src/mem/comm_monitor.cc - testing/jenkins-gem5-prod - Git at Google

 /*
  * Copyright (c) 2012-2013, 2015, 2018 ARM Limited
  * Copyright (c) 2016 Google Inc.
  * Copyright (c) 2017, Centre National de la Recherche Scientifique
  * 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: Thomas Grass
  *          Andreas Hansson
  *          Rahul Thakur
  *          Pierre-Yves Peneau
  */

 #include "mem/comm_monitor.hh"

 #include "base/trace.hh"
 #include "debug/CommMonitor.hh"
 #include "sim/stats.hh"

 CommMonitor::CommMonitor(Params* params)
     : MemObject(params),
       masterPort(name() + "-master", *this),
       slavePort(name() + "-slave", *this),
       samplePeriodicEvent([this]{ samplePeriodic(); }, name()),
       samplePeriodTicks(params->sample_period),
       samplePeriod(params->sample_period / SimClock::Float::s),
       stats(params)
 {
     DPRINTF(CommMonitor,
             "Created monitor %s with sample period %d ticks (%f ms)\n",
             name(), samplePeriodTicks, samplePeriod * 1E3);
 }

 CommMonitor*
 CommMonitorParams::create()
 {
     return new CommMonitor(this);
 }

 void
 CommMonitor::init()
 {
     // make sure both sides of the monitor are connected
     if (!slavePort.isConnected() || !masterPort.isConnected())
         fatal("Communication monitor is not connected on both sides.\n");
 }

 void
 CommMonitor::regProbePoints()
 {
     ppPktReq.reset(new ProbePoints::Packet(getProbeManager(), "PktRequest"));
     ppPktResp.reset(new ProbePoints::Packet(getProbeManager(), "PktResponse"));
 }

 Port &
 CommMonitor::getPort(const std::string &if_name, PortID idx)
 {
     if (if_name == "master") {
         return masterPort;
     } else if (if_name == "slave") {
         return slavePort;
     } else {
         return MemObject::getPort(if_name, idx);
     }
 }

 void
 CommMonitor::recvFunctional(PacketPtr pkt)
 {
     masterPort.sendFunctional(pkt);
 }

 void
 CommMonitor::recvFunctionalSnoop(PacketPtr pkt)
 {
     slavePort.sendFunctionalSnoop(pkt);
 }

 void
 CommMonitor::MonitorStats::updateReqStats(
     const ProbePoints::PacketInfo& pkt_info, bool is_atomic,
     bool expects_response)
 {
     if (pkt_info.cmd.isRead()) {
         // Increment number of observed read transactions
         if (!disableTransactionHists)
             ++readTrans;

         // Get sample of burst length
         if (!disableBurstLengthHists)
             readBurstLengthHist.sample(pkt_info.size);

         // Sample the masked address
         if (!disableAddrDists)
             readAddrDist.sample(pkt_info.addr & readAddrMask);

         if (!disableITTDists) {
             // Sample value of read-read inter transaction time
             if (timeOfLastRead != 0)
                 ittReadRead.sample(curTick() - timeOfLastRead);
             timeOfLastRead = curTick();

             // Sample value of req-req inter transaction time
             if (timeOfLastReq != 0)
                 ittReqReq.sample(curTick() - timeOfLastReq);
             timeOfLastReq = curTick();
         }
         if (!is_atomic && !disableOutstandingHists && expects_response)
             ++outstandingReadReqs;

     } else if (pkt_info.cmd.isWrite()) {
         // Same as for reads
         if (!disableTransactionHists)
             ++writeTrans;

         if (!disableBurstLengthHists)
             writeBurstLengthHist.sample(pkt_info.size);

         // Update the bandwidth stats on the request
         if (!disableBandwidthHists) {
             writtenBytes += pkt_info.size;
             totalWrittenBytes += pkt_info.size;
         }

         // Sample the masked write address
         if (!disableAddrDists)
             writeAddrDist.sample(pkt_info.addr & writeAddrMask);

         if (!disableITTDists) {
             // Sample value of write-to-write inter transaction time
             if (timeOfLastWrite != 0)
                 ittWriteWrite.sample(curTick() - timeOfLastWrite);
             timeOfLastWrite = curTick();

             // Sample value of req-to-req inter transaction time
             if (timeOfLastReq != 0)
                 ittReqReq.sample(curTick() - timeOfLastReq);
             timeOfLastReq = curTick();
         }

         if (!is_atomic && !disableOutstandingHists && expects_response)
             ++outstandingWriteReqs;
     }
 }

 void
 CommMonitor::MonitorStats::updateRespStats(
     const ProbePoints::PacketInfo& pkt_info, Tick latency, bool is_atomic)
 {
     if (pkt_info.cmd.isRead()) {
         // Decrement number of outstanding read requests
         if (!is_atomic && !disableOutstandingHists) {
             assert(outstandingReadReqs != 0);
             --outstandingReadReqs;
         }

         if (!disableLatencyHists)
             readLatencyHist.sample(latency);

         // Update the bandwidth stats based on responses for reads
         if (!disableBandwidthHists) {
             readBytes += pkt_info.size;
             totalReadBytes += pkt_info.size;
         }

     } else if (pkt_info.cmd.isWrite()) {
         // Decrement number of outstanding write requests
         if (!is_atomic && !disableOutstandingHists) {
             assert(outstandingWriteReqs != 0);
             --outstandingWriteReqs;
         }

         if (!disableLatencyHists)
             writeLatencyHist.sample(latency);
     }
 }

 Tick
 CommMonitor::recvAtomic(PacketPtr pkt)
 {
     const bool expects_response(pkt->needsResponse() &&
                                 !pkt->cacheResponding());
     ProbePoints::PacketInfo req_pkt_info(pkt);
     ppPktReq->notify(req_pkt_info);

     const Tick delay(masterPort.sendAtomic(pkt));

     stats.updateReqStats(req_pkt_info, true, expects_response);
     if (expects_response)
         stats.updateRespStats(req_pkt_info, delay, true);

     assert(pkt->isResponse());
     ProbePoints::PacketInfo resp_pkt_info(pkt);
     ppPktResp->notify(resp_pkt_info);
     return delay;
 }

 Tick
 CommMonitor::recvAtomicSnoop(PacketPtr pkt)
 {
     return slavePort.sendAtomicSnoop(pkt);
 }

 bool
 CommMonitor::recvTimingReq(PacketPtr pkt)
 {
     // should always see a request
     assert(pkt->isRequest());

     // Store relevant fields of packet, because packet may be modified
     // or even deleted when sendTiming() is called.
     const ProbePoints::PacketInfo pkt_info(pkt);

     const bool expects_response(pkt->needsResponse() &&
                                 !pkt->cacheResponding());

     // If a cache miss is served by a cache, a monitor near the memory
     // would see a request which needs a response, but this response
     // would not come back from the memory. Therefore we additionally
     // have to check the cacheResponding flag
     if (expects_response && !stats.disableLatencyHists) {
         pkt->pushSenderState(new CommMonitorSenderState(curTick()));
     }

     // Attempt to send the packet
     bool successful = masterPort.sendTimingReq(pkt);

     // If not successful, restore the sender state
     if (!successful && expects_response && !stats.disableLatencyHists) {
         delete pkt->popSenderState();
     }

     if (successful) {
         ppPktReq->notify(pkt_info);
     }

     if (successful) {
         DPRINTF(CommMonitor, "Forwarded %s request\n", pkt->isRead() ? "read" :
                 pkt->isWrite() ? "write" : "non read/write");
         stats.updateReqStats(pkt_info, false, expects_response);
     }
     return successful;
 }

 bool
 CommMonitor::recvTimingResp(PacketPtr pkt)
 {
     // should always see responses
     assert(pkt->isResponse());

     // Store relevant fields of packet, because packet may be modified
     // or even deleted when sendTiming() is called.
     const ProbePoints::PacketInfo pkt_info(pkt);

     Tick latency = 0;
     CommMonitorSenderState* received_state =
         dynamic_cast<CommMonitorSenderState*>(pkt->senderState);

     if (!stats.disableLatencyHists) {
         // Restore initial sender state
         if (received_state == NULL)
             panic("Monitor got a response without monitor sender state\n");

         // Restore the sate
         pkt->senderState = received_state->predecessor;
     }

     // Attempt to send the packet
     bool successful = slavePort.sendTimingResp(pkt);

     if (!stats.disableLatencyHists) {
         // If packet successfully send, sample value of latency,
         // afterwards delete sender state, otherwise restore state
         if (successful) {
             latency = curTick() - received_state->transmitTime;
             DPRINTF(CommMonitor, "Latency: %d\n", latency);
             delete received_state;
         } else {
             // Don't delete anything and let the packet look like we
             // did not touch it
             pkt->senderState = received_state;
         }
     }

     if (successful) {
         ppPktResp->notify(pkt_info);
         DPRINTF(CommMonitor, "Received %s response\n", pkt->isRead() ? "read" :
                 pkt->isWrite() ?  "write" : "non read/write");
         stats.updateRespStats(pkt_info, latency, false);
     }
     return successful;
 }

 void
 CommMonitor::recvTimingSnoopReq(PacketPtr pkt)
 {
     slavePort.sendTimingSnoopReq(pkt);
 }

 bool
 CommMonitor::recvTimingSnoopResp(PacketPtr pkt)
 {
     return masterPort.sendTimingSnoopResp(pkt);
 }

 void
 CommMonitor::recvRetrySnoopResp()
 {
     slavePort.sendRetrySnoopResp();
 }

 bool
 CommMonitor::isSnooping() const
 {
     // check if the connected master port is snooping
     return slavePort.isSnooping();
 }

 AddrRangeList
 CommMonitor::getAddrRanges() const
 {
     // get the address ranges of the connected slave port
     return masterPort.getAddrRanges();
 }

 void
 CommMonitor::recvReqRetry()
 {
     slavePort.sendRetryReq();
 }

 void
 CommMonitor::recvRespRetry()
 {
     masterPort.sendRetryResp();
 }

 bool
 CommMonitor::tryTiming(PacketPtr pkt)
 {
     return masterPort.tryTiming(pkt);
 }

 void
 CommMonitor::recvRangeChange()
 {
     slavePort.sendRangeChange();
 }

 void
 CommMonitor::regStats()
 {
     MemObject::regStats();

     // Initialise all the monitor stats
     using namespace Stats;

     stats.readBurstLengthHist
         .init(params()->burst_length_bins)
         .name(name() + ".readBurstLengthHist")
         .desc("Histogram of burst lengths of transmitted packets")
         .flags(stats.disableBurstLengthHists ? nozero : pdf);

     stats.writeBurstLengthHist
         .init(params()->burst_length_bins)
         .name(name() + ".writeBurstLengthHist")
         .desc("Histogram of burst lengths of transmitted packets")
         .flags(stats.disableBurstLengthHists ? nozero : pdf);

     // Stats based on received responses
     stats.readBandwidthHist
         .init(params()->bandwidth_bins)
         .name(name() + ".readBandwidthHist")
         .desc("Histogram of read bandwidth per sample period (bytes/s)")
         .flags(stats.disableBandwidthHists ? nozero : pdf);

     stats.averageReadBW
         .name(name() + ".averageReadBandwidth")
         .desc("Average read bandwidth (bytes/s)")
         .flags(stats.disableBandwidthHists ? nozero : pdf);

     stats.totalReadBytes
         .name(name() + ".totalReadBytes")
         .desc("Number of bytes read")
         .flags(stats.disableBandwidthHists ? nozero : pdf);

     stats.averageReadBW = stats.totalReadBytes / simSeconds;

     // Stats based on successfully sent requests
     stats.writeBandwidthHist
         .init(params()->bandwidth_bins)
         .name(name() + ".writeBandwidthHist")
         .desc("Histogram of write bandwidth (bytes/s)")
         .flags(stats.disableBandwidthHists ? (pdf | nozero) : pdf);

     stats.averageWriteBW
         .name(name() + ".averageWriteBandwidth")
         .desc("Average write bandwidth (bytes/s)")
         .flags(stats.disableBandwidthHists ? nozero : pdf);

     stats.totalWrittenBytes
         .name(name() + ".totalWrittenBytes")
         .desc("Number of bytes written")
         .flags(stats.disableBandwidthHists ? nozero : pdf);

     stats.averageWriteBW = stats.totalWrittenBytes / simSeconds;

     stats.readLatencyHist
         .init(params()->latency_bins)
         .name(name() + ".readLatencyHist")
         .desc("Read request-response latency")
         .flags(stats.disableLatencyHists ? nozero : pdf);

     stats.writeLatencyHist
         .init(params()->latency_bins)
         .name(name() + ".writeLatencyHist")
         .desc("Write request-response latency")
         .flags(stats.disableLatencyHists ? nozero : pdf);

     stats.ittReadRead
         .init(1, params()->itt_max_bin, params()->itt_max_bin /
               params()->itt_bins)
         .name(name() + ".ittReadRead")
         .desc("Read-to-read inter transaction time")
         .flags(stats.disableITTDists ? nozero : pdf);

     stats.ittWriteWrite
         .init(1, params()->itt_max_bin, params()->itt_max_bin /
               params()->itt_bins)
         .name(name() + ".ittWriteWrite")
         .desc("Write-to-write inter transaction time")
         .flags(stats.disableITTDists ? nozero : pdf);

     stats.ittReqReq
         .init(1, params()->itt_max_bin, params()->itt_max_bin /
               params()->itt_bins)
         .name(name() + ".ittReqReq")
         .desc("Request-to-request inter transaction time")
         .flags(stats.disableITTDists ? nozero : pdf);

     stats.outstandingReadsHist
         .init(params()->outstanding_bins)
         .name(name() + ".outstandingReadsHist")
         .desc("Outstanding read transactions")
         .flags(stats.disableOutstandingHists ? nozero : pdf);

     stats.outstandingWritesHist
         .init(params()->outstanding_bins)
         .name(name() + ".outstandingWritesHist")
         .desc("Outstanding write transactions")
         .flags(stats.disableOutstandingHists ? nozero : pdf);

     stats.readTransHist
         .init(params()->transaction_bins)
         .name(name() + ".readTransHist")
         .desc("Histogram of read transactions per sample period")
         .flags(stats.disableTransactionHists ? nozero : pdf);

     stats.writeTransHist
         .init(params()->transaction_bins)
         .name(name() + ".writeTransHist")
         .desc("Histogram of write transactions per sample period")
         .flags(stats.disableTransactionHists ? nozero : pdf);

     stats.readAddrDist
         .init(0)
         .name(name() + ".readAddrDist")
         .desc("Read address distribution")
         .flags(stats.disableAddrDists ? nozero : pdf);

     stats.writeAddrDist
         .init(0)
         .name(name() + ".writeAddrDist")
         .desc("Write address distribution")
         .flags(stats.disableAddrDists ? nozero : pdf);
 }

 void
 CommMonitor::samplePeriodic()
 {
     // the periodic stats update runs on the granularity of sample
     // periods, but in combination with this there may also be a
     // external resets and dumps of the stats (through schedStatEvent)
     // causing the stats themselves to capture less than a sample
     // period

     // only capture if we have not reset the stats during the last
     // sample period
     if (simTicks.value() >= samplePeriodTicks) {
         if (!stats.disableTransactionHists) {
             stats.readTransHist.sample(stats.readTrans);
             stats.writeTransHist.sample(stats.writeTrans);
         }

         if (!stats.disableBandwidthHists) {
             stats.readBandwidthHist.sample(stats.readBytes / samplePeriod);
             stats.writeBandwidthHist.sample(stats.writtenBytes / samplePeriod);
         }

         if (!stats.disableOutstandingHists) {
             stats.outstandingReadsHist.sample(stats.outstandingReadReqs);
             stats.outstandingWritesHist.sample(stats.outstandingWriteReqs);
         }
     }

     // reset the sampled values
     stats.readTrans = 0;
     stats.writeTrans = 0;

     stats.readBytes = 0;
     stats.writtenBytes = 0;

     schedule(samplePeriodicEvent, curTick() + samplePeriodTicks);
 }

 void
 CommMonitor::startup()
 {
     schedule(samplePeriodicEvent, curTick() + samplePeriodTicks);
 }
	/*
	* Copyright (c) 2012-2013, 2015, 2018 ARM Limited
	* Copyright (c) 2016 Google Inc.
	* Copyright (c) 2017, Centre National de la Recherche Scientifique
	* 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: Thomas Grass
	* Andreas Hansson
	* Rahul Thakur
	* Pierre-Yves Peneau
	*/

	#include "mem/comm_monitor.hh"

	#include "base/trace.hh"
	#include "debug/CommMonitor.hh"
	#include "sim/stats.hh"

	CommMonitor::CommMonitor(Params* params)
	: MemObject(params),
	masterPort(name() + "-master", *this),
	slavePort(name() + "-slave", *this),
	samplePeriodicEvent([this]{ samplePeriodic(); }, name()),
	samplePeriodTicks(params->sample_period),
	samplePeriod(params->sample_period / SimClock::Float::s),
	stats(params)
	{
	DPRINTF(CommMonitor,
	"Created monitor %s with sample period %d ticks (%f ms)\n",
	name(), samplePeriodTicks, samplePeriod * 1E3);
	}

	CommMonitor*
	CommMonitorParams::create()
	{
	return new CommMonitor(this);
	}

	void
	CommMonitor::init()
	{
	// make sure both sides of the monitor are connected
	if (!slavePort.isConnected() \|\| !masterPort.isConnected())
	fatal("Communication monitor is not connected on both sides.\n");
	}

	void
	CommMonitor::regProbePoints()
	{
	ppPktReq.reset(new ProbePoints::Packet(getProbeManager(), "PktRequest"));
	ppPktResp.reset(new ProbePoints::Packet(getProbeManager(), "PktResponse"));
	}

	Port &
	CommMonitor::getPort(const std::string &if_name, PortID idx)
	{
	if (if_name == "master") {
	return masterPort;
	} else if (if_name == "slave") {
	return slavePort;
	} else {
	return MemObject::getPort(if_name, idx);
	}
	}

	void
	CommMonitor::recvFunctional(PacketPtr pkt)
	{
	masterPort.sendFunctional(pkt);
	}

	void
	CommMonitor::recvFunctionalSnoop(PacketPtr pkt)
	{
	slavePort.sendFunctionalSnoop(pkt);
	}

	void
	CommMonitor::MonitorStats::updateReqStats(
	const ProbePoints::PacketInfo& pkt_info, bool is_atomic,
	bool expects_response)
	{
	if (pkt_info.cmd.isRead()) {
	// Increment number of observed read transactions
	if (!disableTransactionHists)
	++readTrans;

	// Get sample of burst length
	if (!disableBurstLengthHists)
	readBurstLengthHist.sample(pkt_info.size);

	// Sample the masked address
	if (!disableAddrDists)
	readAddrDist.sample(pkt_info.addr & readAddrMask);

	if (!disableITTDists) {
	// Sample value of read-read inter transaction time
	if (timeOfLastRead != 0)
	ittReadRead.sample(curTick() - timeOfLastRead);
	timeOfLastRead = curTick();

	// Sample value of req-req inter transaction time
	if (timeOfLastReq != 0)
	ittReqReq.sample(curTick() - timeOfLastReq);
	timeOfLastReq = curTick();
	}
	if (!is_atomic && !disableOutstandingHists && expects_response)
	++outstandingReadReqs;

	} else if (pkt_info.cmd.isWrite()) {
	// Same as for reads
	if (!disableTransactionHists)
	++writeTrans;

	if (!disableBurstLengthHists)
	writeBurstLengthHist.sample(pkt_info.size);

	// Update the bandwidth stats on the request
	if (!disableBandwidthHists) {
	writtenBytes += pkt_info.size;
	totalWrittenBytes += pkt_info.size;
	}

	// Sample the masked write address
	if (!disableAddrDists)
	writeAddrDist.sample(pkt_info.addr & writeAddrMask);

	if (!disableITTDists) {
	// Sample value of write-to-write inter transaction time
	if (timeOfLastWrite != 0)
	ittWriteWrite.sample(curTick() - timeOfLastWrite);
	timeOfLastWrite = curTick();

	// Sample value of req-to-req inter transaction time
	if (timeOfLastReq != 0)
	ittReqReq.sample(curTick() - timeOfLastReq);
	timeOfLastReq = curTick();
	}

	if (!is_atomic && !disableOutstandingHists && expects_response)
	++outstandingWriteReqs;
	}
	}

	void
	CommMonitor::MonitorStats::updateRespStats(
	const ProbePoints::PacketInfo& pkt_info, Tick latency, bool is_atomic)
	{
	if (pkt_info.cmd.isRead()) {
	// Decrement number of outstanding read requests
	if (!is_atomic && !disableOutstandingHists) {
	assert(outstandingReadReqs != 0);
	--outstandingReadReqs;
	}

	if (!disableLatencyHists)
	readLatencyHist.sample(latency);

	// Update the bandwidth stats based on responses for reads
	if (!disableBandwidthHists) {
	readBytes += pkt_info.size;
	totalReadBytes += pkt_info.size;
	}

	} else if (pkt_info.cmd.isWrite()) {
	// Decrement number of outstanding write requests
	if (!is_atomic && !disableOutstandingHists) {
	assert(outstandingWriteReqs != 0);
	--outstandingWriteReqs;
	}

	if (!disableLatencyHists)
	writeLatencyHist.sample(latency);
	}
	}

	Tick
	CommMonitor::recvAtomic(PacketPtr pkt)
	{
	const bool expects_response(pkt->needsResponse() &&
	!pkt->cacheResponding());
	ProbePoints::PacketInfo req_pkt_info(pkt);
	ppPktReq->notify(req_pkt_info);

	const Tick delay(masterPort.sendAtomic(pkt));

	stats.updateReqStats(req_pkt_info, true, expects_response);
	if (expects_response)
	stats.updateRespStats(req_pkt_info, delay, true);

	assert(pkt->isResponse());
	ProbePoints::PacketInfo resp_pkt_info(pkt);
	ppPktResp->notify(resp_pkt_info);
	return delay;
	}

	Tick
	CommMonitor::recvAtomicSnoop(PacketPtr pkt)
	{
	return slavePort.sendAtomicSnoop(pkt);
	}

	bool
	CommMonitor::recvTimingReq(PacketPtr pkt)
	{
	// should always see a request
	assert(pkt->isRequest());

	// Store relevant fields of packet, because packet may be modified
	// or even deleted when sendTiming() is called.
	const ProbePoints::PacketInfo pkt_info(pkt);

	const bool expects_response(pkt->needsResponse() &&
	!pkt->cacheResponding());

	// If a cache miss is served by a cache, a monitor near the memory
	// would see a request which needs a response, but this response
	// would not come back from the memory. Therefore we additionally
	// have to check the cacheResponding flag
	if (expects_response && !stats.disableLatencyHists) {
	pkt->pushSenderState(new CommMonitorSenderState(curTick()));
	}

	// Attempt to send the packet
	bool successful = masterPort.sendTimingReq(pkt);

	// If not successful, restore the sender state
	if (!successful && expects_response && !stats.disableLatencyHists) {
	delete pkt->popSenderState();
	}

	if (successful) {
	ppPktReq->notify(pkt_info);
	}

	if (successful) {
	DPRINTF(CommMonitor, "Forwarded %s request\n", pkt->isRead() ? "read" :
	pkt->isWrite() ? "write" : "non read/write");
	stats.updateReqStats(pkt_info, false, expects_response);
	}
	return successful;
	}

	bool
	CommMonitor::recvTimingResp(PacketPtr pkt)
	{
	// should always see responses
	assert(pkt->isResponse());

	// Store relevant fields of packet, because packet may be modified
	// or even deleted when sendTiming() is called.
	const ProbePoints::PacketInfo pkt_info(pkt);

	Tick latency = 0;
	CommMonitorSenderState* received_state =
	dynamic_cast<CommMonitorSenderState*>(pkt->senderState);

	if (!stats.disableLatencyHists) {
	// Restore initial sender state
	if (received_state == NULL)
	panic("Monitor got a response without monitor sender state\n");

	// Restore the sate
	pkt->senderState = received_state->predecessor;
	}

	// Attempt to send the packet
	bool successful = slavePort.sendTimingResp(pkt);

	if (!stats.disableLatencyHists) {
	// If packet successfully send, sample value of latency,
	// afterwards delete sender state, otherwise restore state
	if (successful) {
	latency = curTick() - received_state->transmitTime;
	DPRINTF(CommMonitor, "Latency: %d\n", latency);
	delete received_state;
	} else {
	// Don't delete anything and let the packet look like we
	// did not touch it
	pkt->senderState = received_state;
	}
	}

	if (successful) {
	ppPktResp->notify(pkt_info);
	DPRINTF(CommMonitor, "Received %s response\n", pkt->isRead() ? "read" :
	pkt->isWrite() ? "write" : "non read/write");
	stats.updateRespStats(pkt_info, latency, false);
	}
	return successful;
	}

	void
	CommMonitor::recvTimingSnoopReq(PacketPtr pkt)
	{
	slavePort.sendTimingSnoopReq(pkt);
	}

	bool
	CommMonitor::recvTimingSnoopResp(PacketPtr pkt)
	{
	return masterPort.sendTimingSnoopResp(pkt);
	}

	void
	CommMonitor::recvRetrySnoopResp()
	{
	slavePort.sendRetrySnoopResp();
	}

	bool
	CommMonitor::isSnooping() const
	{
	// check if the connected master port is snooping
	return slavePort.isSnooping();
	}

	AddrRangeList
	CommMonitor::getAddrRanges() const
	{
	// get the address ranges of the connected slave port
	return masterPort.getAddrRanges();
	}

	void
	CommMonitor::recvReqRetry()
	{
	slavePort.sendRetryReq();
	}

	void
	CommMonitor::recvRespRetry()
	{
	masterPort.sendRetryResp();
	}

	bool
	CommMonitor::tryTiming(PacketPtr pkt)
	{
	return masterPort.tryTiming(pkt);
	}

	void
	CommMonitor::recvRangeChange()
	{
	slavePort.sendRangeChange();
	}

	void
	CommMonitor::regStats()
	{
	MemObject::regStats();

	// Initialise all the monitor stats
	using namespace Stats;

	stats.readBurstLengthHist
	.init(params()->burst_length_bins)
	.name(name() + ".readBurstLengthHist")
	.desc("Histogram of burst lengths of transmitted packets")
	.flags(stats.disableBurstLengthHists ? nozero : pdf);

	stats.writeBurstLengthHist
	.init(params()->burst_length_bins)
	.name(name() + ".writeBurstLengthHist")
	.desc("Histogram of burst lengths of transmitted packets")
	.flags(stats.disableBurstLengthHists ? nozero : pdf);

	// Stats based on received responses
	stats.readBandwidthHist
	.init(params()->bandwidth_bins)
	.name(name() + ".readBandwidthHist")
	.desc("Histogram of read bandwidth per sample period (bytes/s)")
	.flags(stats.disableBandwidthHists ? nozero : pdf);

	stats.averageReadBW
	.name(name() + ".averageReadBandwidth")
	.desc("Average read bandwidth (bytes/s)")
	.flags(stats.disableBandwidthHists ? nozero : pdf);

	stats.totalReadBytes
	.name(name() + ".totalReadBytes")
	.desc("Number of bytes read")
	.flags(stats.disableBandwidthHists ? nozero : pdf);

	stats.averageReadBW = stats.totalReadBytes / simSeconds;

	// Stats based on successfully sent requests
	stats.writeBandwidthHist
	.init(params()->bandwidth_bins)
	.name(name() + ".writeBandwidthHist")
	.desc("Histogram of write bandwidth (bytes/s)")
	.flags(stats.disableBandwidthHists ? (pdf \| nozero) : pdf);

	stats.averageWriteBW
	.name(name() + ".averageWriteBandwidth")
	.desc("Average write bandwidth (bytes/s)")
	.flags(stats.disableBandwidthHists ? nozero : pdf);

	stats.totalWrittenBytes
	.name(name() + ".totalWrittenBytes")
	.desc("Number of bytes written")
	.flags(stats.disableBandwidthHists ? nozero : pdf);

	stats.averageWriteBW = stats.totalWrittenBytes / simSeconds;

	stats.readLatencyHist
	.init(params()->latency_bins)
	.name(name() + ".readLatencyHist")
	.desc("Read request-response latency")
	.flags(stats.disableLatencyHists ? nozero : pdf);

	stats.writeLatencyHist
	.init(params()->latency_bins)
	.name(name() + ".writeLatencyHist")
	.desc("Write request-response latency")
	.flags(stats.disableLatencyHists ? nozero : pdf);

	stats.ittReadRead
	.init(1, params()->itt_max_bin, params()->itt_max_bin /
	params()->itt_bins)
	.name(name() + ".ittReadRead")
	.desc("Read-to-read inter transaction time")
	.flags(stats.disableITTDists ? nozero : pdf);

	stats.ittWriteWrite
	.init(1, params()->itt_max_bin, params()->itt_max_bin /
	params()->itt_bins)
	.name(name() + ".ittWriteWrite")
	.desc("Write-to-write inter transaction time")
	.flags(stats.disableITTDists ? nozero : pdf);

	stats.ittReqReq
	.init(1, params()->itt_max_bin, params()->itt_max_bin /
	params()->itt_bins)
	.name(name() + ".ittReqReq")
	.desc("Request-to-request inter transaction time")
	.flags(stats.disableITTDists ? nozero : pdf);

	stats.outstandingReadsHist
	.init(params()->outstanding_bins)
	.name(name() + ".outstandingReadsHist")
	.desc("Outstanding read transactions")
	.flags(stats.disableOutstandingHists ? nozero : pdf);

	stats.outstandingWritesHist
	.init(params()->outstanding_bins)
	.name(name() + ".outstandingWritesHist")
	.desc("Outstanding write transactions")
	.flags(stats.disableOutstandingHists ? nozero : pdf);

	stats.readTransHist
	.init(params()->transaction_bins)
	.name(name() + ".readTransHist")
	.desc("Histogram of read transactions per sample period")
	.flags(stats.disableTransactionHists ? nozero : pdf);

	stats.writeTransHist
	.init(params()->transaction_bins)
	.name(name() + ".writeTransHist")
	.desc("Histogram of write transactions per sample period")
	.flags(stats.disableTransactionHists ? nozero : pdf);

	stats.readAddrDist
	.init(0)
	.name(name() + ".readAddrDist")
	.desc("Read address distribution")
	.flags(stats.disableAddrDists ? nozero : pdf);

	stats.writeAddrDist
	.init(0)
	.name(name() + ".writeAddrDist")
	.desc("Write address distribution")
	.flags(stats.disableAddrDists ? nozero : pdf);
	}

	void
	CommMonitor::samplePeriodic()
	{
	// the periodic stats update runs on the granularity of sample
	// periods, but in combination with this there may also be a
	// external resets and dumps of the stats (through schedStatEvent)
	// causing the stats themselves to capture less than a sample
	// period

	// only capture if we have not reset the stats during the last
	// sample period
	if (simTicks.value() >= samplePeriodTicks) {
	if (!stats.disableTransactionHists) {
	stats.readTransHist.sample(stats.readTrans);
	stats.writeTransHist.sample(stats.writeTrans);
	}

	if (!stats.disableBandwidthHists) {
	stats.readBandwidthHist.sample(stats.readBytes / samplePeriod);
	stats.writeBandwidthHist.sample(stats.writtenBytes / samplePeriod);
	}

	if (!stats.disableOutstandingHists) {
	stats.outstandingReadsHist.sample(stats.outstandingReadReqs);
	stats.outstandingWritesHist.sample(stats.outstandingWriteReqs);
	}
	}

	// reset the sampled values
	stats.readTrans = 0;
	stats.writeTrans = 0;

	stats.readBytes = 0;
	stats.writtenBytes = 0;

	schedule(samplePeriodicEvent, curTick() + samplePeriodTicks);
	}

	void
	CommMonitor::startup()
	{
	schedule(samplePeriodicEvent, curTick() + samplePeriodTicks);
	}