriteBarrier : SchedWrite;
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// Vector ALU instructions
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def Write32Bit : SchedWrite;
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def WriteQuarterRate32 : SchedWrite;
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def WriteFullOrQuarterRate32 : SchedWrite;
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def WriteFloatFMA : SchedWrite;
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// Slow quarter rate f64 instruction.
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def WriteDouble : SchedWrite;
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// half rate f64 instruction (same as v_add_f64)
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def WriteDoubleAdd : SchedWrite;
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// Half rate 64-bit instructions.
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def Write64Bit : SchedWrite;
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// FIXME: Should there be a class for instructions which are VALU
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// instructions and have VALU rates, but write to the SALU (i.e. VOPC
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// instructions)
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class SISchedMachineModel : SchedMachineModel {
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let CompleteModel = 1;
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// MicroOpBufferSize = 1 means that instructions will always be added
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// the ready queue when they become available. This exposes them
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// to the register pressure analysis.
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let MicroOpBufferSize = 1;
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let IssueWidth = 1;
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let PostRAScheduler = 1;
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}
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def SIFullSpeedModel : SISchedMachineModel;
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def SIQuarterSpeedModel : SISchedMachineModel;
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// XXX: Are the resource counts correct?
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def HWBranch : ProcResource<1> {
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let BufferSize = 1;
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}
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def HWExport : ProcResource<1> {
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let BufferSize = 7; // Taken from S_WAITCNT
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}
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def HWLGKM : ProcResource<1> {
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let BufferSize = 31; // Taken from S_WAITCNT
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}
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def HWSALU : ProcResource<1> {
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let BufferSize = 1;
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}
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def HWVMEM : ProcResource<1> {
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let BufferSize = 15; // Taken from S_WAITCNT
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}
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def HWVALU : ProcResource<1> {
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let BufferSize = 1;
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}
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class HWWriteRes<SchedWrite write, list<ProcResourceKind> resources,
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int latency> : WriteRes<write, resources> {
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let Latency = latency;
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}
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class HWVALUWriteRes<SchedWrite write, int latency> :
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HWWriteRes<write, [HWVALU], latency>;
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// The latency numbers are taken from AMD Accelerated Parallel Processing
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// guide. They may not be accurate.
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// The latency values are 1 / (operations / cycle) / 4.
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multiclass SICommonWriteRes {
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def : HWWriteRes<WriteBranch, [HWBranch], 8>;
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def : HWWriteRes<WriteExport, [HWExport], 4>;
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def : HWWriteRes<WriteLDS, [HWLGKM], 5>; // Can be between 2 and 64
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def : HWWriteRes<WriteSALU, [HWSALU], 1>;
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def : HWWriteRes<WriteSMEM, [HWLGKM], 5>;
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def : HWWriteRes<WriteVMEM, [HWVMEM], 80>;
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def : HWWriteRes<WriteBarrier, [HWBranch], 500>; // XXX: Guessed ???
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def : HWVALUWriteRes<Write32Bit, 1>;
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def : HWVALUWriteRes<Write64Bit, 2>;
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def : HWVALUWriteRes<WriteQuarterRate32, 4>;
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}
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def PredIsVGPR32Copy : SchedPredicate<[{TII->isVGPRCopy(*MI) && TII->getOpSize(*MI, 0) <= 32}]>;
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def PredIsVGPR64Copy : SchedPredicate<[{TII->isVGPRCopy(*MI) && TII->getOpSize(*MI, 0) > 32}]>;
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def WriteCopy : SchedWriteVariant<[
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SchedVar<PredIsVGPR32Copy, [Write32Bit]>,
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SchedVar<PredIsVGPR64Copy, [Write64Bit]>,
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SchedVar<NoSchedPred, [WriteSALU]>]>;
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let SchedModel = SIFullSpeedModel in {
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defm : SICommonWriteRes;
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def : HWVALUWriteRes<WriteFloatFMA, 1>;
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def : HWVALUWriteRes<WriteDouble, 4>;
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def : HWVALUWriteRes<WriteDoubleAdd, 2>;
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def : InstRW<[WriteCopy], (instrs COPY)>;
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} // End SchedModel = SIFullSpeedModel
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let SchedModel = SIQuarterSpeedModel in {
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defm : SICommonWriteRes;
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def : HWVALUWriteRes<WriteFloatFMA, 16>;
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def : HWVALUWriteRes<WriteDouble, 16>;
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def : HWVALUWriteRes<WriteDoubleAdd, 8>;
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def : InstRW<[WriteCopy], (instrs COPY)>;
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} // End SchedModel = SIQuarterSpeedModel
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