//=- X86ScheduleBtVer2.td - X86 BtVer2 (Jaguar) Scheduling ---*- tablegen -*-=// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file defines the machine model for AMD btver2 (Jaguar) to support // instruction scheduling and other instruction cost heuristics. Based off AMD Software // Optimization Guide for AMD Family 16h Processors & Instruction Latency appendix. // //===----------------------------------------------------------------------===// def BtVer2Model : SchedMachineModel { // All x86 instructions are modeled as a single micro-op, and btver2 can // decode 2 instructions per cycle. let IssueWidth = 2; let MicroOpBufferSize = 64; // Retire Control Unit let LoadLatency = 5; // FPU latency (worse case cf Integer 3 cycle latency) let HighLatency = 25; let MispredictPenalty = 14; // Minimum branch misdirection penalty let PostRAScheduler = 1; // FIXME: SSE4/AVX is unimplemented. This flag is set to allow // the scheduler to assign a default model to unrecognized opcodes. let CompleteModel = 0; } let SchedModel = BtVer2Model in { // Jaguar can issue up to 6 micro-ops in one cycle def JALU0 : ProcResource<1>; // Integer Pipe0: integer ALU0 (also handle FP->INT jam) def JALU1 : ProcResource<1>; // Integer Pipe1: integer ALU1/MUL/DIV def JLAGU : ProcResource<1>; // Integer Pipe2: LAGU def JSAGU : ProcResource<1>; // Integer Pipe3: SAGU (also handles 3-operand LEA) def JFPU0 : ProcResource<1>; // Vector/FPU Pipe0: VALU0/VIMUL/FPA def JFPU1 : ProcResource<1>; // Vector/FPU Pipe1: VALU1/STC/FPM // The Integer PRF for Jaguar is 64 entries, and it holds the architectural and // speculative version of the 64-bit integer registers. // Reference: www.realworldtech.com/jaguar/4/ // // The processor always keeps the different parts of an integer register // together. An instruction that writes to a part of a register will therefore // have a false dependence on any previous write to the same register or any // part of it. // Reference: Section 21.10 "AMD Bobcat and Jaguar pipeline: Partial register // access" - Agner Fog's "microarchitecture.pdf". def JIntegerPRF : RegisterFile<64, [GR64, CCR]>; // The Jaguar FP Retire Queue renames SIMD and FP uOps onto a pool of 72 SSE // registers. Operations on 256-bit data types are cracked into two COPs. // Reference: www.realworldtech.com/jaguar/4/ def JFpuPRF: RegisterFile<72, [VR64, VR128, VR256], [1, 1, 2]>; // The retire control unit (RCU) can track up to 64 macro-ops in-flight. It can // retire up to two macro-ops per cycle. // Reference: "Software Optimization Guide for AMD Family 16h Processors" def JRCU : RetireControlUnit<64, 2>; // Integer Pipe Scheduler def JALU01 : ProcResGroup<[JALU0, JALU1]> { let BufferSize=20; } // AGU Pipe Scheduler def JLSAGU : ProcResGroup<[JLAGU, JSAGU]> { let BufferSize=12; } // Fpu Pipe Scheduler def JFPU01 : ProcResGroup<[JFPU0, JFPU1]> { let BufferSize=18; } // Functional units def JDiv : ProcResource<1>; // integer division def JMul : ProcResource<1>; // integer multiplication def JVALU0 : ProcResource<1>; // vector integer def JVALU1 : ProcResource<1>; // vector integer def JVIMUL : ProcResource<1>; // vector integer multiplication def JSTC : ProcResource<1>; // vector store/convert def JFPM : ProcResource<1>; // FP multiplication def JFPA : ProcResource<1>; // FP addition // Functional unit groups def JFPX : ProcResGroup<[JFPA, JFPM]>; def JVALU : ProcResGroup<[JVALU0, JVALU1]>; // Integer loads are 3 cycles, so ReadAfterLd registers needn't be available until 3 // cycles after the memory operand. def : ReadAdvance; // Many SchedWrites are defined in pairs with and without a folded load. // Instructions with folded loads are usually micro-fused, so they only appear // as two micro-ops when dispatched by the schedulers. // This multiclass defines the resource usage for variants with and without // folded loads. multiclass JWriteResIntPair ExePorts, int Lat, list Res = [], int UOps = 1> { // Register variant is using a single cycle on ExePort. def : WriteRes { let Latency = Lat; let ResourceCycles = Res; let NumMicroOps = UOps; } // Memory variant also uses a cycle on JLAGU and adds 3 cycles to the // latency. def : WriteRes { let Latency = !add(Lat, 3); let ResourceCycles = !if(!empty(Res), [], !listconcat([1], Res)); let NumMicroOps = UOps; } } multiclass JWriteResFpuPair ExePorts, int Lat, list Res = [], int UOps = 1> { // Register variant is using a single cycle on ExePort. def : WriteRes { let Latency = Lat; let ResourceCycles = Res; let NumMicroOps = UOps; } // Memory variant also uses a cycle on JLAGU and adds 5 cycles to the // latency. def : WriteRes { let Latency = !add(Lat, 5); let ResourceCycles = !if(!empty(Res), [], !listconcat([1], Res)); let NumMicroOps = UOps; } } multiclass JWriteResYMMPair ExePorts, int Lat, list Res = [2], int UOps = 2> { // Register variant is using a single cycle on ExePort. def : WriteRes { let Latency = Lat; let ResourceCycles = Res; let NumMicroOps = UOps; } // Memory variant also uses 2 cycles on JLAGU and adds 5 cycles to the // latency. def : WriteRes { let Latency = !add(Lat, 5); let ResourceCycles = !listconcat([2], Res); let NumMicroOps = UOps; } } // A folded store needs a cycle on the SAGU for the store data. def : WriteRes; //////////////////////////////////////////////////////////////////////////////// // Arithmetic. //////////////////////////////////////////////////////////////////////////////// defm : JWriteResIntPair; defm : JWriteResIntPair; defm : JWriteResIntPair; // i8/i16/i32 multiplication defm : JWriteResIntPair; // i64 multiplication defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : JWriteResIntPair; defm : JWriteResIntPair; defm : JWriteResIntPair; defm : JWriteResIntPair; defm : JWriteResIntPair; defm : JWriteResIntPair; defm : JWriteResIntPair; defm : JWriteResIntPair; defm : JWriteResIntPair; defm : JWriteResIntPair; // Conditional move. defm : JWriteResIntPair; // Conditional (CF + ZF flag) move. defm : X86WriteRes; // x87 conditional move. def : WriteRes; // Setcc. def : WriteRes; def : WriteRes; def : WriteRes; // This is for simple LEAs with one or two input operands. def : WriteRes; // Bit counts. defm : JWriteResIntPair; defm : JWriteResIntPair; defm : JWriteResIntPair; defm : JWriteResIntPair; defm : JWriteResIntPair; // BMI1 BEXTR, BMI2 BZHI defm : JWriteResIntPair; defm : X86WriteResPairUnsupported; //////////////////////////////////////////////////////////////////////////////// // Integer shifts and rotates. //////////////////////////////////////////////////////////////////////////////// defm : JWriteResIntPair; // SHLD/SHRD. defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; //////////////////////////////////////////////////////////////////////////////// // Loads, stores, and moves, not folded with other operations. //////////////////////////////////////////////////////////////////////////////// def : WriteRes { let Latency = 5; } def : WriteRes; def : WriteRes; def : WriteRes; // Load/store MXCSR. // FIXME: These are copy and pasted from WriteLoad/Store. def : WriteRes { let Latency = 5; } def : WriteRes; // Treat misc copies as a move. def : InstRW<[WriteMove], (instrs COPY)>; //////////////////////////////////////////////////////////////////////////////// // Idioms that clear a register, like xorps %xmm0, %xmm0. // These can often bypass execution ports completely. //////////////////////////////////////////////////////////////////////////////// def : WriteRes; //////////////////////////////////////////////////////////////////////////////// // Branches don't produce values, so they have no latency, but they still // consume resources. Indirect branches can fold loads. //////////////////////////////////////////////////////////////////////////////// defm : JWriteResIntPair; //////////////////////////////////////////////////////////////////////////////// // Special case scheduling classes. //////////////////////////////////////////////////////////////////////////////// def : WriteRes { let Latency = 100; } def : WriteRes { let Latency = 100; } def : WriteRes; // Nops don't have dependencies, so there's no actual latency, but we set this // to '1' to tell the scheduler that the nop uses an ALU slot for a cycle. def : WriteRes { let Latency = 1; } //////////////////////////////////////////////////////////////////////////////// // Floating point. This covers both scalar and vector operations. //////////////////////////////////////////////////////////////////////////////// defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : JWriteResFpuPair; defm : JWriteResFpuPair; defm : JWriteResYMMPair; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : JWriteResFpuPair; defm : JWriteResYMMPair; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : JWriteResFpuPair; defm : JWriteResYMMPair; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : JWriteResFpuPair; defm : JWriteResYMMPair; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : JWriteResFpuPair; defm : JWriteResFpuPair; defm : JWriteResYMMPair; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : JWriteResFpuPair; defm : JWriteResYMMPair; defm : X86WriteResPairUnsupported; defm : X86WriteResPairUnsupported; defm : X86WriteResPairUnsupported; defm : X86WriteResPairUnsupported; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : JWriteResFpuPair; defm : JWriteResYMMPair; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : JWriteResFpuPair; defm : JWriteResYMMPair; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : JWriteResFpuPair; defm : JWriteResYMMPair; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : JWriteResFpuPair; defm : JWriteResYMMPair; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : JWriteResFpuPair; defm : JWriteResYMMPair; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : JWriteResFpuPair; defm : JWriteResYMMPair; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : JWriteResFpuPair; defm : JWriteResYMMPair; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : JWriteResFpuPair; defm : JWriteResFpuPair; defm : JWriteResYMMPair; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : JWriteResYMMPair; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : JWriteResYMMPair; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : JWriteResYMMPair; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : JWriteResYMMPair; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : JWriteResYMMPair; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : JWriteResYMMPair; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : X86WriteResPairUnsupported; //////////////////////////////////////////////////////////////////////////////// // Conversions. //////////////////////////////////////////////////////////////////////////////// defm : JWriteResFpuPair; defm : JWriteResFpuPair; defm : JWriteResYMMPair; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : JWriteResFpuPair; defm : JWriteResYMMPair; defm : X86WriteResPairUnsupported; // FIXME: f+3 ST, LD+STC latency defm : JWriteResFpuPair; defm : JWriteResFpuPair; defm : JWriteResYMMPair; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : JWriteResFpuPair; defm : JWriteResYMMPair; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : JWriteResFpuPair; defm : JWriteResYMMPair; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : JWriteResFpuPair; defm : JWriteResYMMPair; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : JWriteResYMMPair; defm : X86WriteResPairUnsupported; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteResUnsupported; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteResUnsupported; //////////////////////////////////////////////////////////////////////////////// // Vector integer operations. //////////////////////////////////////////////////////////////////////////////// defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : JWriteResFpuPair; defm : JWriteResFpuPair; defm : X86WriteResPairUnsupported; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : JWriteResFpuPair; defm : X86WriteResPairUnsupported; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : JWriteResFpuPair; defm : X86WriteResPairUnsupported; defm : X86WriteResPairUnsupported; defm : X86WriteResPairUnsupported; defm : X86WriteResPairUnsupported; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : JWriteResFpuPair; defm : X86WriteResPairUnsupported; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : X86WriteResPairUnsupported; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : X86WriteResPairUnsupported; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : JWriteResFpuPair; defm : X86WriteResPairUnsupported; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : JWriteResFpuPair; defm : JWriteResFpuPair; defm : X86WriteResPairUnsupported; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : JWriteResFpuPair; defm : X86WriteResPairUnsupported; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : X86WriteResPairUnsupported; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : X86WriteResPairUnsupported; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : JWriteResFpuPair; defm : X86WriteResPairUnsupported; defm : X86WriteResPairUnsupported; defm : JWriteResFpuPair; defm : JWriteResYMMPair; defm : X86WriteResPairUnsupported; defm : X86WriteResPairUnsupported; defm : X86WriteResPairUnsupported; //////////////////////////////////////////////////////////////////////////////// // Vector insert/extract operations. //////////////////////////////////////////////////////////////////////////////// defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; defm : X86WriteRes; //////////////////////////////////////////////////////////////////////////////// // SSE42 String instructions. //////////////////////////////////////////////////////////////////////////////// defm : JWriteResFpuPair; defm : JWriteResFpuPair; defm : JWriteResFpuPair; defm : JWriteResFpuPair; //////////////////////////////////////////////////////////////////////////////// // MOVMSK Instructions. //////////////////////////////////////////////////////////////////////////////// def : WriteRes { let Latency = 3; } def : WriteRes { let Latency = 3; } defm : X86WriteResUnsupported; def : WriteRes { let Latency = 3; } //////////////////////////////////////////////////////////////////////////////// // AES Instructions. //////////////////////////////////////////////////////////////////////////////// defm : JWriteResFpuPair; defm : JWriteResFpuPair; defm : JWriteResFpuPair; //////////////////////////////////////////////////////////////////////////////// // Horizontal add/sub instructions. //////////////////////////////////////////////////////////////////////////////// defm : JWriteResFpuPair; defm : JWriteResYMMPair; defm : JWriteResFpuPair; defm : JWriteResFpuPair; defm : X86WriteResPairUnsupported; //////////////////////////////////////////////////////////////////////////////// // Carry-less multiplication instructions. //////////////////////////////////////////////////////////////////////////////// defm : JWriteResFpuPair; //////////////////////////////////////////////////////////////////////////////// // SSE4A instructions. //////////////////////////////////////////////////////////////////////////////// def JWriteINSERTQ: SchedWriteRes<[JFPU01, JVALU]> { let Latency = 2; let ResourceCycles = [1, 4]; } def : InstRW<[JWriteINSERTQ], (instrs INSERTQ, INSERTQI)>; //////////////////////////////////////////////////////////////////////////////// // AVX instructions. //////////////////////////////////////////////////////////////////////////////// def JWriteVBROADCASTYLd: SchedWriteRes<[JLAGU, JFPU01, JFPX]> { let Latency = 6; let ResourceCycles = [1, 2, 4]; let NumMicroOps = 2; } def : InstRW<[JWriteVBROADCASTYLd, ReadAfterLd], (instrs VBROADCASTSDYrm, VBROADCASTSSYrm)>; def JWriteJVZEROALL: SchedWriteRes<[]> { let Latency = 90; let NumMicroOps = 73; } def : InstRW<[JWriteJVZEROALL], (instrs VZEROALL)>; def JWriteJVZEROUPPER: SchedWriteRes<[]> { let Latency = 46; let NumMicroOps = 37; } def : InstRW<[JWriteJVZEROUPPER], (instrs VZEROUPPER)>; /////////////////////////////////////////////////////////////////////////////// // SchedWriteVariant definitions. /////////////////////////////////////////////////////////////////////////////// def JWriteZeroLatency : SchedWriteRes<[]> { let Latency = 0; } // Certain instructions that use the same register for both source // operands do not have a real dependency on the previous contents of the // register, and thus, do not have to wait before completing. They can be // optimized out at register renaming stage. // Reference: Section 10.8 of the "Software Optimization Guide for AMD Family // 15h Processors". // Reference: Agner's Fog "The microarchitecture of Intel, AMD and VIA CPUs", // Section 21.8 [Dependency-breaking instructions]. def JWriteZeroIdiom : SchedWriteVariant<[ SchedVar, [JWriteZeroLatency]>, SchedVar, [WriteALU]> ]>; def : InstRW<[JWriteZeroIdiom], (instrs SUB32rr, SUB64rr, XOR32rr, XOR64rr)>; def JWriteFZeroIdiom : SchedWriteVariant<[ SchedVar, [JWriteZeroLatency]>, SchedVar, [WriteFLogic]> ]>; def : InstRW<[JWriteFZeroIdiom], (instrs XORPSrr, VXORPSrr, XORPDrr, VXORPDrr, ANDNPSrr, VANDNPSrr, ANDNPDrr, VANDNPDrr)>; def JWriteVZeroIdiomLogic : SchedWriteVariant<[ SchedVar, [JWriteZeroLatency]>, SchedVar, [WriteVecLogic]> ]>; def : InstRW<[JWriteVZeroIdiomLogic], (instrs MMX_PXORirr, MMX_PANDNirr)>; def JWriteVZeroIdiomLogicX : SchedWriteVariant<[ SchedVar, [JWriteZeroLatency]>, SchedVar, [WriteVecLogicX]> ]>; def : InstRW<[JWriteVZeroIdiomLogicX], (instrs PXORrr, VPXORrr, PANDNrr, VPANDNrr)>; def JWriteVZeroIdiomALU : SchedWriteVariant<[ SchedVar, [JWriteZeroLatency]>, SchedVar, [WriteVecALU]> ]>; def : InstRW<[JWriteVZeroIdiomALU], (instrs MMX_PSUBBirr, MMX_PSUBDirr, MMX_PSUBQirr, MMX_PSUBWirr, MMX_PCMPGTBirr, MMX_PCMPGTDirr, MMX_PCMPGTWirr)>; def JWriteVZeroIdiomALUX : SchedWriteVariant<[ SchedVar, [JWriteZeroLatency]>, SchedVar, [WriteVecALUX]> ]>; def : InstRW<[JWriteVZeroIdiomALUX], (instrs PSUBBrr, VPSUBBrr, PSUBDrr, VPSUBDrr, PSUBQrr, VPSUBQrr, PSUBWrr, VPSUBWrr, PCMPGTBrr, VPCMPGTBrr, PCMPGTDrr, VPCMPGTDrr, PCMPGTQrr, VPCMPGTQrr, PCMPGTWrr, VPCMPGTWrr)>; // This write is used for slow LEA instructions. def JWrite3OpsLEA : SchedWriteRes<[JALU1, JSAGU]> { let Latency = 2; } // On Jaguar, a slow LEA is either a 3Ops LEA (base, index, offset), or an LEA // with a `Scale` value different than 1. def JSlowLEAPredicate : MCSchedPredicate< CheckAny<[ // A 3-operand LEA (base, index, offset). IsThreeOperandsLEAFn, // An LEA with a "Scale" different than 1. CheckAll<[ CheckIsImmOperand<2>, CheckNot> ]> ]> >; def JWriteLEA : SchedWriteVariant<[ SchedVar, SchedVar, [WriteLEA]> ]>; def : InstRW<[JWriteLEA], (instrs LEA32r, LEA64r, LEA64_32r)>; def JSlowLEA16r : SchedWriteRes<[JALU01]> { let Latency = 3; let ResourceCycles = [4]; } def : InstRW<[JSlowLEA16r], (instrs LEA16r)>; } // SchedModel