cpu/base_dyn_inst.hh - arm/gem5 - Git at Google

 /*
  * Copyright (c) 2004-2005 The Regents of The University of Michigan
  * All rights reserved.
  *
  * Redistribution and use in source and binary forms, with or without
  * modification, are permitted provided that the following conditions are
  * met: redistributions of source code must retain the above copyright
  * notice, this list of conditions and the following disclaimer;
  * redistributions in binary form must reproduce the above copyright
  * notice, this list of conditions and the following disclaimer in the
  * documentation and/or other materials provided with the distribution;
  * neither the name of the copyright holders nor the names of its
  * contributors may be used to endorse or promote products derived from
  * this software without specific prior written permission.
  *
  * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
  * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
  * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
  * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
  * OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
  * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
  * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
  * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
  * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
  * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
  * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
  */

 #ifndef __CPU_BASE_DYN_INST_HH__
 #define __CPU_BASE_DYN_INST_HH__

 #include <string>
 #include <vector>

 #include "base/fast_alloc.hh"
 #include "base/trace.hh"
 #include "cpu/exetrace.hh"
 #include "cpu/inst_seq.hh"
 #include "cpu/o3/comm.hh"
 #include "cpu/static_inst.hh"
 #include "encumbered/cpu/full/bpred_update.hh"
 #include "encumbered/cpu/full/op_class.hh"
 #include "encumbered/cpu/full/spec_memory.hh"
 #include "encumbered/cpu/full/spec_state.hh"
 #include "encumbered/mem/functional/main.hh"

 /**
  * @file
  * Defines a dynamic instruction context.
  */

 // Forward declaration.
 template <class ISA>
 class StaticInstPtr;

 template <class Impl>
 class BaseDynInst : public FastAlloc, public RefCounted
 {
   public:
     // Typedef for the CPU.
     typedef typename Impl::FullCPU FullCPU;

     //Typedef to get the ISA.
     typedef typename Impl::ISA ISA;

     /// Binary machine instruction type.
     typedef typename ISA::MachInst MachInst;
     /// Memory address type.
     typedef typename ISA::Addr	   Addr;
     /// Logical register index type.
     typedef typename ISA::RegIndex RegIndex;
     /// Integer register index type.
     typedef typename ISA::IntReg   IntReg;

     enum {
         MaxInstSrcRegs = ISA::MaxInstSrcRegs,	//< Max source regs
         MaxInstDestRegs = ISA::MaxInstDestRegs,	//< Max dest regs
     };

     /** The static inst used by this dyn inst. */
     StaticInstPtr<ISA> staticInst;

     ////////////////////////////////////////////
     //
     // INSTRUCTION EXECUTION
     //
     ////////////////////////////////////////////
     Trace::InstRecord *traceData;

     template <class T>
     Fault read(Addr addr, T &data, unsigned flags);

     template <class T>
     Fault write(T data, Addr addr, unsigned flags,
                         uint64_t *res);

     void prefetch(Addr addr, unsigned flags);
     void writeHint(Addr addr, int size, unsigned flags);
     Fault copySrcTranslate(Addr src);
     Fault copy(Addr dest);

     /** @todo: Consider making this private. */
   public:
     /** Is this instruction valid. */
     bool valid;

     /** The sequence number of the instruction. */
     InstSeqNum seqNum;

     /** How many source registers are ready. */
     unsigned readyRegs;

     /** Is the instruction completed. */
     bool completed;

     /** Can this instruction issue. */
     bool canIssue;

     /** Has this instruction issued. */
     bool issued;

     /** Has this instruction executed (or made it through execute) yet. */
     bool executed;

     /** Can this instruction commit. */
     bool canCommit;

     /** Is this instruction squashed. */
     bool squashed;

     /** Is this instruction squashed in the instruction queue. */
     bool squashedInIQ;

     /** Is this a recover instruction. */
     bool recoverInst;

     /** Is this a thread blocking instruction. */
     bool blockingInst;	/* this inst has called thread_block() */

     /** Is this a thread syncrhonization instruction. */
     bool threadsyncWait;

     /** The thread this instruction is from. */
     short threadNumber;

     /** data address space ID, for loads & stores. */
     short asid;

     /** Pointer to the FullCPU object. */
     FullCPU *cpu;

     /** Pointer to the exec context.  Will not exist in the final version. */
     ExecContext *xc;

     /** The kind of fault this instruction has generated. */
     Fault fault;

     /** The effective virtual address (lds & stores only). */
     Addr effAddr;

     /** The effective physical address. */
     Addr physEffAddr;

     /** Effective virtual address for a copy source. */
     Addr copySrcEffAddr;

     /** Effective physical address for a copy source. */
     Addr copySrcPhysEffAddr;

     /** The memory request flags (from translation). */
     unsigned memReqFlags;

     /** The size of the data to be stored. */
     int storeSize;

     /** The data to be stored. */
     IntReg storeData;

     union Result {
         uint64_t integer;
         float fp;
         double dbl;
     };

     /** The result of the instruction; assumes for now that there's only one
      *  destination register.
      */
     Result instResult;

     /** PC of this instruction. */
     Addr PC;

     /** Next non-speculative PC.  It is not filled in at fetch, but rather
      *  once the target of the branch is truly known (either decode or
      *  execute).
      */
     Addr nextPC;

     /** Predicted next PC. */
     Addr predPC;

     /** Count of total number of dynamic instructions. */
     static int instcount;

     /** Whether or not the source register is ready.  Not sure this should be
      *  here vs. the derived class.
      */
     bool _readySrcRegIdx[MaxInstSrcRegs];

   public:
     /** BaseDynInst constructor given a binary instruction. */
     BaseDynInst(MachInst inst, Addr PC, Addr Pred_PC, InstSeqNum seq_num,
                 FullCPU *cpu);

     /** BaseDynInst constructor given a static inst pointer. */
     BaseDynInst(StaticInstPtr<ISA> &_staticInst);

     /** BaseDynInst destructor. */
     ~BaseDynInst();

   private:
     /** Function to initialize variables in the constructors. */
     void initVars();

   public:
     void
     trace_mem(Fault fault,      // last fault
               MemCmd cmd,       // last command
               Addr addr,        // virtual address of access
               void *p,          // memory accessed
               int nbytes);      // access size

     /** Dumps out contents of this BaseDynInst. */
     void dump();

     /** Dumps out contents of this BaseDynInst into given string. */
     void dump(std::string &outstring);

     /** Returns the fault type. */
     Fault getFault() { return fault; }

     /** Checks whether or not this instruction has had its branch target
      *  calculated yet.  For now it is not utilized and is hacked to be
      *  always false.
      */
     bool doneTargCalc() { return false; }

     /** Returns the next PC.  This could be the speculative next PC if it is
      *  called prior to the actual branch target being calculated.
      */
     Addr readNextPC() { return nextPC; }

     /** Set the predicted target of this current instruction. */
     void setPredTarg(Addr predicted_PC) { predPC = predicted_PC; }

     /** Returns the predicted target of the branch. */
     Addr readPredTarg() { return predPC; }

     /** Returns whether the instruction was predicted taken or not. */
     bool predTaken() {
         return( predPC != (PC + sizeof(MachInst) ) );
     }

     /** Returns whether the instruction mispredicted. */
     bool mispredicted() { return (predPC != nextPC); }

     //
     //  Instruction types.  Forward checks to StaticInst object.
     //
     bool isNop()	  const { return staticInst->isNop(); }
     bool isMemRef()    	  const { return staticInst->isMemRef(); }
     bool isLoad()	  const { return staticInst->isLoad(); }
     bool isStore()	  const { return staticInst->isStore(); }
     bool isInstPrefetch() const { return staticInst->isInstPrefetch(); }
     bool isDataPrefetch() const { return staticInst->isDataPrefetch(); }
     bool isCopy()         const { return staticInst->isCopy(); }
     bool isInteger()	  const { return staticInst->isInteger(); }
     bool isFloating()	  const { return staticInst->isFloating(); }
     bool isControl()	  const { return staticInst->isControl(); }
     bool isCall()	  const { return staticInst->isCall(); }
     bool isReturn()	  const { return staticInst->isReturn(); }
     bool isDirectCtrl()	  const { return staticInst->isDirectCtrl(); }
     bool isIndirectCtrl() const { return staticInst->isIndirectCtrl(); }
     bool isCondCtrl()	  const { return staticInst->isCondCtrl(); }
     bool isUncondCtrl()	  const { return staticInst->isUncondCtrl(); }
     bool isThreadSync()   const { return staticInst->isThreadSync(); }
     bool isSerializing()  const { return staticInst->isSerializing(); }
     bool isMemBarrier()   const { return staticInst->isMemBarrier(); }
     bool isWriteBarrier() const { return staticInst->isWriteBarrier(); }
     bool isNonSpeculative() const { return staticInst->isNonSpeculative(); }

     /** Returns the opclass of this instruction. */
     OpClass opClass() const { return staticInst->opClass(); }

     /** Returns the branch target address. */
     Addr branchTarget() const { return staticInst->branchTarget(PC); }

     /** Number of source registers. */
     int8_t numSrcRegs()	 const { return staticInst->numSrcRegs(); }

     /** Number of destination registers. */
     int8_t numDestRegs() const { return staticInst->numDestRegs(); }

     // the following are used to track physical register usage
     // for machines with separate int & FP reg files
     int8_t numFPDestRegs()  const { return staticInst->numFPDestRegs(); }
     int8_t numIntDestRegs() const { return staticInst->numIntDestRegs(); }

     /** Returns the logical register index of the i'th destination register. */
     RegIndex destRegIdx(int i) const
     {
         return staticInst->destRegIdx(i);
     }

     /** Returns the logical register index of the i'th source register. */
     RegIndex srcRegIdx(int i) const
     {
         return staticInst->srcRegIdx(i);
     }

     /** Returns the result of an integer instruction. */
     uint64_t readIntResult() { return instResult.integer; }

     /** Returns the result of a floating point instruction. */
     float readFloatResult() { return instResult.fp; }

     /** Returns the result of a floating point (double) instruction. */
     double readDoubleResult() { return instResult.dbl; }

     //Push to .cc file.
     /** Records that one of the source registers is ready. */
     void markSrcRegReady()
     {
         ++readyRegs;
         if(readyRegs == numSrcRegs()) {
             canIssue = true;
         }
     }

     /** Marks a specific register as ready.
      *  @todo: Move this to .cc file.
      */
     void markSrcRegReady(RegIndex src_idx)
     {
         ++readyRegs;

         _readySrcRegIdx[src_idx] = 1;

         if(readyRegs == numSrcRegs()) {
             canIssue = true;
         }
     }

     /** Returns if a source register is ready. */
     bool isReadySrcRegIdx(int idx) const
     {
         return this->_readySrcRegIdx[idx];
     }

     /** Sets this instruction as completed. */
     void setCompleted() { completed = true; }

     /** Returns whethe or not this instruction is completed. */
     bool isCompleted() const { return completed; }

     /** Sets this instruction as ready to issue. */
     void setCanIssue() { canIssue = true; }

     /** Returns whether or not this instruction is ready to issue. */
     bool readyToIssue() const { return canIssue; }

     /** Sets this instruction as issued from the IQ. */
     void setIssued() { issued = true; }

     /** Returns whether or not this instruction has issued. */
     bool isIssued() const { return issued; }

     /** Sets this instruction as executed. */
     void setExecuted() { executed = true; }

     /** Returns whether or not this instruction has executed. */
     bool isExecuted() const { return executed; }

     /** Sets this instruction as ready to commit. */
     void setCanCommit() { canCommit = true; }

     /** Clears this instruction as being ready to commit. */
     void clearCanCommit() { canCommit = false; }

     /** Returns whether or not this instruction is ready to commit. */
     bool readyToCommit() const { return canCommit; }

     /** Sets this instruction as squashed. */
     void setSquashed() { squashed = true; }

     /** Returns whether or not this instruction is squashed. */
     bool isSquashed() const { return squashed; }

     /** Sets this instruction as squashed in the IQ. */
     void setSquashedInIQ() { squashedInIQ = true; }

     /** Returns whether or not this instruction is squashed in the IQ. */
     bool isSquashedInIQ() const { return squashedInIQ; }

     /** Read the PC of this instruction. */
     const Addr readPC() const { return PC; }

     /** Set the next PC of this instruction (its actual target). */
     void setNextPC(uint64_t val) { nextPC = val; }

     /** Returns the exec context.
      *  @todo: Remove this once the ExecContext is no longer used.
      */
     ExecContext *xcBase() { return xc; }

   private:
     /** Instruction effective address.
      *  @todo: Consider if this is necessary or not.
      */
     Addr instEffAddr;
     /** Whether or not the effective address calculation is completed.
      *  @todo: Consider if this is necessary or not.
      */
     bool eaCalcDone;

   public:
     /** Sets the effective address. */
     void setEA(Addr &ea) { instEffAddr = ea; eaCalcDone = true; }

     /** Returns the effective address. */
     const Addr &getEA() const { return instEffAddr; }

     /** Returns whether or not the eff. addr. calculation has been completed. */
     bool doneEACalc() { return eaCalcDone; }

     /** Returns whether or not the eff. addr. source registers are ready. */
     bool eaSrcsReady();

   public:
     /** Load queue index. */
     int16_t lqIdx;

     /** Store queue index. */
     int16_t sqIdx;
 };

 template<class Impl>
 template<class T>
 inline Fault
 BaseDynInst<Impl>::read(Addr addr, T &data, unsigned flags)
 {
     MemReqPtr req = new MemReq(addr, xc, sizeof(T), flags);
     req->asid = asid;

     fault = cpu->translateDataReadReq(req);

     // Record key MemReq parameters so we can generate another one
     // just like it for the timing access without calling translate()
     // again (which might mess up the TLB).
     // Do I ever really need this? -KTL 3/05
     effAddr = req->vaddr;
     physEffAddr = req->paddr;
     memReqFlags = req->flags;

     /**
      * @todo
      * Replace the disjoint functional memory with a unified one and remove
      * this hack.
      */
 #ifndef FULL_SYSTEM
     req->paddr = req->vaddr;
 #endif

     if (fault == No_Fault) {
         fault = cpu->read(req, data, lqIdx);
     } else {
         // Return a fixed value to keep simulation deterministic even
         // along misspeculated paths.
         data = (T)-1;
     }

     if (traceData) {
         traceData->setAddr(addr);
         traceData->setData(data);
     }

     return fault;
 }

 template<class Impl>
 template<class T>
 inline Fault
 BaseDynInst<Impl>::write(T data, Addr addr, unsigned flags, uint64_t *res)
 {
     if (traceData) {
         traceData->setAddr(addr);
         traceData->setData(data);
     }

     MemReqPtr req = new MemReq(addr, xc, sizeof(T), flags);

     req->asid = asid;

     fault = cpu->translateDataWriteReq(req);

     // Record key MemReq parameters so we can generate another one
     // just like it for the timing access without calling translate()
     // again (which might mess up the TLB).
     effAddr = req->vaddr;
     physEffAddr = req->paddr;
     memReqFlags = req->flags;

     /**
      * @todo
      * Replace the disjoint functional memory with a unified one and remove
      * this hack.
      */
 #ifndef FULL_SYSTEM
     req->paddr = req->vaddr;
 #endif

     if (fault == No_Fault) {
         fault = cpu->write(req, data, sqIdx);
     }

     if (res) {
         // always return some result to keep misspeculated paths
         // (which will ignore faults) deterministic
         *res = (fault == No_Fault) ? req->result : 0;
     }

     return fault;
 }

 #endif // __CPU_BASE_DYN_INST_HH__
	/*
	* Copyright (c) 2004-2005 The Regents of The University of Michigan
	* All rights reserved.
	*
	* Redistribution and use in source and binary forms, with or without
	* modification, are permitted provided that the following conditions are
	* met: redistributions of source code must retain the above copyright
	* notice, this list of conditions and the following disclaimer;
	* redistributions in binary form must reproduce the above copyright
	* notice, this list of conditions and the following disclaimer in the
	* documentation and/or other materials provided with the distribution;
	* neither the name of the copyright holders nor the names of its
	* contributors may be used to endorse or promote products derived from
	* this software without specific prior written permission.
	*
	* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
	* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
	* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
	* A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
	* OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
	* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
	* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
	* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
	* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
	*/

	#ifndef __CPU_BASE_DYN_INST_HH__
	#define __CPU_BASE_DYN_INST_HH__

	#include <string>
	#include <vector>

	#include "base/fast_alloc.hh"
	#include "base/trace.hh"
	#include "cpu/exetrace.hh"
	#include "cpu/inst_seq.hh"
	#include "cpu/o3/comm.hh"
	#include "cpu/static_inst.hh"
	#include "encumbered/cpu/full/bpred_update.hh"
	#include "encumbered/cpu/full/op_class.hh"
	#include "encumbered/cpu/full/spec_memory.hh"
	#include "encumbered/cpu/full/spec_state.hh"
	#include "encumbered/mem/functional/main.hh"

	/**
	* @file
	* Defines a dynamic instruction context.
	*/

	// Forward declaration.
	template <class ISA>
	class StaticInstPtr;

	template <class Impl>
	class BaseDynInst : public FastAlloc, public RefCounted
	{
	public:
	// Typedef for the CPU.
	typedef typename Impl::FullCPU FullCPU;

	//Typedef to get the ISA.
	typedef typename Impl::ISA ISA;

	/// Binary machine instruction type.
	typedef typename ISA::MachInst MachInst;
	/// Memory address type.
	typedef typename ISA::Addr Addr;
	/// Logical register index type.
	typedef typename ISA::RegIndex RegIndex;
	/// Integer register index type.
	typedef typename ISA::IntReg IntReg;

	enum {
	MaxInstSrcRegs = ISA::MaxInstSrcRegs, //< Max source regs
	MaxInstDestRegs = ISA::MaxInstDestRegs, //< Max dest regs
	};

	/** The static inst used by this dyn inst. */
	StaticInstPtr<ISA> staticInst;

	////////////////////////////////////////////
	//
	// INSTRUCTION EXECUTION
	//
	////////////////////////////////////////////
	Trace::InstRecord *traceData;

	template <class T>
	Fault read(Addr addr, T &data, unsigned flags);

	template <class T>
	Fault write(T data, Addr addr, unsigned flags,
	uint64_t *res);

	void prefetch(Addr addr, unsigned flags);
	void writeHint(Addr addr, int size, unsigned flags);
	Fault copySrcTranslate(Addr src);
	Fault copy(Addr dest);

	/** @todo: Consider making this private. */
	public:
	/** Is this instruction valid. */
	bool valid;

	/** The sequence number of the instruction. */
	InstSeqNum seqNum;

	/** How many source registers are ready. */
	unsigned readyRegs;

	/** Is the instruction completed. */
	bool completed;

	/** Can this instruction issue. */
	bool canIssue;

	/** Has this instruction issued. */
	bool issued;

	/** Has this instruction executed (or made it through execute) yet. */
	bool executed;

	/** Can this instruction commit. */
	bool canCommit;

	/** Is this instruction squashed. */
	bool squashed;

	/** Is this instruction squashed in the instruction queue. */
	bool squashedInIQ;

	/** Is this a recover instruction. */
	bool recoverInst;

	/** Is this a thread blocking instruction. */
	bool blockingInst; /* this inst has called thread_block() */

	/** Is this a thread syncrhonization instruction. */
	bool threadsyncWait;

	/** The thread this instruction is from. */
	short threadNumber;

	/** data address space ID, for loads & stores. */
	short asid;

	/** Pointer to the FullCPU object. */
	FullCPU *cpu;

	/** Pointer to the exec context. Will not exist in the final version. */
	ExecContext *xc;

	/** The kind of fault this instruction has generated. */
	Fault fault;

	/** The effective virtual address (lds & stores only). */
	Addr effAddr;

	/** The effective physical address. */
	Addr physEffAddr;

	/** Effective virtual address for a copy source. */
	Addr copySrcEffAddr;

	/** Effective physical address for a copy source. */
	Addr copySrcPhysEffAddr;

	/** The memory request flags (from translation). */
	unsigned memReqFlags;

	/** The size of the data to be stored. */
	int storeSize;

	/** The data to be stored. */
	IntReg storeData;

	union Result {
	uint64_t integer;
	float fp;
	double dbl;
	};

	/** The result of the instruction; assumes for now that there's only one
	* destination register.
	*/
	Result instResult;

	/** PC of this instruction. */
	Addr PC;

	/** Next non-speculative PC. It is not filled in at fetch, but rather
	* once the target of the branch is truly known (either decode or
	* execute).
	*/
	Addr nextPC;

	/** Predicted next PC. */
	Addr predPC;

	/** Count of total number of dynamic instructions. */
	static int instcount;

	/** Whether or not the source register is ready. Not sure this should be
	* here vs. the derived class.
	*/
	bool _readySrcRegIdx[MaxInstSrcRegs];

	public:
	/** BaseDynInst constructor given a binary instruction. */
	BaseDynInst(MachInst inst, Addr PC, Addr Pred_PC, InstSeqNum seq_num,
	FullCPU *cpu);

	/** BaseDynInst constructor given a static inst pointer. */
	BaseDynInst(StaticInstPtr<ISA> &_staticInst);

	/** BaseDynInst destructor. */
	~BaseDynInst();

	private:
	/** Function to initialize variables in the constructors. */
	void initVars();

	public:
	void
	trace_mem(Fault fault, // last fault
	MemCmd cmd, // last command
	Addr addr, // virtual address of access
	void *p, // memory accessed
	int nbytes); // access size

	/** Dumps out contents of this BaseDynInst. */
	void dump();

	/** Dumps out contents of this BaseDynInst into given string. */
	void dump(std::string &outstring);

	/** Returns the fault type. */
	Fault getFault() { return fault; }

	/** Checks whether or not this instruction has had its branch target
	* calculated yet. For now it is not utilized and is hacked to be
	* always false.
	*/
	bool doneTargCalc() { return false; }

	/** Returns the next PC. This could be the speculative next PC if it is
	* called prior to the actual branch target being calculated.
	*/
	Addr readNextPC() { return nextPC; }

	/** Set the predicted target of this current instruction. */
	void setPredTarg(Addr predicted_PC) { predPC = predicted_PC; }

	/** Returns the predicted target of the branch. */
	Addr readPredTarg() { return predPC; }

	/** Returns whether the instruction was predicted taken or not. */
	bool predTaken() {
	return( predPC != (PC + sizeof(MachInst) ) );
	}

	/** Returns whether the instruction mispredicted. */
	bool mispredicted() { return (predPC != nextPC); }

	//
	// Instruction types. Forward checks to StaticInst object.
	//
	bool isNop() const { return staticInst->isNop(); }
	bool isMemRef() const { return staticInst->isMemRef(); }
	bool isLoad() const { return staticInst->isLoad(); }
	bool isStore() const { return staticInst->isStore(); }
	bool isInstPrefetch() const { return staticInst->isInstPrefetch(); }
	bool isDataPrefetch() const { return staticInst->isDataPrefetch(); }
	bool isCopy() const { return staticInst->isCopy(); }
	bool isInteger() const { return staticInst->isInteger(); }
	bool isFloating() const { return staticInst->isFloating(); }
	bool isControl() const { return staticInst->isControl(); }
	bool isCall() const { return staticInst->isCall(); }
	bool isReturn() const { return staticInst->isReturn(); }
	bool isDirectCtrl() const { return staticInst->isDirectCtrl(); }
	bool isIndirectCtrl() const { return staticInst->isIndirectCtrl(); }
	bool isCondCtrl() const { return staticInst->isCondCtrl(); }
	bool isUncondCtrl() const { return staticInst->isUncondCtrl(); }
	bool isThreadSync() const { return staticInst->isThreadSync(); }
	bool isSerializing() const { return staticInst->isSerializing(); }
	bool isMemBarrier() const { return staticInst->isMemBarrier(); }
	bool isWriteBarrier() const { return staticInst->isWriteBarrier(); }
	bool isNonSpeculative() const { return staticInst->isNonSpeculative(); }

	/** Returns the opclass of this instruction. */
	OpClass opClass() const { return staticInst->opClass(); }

	/** Returns the branch target address. */
	Addr branchTarget() const { return staticInst->branchTarget(PC); }

	/** Number of source registers. */
	int8_t numSrcRegs() const { return staticInst->numSrcRegs(); }

	/** Number of destination registers. */
	int8_t numDestRegs() const { return staticInst->numDestRegs(); }

	// the following are used to track physical register usage
	// for machines with separate int & FP reg files
	int8_t numFPDestRegs() const { return staticInst->numFPDestRegs(); }
	int8_t numIntDestRegs() const { return staticInst->numIntDestRegs(); }

	/** Returns the logical register index of the i'th destination register. */
	RegIndex destRegIdx(int i) const
	{
	return staticInst->destRegIdx(i);
	}

	/** Returns the logical register index of the i'th source register. */
	RegIndex srcRegIdx(int i) const
	{
	return staticInst->srcRegIdx(i);
	}

	/** Returns the result of an integer instruction. */
	uint64_t readIntResult() { return instResult.integer; }

	/** Returns the result of a floating point instruction. */
	float readFloatResult() { return instResult.fp; }

	/** Returns the result of a floating point (double) instruction. */
	double readDoubleResult() { return instResult.dbl; }

	//Push to .cc file.
	/** Records that one of the source registers is ready. */
	void markSrcRegReady()
	{
	++readyRegs;
	if(readyRegs == numSrcRegs()) {
	canIssue = true;
	}
	}

	/** Marks a specific register as ready.
	* @todo: Move this to .cc file.
	*/
	void markSrcRegReady(RegIndex src_idx)
	{
	++readyRegs;

	_readySrcRegIdx[src_idx] = 1;

	if(readyRegs == numSrcRegs()) {
	canIssue = true;
	}
	}

	/** Returns if a source register is ready. */
	bool isReadySrcRegIdx(int idx) const
	{
	return this->_readySrcRegIdx[idx];
	}

	/** Sets this instruction as completed. */
	void setCompleted() { completed = true; }

	/** Returns whethe or not this instruction is completed. */
	bool isCompleted() const { return completed; }

	/** Sets this instruction as ready to issue. */
	void setCanIssue() { canIssue = true; }

	/** Returns whether or not this instruction is ready to issue. */
	bool readyToIssue() const { return canIssue; }

	/** Sets this instruction as issued from the IQ. */
	void setIssued() { issued = true; }

	/** Returns whether or not this instruction has issued. */
	bool isIssued() const { return issued; }

	/** Sets this instruction as executed. */
	void setExecuted() { executed = true; }

	/** Returns whether or not this instruction has executed. */
	bool isExecuted() const { return executed; }

	/** Sets this instruction as ready to commit. */
	void setCanCommit() { canCommit = true; }

	/** Clears this instruction as being ready to commit. */
	void clearCanCommit() { canCommit = false; }

	/** Returns whether or not this instruction is ready to commit. */
	bool readyToCommit() const { return canCommit; }

	/** Sets this instruction as squashed. */
	void setSquashed() { squashed = true; }

	/** Returns whether or not this instruction is squashed. */
	bool isSquashed() const { return squashed; }

	/** Sets this instruction as squashed in the IQ. */
	void setSquashedInIQ() { squashedInIQ = true; }

	/** Returns whether or not this instruction is squashed in the IQ. */
	bool isSquashedInIQ() const { return squashedInIQ; }

	/** Read the PC of this instruction. */
	const Addr readPC() const { return PC; }

	/** Set the next PC of this instruction (its actual target). */
	void setNextPC(uint64_t val) { nextPC = val; }

	/** Returns the exec context.
	* @todo: Remove this once the ExecContext is no longer used.
	*/
	ExecContext *xcBase() { return xc; }

	private:
	/** Instruction effective address.
	* @todo: Consider if this is necessary or not.
	*/
	Addr instEffAddr;
	/** Whether or not the effective address calculation is completed.
	* @todo: Consider if this is necessary or not.
	*/
	bool eaCalcDone;

	public:
	/** Sets the effective address. */
	void setEA(Addr &ea) { instEffAddr = ea; eaCalcDone = true; }

	/** Returns the effective address. */
	const Addr &getEA() const { return instEffAddr; }

	/** Returns whether or not the eff. addr. calculation has been completed. */
	bool doneEACalc() { return eaCalcDone; }

	/** Returns whether or not the eff. addr. source registers are ready. */
	bool eaSrcsReady();

	public:
	/** Load queue index. */
	int16_t lqIdx;

	/** Store queue index. */
	int16_t sqIdx;
	};

	template<class Impl>
	template<class T>
	inline Fault
	BaseDynInst<Impl>::read(Addr addr, T &data, unsigned flags)
	{
	MemReqPtr req = new MemReq(addr, xc, sizeof(T), flags);
	req->asid = asid;

	fault = cpu->translateDataReadReq(req);

	// Record key MemReq parameters so we can generate another one
	// just like it for the timing access without calling translate()
	// again (which might mess up the TLB).
	// Do I ever really need this? -KTL 3/05
	effAddr = req->vaddr;
	physEffAddr = req->paddr;
	memReqFlags = req->flags;

	/**
	* @todo
	* Replace the disjoint functional memory with a unified one and remove
	* this hack.
	*/
	#ifndef FULL_SYSTEM
	req->paddr = req->vaddr;
	#endif

	if (fault == No_Fault) {
	fault = cpu->read(req, data, lqIdx);
	} else {
	// Return a fixed value to keep simulation deterministic even
	// along misspeculated paths.
	data = (T)-1;
	}

	if (traceData) {
	traceData->setAddr(addr);
	traceData->setData(data);
	}

	return fault;
	}

	template<class Impl>
	template<class T>
	inline Fault
	BaseDynInst<Impl>::write(T data, Addr addr, unsigned flags, uint64_t *res)
	{
	if (traceData) {
	traceData->setAddr(addr);
	traceData->setData(data);
	}

	MemReqPtr req = new MemReq(addr, xc, sizeof(T), flags);

	req->asid = asid;

	fault = cpu->translateDataWriteReq(req);

	// Record key MemReq parameters so we can generate another one
	// just like it for the timing access without calling translate()
	// again (which might mess up the TLB).
	effAddr = req->vaddr;
	physEffAddr = req->paddr;
	memReqFlags = req->flags;

	/**
	* @todo
	* Replace the disjoint functional memory with a unified one and remove
	* this hack.
	*/
	#ifndef FULL_SYSTEM
	req->paddr = req->vaddr;
	#endif

	if (fault == No_Fault) {
	fault = cpu->write(req, data, sqIdx);
	}

	if (res) {
	// always return some result to keep misspeculated paths
	// (which will ignore faults) deterministic
	*res = (fault == No_Fault) ? req->result : 0;
	}

	return fault;
	}

	#endif // __CPU_BASE_DYN_INST_HH__