//===-- ARMSchedule.td - ARM Scheduling Definitions --------*- tablegen -*-===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// //===----------------------------------------------------------------------===// // Instruction scheduling annotations for in-order and out-of-order CPUs. // These annotations are independent of the itinerary class defined below. // Here we define the subtarget independent read/write per-operand resources. // The subtarget schedule definitions will then map these to the subtarget's // resource usages. // For example: // The instruction cycle timings table might contain an entry for an operation // like the following: // Rd <- ADD Rn, Rm, <shift> Rs // Uops | Latency from register | Uops - resource requirements - latency // 2 | Rn: 1 Rm: 4 Rs: 4 | uop T0, Rm, Rs - P01 - 3 // | | uopc Rd, Rn, T0 - P01 - 1 // This is telling us that the result will be available in destination register // Rd after a minimum of three cycles after the result in Rm and Rs is available // and one cycle after the result in Rn is available. The micro-ops can execute // on resource P01. // To model this, we need to express that we need to dispatch two micro-ops, // that the resource P01 is needed and that the latency to Rn is different than // the latency to Rm and Rs. The scheduler can decrease Rn's producer latency by // two. // We will do this by assigning (abstract) resources to register defs/uses. // ARMSchedule.td: // def WriteALUsr : SchedWrite; // def ReadAdvanceALUsr : ScheRead; // // ARMInstrInfo.td: // def ADDrs : I<>, Sched<[WriteALUsr, ReadAdvanceALUsr, ReadDefault, // ReadDefault]> { ...} // ReadAdvance read resources allow us to define "pipeline by-passes" or // shorter latencies to certain registers as needed in the example above. // The "ReadDefault" can be omitted. // Next, the subtarget td file assigns resources to the abstract resources // defined here. // ARMScheduleSubtarget.td: // // Resources. // def P01 : ProcResource<3>; // ALU unit (3 of it). // ... // // Resource usages. // def : WriteRes<WriteALUsr, [P01, P01]> { // Latency = 4; // Latency of 4. // NumMicroOps = 2; // Dispatch 2 micro-ops. // // The two instances of resource P01 are occupied for one cycle. It is one // // cycle because these resources happen to be pipelined. // ResourceCycles = [1, 1]; // } // def : ReadAdvance<ReadAdvanceALUsr, 3>; //===----------------------------------------------------------------------===// // Sched definitions for integer pipeline instructions // // Basic ALU operation. def WriteALU : SchedWrite; def ReadALU : SchedRead; // Basic ALU with shifts. def WriteALUsi : SchedWrite; // Shift by immediate. def WriteALUsr : SchedWrite; // Shift by register. def WriteALUSsr : SchedWrite; // Shift by register (flag setting). def ReadALUsr : SchedRead; // Some operands are read later. // Compares. def WriteCMP : SchedWrite; def WriteCMPsi : SchedWrite; def WriteCMPsr : SchedWrite; // Multiplys. def WriteMUL16 : SchedWrite; // 16-bit multiply. def WriteMUL32 : SchedWrite; // 32-bit multiply. def WriteMUL64Lo : SchedWrite; // 64-bit result. Low reg. def WriteMUL64Hi : SchedWrite; // 64-bit result. High reg. def ReadMUL : SchedRead; // Multiply-accumulates. def WriteMAC16 : SchedWrite; // 16-bit mac. def WriteMAC32 : SchedWrite; // 32-bit mac. def WriteMAC64Lo : SchedWrite; // 64-bit mac. Low reg. def WriteMAC64Hi : SchedWrite; // 64-bit mac. High reg. def ReadMAC : SchedRead; // Divisions. def WriteDIV : SchedWrite; // Loads/Stores. def WriteLd : SchedWrite; def WritePreLd : SchedWrite; def WriteST : SchedWrite; // Branches. def WriteBr : SchedWrite; def WriteBrL : SchedWrite; def WriteBrTbl : SchedWrite; // Noop. def WriteNoop : SchedWrite; //===----------------------------------------------------------------------===// // Sched definitions for floating-point and neon instructions // // Floating point conversions def WriteFPCVT : SchedWrite; def WriteFPMOV : SchedWrite; // FP -> GPR and vice-versa // ALU operations (32/64-bit) def WriteFPALU32 : SchedWrite; def WriteFPALU64 : SchedWrite; // Multiplication def WriteFPMUL32 : SchedWrite; def WriteFPMUL64 : SchedWrite; def ReadFPMUL : SchedRead; // multiplier read def ReadFPMAC : SchedRead; // accumulator read // Multiply-accumulate def WriteFPMAC32 : SchedWrite; def WriteFPMAC64 : SchedWrite; // Division def WriteFPDIV32 : SchedWrite; def WriteFPDIV64 : SchedWrite; // Square-root def WriteFPSQRT32 : SchedWrite; def WriteFPSQRT64 : SchedWrite; // Vector load and stores def WriteVLD1 : SchedWrite; def WriteVLD2 : SchedWrite; def WriteVLD3 : SchedWrite; def WriteVLD4 : SchedWrite; def WriteVST1 : SchedWrite; def WriteVST2 : SchedWrite; def WriteVST3 : SchedWrite; def WriteVST4 : SchedWrite; // Define TII for use in SchedVariant Predicates. def : PredicateProlog<[{ const ARMBaseInstrInfo *TII = static_cast<const ARMBaseInstrInfo*>(SchedModel->getInstrInfo()); (void)TII; const ARMSubtarget *STI = static_cast<const ARMSubtarget*>(SchedModel->getSubtargetInfo()); (void)STI; }]>; def IsPredicated : CheckFunctionPredicateWithTII< "ARM_MC::isPredicated", "isPredicated" >; def IsPredicatedPred : MCSchedPredicate<IsPredicated>; def IsCPSRDefined : CheckFunctionPredicateWithTII< "ARM_MC::isCPSRDefined", "ARMBaseInstrInfo::isCPSRDefined" >; def IsCPSRDefinedPred : MCSchedPredicate<IsCPSRDefined>; let FunctionMapper = "ARM_AM::getAM2ShiftOpc" in { class CheckAM2NoShift<int n> : CheckImmOperand_s<n, "ARM_AM::no_shift">; class CheckAM2ShiftLSL<int n> : CheckImmOperand_s<n, "ARM_AM::lsl">; } let FunctionMapper = "ARM_AM::getAM2Op" in { class CheckAM2OpAdd<int n> : CheckImmOperand_s<n, "ARM_AM::add"> {} class CheckAM2OpSub<int n> : CheckImmOperand_s<n, "ARM_AM::sub"> {} } let FunctionMapper = "ARM_AM::getAM2Offset" in { class CheckAM2Offset<int n, int of> : CheckImmOperand<n, of> {} } def IsLDMBaseRegInList : CheckFunctionPredicate< "ARM_MC::isLDMBaseRegInList", "ARM_MC::isLDMBaseRegInList" >; let FunctionMapper = "ARM_AM::getAM3Op" in { class CheckAM3OpSub<int n> : CheckImmOperand_s<n, "ARM_AM::sub"> {} } // LDM, base reg in list def IsLDMBaseRegInListPred : MCSchedPredicate<IsLDMBaseRegInList>; class IsRegPCPred<int n> : MCSchedPredicate<CheckRegOperand<n, PC>>; class BranchWriteRes<int lat, int uops, list<ProcResourceKind> resl, list<int> rcl, SchedWriteRes wr> : SchedWriteRes<!listconcat(wr.ProcResources, resl)> { let Latency = !add(wr.Latency, lat); let ResourceCycles = !listconcat(wr.ResourceCycles, rcl); let NumMicroOps = !add(wr.NumMicroOps, uops); SchedWriteRes BaseWr = wr; } class CheckBranchForm<int n, BranchWriteRes br> : SchedWriteVariant<[ SchedVar<IsRegPCPred<n>, [br]>, SchedVar<NoSchedPred, [br.BaseWr]> ]>; //===----------------------------------------------------------------------===// // Instruction Itinerary classes used for ARM // def IIC_iALUx : InstrItinClass; def IIC_iALUi : InstrItinClass; def IIC_iALUr : InstrItinClass; def IIC_iALUsi : InstrItinClass; def IIC_iALUsir : InstrItinClass; def IIC_iALUsr : InstrItinClass; def IIC_iBITi : InstrItinClass; def IIC_iBITr : InstrItinClass; def IIC_iBITsi : InstrItinClass; def IIC_iBITsr : InstrItinClass; def IIC_iUNAr : InstrItinClass; def IIC_iUNAsi : InstrItinClass; def IIC_iEXTr : InstrItinClass; def IIC_iEXTAr : InstrItinClass; def IIC_iEXTAsr : InstrItinClass; def IIC_iCMPi : InstrItinClass; def IIC_iCMPr : InstrItinClass; def IIC_iCMPsi : InstrItinClass; def IIC_iCMPsr : InstrItinClass; def IIC_iTSTi : InstrItinClass; def IIC_iTSTr : InstrItinClass; def IIC_iTSTsi : InstrItinClass; def IIC_iTSTsr : InstrItinClass; def IIC_iMOVi : InstrItinClass; def IIC_iMOVr : InstrItinClass; def IIC_iMOVsi : InstrItinClass; def IIC_iMOVsr : InstrItinClass; def IIC_iMOVix2 : InstrItinClass; def IIC_iMOVix2addpc : InstrItinClass; def IIC_iMOVix2ld : InstrItinClass; def IIC_iMVNi : InstrItinClass; def IIC_iMVNr : InstrItinClass; def IIC_iMVNsi : InstrItinClass; def IIC_iMVNsr : InstrItinClass; def IIC_iCMOVi : InstrItinClass; def IIC_iCMOVr : InstrItinClass; def IIC_iCMOVsi : InstrItinClass; def IIC_iCMOVsr : InstrItinClass; def IIC_iCMOVix2 : InstrItinClass; def IIC_iMUL16 : InstrItinClass; def IIC_iMAC16 : InstrItinClass; def IIC_iMUL32 : InstrItinClass; def IIC_iMAC32 : InstrItinClass; def IIC_iMUL64 : InstrItinClass; def IIC_iMAC64 : InstrItinClass; def IIC_iDIV : InstrItinClass; def IIC_iLoad_i : InstrItinClass; def IIC_iLoad_r : InstrItinClass; def IIC_iLoad_si : InstrItinClass; def IIC_iLoad_iu : InstrItinClass; def IIC_iLoad_ru : InstrItinClass; def IIC_iLoad_siu : InstrItinClass; def IIC_iLoad_bh_i : InstrItinClass; def IIC_iLoad_bh_r : InstrItinClass; def IIC_iLoad_bh_si : InstrItinClass; def IIC_iLoad_bh_iu : InstrItinClass; def IIC_iLoad_bh_ru : InstrItinClass; def IIC_iLoad_bh_siu : InstrItinClass; def IIC_iLoad_d_i : InstrItinClass; def IIC_iLoad_d_r : InstrItinClass; def IIC_iLoad_d_ru : InstrItinClass; def IIC_iLoad_m : InstrItinClass; def IIC_iLoad_mu : InstrItinClass; def IIC_iLoad_mBr : InstrItinClass; def IIC_iPop : InstrItinClass; def IIC_iPop_Br : InstrItinClass; def IIC_iLoadiALU : InstrItinClass; def IIC_iStore_i : InstrItinClass; def IIC_iStore_r : InstrItinClass; def IIC_iStore_si : InstrItinClass; def IIC_iStore_iu : InstrItinClass; def IIC_iStore_ru : InstrItinClass; def IIC_iStore_siu : InstrItinClass; def IIC_iStore_bh_i : InstrItinClass; def IIC_iStore_bh_r : InstrItinClass; def IIC_iStore_bh_si : InstrItinClass; def IIC_iStore_bh_iu : InstrItinClass; def IIC_iStore_bh_ru : InstrItinClass; def IIC_iStore_bh_siu : InstrItinClass; def IIC_iStore_d_i : InstrItinClass; def IIC_iStore_d_r : InstrItinClass; def IIC_iStore_d_ru : InstrItinClass; def IIC_iStore_m : InstrItinClass; def IIC_iStore_mu : InstrItinClass; def IIC_Preload : InstrItinClass; def IIC_Br : InstrItinClass; def IIC_fpSTAT : InstrItinClass; def IIC_fpUNA16 : InstrItinClass; def IIC_fpUNA32 : InstrItinClass; def IIC_fpUNA64 : InstrItinClass; def IIC_fpCMP16 : InstrItinClass; def IIC_fpCMP32 : InstrItinClass; def IIC_fpCMP64 : InstrItinClass; def IIC_fpCVTSD : InstrItinClass; def IIC_fpCVTDS : InstrItinClass; def IIC_fpCVTSH : InstrItinClass; def IIC_fpCVTHS : InstrItinClass; def IIC_fpCVTIH : InstrItinClass; def IIC_fpCVTIS : InstrItinClass; def IIC_fpCVTID : InstrItinClass; def IIC_fpCVTHI : InstrItinClass; def IIC_fpCVTSI : InstrItinClass; def IIC_fpCVTDI : InstrItinClass; def IIC_fpMOVIS : InstrItinClass; def IIC_fpMOVID : InstrItinClass; def IIC_fpMOVSI : InstrItinClass; def IIC_fpMOVDI : InstrItinClass; def IIC_fpALU16 : InstrItinClass; def IIC_fpALU32 : InstrItinClass; def IIC_fpALU64 : InstrItinClass; def IIC_fpMUL16 : InstrItinClass; def IIC_fpMUL32 : InstrItinClass; def IIC_fpMUL64 : InstrItinClass; def IIC_fpMAC16 : InstrItinClass; def IIC_fpMAC32 : InstrItinClass; def IIC_fpMAC64 : InstrItinClass; def IIC_fpFMAC16 : InstrItinClass; def IIC_fpFMAC32 : InstrItinClass; def IIC_fpFMAC64 : InstrItinClass; def IIC_fpDIV16 : InstrItinClass; def IIC_fpDIV32 : InstrItinClass; def IIC_fpDIV64 : InstrItinClass; def IIC_fpSQRT16 : InstrItinClass; def IIC_fpSQRT32 : InstrItinClass; def IIC_fpSQRT64 : InstrItinClass; def IIC_fpLoad16 : InstrItinClass; def IIC_fpLoad32 : InstrItinClass; def IIC_fpLoad64 : InstrItinClass; def IIC_fpLoad_m : InstrItinClass; def IIC_fpLoad_mu : InstrItinClass; def IIC_fpStore16 : InstrItinClass; def IIC_fpStore32 : InstrItinClass; def IIC_fpStore64 : InstrItinClass; def IIC_fpStore_m : InstrItinClass; def IIC_fpStore_mu : InstrItinClass; def IIC_VLD1 : InstrItinClass; def IIC_VLD1x2 : InstrItinClass; def IIC_VLD1x3 : InstrItinClass; def IIC_VLD1x4 : InstrItinClass; def IIC_VLD1u : InstrItinClass; def IIC_VLD1x2u : InstrItinClass; def IIC_VLD1x3u : InstrItinClass; def IIC_VLD1x4u : InstrItinClass; def IIC_VLD1ln : InstrItinClass; def IIC_VLD1lnu : InstrItinClass; def IIC_VLD1dup : InstrItinClass; def IIC_VLD1dupu : InstrItinClass; def IIC_VLD2 : InstrItinClass; def IIC_VLD2x2 : InstrItinClass; def IIC_VLD2u : InstrItinClass; def IIC_VLD2x2u : InstrItinClass; def IIC_VLD2ln : InstrItinClass; def IIC_VLD2lnu : InstrItinClass; def IIC_VLD2dup : InstrItinClass; def IIC_VLD2dupu : InstrItinClass; def IIC_VLD3 : InstrItinClass; def IIC_VLD3ln : InstrItinClass; def IIC_VLD3u : InstrItinClass; def IIC_VLD3lnu : InstrItinClass; def IIC_VLD3dup : InstrItinClass; def IIC_VLD3dupu : InstrItinClass; def IIC_VLD4 : InstrItinClass; def IIC_VLD4ln : InstrItinClass; def IIC_VLD4u : InstrItinClass; def IIC_VLD4lnu : InstrItinClass; def IIC_VLD4dup : InstrItinClass; def IIC_VLD4dupu : InstrItinClass; def IIC_VST1 : InstrItinClass; def IIC_VST1x2 : InstrItinClass; def IIC_VST1x3 : InstrItinClass; def IIC_VST1x4 : InstrItinClass; def IIC_VST1u : InstrItinClass; def IIC_VST1x2u : InstrItinClass; def IIC_VST1x3u : InstrItinClass; def IIC_VST1x4u : InstrItinClass; def IIC_VST1ln : InstrItinClass; def IIC_VST1lnu : InstrItinClass; def IIC_VST2 : InstrItinClass; def IIC_VST2x2 : InstrItinClass; def IIC_VST2u : InstrItinClass; def IIC_VST2x2u : InstrItinClass; def IIC_VST2ln : InstrItinClass; def IIC_VST2lnu : InstrItinClass; def IIC_VST3 : InstrItinClass; def IIC_VST3u : InstrItinClass; def IIC_VST3ln : InstrItinClass; def IIC_VST3lnu : InstrItinClass; def IIC_VST4 : InstrItinClass; def IIC_VST4u : InstrItinClass; def IIC_VST4ln : InstrItinClass; def IIC_VST4lnu : InstrItinClass; def IIC_VUNAD : InstrItinClass; def IIC_VUNAQ : InstrItinClass; def IIC_VBIND : InstrItinClass; def IIC_VBINQ : InstrItinClass; def IIC_VPBIND : InstrItinClass; def IIC_VFMULD : InstrItinClass; def IIC_VFMULQ : InstrItinClass; def IIC_VMOV : InstrItinClass; def IIC_VMOVImm : InstrItinClass; def IIC_VMOVD : InstrItinClass; def IIC_VMOVQ : InstrItinClass; def IIC_VMOVIS : InstrItinClass; def IIC_VMOVID : InstrItinClass; def IIC_VMOVISL : InstrItinClass; def IIC_VMOVSI : InstrItinClass; def IIC_VMOVDI : InstrItinClass; def IIC_VMOVN : InstrItinClass; def IIC_VPERMD : InstrItinClass; def IIC_VPERMQ : InstrItinClass; def IIC_VPERMQ3 : InstrItinClass; def IIC_VMACD : InstrItinClass; def IIC_VMACQ : InstrItinClass; def IIC_VFMACD : InstrItinClass; def IIC_VFMACQ : InstrItinClass; def IIC_VRECSD : InstrItinClass; def IIC_VRECSQ : InstrItinClass; def IIC_VCNTiD : InstrItinClass; def IIC_VCNTiQ : InstrItinClass; def IIC_VUNAiD : InstrItinClass; def IIC_VUNAiQ : InstrItinClass; def IIC_VQUNAiD : InstrItinClass; def IIC_VQUNAiQ : InstrItinClass; def IIC_VBINiD : InstrItinClass; def IIC_VBINiQ : InstrItinClass; def IIC_VSUBiD : InstrItinClass; def IIC_VSUBiQ : InstrItinClass; def IIC_VBINi4D : InstrItinClass; def IIC_VBINi4Q : InstrItinClass; def IIC_VSUBi4D : InstrItinClass; def IIC_VSUBi4Q : InstrItinClass; def IIC_VABAD : InstrItinClass; def IIC_VABAQ : InstrItinClass; def IIC_VSHLiD : InstrItinClass; def IIC_VSHLiQ : InstrItinClass; def IIC_VSHLi4D : InstrItinClass; def IIC_VSHLi4Q : InstrItinClass; def IIC_VPALiD : InstrItinClass; def IIC_VPALiQ : InstrItinClass; def IIC_VMULi16D : InstrItinClass; def IIC_VMULi32D : InstrItinClass; def IIC_VMULi16Q : InstrItinClass; def IIC_VMULi32Q : InstrItinClass; def IIC_VMACi16D : InstrItinClass; def IIC_VMACi32D : InstrItinClass; def IIC_VMACi16Q : InstrItinClass; def IIC_VMACi32Q : InstrItinClass; def IIC_VEXTD : InstrItinClass; def IIC_VEXTQ : InstrItinClass; def IIC_VTB1 : InstrItinClass; def IIC_VTB2 : InstrItinClass; def IIC_VTB3 : InstrItinClass; def IIC_VTB4 : InstrItinClass; def IIC_VTBX1 : InstrItinClass; def IIC_VTBX2 : InstrItinClass; def IIC_VTBX3 : InstrItinClass; def IIC_VTBX4 : InstrItinClass; def IIC_VDOTPROD : InstrItinClass;