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MemoryController.cpp
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MemoryController.cpp
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/*********************************************************************************
* Copyright (c) 2010-2011, Elliott Cooper-Balis
* Paul Rosenfeld
* Bruce Jacob
* University of Maryland
* dramninjas [at] gmail [dot] com
* 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.
*
* 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 HOLDER 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.
*********************************************************************************/
//MemoryController.cpp
//
//Class file for memory controller object
//
#include "MemoryController.h"
#include "MemorySystem.h"
#include "AddressMapping.h"
#define SEQUENTIAL(rank,bank) (rank*NUM_BANKS)+bank
/* Power computations are localized to MemoryController.cpp */
extern unsigned IDD0;
extern unsigned IDD1;
extern unsigned IDD2P;
extern unsigned IDD2Q;
extern unsigned IDD2N;
extern unsigned IDD3Pf;
extern unsigned IDD3Ps;
extern unsigned IDD3N;
extern unsigned IDD4W;
extern unsigned IDD4R;
extern unsigned IDD5;
extern unsigned IDD6;
extern unsigned IDD6L;
extern unsigned IDD7;
extern float Vdd;
using namespace DRAMSim;
MemoryController::MemoryController(MemorySystem *parent, CSVWriter &csvOut_, ostream &dramsim_log_) :
dramsim_log(dramsim_log_),
bankStates(NUM_RANKS, vector<BankState>(NUM_BANKS, dramsim_log)),
commandQueue(bankStates, dramsim_log_),
poppedBusPacket(NULL),
csvOut(csvOut_),
totalTransactions(0),
refreshRank(0)
{
//get handle on parent
parentMemorySystem = parent;
//bus related fields
outgoingCmdPacket = NULL;
outgoingDataPacket = NULL;
dataCyclesLeft = 0;
cmdCyclesLeft = 0;
//set here to avoid compile errors
currentClockCycle = 0;
//reserve memory for vectors
transactionQueue.reserve(TRANS_QUEUE_DEPTH);
powerDown = vector<bool>(NUM_RANKS,false);
grandTotalBankAccesses = vector<uint64_t>(NUM_RANKS*NUM_BANKS,0);
totalReadsPerBank = vector<uint64_t>(NUM_RANKS*NUM_BANKS,0);
totalWritesPerBank = vector<uint64_t>(NUM_RANKS*NUM_BANKS,0);
totalReadsPerRank = vector<uint64_t>(NUM_RANKS,0);
totalWritesPerRank = vector<uint64_t>(NUM_RANKS,0);
writeDataCountdown.reserve(NUM_RANKS);
writeDataToSend.reserve(NUM_RANKS);
refreshCountdown.reserve(NUM_RANKS);
//Power related packets
backgroundEnergy = vector <uint64_t >(NUM_RANKS,0);
burstEnergy = vector <uint64_t> (NUM_RANKS,0);
actpreEnergy = vector <uint64_t> (NUM_RANKS,0);
refreshEnergy = vector <uint64_t> (NUM_RANKS,0);
totalEpochLatency = vector<uint64_t> (NUM_RANKS*NUM_BANKS,0);
//staggers when each rank is due for a refresh
for (size_t i=0;i<NUM_RANKS;i++)
{
refreshCountdown.push_back((int)((REFRESH_PERIOD/tCK)/NUM_RANKS)*(i+1));
}
}
//get a bus packet from either data or cmd bus
void MemoryController::receiveFromBus(BusPacket *bpacket)
{
if (bpacket->busPacketType != DATA)
{
ERROR("== Error - Memory Controller received a non-DATA bus packet from rank");
bpacket->print();
exit(0);
}
if (DEBUG_BUS)
{
PRINTN(" -- MC Receiving From Data Bus : ");
bpacket->print();
}
//add to return read data queue
returnTransaction.push_back(new Transaction(RETURN_DATA, bpacket->physicalAddress, bpacket->data));
totalReadsPerBank[SEQUENTIAL(bpacket->rank,bpacket->bank)]++;
// this delete statement saves a mindboggling amount of memory
delete(bpacket);
}
//sends read data back to the CPU
void MemoryController::returnReadData(const Transaction *trans)
{
if (parentMemorySystem->ReturnReadData!=NULL)
{
(*parentMemorySystem->ReturnReadData)(parentMemorySystem->systemID, trans->address, currentClockCycle);
}
}
//gives the memory controller a handle on the rank objects
void MemoryController::attachRanks(vector<Rank *> *ranks)
{
this->ranks = ranks;
}
//memory controller update
void MemoryController::update()
{
//PRINT(" ------------------------- [" << currentClockCycle << "] -------------------------");
//update bank states
for (size_t i=0;i<NUM_RANKS;i++)
{
for (size_t j=0;j<NUM_BANKS;j++)
{
if (bankStates[i][j].stateChangeCountdown>0)
{
//decrement counters
bankStates[i][j].stateChangeCountdown--;
//if counter has reached 0, change state
if (bankStates[i][j].stateChangeCountdown == 0)
{
switch (bankStates[i][j].lastCommand)
{
//only these commands have an implicit state change
case WRITE_P:
case READ_P:
bankStates[i][j].currentBankState = Precharging;
bankStates[i][j].lastCommand = PRECHARGE;
bankStates[i][j].stateChangeCountdown = tRP;
break;
case REFRESH:
case PRECHARGE:
bankStates[i][j].currentBankState = Idle;
break;
default:
break;
}
}
}
}
}
//check for outgoing command packets and handle countdowns
if (outgoingCmdPacket != NULL)
{
cmdCyclesLeft--;
if (cmdCyclesLeft == 0) //packet is ready to be received by rank
{
(*ranks)[outgoingCmdPacket->rank]->receiveFromBus(outgoingCmdPacket);
outgoingCmdPacket = NULL;
}
}
//check for outgoing data packets and handle countdowns
if (outgoingDataPacket != NULL)
{
dataCyclesLeft--;
if (dataCyclesLeft == 0)
{
//inform upper levels that a write is done
if (parentMemorySystem->WriteDataDone!=NULL)
{
(*parentMemorySystem->WriteDataDone)(parentMemorySystem->systemID,outgoingDataPacket->physicalAddress, currentClockCycle);
}
(*ranks)[outgoingDataPacket->rank]->receiveFromBus(outgoingDataPacket);
outgoingDataPacket=NULL;
}
}
//if any outstanding write data needs to be sent
//and the appropriate amount of time has passed (WL)
//then send data on bus
//
//write data held in fifo vector along with countdowns
if (writeDataCountdown.size() > 0)
{
for (size_t i=0;i<writeDataCountdown.size();i++)
{
writeDataCountdown[i]--;
}
if (writeDataCountdown[0]==0)
{
//send to bus and print debug stuff
if (DEBUG_BUS)
{
PRINTN(" -- MC Issuing On Data Bus : ");
writeDataToSend[0]->print();
}
// queue up the packet to be sent
if (outgoingDataPacket != NULL)
{
ERROR("== Error - Data Bus Collision");
exit(-1);
}
outgoingDataPacket = writeDataToSend[0];
dataCyclesLeft = BL/2;
totalTransactions++;
totalWritesPerBank[SEQUENTIAL(writeDataToSend[0]->rank,writeDataToSend[0]->bank)]++;
writeDataCountdown.erase(writeDataCountdown.begin());
writeDataToSend.erase(writeDataToSend.begin());
}
}
//if its time for a refresh issue a refresh
// else pop from command queue if it's not empty
if (refreshCountdown[refreshRank]==0)
{
commandQueue.needRefresh(refreshRank);
(*ranks)[refreshRank]->refreshWaiting = true;
refreshCountdown[refreshRank] = REFRESH_PERIOD/tCK;
refreshRank++;
if (refreshRank == NUM_RANKS)
{
refreshRank = 0;
}
}
//if a rank is powered down, make sure we power it up in time for a refresh
else if (powerDown[refreshRank] && refreshCountdown[refreshRank] <= tXP)
{
(*ranks)[refreshRank]->refreshWaiting = true;
}
//pass a pointer to a poppedBusPacket
//function returns true if there is something valid in poppedBusPacket
if (commandQueue.pop(&poppedBusPacket))
{
if (poppedBusPacket->busPacketType == WRITE || poppedBusPacket->busPacketType == WRITE_P)
{
writeDataToSend.push_back(new BusPacket(DATA, poppedBusPacket->physicalAddress, poppedBusPacket->column,
poppedBusPacket->row, poppedBusPacket->rank, poppedBusPacket->bank,
poppedBusPacket->data, dramsim_log));
writeDataCountdown.push_back(WL);
}
//
//update each bank's state based on the command that was just popped out of the command queue
//
//for readability's sake
unsigned rank = poppedBusPacket->rank;
unsigned bank = poppedBusPacket->bank;
switch (poppedBusPacket->busPacketType)
{
case READ_P:
case READ:
//add energy to account for total
if (DEBUG_POWER)
{
PRINT(" ++ Adding Read energy to total energy");
}
burstEnergy[rank] += (IDD4R - IDD3N) * BL/2 * NUM_DEVICES;
if (poppedBusPacket->busPacketType == READ_P)
{
//Don't bother setting next read or write times because the bank is no longer active
//bankStates[rank][bank].currentBankState = Idle;
bankStates[rank][bank].nextActivate = max(currentClockCycle + READ_AUTOPRE_DELAY,
bankStates[rank][bank].nextActivate);
bankStates[rank][bank].lastCommand = READ_P;
bankStates[rank][bank].stateChangeCountdown = READ_TO_PRE_DELAY;
}
else if (poppedBusPacket->busPacketType == READ)
{
bankStates[rank][bank].nextPrecharge = max(currentClockCycle + READ_TO_PRE_DELAY,
bankStates[rank][bank].nextPrecharge);
bankStates[rank][bank].lastCommand = READ;
}
for (size_t i=0;i<NUM_RANKS;i++)
{
for (size_t j=0;j<NUM_BANKS;j++)
{
if (i!=poppedBusPacket->rank)
{
//check to make sure it is active before trying to set (save's time?)
if (bankStates[i][j].currentBankState == RowActive)
{
bankStates[i][j].nextRead = max(currentClockCycle + BL/2 + tRTRS, bankStates[i][j].nextRead);
bankStates[i][j].nextWrite = max(currentClockCycle + READ_TO_WRITE_DELAY,
bankStates[i][j].nextWrite);
}
}
else
{
bankStates[i][j].nextRead = max(currentClockCycle + max(tCCD, BL/2), bankStates[i][j].nextRead);
bankStates[i][j].nextWrite = max(currentClockCycle + READ_TO_WRITE_DELAY,
bankStates[i][j].nextWrite);
}
}
}
if (poppedBusPacket->busPacketType == READ_P)
{
//set read and write to nextActivate so the state table will prevent a read or write
// being issued (in cq.isIssuable())before the bank state has been changed because of the
// auto-precharge associated with this command
bankStates[rank][bank].nextRead = bankStates[rank][bank].nextActivate;
bankStates[rank][bank].nextWrite = bankStates[rank][bank].nextActivate;
}
break;
case WRITE_P:
case WRITE:
if (poppedBusPacket->busPacketType == WRITE_P)
{
bankStates[rank][bank].nextActivate = max(currentClockCycle + WRITE_AUTOPRE_DELAY,
bankStates[rank][bank].nextActivate);
bankStates[rank][bank].lastCommand = WRITE_P;
bankStates[rank][bank].stateChangeCountdown = WRITE_TO_PRE_DELAY;
}
else if (poppedBusPacket->busPacketType == WRITE)
{
bankStates[rank][bank].nextPrecharge = max(currentClockCycle + WRITE_TO_PRE_DELAY,
bankStates[rank][bank].nextPrecharge);
bankStates[rank][bank].lastCommand = WRITE;
}
//add energy to account for total
if (DEBUG_POWER)
{
PRINT(" ++ Adding Write energy to total energy");
}
burstEnergy[rank] += (IDD4W - IDD3N) * BL/2 * NUM_DEVICES;
for (size_t i=0;i<NUM_RANKS;i++)
{
for (size_t j=0;j<NUM_BANKS;j++)
{
if (i!=poppedBusPacket->rank)
{
if (bankStates[i][j].currentBankState == RowActive)
{
bankStates[i][j].nextWrite = max(currentClockCycle + BL/2 + tRTRS, bankStates[i][j].nextWrite);
bankStates[i][j].nextRead = max(currentClockCycle + WRITE_TO_READ_DELAY_R,
bankStates[i][j].nextRead);
}
}
else
{
bankStates[i][j].nextWrite = max(currentClockCycle + max(BL/2, tCCD), bankStates[i][j].nextWrite);
bankStates[i][j].nextRead = max(currentClockCycle + WRITE_TO_READ_DELAY_B,
bankStates[i][j].nextRead);
}
}
}
//set read and write to nextActivate so the state table will prevent a read or write
// being issued (in cq.isIssuable())before the bank state has been changed because of the
// auto-precharge associated with this command
if (poppedBusPacket->busPacketType == WRITE_P)
{
bankStates[rank][bank].nextRead = bankStates[rank][bank].nextActivate;
bankStates[rank][bank].nextWrite = bankStates[rank][bank].nextActivate;
}
break;
case ACTIVATE:
//add energy to account for total
if (DEBUG_POWER)
{
PRINT(" ++ Adding Activate and Precharge energy to total energy");
}
actpreEnergy[rank] += ((IDD0 * tRC) - ((IDD3N * tRAS) + (IDD2N * (tRC - tRAS)))) * NUM_DEVICES;
bankStates[rank][bank].currentBankState = RowActive;
bankStates[rank][bank].lastCommand = ACTIVATE;
bankStates[rank][bank].openRowAddress = poppedBusPacket->row;
bankStates[rank][bank].nextActivate = max(currentClockCycle + tRC, bankStates[rank][bank].nextActivate);
bankStates[rank][bank].nextPrecharge = max(currentClockCycle + tRAS, bankStates[rank][bank].nextPrecharge);
//if we are using posted-CAS, the next column access can be sooner than normal operation
bankStates[rank][bank].nextRead = max(currentClockCycle + (tRCD-AL), bankStates[rank][bank].nextRead);
bankStates[rank][bank].nextWrite = max(currentClockCycle + (tRCD-AL), bankStates[rank][bank].nextWrite);
for (size_t i=0;i<NUM_BANKS;i++)
{
if (i!=poppedBusPacket->bank)
{
bankStates[rank][i].nextActivate = max(currentClockCycle + tRRD, bankStates[rank][i].nextActivate);
}
}
break;
case PRECHARGE:
bankStates[rank][bank].currentBankState = Precharging;
bankStates[rank][bank].lastCommand = PRECHARGE;
bankStates[rank][bank].stateChangeCountdown = tRP;
bankStates[rank][bank].nextActivate = max(currentClockCycle + tRP, bankStates[rank][bank].nextActivate);
break;
case REFRESH:
//add energy to account for total
if (DEBUG_POWER)
{
PRINT(" ++ Adding Refresh energy to total energy");
}
refreshEnergy[rank] += (IDD5 - IDD3N) * tRFC * NUM_DEVICES;
for (size_t i=0;i<NUM_BANKS;i++)
{
bankStates[rank][i].nextActivate = currentClockCycle + tRFC;
bankStates[rank][i].currentBankState = Refreshing;
bankStates[rank][i].lastCommand = REFRESH;
bankStates[rank][i].stateChangeCountdown = tRFC;
}
break;
default:
ERROR("== Error - Popped a command we shouldn't have of type : " << poppedBusPacket->busPacketType);
exit(0);
}
//issue on bus and print debug
if (DEBUG_BUS)
{
PRINTN(" -- MC Issuing On Command Bus : ");
poppedBusPacket->print();
}
//check for collision on bus
if (outgoingCmdPacket != NULL)
{
ERROR("== Error - Command Bus Collision");
exit(-1);
}
outgoingCmdPacket = poppedBusPacket;
cmdCyclesLeft = tCMD;
}
for (size_t i=0;i<transactionQueue.size();i++)
{
//pop off top transaction from queue
//
// assuming simple scheduling at the moment
// will eventually add policies here
Transaction *transaction = transactionQueue[i];
//map address to rank,bank,row,col
unsigned newTransactionChan, newTransactionRank, newTransactionBank, newTransactionRow, newTransactionColumn;
// pass these in as references so they get set by the addressMapping function
addressMapping(transaction->address, newTransactionChan, newTransactionRank, newTransactionBank, newTransactionRow, newTransactionColumn);
//if we have room, break up the transaction into the appropriate commands
//and add them to the command queue
if (commandQueue.hasRoomFor(2, newTransactionRank, newTransactionBank))
{
if (DEBUG_ADDR_MAP)
{
PRINTN("== New Transaction - Mapping Address [0x" << hex << transaction->address << dec << "]");
if (transaction->transactionType == DATA_READ)
{
PRINT(" (Read)");
}
else
{
PRINT(" (Write)");
}
PRINT(" Rank : " << newTransactionRank);
PRINT(" Bank : " << newTransactionBank);
PRINT(" Row : " << newTransactionRow);
PRINT(" Col : " << newTransactionColumn);
}
//now that we know there is room in the command queue, we can remove from the transaction queue
transactionQueue.erase(transactionQueue.begin()+i);
//create activate command to the row we just translated
BusPacket *ACTcommand = new BusPacket(ACTIVATE, transaction->address,
newTransactionColumn, newTransactionRow, newTransactionRank,
newTransactionBank, 0, dramsim_log);
//create read or write command and enqueue it
BusPacketType bpType = transaction->getBusPacketType();
BusPacket *command = new BusPacket(bpType, transaction->address,
newTransactionColumn, newTransactionRow, newTransactionRank,
newTransactionBank, transaction->data, dramsim_log);
commandQueue.enqueue(ACTcommand);
commandQueue.enqueue(command);
// If we have a read, save the transaction so when the data comes back
// in a bus packet, we can staple it back into a transaction and return it
if (transaction->transactionType == DATA_READ)
{
pendingReadTransactions.push_back(transaction);
}
else
{
// just delete the transaction now that it's a buspacket
delete transaction;
}
/* only allow one transaction to be scheduled per cycle -- this should
* be a reasonable assumption considering how much logic would be
* required to schedule multiple entries per cycle (parallel data
* lines, switching logic, decision logic)
*/
break;
}
else // no room, do nothing this cycle
{
//PRINT( "== Warning - No room in command queue" << endl;
}
}
//calculate power
// this is done on a per-rank basis, since power characterization is done per device (not per bank)
for (size_t i=0;i<NUM_RANKS;i++)
{
if (USE_LOW_POWER)
{
//if there are no commands in the queue and that particular rank is not waiting for a refresh...
if (commandQueue.isEmpty(i) && !(*ranks)[i]->refreshWaiting)
{
//check to make sure all banks are idle
bool allIdle = true;
for (size_t j=0;j<NUM_BANKS;j++)
{
if (bankStates[i][j].currentBankState != Idle)
{
allIdle = false;
break;
}
}
//if they ARE all idle, put in power down mode and set appropriate fields
if (allIdle)
{
powerDown[i] = true;
(*ranks)[i]->powerDown();
for (size_t j=0;j<NUM_BANKS;j++)
{
bankStates[i][j].currentBankState = PowerDown;
bankStates[i][j].nextPowerUp = currentClockCycle + tCKE;
}
}
}
//if there IS something in the queue or there IS a refresh waiting (and we can power up), do it
else if (currentClockCycle >= bankStates[i][0].nextPowerUp && powerDown[i]) //use 0 since theyre all the same
{
powerDown[i] = false;
(*ranks)[i]->powerUp();
for (size_t j=0;j<NUM_BANKS;j++)
{
bankStates[i][j].currentBankState = Idle;
bankStates[i][j].nextActivate = currentClockCycle + tXP;
}
}
}
//check for open bank
bool bankOpen = false;
for (size_t j=0;j<NUM_BANKS;j++)
{
if (bankStates[i][j].currentBankState == Refreshing ||
bankStates[i][j].currentBankState == RowActive)
{
bankOpen = true;
break;
}
}
//background power is dependent on whether or not a bank is open or not
if (bankOpen)
{
if (DEBUG_POWER)
{
PRINT(" ++ Adding IDD3N to total energy [from rank "<< i <<"]");
}
backgroundEnergy[i] += IDD3N * NUM_DEVICES;
}
else
{
//if we're in power-down mode, use the correct current
if (powerDown[i])
{
if (DEBUG_POWER)
{
PRINT(" ++ Adding IDD2P to total energy [from rank " << i << "]");
}
backgroundEnergy[i] += IDD2P * NUM_DEVICES;
}
else
{
if (DEBUG_POWER)
{
PRINT(" ++ Adding IDD2N to total energy [from rank " << i << "]");
}
backgroundEnergy[i] += IDD2N * NUM_DEVICES;
}
}
}
//check for outstanding data to return to the CPU
if (returnTransaction.size()>0)
{
if (DEBUG_BUS)
{
PRINTN(" -- MC Issuing to CPU bus : " << *returnTransaction[0]);
}
totalTransactions++;
bool foundMatch=false;
//find the pending read transaction to calculate latency
for (size_t i=0;i<pendingReadTransactions.size();i++)
{
if (pendingReadTransactions[i]->address == returnTransaction[0]->address)
{
//if(currentClockCycle - pendingReadTransactions[i]->timeAdded > 2000)
// {
// pendingReadTransactions[i]->print();
// exit(0);
// }
unsigned chan,rank,bank,row,col;
addressMapping(returnTransaction[0]->address,chan,rank,bank,row,col);
insertHistogram(currentClockCycle-pendingReadTransactions[i]->timeAdded,rank,bank);
//return latency
returnReadData(pendingReadTransactions[i]);
delete pendingReadTransactions[i];
pendingReadTransactions.erase(pendingReadTransactions.begin()+i);
foundMatch=true;
break;
}
}
if (!foundMatch)
{
ERROR("Can't find a matching transaction for 0x"<<hex<<returnTransaction[0]->address<<dec);
abort();
}
delete returnTransaction[0];
returnTransaction.erase(returnTransaction.begin());
}
//decrement refresh counters
for (size_t i=0;i<NUM_RANKS;i++)
{
refreshCountdown[i]--;
}
//
//print debug
//
if (DEBUG_TRANS_Q)
{
PRINT("== Printing transaction queue");
for (size_t i=0;i<transactionQueue.size();i++)
{
PRINTN(" " << i << "] "<< *transactionQueue[i]);
}
}
if (DEBUG_BANKSTATE)
{
//TODO: move this to BankState.cpp
PRINT("== Printing bank states (According to MC)");
for (size_t i=0;i<NUM_RANKS;i++)
{
for (size_t j=0;j<NUM_BANKS;j++)
{
if (bankStates[i][j].currentBankState == RowActive)
{
PRINTN("[" << bankStates[i][j].openRowAddress << "] ");
}
else if (bankStates[i][j].currentBankState == Idle)
{
PRINTN("[idle] ");
}
else if (bankStates[i][j].currentBankState == Precharging)
{
PRINTN("[pre] ");
}
else if (bankStates[i][j].currentBankState == Refreshing)
{
PRINTN("[ref] ");
}
else if (bankStates[i][j].currentBankState == PowerDown)
{
PRINTN("[lowp] ");
}
}
PRINT(""); // effectively just cout<<endl;
}
}
if (DEBUG_CMD_Q)
{
commandQueue.print();
}
commandQueue.step();
}
bool MemoryController::WillAcceptTransaction()
{
return transactionQueue.size() < TRANS_QUEUE_DEPTH;
}
//allows outside source to make request of memory system
bool MemoryController::addTransaction(Transaction *trans)
{
if (WillAcceptTransaction())
{
trans->timeAdded = currentClockCycle;
transactionQueue.push_back(trans);
return true;
}
else
{
return false;
}
}
void MemoryController::resetStats()
{
for (size_t i=0; i<NUM_RANKS; i++)
{
for (size_t j=0; j<NUM_BANKS; j++)
{
//XXX: this means the bank list won't be printed for partial epochs
grandTotalBankAccesses[SEQUENTIAL(i,j)] += totalReadsPerBank[SEQUENTIAL(i,j)] + totalWritesPerBank[SEQUENTIAL(i,j)];
totalReadsPerBank[SEQUENTIAL(i,j)] = 0;
totalWritesPerBank[SEQUENTIAL(i,j)] = 0;
totalEpochLatency[SEQUENTIAL(i,j)] = 0;
}
burstEnergy[i] = 0;
actpreEnergy[i] = 0;
refreshEnergy[i] = 0;
backgroundEnergy[i] = 0;
totalReadsPerRank[i] = 0;
totalWritesPerRank[i] = 0;
}
}
//prints statistics at the end of an epoch or simulation
void MemoryController::printStats(bool finalStats)
{
unsigned myChannel = parentMemorySystem->systemID;
//if we are not at the end of the epoch, make sure to adjust for the actual number of cycles elapsed
uint64_t cyclesElapsed = (currentClockCycle % EPOCH_LENGTH == 0) ? EPOCH_LENGTH : currentClockCycle % EPOCH_LENGTH;
unsigned bytesPerTransaction = (JEDEC_DATA_BUS_BITS*BL)/8;
uint64_t totalBytesTransferred = totalTransactions * bytesPerTransaction;
double secondsThisEpoch = (double)cyclesElapsed * tCK * 1E-9;
// only per rank
vector<double> backgroundPower = vector<double>(NUM_RANKS,0.0);
vector<double> burstPower = vector<double>(NUM_RANKS,0.0);
vector<double> refreshPower = vector<double>(NUM_RANKS,0.0);
vector<double> actprePower = vector<double>(NUM_RANKS,0.0);
vector<double> averagePower = vector<double>(NUM_RANKS,0.0);
// per bank variables
vector<double> averageLatency = vector<double>(NUM_RANKS*NUM_BANKS,0.0);
vector<double> bandwidth = vector<double>(NUM_RANKS*NUM_BANKS,0.0);
double totalBandwidth=0.0;
for (size_t i=0;i<NUM_RANKS;i++)
{
for (size_t j=0; j<NUM_BANKS; j++)
{
bandwidth[SEQUENTIAL(i,j)] = (((double)(totalReadsPerBank[SEQUENTIAL(i,j)]+totalWritesPerBank[SEQUENTIAL(i,j)]) * (double)bytesPerTransaction)/(1024.0*1024.0*1024.0)) / secondsThisEpoch;
averageLatency[SEQUENTIAL(i,j)] = ((float)totalEpochLatency[SEQUENTIAL(i,j)] / (float)(totalReadsPerBank[SEQUENTIAL(i,j)])) * tCK;
totalBandwidth+=bandwidth[SEQUENTIAL(i,j)];
totalReadsPerRank[i] += totalReadsPerBank[SEQUENTIAL(i,j)];
totalWritesPerRank[i] += totalWritesPerBank[SEQUENTIAL(i,j)];
}
}
#ifdef LOG_OUTPUT
dramsim_log.precision(3);
dramsim_log.setf(ios::fixed,ios::floatfield);
#else
cout.precision(3);
cout.setf(ios::fixed,ios::floatfield);
#endif
PRINT( " =======================================================" );
PRINT( " ============== Printing Statistics [id:"<<parentMemorySystem->systemID<<"]==============" );
PRINTN( " Total Return Transactions : " << totalTransactions );
PRINT( " ("<<totalBytesTransferred <<" bytes) aggregate average bandwidth "<<totalBandwidth<<"GB/s");
double totalAggregateBandwidth = 0.0;
for (size_t r=0;r<NUM_RANKS;r++)
{
PRINT( " -Rank "<<r<<" : ");
PRINTN( " -Reads : " << totalReadsPerRank[r]);
PRINT( " ("<<totalReadsPerRank[r] * bytesPerTransaction<<" bytes)");
PRINTN( " -Writes : " << totalWritesPerRank[r]);
PRINT( " ("<<totalWritesPerRank[r] * bytesPerTransaction<<" bytes)");
for (size_t j=0;j<NUM_BANKS;j++)
{
PRINT( " -Bandwidth / Latency (Bank " <<j<<"): " <<bandwidth[SEQUENTIAL(r,j)] << " GB/s\t\t" <<averageLatency[SEQUENTIAL(r,j)] << " ns");
}
// factor of 1000 at the end is to account for the fact that totalEnergy is accumulated in mJ since IDD values are given in mA
backgroundPower[r] = ((double)backgroundEnergy[r] / (double)(cyclesElapsed)) * Vdd / 1000.0;
burstPower[r] = ((double)burstEnergy[r] / (double)(cyclesElapsed)) * Vdd / 1000.0;
refreshPower[r] = ((double) refreshEnergy[r] / (double)(cyclesElapsed)) * Vdd / 1000.0;
actprePower[r] = ((double)actpreEnergy[r] / (double)(cyclesElapsed)) * Vdd / 1000.0;
averagePower[r] = ((backgroundEnergy[r] + burstEnergy[r] + refreshEnergy[r] + actpreEnergy[r]) / (double)cyclesElapsed) * Vdd / 1000.0;
if ((*parentMemorySystem->ReportPower)!=NULL)
{
(*parentMemorySystem->ReportPower)(backgroundPower[r],burstPower[r],refreshPower[r],actprePower[r]);
}
PRINT( " == Power Data for Rank " << r );
PRINT( " Average Power (watts) : " << averagePower[r] );
PRINT( " -Background (watts) : " << backgroundPower[r] );
PRINT( " -Act/Pre (watts) : " << actprePower[r] );
PRINT( " -Burst (watts) : " << burstPower[r]);
PRINT( " -Refresh (watts) : " << refreshPower[r] );
if (VIS_FILE_OUTPUT)
{
// cout << "c="<<myChannel<< " r="<<r<<"writing to csv out on cycle "<< currentClockCycle<<endl;
// write the vis file output
csvOut << CSVWriter::IndexedName("Background_Power",myChannel,r) <<backgroundPower[r];
csvOut << CSVWriter::IndexedName("ACT_PRE_Power",myChannel,r) << actprePower[r];
csvOut << CSVWriter::IndexedName("Burst_Power",myChannel,r) << burstPower[r];
csvOut << CSVWriter::IndexedName("Refresh_Power",myChannel,r) << refreshPower[r];
double totalRankBandwidth=0.0;
for (size_t b=0; b<NUM_BANKS; b++)
{
csvOut << CSVWriter::IndexedName("Bandwidth",myChannel,r,b) << bandwidth[SEQUENTIAL(r,b)];
totalRankBandwidth += bandwidth[SEQUENTIAL(r,b)];
totalAggregateBandwidth += bandwidth[SEQUENTIAL(r,b)];
csvOut << CSVWriter::IndexedName("Average_Latency",myChannel,r,b) << averageLatency[SEQUENTIAL(r,b)];
}
csvOut << CSVWriter::IndexedName("Rank_Aggregate_Bandwidth",myChannel,r) << totalRankBandwidth;
csvOut << CSVWriter::IndexedName("Rank_Average_Bandwidth",myChannel,r) << totalRankBandwidth/NUM_RANKS;
}
}
if (VIS_FILE_OUTPUT)
{
csvOut << CSVWriter::IndexedName("Aggregate_Bandwidth",myChannel) << totalAggregateBandwidth;
csvOut << CSVWriter::IndexedName("Average_Bandwidth",myChannel) << totalAggregateBandwidth / (NUM_RANKS*NUM_BANKS);
}
// only print the latency histogram at the end of the simulation since it clogs the output too much to print every epoch
if (finalStats)
{
PRINT( " --- Latency list ("<<latencies.size()<<")");
PRINT( " [lat] : #");
if (VIS_FILE_OUTPUT)
{
csvOut.getOutputStream() << "!!HISTOGRAM_DATA"<<endl;
}
map<unsigned,unsigned>::iterator it; //
for (it=latencies.begin(); it!=latencies.end(); it++)
{
PRINT( " ["<< it->first <<"-"<<it->first+(HISTOGRAM_BIN_SIZE-1)<<"] : "<< it->second );
if (VIS_FILE_OUTPUT)
{
csvOut.getOutputStream() << it->first <<"="<< it->second << endl;
}
}
if (currentClockCycle % EPOCH_LENGTH == 0)
{
PRINT( " --- Grand Total Bank usage list");
for (size_t i=0;i<NUM_RANKS;i++)
{
PRINT("Rank "<<i<<":");
for (size_t j=0;j<NUM_BANKS;j++)
{
PRINT( " b"<<j<<": "<<grandTotalBankAccesses[SEQUENTIAL(i,j)]);
}
}
}
}
PRINT(endl<< " == Pending Transactions : "<<pendingReadTransactions.size()<<" ("<<currentClockCycle<<")==");
/*
for(size_t i=0;i<pendingReadTransactions.size();i++)
{
PRINT( i << "] I've been waiting for "<<currentClockCycle-pendingReadTransactions[i].timeAdded<<endl;
}
*/
#ifdef LOG_OUTPUT
dramsim_log.flush();
#endif
resetStats();
}
MemoryController::~MemoryController()
{
//ERROR("MEMORY CONTROLLER DESTRUCTOR");
//abort();
for (size_t i=0; i<pendingReadTransactions.size(); i++)
{
delete pendingReadTransactions[i];
}
for (size_t i=0; i<returnTransaction.size(); i++)
{
delete returnTransaction[i];
}
}
//inserts a latency into the latency histogram
void MemoryController::insertHistogram(unsigned latencyValue, unsigned rank, unsigned bank)
{
totalEpochLatency[SEQUENTIAL(rank,bank)] += latencyValue;
//poor man's way to bin things.
latencies[(latencyValue/HISTOGRAM_BIN_SIZE)*HISTOGRAM_BIN_SIZE]++;
}