src/mem/qos/mem_ctrl.hh - public/gem5 - Git at Google

 /*
  * Copyright (c) 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.
  *
  * 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: Matteo Andreozzi
  */

 #include "debug/QOS.hh"
 #include "mem/abstract_mem.hh"
 #include "mem/qos/q_policy.hh"
 #include "mem/qos/policy.hh"
 #include "params/QoSMemCtrl.hh"
 #include "sim/system.hh"

 #include <unordered_map>
 #include <vector>
 #include <deque>

 #ifndef __MEM_QOS_MEM_CTRL_HH__
 #define __MEM_QOS_MEM_CTRL_HH__

 namespace QoS {

 /**
  * The QoS::MemCtrl is a base class for Memory objects
  * which support QoS - it provides access to a set of QoS
  * scheduling policies
  */
 class MemCtrl: public AbstractMemory
 {
   public:
     /** Bus Direction */
     enum BusState { READ, WRITE };

   protected:
     /** QoS Policy, assigns QoS priority to the incoming packets */
     const std::unique_ptr<Policy> policy;

     /** QoS Bus Turnaround Policy: selects the bus direction (READ/WRITE) */
     const std::unique_ptr<TurnaroundPolicy> turnPolicy;

     /** QoS Queue Policy: selects packet among same-priority queue */
     const std::unique_ptr<QueuePolicy> queuePolicy;

     /** Number of configured QoS priorities */
     const uint8_t _numPriorities;

     /** Enables QoS priority escalation */
     const bool qosPriorityEscalation;

     /**
      * Enables QoS synchronized scheduling invokes the QoS scheduler
      * on all masters, at every packet arrival.
      */
     const bool qosSyncroScheduler;

     /** Hash of master ID - master name */
     std::unordered_map<MasterID, const std::string> masters;

     /** Hash of masters - number of packets queued per priority */
     std::unordered_map<MasterID, std::vector<uint64_t> > packetPriorities;

     /** Hash of masters - address of request - queue of times of request */
     std::unordered_map<MasterID,
             std::unordered_map<uint64_t, std::deque<uint64_t>> > requestTimes;

     /**
      * Vector of QoS priorities/last service time. Refreshed at every
      * qosSchedule call.
      */
     std::vector<Tick> serviceTick;

     /** Read request packets queue length in #packets, per QoS priority */
     std::vector<uint64_t> readQueueSizes;

     /** Write request packets queue length in #packets, per QoS priority */
     std::vector<uint64_t> writeQueueSizes;

     /** Total read request packets queue length in #packets */
     uint64_t totalReadQueueSize;

     /** Total write request packets queue length in #packets */
     uint64_t totalWriteQueueSize;

     /**
      * Bus state used to control the read/write switching and drive
      * the scheduling of the next request.
      */
     BusState busState;

     /** bus state for next request event triggered */
     BusState busStateNext;

     /** per-master average QoS priority */
     Stats::VectorStandardDeviation avgPriority;
     /** per-master average QoS distance between assigned and queued values */
     Stats::VectorStandardDeviation avgPriorityDistance;

     /** per-priority minimum latency */
     Stats::Vector priorityMinLatency;
     /** per-priority maximum latency */
     Stats::Vector priorityMaxLatency;
     /** Count the number of turnarounds READ to WRITE */
     Stats::Scalar numReadWriteTurnArounds;
     /** Count the number of turnarounds WRITE to READ */
     Stats::Scalar numWriteReadTurnArounds;
     /** Count the number of times bus staying in READ state */
     Stats::Scalar numStayReadState;
     /** Count the number of times bus staying in WRITE state */
     Stats::Scalar numStayWriteState;

     /** registers statistics */
     void regStats() override;

     /**
      * Initializes dynamically counters and
      * statistics for a given Master
      *
      * @param m_id the master ID
      */
     void addMaster(const MasterID m_id);

     /**
      * Called upon receiving a request or
      * updates statistics and updates queues status
      *
      * @param dir request direction
      * @param m_id master id
      * @param qos packet qos value
      * @param addr packet address
      * @param entries number of entries to record
      */
     void logRequest(BusState dir, MasterID m_id, uint8_t qos,
                     Addr addr, uint64_t entries);

     /**
      * Called upon receiving a response,
      * updates statistics and updates queues status
      *
      * @param dir response direction
      * @param m_id master id
      * @param qos packet qos value
      * @param addr packet address
      * @param entries number of entries to record
      * @param delay response delay
      */
     void logResponse(BusState dir, MasterID m_id, uint8_t qos,
                      Addr addr, uint64_t entries, double delay);

     /**
      * Assign priority to a packet by executing
      * the configured QoS policy.
      *
      * @param queues_ptr list of pointers to packet queues
      * @param queue_entry_size size in bytes per each packet in the queue
      * @param pkt pointer to the Packet
      * @return a QoS priority value
      */
     template<typename Queues>
     uint8_t qosSchedule(std::initializer_list<Queues*> queues_ptr,
                         uint64_t queue_entry_size, const PacketPtr pkt);

     using SimObject::schedule;
     uint8_t schedule(MasterID m_id, uint64_t data);
     uint8_t schedule(const PacketPtr pkt);

     /**
      * Returns next bus direction (READ or WRITE)
      * based on configured policy.
      */
     BusState selectNextBusState();

     /**
      * Set current bus direction (READ or WRITE)
      * from next selected one
      */
     void setCurrentBusState() { busState = busStateNext; }

     /**
      * Record statistics on turnarounds based on
      * busStateNext and busState values
      */
     void recordTurnaroundStats();

     /**
      * Escalates/demotes priority of all packets
      * belonging to the passed master to given
      * priority value
      *
      * @param queues list of pointers to packet queues
      * @param queue_entry_size size of an entry in the queue
      * @param m_id master whose packets priority will change
      * @param tgt_prio target priority value
      */
     template<typename Queues>
     void escalate(std::initializer_list<Queues*> queues,
                   uint64_t queue_entry_size,
                   MasterID m_id, uint8_t tgt_prio);

     /**
      * Escalates/demotes priority of all packets
      * belonging to the passed master to given
      * priority value in a specified cluster of queues
      * (e.g. read queues or write queues) which is passed
      * as an argument to the function.
      * The curr_prio/tgt_prio parameters are queue selectors in the
      * queue cluster.
      *
      * @param queues reference to packet queues
      * @param queue_entry_size size of an entry in the queue
      * @param m_id master whose packets priority will change
      * @param curr_prio source queue priority value
      * @param tgt_prio target queue priority value
      */
     template<typename Queues>
     void escalateQueues(Queues& queues, uint64_t queue_entry_size,
                         MasterID m_id, uint8_t curr_prio, uint8_t tgt_prio);

   public:
     /**
      * QoS Memory base class
      *
      * @param p pointer to QoSMemCtrl parameters
      */
     MemCtrl(const QoSMemCtrlParams*);

     virtual ~MemCtrl();

     /**
      * Initializes this object
      */
     void init() override;

     /**
      * Gets the current bus state
      *
      * @return current bus state
      */
     BusState getBusState() const { return busState; }

     /**
      * Gets the next bus state
      *
      * @return next bus state
      */
     BusState getBusStateNext() const { return busStateNext; }

     /**
      * hasMaster returns true if the selected master(ID) has
      * been registered in the memory controller, which happens if
      * the memory controller has received at least a packet from
      * that master.
      *
      * @param m_id master id to lookup
      * @return true if the memory controller has received a packet
      *         from the master, false otherwise.
      */
     bool hasMaster(MasterID m_id) const
     {
         return masters.find(m_id) != masters.end();
     }

     /**
      * Gets a READ queue size
      *
      * @param prio QoS Priority of the queue
      * @return queue size in packets
      */
     uint64_t getReadQueueSize(const uint8_t prio) const
     { return readQueueSizes[prio]; }

     /**
      * Gets a WRITE queue size
      *
      * @param prio QoS Priority of the queue
      * @return queue size in packets
      */
     uint64_t getWriteQueueSize(const uint8_t prio) const
     { return writeQueueSizes[prio]; }

     /**
      * Gets the total combined READ queues size
      *
      * @return total queues size in packets
      */
     uint64_t getTotalReadQueueSize() const { return totalReadQueueSize; }

     /**
      * Gets the total combined WRITE queues size
      *
      * @return total queues size in packets
      */
     uint64_t getTotalWriteQueueSize() const { return totalWriteQueueSize; }

     /**
      * Gets the last service tick related to a QoS Priority
      *
      * @param prio QoS Priority
      * @return tick
      */
     Tick getServiceTick(const uint8_t prio) const { return serviceTick[prio]; }

     /**
      * Gets the total number of priority levels in the
      * QoS memory controller.
      *
      * @return total number of priority levels
      */
     uint8_t numPriorities() const { return _numPriorities; }
 };

 template<typename Queues>
 void
 MemCtrl::escalateQueues(Queues& queues, uint64_t queue_entry_size,
                         MasterID m_id, uint8_t curr_prio, uint8_t tgt_prio)
 {
     auto it = queues[curr_prio].begin();
     while (it != queues[curr_prio].end()) {
         // No packets left to move
         if (packetPriorities[m_id][curr_prio] == 0)
             break;

         auto pkt = *it;

         DPRINTF(QOS,
                 "QoSMemCtrl::escalate checking priority %d packet "
                 "m_id %d address %d\n", curr_prio,
                 pkt->masterId(), pkt->getAddr());

         // Found a packet to move
         if (pkt->masterId() == m_id) {

             uint64_t moved_entries = divCeil(pkt->getSize(),
                                              queue_entry_size);

             DPRINTF(QOS,
                     "QoSMemCtrl::escalate Master %s [id %d] moving "
                     "packet addr %d size %d (p size %d) from priority %d "
                     "to priority %d - "
                     "this master packets %d (entries to move %d)\n",
                     masters[m_id], m_id, pkt->getAddr(),
                     pkt->getSize(),
                     queue_entry_size, curr_prio, tgt_prio,
                     packetPriorities[m_id][curr_prio], moved_entries);


             if (pkt->isRead()) {
                 panic_if(readQueueSizes[curr_prio] < moved_entries,
                          "QoSMemCtrl::escalate master %s negative READ "
                          "packets for priority %d",
                         masters[m_id], tgt_prio);
                 readQueueSizes[curr_prio] -= moved_entries;
                 readQueueSizes[tgt_prio] += moved_entries;
             } else if (pkt->isWrite()) {
                 panic_if(writeQueueSizes[curr_prio] < moved_entries,
                          "QoSMemCtrl::escalate master %s negative WRITE "
                          "packets for priority %d",
                         masters[m_id], tgt_prio);
                 writeQueueSizes[curr_prio] -= moved_entries;
                 writeQueueSizes[tgt_prio] += moved_entries;
             }

             // Change QoS priority and move packet
             pkt->qosValue(tgt_prio);
             queues[tgt_prio].push_back(pkt);

             // Erase element from source packet queue, this will
             // increment the iterator
             it = queues[curr_prio].erase(it);
             panic_if(packetPriorities[m_id][curr_prio] < moved_entries,
                      "QoSMemCtrl::escalate master %s negative packets "
                      "for priority %d",
                      masters[m_id], tgt_prio);

             packetPriorities[m_id][curr_prio] -= moved_entries;
             packetPriorities[m_id][tgt_prio] += moved_entries;
         } else {
             // Increment iterator to next location in the queue
             it++;
         }
     }
 }

 template<typename Queues>
 void
 MemCtrl::escalate(std::initializer_list<Queues*> queues,
                   uint64_t queue_entry_size,
                   MasterID m_id, uint8_t tgt_prio)
 {
     // If needed, initialize all counters and statistics
     // for this master
     addMaster(m_id);

     DPRINTF(QOS,
             "QoSMemCtrl::escalate Master %s [id %d] to priority "
             "%d (currently %d packets)\n",masters[m_id], m_id, tgt_prio,
             packetPriorities[m_id][tgt_prio]);

     for (uint8_t curr_prio = 0; curr_prio < numPriorities(); ++curr_prio) {
         // Skip target priority
         if (curr_prio == tgt_prio)
             continue;

         // Process other priority packet
         while (packetPriorities[m_id][curr_prio] > 0) {
             DPRINTF(QOS,
                     "QoSMemCtrl::escalate MID %d checking priority %d "
                     "(packets %d)- current packets in prio %d:  %d\n"
                     "\t(source read %d source write %d target read %d, "
                     "target write %d)\n",
                     m_id, curr_prio, packetPriorities[m_id][curr_prio],
                     tgt_prio, packetPriorities[m_id][tgt_prio],
                     readQueueSizes[curr_prio],
                     writeQueueSizes[curr_prio], readQueueSizes[tgt_prio],
                     writeQueueSizes[tgt_prio]);

             // Check both read and write queue
             for (auto q : queues) {
                 escalateQueues(*q, queue_entry_size, m_id,
                                curr_prio, tgt_prio);
             }
         }
     }

     DPRINTF(QOS,
             "QoSMemCtrl::escalate Completed master %s [id %d] to priority %d "
             "(now %d packets)\n\t(total read %d, total write %d)\n",
             masters[m_id], m_id, tgt_prio, packetPriorities[m_id][tgt_prio],
             readQueueSizes[tgt_prio], writeQueueSizes[tgt_prio]);
 }

 template<typename Queues>
 uint8_t
 MemCtrl::qosSchedule(std::initializer_list<Queues*> queues,
                      const uint64_t queue_entry_size,
                      const PacketPtr pkt)
 {
     // Schedule packet.
     uint8_t pkt_priority = schedule(pkt);

     assert(pkt_priority < numPriorities());

     pkt->qosValue(pkt_priority);

     if (qosSyncroScheduler) {
         // Call the scheduling function on all other masters.
         for (const auto& m : masters) {

             if (m.first == pkt->masterId())
                 continue;

             uint8_t prio = schedule(m.first, 0);

             if (qosPriorityEscalation) {
                 DPRINTF(QOS,
                         "QoSMemCtrl::qosSchedule: (syncro) escalating "
                         "MASTER %s to assigned priority %d\n",
                         _system->getMasterName(m.first),
                         prio);
                 escalate(queues, queue_entry_size, m.first, prio);
             }
         }
     }

     if (qosPriorityEscalation) {
         DPRINTF(QOS,
                 "QoSMemCtrl::qosSchedule: escalating "
                 "MASTER %s to assigned priority %d\n",
                 _system->getMasterName(pkt->masterId()),
                 pkt_priority);
         escalate(queues, queue_entry_size, pkt->masterId(), pkt_priority);
     }

     // Update last service tick for selected priority
     serviceTick[pkt_priority] = curTick();

     return pkt_priority;
 }

 } // namespace QoS

 #endif /* __MEM_QOS_MEM_CTRL_HH__ */
	/*
	* Copyright (c) 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.
	*
	* 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: Matteo Andreozzi
	*/

	#include "debug/QOS.hh"
	#include "mem/abstract_mem.hh"
	#include "mem/qos/q_policy.hh"
	#include "mem/qos/policy.hh"
	#include "params/QoSMemCtrl.hh"
	#include "sim/system.hh"

	#include <unordered_map>
	#include <vector>
	#include <deque>

	#ifndef __MEM_QOS_MEM_CTRL_HH__
	#define __MEM_QOS_MEM_CTRL_HH__

	namespace QoS {

	/**
	* The QoS::MemCtrl is a base class for Memory objects
	* which support QoS - it provides access to a set of QoS
	* scheduling policies
	*/
	class MemCtrl: public AbstractMemory
	{
	public:
	/** Bus Direction */
	enum BusState { READ, WRITE };

	protected:
	/** QoS Policy, assigns QoS priority to the incoming packets */
	const std::unique_ptr<Policy> policy;

	/** QoS Bus Turnaround Policy: selects the bus direction (READ/WRITE) */
	const std::unique_ptr<TurnaroundPolicy> turnPolicy;

	/** QoS Queue Policy: selects packet among same-priority queue */
	const std::unique_ptr<QueuePolicy> queuePolicy;

	/** Number of configured QoS priorities */
	const uint8_t _numPriorities;

	/** Enables QoS priority escalation */
	const bool qosPriorityEscalation;

	/**
	* Enables QoS synchronized scheduling invokes the QoS scheduler
	* on all masters, at every packet arrival.
	*/
	const bool qosSyncroScheduler;

	/** Hash of master ID - master name */
	std::unordered_map<MasterID, const std::string> masters;

	/** Hash of masters - number of packets queued per priority */
	std::unordered_map<MasterID, std::vector<uint64_t> > packetPriorities;

	/** Hash of masters - address of request - queue of times of request */
	std::unordered_map<MasterID,
	std::unordered_map<uint64_t, std::deque<uint64_t>> > requestTimes;

	/**
	* Vector of QoS priorities/last service time. Refreshed at every
	* qosSchedule call.
	*/
	std::vector<Tick> serviceTick;

	/** Read request packets queue length in #packets, per QoS priority */
	std::vector<uint64_t> readQueueSizes;

	/** Write request packets queue length in #packets, per QoS priority */
	std::vector<uint64_t> writeQueueSizes;

	/** Total read request packets queue length in #packets */
	uint64_t totalReadQueueSize;

	/** Total write request packets queue length in #packets */
	uint64_t totalWriteQueueSize;

	/**
	* Bus state used to control the read/write switching and drive
	* the scheduling of the next request.
	*/
	BusState busState;

	/** bus state for next request event triggered */
	BusState busStateNext;

	/** per-master average QoS priority */
	Stats::VectorStandardDeviation avgPriority;
	/** per-master average QoS distance between assigned and queued values */
	Stats::VectorStandardDeviation avgPriorityDistance;

	/** per-priority minimum latency */
	Stats::Vector priorityMinLatency;
	/** per-priority maximum latency */
	Stats::Vector priorityMaxLatency;
	/** Count the number of turnarounds READ to WRITE */
	Stats::Scalar numReadWriteTurnArounds;
	/** Count the number of turnarounds WRITE to READ */
	Stats::Scalar numWriteReadTurnArounds;
	/** Count the number of times bus staying in READ state */
	Stats::Scalar numStayReadState;
	/** Count the number of times bus staying in WRITE state */
	Stats::Scalar numStayWriteState;

	/** registers statistics */
	void regStats() override;

	/**
	* Initializes dynamically counters and
	* statistics for a given Master
	*
	* @param m_id the master ID
	*/
	void addMaster(const MasterID m_id);

	/**
	* Called upon receiving a request or
	* updates statistics and updates queues status
	*
	* @param dir request direction
	* @param m_id master id
	* @param qos packet qos value
	* @param addr packet address
	* @param entries number of entries to record
	*/
	void logRequest(BusState dir, MasterID m_id, uint8_t qos,
	Addr addr, uint64_t entries);

	/**
	* Called upon receiving a response,
	* updates statistics and updates queues status
	*
	* @param dir response direction
	* @param m_id master id
	* @param qos packet qos value
	* @param addr packet address
	* @param entries number of entries to record
	* @param delay response delay
	*/
	void logResponse(BusState dir, MasterID m_id, uint8_t qos,
	Addr addr, uint64_t entries, double delay);

	/**
	* Assign priority to a packet by executing
	* the configured QoS policy.
	*
	* @param queues_ptr list of pointers to packet queues
	* @param queue_entry_size size in bytes per each packet in the queue
	* @param pkt pointer to the Packet
	* @return a QoS priority value
	*/
	template<typename Queues>
	uint8_t qosSchedule(std::initializer_list<Queues*> queues_ptr,
	uint64_t queue_entry_size, const PacketPtr pkt);

	using SimObject::schedule;
	uint8_t schedule(MasterID m_id, uint64_t data);
	uint8_t schedule(const PacketPtr pkt);

	/**
	* Returns next bus direction (READ or WRITE)
	* based on configured policy.
	*/
	BusState selectNextBusState();

	/**
	* Set current bus direction (READ or WRITE)
	* from next selected one
	*/
	void setCurrentBusState() { busState = busStateNext; }

	/**
	* Record statistics on turnarounds based on
	* busStateNext and busState values
	*/
	void recordTurnaroundStats();

	/**
	* Escalates/demotes priority of all packets
	* belonging to the passed master to given
	* priority value
	*
	* @param queues list of pointers to packet queues
	* @param queue_entry_size size of an entry in the queue
	* @param m_id master whose packets priority will change
	* @param tgt_prio target priority value
	*/
	template<typename Queues>
	void escalate(std::initializer_list<Queues*> queues,
	uint64_t queue_entry_size,
	MasterID m_id, uint8_t tgt_prio);

	/**
	* Escalates/demotes priority of all packets
	* belonging to the passed master to given
	* priority value in a specified cluster of queues
	* (e.g. read queues or write queues) which is passed
	* as an argument to the function.
	* The curr_prio/tgt_prio parameters are queue selectors in the
	* queue cluster.
	*
	* @param queues reference to packet queues
	* @param queue_entry_size size of an entry in the queue
	* @param m_id master whose packets priority will change
	* @param curr_prio source queue priority value
	* @param tgt_prio target queue priority value
	*/
	template<typename Queues>
	void escalateQueues(Queues& queues, uint64_t queue_entry_size,
	MasterID m_id, uint8_t curr_prio, uint8_t tgt_prio);

	public:
	/**
	* QoS Memory base class
	*
	* @param p pointer to QoSMemCtrl parameters
	*/
	MemCtrl(const QoSMemCtrlParams*);

	virtual ~MemCtrl();

	/**
	* Initializes this object
	*/
	void init() override;

	/**
	* Gets the current bus state
	*
	* @return current bus state
	*/
	BusState getBusState() const { return busState; }

	/**
	* Gets the next bus state
	*
	* @return next bus state
	*/
	BusState getBusStateNext() const { return busStateNext; }

	/**
	* hasMaster returns true if the selected master(ID) has
	* been registered in the memory controller, which happens if
	* the memory controller has received at least a packet from
	* that master.
	*
	* @param m_id master id to lookup
	* @return true if the memory controller has received a packet
	* from the master, false otherwise.
	*/
	bool hasMaster(MasterID m_id) const
	{
	return masters.find(m_id) != masters.end();
	}

	/**
	* Gets a READ queue size
	*
	* @param prio QoS Priority of the queue
	* @return queue size in packets
	*/
	uint64_t getReadQueueSize(const uint8_t prio) const
	{ return readQueueSizes[prio]; }

	/**
	* Gets a WRITE queue size
	*
	* @param prio QoS Priority of the queue
	* @return queue size in packets
	*/
	uint64_t getWriteQueueSize(const uint8_t prio) const
	{ return writeQueueSizes[prio]; }

	/**
	* Gets the total combined READ queues size
	*
	* @return total queues size in packets
	*/
	uint64_t getTotalReadQueueSize() const { return totalReadQueueSize; }

	/**
	* Gets the total combined WRITE queues size
	*
	* @return total queues size in packets
	*/
	uint64_t getTotalWriteQueueSize() const { return totalWriteQueueSize; }

	/**
	* Gets the last service tick related to a QoS Priority
	*
	* @param prio QoS Priority
	* @return tick
	*/
	Tick getServiceTick(const uint8_t prio) const { return serviceTick[prio]; }

	/**
	* Gets the total number of priority levels in the
	* QoS memory controller.
	*
	* @return total number of priority levels
	*/
	uint8_t numPriorities() const { return _numPriorities; }
	};

	template<typename Queues>
	void
	MemCtrl::escalateQueues(Queues& queues, uint64_t queue_entry_size,
	MasterID m_id, uint8_t curr_prio, uint8_t tgt_prio)
	{
	auto it = queues[curr_prio].begin();
	while (it != queues[curr_prio].end()) {
	// No packets left to move
	if (packetPriorities[m_id][curr_prio] == 0)
	break;

	auto pkt = *it;

	DPRINTF(QOS,
	"QoSMemCtrl::escalate checking priority %d packet "
	"m_id %d address %d\n", curr_prio,
	pkt->masterId(), pkt->getAddr());

	// Found a packet to move
	if (pkt->masterId() == m_id) {

	uint64_t moved_entries = divCeil(pkt->getSize(),
	queue_entry_size);

	DPRINTF(QOS,
	"QoSMemCtrl::escalate Master %s [id %d] moving "
	"packet addr %d size %d (p size %d) from priority %d "
	"to priority %d - "
	"this master packets %d (entries to move %d)\n",
	masters[m_id], m_id, pkt->getAddr(),
	pkt->getSize(),
	queue_entry_size, curr_prio, tgt_prio,
	packetPriorities[m_id][curr_prio], moved_entries);


	if (pkt->isRead()) {
	panic_if(readQueueSizes[curr_prio] < moved_entries,
	"QoSMemCtrl::escalate master %s negative READ "
	"packets for priority %d",
	masters[m_id], tgt_prio);
	readQueueSizes[curr_prio] -= moved_entries;
	readQueueSizes[tgt_prio] += moved_entries;
	} else if (pkt->isWrite()) {
	panic_if(writeQueueSizes[curr_prio] < moved_entries,
	"QoSMemCtrl::escalate master %s negative WRITE "
	"packets for priority %d",
	masters[m_id], tgt_prio);
	writeQueueSizes[curr_prio] -= moved_entries;
	writeQueueSizes[tgt_prio] += moved_entries;
	}

	// Change QoS priority and move packet
	pkt->qosValue(tgt_prio);
	queues[tgt_prio].push_back(pkt);

	// Erase element from source packet queue, this will
	// increment the iterator
	it = queues[curr_prio].erase(it);
	panic_if(packetPriorities[m_id][curr_prio] < moved_entries,
	"QoSMemCtrl::escalate master %s negative packets "
	"for priority %d",
	masters[m_id], tgt_prio);

	packetPriorities[m_id][curr_prio] -= moved_entries;
	packetPriorities[m_id][tgt_prio] += moved_entries;
	} else {
	// Increment iterator to next location in the queue
	it++;
	}
	}
	}

	template<typename Queues>
	void
	MemCtrl::escalate(std::initializer_list<Queues*> queues,
	uint64_t queue_entry_size,
	MasterID m_id, uint8_t tgt_prio)
	{
	// If needed, initialize all counters and statistics
	// for this master
	addMaster(m_id);

	DPRINTF(QOS,
	"QoSMemCtrl::escalate Master %s [id %d] to priority "
	"%d (currently %d packets)\n",masters[m_id], m_id, tgt_prio,
	packetPriorities[m_id][tgt_prio]);

	for (uint8_t curr_prio = 0; curr_prio < numPriorities(); ++curr_prio) {
	// Skip target priority
	if (curr_prio == tgt_prio)
	continue;

	// Process other priority packet
	while (packetPriorities[m_id][curr_prio] > 0) {
	DPRINTF(QOS,
	"QoSMemCtrl::escalate MID %d checking priority %d "
	"(packets %d)- current packets in prio %d: %d\n"
	"\t(source read %d source write %d target read %d, "
	"target write %d)\n",
	m_id, curr_prio, packetPriorities[m_id][curr_prio],
	tgt_prio, packetPriorities[m_id][tgt_prio],
	readQueueSizes[curr_prio],
	writeQueueSizes[curr_prio], readQueueSizes[tgt_prio],
	writeQueueSizes[tgt_prio]);

	// Check both read and write queue
	for (auto q : queues) {
	escalateQueues(*q, queue_entry_size, m_id,
	curr_prio, tgt_prio);
	}
	}
	}

	DPRINTF(QOS,
	"QoSMemCtrl::escalate Completed master %s [id %d] to priority %d "
	"(now %d packets)\n\t(total read %d, total write %d)\n",
	masters[m_id], m_id, tgt_prio, packetPriorities[m_id][tgt_prio],
	readQueueSizes[tgt_prio], writeQueueSizes[tgt_prio]);
	}

	template<typename Queues>
	uint8_t
	MemCtrl::qosSchedule(std::initializer_list<Queues*> queues,
	const uint64_t queue_entry_size,
	const PacketPtr pkt)
	{
	// Schedule packet.
	uint8_t pkt_priority = schedule(pkt);

	assert(pkt_priority < numPriorities());

	pkt->qosValue(pkt_priority);

	if (qosSyncroScheduler) {
	// Call the scheduling function on all other masters.
	for (const auto& m : masters) {

	if (m.first == pkt->masterId())
	continue;

	uint8_t prio = schedule(m.first, 0);

	if (qosPriorityEscalation) {
	DPRINTF(QOS,
	"QoSMemCtrl::qosSchedule: (syncro) escalating "
	"MASTER %s to assigned priority %d\n",
	_system->getMasterName(m.first),
	prio);
	escalate(queues, queue_entry_size, m.first, prio);
	}
	}
	}

	if (qosPriorityEscalation) {
	DPRINTF(QOS,
	"QoSMemCtrl::qosSchedule: escalating "
	"MASTER %s to assigned priority %d\n",
	_system->getMasterName(pkt->masterId()),
	pkt_priority);
	escalate(queues, queue_entry_size, pkt->masterId(), pkt_priority);
	}

	// Update last service tick for selected priority
	serviceTick[pkt_priority] = curTick();

	return pkt_priority;
	}

	} // namespace QoS

	#endif /* __MEM_QOS_MEM_CTRL_HH__ */