/* * Copyright (c) 2012-2013, 2016-2017 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: Thomas Grass * Andreas Hansson * Sascha Bischoff */ #include "cpu/testers/traffic_gen/traffic_gen.hh" #include #include #include #include "base/intmath.hh" #include "base/random.hh" #include "debug/Checkpoint.hh" #include "debug/TrafficGen.hh" #include "sim/stats.hh" #include "sim/system.hh" using namespace std; TrafficGen::TrafficGen(const TrafficGenParams* p) : MemObject(p), system(p->system), masterID(system->getMasterId(this)), configFile(p->config_file), elasticReq(p->elastic_req), progressCheck(p->progress_check), noProgressEvent([this]{ noProgress(); }, name()), nextTransitionTick(0), nextPacketTick(0), currState(0), port(name() + ".port", *this), retryPkt(NULL), retryPktTick(0), updateEvent([this]{ update(); }, name()), numSuppressed(0) { } TrafficGen* TrafficGenParams::create() { return new TrafficGen(this); } BaseMasterPort& TrafficGen::getMasterPort(const string& if_name, PortID idx) { if (if_name == "port") { return port; } else { return MemObject::getMasterPort(if_name, idx); } } void TrafficGen::init() { if (!port.isConnected()) fatal("The port of %s is not connected!\n", name()); // if the system is in timing mode active the request generator if (system->isTimingMode()) { DPRINTF(TrafficGen, "Timing mode, activating request generator\n"); parseConfig(); // enter initial state enterState(currState); } else { DPRINTF(TrafficGen, "Traffic generator is only active in timing mode\n"); } } void TrafficGen::initState() { // when not restoring from a checkpoint, make sure we kick things off if (system->isTimingMode()) { // call nextPacketTick on the state to advance it nextPacketTick = states[currState]->nextPacketTick(elasticReq, 0); schedule(updateEvent, std::min(nextPacketTick, nextTransitionTick)); } else { DPRINTF(TrafficGen, "Traffic generator is only active in timing mode\n"); } } DrainState TrafficGen::drain() { if (!updateEvent.scheduled()) { // no event has been scheduled yet (e.g. switched from atomic mode) return DrainState::Drained; } if (retryPkt == NULL) { // shut things down nextPacketTick = MaxTick; nextTransitionTick = MaxTick; deschedule(updateEvent); return DrainState::Drained; } else { return DrainState::Draining; } } void TrafficGen::serialize(CheckpointOut &cp) const { DPRINTF(Checkpoint, "Serializing TrafficGen\n"); // save ticks of the graph event if it is scheduled Tick nextEvent = updateEvent.scheduled() ? updateEvent.when() : 0; DPRINTF(TrafficGen, "Saving nextEvent=%llu\n", nextEvent); SERIALIZE_SCALAR(nextEvent); SERIALIZE_SCALAR(nextTransitionTick); SERIALIZE_SCALAR(nextPacketTick); SERIALIZE_SCALAR(currState); } void TrafficGen::unserialize(CheckpointIn &cp) { // restore scheduled events Tick nextEvent; UNSERIALIZE_SCALAR(nextEvent); if (nextEvent != 0) { schedule(updateEvent, nextEvent); } UNSERIALIZE_SCALAR(nextTransitionTick); UNSERIALIZE_SCALAR(nextPacketTick); // @todo In the case of a stateful generator state such as the // trace player we would also have to restore the position in the // trace playback and the tick offset UNSERIALIZE_SCALAR(currState); } void TrafficGen::update() { // shift our progress-tracking event forward reschedule(noProgressEvent, curTick() + progressCheck, true); // if we have reached the time for the next state transition, then // perform the transition if (curTick() >= nextTransitionTick) { transition(); } else { assert(curTick() >= nextPacketTick); // get the next packet and try to send it PacketPtr pkt = states[currState]->getNextPacket(); // suppress packets that are not destined for a memory, such as // device accesses that could be part of a trace if (system->isMemAddr(pkt->getAddr())) { numPackets++; if (!port.sendTimingReq(pkt)) { retryPkt = pkt; retryPktTick = curTick(); } } else { DPRINTF(TrafficGen, "Suppressed packet %s 0x%x\n", pkt->cmdString(), pkt->getAddr()); ++numSuppressed; if (numSuppressed % 10000) warn("%s suppressed %d packets with non-memory addresses\n", name(), numSuppressed); delete pkt; pkt = nullptr; } } // if we are waiting for a retry, do not schedule any further // events, in the case of a transition or a successful send, go // ahead and determine when the next update should take place if (retryPkt == NULL) { // schedule next update event based on either the next execute // tick or the next transition, which ever comes first nextPacketTick = states[currState]->nextPacketTick(elasticReq, 0); Tick nextEventTick = std::min(nextPacketTick, nextTransitionTick); DPRINTF(TrafficGen, "Next event scheduled at %lld\n", nextEventTick); schedule(updateEvent, nextEventTick); } } std::string TrafficGen::resolveFile(const std::string &name) { // Do nothing for empty and absolute file names if (name.empty() || name[0] == '/') return name; char *config_path = strdup(configFile.c_str()); char *config_dir = dirname(config_path); const std::string config_rel = csprintf("%s/%s", config_dir, name); free(config_path); // Check the path relative to the config file first if (access(config_rel.c_str(), R_OK) == 0) return config_rel; // Fall back to the old behavior and search relative to the // current working directory. return name; } void TrafficGen::parseConfig() { // keep track of the transitions parsed to create the matrix when // done vector transitions; // open input file ifstream infile; infile.open(configFile.c_str(), ifstream::in); if (!infile.is_open()) { fatal("Traffic generator %s config file not found at %s\n", name(), configFile); } bool init_state_set = false; // read line by line and determine the action based on the first // keyword string keyword; string line; while (getline(infile, line).good()) { // see if this line is a comment line, and if so skip it if (line.find('#') != 1) { // create an input stream for the tokenization istringstream is(line); // determine the keyword is >> keyword; if (keyword == "STATE") { // parse the behaviour of this state uint32_t id; Tick duration; string mode; is >> id >> duration >> mode; if (mode == "TRACE") { string traceFile; Addr addrOffset; is >> traceFile >> addrOffset; traceFile = resolveFile(traceFile); states[id] = new TraceGen(name(), masterID, duration, traceFile, addrOffset); DPRINTF(TrafficGen, "State: %d TraceGen\n", id); } else if (mode == "IDLE") { states[id] = new IdleGen(name(), masterID, duration); DPRINTF(TrafficGen, "State: %d IdleGen\n", id); } else if (mode == "EXIT") { states[id] = new ExitGen(name(), masterID, duration); DPRINTF(TrafficGen, "State: %d ExitGen\n", id); } else if (mode == "LINEAR" || mode == "RANDOM" || mode == "DRAM" || mode == "DRAM_ROTATE") { uint32_t read_percent; Addr start_addr; Addr end_addr; Addr blocksize; Tick min_period; Tick max_period; Addr data_limit; is >> read_percent >> start_addr >> end_addr >> blocksize >> min_period >> max_period >> data_limit; DPRINTF(TrafficGen, "%s, addr %x to %x, size %d," " period %d to %d, %d%% reads\n", mode, start_addr, end_addr, blocksize, min_period, max_period, read_percent); if (blocksize > system->cacheLineSize()) fatal("TrafficGen %s block size (%d) is larger than " "cache line size (%d)\n", name(), blocksize, system->cacheLineSize()); if (read_percent > 100) fatal("%s cannot have more than 100% reads", name()); if (min_period > max_period) fatal("%s cannot have min_period > max_period", name()); if (mode == "LINEAR") { states[id] = new LinearGen(name(), masterID, duration, start_addr, end_addr, blocksize, min_period, max_period, read_percent, data_limit); DPRINTF(TrafficGen, "State: %d LinearGen\n", id); } else if (mode == "RANDOM") { states[id] = new RandomGen(name(), masterID, duration, start_addr, end_addr, blocksize, min_period, max_period, read_percent, data_limit); DPRINTF(TrafficGen, "State: %d RandomGen\n", id); } else if (mode == "DRAM" || mode == "DRAM_ROTATE") { // stride size (bytes) of the request for achieving // required hit length unsigned int stride_size; unsigned int page_size; unsigned int nbr_of_banks_DRAM; unsigned int nbr_of_banks_util; unsigned int addr_mapping; unsigned int nbr_of_ranks; is >> stride_size >> page_size >> nbr_of_banks_DRAM >> nbr_of_banks_util >> addr_mapping >> nbr_of_ranks; if (stride_size > page_size) warn("DRAM generator stride size (%d) is greater " "than page size (%d) of the memory\n", blocksize, page_size); if (nbr_of_banks_util > nbr_of_banks_DRAM) fatal("Attempting to use more banks (%d) than " "what is available (%d)\n", nbr_of_banks_util, nbr_of_banks_DRAM); // count the number of sequential packets to // generate unsigned int num_seq_pkts = 1; if (stride_size > blocksize) { num_seq_pkts = divCeil(stride_size, blocksize); DPRINTF(TrafficGen, "stride size: %d " "block size: %d, num_seq_pkts: %d\n", stride_size, blocksize, num_seq_pkts); } if (mode == "DRAM") { states[id] = new DramGen(name(), masterID, duration, start_addr, end_addr, blocksize, min_period, max_period, read_percent, data_limit, num_seq_pkts, page_size, nbr_of_banks_DRAM, nbr_of_banks_util, addr_mapping, nbr_of_ranks); DPRINTF(TrafficGen, "State: %d DramGen\n", id); } else { // Will rotate to the next rank after rotating // through all banks, for each command type. // In the 50% read case, series will be issued // for both RD & WR before the rank in incremented unsigned int max_seq_count_per_rank = (read_percent == 50) ? nbr_of_banks_util * 2 : nbr_of_banks_util; states[id] = new DramRotGen(name(), masterID, duration, start_addr, end_addr, blocksize, min_period, max_period, read_percent, data_limit, num_seq_pkts, page_size, nbr_of_banks_DRAM, nbr_of_banks_util, addr_mapping, nbr_of_ranks, max_seq_count_per_rank); DPRINTF(TrafficGen, "State: %d DramRotGen\n", id); } } } else { fatal("%s: Unknown traffic generator mode: %s", name(), mode); } } else if (keyword == "TRANSITION") { Transition transition; is >> transition.from >> transition.to >> transition.p; transitions.push_back(transition); DPRINTF(TrafficGen, "Transition: %d -> %d\n", transition.from, transition.to); } else if (keyword == "INIT") { // set the initial state as the active state is >> currState; init_state_set = true; DPRINTF(TrafficGen, "Initial state: %d\n", currState); } } } if (!init_state_set) fatal("%s: initial state not specified (add 'INIT ' line " "to the config file)\n", name()); // resize and populate state transition matrix transitionMatrix.resize(states.size()); for (size_t i = 0; i < states.size(); i++) { transitionMatrix[i].resize(states.size()); } for (vector::iterator t = transitions.begin(); t != transitions.end(); ++t) { transitionMatrix[t->from][t->to] = t->p; } // ensure the egress edges do not have a probability larger than // one for (size_t i = 0; i < states.size(); i++) { double sum = 0; for (size_t j = 0; j < states.size(); j++) { sum += transitionMatrix[i][j]; } // avoid comparing floating point numbers if (abs(sum - 1.0) > 0.001) fatal("%s has transition probability != 1 for state %d\n", name(), i); } // close input file infile.close(); } void TrafficGen::transition() { // exit the current state states[currState]->exit(); // determine next state double p = random_mt.random(); assert(currState < transitionMatrix.size()); double cumulative = 0.0; size_t i = 0; do { cumulative += transitionMatrix[currState][i]; ++i; } while (cumulative < p && i < transitionMatrix[currState].size()); enterState(i - 1); } void TrafficGen::enterState(uint32_t newState) { DPRINTF(TrafficGen, "Transition to state %d\n", newState); currState = newState; // we could have been delayed and not transitioned on the exact // tick when we were supposed to (due to back pressure when // sending a packet) nextTransitionTick = curTick() + states[currState]->duration; states[currState]->enter(); } void TrafficGen::recvReqRetry() { assert(retryPkt != NULL); DPRINTF(TrafficGen, "Received retry\n"); numRetries++; // attempt to send the packet, and if we are successful start up // the machinery again if (port.sendTimingReq(retryPkt)) { retryPkt = NULL; // remember how much delay was incurred due to back-pressure // when sending the request, we also use this to derive // the tick for the next packet Tick delay = curTick() - retryPktTick; retryPktTick = 0; retryTicks += delay; if (drainState() != DrainState::Draining) { // packet is sent, so find out when the next one is due nextPacketTick = states[currState]->nextPacketTick(elasticReq, delay); Tick nextEventTick = std::min(nextPacketTick, nextTransitionTick); schedule(updateEvent, std::max(curTick(), nextEventTick)); } else { // shut things down nextPacketTick = MaxTick; nextTransitionTick = MaxTick; signalDrainDone(); } } } void TrafficGen::noProgress() { fatal("TrafficGen %s spent %llu ticks without making progress", name(), progressCheck); } void TrafficGen::regStats() { ClockedObject::regStats(); // Initialise all the stats using namespace Stats; numPackets .name(name() + ".numPackets") .desc("Number of packets generated"); numRetries .name(name() + ".numRetries") .desc("Number of retries"); retryTicks .name(name() + ".retryTicks") .desc("Time spent waiting due to back-pressure (ticks)"); } bool TrafficGen::TrafficGenPort::recvTimingResp(PacketPtr pkt) { delete pkt; return true; }