src/mem/xbar.hh - testing/jenkins-gem5-prod - Git at Google

 /*
  * Copyright (c) 2011-2015, 2018 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.
  *
  * Copyright (c) 2002-2005 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.
  *
  * Authors: Ron Dreslinski
  *          Ali Saidi
  *          Andreas Hansson
  *          William Wang
  */

 /**
  * @file
  * Declaration of an abstract crossbar base class.
  */

 #ifndef __MEM_XBAR_HH__
 #define __MEM_XBAR_HH__

 #include <deque>
 #include <unordered_map>

 #include "base/addr_range_map.hh"
 #include "base/types.hh"
 #include "mem/mem_object.hh"
 #include "mem/qport.hh"
 #include "params/BaseXBar.hh"
 #include "sim/stats.hh"

 /**
  * The base crossbar contains the common elements of the non-coherent
  * and coherent crossbar. It is an abstract class that does not have
  * any of the functionality relating to the actual reception and
  * transmission of packets, as this is left for the subclasses.
  *
  * The BaseXBar is responsible for the basic flow control (busy or
  * not), the administration of retries, and the address decoding.
  */
 class BaseXBar : public MemObject
 {

   protected:

     /**
      * A layer is an internal crossbar arbitration point with its own
      * flow control. Each layer is a converging multiplexer tree. By
      * instantiating one layer per destination port (and per packet
      * type, i.e. request, response, snoop request and snoop
      * response), we model full crossbar structures like AXI, ACE,
      * PCIe, etc.
      *
      * The template parameter, PortClass, indicates the destination
      * port type for the layer. The retry list holds either master
      * ports or slave ports, depending on the direction of the
      * layer. Thus, a request layer has a retry list containing slave
      * ports, whereas a response layer holds master ports.
      */
     template <typename SrcType, typename DstType>
     class Layer : public Drainable
     {

       public:

         /**
          * Create a layer and give it a name. The layer uses
          * the crossbar an event manager.
          *
          * @param _port destination port the layer converges at
          * @param _xbar the crossbar this layer belongs to
          * @param _name the layer's name
          */
         Layer(DstType& _port, BaseXBar& _xbar, const std::string& _name);

         /**
          * Drain according to the normal semantics, so that the crossbar
          * can tell the layer to drain, and pass an event to signal
          * back when drained.
          *
          * @param de drain event to call once drained
          *
          * @return 1 if busy or waiting to retry, or 0 if idle
          */
         DrainState drain() override;

         /**
          * Get the crossbar layer's name
          */
         const std::string name() const { return xbar.name() + _name; }


         /**
          * Determine if the layer accepts a packet from a specific
          * port. If not, the port in question is also added to the
          * retry list. In either case the state of the layer is
          * updated accordingly.
          *
          * @param port Source port presenting the packet
          *
          * @return True if the layer accepts the packet
          */
         bool tryTiming(SrcType* src_port);

         /**
          * Deal with a destination port accepting a packet by potentially
          * removing the source port from the retry list (if retrying) and
          * occupying the layer accordingly.
          *
          * @param busy_time Time to spend as a result of a successful send
          */
         void succeededTiming(Tick busy_time);

         /**
          * Deal with a destination port not accepting a packet by
          * potentially adding the source port to the retry list (if
          * not already at the front) and occupying the layer
          * accordingly.
          *
          * @param src_port Source port
          * @param busy_time Time to spend as a result of a failed send
          */
         void failedTiming(SrcType* src_port, Tick busy_time);

         /** Occupy the layer until until */
         void occupyLayer(Tick until);

         /**
          * Send a retry to the port at the head of waitingForLayer. The
          * caller must ensure that the list is not empty.
          */
         void retryWaiting();

         /**
          * Handle a retry from a neighbouring module. This wraps
          * retryWaiting by verifying that there are ports waiting
          * before calling retryWaiting.
          */
         void recvRetry();

         /**
          * Register stats for the layer
          */
         void regStats();

       protected:

         /**
          * Sending the actual retry, in a manner specific to the
          * individual layers. Note that for a MasterPort, there is
          * both a RequestLayer and a SnoopResponseLayer using the same
          * port, but using different functions for the flow control.
          */
         virtual void sendRetry(SrcType* retry_port) = 0;

       private:

         /** The destination port this layer converges at. */
         DstType& port;

         /** The crossbar this layer is a part of. */
         BaseXBar& xbar;

         /** A name for this layer. */
         std::string _name;

         /**
          * We declare an enum to track the state of the layer. The
          * starting point is an idle state where the layer is waiting
          * for a packet to arrive. Upon arrival, the layer
          * transitions to the busy state, where it remains either
          * until the packet transfer is done, or the header time is
          * spent. Once the layer leaves the busy state, it can
          * either go back to idle, if no packets have arrived while it
          * was busy, or the layer goes on to retry the first port
          * in waitingForLayer. A similar transition takes place from
          * idle to retry if the layer receives a retry from one of
          * its connected ports. The retry state lasts until the port
          * in questions calls sendTiming and returns control to the
          * layer, or goes to a busy state if the port does not
          * immediately react to the retry by calling sendTiming.
          */
         enum State { IDLE, BUSY, RETRY };

         /** track the state of the layer */
         State state;

         /**
          * A deque of ports that retry should be called on because
          * the original send was delayed due to a busy layer.
          */
         std::deque<SrcType*> waitingForLayer;

         /**
          * Track who is waiting for the retry when receiving it from a
          * peer. If no port is waiting NULL is stored.
          */
         SrcType* waitingForPeer;

         /**
          * Release the layer after being occupied and return to an
          * idle state where we proceed to send a retry to any
          * potential waiting port, or drain if asked to do so.
          */
         void releaseLayer();

         /** event used to schedule a release of the layer */
         EventFunctionWrapper releaseEvent;

         /**
          * Stats for occupancy and utilization. These stats capture
          * the time the layer spends in the busy state and are thus only
          * relevant when the memory system is in timing mode.
          */
         Stats::Scalar occupancy;
         Stats::Formula utilization;

     };

     class ReqLayer : public Layer<SlavePort,MasterPort>
     {
       public:
         /**
          * Create a request layer and give it a name.
          *
          * @param _port destination port the layer converges at
          * @param _xbar the crossbar this layer belongs to
          * @param _name the layer's name
          */
         ReqLayer(MasterPort& _port, BaseXBar& _xbar, const std::string& _name) :
             Layer(_port, _xbar, _name) {}

       protected:

         void sendRetry(SlavePort* retry_port)
         { retry_port->sendRetryReq(); }
     };

     class RespLayer : public Layer<MasterPort,SlavePort>
     {
       public:
         /**
          * Create a response layer and give it a name.
          *
          * @param _port destination port the layer converges at
          * @param _xbar the crossbar this layer belongs to
          * @param _name the layer's name
          */
         RespLayer(SlavePort& _port, BaseXBar& _xbar, const std::string& _name) :
             Layer(_port, _xbar, _name) {}

       protected:

         void sendRetry(MasterPort* retry_port)
         { retry_port->sendRetryResp(); }
     };

     class SnoopRespLayer : public Layer<SlavePort,MasterPort>
     {
       public:
         /**
          * Create a snoop response layer and give it a name.
          *
          * @param _port destination port the layer converges at
          * @param _xbar the crossbar this layer belongs to
          * @param _name the layer's name
          */
         SnoopRespLayer(MasterPort& _port, BaseXBar& _xbar,
                        const std::string& _name) :
             Layer(_port, _xbar, _name) {}

       protected:

         void sendRetry(SlavePort* retry_port)
         { retry_port->sendRetrySnoopResp(); }
     };

     /**
      * Cycles of front-end pipeline including the delay to accept the request
      * and to decode the address.
      */
     const Cycles frontendLatency;
     /** Cycles of forward latency */
     const Cycles forwardLatency;
     /** Cycles of response latency */
     const Cycles responseLatency;
     /** the width of the xbar in bytes */
     const uint32_t width;

     AddrRangeMap<PortID, 3> portMap;

     /**
      * Remember where request packets came from so that we can route
      * responses to the appropriate port. This relies on the fact that
      * the underlying Request pointer inside the Packet stays
      * constant.
      */
     std::unordered_map<RequestPtr, PortID> routeTo;

     /** all contigous ranges seen by this crossbar */
     AddrRangeList xbarRanges;

     AddrRange defaultRange;

     /**
      * Function called by the port when the crossbar is recieving a
      * range change.
      *
      * @param master_port_id id of the port that received the change
      */
     virtual void recvRangeChange(PortID master_port_id);

     /**
      * Find which port connected to this crossbar (if any) should be
      * given a packet with this address range.
      *
      * @param addr_range Address range to find port for.
      * @return id of port that the packet should be sent out of.
      */
     PortID findPort(AddrRange addr_range);

     /**
      * Return the address ranges the crossbar is responsible for.
      *
      * @return a list of non-overlapping address ranges
      */
     AddrRangeList getAddrRanges() const;

     /**
      * Calculate the timing parameters for the packet. Updates the
      * headerDelay and payloadDelay fields of the packet
      * object with the relative number of ticks required to transmit
      * the header and the payload, respectively.
      *
      * @param pkt Packet to populate with timings
      * @param header_delay Header delay to be added
      */
     void calcPacketTiming(PacketPtr pkt, Tick header_delay);

     /**
      * Remember for each of the master ports of the crossbar if we got
      * an address range from the connected slave. For convenience,
      * also keep track of if we got ranges from all the slave modules
      * or not.
      */
     std::vector<bool> gotAddrRanges;
     bool gotAllAddrRanges;

     /** The master and slave ports of the crossbar */
     std::vector<QueuedSlavePort*> slavePorts;
     std::vector<MasterPort*> masterPorts;

     /** Port that handles requests that don't match any of the interfaces.*/
     PortID defaultPortID;

     /** If true, use address range provided by default device.  Any
        address not handled by another port and not in default device's
        range will cause a fatal error.  If false, just send all
        addresses not handled by another port to default device. */
     const bool useDefaultRange;

     BaseXBar(const BaseXBarParams *p);

     /**
      * Stats for transaction distribution and data passing through the
      * crossbar. The transaction distribution is globally counting
      * different types of commands. The packet count and total packet
      * size are two-dimensional vectors that are indexed by the
      * slave port and master port id (thus the neighbouring master and
      * neighbouring slave), summing up both directions (request and
      * response).
      */
     Stats::Vector transDist;
     Stats::Vector2d pktCount;
     Stats::Vector2d pktSize;

   public:

     virtual ~BaseXBar();

     virtual void init();

     /** A function used to return the port associated with this object. */
     BaseMasterPort& getMasterPort(const std::string& if_name,
                                   PortID idx = InvalidPortID);
     BaseSlavePort& getSlavePort(const std::string& if_name,
                                 PortID idx = InvalidPortID);

     virtual void regStats();

 };

 #endif //__MEM_XBAR_HH__
	/*
	* Copyright (c) 2011-2015, 2018 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.
	*
	* Copyright (c) 2002-2005 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.
	*
	* Authors: Ron Dreslinski
	* Ali Saidi
	* Andreas Hansson
	* William Wang
	*/

	/**
	* @file
	* Declaration of an abstract crossbar base class.
	*/

	#ifndef __MEM_XBAR_HH__
	#define __MEM_XBAR_HH__

	#include <deque>
	#include <unordered_map>

	#include "base/addr_range_map.hh"
	#include "base/types.hh"
	#include "mem/mem_object.hh"
	#include "mem/qport.hh"
	#include "params/BaseXBar.hh"
	#include "sim/stats.hh"

	/**
	* The base crossbar contains the common elements of the non-coherent
	* and coherent crossbar. It is an abstract class that does not have
	* any of the functionality relating to the actual reception and
	* transmission of packets, as this is left for the subclasses.
	*
	* The BaseXBar is responsible for the basic flow control (busy or
	* not), the administration of retries, and the address decoding.
	*/
	class BaseXBar : public MemObject
	{

	protected:

	/**
	* A layer is an internal crossbar arbitration point with its own
	* flow control. Each layer is a converging multiplexer tree. By
	* instantiating one layer per destination port (and per packet
	* type, i.e. request, response, snoop request and snoop
	* response), we model full crossbar structures like AXI, ACE,
	* PCIe, etc.
	*
	* The template parameter, PortClass, indicates the destination
	* port type for the layer. The retry list holds either master
	* ports or slave ports, depending on the direction of the
	* layer. Thus, a request layer has a retry list containing slave
	* ports, whereas a response layer holds master ports.
	*/
	template <typename SrcType, typename DstType>
	class Layer : public Drainable
	{

	public:

	/**
	* Create a layer and give it a name. The layer uses
	* the crossbar an event manager.
	*
	* @param _port destination port the layer converges at
	* @param _xbar the crossbar this layer belongs to
	* @param _name the layer's name
	*/
	Layer(DstType& _port, BaseXBar& _xbar, const std::string& _name);

	/**
	* Drain according to the normal semantics, so that the crossbar
	* can tell the layer to drain, and pass an event to signal
	* back when drained.
	*
	* @param de drain event to call once drained
	*
	* @return 1 if busy or waiting to retry, or 0 if idle
	*/
	DrainState drain() override;

	/**
	* Get the crossbar layer's name
	*/
	const std::string name() const { return xbar.name() + _name; }


	/**
	* Determine if the layer accepts a packet from a specific
	* port. If not, the port in question is also added to the
	* retry list. In either case the state of the layer is
	* updated accordingly.
	*
	* @param port Source port presenting the packet
	*
	* @return True if the layer accepts the packet
	*/
	bool tryTiming(SrcType* src_port);

	/**
	* Deal with a destination port accepting a packet by potentially
	* removing the source port from the retry list (if retrying) and
	* occupying the layer accordingly.
	*
	* @param busy_time Time to spend as a result of a successful send
	*/
	void succeededTiming(Tick busy_time);

	/**
	* Deal with a destination port not accepting a packet by
	* potentially adding the source port to the retry list (if
	* not already at the front) and occupying the layer
	* accordingly.
	*
	* @param src_port Source port
	* @param busy_time Time to spend as a result of a failed send
	*/
	void failedTiming(SrcType* src_port, Tick busy_time);

	/** Occupy the layer until until */
	void occupyLayer(Tick until);

	/**
	* Send a retry to the port at the head of waitingForLayer. The
	* caller must ensure that the list is not empty.
	*/
	void retryWaiting();

	/**
	* Handle a retry from a neighbouring module. This wraps
	* retryWaiting by verifying that there are ports waiting
	* before calling retryWaiting.
	*/
	void recvRetry();

	/**
	* Register stats for the layer
	*/
	void regStats();

	protected:

	/**
	* Sending the actual retry, in a manner specific to the
	* individual layers. Note that for a MasterPort, there is
	* both a RequestLayer and a SnoopResponseLayer using the same
	* port, but using different functions for the flow control.
	*/
	virtual void sendRetry(SrcType* retry_port) = 0;

	private:

	/** The destination port this layer converges at. */
	DstType& port;

	/** The crossbar this layer is a part of. */
	BaseXBar& xbar;

	/** A name for this layer. */
	std::string _name;

	/**
	* We declare an enum to track the state of the layer. The
	* starting point is an idle state where the layer is waiting
	* for a packet to arrive. Upon arrival, the layer
	* transitions to the busy state, where it remains either
	* until the packet transfer is done, or the header time is
	* spent. Once the layer leaves the busy state, it can
	* either go back to idle, if no packets have arrived while it
	* was busy, or the layer goes on to retry the first port
	* in waitingForLayer. A similar transition takes place from
	* idle to retry if the layer receives a retry from one of
	* its connected ports. The retry state lasts until the port
	* in questions calls sendTiming and returns control to the
	* layer, or goes to a busy state if the port does not
	* immediately react to the retry by calling sendTiming.
	*/
	enum State { IDLE, BUSY, RETRY };

	/** track the state of the layer */
	State state;

	/**
	* A deque of ports that retry should be called on because
	* the original send was delayed due to a busy layer.
	*/
	std::deque<SrcType*> waitingForLayer;

	/**
	* Track who is waiting for the retry when receiving it from a
	* peer. If no port is waiting NULL is stored.
	*/
	SrcType* waitingForPeer;

	/**
	* Release the layer after being occupied and return to an
	* idle state where we proceed to send a retry to any
	* potential waiting port, or drain if asked to do so.
	*/
	void releaseLayer();

	/** event used to schedule a release of the layer */
	EventFunctionWrapper releaseEvent;

	/**
	* Stats for occupancy and utilization. These stats capture
	* the time the layer spends in the busy state and are thus only
	* relevant when the memory system is in timing mode.
	*/
	Stats::Scalar occupancy;
	Stats::Formula utilization;

	};

	class ReqLayer : public Layer<SlavePort,MasterPort>
	{
	public:
	/**
	* Create a request layer and give it a name.
	*
	* @param _port destination port the layer converges at
	* @param _xbar the crossbar this layer belongs to
	* @param _name the layer's name
	*/
	ReqLayer(MasterPort& _port, BaseXBar& _xbar, const std::string& _name) :
	Layer(_port, _xbar, _name) {}

	protected:

	void sendRetry(SlavePort* retry_port)
	{ retry_port->sendRetryReq(); }
	};

	class RespLayer : public Layer<MasterPort,SlavePort>
	{
	public:
	/**
	* Create a response layer and give it a name.
	*
	* @param _port destination port the layer converges at
	* @param _xbar the crossbar this layer belongs to
	* @param _name the layer's name
	*/
	RespLayer(SlavePort& _port, BaseXBar& _xbar, const std::string& _name) :
	Layer(_port, _xbar, _name) {}

	protected:

	void sendRetry(MasterPort* retry_port)
	{ retry_port->sendRetryResp(); }
	};

	class SnoopRespLayer : public Layer<SlavePort,MasterPort>
	{
	public:
	/**
	* Create a snoop response layer and give it a name.
	*
	* @param _port destination port the layer converges at
	* @param _xbar the crossbar this layer belongs to
	* @param _name the layer's name
	*/
	SnoopRespLayer(MasterPort& _port, BaseXBar& _xbar,
	const std::string& _name) :
	Layer(_port, _xbar, _name) {}

	protected:

	void sendRetry(SlavePort* retry_port)
	{ retry_port->sendRetrySnoopResp(); }
	};

	/**
	* Cycles of front-end pipeline including the delay to accept the request
	* and to decode the address.
	*/
	const Cycles frontendLatency;
	/** Cycles of forward latency */
	const Cycles forwardLatency;
	/** Cycles of response latency */
	const Cycles responseLatency;
	/** the width of the xbar in bytes */
	const uint32_t width;

	AddrRangeMap<PortID, 3> portMap;

	/**
	* Remember where request packets came from so that we can route
	* responses to the appropriate port. This relies on the fact that
	* the underlying Request pointer inside the Packet stays
	* constant.
	*/
	std::unordered_map<RequestPtr, PortID> routeTo;

	/** all contigous ranges seen by this crossbar */
	AddrRangeList xbarRanges;

	AddrRange defaultRange;

	/**
	* Function called by the port when the crossbar is recieving a
	* range change.
	*
	* @param master_port_id id of the port that received the change
	*/
	virtual void recvRangeChange(PortID master_port_id);

	/**
	* Find which port connected to this crossbar (if any) should be
	* given a packet with this address range.
	*
	* @param addr_range Address range to find port for.
	* @return id of port that the packet should be sent out of.
	*/
	PortID findPort(AddrRange addr_range);

	/**
	* Return the address ranges the crossbar is responsible for.
	*
	* @return a list of non-overlapping address ranges
	*/
	AddrRangeList getAddrRanges() const;

	/**
	* Calculate the timing parameters for the packet. Updates the
	* headerDelay and payloadDelay fields of the packet
	* object with the relative number of ticks required to transmit
	* the header and the payload, respectively.
	*
	* @param pkt Packet to populate with timings
	* @param header_delay Header delay to be added
	*/
	void calcPacketTiming(PacketPtr pkt, Tick header_delay);

	/**
	* Remember for each of the master ports of the crossbar if we got
	* an address range from the connected slave. For convenience,
	* also keep track of if we got ranges from all the slave modules
	* or not.
	*/
	std::vector<bool> gotAddrRanges;
	bool gotAllAddrRanges;

	/** The master and slave ports of the crossbar */
	std::vector<QueuedSlavePort*> slavePorts;
	std::vector<MasterPort*> masterPorts;

	/** Port that handles requests that don't match any of the interfaces.*/
	PortID defaultPortID;

	/** If true, use address range provided by default device. Any
	address not handled by another port and not in default device's
	range will cause a fatal error. If false, just send all
	addresses not handled by another port to default device. */
	const bool useDefaultRange;

	BaseXBar(const BaseXBarParams *p);

	/**
	* Stats for transaction distribution and data passing through the
	* crossbar. The transaction distribution is globally counting
	* different types of commands. The packet count and total packet
	* size are two-dimensional vectors that are indexed by the
	* slave port and master port id (thus the neighbouring master and
	* neighbouring slave), summing up both directions (request and
	* response).
	*/
	Stats::Vector transDist;
	Stats::Vector2d pktCount;
	Stats::Vector2d pktSize;

	public:

	virtual ~BaseXBar();

	virtual void init();

	/** A function used to return the port associated with this object. */
	BaseMasterPort& getMasterPort(const std::string& if_name,
	PortID idx = InvalidPortID);
	BaseSlavePort& getSlavePort(const std::string& if_name,
	PortID idx = InvalidPortID);

	virtual void regStats();

	};

	#endif //__MEM_XBAR_HH__