//===- ModuloSchedule.h - Software pipeline schedule expansion ------------===// // // 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 // //===----------------------------------------------------------------------===// // // Software pipelining (SWP) is an instruction scheduling technique for loops // that overlaps loop iterations and exploits ILP via compiler transformations. // // There are multiple methods for analyzing a loop and creating a schedule. // An example algorithm is Swing Modulo Scheduling (implemented by the // MachinePipeliner). The details of how a schedule is arrived at are irrelevant // for the task of actually rewriting a loop to adhere to the schedule, which // is what this file does. // // A schedule is, for every instruction in a block, a Cycle and a Stage. Note // that we only support single-block loops, so "block" and "loop" can be used // interchangably. // // The Cycle of an instruction defines a partial order of the instructions in // the remapped loop. Instructions within a cycle must not consume the output // of any instruction in the same cycle. Cycle information is assumed to have // been calculated such that the processor will execute instructions in // lock-step (for example in a VLIW ISA). // // The Stage of an instruction defines the mapping between logical loop // iterations and pipelined loop iterations. An example (unrolled) pipeline // may look something like: // // I0[0] Execute instruction I0 of iteration 0 // I1[0], I0[1] Execute I0 of iteration 1 and I1 of iteration 1 // I1[1], I0[2] // I1[2], I0[3] // // In the schedule for this unrolled sequence we would say that I0 was scheduled // in stage 0 and I1 in stage 1: // // loop: // [stage 0] x = I0 // [stage 1] I1 x (from stage 0) // // And to actually generate valid code we must insert a phi: // // loop: // x' = phi(x) // x = I0 // I1 x' // // This is a simple example; the rules for how to generate correct code given // an arbitrary schedule containing loop-carried values are complex. // // Note that these examples only mention the steady-state kernel of the // generated loop; prologs and epilogs must be generated also that prime and // flush the pipeline. Doing so is nontrivial. // //===----------------------------------------------------------------------===// #ifndef LLVM_LIB_CODEGEN_MODULOSCHEDULE_H #define LLVM_LIB_CODEGEN_MODULOSCHEDULE_H #include "llvm/CodeGen/MachineFunction.h" #include "llvm/CodeGen/MachineLoopInfo.h" #include "llvm/CodeGen/MachineLoopUtils.h" #include "llvm/CodeGen/TargetInstrInfo.h" #include "llvm/CodeGen/TargetSubtargetInfo.h" #include #include namespace llvm { class MachineBasicBlock; class MachineInstr; class LiveIntervals; /// Represents a schedule for a single-block loop. For every instruction we /// maintain a Cycle and Stage. class ModuloSchedule { private: /// The block containing the loop instructions. MachineLoop *Loop; /// The instructions to be generated, in total order. Cycle provides a partial /// order; the total order within cycles has been decided by the schedule /// producer. std::vector ScheduledInstrs; /// The cycle for each instruction. DenseMap Cycle; /// The stage for each instruction. DenseMap Stage; /// The number of stages in this schedule (Max(Stage) + 1). int NumStages; public: /// Create a new ModuloSchedule. /// \arg ScheduledInstrs The new loop instructions, in total resequenced /// order. /// \arg Cycle Cycle index for all instructions in ScheduledInstrs. Cycle does /// not need to start at zero. ScheduledInstrs must be partially ordered by /// Cycle. /// \arg Stage Stage index for all instructions in ScheduleInstrs. ModuloSchedule(MachineFunction &MF, MachineLoop *Loop, std::vector ScheduledInstrs, DenseMap Cycle, DenseMap Stage) : Loop(Loop), ScheduledInstrs(ScheduledInstrs), Cycle(std::move(Cycle)), Stage(std::move(Stage)) { NumStages = 0; for (auto &KV : this->Stage) NumStages = std::max(NumStages, KV.second); ++NumStages; } /// Return the single-block loop being scheduled. MachineLoop *getLoop() const { return Loop; } /// Return the number of stages contained in this schedule, which is the /// largest stage index + 1. int getNumStages() const { return NumStages; } /// Return the first cycle in the schedule, which is the cycle index of the /// first instruction. int getFirstCycle() { return Cycle[ScheduledInstrs.front()]; } /// Return the final cycle in the schedule, which is the cycle index of the /// last instruction. int getFinalCycle() { return Cycle[ScheduledInstrs.back()]; } /// Return the stage that MI is scheduled in, or -1. int getStage(MachineInstr *MI) { auto I = Stage.find(MI); return I == Stage.end() ? -1 : I->second; } /// Return the cycle that MI is scheduled at, or -1. int getCycle(MachineInstr *MI) { auto I = Cycle.find(MI); return I == Cycle.end() ? -1 : I->second; } /// Set the stage of a newly created instruction. void setStage(MachineInstr *MI, int MIStage) { assert(Stage.count(MI) == 0); Stage[MI] = MIStage; } /// Return the rescheduled instructions in order. ArrayRef getInstructions() { return ScheduledInstrs; } void dump() { print(dbgs()); } void print(raw_ostream &OS); }; /// The ModuloScheduleExpander takes a ModuloSchedule and expands it in-place, /// rewriting the old loop and inserting prologs and epilogs as required. class ModuloScheduleExpander { public: using InstrChangesTy = DenseMap>; private: using ValueMapTy = DenseMap; using MBBVectorTy = SmallVectorImpl; using InstrMapTy = DenseMap; ModuloSchedule &Schedule; MachineFunction &MF; const TargetSubtargetInfo &ST; MachineRegisterInfo &MRI; const TargetInstrInfo *TII; LiveIntervals &LIS; MachineBasicBlock *BB; MachineBasicBlock *Preheader; MachineBasicBlock *NewKernel = nullptr; std::unique_ptr LoopInfo; /// Map for each register and the max difference between its uses and def. /// The first element in the pair is the max difference in stages. The /// second is true if the register defines a Phi value and loop value is /// scheduled before the Phi. std::map> RegToStageDiff; /// Instructions to change when emitting the final schedule. InstrChangesTy InstrChanges; void generatePipelinedLoop(); void generateProlog(unsigned LastStage, MachineBasicBlock *KernelBB, ValueMapTy *VRMap, MBBVectorTy &PrologBBs); void generateEpilog(unsigned LastStage, MachineBasicBlock *KernelBB, ValueMapTy *VRMap, MBBVectorTy &EpilogBBs, MBBVectorTy &PrologBBs); void generateExistingPhis(MachineBasicBlock *NewBB, MachineBasicBlock *BB1, MachineBasicBlock *BB2, MachineBasicBlock *KernelBB, ValueMapTy *VRMap, InstrMapTy &InstrMap, unsigned LastStageNum, unsigned CurStageNum, bool IsLast); void generatePhis(MachineBasicBlock *NewBB, MachineBasicBlock *BB1, MachineBasicBlock *BB2, MachineBasicBlock *KernelBB, ValueMapTy *VRMap, InstrMapTy &InstrMap, unsigned LastStageNum, unsigned CurStageNum, bool IsLast); void removeDeadInstructions(MachineBasicBlock *KernelBB, MBBVectorTy &EpilogBBs); void splitLifetimes(MachineBasicBlock *KernelBB, MBBVectorTy &EpilogBBs); void addBranches(MachineBasicBlock &PreheaderBB, MBBVectorTy &PrologBBs, MachineBasicBlock *KernelBB, MBBVectorTy &EpilogBBs, ValueMapTy *VRMap); bool computeDelta(MachineInstr &MI, unsigned &Delta); void updateMemOperands(MachineInstr &NewMI, MachineInstr &OldMI, unsigned Num); MachineInstr *cloneInstr(MachineInstr *OldMI, unsigned CurStageNum, unsigned InstStageNum); MachineInstr *cloneAndChangeInstr(MachineInstr *OldMI, unsigned CurStageNum, unsigned InstStageNum); void updateInstruction(MachineInstr *NewMI, bool LastDef, unsigned CurStageNum, unsigned InstrStageNum, ValueMapTy *VRMap); MachineInstr *findDefInLoop(unsigned Reg); unsigned getPrevMapVal(unsigned StageNum, unsigned PhiStage, unsigned LoopVal, unsigned LoopStage, ValueMapTy *VRMap, MachineBasicBlock *BB); void rewritePhiValues(MachineBasicBlock *NewBB, unsigned StageNum, ValueMapTy *VRMap, InstrMapTy &InstrMap); void rewriteScheduledInstr(MachineBasicBlock *BB, InstrMapTy &InstrMap, unsigned CurStageNum, unsigned PhiNum, MachineInstr *Phi, unsigned OldReg, unsigned NewReg, unsigned PrevReg = 0); bool isLoopCarried(MachineInstr &Phi); /// Return the max. number of stages/iterations that can occur between a /// register definition and its uses. unsigned getStagesForReg(int Reg, unsigned CurStage) { std::pair Stages = RegToStageDiff[Reg]; if ((int)CurStage > Schedule.getNumStages() - 1 && Stages.first == 0 && Stages.second) return 1; return Stages.first; } /// The number of stages for a Phi is a little different than other /// instructions. The minimum value computed in RegToStageDiff is 1 /// because we assume the Phi is needed for at least 1 iteration. /// This is not the case if the loop value is scheduled prior to the /// Phi in the same stage. This function returns the number of stages /// or iterations needed between the Phi definition and any uses. unsigned getStagesForPhi(int Reg) { std::pair Stages = RegToStageDiff[Reg]; if (Stages.second) return Stages.first; return Stages.first - 1; } public: /// Create a new ModuloScheduleExpander. /// \arg InstrChanges Modifications to make to instructions with memory /// operands. /// FIXME: InstrChanges is opaque and is an implementation detail of an /// optimization in MachinePipeliner that crosses abstraction boundaries. ModuloScheduleExpander(MachineFunction &MF, ModuloSchedule &S, LiveIntervals &LIS, InstrChangesTy InstrChanges) : Schedule(S), MF(MF), ST(MF.getSubtarget()), MRI(MF.getRegInfo()), TII(ST.getInstrInfo()), LIS(LIS), InstrChanges(std::move(InstrChanges)) {} /// Performs the actual expansion. void expand(); /// Performs final cleanup after expansion. void cleanup(); /// Returns the newly rewritten kernel block, or nullptr if this was /// optimized away. MachineBasicBlock *getRewrittenKernel() { return NewKernel; } }; /// A reimplementation of ModuloScheduleExpander. It works by generating a /// standalone kernel loop and peeling out the prologs and epilogs. class PeelingModuloScheduleExpander { public: PeelingModuloScheduleExpander(MachineFunction &MF, ModuloSchedule &S, LiveIntervals *LIS) : Schedule(S), MF(MF), ST(MF.getSubtarget()), MRI(MF.getRegInfo()), TII(ST.getInstrInfo()), LIS(LIS) {} void expand(); /// Runs ModuloScheduleExpander and treats it as a golden input to validate /// aspects of the code generated by PeelingModuloScheduleExpander. void validateAgainstModuloScheduleExpander(); protected: ModuloSchedule &Schedule; MachineFunction &MF; const TargetSubtargetInfo &ST; MachineRegisterInfo &MRI; const TargetInstrInfo *TII; LiveIntervals *LIS; /// The original loop block that gets rewritten in-place. MachineBasicBlock *BB; /// The original loop preheader. MachineBasicBlock *Preheader; /// All prolog and epilog blocks. SmallVector Prologs, Epilogs; /// For every block, the stages that are produced. DenseMap LiveStages; /// For every block, the stages that are available. A stage can be available /// but not produced (in the epilog) or produced but not available (in the /// prolog). DenseMap AvailableStages; /// When peeling the epilogue keep track of the distance between the phi /// nodes and the kernel. DenseMap PhiNodeLoopIteration; /// CanonicalMIs and BlockMIs form a bidirectional map between any of the /// loop kernel clones. DenseMap CanonicalMIs; DenseMap, MachineInstr *> BlockMIs; /// State passed from peelKernel to peelPrologAndEpilogs(). std::deque PeeledFront, PeeledBack; /// Illegal phis that need to be deleted once we re-link stages. SmallVector IllegalPhisToDelete; /// Converts BB from the original loop body to the rewritten, pipelined /// steady-state. void rewriteKernel(); /// Peels one iteration of the rewritten kernel (BB) in the specified /// direction. MachineBasicBlock *peelKernel(LoopPeelDirection LPD); // Delete instructions whose stage is less than MinStage in the given basic // block. void filterInstructions(MachineBasicBlock *MB, int MinStage); // Move instructions of the given stage from sourceBB to DestBB. Remap the phi // instructions to keep a valid IR. void moveStageBetweenBlocks(MachineBasicBlock *DestBB, MachineBasicBlock *SourceBB, unsigned Stage); /// Peel the kernel forwards and backwards to produce prologs and epilogs, /// and stitch them together. void peelPrologAndEpilogs(); /// All prolog and epilog blocks are clones of the kernel, so any produced /// register in one block has an corollary in all other blocks. Register getEquivalentRegisterIn(Register Reg, MachineBasicBlock *BB); /// Change all users of MI, if MI is predicated out /// (LiveStages[MI->getParent()] == false). void rewriteUsesOf(MachineInstr *MI); /// Insert branches between prologs, kernel and epilogs. void fixupBranches(); /// Create a poor-man's LCSSA by cloning only the PHIs from the kernel block /// to a block dominated by all prologs and epilogs. This allows us to treat /// the loop exiting block as any other kernel clone. MachineBasicBlock *CreateLCSSAExitingBlock(); /// Helper to get the stage of an instruction in the schedule. unsigned getStage(MachineInstr *MI) { if (CanonicalMIs.count(MI)) MI = CanonicalMIs[MI]; return Schedule.getStage(MI); } /// Helper function to find the right canonical register for a phi instruction /// coming from a peeled out prologue. Register getPhiCanonicalReg(MachineInstr* CanonicalPhi, MachineInstr* Phi); /// Target loop info before kernel peeling. std::unique_ptr LoopInfo; }; /// Expander that simply annotates each scheduled instruction with a post-instr /// symbol that can be consumed by the ModuloScheduleTest pass. /// /// The post-instr symbol is a way of annotating an instruction that can be /// roundtripped in MIR. The syntax is: /// MYINST %0, post-instr-symbol class ModuloScheduleTestAnnotater { MachineFunction &MF; ModuloSchedule &S; public: ModuloScheduleTestAnnotater(MachineFunction &MF, ModuloSchedule &S) : MF(MF), S(S) {} /// Performs the annotation. void annotate(); }; } // end namespace llvm #endif // LLVM_LIB_CODEGEN_MODULOSCHEDULE_H