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/*
* Copyright (c) 2012-2014, TU Delft
* Copyright (c) 2012-2014, TU Eindhoven
* Copyright (c) 2012-2014, TU Kaiserslautern
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are
* met:
*
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
*
* 2. 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.
*
* 3. Neither the name of the copyright holder 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
* 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.
*
* Authors: Karthik Chandrasekar, Matthias Jung, Omar Naji, Sven Goossens
*
*/
#include <fstream>
#include <algorithm>
#include <sstream>
#include "CommandAnalysis.h"
#include "CmdScheduler.h"
using namespace Data;
using namespace std;
bool commandSorter(const MemCommand& i, const MemCommand& j)
{
if (i.getTimeInt64() == j.getTimeInt64()) {
return i.getType() == MemCommand::PRE && j.getType() != MemCommand::PRE;
} else {
return i.getTimeInt64() < j.getTimeInt64();
}
}
CommandAnalysis::CommandAnalysis(const int64_t nbrofBanks)
{
// Initializing all counters and variables
clearStats(0);
zero = 0;
bankstate.resize(static_cast<size_t>(nbrofBanks), 0);
last_states.resize(static_cast<size_t>(nbrofBanks));
mem_state = 0;
num_active_banks = 0;
cmd_list.clear();
cached_cmd.clear();
activation_cycle.resize(static_cast<size_t>(nbrofBanks), 0);
}
// function to clear counters
void CommandAnalysis::clearStats(const int64_t timestamp)
{
numberofacts = 0;
numberofpres = 0;
numberofreads = 0;
numberofwrites = 0;
numberofrefs = 0;
f_act_pdns = 0;
s_act_pdns = 0;
f_pre_pdns = 0;
s_pre_pdns = 0;
numberofsrefs = 0;
actcycles = 0;
precycles = 0;
f_act_pdcycles = 0;
s_act_pdcycles = 0;
f_pre_pdcycles = 0;
s_pre_pdcycles = 0;
pup_act_cycles = 0;
pup_pre_cycles = 0;
sref_cycles = 0;
spup_cycles = 0;
sref_ref_act_cycles = 0;
sref_ref_pre_cycles = 0;
spup_ref_act_cycles = 0;
spup_ref_pre_cycles = 0;
idlecycles_act = 0;
idlecycles_pre = 0;
// reset count references to timestamp so that they are moved
// to start of next stats generation
first_act_cycle = timestamp;
last_pre_cycle = timestamp;
pdn_cycle = timestamp;
sref_cycle = timestamp;
end_act_op = timestamp;
end_read_op = timestamp;
end_write_op = timestamp;
latest_act_cycle = -1;
latest_read_cycle = -1;
latest_write_cycle = -1;
if (timestamp == 0) {
// set to -1 at beginning of simulation
latest_pre_cycle = -1;
} else {
// NOTE: reference is adjusted by tRP (PRE delay) when updating counter
// could remove tRP to ensure counter starts at beginning of next block;
// currently simply setting to timestamp for simplicity
latest_pre_cycle = timestamp;
}
}
// function to clear all arrays
void CommandAnalysis::clear()
{
cached_cmd.clear();
cmd_list.clear();
last_states.clear();
bankstate.clear();
}
// Reads through the trace file, identifies the timestamp, command and bank
// If the issued command includes an auto-precharge, adds an explicit
// precharge to a cached command list and computes the precharge offset from the
// issued command timestamp, when the auto-precharge would kick in
void CommandAnalysis::getCommands(const Data::MemorySpecification& memSpec,
std::vector<MemCommand>& list, bool lastupdate)
{
for (size_t i = 0; i < list.size(); ++i) {
MemCommand& cmd = list[i];
MemCommand::cmds cmdType = cmd.getType();
if (cmdType == MemCommand::ACT) {
activation_cycle[cmd.getBank()] = cmd.getTimeInt64();
} else if (cmdType == MemCommand::RDA || cmdType == MemCommand::WRA) {
// Remove auto-precharge flag from command
cmd.setType(cmd.typeWithoutAutoPrechargeFlag());
// Add the auto precharge to the list of cached_cmds
int64_t preTime = max(cmd.getTimeInt64() + cmd.getPrechargeOffset(memSpec, cmdType),
activation_cycle[cmd.getBank()] + memSpec.memTimingSpec.RAS);
list.push_back(MemCommand(MemCommand::PRE, cmd.getBank(), preTime));
}
}
sort(list.begin(), list.end(), commandSorter);
if (lastupdate && list.empty() == false) {
// Add cycles at the end of the list
int64_t t = timeToCompletion(memSpec, list.back().getType()) + list.back().getTimeInt64() - 1;
list.push_back(MemCommand(MemCommand::NOP, 0, t));
}
evaluate(memSpec, list);
} // CommandAnalysis::getCommands
// To get the time of completion of the issued command
// Derived based on JEDEC specifications
int64_t CommandAnalysis::timeToCompletion(const MemorySpecification&
memSpec, MemCommand::cmds type)
{
int64_t offset = 0;
const MemTimingSpec& memTimingSpec = memSpec.memTimingSpec;
const MemArchitectureSpec& memArchSpec = memSpec.memArchSpec;
if (type == MemCommand::RD) {
offset = memTimingSpec.RL +
memTimingSpec.DQSCK + 1 + (memArchSpec.burstLength /
memArchSpec.dataRate);
} else if (type == MemCommand::WR) {
offset = memTimingSpec.WL +
(memArchSpec.burstLength / memArchSpec.dataRate) +
memTimingSpec.WR;
} else if (type == MemCommand::ACT) {
offset = memTimingSpec.RCD;
} else if ((type == MemCommand::PRE) || (type == MemCommand::PREA)) {
offset = memTimingSpec.RP;
}
return offset;
} // CommandAnalysis::timeToCompletion
// Used to analyse a given list of commands and identify command timings
// and memory state transitions
void CommandAnalysis::evaluate(const MemorySpecification& memSpec,
vector<MemCommand>& cmd_list)
{
// for each command identify timestamp, type and bank
for (auto cmd : cmd_list) {
// For command type
int type = cmd.getType();
// For command bank
int bank = static_cast<int>(cmd.getBank());
// Command Issue timestamp in clock cycles (cc)
int64_t timestamp = cmd.getTimeInt64();
if (type == MemCommand::ACT) {
printWarningIfPoweredDown("Command issued while in power-down mode.", type, timestamp, bank);
// If command is ACT - update number of acts, bank state of the
// target bank, first and latest activation cycle and the memory
// state. Update the number of precharged/idle-precharged cycles.
numberofacts++;
if (bankstate[static_cast<size_t>(bank)] == 1) {
printWarning("Bank is already active!", type, timestamp, bank);
}
bankstate[static_cast<size_t>(bank)] = 1;
if (num_active_banks == 0) {
first_act_cycle = timestamp;
precycles += max(zero, timestamp - last_pre_cycle);
idle_pre_update(memSpec, timestamp, latest_pre_cycle);
}
latest_act_cycle = timestamp;
num_active_banks++;
} else if (type == MemCommand::RD) {
printWarningIfPoweredDown("Command issued while in power-down mode.", type, timestamp, bank);
// If command is RD - update number of reads and read cycle. Check
// for active idle cycles (if any).
if (bankstate[static_cast<size_t>(bank)] == 0) {
printWarning("Bank is not active!", type, timestamp, bank);
}
numberofreads++;
idle_act_update(memSpec, latest_read_cycle, latest_write_cycle,
latest_act_cycle, timestamp);
latest_read_cycle = timestamp;
} else if (type == MemCommand::WR) {
printWarningIfPoweredDown("Command issued while in power-down mode.", type, timestamp, bank);
// If command is WR - update number of writes and write cycle. Check
// for active idle cycles (if any).
if (bankstate[static_cast<size_t>(bank)] == 0) {
printWarning("Bank is not active!", type, timestamp, bank);
}
numberofwrites++;
idle_act_update(memSpec, latest_read_cycle, latest_write_cycle,
latest_act_cycle, timestamp);
latest_write_cycle = timestamp;
} else if (type == MemCommand::REF) {
printWarningIfPoweredDown("Command issued while in power-down mode.", type, timestamp, bank);
// If command is REF - update number of refreshes, set bank state of
// all banks to ACT, set the last PRE cycles at RFC-RP cycles from
// timestamp, set the number of active cycles to RFC-RP and check
// for active and precharged cycles and idle active and idle
// precharged cycles before refresh. Change memory state to 0.
printWarningIfActive("One or more banks are active! REF requires all banks to be precharged.", type, timestamp, bank);
numberofrefs++;
idle_pre_update(memSpec, timestamp, latest_pre_cycle);
first_act_cycle = timestamp;
precycles += max(zero, timestamp - last_pre_cycle);
last_pre_cycle = timestamp + memSpec.memTimingSpec.RFC -
memSpec.memTimingSpec.RP;
latest_pre_cycle = last_pre_cycle;
actcycles += memSpec.memTimingSpec.RFC - memSpec.memTimingSpec.RP;
num_active_banks = 0;
for (auto& b : bankstate) {
b = 0;
}
} else if (type == MemCommand::PRE) {
printWarningIfPoweredDown("Command issued while in power-down mode.", type, timestamp, bank);
// If command is explicit PRE - update number of precharges, bank
// state of the target bank and last and latest precharge cycle.
// Calculate the number of active cycles if the memory was in the
// active state before, but there is a state transition to PRE now.
// If not, update the number of precharged cycles and idle cycles.
// Update memory state if needed.
if (bankstate[static_cast<size_t>(bank)] == 1) {
numberofpres++;
}
bankstate[static_cast<size_t>(bank)] = 0;
if (num_active_banks == 1) {
actcycles += max(zero, timestamp - first_act_cycle);
last_pre_cycle = timestamp;
idle_act_update(memSpec, latest_read_cycle, latest_write_cycle,
latest_act_cycle, timestamp);
} else if (num_active_banks == 0) {
precycles += max(zero, timestamp - last_pre_cycle);
idle_pre_update(memSpec, timestamp, latest_pre_cycle);
last_pre_cycle = timestamp;
}
latest_pre_cycle = timestamp;
if (num_active_banks > 0) {
num_active_banks--;
} else {
num_active_banks = 0;
}
} else if (type == MemCommand::PREA) {
printWarningIfPoweredDown("Command issued while in power-down mode.", type, timestamp, bank);
// If command is explicit PREA (precharge all banks) - update
// number of precharges by the number of banks, update the bank
// state of all banks to PRE and set the precharge cycle.
// Calculate the number of active cycles if the memory was in the
// active state before, but there is a state transition to PRE now.
// If not, update the number of precharged cycles and idle cycles.
numberofpres += num_active_banks;
if (num_active_banks > 0) {
actcycles += max(zero, timestamp - first_act_cycle);
idle_act_update(memSpec, latest_read_cycle, latest_write_cycle,
latest_act_cycle, timestamp);
} else if (num_active_banks == 0) {
precycles += max(zero, timestamp - last_pre_cycle);
idle_pre_update(memSpec, timestamp, latest_pre_cycle);
}
latest_pre_cycle = timestamp;
last_pre_cycle = timestamp;
num_active_banks = 0;
for (auto& b : bankstate) {
b = 0;
}
} else if (type == MemCommand::PDN_F_ACT) {
// If command is fast-exit active power-down - update number of
// power-downs, set the power-down cycle and the memory mode to
// fast-exit active power-down. Save states of all the banks from
// the cycle before entering active power-down, to be returned to
// after powering-up. Update active and active idle cycles.
printWarningIfNotActive("All banks are precharged! Incorrect use of Active Power-Down.", type, timestamp, bank);
f_act_pdns++;
last_states = bankstate;
pdn_cycle = timestamp;
actcycles += max(zero, timestamp - first_act_cycle);
idle_act_update(memSpec, latest_read_cycle, latest_write_cycle,
latest_act_cycle, timestamp);
mem_state = CommandAnalysis::MS_PDN_F_ACT;
} else if (type == MemCommand::PDN_S_ACT) {
// If command is slow-exit active power-down - update number of
// power-downs, set the power-down cycle and the memory mode to
// slow-exit active power-down. Save states of all the banks from
// the cycle before entering active power-down, to be returned to
// after powering-up. Update active and active idle cycles.
printWarningIfNotActive("All banks are precharged! Incorrect use of Active Power-Down.", type, timestamp, bank);
s_act_pdns++;
last_states = bankstate;
pdn_cycle = timestamp;
actcycles += max(zero, timestamp - first_act_cycle);
idle_act_update(memSpec, latest_read_cycle, latest_write_cycle,
latest_act_cycle, timestamp);
mem_state = CommandAnalysis::MS_PDN_S_ACT;
} else if (type == MemCommand::PDN_F_PRE) {
// If command is fast-exit precharged power-down - update number of
// power-downs, set the power-down cycle and the memory mode to
// fast-exit precahrged power-down. Update precharged and precharged
// idle cycles.
printWarningIfActive("One or more banks are active! Incorrect use of Precharged Power-Down.", type, timestamp, bank);
f_pre_pdns++;
pdn_cycle = timestamp;
precycles += max(zero, timestamp - last_pre_cycle);
idle_pre_update(memSpec, timestamp, latest_pre_cycle);
mem_state = CommandAnalysis::MS_PDN_F_PRE;
} else if (type == MemCommand::PDN_S_PRE) {
// If command is slow-exit precharged power-down - update number of
// power-downs, set the power-down cycle and the memory mode to
// slow-exit precahrged power-down. Update precharged and precharged
// idle cycles.
printWarningIfActive("One or more banks are active! Incorrect use of Precharged Power-Down.", type, timestamp, bank);
s_pre_pdns++;
pdn_cycle = timestamp;
precycles += max(zero, timestamp - last_pre_cycle);
idle_pre_update(memSpec, timestamp, latest_pre_cycle);
mem_state = CommandAnalysis::MS_PDN_S_PRE;
} else if (type == MemCommand::PUP_ACT) {
// If command is power-up in the active mode - check the power-down
// exit-mode employed (fast or slow), update the number of power-down
// and power-up cycles and the latest and first act cycle. Also, reset
// all the individual bank states to the respective saved states
// before entering power-down.
if (mem_state == CommandAnalysis::MS_PDN_F_ACT) {
f_act_pdcycles += max(zero, timestamp - pdn_cycle);
pup_act_cycles += memSpec.memTimingSpec.XP;
latest_act_cycle = max(timestamp, timestamp +
memSpec.memTimingSpec.XP - memSpec.memTimingSpec.RCD);
} else if (mem_state == CommandAnalysis::MS_PDN_S_ACT) {
s_act_pdcycles += max(zero, timestamp - pdn_cycle);
if (memSpec.memArchSpec.dll == false) {
pup_act_cycles += memSpec.memTimingSpec.XP;
latest_act_cycle = max(timestamp, timestamp +
memSpec.memTimingSpec.XP - memSpec.memTimingSpec.RCD);
} else {
pup_act_cycles += memSpec.memTimingSpec.XPDLL -
memSpec.memTimingSpec.RCD;
latest_act_cycle = max(timestamp, timestamp +
memSpec.memTimingSpec.XPDLL -
(2 * memSpec.memTimingSpec.RCD));
}
} else if (mem_state != CommandAnalysis::MS_PDN_S_ACT || mem_state != CommandAnalysis::MS_PDN_F_ACT) {
cerr << "Incorrect use of Active Power-Up!" << endl;
}
num_active_banks = 0;
mem_state = 0;
bankstate = last_states;
for (auto& a : last_states) {
num_active_banks += static_cast<unsigned int>(a);
}
first_act_cycle = timestamp;
} else if (type == MemCommand::PUP_PRE) {
// If command is power-up in the precharged mode - check the power-down
// exit-mode employed (fast or slow), update the number of power-down
// and power-up cycles and the latest and last pre cycle.
if (mem_state == CommandAnalysis::MS_PDN_F_PRE) {
f_pre_pdcycles += max(zero, timestamp - pdn_cycle);
pup_pre_cycles += memSpec.memTimingSpec.XP;
latest_pre_cycle = max(timestamp, timestamp +
memSpec.memTimingSpec.XP - memSpec.memTimingSpec.RP);
} else if (mem_state == CommandAnalysis::MS_PDN_S_PRE) {
s_pre_pdcycles += max(zero, timestamp - pdn_cycle);
if (memSpec.memArchSpec.dll == false) {
pup_pre_cycles += memSpec.memTimingSpec.XP;
latest_pre_cycle = max(timestamp, timestamp +
memSpec.memTimingSpec.XP - memSpec.memTimingSpec.RP);
} else {
pup_pre_cycles += memSpec.memTimingSpec.XPDLL -
memSpec.memTimingSpec.RCD;
latest_pre_cycle = max(timestamp, timestamp +
memSpec.memTimingSpec.XPDLL - memSpec.memTimingSpec.RCD -
memSpec.memTimingSpec.RP);
}
} else if (mem_state != CommandAnalysis::MS_PDN_S_PRE || mem_state != CommandAnalysis::MS_PDN_F_PRE) {
cerr << "Incorrect use of Precharged Power-Up!" << endl;
}
mem_state = 0;
num_active_banks = 0;
last_pre_cycle = timestamp;
} else if (type == MemCommand::SREN) {
// If command is self-refresh - update number of self-refreshes,
// set memory state to SREF, update precharge and idle precharge
// cycles and set the self-refresh cycle.
printWarningIfActive("One or more banks are active! SREF requires all banks to be precharged.", type, timestamp, bank);
numberofsrefs++;
sref_cycle = timestamp;
precycles += max(zero, timestamp - last_pre_cycle);
idle_pre_update(memSpec, timestamp, latest_pre_cycle);
mem_state = CommandAnalysis::MS_SREF;
} else if (type == MemCommand::SREX) {
// If command is self-refresh exit - update the number of self-refresh
// clock cycles, number of active and precharged auto-refresh clock
// cycles during self-refresh and self-refresh exit based on the number
// of cycles in the self-refresh mode and auto-refresh duration (RFC).
// Set the last and latest precharge cycle accordingly and set the
// memory state to 0.
if (mem_state != CommandAnalysis::MS_SREF) {
cerr << "Incorrect use of Self-Refresh Power-Up!" << endl;
}
if (max(zero, timestamp - sref_cycle) >= memSpec.memTimingSpec.RFC) {
sref_cycles += max(zero, timestamp - sref_cycle
- memSpec.memTimingSpec.RFC);
sref_ref_act_cycles += memSpec.memTimingSpec.RFC -
memSpec.memTimingSpec.RP;
sref_ref_pre_cycles += memSpec.memTimingSpec.RP;
last_pre_cycle = timestamp;
if (memSpec.memArchSpec.dll == false) {
spup_cycles += memSpec.memTimingSpec.XS;
latest_pre_cycle = max(timestamp, timestamp +
memSpec.memTimingSpec.XS - memSpec.memTimingSpec.RP);
} else {
spup_cycles += memSpec.memTimingSpec.XSDLL -
memSpec.memTimingSpec.RCD;
latest_pre_cycle = max(timestamp, timestamp +
memSpec.memTimingSpec.XSDLL - memSpec.memTimingSpec.RCD
- memSpec.memTimingSpec.RP);
}
} else {
int64_t sref_diff = memSpec.memTimingSpec.RFC - memSpec.memTimingSpec.RP;
int64_t sref_pre = max(zero, timestamp - sref_cycle - sref_diff);
int64_t spup_pre = memSpec.memTimingSpec.RP - sref_pre;
int64_t sref_act = max(zero, timestamp - sref_cycle);
int64_t spup_act = memSpec.memTimingSpec.RFC - sref_act;
if (max(zero, timestamp - sref_cycle) >= sref_diff) {
sref_ref_act_cycles += sref_diff;
sref_ref_pre_cycles += sref_pre;
spup_ref_pre_cycles += spup_pre;
last_pre_cycle = timestamp + spup_pre;
if (memSpec.memArchSpec.dll == false) {
spup_cycles += memSpec.memTimingSpec.XS - spup_pre;
latest_pre_cycle = max(timestamp, timestamp +
memSpec.memTimingSpec.XS - spup_pre -
memSpec.memTimingSpec.RP);
} else {
spup_cycles += memSpec.memTimingSpec.XSDLL -
memSpec.memTimingSpec.RCD - spup_pre;
latest_pre_cycle = max(timestamp, timestamp +
memSpec.memTimingSpec.XSDLL - memSpec.memTimingSpec.RCD -
spup_pre - memSpec.memTimingSpec.RP);
}
} else {
sref_ref_act_cycles += sref_act;
spup_ref_act_cycles += spup_act;
spup_ref_pre_cycles += memSpec.memTimingSpec.RP;
last_pre_cycle = timestamp + spup_act + memSpec.memTimingSpec.RP;
if (memSpec.memArchSpec.dll == false) {
spup_cycles += memSpec.memTimingSpec.XS - spup_act -
memSpec.memTimingSpec.RP;
latest_pre_cycle = max(timestamp, timestamp +
memSpec.memTimingSpec.XS - spup_act -
(2 * memSpec.memTimingSpec.RP));
} else {
spup_cycles += memSpec.memTimingSpec.XSDLL -
memSpec.memTimingSpec.RCD - spup_act -
memSpec.memTimingSpec.RP;
latest_pre_cycle = max(timestamp, timestamp +
memSpec.memTimingSpec.XSDLL - memSpec.memTimingSpec.RCD -
spup_act - (2 * memSpec.memTimingSpec.RP));
}
}
}
mem_state = 0;
num_active_banks = 0;
} else if (type == MemCommand::END || type == MemCommand::NOP) {
// May be optionally used at the end of memory trace for better accuracy
// Update all counters based on completion of operations.
if (num_active_banks > 0 && mem_state == 0) {
actcycles += max(zero, timestamp - first_act_cycle);
idle_act_update(memSpec, latest_read_cycle, latest_write_cycle,
latest_act_cycle, timestamp);
} else if (num_active_banks == 0 && mem_state == 0) {
precycles += max(zero, timestamp - last_pre_cycle);
idle_pre_update(memSpec, timestamp, latest_pre_cycle);
} else if (mem_state == CommandAnalysis::MS_PDN_F_ACT) {
f_act_pdcycles += max(zero, timestamp - pdn_cycle);
} else if (mem_state == CommandAnalysis::MS_PDN_S_ACT) {
s_act_pdcycles += max(zero, timestamp - pdn_cycle);
} else if (mem_state == CommandAnalysis::MS_PDN_F_PRE) {
f_pre_pdcycles += max(zero, timestamp - pdn_cycle);
} else if (mem_state == CommandAnalysis::MS_PDN_S_PRE) {
s_pre_pdcycles += max(zero, timestamp - pdn_cycle);
} else if (mem_state == CommandAnalysis::MS_SREF) {
sref_cycles += max(zero, timestamp - sref_cycle);
}
} else {
printWarning("Unknown command given, exiting.", type, timestamp, bank);
exit(-1);
}
}
} // CommandAnalysis::evaluate
// To update idle period information whenever active cycles may be idle
void CommandAnalysis::idle_act_update(const MemorySpecification& memSpec,
int64_t latest_read_cycle, int64_t latest_write_cycle,
int64_t latest_act_cycle, int64_t timestamp)
{
if (latest_read_cycle >= 0) {
end_read_op = latest_read_cycle + timeToCompletion(memSpec,
MemCommand::RD) - 1;
}
if (latest_write_cycle >= 0) {
end_write_op = latest_write_cycle + timeToCompletion(memSpec,
MemCommand::WR) - 1;
}
if (latest_act_cycle >= 0) {
end_act_op = latest_act_cycle + timeToCompletion(memSpec,
MemCommand::ACT) - 1;
}
idlecycles_act += max(zero, timestamp - max(max(end_read_op, end_write_op),
end_act_op));
} // CommandAnalysis::idle_act_update
// To update idle period information whenever precharged cycles may be idle
void CommandAnalysis::idle_pre_update(const MemorySpecification& memSpec,
int64_t timestamp, int64_t latest_pre_cycle)
{
if (latest_pre_cycle > 0) {
idlecycles_pre += max(zero, timestamp - latest_pre_cycle -
memSpec.memTimingSpec.RP);
} else if (latest_pre_cycle == 0) {
idlecycles_pre += max(zero, timestamp - latest_pre_cycle);
}
}
void CommandAnalysis::printWarningIfActive(const string& warning, int type, int64_t timestamp, int bank)
{
if (num_active_banks != 0) {
printWarning(warning, type, timestamp, bank);
}
}
void CommandAnalysis::printWarningIfNotActive(const string& warning, int type, int64_t timestamp, int bank)
{
if (num_active_banks == 0) {
printWarning(warning, type, timestamp, bank);
}
}
void CommandAnalysis::printWarningIfPoweredDown(const string& warning, int type, int64_t timestamp, int bank)
{
if (mem_state != 0) {
printWarning(warning, type, timestamp, bank);
}
}
void CommandAnalysis::printWarning(const string& warning, int type, int64_t timestamp, int bank)
{
cerr << "WARNING: " << warning << endl;
cerr << "Command: " << type << ", Timestamp: " << timestamp <<
", Bank: " << bank << endl;
}
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