//===-- llvm/MC/MCSchedule.h - Scheduling -----------------------*- C++ -*-===// // // 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 // //===----------------------------------------------------------------------===// // // This file defines the classes used to describe a subtarget's machine model // for scheduling and other instruction cost heuristics. // //===----------------------------------------------------------------------===// #ifndef LLVM_MC_MCSCHEDULE_H #define LLVM_MC_MCSCHEDULE_H #include "llvm/ADT/Optional.h" #include "llvm/Config/llvm-config.h" #include "llvm/Support/DataTypes.h" #include namespace llvm { template class ArrayRef; struct InstrItinerary; class MCSubtargetInfo; class MCInstrInfo; class MCInst; class InstrItineraryData; /// Define a kind of processor resource that will be modeled by the scheduler. struct MCProcResourceDesc { const char *Name; unsigned NumUnits; // Number of resource of this kind unsigned SuperIdx; // Index of the resources kind that contains this kind. // Number of resources that may be buffered. // // Buffered resources (BufferSize != 0) may be consumed at some indeterminate // cycle after dispatch. This should be used for out-of-order cpus when // instructions that use this resource can be buffered in a reservaton // station. // // Unbuffered resources (BufferSize == 0) always consume their resource some // fixed number of cycles after dispatch. If a resource is unbuffered, then // the scheduler will avoid scheduling instructions with conflicting resources // in the same cycle. This is for in-order cpus, or the in-order portion of // an out-of-order cpus. int BufferSize; // If the resource has sub-units, a pointer to the first element of an array // of `NumUnits` elements containing the ProcResourceIdx of the sub units. // nullptr if the resource does not have sub-units. const unsigned *SubUnitsIdxBegin; bool operator==(const MCProcResourceDesc &Other) const { return NumUnits == Other.NumUnits && SuperIdx == Other.SuperIdx && BufferSize == Other.BufferSize; } }; /// Identify one of the processor resource kinds consumed by a particular /// scheduling class for the specified number of cycles. struct MCWriteProcResEntry { uint16_t ProcResourceIdx; uint16_t Cycles; bool operator==(const MCWriteProcResEntry &Other) const { return ProcResourceIdx == Other.ProcResourceIdx && Cycles == Other.Cycles; } }; /// Specify the latency in cpu cycles for a particular scheduling class and def /// index. -1 indicates an invalid latency. Heuristics would typically consider /// an instruction with invalid latency to have infinite latency. Also identify /// the WriteResources of this def. When the operand expands to a sequence of /// writes, this ID is the last write in the sequence. struct MCWriteLatencyEntry { int16_t Cycles; uint16_t WriteResourceID; bool operator==(const MCWriteLatencyEntry &Other) const { return Cycles == Other.Cycles && WriteResourceID == Other.WriteResourceID; } }; /// Specify the number of cycles allowed after instruction issue before a /// particular use operand reads its registers. This effectively reduces the /// write's latency. Here we allow negative cycles for corner cases where /// latency increases. This rule only applies when the entry's WriteResource /// matches the write's WriteResource. /// /// MCReadAdvanceEntries are sorted first by operand index (UseIdx), then by /// WriteResourceIdx. struct MCReadAdvanceEntry { unsigned UseIdx; unsigned WriteResourceID; int Cycles; bool operator==(const MCReadAdvanceEntry &Other) const { return UseIdx == Other.UseIdx && WriteResourceID == Other.WriteResourceID && Cycles == Other.Cycles; } }; /// Summarize the scheduling resources required for an instruction of a /// particular scheduling class. /// /// Defined as an aggregate struct for creating tables with initializer lists. struct MCSchedClassDesc { static const unsigned short InvalidNumMicroOps = (1U << 14) - 1; static const unsigned short VariantNumMicroOps = InvalidNumMicroOps - 1; #if !defined(NDEBUG) || defined(LLVM_ENABLE_DUMP) const char* Name; #endif uint16_t NumMicroOps : 14; bool BeginGroup : 1; bool EndGroup : 1; uint16_t WriteProcResIdx; // First index into WriteProcResTable. uint16_t NumWriteProcResEntries; uint16_t WriteLatencyIdx; // First index into WriteLatencyTable. uint16_t NumWriteLatencyEntries; uint16_t ReadAdvanceIdx; // First index into ReadAdvanceTable. uint16_t NumReadAdvanceEntries; bool isValid() const { return NumMicroOps != InvalidNumMicroOps; } bool isVariant() const { return NumMicroOps == VariantNumMicroOps; } }; /// Specify the cost of a register definition in terms of number of physical /// register allocated at register renaming stage. For example, AMD Jaguar. /// natively supports 128-bit data types, and operations on 256-bit registers /// (i.e. YMM registers) are internally split into two COPs (complex operations) /// and each COP updates a physical register. Basically, on Jaguar, a YMM /// register write effectively consumes two physical registers. That means, /// the cost of a YMM write in the BtVer2 model is 2. struct MCRegisterCostEntry { unsigned RegisterClassID; unsigned Cost; bool AllowMoveElimination; }; /// A register file descriptor. /// /// This struct allows to describe processor register files. In particular, it /// helps describing the size of the register file, as well as the cost of /// allocating a register file at register renaming stage. /// FIXME: this struct can be extended to provide information about the number /// of read/write ports to the register file. A value of zero for field /// 'NumPhysRegs' means: this register file has an unbounded number of physical /// registers. struct MCRegisterFileDesc { const char *Name; uint16_t NumPhysRegs; uint16_t NumRegisterCostEntries; // Index of the first cost entry in MCExtraProcessorInfo::RegisterCostTable. uint16_t RegisterCostEntryIdx; // A value of zero means: there is no limit in the number of moves that can be // eliminated every cycle. uint16_t MaxMovesEliminatedPerCycle; // Ture if this register file only knows how to optimize register moves from // known zero registers. bool AllowZeroMoveEliminationOnly; }; /// Provide extra details about the machine processor. /// /// This is a collection of "optional" processor information that is not /// normally used by the LLVM machine schedulers, but that can be consumed by /// external tools like llvm-mca to improve the quality of the peformance /// analysis. struct MCExtraProcessorInfo { // Actual size of the reorder buffer in hardware. unsigned ReorderBufferSize; // Number of instructions retired per cycle. unsigned MaxRetirePerCycle; const MCRegisterFileDesc *RegisterFiles; unsigned NumRegisterFiles; const MCRegisterCostEntry *RegisterCostTable; unsigned NumRegisterCostEntries; unsigned LoadQueueID; unsigned StoreQueueID; }; /// Machine model for scheduling, bundling, and heuristics. /// /// The machine model directly provides basic information about the /// microarchitecture to the scheduler in the form of properties. It also /// optionally refers to scheduler resource tables and itinerary /// tables. Scheduler resource tables model the latency and cost for each /// instruction type. Itinerary tables are an independent mechanism that /// provides a detailed reservation table describing each cycle of instruction /// execution. Subtargets may define any or all of the above categories of data /// depending on the type of CPU and selected scheduler. /// /// The machine independent properties defined here are used by the scheduler as /// an abstract machine model. A real micro-architecture has a number of /// buffers, queues, and stages. Declaring that a given machine-independent /// abstract property corresponds to a specific physical property across all /// subtargets can't be done. Nonetheless, the abstract model is /// useful. Futhermore, subtargets typically extend this model with processor /// specific resources to model any hardware features that can be exploited by /// scheduling heuristics and aren't sufficiently represented in the abstract. /// /// The abstract pipeline is built around the notion of an "issue point". This /// is merely a reference point for counting machine cycles. The physical /// machine will have pipeline stages that delay execution. The scheduler does /// not model those delays because they are irrelevant as long as they are /// consistent. Inaccuracies arise when instructions have different execution /// delays relative to each other, in addition to their intrinsic latency. Those /// special cases can be handled by TableGen constructs such as, ReadAdvance, /// which reduces latency when reading data, and ResourceCycles, which consumes /// a processor resource when writing data for a number of abstract /// cycles. /// /// TODO: One tool currently missing is the ability to add a delay to /// ResourceCycles. That would be easy to add and would likely cover all cases /// currently handled by the legacy itinerary tables. /// /// A note on out-of-order execution and, more generally, instruction /// buffers. Part of the CPU pipeline is always in-order. The issue point, which /// is the point of reference for counting cycles, only makes sense as an /// in-order part of the pipeline. Other parts of the pipeline are sometimes /// falling behind and sometimes catching up. It's only interesting to model /// those other, decoupled parts of the pipeline if they may be predictably /// resource constrained in a way that the scheduler can exploit. /// /// The LLVM machine model distinguishes between in-order constraints and /// out-of-order constraints so that the target's scheduling strategy can apply /// appropriate heuristics. For a well-balanced CPU pipeline, out-of-order /// resources would not typically be treated as a hard scheduling /// constraint. For example, in the GenericScheduler, a delay caused by limited /// out-of-order resources is not directly reflected in the number of cycles /// that the scheduler sees between issuing an instruction and its dependent /// instructions. In other words, out-of-order resources don't directly increase /// the latency between pairs of instructions. However, they can still be used /// to detect potential bottlenecks across a sequence of instructions and bias /// the scheduling heuristics appropriately. struct MCSchedModel { // IssueWidth is the maximum number of instructions that may be scheduled in // the same per-cycle group. This is meant to be a hard in-order constraint // (a.k.a. "hazard"). In the GenericScheduler strategy, no more than // IssueWidth micro-ops can ever be scheduled in a particular cycle. // // In practice, IssueWidth is useful to model any bottleneck between the // decoder (after micro-op expansion) and the out-of-order reservation // stations or the decoder bandwidth itself. If the total number of // reservation stations is also a bottleneck, or if any other pipeline stage // has a bandwidth limitation, then that can be naturally modeled by adding an // out-of-order processor resource. unsigned IssueWidth; static const unsigned DefaultIssueWidth = 1; // MicroOpBufferSize is the number of micro-ops that the processor may buffer // for out-of-order execution. // // "0" means operations that are not ready in this cycle are not considered // for scheduling (they go in the pending queue). Latency is paramount. This // may be more efficient if many instructions are pending in a schedule. // // "1" means all instructions are considered for scheduling regardless of // whether they are ready in this cycle. Latency still causes issue stalls, // but we balance those stalls against other heuristics. // // "> 1" means the processor is out-of-order. This is a machine independent // estimate of highly machine specific characteristics such as the register // renaming pool and reorder buffer. unsigned MicroOpBufferSize; static const unsigned DefaultMicroOpBufferSize = 0; // LoopMicroOpBufferSize is the number of micro-ops that the processor may // buffer for optimized loop execution. More generally, this represents the // optimal number of micro-ops in a loop body. A loop may be partially // unrolled to bring the count of micro-ops in the loop body closer to this // number. unsigned LoopMicroOpBufferSize; static const unsigned DefaultLoopMicroOpBufferSize = 0; // LoadLatency is the expected latency of load instructions. unsigned LoadLatency; static const unsigned DefaultLoadLatency = 4; // HighLatency is the expected latency of "very high latency" operations. // See TargetInstrInfo::isHighLatencyDef(). // By default, this is set to an arbitrarily high number of cycles // likely to have some impact on scheduling heuristics. unsigned HighLatency; static const unsigned DefaultHighLatency = 10; // MispredictPenalty is the typical number of extra cycles the processor // takes to recover from a branch misprediction. unsigned MispredictPenalty; static const unsigned DefaultMispredictPenalty = 10; bool PostRAScheduler; // default value is false bool CompleteModel; unsigned ProcID; const MCProcResourceDesc *ProcResourceTable; const MCSchedClassDesc *SchedClassTable; unsigned NumProcResourceKinds; unsigned NumSchedClasses; // Instruction itinerary tables used by InstrItineraryData. friend class InstrItineraryData; const InstrItinerary *InstrItineraries; const MCExtraProcessorInfo *ExtraProcessorInfo; bool hasExtraProcessorInfo() const { return ExtraProcessorInfo; } unsigned getProcessorID() const { return ProcID; } /// Does this machine model include instruction-level scheduling. bool hasInstrSchedModel() const { return SchedClassTable; } const MCExtraProcessorInfo &getExtraProcessorInfo() const { assert(hasExtraProcessorInfo() && "No extra information available for this model"); return *ExtraProcessorInfo; } /// Return true if this machine model data for all instructions with a /// scheduling class (itinerary class or SchedRW list). bool isComplete() const { return CompleteModel; } /// Return true if machine supports out of order execution. bool isOutOfOrder() const { return MicroOpBufferSize > 1; } unsigned getNumProcResourceKinds() const { return NumProcResourceKinds; } const MCProcResourceDesc *getProcResource(unsigned ProcResourceIdx) const { assert(hasInstrSchedModel() && "No scheduling machine model"); assert(ProcResourceIdx < NumProcResourceKinds && "bad proc resource idx"); return &ProcResourceTable[ProcResourceIdx]; } const MCSchedClassDesc *getSchedClassDesc(unsigned SchedClassIdx) const { assert(hasInstrSchedModel() && "No scheduling machine model"); assert(SchedClassIdx < NumSchedClasses && "bad scheduling class idx"); return &SchedClassTable[SchedClassIdx]; } /// Returns the latency value for the scheduling class. static int computeInstrLatency(const MCSubtargetInfo &STI, const MCSchedClassDesc &SCDesc); int computeInstrLatency(const MCSubtargetInfo &STI, unsigned SClass) const; int computeInstrLatency(const MCSubtargetInfo &STI, const MCInstrInfo &MCII, const MCInst &Inst) const; // Returns the reciprocal throughput information from a MCSchedClassDesc. static double getReciprocalThroughput(const MCSubtargetInfo &STI, const MCSchedClassDesc &SCDesc); static double getReciprocalThroughput(unsigned SchedClass, const InstrItineraryData &IID); double getReciprocalThroughput(const MCSubtargetInfo &STI, const MCInstrInfo &MCII, const MCInst &Inst) const; /// Returns the maximum forwarding delay for register reads dependent on /// writes of scheduling class WriteResourceIdx. static unsigned getForwardingDelayCycles(ArrayRef Entries, unsigned WriteResourceIdx = 0); /// Returns the default initialized model. static const MCSchedModel &GetDefaultSchedModel() { return Default; } static const MCSchedModel Default; }; } // namespace llvm #endif