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/*
* Copyright (c) 2014 ARM Limited
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#include "mem/drampower.hh"
#include "base/intmath.hh"
#include "sim/core.hh"
namespace gem5
{
DRAMPower::DRAMPower(const DRAMInterfaceParams &p, bool include_io) :
powerlib(libDRAMPower(getMemSpec(p), include_io))
{
}
Data::MemArchitectureSpec
DRAMPower::getArchParams(const DRAMInterfaceParams &p)
{
Data::MemArchitectureSpec archSpec;
archSpec.burstLength = p.burst_length;
archSpec.nbrOfBanks = p.banks_per_rank;
// One DRAMPower instance per rank, hence set this to 1
archSpec.nbrOfRanks = 1;
archSpec.dataRate = p.beats_per_clock;
// For now we can ignore the number of columns and rows as they
// are not used in the power calculation.
archSpec.nbrOfColumns = 0;
archSpec.nbrOfRows = 0;
archSpec.width = p.device_bus_width;
archSpec.nbrOfBankGroups = p.bank_groups_per_rank;
archSpec.dll = p.dll;
archSpec.twoVoltageDomains = hasTwoVDD(p);
// Keep this disabled for now until the model is firmed up.
archSpec.termination = false;
return archSpec;
}
Data::MemTimingSpec
DRAMPower::getTimingParams(const DRAMInterfaceParams &p)
{
// Set the values that are used for power calculations and ignore
// the ones only used by the controller functionality in DRAMPower
// All DRAMPower timings are in clock cycles
Data::MemTimingSpec timingSpec;
timingSpec.RC = divCeil((p.tRAS + p.tRP), p.tCK);
timingSpec.RCD = divCeil(p.tRCD, p.tCK);
timingSpec.RL = divCeil(p.tCL, p.tCK);
timingSpec.RP = divCeil(p.tRP, p.tCK);
timingSpec.RFC = divCeil(p.tRFC, p.tCK);
timingSpec.RAS = divCeil(p.tRAS, p.tCK);
// Write latency is read latency - 1 cycle
// Source: B.Jacob Memory Systems Cache, DRAM, Disk
timingSpec.WL = timingSpec.RL - 1;
timingSpec.DQSCK = 0; // ignore for now
timingSpec.RTP = divCeil(p.tRTP, p.tCK);
timingSpec.WR = divCeil(p.tWR, p.tCK);
timingSpec.XP = divCeil(p.tXP, p.tCK);
timingSpec.XPDLL = divCeil(p.tXPDLL, p.tCK);
timingSpec.XS = divCeil(p.tXS, p.tCK);
timingSpec.XSDLL = divCeil(p.tXSDLL, p.tCK);
// Clock period in ns
timingSpec.clkPeriod = (p.tCK / (double)(sim_clock::as_int::ns));
assert(timingSpec.clkPeriod != 0);
timingSpec.clkMhz = (1 / timingSpec.clkPeriod) * 1000;
return timingSpec;
}
Data::MemPowerSpec
DRAMPower::getPowerParams(const DRAMInterfaceParams &p)
{
// All DRAMPower currents are in mA
Data::MemPowerSpec powerSpec;
powerSpec.idd0 = p.IDD0 * 1000;
powerSpec.idd02 = p.IDD02 * 1000;
powerSpec.idd2p0 = p.IDD2P0 * 1000;
powerSpec.idd2p02 = p.IDD2P02 * 1000;
powerSpec.idd2p1 = p.IDD2P1 * 1000;
powerSpec.idd2p12 = p.IDD2P12 * 1000;
powerSpec.idd2n = p.IDD2N * 1000;
powerSpec.idd2n2 = p.IDD2N2 * 1000;
powerSpec.idd3p0 = p.IDD3P0 * 1000;
powerSpec.idd3p02 = p.IDD3P02 * 1000;
powerSpec.idd3p1 = p.IDD3P1 * 1000;
powerSpec.idd3p12 = p.IDD3P12 * 1000;
powerSpec.idd3n = p.IDD3N * 1000;
powerSpec.idd3n2 = p.IDD3N2 * 1000;
powerSpec.idd4r = p.IDD4R * 1000;
powerSpec.idd4r2 = p.IDD4R2 * 1000;
powerSpec.idd4w = p.IDD4W * 1000;
powerSpec.idd4w2 = p.IDD4W2 * 1000;
powerSpec.idd5 = p.IDD5 * 1000;
powerSpec.idd52 = p.IDD52 * 1000;
powerSpec.idd6 = p.IDD6 * 1000;
powerSpec.idd62 = p.IDD62 * 1000;
powerSpec.vdd = p.VDD;
powerSpec.vdd2 = p.VDD2;
return powerSpec;
}
Data::MemorySpecification
DRAMPower::getMemSpec(const DRAMInterfaceParams &p)
{
Data::MemorySpecification memSpec;
memSpec.memArchSpec = getArchParams(p);
memSpec.memTimingSpec = getTimingParams(p);
memSpec.memPowerSpec = getPowerParams(p);
return memSpec;
}
bool
DRAMPower::hasTwoVDD(const DRAMInterfaceParams &p)
{
return p.VDD2 == 0 ? false : true;
}
uint8_t
DRAMPower::getDataRate(const DRAMInterfaceParams &p)
{
uint32_t burst_cycles = divCeil(p.tBURST_MAX, p.tCK);
uint8_t data_rate = p.burst_length / burst_cycles;
// 4 for GDDR5
if (data_rate != 1 && data_rate != 2 && data_rate != 4 && data_rate != 8)
fatal("Got unexpected data rate %d, should be 1 or 2 or 4 or 8\n");
return data_rate;
}
} // namespace gem5