src/mem/hbm_ctrl.cc - public/gem5 - Git at Google

 /*
  * Copyright (c) 2022 The Regents of the University of California
  * 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.
  */

 #include "mem/hbm_ctrl.hh"

 #include "base/trace.hh"
 #include "debug/DRAM.hh"
 #include "debug/Drain.hh"
 #include "debug/MemCtrl.hh"
 #include "debug/QOS.hh"
 #include "mem/dram_interface.hh"
 #include "mem/mem_interface.hh"
 #include "sim/system.hh"

 namespace gem5
 {

 namespace memory
 {

 HBMCtrl::HBMCtrl(const HBMCtrlParams &p) :
     MemCtrl(p),
     retryRdReqPC1(false), retryWrReqPC1(false),
     nextReqEventPC1([this] {processNextReqEvent(pc1Int, respQueuePC1,
                          respondEventPC1, nextReqEventPC1, retryWrReqPC1);},
                          name()),
     respondEventPC1([this] {processRespondEvent(pc1Int, respQueuePC1,
                          respondEventPC1, retryRdReqPC1); }, name()),
     pc1Int(p.dram_2),
     partitionedQ(p.partitioned_q)
 {
     DPRINTF(MemCtrl, "Setting up HBM controller\n");

     pc0Int = dynamic_cast<DRAMInterface*>(dram);

     assert(dynamic_cast<DRAMInterface*>(p.dram_2) != nullptr);

     readBufferSize = pc0Int->readBufferSize + pc1Int->readBufferSize;
     writeBufferSize = pc0Int->writeBufferSize + pc1Int->writeBufferSize;

     fatal_if(!pc0Int, "Memory controller must have pc0 interface");
     fatal_if(!pc1Int, "Memory controller must have pc1 interface");

     pc0Int->setCtrl(this, commandWindow, 0);
     pc1Int->setCtrl(this, commandWindow, 1);

     if (partitionedQ) {
         writeHighThreshold = (writeBufferSize * (p.write_high_thresh_perc/2)
                              / 100.0);
         writeLowThreshold = (writeBufferSize * (p.write_low_thresh_perc/2)
                             / 100.0);
     } else {
         writeHighThreshold = (writeBufferSize * p.write_high_thresh_perc
                             / 100.0);
         writeLowThreshold = (writeBufferSize * p.write_low_thresh_perc
                             / 100.0);
     }
 }

 void
 HBMCtrl::init()
 {
     MemCtrl::init();
 }

 void
 HBMCtrl::startup()
 {
     MemCtrl::startup();

     isTimingMode = system()->isTimingMode();
     if (isTimingMode) {
         // shift the bus busy time sufficiently far ahead that we never
         // have to worry about negative values when computing the time for
         // the next request, this will add an insignificant bubble at the
         // start of simulation
         pc1Int->nextBurstAt = curTick() + pc1Int->commandOffset();
     }
 }

 Tick
 HBMCtrl::recvAtomic(PacketPtr pkt)
 {
     Tick latency = 0;

     if (pc0Int->getAddrRange().contains(pkt->getAddr())) {
         latency = MemCtrl::recvAtomicLogic(pkt, pc0Int);
     } else if (pc1Int->getAddrRange().contains(pkt->getAddr())) {
         latency = MemCtrl::recvAtomicLogic(pkt, pc1Int);
     } else {
         panic("Can't handle address range for packet %s\n", pkt->print());
     }

     return latency;
 }

 void
 HBMCtrl::recvFunctional(PacketPtr pkt)
 {
     bool found = MemCtrl::recvFunctionalLogic(pkt, pc0Int);

     if (!found) {
         found = MemCtrl::recvFunctionalLogic(pkt, pc1Int);
     }

     if (!found) {
         panic("Can't handle address range for packet %s\n", pkt->print());
     }
 }

 Tick
 HBMCtrl::recvAtomicBackdoor(PacketPtr pkt, MemBackdoorPtr &backdoor)
 {
     Tick latency = recvAtomic(pkt);

     if (pc0Int && pc0Int->getAddrRange().contains(pkt->getAddr())) {
         pc0Int->getBackdoor(backdoor);
     } else if (pc1Int && pc1Int->getAddrRange().contains(pkt->getAddr())) {
         pc1Int->getBackdoor(backdoor);
     }
     else {
         panic("Can't handle address range for packet %s\n",
               pkt->print());
     }
     return latency;
 }

 bool
 HBMCtrl::writeQueueFullPC0(unsigned int neededEntries) const
 {
     DPRINTF(MemCtrl,
             "Write queue limit %d, PC0 size %d, entries needed %d\n",
             writeBufferSize, writeQueueSizePC0, neededEntries);

     unsigned int wrsize_new = (writeQueueSizePC0 + neededEntries);
     return wrsize_new > (writeBufferSize/2);
 }

 bool
 HBMCtrl::writeQueueFullPC1(unsigned int neededEntries) const
 {
     DPRINTF(MemCtrl,
             "Write queue limit %d, PC1 size %d, entries needed %d\n",
             writeBufferSize, writeQueueSizePC1, neededEntries);

     unsigned int wrsize_new = (writeQueueSizePC1 + neededEntries);
     return wrsize_new > (writeBufferSize/2);
 }

 bool
 HBMCtrl::readQueueFullPC0(unsigned int neededEntries) const
 {
     DPRINTF(MemCtrl,
             "Read queue limit %d, PC0 size %d, entries needed %d\n",
             readBufferSize, readQueueSizePC0 + respQueue.size(),
             neededEntries);

     unsigned int rdsize_new = readQueueSizePC0 + respQueue.size()
                                                + neededEntries;
     return rdsize_new > (readBufferSize/2);
 }

 bool
 HBMCtrl::readQueueFullPC1(unsigned int neededEntries) const
 {
     DPRINTF(MemCtrl,
             "Read queue limit %d, PC1 size %d, entries needed %d\n",
             readBufferSize, readQueueSizePC1 + respQueuePC1.size(),
             neededEntries);

     unsigned int rdsize_new = readQueueSizePC1 + respQueuePC1.size()
                                                + neededEntries;
     return rdsize_new > (readBufferSize/2);
 }

 bool
 HBMCtrl::readQueueFull(unsigned int neededEntries) const
 {
     DPRINTF(MemCtrl,
             "HBMCtrl: Read queue limit %d, entries needed %d\n",
             readBufferSize, neededEntries);

     unsigned int rdsize_new = totalReadQueueSize + respQueue.size() +
                                 respQueuePC1.size() + neededEntries;
     return rdsize_new > readBufferSize;
 }

 bool
 HBMCtrl::recvTimingReq(PacketPtr pkt)
 {
     // This is where we enter from the outside world
     DPRINTF(MemCtrl, "recvTimingReq: request %s addr %#x size %d\n",
             pkt->cmdString(), pkt->getAddr(), pkt->getSize());

     panic_if(pkt->cacheResponding(), "Should not see packets where cache "
                                         "is responding");

     panic_if(!(pkt->isRead() || pkt->isWrite()),
                 "Should only see read and writes at memory controller\n");

     // Calc avg gap between requests
     if (prevArrival != 0) {
         stats.totGap += curTick() - prevArrival;
     }
     prevArrival = curTick();

     // What type of media does this packet access?
     bool is_pc0;

     // TODO: make the interleaving bit across pseudo channels a parameter
     if (bits(pkt->getAddr(), 6) == 0) {
         is_pc0 = true;
     } else {
         is_pc0 = false;
     }

     // Find out how many memory packets a pkt translates to
     // If the burst size is equal or larger than the pkt size, then a pkt
     // translates to only one memory packet. Otherwise, a pkt translates to
     // multiple memory packets
     unsigned size = pkt->getSize();
     uint32_t burst_size = pc0Int->bytesPerBurst();
     unsigned offset = pkt->getAddr() & (burst_size - 1);
     unsigned int pkt_count = divCeil(offset + size, burst_size);

     // run the QoS scheduler and assign a QoS priority value to the packet
     qosSchedule({&readQueue, &writeQueue}, burst_size, pkt);

     // check local buffers and do not accept if full
     if (pkt->isWrite()) {
         if (is_pc0) {
             if (partitionedQ ? writeQueueFullPC0(pkt_count) :
                                         writeQueueFull(pkt_count))
             {
                 DPRINTF(MemCtrl, "Write queue full, not accepting\n");
                 // remember that we have to retry this port
                 MemCtrl::retryWrReq = true;
                 stats.numWrRetry++;
                 return false;
             } else {
                 addToWriteQueue(pkt, pkt_count, pc0Int);
                 stats.writeReqs++;
                 stats.bytesWrittenSys += size;
             }
         } else {
             if (partitionedQ ? writeQueueFullPC1(pkt_count) :
                                         writeQueueFull(pkt_count))
             {
                 DPRINTF(MemCtrl, "Write queue full, not accepting\n");
                 // remember that we have to retry this port
                 retryWrReqPC1 = true;
                 stats.numWrRetry++;
                 return false;
             } else {
                 addToWriteQueue(pkt, pkt_count, pc1Int);
                 stats.writeReqs++;
                 stats.bytesWrittenSys += size;
             }
         }
     } else {

         assert(pkt->isRead());
         assert(size != 0);

         if (is_pc0) {
             if (partitionedQ ? readQueueFullPC0(pkt_count) :
                                         HBMCtrl::readQueueFull(pkt_count)) {
                 DPRINTF(MemCtrl, "Read queue full, not accepting\n");
                 // remember that we have to retry this port
                 retryRdReqPC1 = true;
                 stats.numRdRetry++;
                 return false;
             } else {
                 if (!addToReadQueue(pkt, pkt_count, pc0Int)) {
                     if (!nextReqEvent.scheduled()) {
                         DPRINTF(MemCtrl, "Request scheduled immediately\n");
                         schedule(nextReqEvent, curTick());
                     }
                 }

                 stats.readReqs++;
                 stats.bytesReadSys += size;
             }
         } else {
             if (partitionedQ ? readQueueFullPC1(pkt_count) :
                                         HBMCtrl::readQueueFull(pkt_count)) {
                 DPRINTF(MemCtrl, "Read queue full, not accepting\n");
                 // remember that we have to retry this port
                 retryRdReqPC1 = true;
                 stats.numRdRetry++;
                 return false;
             } else {
                 if (!addToReadQueue(pkt, pkt_count, pc1Int)) {
                     if (!nextReqEventPC1.scheduled()) {
                         DPRINTF(MemCtrl, "Request scheduled immediately\n");
                         schedule(nextReqEventPC1, curTick());
                     }
                 }
                 stats.readReqs++;
                 stats.bytesReadSys += size;
             }
         }
     }

     return true;
 }

 void
 HBMCtrl::pruneRowBurstTick()
 {
     auto it = rowBurstTicks.begin();
     while (it != rowBurstTicks.end()) {
         auto current_it = it++;
         if (MemCtrl::getBurstWindow(curTick()) > *current_it) {
             DPRINTF(MemCtrl, "Removing burstTick for %d\n", *current_it);
             rowBurstTicks.erase(current_it);
         }
     }
 }

 void
 HBMCtrl::pruneColBurstTick()
 {
     auto it = colBurstTicks.begin();
     while (it != colBurstTicks.end()) {
         auto current_it = it++;
         if (MemCtrl::getBurstWindow(curTick()) > *current_it) {
             DPRINTF(MemCtrl, "Removing burstTick for %d\n", *current_it);
             colBurstTicks.erase(current_it);
         }
     }
 }

 void
 HBMCtrl::pruneBurstTick()
 {
     pruneRowBurstTick();
     pruneColBurstTick();
 }

 Tick
 HBMCtrl::verifySingleCmd(Tick cmd_tick, Tick max_cmds_per_burst, bool row_cmd)
 {
     // start with assumption that there is no contention on command bus
     Tick cmd_at = cmd_tick;

     // get tick aligned to burst window
     Tick burst_tick = MemCtrl::getBurstWindow(cmd_tick);

     // verify that we have command bandwidth to issue the command
     // if not, iterate over next window(s) until slot found

     if (row_cmd) {
         while (rowBurstTicks.count(burst_tick) >= max_cmds_per_burst) {
             DPRINTF(MemCtrl, "Contention found on row command bus at %d\n",
                     burst_tick);
             burst_tick += commandWindow;
             cmd_at = burst_tick;
         }
         DPRINTF(MemCtrl, "Now can send a row cmd_at %d\n",
                     cmd_at);
         rowBurstTicks.insert(burst_tick);

     } else {
         while (colBurstTicks.count(burst_tick) >= max_cmds_per_burst) {
             DPRINTF(MemCtrl, "Contention found on col command bus at %d\n",
                     burst_tick);
             burst_tick += commandWindow;
             cmd_at = burst_tick;
         }
         DPRINTF(MemCtrl, "Now can send a col cmd_at %d\n",
                     cmd_at);
         colBurstTicks.insert(burst_tick);
     }
     return cmd_at;
 }

 Tick
 HBMCtrl::verifyMultiCmd(Tick cmd_tick, Tick max_cmds_per_burst,
                         Tick max_multi_cmd_split)
 {

     // start with assumption that there is no contention on command bus
     Tick cmd_at = cmd_tick;

     // get tick aligned to burst window
     Tick burst_tick = MemCtrl::getBurstWindow(cmd_tick);

     // Command timing requirements are from 2nd command
     // Start with assumption that 2nd command will issue at cmd_at and
     // find prior slot for 1st command to issue
     // Given a maximum latency of max_multi_cmd_split between the commands,
     // find the burst at the maximum latency prior to cmd_at
     Tick burst_offset = 0;
     Tick first_cmd_offset = cmd_tick % commandWindow;
     while (max_multi_cmd_split > (first_cmd_offset + burst_offset)) {
         burst_offset += commandWindow;
     }
     // get the earliest burst aligned address for first command
     // ensure that the time does not go negative
     Tick first_cmd_tick = burst_tick - std::min(burst_offset, burst_tick);

     // Can required commands issue?
     bool first_can_issue = false;
     bool second_can_issue = false;
     // verify that we have command bandwidth to issue the command(s)
     while (!first_can_issue || !second_can_issue) {
         bool same_burst = (burst_tick == first_cmd_tick);
         auto first_cmd_count = rowBurstTicks.count(first_cmd_tick);
         auto second_cmd_count = same_burst ?
                         first_cmd_count + 1 : rowBurstTicks.count(burst_tick);

         first_can_issue = first_cmd_count < max_cmds_per_burst;
         second_can_issue = second_cmd_count < max_cmds_per_burst;

         if (!second_can_issue) {
             DPRINTF(MemCtrl, "Contention (cmd2) found on command bus at %d\n",
                     burst_tick);
             burst_tick += commandWindow;
             cmd_at = burst_tick;
         }

         // Verify max_multi_cmd_split isn't violated when command 2 is shifted
         // If commands initially were issued in same burst, they are
         // now in consecutive bursts and can still issue B2B
         bool gap_violated = !same_burst &&
                         ((burst_tick - first_cmd_tick) > max_multi_cmd_split);

         if (!first_can_issue || (!second_can_issue && gap_violated)) {
             DPRINTF(MemCtrl, "Contention (cmd1) found on command bus at %d\n",
                     first_cmd_tick);
             first_cmd_tick += commandWindow;
         }
     }

     // Add command to burstTicks
     rowBurstTicks.insert(burst_tick);
     rowBurstTicks.insert(first_cmd_tick);

     return cmd_at;
 }

 void
 HBMCtrl::drainResume()
 {

     MemCtrl::drainResume();

     if (!isTimingMode && system()->isTimingMode()) {
         // if we switched to timing mode, kick things into action,
         // and behave as if we restored from a checkpoint
         startup();
         pc1Int->startup();
     } else if (isTimingMode && !system()->isTimingMode()) {
         // if we switch from timing mode, stop the refresh events to
         // not cause issues with KVM
         if (pc1Int) {
             pc1Int->drainRanks();
         }
     }

     // update the mode
     isTimingMode = system()->isTimingMode();
 }

 AddrRangeList
 HBMCtrl::getAddrRanges()
 {
     AddrRangeList ranges;
     ranges.push_back(pc0Int->getAddrRange());
     ranges.push_back(pc1Int->getAddrRange());
     return ranges;
 }

 } // namespace memory
 } // namespace gem5
	/*
	* Copyright (c) 2022 The Regents of the University of California
	* 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.
	*/

	#include "mem/hbm_ctrl.hh"

	#include "base/trace.hh"
	#include "debug/DRAM.hh"
	#include "debug/Drain.hh"
	#include "debug/MemCtrl.hh"
	#include "debug/QOS.hh"
	#include "mem/dram_interface.hh"
	#include "mem/mem_interface.hh"
	#include "sim/system.hh"

	namespace gem5
	{

	namespace memory
	{

	HBMCtrl::HBMCtrl(const HBMCtrlParams &p) :
	MemCtrl(p),
	retryRdReqPC1(false), retryWrReqPC1(false),
	nextReqEventPC1([this] {processNextReqEvent(pc1Int, respQueuePC1,
	respondEventPC1, nextReqEventPC1, retryWrReqPC1);},
	name()),
	respondEventPC1([this] {processRespondEvent(pc1Int, respQueuePC1,
	respondEventPC1, retryRdReqPC1); }, name()),
	pc1Int(p.dram_2),
	partitionedQ(p.partitioned_q)
	{
	DPRINTF(MemCtrl, "Setting up HBM controller\n");

	pc0Int = dynamic_cast<DRAMInterface*>(dram);

	assert(dynamic_cast<DRAMInterface*>(p.dram_2) != nullptr);

	readBufferSize = pc0Int->readBufferSize + pc1Int->readBufferSize;
	writeBufferSize = pc0Int->writeBufferSize + pc1Int->writeBufferSize;

	fatal_if(!pc0Int, "Memory controller must have pc0 interface");
	fatal_if(!pc1Int, "Memory controller must have pc1 interface");

	pc0Int->setCtrl(this, commandWindow, 0);
	pc1Int->setCtrl(this, commandWindow, 1);

	if (partitionedQ) {
	writeHighThreshold = (writeBufferSize * (p.write_high_thresh_perc/2)
	/ 100.0);
	writeLowThreshold = (writeBufferSize * (p.write_low_thresh_perc/2)
	/ 100.0);
	} else {
	writeHighThreshold = (writeBufferSize * p.write_high_thresh_perc
	/ 100.0);
	writeLowThreshold = (writeBufferSize * p.write_low_thresh_perc
	/ 100.0);
	}
	}

	void
	HBMCtrl::init()
	{
	MemCtrl::init();
	}

	void
	HBMCtrl::startup()
	{
	MemCtrl::startup();

	isTimingMode = system()->isTimingMode();
	if (isTimingMode) {
	// shift the bus busy time sufficiently far ahead that we never
	// have to worry about negative values when computing the time for
	// the next request, this will add an insignificant bubble at the
	// start of simulation
	pc1Int->nextBurstAt = curTick() + pc1Int->commandOffset();
	}
	}

	Tick
	HBMCtrl::recvAtomic(PacketPtr pkt)
	{
	Tick latency = 0;

	if (pc0Int->getAddrRange().contains(pkt->getAddr())) {
	latency = MemCtrl::recvAtomicLogic(pkt, pc0Int);
	} else if (pc1Int->getAddrRange().contains(pkt->getAddr())) {
	latency = MemCtrl::recvAtomicLogic(pkt, pc1Int);
	} else {
	panic("Can't handle address range for packet %s\n", pkt->print());
	}

	return latency;
	}

	void
	HBMCtrl::recvFunctional(PacketPtr pkt)
	{
	bool found = MemCtrl::recvFunctionalLogic(pkt, pc0Int);

	if (!found) {
	found = MemCtrl::recvFunctionalLogic(pkt, pc1Int);
	}

	if (!found) {
	panic("Can't handle address range for packet %s\n", pkt->print());
	}
	}

	Tick
	HBMCtrl::recvAtomicBackdoor(PacketPtr pkt, MemBackdoorPtr &backdoor)
	{
	Tick latency = recvAtomic(pkt);

	if (pc0Int && pc0Int->getAddrRange().contains(pkt->getAddr())) {
	pc0Int->getBackdoor(backdoor);
	} else if (pc1Int && pc1Int->getAddrRange().contains(pkt->getAddr())) {
	pc1Int->getBackdoor(backdoor);
	}
	else {
	panic("Can't handle address range for packet %s\n",
	pkt->print());
	}
	return latency;
	}

	bool
	HBMCtrl::writeQueueFullPC0(unsigned int neededEntries) const
	{
	DPRINTF(MemCtrl,
	"Write queue limit %d, PC0 size %d, entries needed %d\n",
	writeBufferSize, writeQueueSizePC0, neededEntries);

	unsigned int wrsize_new = (writeQueueSizePC0 + neededEntries);
	return wrsize_new > (writeBufferSize/2);
	}

	bool
	HBMCtrl::writeQueueFullPC1(unsigned int neededEntries) const
	{
	DPRINTF(MemCtrl,
	"Write queue limit %d, PC1 size %d, entries needed %d\n",
	writeBufferSize, writeQueueSizePC1, neededEntries);

	unsigned int wrsize_new = (writeQueueSizePC1 + neededEntries);
	return wrsize_new > (writeBufferSize/2);
	}

	bool
	HBMCtrl::readQueueFullPC0(unsigned int neededEntries) const
	{
	DPRINTF(MemCtrl,
	"Read queue limit %d, PC0 size %d, entries needed %d\n",
	readBufferSize, readQueueSizePC0 + respQueue.size(),
	neededEntries);

	unsigned int rdsize_new = readQueueSizePC0 + respQueue.size()
	+ neededEntries;
	return rdsize_new > (readBufferSize/2);
	}

	bool
	HBMCtrl::readQueueFullPC1(unsigned int neededEntries) const
	{
	DPRINTF(MemCtrl,
	"Read queue limit %d, PC1 size %d, entries needed %d\n",
	readBufferSize, readQueueSizePC1 + respQueuePC1.size(),
	neededEntries);

	unsigned int rdsize_new = readQueueSizePC1 + respQueuePC1.size()
	+ neededEntries;
	return rdsize_new > (readBufferSize/2);
	}

	bool
	HBMCtrl::readQueueFull(unsigned int neededEntries) const
	{
	DPRINTF(MemCtrl,
	"HBMCtrl: Read queue limit %d, entries needed %d\n",
	readBufferSize, neededEntries);

	unsigned int rdsize_new = totalReadQueueSize + respQueue.size() +
	respQueuePC1.size() + neededEntries;
	return rdsize_new > readBufferSize;
	}

	bool
	HBMCtrl::recvTimingReq(PacketPtr pkt)
	{
	// This is where we enter from the outside world
	DPRINTF(MemCtrl, "recvTimingReq: request %s addr %#x size %d\n",
	pkt->cmdString(), pkt->getAddr(), pkt->getSize());

	panic_if(pkt->cacheResponding(), "Should not see packets where cache "
	"is responding");

	panic_if(!(pkt->isRead() \|\| pkt->isWrite()),
	"Should only see read and writes at memory controller\n");

	// Calc avg gap between requests
	if (prevArrival != 0) {
	stats.totGap += curTick() - prevArrival;
	}
	prevArrival = curTick();

	// What type of media does this packet access?
	bool is_pc0;

	// TODO: make the interleaving bit across pseudo channels a parameter
	if (bits(pkt->getAddr(), 6) == 0) {
	is_pc0 = true;
	} else {
	is_pc0 = false;
	}

	// Find out how many memory packets a pkt translates to
	// If the burst size is equal or larger than the pkt size, then a pkt
	// translates to only one memory packet. Otherwise, a pkt translates to
	// multiple memory packets
	unsigned size = pkt->getSize();
	uint32_t burst_size = pc0Int->bytesPerBurst();
	unsigned offset = pkt->getAddr() & (burst_size - 1);
	unsigned int pkt_count = divCeil(offset + size, burst_size);

	// run the QoS scheduler and assign a QoS priority value to the packet
	qosSchedule({&readQueue, &writeQueue}, burst_size, pkt);

	// check local buffers and do not accept if full
	if (pkt->isWrite()) {
	if (is_pc0) {
	if (partitionedQ ? writeQueueFullPC0(pkt_count) :
	writeQueueFull(pkt_count))
	{
	DPRINTF(MemCtrl, "Write queue full, not accepting\n");
	// remember that we have to retry this port
	MemCtrl::retryWrReq = true;
	stats.numWrRetry++;
	return false;
	} else {
	addToWriteQueue(pkt, pkt_count, pc0Int);
	stats.writeReqs++;
	stats.bytesWrittenSys += size;
	}
	} else {
	if (partitionedQ ? writeQueueFullPC1(pkt_count) :
	writeQueueFull(pkt_count))
	{
	DPRINTF(MemCtrl, "Write queue full, not accepting\n");
	// remember that we have to retry this port
	retryWrReqPC1 = true;
	stats.numWrRetry++;
	return false;
	} else {
	addToWriteQueue(pkt, pkt_count, pc1Int);
	stats.writeReqs++;
	stats.bytesWrittenSys += size;
	}
	}
	} else {

	assert(pkt->isRead());
	assert(size != 0);

	if (is_pc0) {
	if (partitionedQ ? readQueueFullPC0(pkt_count) :
	HBMCtrl::readQueueFull(pkt_count)) {
	DPRINTF(MemCtrl, "Read queue full, not accepting\n");
	// remember that we have to retry this port
	retryRdReqPC1 = true;
	stats.numRdRetry++;
	return false;
	} else {
	if (!addToReadQueue(pkt, pkt_count, pc0Int)) {
	if (!nextReqEvent.scheduled()) {
	DPRINTF(MemCtrl, "Request scheduled immediately\n");
	schedule(nextReqEvent, curTick());
	}
	}

	stats.readReqs++;
	stats.bytesReadSys += size;
	}
	} else {
	if (partitionedQ ? readQueueFullPC1(pkt_count) :
	HBMCtrl::readQueueFull(pkt_count)) {
	DPRINTF(MemCtrl, "Read queue full, not accepting\n");
	// remember that we have to retry this port
	retryRdReqPC1 = true;
	stats.numRdRetry++;
	return false;
	} else {
	if (!addToReadQueue(pkt, pkt_count, pc1Int)) {
	if (!nextReqEventPC1.scheduled()) {
	DPRINTF(MemCtrl, "Request scheduled immediately\n");
	schedule(nextReqEventPC1, curTick());
	}
	}
	stats.readReqs++;
	stats.bytesReadSys += size;
	}
	}
	}

	return true;
	}

	void
	HBMCtrl::pruneRowBurstTick()
	{
	auto it = rowBurstTicks.begin();
	while (it != rowBurstTicks.end()) {
	auto current_it = it++;
	if (MemCtrl::getBurstWindow(curTick()) > *current_it) {
	DPRINTF(MemCtrl, "Removing burstTick for %d\n", *current_it);
	rowBurstTicks.erase(current_it);
	}
	}
	}

	void
	HBMCtrl::pruneColBurstTick()
	{
	auto it = colBurstTicks.begin();
	while (it != colBurstTicks.end()) {
	auto current_it = it++;
	if (MemCtrl::getBurstWindow(curTick()) > *current_it) {
	DPRINTF(MemCtrl, "Removing burstTick for %d\n", *current_it);
	colBurstTicks.erase(current_it);
	}
	}
	}

	void
	HBMCtrl::pruneBurstTick()
	{
	pruneRowBurstTick();
	pruneColBurstTick();
	}

	Tick
	HBMCtrl::verifySingleCmd(Tick cmd_tick, Tick max_cmds_per_burst, bool row_cmd)
	{
	// start with assumption that there is no contention on command bus
	Tick cmd_at = cmd_tick;

	// get tick aligned to burst window
	Tick burst_tick = MemCtrl::getBurstWindow(cmd_tick);

	// verify that we have command bandwidth to issue the command
	// if not, iterate over next window(s) until slot found

	if (row_cmd) {
	while (rowBurstTicks.count(burst_tick) >= max_cmds_per_burst) {
	DPRINTF(MemCtrl, "Contention found on row command bus at %d\n",
	burst_tick);
	burst_tick += commandWindow;
	cmd_at = burst_tick;
	}
	DPRINTF(MemCtrl, "Now can send a row cmd_at %d\n",
	cmd_at);
	rowBurstTicks.insert(burst_tick);

	} else {
	while (colBurstTicks.count(burst_tick) >= max_cmds_per_burst) {
	DPRINTF(MemCtrl, "Contention found on col command bus at %d\n",
	burst_tick);
	burst_tick += commandWindow;
	cmd_at = burst_tick;
	}
	DPRINTF(MemCtrl, "Now can send a col cmd_at %d\n",
	cmd_at);
	colBurstTicks.insert(burst_tick);
	}
	return cmd_at;
	}

	Tick
	HBMCtrl::verifyMultiCmd(Tick cmd_tick, Tick max_cmds_per_burst,
	Tick max_multi_cmd_split)
	{

	// start with assumption that there is no contention on command bus
	Tick cmd_at = cmd_tick;

	// get tick aligned to burst window
	Tick burst_tick = MemCtrl::getBurstWindow(cmd_tick);

	// Command timing requirements are from 2nd command
	// Start with assumption that 2nd command will issue at cmd_at and
	// find prior slot for 1st command to issue
	// Given a maximum latency of max_multi_cmd_split between the commands,
	// find the burst at the maximum latency prior to cmd_at
	Tick burst_offset = 0;
	Tick first_cmd_offset = cmd_tick % commandWindow;
	while (max_multi_cmd_split > (first_cmd_offset + burst_offset)) {
	burst_offset += commandWindow;
	}
	// get the earliest burst aligned address for first command
	// ensure that the time does not go negative
	Tick first_cmd_tick = burst_tick - std::min(burst_offset, burst_tick);

	// Can required commands issue?
	bool first_can_issue = false;
	bool second_can_issue = false;
	// verify that we have command bandwidth to issue the command(s)
	while (!first_can_issue \|\| !second_can_issue) {
	bool same_burst = (burst_tick == first_cmd_tick);
	auto first_cmd_count = rowBurstTicks.count(first_cmd_tick);
	auto second_cmd_count = same_burst ?
	first_cmd_count + 1 : rowBurstTicks.count(burst_tick);

	first_can_issue = first_cmd_count < max_cmds_per_burst;
	second_can_issue = second_cmd_count < max_cmds_per_burst;

	if (!second_can_issue) {
	DPRINTF(MemCtrl, "Contention (cmd2) found on command bus at %d\n",
	burst_tick);
	burst_tick += commandWindow;
	cmd_at = burst_tick;
	}

	// Verify max_multi_cmd_split isn't violated when command 2 is shifted
	// If commands initially were issued in same burst, they are
	// now in consecutive bursts and can still issue B2B
	bool gap_violated = !same_burst &&
	((burst_tick - first_cmd_tick) > max_multi_cmd_split);

	if (!first_can_issue \|\| (!second_can_issue && gap_violated)) {
	DPRINTF(MemCtrl, "Contention (cmd1) found on command bus at %d\n",
	first_cmd_tick);
	first_cmd_tick += commandWindow;
	}
	}

	// Add command to burstTicks
	rowBurstTicks.insert(burst_tick);
	rowBurstTicks.insert(first_cmd_tick);

	return cmd_at;
	}

	void
	HBMCtrl::drainResume()
	{

	MemCtrl::drainResume();

	if (!isTimingMode && system()->isTimingMode()) {
	// if we switched to timing mode, kick things into action,
	// and behave as if we restored from a checkpoint
	startup();
	pc1Int->startup();
	} else if (isTimingMode && !system()->isTimingMode()) {
	// if we switch from timing mode, stop the refresh events to
	// not cause issues with KVM
	if (pc1Int) {
	pc1Int->drainRanks();
	}
	}

	// update the mode
	isTimingMode = system()->isTimingMode();
	}

	AddrRangeList
	HBMCtrl::getAddrRanges()
	{
	AddrRangeList ranges;
	ranges.push_back(pc0Int->getAddrRange());
	ranges.push_back(pc1Int->getAddrRange());
	return ranges;
	}

	} // namespace memory
	} // namespace gem5