include/llvm/MCA/Instruction.h - llvm - Git at Google

 //===--------------------- Instruction.h ------------------------*- C++ -*-===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 /// \file
 ///
 /// This file defines abstractions used by the Pipeline to model register reads,
 /// register writes and instructions.
 ///
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_MCA_INSTRUCTION_H
 #define LLVM_MCA_INSTRUCTION_H

 #include "llvm/ADT/ArrayRef.h"
 #include "llvm/ADT/STLExtras.h"
 #include "llvm/ADT/SmallVector.h"
 #include "llvm/Support/MathExtras.h"

 #ifndef NDEBUG
 #include "llvm/Support/raw_ostream.h"
 #endif

 #include <memory>

 namespace llvm {

 namespace mca {

 constexpr int UNKNOWN_CYCLES = -512;

 /// A register write descriptor.
 struct WriteDescriptor {
   // Operand index. The index is negative for implicit writes only.
   // For implicit writes, the actual operand index is computed performing
   // a bitwise not of the OpIndex.
   int OpIndex;
   // Write latency. Number of cycles before write-back stage.
   unsigned Latency;
   // This field is set to a value different than zero only if this
   // is an implicit definition.
   unsigned RegisterID;
   // Instruction itineraries would set this field to the SchedClass ID.
   // Otherwise, it defaults to the WriteResourceID from the MCWriteLatencyEntry
   // element associated to this write.
   // When computing read latencies, this value is matched against the
   // "ReadAdvance" information. The hardware backend may implement
   // dedicated forwarding paths to quickly propagate write results to dependent
   // instructions waiting in the reservation station (effectively bypassing the
   // write-back stage).
   unsigned SClassOrWriteResourceID;
   // True only if this is a write obtained from an optional definition.
   // Optional definitions are allowed to reference regID zero (i.e. "no
   // register").
   bool IsOptionalDef;

   bool isImplicitWrite() const { return OpIndex < 0; };
 };

 /// A register read descriptor.
 struct ReadDescriptor {
   // A MCOperand index. This is used by the Dispatch logic to identify register
   // reads. Implicit reads have negative indices. The actual operand index of an
   // implicit read is the bitwise not of field OpIndex.
   int OpIndex;
   // The actual "UseIdx". This is used to query the ReadAdvance table. Explicit
   // uses always come first in the sequence of uses.
   unsigned UseIndex;
   // This field is only set if this is an implicit read.
   unsigned RegisterID;
   // Scheduling Class Index. It is used to query the scheduling model for the
   // MCSchedClassDesc object.
   unsigned SchedClassID;

   bool isImplicitRead() const { return OpIndex < 0; };
 };

 class ReadState;

 /// Tracks uses of a register definition (e.g. register write).
 ///
 /// Each implicit/explicit register write is associated with an instance of
 /// this class. A WriteState object tracks the dependent users of a
 /// register write. It also tracks how many cycles are left before the write
 /// back stage.
 class WriteState {
   const WriteDescriptor *WD;
   // On instruction issue, this field is set equal to the write latency.
   // Before instruction issue, this field defaults to -512, a special
   // value that represents an "unknown" number of cycles.
   int CyclesLeft;

   // Actual register defined by this write. This field is only used
   // to speedup queries on the register file.
   // For implicit writes, this field always matches the value of
   // field RegisterID from WD.
   unsigned RegisterID;

   // Physical register file that serves register RegisterID.
   unsigned PRFID;

   // True if this write implicitly clears the upper portion of RegisterID's
   // super-registers.
   bool ClearsSuperRegs;

   // True if this write is from a dependency breaking zero-idiom instruction.
   bool WritesZero;

   // True if this write has been eliminated at register renaming stage.
   // Example: a register move doesn't consume scheduler/pipleline resources if
   // it is eliminated at register renaming stage. It still consumes
   // decode bandwidth, and ROB entries.
   bool IsEliminated;

   // This field is set if this is a partial register write, and it has a false
   // dependency on any previous write of the same register (or a portion of it).
   // DependentWrite must be able to complete before this write completes, so
   // that we don't break the WAW, and the two writes can be merged together.
   const WriteState *DependentWrite;

   // A partial write that is in a false dependency with this write.
   WriteState *PartialWrite;

   unsigned DependentWriteCyclesLeft;

   // A list of dependent reads. Users is a set of dependent
   // reads. A dependent read is added to the set only if CyclesLeft
   // is "unknown". As soon as CyclesLeft is 'known', each user in the set
   // gets notified with the actual CyclesLeft.

   // The 'second' element of a pair is a "ReadAdvance" number of cycles.
   SmallVector<std::pair<ReadState *, int>, 4> Users;

 public:
   WriteState(const WriteDescriptor &Desc, unsigned RegID,
              bool clearsSuperRegs = false, bool writesZero = false)
       : WD(&Desc), CyclesLeft(UNKNOWN_CYCLES), RegisterID(RegID), PRFID(0),
         ClearsSuperRegs(clearsSuperRegs), WritesZero(writesZero),
         IsEliminated(false), DependentWrite(nullptr), PartialWrite(nullptr),
         DependentWriteCyclesLeft(0) {}

   WriteState(const WriteState &Other) = default;
   WriteState &operator=(const WriteState &Other) = default;

   int getCyclesLeft() const { return CyclesLeft; }
   unsigned getWriteResourceID() const { return WD->SClassOrWriteResourceID; }
   unsigned getRegisterID() const { return RegisterID; }
   unsigned getRegisterFileID() const { return PRFID; }
   unsigned getLatency() const { return WD->Latency; }

   void addUser(ReadState *Use, int ReadAdvance);
   void addUser(WriteState *Use);

   unsigned getDependentWriteCyclesLeft() const {
     return DependentWriteCyclesLeft;
   }

   unsigned getNumUsers() const {
     unsigned NumUsers = Users.size();
     if (PartialWrite)
       ++NumUsers;
     return NumUsers;
   }

   bool clearsSuperRegisters() const { return ClearsSuperRegs; }
   bool isWriteZero() const { return WritesZero; }
   bool isEliminated() const { return IsEliminated; }
   bool isExecuted() const {
     return CyclesLeft != UNKNOWN_CYCLES && CyclesLeft <= 0;
   }

   const WriteState *getDependentWrite() const { return DependentWrite; }
   void setDependentWrite(WriteState *Other) { DependentWrite = Other; }
   void writeStartEvent(unsigned Cycles) {
     DependentWriteCyclesLeft = Cycles;
     DependentWrite = nullptr;
   }

   void setWriteZero() { WritesZero = true; }
   void setEliminated() {
     assert(Users.empty() && "Write is in an inconsistent state.");
     CyclesLeft = 0;
     IsEliminated = true;
   }

   void setPRF(unsigned PRF) { PRFID = PRF; }

   // On every cycle, update CyclesLeft and notify dependent users.
   void cycleEvent();
   void onInstructionIssued();

 #ifndef NDEBUG
   void dump() const;
 #endif
 };

 /// Tracks register operand latency in cycles.
 ///
 /// A read may be dependent on more than one write. This occurs when some
 /// writes only partially update the register associated to this read.
 class ReadState {
   const ReadDescriptor *RD;
   // Physical register identified associated to this read.
   unsigned RegisterID;
   // Physical register file that serves register RegisterID.
   unsigned PRFID;
   // Number of writes that contribute to the definition of RegisterID.
   // In the absence of partial register updates, the number of DependentWrites
   // cannot be more than one.
   unsigned DependentWrites;
   // Number of cycles left before RegisterID can be read. This value depends on
   // the latency of all the dependent writes. It defaults to UNKNOWN_CYCLES.
   // It gets set to the value of field TotalCycles only when the 'CyclesLeft' of
   // every dependent write is known.
   int CyclesLeft;
   // This field is updated on every writeStartEvent(). When the number of
   // dependent writes (i.e. field DependentWrite) is zero, this value is
   // propagated to field CyclesLeft.
   unsigned TotalCycles;
   // This field is set to true only if there are no dependent writes, and
   // there are no `CyclesLeft' to wait.
   bool IsReady;
   // True if this is a read from a known zero register.
   bool IsZero;
   // True if this register read is from a dependency-breaking instruction.
   bool IndependentFromDef;

 public:
   ReadState(const ReadDescriptor &Desc, unsigned RegID)
       : RD(&Desc), RegisterID(RegID), PRFID(0), DependentWrites(0),
         CyclesLeft(UNKNOWN_CYCLES), TotalCycles(0), IsReady(true),
         IsZero(false), IndependentFromDef(false) {}

   const ReadDescriptor &getDescriptor() const { return *RD; }
   unsigned getSchedClass() const { return RD->SchedClassID; }
   unsigned getRegisterID() const { return RegisterID; }
   unsigned getRegisterFileID() const { return PRFID; }

   bool isReady() const { return IsReady; }
   bool isImplicitRead() const { return RD->isImplicitRead(); }

   bool isIndependentFromDef() const { return IndependentFromDef; }
   void setIndependentFromDef() { IndependentFromDef = true; }

   void cycleEvent();
   void writeStartEvent(unsigned Cycles);
   void setDependentWrites(unsigned Writes) {
     DependentWrites = Writes;
     IsReady = !Writes;
   }

   bool isReadZero() const { return IsZero; }
   void setReadZero() { IsZero = true; }
   void setPRF(unsigned ID) { PRFID = ID; }
 };

 /// A sequence of cycles.
 ///
 /// This class can be used as a building block to construct ranges of cycles.
 class CycleSegment {
   unsigned Begin; // Inclusive.
   unsigned End;   // Exclusive.
   bool Reserved;  // Resources associated to this segment must be reserved.

 public:
   CycleSegment(unsigned StartCycle, unsigned EndCycle, bool IsReserved = false)
       : Begin(StartCycle), End(EndCycle), Reserved(IsReserved) {}

   bool contains(unsigned Cycle) const { return Cycle >= Begin && Cycle < End; }
   bool startsAfter(const CycleSegment &CS) const { return End <= CS.Begin; }
   bool endsBefore(const CycleSegment &CS) const { return Begin >= CS.End; }
   bool overlaps(const CycleSegment &CS) const {
     return !startsAfter(CS) && !endsBefore(CS);
   }
   bool isExecuting() const { return Begin == 0 && End != 0; }
   bool isExecuted() const { return End == 0; }
   bool operator<(const CycleSegment &Other) const {
     return Begin < Other.Begin;
   }
   CycleSegment &operator--(void) {
     if (Begin)
       Begin--;
     if (End)
       End--;
     return *this;
   }

   bool isValid() const { return Begin <= End; }
   unsigned size() const { return End - Begin; };
   void subtract(unsigned Cycles) {
     assert(End >= Cycles);
     End -= Cycles;
   }

   unsigned begin() const { return Begin; }
   unsigned end() const { return End; }
   void setEnd(unsigned NewEnd) { End = NewEnd; }
   bool isReserved() const { return Reserved; }
   void setReserved() { Reserved = true; }
 };

 /// Helper used by class InstrDesc to describe how hardware resources
 /// are used.
 ///
 /// This class describes how many resource units of a specific resource kind
 /// (and how many cycles) are "used" by an instruction.
 struct ResourceUsage {
   CycleSegment CS;
   unsigned NumUnits;
   ResourceUsage(CycleSegment Cycles, unsigned Units = 1)
       : CS(Cycles), NumUnits(Units) {}
   unsigned size() const { return CS.size(); }
   bool isReserved() const { return CS.isReserved(); }
   void setReserved() { CS.setReserved(); }
 };

 /// An instruction descriptor
 struct InstrDesc {
   SmallVector<WriteDescriptor, 4> Writes; // Implicit writes are at the end.
   SmallVector<ReadDescriptor, 4> Reads;   // Implicit reads are at the end.

   // For every resource used by an instruction of this kind, this vector
   // reports the number of "consumed cycles".
   SmallVector<std::pair<uint64_t, ResourceUsage>, 4> Resources;

   // A list of buffered resources consumed by this instruction.
   SmallVector<uint64_t, 4> Buffers;

   unsigned MaxLatency;
   // Number of MicroOps for this instruction.
   unsigned NumMicroOps;

   bool MayLoad;
   bool MayStore;
   bool HasSideEffects;
   bool BeginGroup;
   bool EndGroup;

   // True if all buffered resources are in-order, and there is at least one
   // buffer which is a dispatch hazard (BufferSize = 0).
   bool MustIssueImmediately;

   // A zero latency instruction doesn't consume any scheduler resources.
   bool isZeroLatency() const { return !MaxLatency && Resources.empty(); }

   InstrDesc() = default;
   InstrDesc(const InstrDesc &Other) = delete;
   InstrDesc &operator=(const InstrDesc &Other) = delete;
 };

 /// Base class for instructions consumed by the simulation pipeline.
 ///
 /// This class tracks data dependencies as well as generic properties
 /// of the instruction.
 class InstructionBase {
   const InstrDesc &Desc;

   // This field is set for instructions that are candidates for move
   // elimination. For more information about move elimination, see the
   // definition of RegisterMappingTracker in RegisterFile.h
   bool IsOptimizableMove;

   // Output dependencies.
   // One entry per each implicit and explicit register definition.
   SmallVector<WriteState, 4> Defs;

   // Input dependencies.
   // One entry per each implicit and explicit register use.
   SmallVector<ReadState, 4> Uses;

 public:
   InstructionBase(const InstrDesc &D) : Desc(D), IsOptimizableMove(false) {}

   SmallVectorImpl<WriteState> &getDefs() { return Defs; }
   const ArrayRef<WriteState> getDefs() const { return Defs; }
   SmallVectorImpl<ReadState> &getUses() { return Uses; }
   const ArrayRef<ReadState> getUses() const { return Uses; }
   const InstrDesc &getDesc() const { return Desc; }

   unsigned getLatency() const { return Desc.MaxLatency; }

   bool hasDependentUsers() const {
     return any_of(Defs,
                   [](const WriteState &Def) { return Def.getNumUsers() > 0; });
   }

   unsigned getNumUsers() const {
     unsigned NumUsers = 0;
     for (const WriteState &Def : Defs)
       NumUsers += Def.getNumUsers();
     return NumUsers;
   }

   // Returns true if this instruction is a candidate for move elimination.
   bool isOptimizableMove() const { return IsOptimizableMove; }
   void setOptimizableMove() { IsOptimizableMove = true; }
 };

 /// An instruction propagated through the simulated instruction pipeline.
 ///
 /// This class is used to monitor changes to the internal state of instructions
 /// that are sent to the various components of the simulated hardware pipeline.
 class Instruction : public InstructionBase {
   enum InstrStage {
     IS_INVALID,   // Instruction in an invalid state.
     IS_AVAILABLE, // Instruction dispatched but operands are not ready.
     IS_READY,     // Instruction dispatched and operands ready.
     IS_EXECUTING, // Instruction issued.
     IS_EXECUTED,  // Instruction executed. Values are written back.
     IS_RETIRED    // Instruction retired.
   };

   // The current instruction stage.
   enum InstrStage Stage;

   // This value defaults to the instruction latency. This instruction is
   // considered executed when field CyclesLeft goes to zero.
   int CyclesLeft;

   // Retire Unit token ID for this instruction.
   unsigned RCUTokenID;

 public:
   Instruction(const InstrDesc &D)
       : InstructionBase(D), Stage(IS_INVALID), CyclesLeft(UNKNOWN_CYCLES),
         RCUTokenID(0) {}

   unsigned getRCUTokenID() const { return RCUTokenID; }
   int getCyclesLeft() const { return CyclesLeft; }

   // Transition to the dispatch stage, and assign a RCUToken to this
   // instruction. The RCUToken is used to track the completion of every
   // register write performed by this instruction.
   void dispatch(unsigned RCUTokenID);

   // Instruction issued. Transition to the IS_EXECUTING state, and update
   // all the definitions.
   void execute();

   // Force a transition from the IS_AVAILABLE state to the IS_READY state if
   // input operands are all ready. State transitions normally occur at the
   // beginning of a new cycle (see method cycleEvent()). However, the scheduler
   // may decide to promote instructions from the wait queue to the ready queue
   // as the result of another issue event.  This method is called every time the
   // instruction might have changed in state.
   void update();

   bool isDispatched() const { return Stage == IS_AVAILABLE; }
   bool isReady() const { return Stage == IS_READY; }
   bool isExecuting() const { return Stage == IS_EXECUTING; }
   bool isExecuted() const { return Stage == IS_EXECUTED; }
   bool isRetired() const { return Stage == IS_RETIRED; }

   bool isEliminated() const {
     return isReady() && getDefs().size() &&
            all_of(getDefs(),
                   [](const WriteState &W) { return W.isEliminated(); });
   }

   // Forces a transition from state IS_AVAILABLE to state IS_EXECUTED.
   void forceExecuted();

   void retire() {
     assert(isExecuted() && "Instruction is in an invalid state!");
     Stage = IS_RETIRED;
   }

   void cycleEvent();
 };

 /// An InstRef contains both a SourceMgr index and Instruction pair.  The index
 /// is used as a unique identifier for the instruction.  MCA will make use of
 /// this index as a key throughout MCA.
 class InstRef {
   std::pair<unsigned, Instruction *> Data;

 public:
   InstRef() : Data(std::make_pair(0, nullptr)) {}
   InstRef(unsigned Index, Instruction *I) : Data(std::make_pair(Index, I)) {}

   bool operator==(const InstRef &Other) const { return Data == Other.Data; }

   unsigned getSourceIndex() const { return Data.first; }
   Instruction *getInstruction() { return Data.second; }
   const Instruction *getInstruction() const { return Data.second; }

   /// Returns true if this references a valid instruction.
   operator bool() const { return Data.second != nullptr; }

   /// Invalidate this reference.
   void invalidate() { Data.second = nullptr; }

 #ifndef NDEBUG
   void print(raw_ostream &OS) const { OS << getSourceIndex(); }
 #endif
 };

 #ifndef NDEBUG
 inline raw_ostream &operator<<(raw_ostream &OS, const InstRef &IR) {
   IR.print(OS);
   return OS;
 }
 #endif

 /// A reference to a register write.
 ///
 /// This class is mainly used by the register file to describe register
 /// mappings. It correlates a register write to the source index of the
 /// defining instruction.
 class WriteRef {
   std::pair<unsigned, WriteState *> Data;
   static const unsigned INVALID_IID;

 public:
   WriteRef() : Data(INVALID_IID, nullptr) {}
   WriteRef(unsigned SourceIndex, WriteState *WS) : Data(SourceIndex, WS) {}

   unsigned getSourceIndex() const { return Data.first; }
   const WriteState *getWriteState() const { return Data.second; }
   WriteState *getWriteState() { return Data.second; }
   void invalidate() { Data.second = nullptr; }
   bool isWriteZero() const {
     assert(isValid() && "Invalid null WriteState found!");
     return getWriteState()->isWriteZero();
   }

   /// Returns true if this register write has been executed, and the new
   /// register value is therefore available to users.
   bool isAvailable() const {
     if (getSourceIndex() == INVALID_IID)
       return false;
     const WriteState *WS = getWriteState();
     return !WS || WS->isExecuted();
   }

   bool isValid() const { return Data.first != INVALID_IID && Data.second; }
   bool operator==(const WriteRef &Other) const { return Data == Other.Data; }

 #ifndef NDEBUG
   void dump() const;
 #endif
 };

 } // namespace mca
 } // namespace llvm

 #endif // LLVM_MCA_INSTRUCTION_H
	//===--------------------- Instruction.h ------------------------- C++ --===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	/// \file
	///
	/// This file defines abstractions used by the Pipeline to model register reads,
	/// register writes and instructions.
	///
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_MCA_INSTRUCTION_H
	#define LLVM_MCA_INSTRUCTION_H

	#include "llvm/ADT/ArrayRef.h"
	#include "llvm/ADT/STLExtras.h"
	#include "llvm/ADT/SmallVector.h"
	#include "llvm/Support/MathExtras.h"

	#ifndef NDEBUG
	#include "llvm/Support/raw_ostream.h"
	#endif

	#include <memory>

	namespace llvm {

	namespace mca {

	constexpr int UNKNOWN_CYCLES = -512;

	/// A register write descriptor.
	struct WriteDescriptor {
	// Operand index. The index is negative for implicit writes only.
	// For implicit writes, the actual operand index is computed performing
	// a bitwise not of the OpIndex.
	int OpIndex;
	// Write latency. Number of cycles before write-back stage.
	unsigned Latency;
	// This field is set to a value different than zero only if this
	// is an implicit definition.
	unsigned RegisterID;
	// Instruction itineraries would set this field to the SchedClass ID.
	// Otherwise, it defaults to the WriteResourceID from the MCWriteLatencyEntry
	// element associated to this write.
	// When computing read latencies, this value is matched against the
	// "ReadAdvance" information. The hardware backend may implement
	// dedicated forwarding paths to quickly propagate write results to dependent
	// instructions waiting in the reservation station (effectively bypassing the
	// write-back stage).
	unsigned SClassOrWriteResourceID;
	// True only if this is a write obtained from an optional definition.
	// Optional definitions are allowed to reference regID zero (i.e. "no
	// register").
	bool IsOptionalDef;

	bool isImplicitWrite() const { return OpIndex < 0; };
	};

	/// A register read descriptor.
	struct ReadDescriptor {
	// A MCOperand index. This is used by the Dispatch logic to identify register
	// reads. Implicit reads have negative indices. The actual operand index of an
	// implicit read is the bitwise not of field OpIndex.
	int OpIndex;
	// The actual "UseIdx". This is used to query the ReadAdvance table. Explicit
	// uses always come first in the sequence of uses.
	unsigned UseIndex;
	// This field is only set if this is an implicit read.
	unsigned RegisterID;
	// Scheduling Class Index. It is used to query the scheduling model for the
	// MCSchedClassDesc object.
	unsigned SchedClassID;

	bool isImplicitRead() const { return OpIndex < 0; };
	};

	class ReadState;

	/// Tracks uses of a register definition (e.g. register write).
	///
	/// Each implicit/explicit register write is associated with an instance of
	/// this class. A WriteState object tracks the dependent users of a
	/// register write. It also tracks how many cycles are left before the write
	/// back stage.
	class WriteState {
	const WriteDescriptor *WD;
	// On instruction issue, this field is set equal to the write latency.
	// Before instruction issue, this field defaults to -512, a special
	// value that represents an "unknown" number of cycles.
	int CyclesLeft;

	// Actual register defined by this write. This field is only used
	// to speedup queries on the register file.
	// For implicit writes, this field always matches the value of
	// field RegisterID from WD.
	unsigned RegisterID;

	// Physical register file that serves register RegisterID.
	unsigned PRFID;

	// True if this write implicitly clears the upper portion of RegisterID's
	// super-registers.
	bool ClearsSuperRegs;

	// True if this write is from a dependency breaking zero-idiom instruction.
	bool WritesZero;

	// True if this write has been eliminated at register renaming stage.
	// Example: a register move doesn't consume scheduler/pipleline resources if
	// it is eliminated at register renaming stage. It still consumes
	// decode bandwidth, and ROB entries.
	bool IsEliminated;

	// This field is set if this is a partial register write, and it has a false
	// dependency on any previous write of the same register (or a portion of it).
	// DependentWrite must be able to complete before this write completes, so
	// that we don't break the WAW, and the two writes can be merged together.
	const WriteState *DependentWrite;

	// A partial write that is in a false dependency with this write.
	WriteState *PartialWrite;

	unsigned DependentWriteCyclesLeft;

	// A list of dependent reads. Users is a set of dependent
	// reads. A dependent read is added to the set only if CyclesLeft
	// is "unknown". As soon as CyclesLeft is 'known', each user in the set
	// gets notified with the actual CyclesLeft.

	// The 'second' element of a pair is a "ReadAdvance" number of cycles.
	SmallVector<std::pair<ReadState *, int>, 4> Users;

	public:
	WriteState(const WriteDescriptor &Desc, unsigned RegID,
	bool clearsSuperRegs = false, bool writesZero = false)
	: WD(&Desc), CyclesLeft(UNKNOWN_CYCLES), RegisterID(RegID), PRFID(0),
	ClearsSuperRegs(clearsSuperRegs), WritesZero(writesZero),
	IsEliminated(false), DependentWrite(nullptr), PartialWrite(nullptr),
	DependentWriteCyclesLeft(0) {}

	WriteState(const WriteState &Other) = default;
	WriteState &operator=(const WriteState &Other) = default;

	int getCyclesLeft() const { return CyclesLeft; }
	unsigned getWriteResourceID() const { return WD->SClassOrWriteResourceID; }
	unsigned getRegisterID() const { return RegisterID; }
	unsigned getRegisterFileID() const { return PRFID; }
	unsigned getLatency() const { return WD->Latency; }

	void addUser(ReadState *Use, int ReadAdvance);
	void addUser(WriteState *Use);

	unsigned getDependentWriteCyclesLeft() const {
	return DependentWriteCyclesLeft;
	}

	unsigned getNumUsers() const {
	unsigned NumUsers = Users.size();
	if (PartialWrite)
	++NumUsers;
	return NumUsers;
	}

	bool clearsSuperRegisters() const { return ClearsSuperRegs; }
	bool isWriteZero() const { return WritesZero; }
	bool isEliminated() const { return IsEliminated; }
	bool isExecuted() const {
	return CyclesLeft != UNKNOWN_CYCLES && CyclesLeft <= 0;
	}

	const WriteState *getDependentWrite() const { return DependentWrite; }
	void setDependentWrite(WriteState *Other) { DependentWrite = Other; }
	void writeStartEvent(unsigned Cycles) {
	DependentWriteCyclesLeft = Cycles;
	DependentWrite = nullptr;
	}

	void setWriteZero() { WritesZero = true; }
	void setEliminated() {
	assert(Users.empty() && "Write is in an inconsistent state.");
	CyclesLeft = 0;
	IsEliminated = true;
	}

	void setPRF(unsigned PRF) { PRFID = PRF; }

	// On every cycle, update CyclesLeft and notify dependent users.
	void cycleEvent();
	void onInstructionIssued();

	#ifndef NDEBUG
	void dump() const;
	#endif
	};

	/// Tracks register operand latency in cycles.
	///
	/// A read may be dependent on more than one write. This occurs when some
	/// writes only partially update the register associated to this read.
	class ReadState {
	const ReadDescriptor *RD;
	// Physical register identified associated to this read.
	unsigned RegisterID;
	// Physical register file that serves register RegisterID.
	unsigned PRFID;
	// Number of writes that contribute to the definition of RegisterID.
	// In the absence of partial register updates, the number of DependentWrites
	// cannot be more than one.
	unsigned DependentWrites;
	// Number of cycles left before RegisterID can be read. This value depends on
	// the latency of all the dependent writes. It defaults to UNKNOWN_CYCLES.
	// It gets set to the value of field TotalCycles only when the 'CyclesLeft' of
	// every dependent write is known.
	int CyclesLeft;
	// This field is updated on every writeStartEvent(). When the number of
	// dependent writes (i.e. field DependentWrite) is zero, this value is
	// propagated to field CyclesLeft.
	unsigned TotalCycles;
	// This field is set to true only if there are no dependent writes, and
	// there are no `CyclesLeft' to wait.
	bool IsReady;
	// True if this is a read from a known zero register.
	bool IsZero;
	// True if this register read is from a dependency-breaking instruction.
	bool IndependentFromDef;

	public:
	ReadState(const ReadDescriptor &Desc, unsigned RegID)
	: RD(&Desc), RegisterID(RegID), PRFID(0), DependentWrites(0),
	CyclesLeft(UNKNOWN_CYCLES), TotalCycles(0), IsReady(true),
	IsZero(false), IndependentFromDef(false) {}

	const ReadDescriptor &getDescriptor() const { return *RD; }
	unsigned getSchedClass() const { return RD->SchedClassID; }
	unsigned getRegisterID() const { return RegisterID; }
	unsigned getRegisterFileID() const { return PRFID; }

	bool isReady() const { return IsReady; }
	bool isImplicitRead() const { return RD->isImplicitRead(); }

	bool isIndependentFromDef() const { return IndependentFromDef; }
	void setIndependentFromDef() { IndependentFromDef = true; }

	void cycleEvent();
	void writeStartEvent(unsigned Cycles);
	void setDependentWrites(unsigned Writes) {
	DependentWrites = Writes;
	IsReady = !Writes;
	}

	bool isReadZero() const { return IsZero; }
	void setReadZero() { IsZero = true; }
	void setPRF(unsigned ID) { PRFID = ID; }
	};

	/// A sequence of cycles.
	///
	/// This class can be used as a building block to construct ranges of cycles.
	class CycleSegment {
	unsigned Begin; // Inclusive.
	unsigned End; // Exclusive.
	bool Reserved; // Resources associated to this segment must be reserved.

	public:
	CycleSegment(unsigned StartCycle, unsigned EndCycle, bool IsReserved = false)
	: Begin(StartCycle), End(EndCycle), Reserved(IsReserved) {}

	bool contains(unsigned Cycle) const { return Cycle >= Begin && Cycle < End; }
	bool startsAfter(const CycleSegment &CS) const { return End <= CS.Begin; }
	bool endsBefore(const CycleSegment &CS) const { return Begin >= CS.End; }
	bool overlaps(const CycleSegment &CS) const {
	return !startsAfter(CS) && !endsBefore(CS);
	}
	bool isExecuting() const { return Begin == 0 && End != 0; }
	bool isExecuted() const { return End == 0; }
	bool operator<(const CycleSegment &Other) const {
	return Begin < Other.Begin;
	}
	CycleSegment &operator--(void) {
	if (Begin)
	Begin--;
	if (End)
	End--;
	return *this;
	}

	bool isValid() const { return Begin <= End; }
	unsigned size() const { return End - Begin; };
	void subtract(unsigned Cycles) {
	assert(End >= Cycles);
	End -= Cycles;
	}

	unsigned begin() const { return Begin; }
	unsigned end() const { return End; }
	void setEnd(unsigned NewEnd) { End = NewEnd; }
	bool isReserved() const { return Reserved; }
	void setReserved() { Reserved = true; }
	};

	/// Helper used by class InstrDesc to describe how hardware resources
	/// are used.
	///
	/// This class describes how many resource units of a specific resource kind
	/// (and how many cycles) are "used" by an instruction.
	struct ResourceUsage {
	CycleSegment CS;
	unsigned NumUnits;
	ResourceUsage(CycleSegment Cycles, unsigned Units = 1)
	: CS(Cycles), NumUnits(Units) {}
	unsigned size() const { return CS.size(); }
	bool isReserved() const { return CS.isReserved(); }
	void setReserved() { CS.setReserved(); }
	};

	/// An instruction descriptor
	struct InstrDesc {
	SmallVector<WriteDescriptor, 4> Writes; // Implicit writes are at the end.
	SmallVector<ReadDescriptor, 4> Reads; // Implicit reads are at the end.

	// For every resource used by an instruction of this kind, this vector
	// reports the number of "consumed cycles".
	SmallVector<std::pair<uint64_t, ResourceUsage>, 4> Resources;

	// A list of buffered resources consumed by this instruction.
	SmallVector<uint64_t, 4> Buffers;

	unsigned MaxLatency;
	// Number of MicroOps for this instruction.
	unsigned NumMicroOps;

	bool MayLoad;
	bool MayStore;
	bool HasSideEffects;
	bool BeginGroup;
	bool EndGroup;

	// True if all buffered resources are in-order, and there is at least one
	// buffer which is a dispatch hazard (BufferSize = 0).
	bool MustIssueImmediately;

	// A zero latency instruction doesn't consume any scheduler resources.
	bool isZeroLatency() const { return !MaxLatency && Resources.empty(); }

	InstrDesc() = default;
	InstrDesc(const InstrDesc &Other) = delete;
	InstrDesc &operator=(const InstrDesc &Other) = delete;
	};

	/// Base class for instructions consumed by the simulation pipeline.
	///
	/// This class tracks data dependencies as well as generic properties
	/// of the instruction.
	class InstructionBase {
	const InstrDesc &Desc;

	// This field is set for instructions that are candidates for move
	// elimination. For more information about move elimination, see the
	// definition of RegisterMappingTracker in RegisterFile.h
	bool IsOptimizableMove;

	// Output dependencies.
	// One entry per each implicit and explicit register definition.
	SmallVector<WriteState, 4> Defs;

	// Input dependencies.
	// One entry per each implicit and explicit register use.
	SmallVector<ReadState, 4> Uses;

	public:
	InstructionBase(const InstrDesc &D) : Desc(D), IsOptimizableMove(false) {}

	SmallVectorImpl<WriteState> &getDefs() { return Defs; }
	const ArrayRef<WriteState> getDefs() const { return Defs; }
	SmallVectorImpl<ReadState> &getUses() { return Uses; }
	const ArrayRef<ReadState> getUses() const { return Uses; }
	const InstrDesc &getDesc() const { return Desc; }

	unsigned getLatency() const { return Desc.MaxLatency; }

	bool hasDependentUsers() const {
	return any_of(Defs,
	[](const WriteState &Def) { return Def.getNumUsers() > 0; });
	}

	unsigned getNumUsers() const {
	unsigned NumUsers = 0;
	for (const WriteState &Def : Defs)
	NumUsers += Def.getNumUsers();
	return NumUsers;
	}

	// Returns true if this instruction is a candidate for move elimination.
	bool isOptimizableMove() const { return IsOptimizableMove; }
	void setOptimizableMove() { IsOptimizableMove = true; }
	};

	/// An instruction propagated through the simulated instruction pipeline.
	///
	/// This class is used to monitor changes to the internal state of instructions
	/// that are sent to the various components of the simulated hardware pipeline.
	class Instruction : public InstructionBase {
	enum InstrStage {
	IS_INVALID, // Instruction in an invalid state.
	IS_AVAILABLE, // Instruction dispatched but operands are not ready.
	IS_READY, // Instruction dispatched and operands ready.
	IS_EXECUTING, // Instruction issued.
	IS_EXECUTED, // Instruction executed. Values are written back.
	IS_RETIRED // Instruction retired.
	};

	// The current instruction stage.
	enum InstrStage Stage;

	// This value defaults to the instruction latency. This instruction is
	// considered executed when field CyclesLeft goes to zero.
	int CyclesLeft;

	// Retire Unit token ID for this instruction.
	unsigned RCUTokenID;

	public:
	Instruction(const InstrDesc &D)
	: InstructionBase(D), Stage(IS_INVALID), CyclesLeft(UNKNOWN_CYCLES),
	RCUTokenID(0) {}

	unsigned getRCUTokenID() const { return RCUTokenID; }
	int getCyclesLeft() const { return CyclesLeft; }

	// Transition to the dispatch stage, and assign a RCUToken to this
	// instruction. The RCUToken is used to track the completion of every
	// register write performed by this instruction.
	void dispatch(unsigned RCUTokenID);

	// Instruction issued. Transition to the IS_EXECUTING state, and update
	// all the definitions.
	void execute();

	// Force a transition from the IS_AVAILABLE state to the IS_READY state if
	// input operands are all ready. State transitions normally occur at the
	// beginning of a new cycle (see method cycleEvent()). However, the scheduler
	// may decide to promote instructions from the wait queue to the ready queue
	// as the result of another issue event. This method is called every time the
	// instruction might have changed in state.
	void update();

	bool isDispatched() const { return Stage == IS_AVAILABLE; }
	bool isReady() const { return Stage == IS_READY; }
	bool isExecuting() const { return Stage == IS_EXECUTING; }
	bool isExecuted() const { return Stage == IS_EXECUTED; }
	bool isRetired() const { return Stage == IS_RETIRED; }

	bool isEliminated() const {
	return isReady() && getDefs().size() &&
	all_of(getDefs(),
	[](const WriteState &W) { return W.isEliminated(); });
	}

	// Forces a transition from state IS_AVAILABLE to state IS_EXECUTED.
	void forceExecuted();

	void retire() {
	assert(isExecuted() && "Instruction is in an invalid state!");
	Stage = IS_RETIRED;
	}

	void cycleEvent();
	};

	/// An InstRef contains both a SourceMgr index and Instruction pair. The index
	/// is used as a unique identifier for the instruction. MCA will make use of
	/// this index as a key throughout MCA.
	class InstRef {
	std::pair<unsigned, Instruction *> Data;

	public:
	InstRef() : Data(std::make_pair(0, nullptr)) {}
	InstRef(unsigned Index, Instruction *I) : Data(std::make_pair(Index, I)) {}

	bool operator==(const InstRef &Other) const { return Data == Other.Data; }

	unsigned getSourceIndex() const { return Data.first; }
	Instruction *getInstruction() { return Data.second; }
	const Instruction *getInstruction() const { return Data.second; }

	/// Returns true if this references a valid instruction.
	operator bool() const { return Data.second != nullptr; }

	/// Invalidate this reference.
	void invalidate() { Data.second = nullptr; }

	#ifndef NDEBUG
	void print(raw_ostream &OS) const { OS << getSourceIndex(); }
	#endif
	};

	#ifndef NDEBUG
	inline raw_ostream &operator<<(raw_ostream &OS, const InstRef &IR) {
	IR.print(OS);
	return OS;
	}
	#endif

	/// A reference to a register write.
	///
	/// This class is mainly used by the register file to describe register
	/// mappings. It correlates a register write to the source index of the
	/// defining instruction.
	class WriteRef {
	std::pair<unsigned, WriteState *> Data;
	static const unsigned INVALID_IID;

	public:
	WriteRef() : Data(INVALID_IID, nullptr) {}
	WriteRef(unsigned SourceIndex, WriteState *WS) : Data(SourceIndex, WS) {}

	unsigned getSourceIndex() const { return Data.first; }
	const WriteState *getWriteState() const { return Data.second; }
	WriteState *getWriteState() { return Data.second; }
	void invalidate() { Data.second = nullptr; }
	bool isWriteZero() const {
	assert(isValid() && "Invalid null WriteState found!");
	return getWriteState()->isWriteZero();
	}

	/// Returns true if this register write has been executed, and the new
	/// register value is therefore available to users.
	bool isAvailable() const {
	if (getSourceIndex() == INVALID_IID)
	return false;
	const WriteState *WS = getWriteState();
	return !WS \|\| WS->isExecuted();
	}

	bool isValid() const { return Data.first != INVALID_IID && Data.second; }
	bool operator==(const WriteRef &Other) const { return Data == Other.Data; }

	#ifndef NDEBUG
	void dump() const;
	#endif
	};

	} // namespace mca
	} // namespace llvm

	#endif // LLVM_MCA_INSTRUCTION_H