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/*
* Copyright (c) 2017-2020 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.
*
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* met: redistributions of source code must retain the above copyright
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* 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
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* OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
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#include "mem/qos/mem_ctrl.hh"
#include "mem/qos/policy.hh"
#include "mem/qos/q_policy.hh"
#include "mem/qos/turnaround_policy.hh"
#include "sim/core.hh"
namespace gem5
{
namespace memory
{
namespace qos
{
MemCtrl::MemCtrl(const QoSMemCtrlParams &p)
: ClockedObject(p),
policy(p.qos_policy),
turnPolicy(p.qos_turnaround_policy),
queuePolicy(QueuePolicy::create(p)),
_numPriorities(p.qos_priorities),
qosPriorityEscalation(p.qos_priority_escalation),
qosSyncroScheduler(p.qos_syncro_scheduler),
totalReadQueueSize(0), totalWriteQueueSize(0),
busState(READ), busStateNext(READ),
stats(*this),
_system(p.system)
{
// Set the priority policy
if (policy) {
policy->setMemCtrl(this);
}
// Set the queue priority policy
if (queuePolicy) {
queuePolicy->setMemCtrl(this);
}
// Set the bus turnaround policy
if (turnPolicy) {
turnPolicy->setMemCtrl(this);
}
readQueueSizes.resize(_numPriorities);
writeQueueSizes.resize(_numPriorities);
serviceTick.resize(_numPriorities);
}
MemCtrl::~MemCtrl()
{}
void
MemCtrl::logRequest(BusState dir, RequestorID id, uint8_t _qos,
Addr addr, uint64_t entries)
{
// If needed, initialize all counters and statistics
// for this requestor
addRequestor(id);
DPRINTF(QOS,
"qos::MemCtrl::logRequest REQUESTOR %s [id %d] address %#x"
" prio %d this requestor q packets %d"
" - queue size %d - requested entries %d\n",
requestors[id], id, addr, _qos, packetPriorities[id][_qos],
(dir == READ) ? readQueueSizes[_qos]: writeQueueSizes[_qos],
entries);
if (dir == READ) {
readQueueSizes[_qos] += entries;
totalReadQueueSize += entries;
} else if (dir == WRITE) {
writeQueueSizes[_qos] += entries;
totalWriteQueueSize += entries;
}
packetPriorities[id][_qos] += entries;
for (auto j = 0; j < entries; ++j) {
requestTimes[id][addr].push_back(curTick());
}
// Record statistics
stats.avgPriority[id].sample(_qos);
// Compute avg priority distance
for (uint8_t i = 0; i < packetPriorities[id].size(); ++i) {
uint8_t distance =
(abs(int(_qos) - int(i))) * packetPriorities[id][i];
if (distance > 0) {
stats.avgPriorityDistance[id].sample(distance);
DPRINTF(QOS,
"qos::MemCtrl::logRequest REQUESTOR %s [id %d]"
" registering priority distance %d for priority %d"
" (packets %d)\n",
requestors[id], id, distance, i,
packetPriorities[id][i]);
}
}
DPRINTF(QOS,
"qos::MemCtrl::logRequest REQUESTOR %s [id %d] prio %d "
"this requestor q packets %d - new queue size %d\n",
requestors[id], id, _qos, packetPriorities[id][_qos],
(dir == READ) ? readQueueSizes[_qos]: writeQueueSizes[_qos]);
}
void
MemCtrl::logResponse(BusState dir, RequestorID id, uint8_t _qos,
Addr addr, uint64_t entries, double delay)
{
panic_if(!hasRequestor(id),
"Logging response with invalid requestor\n");
DPRINTF(QOS,
"qos::MemCtrl::logResponse REQUESTOR %s [id %d] address %#x prio"
" %d this requestor q packets %d"
" - queue size %d - requested entries %d\n",
requestors[id], id, addr, _qos, packetPriorities[id][_qos],
(dir == READ) ? readQueueSizes[_qos]: writeQueueSizes[_qos],
entries);
if (dir == READ) {
readQueueSizes[_qos] -= entries;
totalReadQueueSize -= entries;
} else if (dir == WRITE) {
writeQueueSizes[_qos] -= entries;
totalWriteQueueSize -= entries;
}
panic_if(packetPriorities[id][_qos] == 0,
"qos::MemCtrl::logResponse requestor %s negative packets "
"for priority %d", requestors[id], _qos);
packetPriorities[id][_qos] -= entries;
for (auto j = 0; j < entries; ++j) {
auto it = requestTimes[id].find(addr);
panic_if(it == requestTimes[id].end(),
"qos::MemCtrl::logResponse requestor %s unmatched response "
"for address %#x received", requestors[id], addr);
// Load request time
uint64_t requestTime = it->second.front();
// Remove request entry
it->second.pop_front();
// Remove whole address entry if last one
if (it->second.empty()) {
requestTimes[id].erase(it);
}
// Compute latency
double latency = (double) (curTick() + delay - requestTime)
/ sim_clock::as_float::s;
if (latency > 0) {
// Record per-priority latency stats
if (stats.priorityMaxLatency[_qos].value() < latency) {
stats.priorityMaxLatency[_qos] = latency;
}
if (stats.priorityMinLatency[_qos].value() > latency
|| stats.priorityMinLatency[_qos].value() == 0) {
stats.priorityMinLatency[_qos] = latency;
}
}
}
DPRINTF(QOS,
"qos::MemCtrl::logResponse REQUESTOR %s [id %d] prio %d "
"this requestor q packets %d - new queue size %d\n",
requestors[id], id, _qos, packetPriorities[id][_qos],
(dir == READ) ? readQueueSizes[_qos]: writeQueueSizes[_qos]);
}
uint8_t
MemCtrl::schedule(RequestorID id, uint64_t data)
{
if (policy) {
return policy->schedule(id, data);
} else {
DPRINTF(QOS,
"qos::MemCtrl::schedule requestor id [%d] "
"data received [%d], but QoS scheduler not initialized\n",
id,data);
return 0;
}
}
uint8_t
MemCtrl::schedule(const PacketPtr pkt)
{
assert(pkt->req);
if (policy) {
return schedule(pkt->req->requestorId(), pkt->getSize());
} else {
DPRINTF(QOS, "qos::MemCtrl::schedule Packet received [Qv %d], "
"but QoS scheduler not initialized\n",
pkt->qosValue());
return pkt->qosValue();
}
}
MemCtrl::BusState
MemCtrl::selectNextBusState()
{
auto bus_state = getBusState();
if (turnPolicy) {
DPRINTF(QOS,
"qos::MemCtrl::selectNextBusState running policy %s\n",
turnPolicy->name());
bus_state = turnPolicy->selectBusState();
} else {
DPRINTF(QOS,
"qos::MemCtrl::selectNextBusState running "
"default bus direction selection policy\n");
if ((!getTotalReadQueueSize() && bus_state == MemCtrl::READ) ||
(!getTotalWriteQueueSize() && bus_state == MemCtrl::WRITE)) {
// READ/WRITE turnaround
bus_state = (bus_state == MemCtrl::READ) ? MemCtrl::WRITE :
MemCtrl::READ;
}
}
return bus_state;
}
void
MemCtrl::addRequestor(RequestorID id)
{
if (!hasRequestor(id)) {
requestors.emplace(id, _system->getRequestorName(id));
packetPriorities[id].resize(numPriorities(), 0);
DPRINTF(QOS,
"qos::MemCtrl::addRequestor registering"
" Requestor %s [id %d]\n",
requestors[id], id);
}
}
MemCtrl::MemCtrlStats::MemCtrlStats(MemCtrl &mc)
: statistics::Group(&mc),
memCtrl(mc),
ADD_STAT(avgPriority, statistics::units::Count::get(),
"Average QoS priority value for accepted requests"),
ADD_STAT(avgPriorityDistance, statistics::units::Count::get(),
"Average QoS priority distance between assigned and queued "
"values"),
ADD_STAT(priorityMinLatency, statistics::units::Second::get(),
"per QoS priority minimum request to response latency"),
ADD_STAT(priorityMaxLatency, statistics::units::Second::get(),
"per QoS priority maximum request to response latency"),
ADD_STAT(numReadWriteTurnArounds, statistics::units::Count::get(),
"Number of turnarounds from READ to WRITE"),
ADD_STAT(numWriteReadTurnArounds, statistics::units::Count::get(),
"Number of turnarounds from WRITE to READ"),
ADD_STAT(numStayReadState, statistics::units::Count::get(),
"Number of times bus staying in READ state"),
ADD_STAT(numStayWriteState, statistics::units::Count::get(),
"Number of times bus staying in WRITE state")
{
}
void
MemCtrl::MemCtrlStats::regStats()
{
statistics::Group::regStats();
using namespace statistics;
System *system = memCtrl._system;
const auto max_requestors = system->maxRequestors();
const auto num_priorities = memCtrl.numPriorities();
// Initializes per requestor statistics
avgPriority
.init(max_requestors)
.flags(nozero | nonan)
.precision(2)
;
avgPriorityDistance
.init(max_requestors)
.flags(nozero | nonan)
;
priorityMinLatency
.init(num_priorities)
.precision(12)
;
priorityMaxLatency
.init(num_priorities)
.precision(12)
;
for (int i = 0; i < max_requestors; i++) {
const std::string name = system->getRequestorName(i);
avgPriority.subname(i, name);
avgPriorityDistance.subname(i, name);
}
for (int j = 0; j < num_priorities; ++j) {
priorityMinLatency.subname(j, std::to_string(j));
priorityMaxLatency.subname(j, std::to_string(j));
}
}
void
MemCtrl::recordTurnaroundStats()
{
if (busStateNext != busState) {
if (busState == READ) {
stats.numWriteReadTurnArounds++;
} else if (busState == WRITE) {
stats.numReadWriteTurnArounds++;
}
} else {
if (busState == READ) {
stats.numStayReadState++;
} else if (busState == WRITE) {
stats.numStayWriteState++;
}
}
}
} // namespace qos
} // namespace memory
} // namespace gem5