src/cpu/minor/execute.hh - public/gem5 - Git at Google

 /*
  * Copyright (c) 2013-2014 ARM Limited
  * All rights reserved
  *
  * The license below extends only to copyright in the software and shall
  * not be construed as granting a license to any other intellectual
  * property including but not limited to intellectual property relating
  * to a hardware implementation of the functionality of the software
  * licensed hereunder.  You may use the software subject to the license
  * terms below provided that you ensure that this notice is replicated
  * unmodified and in its entirety in all distributions of the software,
  * modified or unmodified, in source code or in binary form.
  *
  * 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.
  */

 /**
  * @file
  *
  *  All the fun of executing instructions from Decode and sending branch/new
  *  instruction stream info. to Fetch1.
  */

 #ifndef __CPU_MINOR_EXECUTE_HH__
 #define __CPU_MINOR_EXECUTE_HH__

 #include <vector>

 #include "base/named.hh"
 #include "base/types.hh"
 #include "cpu/minor/buffers.hh"
 #include "cpu/minor/cpu.hh"
 #include "cpu/minor/func_unit.hh"
 #include "cpu/minor/lsq.hh"
 #include "cpu/minor/pipe_data.hh"
 #include "cpu/minor/scoreboard.hh"

 namespace gem5
 {

 GEM5_DEPRECATED_NAMESPACE(Minor, minor);
 namespace minor
 {

 /** Execute stage.  Everything apart from fetching and decoding instructions.
  *  The LSQ lives here too. */
 class Execute : public Named
 {
   protected:

     /** Input port carrying instructions from Decode */
     Latch<ForwardInstData>::Output inp;

     /** Input port carrying stream changes to Fetch1 */
     Latch<BranchData>::Input out;

     /** Pointer back to the containing CPU */
     MinorCPU &cpu;

     /** Index of the zero integer register. */
     const RegIndex zeroReg;

     /** Number of instructions that can be issued per cycle */
     unsigned int issueLimit;

     /** Number of memory ops that can be issued per cycle */
     unsigned int memoryIssueLimit;

     /** Number of instructions that can be committed per cycle */
     unsigned int commitLimit;

     /** Number of memory instructions that can be committed per cycle */
     unsigned int memoryCommitLimit;

     /** If true, more than one input line can be processed each cycle if
      *  there is room to execute more instructions than taken from the first
      *  line */
     bool processMoreThanOneInput;

     /** Descriptions of the functional units we want to generate */
     MinorFUPool &fuDescriptions;

     /** Number of functional units to produce */
     unsigned int numFuncUnits;

     /** Longest latency of any FU, useful for setting up the activity
      *  recoder */
     Cycles longestFuLatency;

     /** Modify instruction trace times on commit */
     bool setTraceTimeOnCommit;

     /** Modify instruction trace times on issue */
     bool setTraceTimeOnIssue;

     /** Allow mem refs to leave their FUs before reaching the head
      *  of the in flight insts queue if their dependencies are met */
     bool allowEarlyMemIssue;

     /** The FU index of the non-existent costless FU for instructions
      *  which pass the MinorDynInst::isNoCostInst test */
     unsigned int noCostFUIndex;

     /** Dcache port to pass on to the CPU.  Execute owns this */
     LSQ lsq;

     /** Scoreboard of instruction dependencies */
     std::vector<Scoreboard> scoreboard;

     /** The execution functional units */
     std::vector<FUPipeline *> funcUnits;

   public: /* Public for Pipeline to be able to pass it to Decode */
     std::vector<InputBuffer<ForwardInstData>> inputBuffer;

   protected:
     /** Stage cycle-by-cycle state */

     /** State that drain passes through (in order).  On a drain request,
      *  Execute transitions into either DrainCurrentInst (if between
      *  microops) or DrainHaltFetch.
      *
      *  Note that Execute doesn't actually have *  a 'Drained' state, only
      *  an indication that it's currently draining and isDrained that can't
      *  tell if there are insts still in the pipeline leading up to
      *  Execute */
     enum DrainState
     {
         NotDraining, /* Not draining, possibly running */
         DrainCurrentInst, /* Draining to end of inst/macroop */
         DrainHaltFetch, /* Halting Fetch after completing current inst */
         DrainAllInsts /* Discarding all remaining insts */
     };

     struct ExecuteThreadInfo
     {
         /** Constructor */
         ExecuteThreadInfo(unsigned int insts_committed) :
             inputIndex(0),
             lastCommitWasEndOfMacroop(true),
             instsBeingCommitted(insts_committed),
             streamSeqNum(InstId::firstStreamSeqNum),
             lastPredictionSeqNum(InstId::firstPredictionSeqNum),
             drainState(NotDraining)
         { }

         ExecuteThreadInfo(const ExecuteThreadInfo& other) :
             inputIndex(other.inputIndex),
             lastCommitWasEndOfMacroop(other.lastCommitWasEndOfMacroop),
             instsBeingCommitted(other.instsBeingCommitted),
             streamSeqNum(other.streamSeqNum),
             lastPredictionSeqNum(other.lastPredictionSeqNum),
             drainState(other.drainState)
         { }

         /** In-order instructions either in FUs or the LSQ */
         Queue<QueuedInst, ReportTraitsAdaptor<QueuedInst> > *inFlightInsts;

         /** Memory ref instructions still in the FUs */
         Queue<QueuedInst, ReportTraitsAdaptor<QueuedInst> > *inFUMemInsts;

         /** Index that we've completed upto in getInput data.  We can say we're
          *  popInput when this equals getInput()->width() */
         unsigned int inputIndex;

         /** The last commit was the end of a full instruction so an interrupt
          *  can safely happen */
         bool lastCommitWasEndOfMacroop;

         /** Structure for reporting insts currently being processed/retired
          *  for MinorTrace */
         ForwardInstData instsBeingCommitted;

         /** Source of sequence number for instuction streams.  Increment this and
          *  pass to fetch whenever an instruction stream needs to be changed.
          *  For any more complicated behaviour (e.g. speculation) there'll need
          *  to be another plan. */
         InstSeqNum streamSeqNum;

         /** A prediction number for use where one isn't available from an
          *  instruction.  This is harvested from committed instructions.
          *  This isn't really needed as the streamSeqNum will change on
          *  a branch, but it minimises disruption in stream identification */
         InstSeqNum lastPredictionSeqNum;

         /** State progression for draining NotDraining -> ... -> DrainAllInsts */
         DrainState drainState;
     };

     std::vector<ExecuteThreadInfo> executeInfo;

     ThreadID interruptPriority;
     ThreadID issuePriority;
     ThreadID commitPriority;

   protected:
     friend std::ostream &operator <<(std::ostream &os, DrainState state);

     /** Get a piece of data to work on from the inputBuffer, or 0 if there
      *  is no data. */
     const ForwardInstData *getInput(ThreadID tid);

     /** Pop an element off the input buffer, if there are any */
     void popInput(ThreadID tid);

     /** Generate Branch data based (into branch) on an observed (or not)
      *  change in PC while executing an instruction.
      *  Also handles branch prediction information within the inst. */
     void tryToBranch(MinorDynInstPtr inst, Fault fault, BranchData &branch);

     /** Actually create a branch to communicate to Fetch1/Fetch2 and,
      *  if that is a stream-changing branch update the streamSeqNum */
     void updateBranchData(ThreadID tid, BranchData::Reason reason,
         MinorDynInstPtr inst, const TheISA::PCState &target,
         BranchData &branch);

     /** Handle extracting mem ref responses from the memory queues and
      *  completing the associated instructions.
      *  Fault is an output and will contain any fault caused (and already
      *  invoked by the function)
      *  Sets branch to any branch generated by the instruction. */
     void handleMemResponse(MinorDynInstPtr inst,
         LSQ::LSQRequestPtr response, BranchData &branch,
         Fault &fault);

     /** Execute a memory reference instruction.  This calls initiateAcc on
      *  the instruction which will then call writeMem or readMem to issue a
      *  memory access to the LSQ.
      *  Returns true if the instruction was executed rather than stalled
      *  because of a lack of LSQ resources and false otherwise.
      *  branch is set to any branch raised by the instruction.
      *  failed_predicate is set to false if the instruction passed its
      *  predicate and so will access memory or true if the instruction
      *  *failed* its predicate and is now complete.
      *  fault is set if any non-NoFault fault is raised.
      *  Any faults raised are actually invoke-d by this function. */
     bool executeMemRefInst(MinorDynInstPtr inst, BranchData &branch,
         bool &failed_predicate, Fault &fault);

     /** Has an interrupt been raised */
     bool isInterrupted(ThreadID thread_id) const;

     /** Are we between instructions?  Can we be interrupted? */
     bool isInbetweenInsts(ThreadID thread_id) const;

     /** Act on an interrupt.  Returns true if an interrupt was actually
      *  signalled and invoked */
     bool takeInterrupt(ThreadID thread_id, BranchData &branch);

     /** Try and issue instructions from the inputBuffer */
     unsigned int issue(ThreadID thread_id);

     /** Try to act on PC-related events.  Returns true if any were
      *  executed */
     bool tryPCEvents(ThreadID thread_id);

     /** Do the stats handling and instruction count and PC event events
      *  related to the new instruction/op counts */
     void doInstCommitAccounting(MinorDynInstPtr inst);

     /** Check all threads for possible interrupts. If interrupt is taken,
      *  returns the tid of the thread.  interrupted is set if any thread
      *  has an interrupt, irrespective of if it is taken */
     ThreadID checkInterrupts(BranchData& branch, bool& interrupted);

     /** Checks if a specific thread has an interrupt.  No action is taken.
      *  this is used for determining if a thread should only commit microops */
     bool hasInterrupt(ThreadID thread_id);

     /** Commit a single instruction.  Returns true if the instruction being
      *  examined was completed (fully executed, discarded, or initiated a
      *  memory access), false if there is still some processing to do.
      *  fu_index is the index of the functional unit this instruction is
      *  being executed in into for funcUnits
      *  If early_memory_issue is true then this is an early execution
      *  of a mem ref and so faults will not be processed.
      *  If the return value is true:
      *      fault is set if a fault happened,
      *      branch is set to indicate any branch that occurs
      *      committed is set to true if this instruction is committed
      *          (and so needs to be traced and accounted for)
      *      completed_mem_issue is set if the instruction was a
      *          memory access that was issued */
     bool commitInst(MinorDynInstPtr inst, bool early_memory_issue,
         BranchData &branch, Fault &fault, bool &committed,
         bool &completed_mem_issue);

     /** Try and commit instructions from the ends of the functional unit
      *  pipelines.
      *  If only_commit_microops is true then only commit upto the
      *  end of the currect full instruction.
      *  If discard is true then discard all instructions rather than
      *  committing.
      *  branch is set to any branch raised during commit. */
     void commit(ThreadID thread_id, bool only_commit_microops, bool discard,
         BranchData &branch);

     /** Set the drain state (with useful debugging messages) */
     void setDrainState(ThreadID thread_id, DrainState state);

     /** Use the current threading policy to determine the next thread to
      *  decode from. */
     ThreadID getCommittingThread();
     ThreadID getIssuingThread();

   public:
     Execute(const std::string &name_,
         MinorCPU &cpu_,
         const MinorCPUParams &params,
         Latch<ForwardInstData>::Output inp_,
         Latch<BranchData>::Input out_);

     ~Execute();

   public:

     /** Returns the DcachePort owned by this Execute to pass upwards */
     MinorCPU::MinorCPUPort &getDcachePort();

     /** To allow ExecContext to find the LSQ */
     LSQ &getLSQ() { return lsq; }

     /** Does the given instruction have the right stream sequence number
      *  to be committed? */
     bool instIsRightStream(MinorDynInstPtr inst);

     /** Returns true if the given instruction is at the head of the
      *  inFlightInsts instruction queue */
     bool instIsHeadInst(MinorDynInstPtr inst);

     /** Pass on input/buffer data to the output if you can */
     void evaluate();

     void minorTrace() const;

     /** After thread suspension, has Execute been drained of in-flight
      *  instructions and memory accesses. */
     bool isDrained();

     /** Like the drain interface on SimObject */
     unsigned int drain();
     void drainResume();
 };

 } // namespace minor
 } // namespace gem5

 #endif /* __CPU_MINOR_EXECUTE_HH__ */
	/*
	* Copyright (c) 2013-2014 ARM Limited
	* All rights reserved
	*
	* The license below extends only to copyright in the software and shall
	* not be construed as granting a license to any other intellectual
	* property including but not limited to intellectual property relating
	* to a hardware implementation of the functionality of the software
	* licensed hereunder. You may use the software subject to the license
	* terms below provided that you ensure that this notice is replicated
	* unmodified and in its entirety in all distributions of the software,
	* modified or unmodified, in source code or in binary form.
	*
	* 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.
	*/

	/**
	* @file
	*
	* All the fun of executing instructions from Decode and sending branch/new
	* instruction stream info. to Fetch1.
	*/

	#ifndef __CPU_MINOR_EXECUTE_HH__
	#define __CPU_MINOR_EXECUTE_HH__

	#include <vector>

	#include "base/named.hh"
	#include "base/types.hh"
	#include "cpu/minor/buffers.hh"
	#include "cpu/minor/cpu.hh"
	#include "cpu/minor/func_unit.hh"
	#include "cpu/minor/lsq.hh"
	#include "cpu/minor/pipe_data.hh"
	#include "cpu/minor/scoreboard.hh"

	namespace gem5
	{

	GEM5_DEPRECATED_NAMESPACE(Minor, minor);
	namespace minor
	{

	/** Execute stage. Everything apart from fetching and decoding instructions.
	* The LSQ lives here too. */
	class Execute : public Named
	{
	protected:

	/** Input port carrying instructions from Decode */
	Latch<ForwardInstData>::Output inp;

	/** Input port carrying stream changes to Fetch1 */
	Latch<BranchData>::Input out;

	/** Pointer back to the containing CPU */
	MinorCPU &cpu;

	/** Index of the zero integer register. */
	const RegIndex zeroReg;

	/** Number of instructions that can be issued per cycle */
	unsigned int issueLimit;

	/** Number of memory ops that can be issued per cycle */
	unsigned int memoryIssueLimit;

	/** Number of instructions that can be committed per cycle */
	unsigned int commitLimit;

	/** Number of memory instructions that can be committed per cycle */
	unsigned int memoryCommitLimit;

	/** If true, more than one input line can be processed each cycle if
	* there is room to execute more instructions than taken from the first
	* line */
	bool processMoreThanOneInput;

	/** Descriptions of the functional units we want to generate */
	MinorFUPool &fuDescriptions;

	/** Number of functional units to produce */
	unsigned int numFuncUnits;

	/** Longest latency of any FU, useful for setting up the activity
	* recoder */
	Cycles longestFuLatency;

	/** Modify instruction trace times on commit */
	bool setTraceTimeOnCommit;

	/** Modify instruction trace times on issue */
	bool setTraceTimeOnIssue;

	/** Allow mem refs to leave their FUs before reaching the head
	* of the in flight insts queue if their dependencies are met */
	bool allowEarlyMemIssue;

	/** The FU index of the non-existent costless FU for instructions
	* which pass the MinorDynInst::isNoCostInst test */
	unsigned int noCostFUIndex;

	/** Dcache port to pass on to the CPU. Execute owns this */
	LSQ lsq;

	/** Scoreboard of instruction dependencies */
	std::vector<Scoreboard> scoreboard;

	/** The execution functional units */
	std::vector<FUPipeline *> funcUnits;

	public: /* Public for Pipeline to be able to pass it to Decode */
	std::vector<InputBuffer<ForwardInstData>> inputBuffer;

	protected:
	/** Stage cycle-by-cycle state */

	/** State that drain passes through (in order). On a drain request,
	* Execute transitions into either DrainCurrentInst (if between
	* microops) or DrainHaltFetch.
	*
	* Note that Execute doesn't actually have * a 'Drained' state, only
	* an indication that it's currently draining and isDrained that can't
	* tell if there are insts still in the pipeline leading up to
	* Execute */
	enum DrainState
	{
	NotDraining, /* Not draining, possibly running */
	DrainCurrentInst, /* Draining to end of inst/macroop */
	DrainHaltFetch, /* Halting Fetch after completing current inst */
	DrainAllInsts /* Discarding all remaining insts */
	};

	struct ExecuteThreadInfo
	{
	/** Constructor */
	ExecuteThreadInfo(unsigned int insts_committed) :
	inputIndex(0),
	lastCommitWasEndOfMacroop(true),
	instsBeingCommitted(insts_committed),
	streamSeqNum(InstId::firstStreamSeqNum),
	lastPredictionSeqNum(InstId::firstPredictionSeqNum),
	drainState(NotDraining)
	{ }

	ExecuteThreadInfo(const ExecuteThreadInfo& other) :
	inputIndex(other.inputIndex),
	lastCommitWasEndOfMacroop(other.lastCommitWasEndOfMacroop),
	instsBeingCommitted(other.instsBeingCommitted),
	streamSeqNum(other.streamSeqNum),
	lastPredictionSeqNum(other.lastPredictionSeqNum),
	drainState(other.drainState)
	{ }

	/** In-order instructions either in FUs or the LSQ */
	Queue<QueuedInst, ReportTraitsAdaptor<QueuedInst> > *inFlightInsts;

	/** Memory ref instructions still in the FUs */
	Queue<QueuedInst, ReportTraitsAdaptor<QueuedInst> > *inFUMemInsts;

	/** Index that we've completed upto in getInput data. We can say we're
	* popInput when this equals getInput()->width() */
	unsigned int inputIndex;

	/** The last commit was the end of a full instruction so an interrupt
	* can safely happen */
	bool lastCommitWasEndOfMacroop;

	/** Structure for reporting insts currently being processed/retired
	* for MinorTrace */
	ForwardInstData instsBeingCommitted;

	/** Source of sequence number for instuction streams. Increment this and
	* pass to fetch whenever an instruction stream needs to be changed.
	* For any more complicated behaviour (e.g. speculation) there'll need
	* to be another plan. */
	InstSeqNum streamSeqNum;

	/** A prediction number for use where one isn't available from an
	* instruction. This is harvested from committed instructions.
	* This isn't really needed as the streamSeqNum will change on
	* a branch, but it minimises disruption in stream identification */
	InstSeqNum lastPredictionSeqNum;

	/** State progression for draining NotDraining -> ... -> DrainAllInsts */
	DrainState drainState;
	};

	std::vector<ExecuteThreadInfo> executeInfo;

	ThreadID interruptPriority;
	ThreadID issuePriority;
	ThreadID commitPriority;

	protected:
	friend std::ostream &operator <<(std::ostream &os, DrainState state);

	/** Get a piece of data to work on from the inputBuffer, or 0 if there
	* is no data. */
	const ForwardInstData *getInput(ThreadID tid);

	/** Pop an element off the input buffer, if there are any */
	void popInput(ThreadID tid);

	/** Generate Branch data based (into branch) on an observed (or not)
	* change in PC while executing an instruction.
	* Also handles branch prediction information within the inst. */
	void tryToBranch(MinorDynInstPtr inst, Fault fault, BranchData &branch);

	/** Actually create a branch to communicate to Fetch1/Fetch2 and,
	* if that is a stream-changing branch update the streamSeqNum */
	void updateBranchData(ThreadID tid, BranchData::Reason reason,
	MinorDynInstPtr inst, const TheISA::PCState &target,
	BranchData &branch);

	/** Handle extracting mem ref responses from the memory queues and
	* completing the associated instructions.
	* Fault is an output and will contain any fault caused (and already
	* invoked by the function)
	* Sets branch to any branch generated by the instruction. */
	void handleMemResponse(MinorDynInstPtr inst,
	LSQ::LSQRequestPtr response, BranchData &branch,
	Fault &fault);

	/** Execute a memory reference instruction. This calls initiateAcc on
	* the instruction which will then call writeMem or readMem to issue a
	* memory access to the LSQ.
	* Returns true if the instruction was executed rather than stalled
	* because of a lack of LSQ resources and false otherwise.
	* branch is set to any branch raised by the instruction.
	* failed_predicate is set to false if the instruction passed its
	* predicate and so will access memory or true if the instruction
	* failed its predicate and is now complete.
	* fault is set if any non-NoFault fault is raised.
	* Any faults raised are actually invoke-d by this function. */
	bool executeMemRefInst(MinorDynInstPtr inst, BranchData &branch,
	bool &failed_predicate, Fault &fault);

	/** Has an interrupt been raised */
	bool isInterrupted(ThreadID thread_id) const;

	/** Are we between instructions? Can we be interrupted? */
	bool isInbetweenInsts(ThreadID thread_id) const;

	/** Act on an interrupt. Returns true if an interrupt was actually
	* signalled and invoked */
	bool takeInterrupt(ThreadID thread_id, BranchData &branch);

	/** Try and issue instructions from the inputBuffer */
	unsigned int issue(ThreadID thread_id);

	/** Try to act on PC-related events. Returns true if any were
	* executed */
	bool tryPCEvents(ThreadID thread_id);

	/** Do the stats handling and instruction count and PC event events
	* related to the new instruction/op counts */
	void doInstCommitAccounting(MinorDynInstPtr inst);

	/** Check all threads for possible interrupts. If interrupt is taken,
	* returns the tid of the thread. interrupted is set if any thread
	* has an interrupt, irrespective of if it is taken */
	ThreadID checkInterrupts(BranchData& branch, bool& interrupted);

	/** Checks if a specific thread has an interrupt. No action is taken.
	* this is used for determining if a thread should only commit microops */
	bool hasInterrupt(ThreadID thread_id);

	/** Commit a single instruction. Returns true if the instruction being
	* examined was completed (fully executed, discarded, or initiated a
	* memory access), false if there is still some processing to do.
	* fu_index is the index of the functional unit this instruction is
	* being executed in into for funcUnits
	* If early_memory_issue is true then this is an early execution
	* of a mem ref and so faults will not be processed.
	* If the return value is true:
	* fault is set if a fault happened,
	* branch is set to indicate any branch that occurs
	* committed is set to true if this instruction is committed
	* (and so needs to be traced and accounted for)
	* completed_mem_issue is set if the instruction was a
	* memory access that was issued */
	bool commitInst(MinorDynInstPtr inst, bool early_memory_issue,
	BranchData &branch, Fault &fault, bool &committed,
	bool &completed_mem_issue);

	/** Try and commit instructions from the ends of the functional unit
	* pipelines.
	* If only_commit_microops is true then only commit upto the
	* end of the currect full instruction.
	* If discard is true then discard all instructions rather than
	* committing.
	* branch is set to any branch raised during commit. */
	void commit(ThreadID thread_id, bool only_commit_microops, bool discard,
	BranchData &branch);

	/** Set the drain state (with useful debugging messages) */
	void setDrainState(ThreadID thread_id, DrainState state);

	/** Use the current threading policy to determine the next thread to
	* decode from. */
	ThreadID getCommittingThread();
	ThreadID getIssuingThread();

	public:
	Execute(const std::string &name_,
	MinorCPU &cpu_,
	const MinorCPUParams &params,
	Latch<ForwardInstData>::Output inp_,
	Latch<BranchData>::Input out_);

	~Execute();

	public:

	/** Returns the DcachePort owned by this Execute to pass upwards */
	MinorCPU::MinorCPUPort &getDcachePort();

	/** To allow ExecContext to find the LSQ */
	LSQ &getLSQ() { return lsq; }

	/** Does the given instruction have the right stream sequence number
	* to be committed? */
	bool instIsRightStream(MinorDynInstPtr inst);

	/** Returns true if the given instruction is at the head of the
	* inFlightInsts instruction queue */
	bool instIsHeadInst(MinorDynInstPtr inst);

	/** Pass on input/buffer data to the output if you can */
	void evaluate();

	void minorTrace() const;

	/** After thread suspension, has Execute been drained of in-flight
	* instructions and memory accesses. */
	bool isDrained();

	/** Like the drain interface on SimObject */
	unsigned int drain();
	void drainResume();
	};

	} // namespace minor
	} // namespace gem5

	#endif /* __CPU_MINOR_EXECUTE_HH__ */