1/* 2 * Copyright (c) 2012-2014, TU Delft 3 * Copyright (c) 2012-2014, TU Eindhoven 4 * Copyright (c) 2012-2014, TU Kaiserslautern 5 * All rights reserved. 6 * 7 * Redistribution and use in source and binary forms, with or without 8 * modification, are permitted provided that the following conditions are --- 17 unchanged lines hidden (view full) --- 26 * HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, 27 * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED 28 * TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR 29 * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF 30 * LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING 31 * NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS 32 * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. 33 * |
34 * Authors: Karthik Chandrasekar 35 * Matthias Jung 36 * Omar Naji 37 * Subash Kannoth 38 * Éder F. Zulian 39 * Felipe S. Prado |
40 * 41 */ 42 43#include "MemoryPowerModel.h" 44 45#include <stdint.h> 46 47#include <cmath> // For pow 48#include <iostream> // fmtflags |
49#include <algorithm> |
50 |
51using namespace std; 52using namespace Data; 53 |
54MemoryPowerModel::MemoryPowerModel() 55{ 56 total_cycles = 0; 57 energy.total_energy = 0; 58} 59 |
60// Calculate energy and average power consumption for the given command trace 61 62void MemoryPowerModel::power_calc(const MemorySpecification& memSpec, 63 const CommandAnalysis& c, |
64 int term, 65 const MemBankWiseParams& bwPowerParams) |
66{ 67 const MemTimingSpec& t = memSpec.memTimingSpec; 68 const MemArchitectureSpec& memArchSpec = memSpec.memArchSpec; 69 const MemPowerSpec& mps = memSpec.memPowerSpec; |
70 const int64_t nbrofBanks = memSpec.memArchSpec.nbrOfBanks; |
71 |
72 energy.act_energy_banks.assign(static_cast<size_t>(nbrofBanks), 0.0); 73 energy.pre_energy_banks.assign(static_cast<size_t>(nbrofBanks), 0.0); 74 energy.read_energy_banks.assign(static_cast<size_t>(nbrofBanks), 0.0); 75 energy.write_energy_banks.assign(static_cast<size_t>(nbrofBanks), 0.0); 76 energy.ref_energy_banks.assign(static_cast<size_t>(nbrofBanks), 0.0); 77 energy.refb_energy_banks.assign(static_cast<size_t>(nbrofBanks), 0.0); 78 energy.act_stdby_energy_banks.assign(static_cast<size_t>(nbrofBanks), 0.0); 79 energy.pre_stdby_energy_banks.assign(static_cast<size_t>(nbrofBanks), 0.0); 80 energy.idle_energy_act_banks.assign(static_cast<size_t>(nbrofBanks), 0.0); 81 energy.idle_energy_pre_banks.assign(static_cast<size_t>(nbrofBanks), 0.0); 82 energy.f_act_pd_energy_banks.assign(static_cast<size_t>(nbrofBanks), 0.0); 83 energy.f_pre_pd_energy_banks.assign(static_cast<size_t>(nbrofBanks), 0.0); 84 energy.s_act_pd_energy_banks.assign(static_cast<size_t>(nbrofBanks), 0.0); 85 energy.s_pre_pd_energy_banks.assign(static_cast<size_t>(nbrofBanks), 0.0); 86 energy.ref_energy_banks.assign(static_cast<size_t>(nbrofBanks), 0.0); 87 energy.sref_energy_banks.assign(static_cast<size_t>(nbrofBanks), 0.0); 88 energy.sref_ref_energy_banks.assign(static_cast<size_t>(nbrofBanks), 0.0); 89 energy.sref_ref_act_energy_banks.assign(static_cast<size_t>(nbrofBanks), 0.0); 90 energy.sref_ref_pre_energy_banks.assign(static_cast<size_t>(nbrofBanks), 0.0); 91 energy.spup_energy_banks.assign(static_cast<size_t>(nbrofBanks), 0.0); 92 energy.spup_ref_energy_banks.assign(static_cast<size_t>(nbrofBanks), 0.0); 93 energy.spup_ref_act_energy_banks.assign(static_cast<size_t>(nbrofBanks), 0.0); 94 energy.spup_ref_pre_energy_banks.assign(static_cast<size_t>(nbrofBanks), 0.0); 95 energy.pup_act_energy_banks.assign(static_cast<size_t>(nbrofBanks), 0.0); 96 energy.pup_pre_energy_banks.assign(static_cast<size_t>(nbrofBanks), 0.0); 97 energy.total_energy_banks.assign(static_cast<size_t>(nbrofBanks), 0.0); 98 |
99 energy.act_energy = 0.0; 100 energy.pre_energy = 0.0; 101 energy.read_energy = 0.0; 102 energy.write_energy = 0.0; 103 energy.ref_energy = 0.0; 104 energy.act_stdby_energy = 0.0; 105 energy.pre_stdby_energy = 0.0; 106 energy.idle_energy_act = 0.0; 107 energy.idle_energy_pre = 0.0; |
108 energy.window_energy = 0.0; |
109 energy.f_act_pd_energy = 0.0; 110 energy.f_pre_pd_energy = 0.0; 111 energy.s_act_pd_energy = 0.0; 112 energy.s_pre_pd_energy = 0.0; 113 energy.sref_energy = 0.0; 114 energy.sref_ref_energy = 0.0; 115 energy.sref_ref_act_energy = 0.0; 116 energy.sref_ref_pre_energy = 0.0; --- 24 unchanged lines hidden (view full) --- 141 // 1 DQS pin is associated with every data byte 142 int64_t dqPlusDqsBits = memArchSpec.width + memArchSpec.width / 8; 143 // 1 DQS and 1 DM pin is associated with every data byte 144 int64_t dqPlusDqsPlusMaskBits = memArchSpec.width + memArchSpec.width / 8 + memArchSpec.width / 8; 145 // Size of one clock period for the data bus. 146 double ddrPeriod = t.clkPeriod / static_cast<double>(memArchSpec.dataRate); 147 148 // Read IO power is consumed by each DQ (data) and DQS (data strobe) pin |
149 energy.read_io_energy = calcIoTermEnergy(sum(c.numberofreadsBanks) * memArchSpec.burstLength, |
150 ddrPeriod, 151 power.IO_power, 152 dqPlusDqsBits); 153 154 // Write ODT power is consumed by each DQ (data), DQS (data strobe) and DM |
155 energy.write_term_energy = calcIoTermEnergy(sum(c.numberofwritesBanks) * memArchSpec.burstLength, |
156 ddrPeriod, 157 power.WR_ODT_power, 158 dqPlusDqsPlusMaskBits); 159 160 if (memArchSpec.nbrOfRanks > 1) { 161 // Termination power consumed in the idle rank during reads on the active 162 // rank by each DQ (data) and DQS (data strobe) pin. |
163 energy.read_oterm_energy = calcIoTermEnergy(sum(c.numberofreadsBanks) * memArchSpec.burstLength, |
164 ddrPeriod, 165 power.TermRD_power, 166 dqPlusDqsBits); 167 168 // Termination power consumed in the idle rank during writes on the active 169 // rank by each DQ (data), DQS (data strobe) and DM (data mask) pin. |
170 energy.write_oterm_energy = calcIoTermEnergy(sum(c.numberofwritesBanks) * memArchSpec.burstLength, |
171 ddrPeriod, 172 power.TermWR_power, 173 dqPlusDqsPlusMaskBits); 174 } 175 176 // Sum of all IO and termination energy 177 energy.io_term_energy = energy.read_io_energy + energy.write_term_energy 178 + energy.read_oterm_energy + energy.write_oterm_energy; 179 } 180 |
181 window_cycles = c.actcycles + c.precycles + |
182 c.f_act_pdcycles + c.f_pre_pdcycles + 183 c.s_act_pdcycles + c.s_pre_pdcycles + c.sref_cycles 184 + c.sref_ref_act_cycles + c.sref_ref_pre_cycles + 185 c.spup_ref_act_cycles + c.spup_ref_pre_cycles; 186 187 EnergyDomain vdd0Domain(mps.vdd, t.clkPeriod); 188 |
189 energy.act_energy = vdd0Domain.calcTivEnergy(sum(c.numberofactsBanks) * t.RAS , mps.idd0 - mps.idd3n); 190 energy.pre_energy = vdd0Domain.calcTivEnergy(sum(c.numberofpresBanks) * (t.RC - t.RAS) , mps.idd0 - mps.idd2n); 191 energy.read_energy = vdd0Domain.calcTivEnergy(sum(c.numberofreadsBanks) * burstCc , mps.idd4r - mps.idd3n); 192 energy.write_energy = vdd0Domain.calcTivEnergy(sum(c.numberofwritesBanks) * burstCc , mps.idd4w - mps.idd3n); |
193 energy.ref_energy = vdd0Domain.calcTivEnergy(c.numberofrefs * t.RFC , mps.idd5 - mps.idd3n); 194 energy.pre_stdby_energy = vdd0Domain.calcTivEnergy(c.precycles, mps.idd2n); 195 energy.act_stdby_energy = vdd0Domain.calcTivEnergy(c.actcycles, mps.idd3n); |
196 197 // Using the number of cycles that at least one bank is active here 198 // But the current iddrho is less than idd3n 199 double iddrho = (static_cast<double>(bwPowerParams.bwPowerFactRho) / 100.0) * (mps.idd3n - mps.idd2n) + mps.idd2n; 200 double esharedActStdby = vdd0Domain.calcTivEnergy(c.actcycles, iddrho); 201 // Fixed componenent for PASR 202 double iddsigma = (static_cast<double>(bwPowerParams.bwPowerFactSigma) / 100.0) * mps.idd6; 203 double esharedPASR = vdd0Domain.calcTivEnergy(c.sref_cycles, iddsigma); 204 // ione is Active background current for a single bank. When a single bank is Active 205 //,all the other remainig (B-1) banks will consume a current of iddrho (based on factor Rho) 206 // So to derrive ione we add (B-1)*iddrho to the idd3n and distribute it to each banks. 207 double ione = (mps.idd3n + (iddrho * (static_cast<double>(nbrofBanks - 1)))) / (static_cast<double>(nbrofBanks)); 208 // If memory specification does not provide bank wise refresh current, 209 // approximate it to single bank background current removed from 210 // single bank active current 211 double idd5Blocal = (mps.idd5B == 0.0) ? (mps.idd0 - ione) :(mps.idd5B); 212 // if memory specification does not provide the REFB timing approximate it 213 // to time of ACT + PRE 214 int64_t tRefBlocal = (t.REFB == 0) ? (t.RAS + t.RP) : (t.REFB); 215 216 //Distribution of energy componets to each banks 217 for (unsigned i = 0; i < nbrofBanks; i++) { 218 energy.act_energy_banks[i] = vdd0Domain.calcTivEnergy(c.numberofactsBanks[i] * t.RAS, mps.idd0 - ione); 219 energy.pre_energy_banks[i] = vdd0Domain.calcTivEnergy(c.numberofpresBanks[i] * (t.RP), mps.idd0 - ione); 220 energy.read_energy_banks[i] = vdd0Domain.calcTivEnergy(c.numberofreadsBanks[i] * burstCc, mps.idd4r - mps.idd3n); 221 energy.write_energy_banks[i] = vdd0Domain.calcTivEnergy(c.numberofwritesBanks[i] * burstCc, mps.idd4w - mps.idd3n); 222 energy.ref_energy_banks[i] = vdd0Domain.calcTivEnergy(c.numberofrefs * t.RFC, mps.idd5 - mps.idd3n) / static_cast<double>(nbrofBanks); 223 energy.refb_energy_banks[i] = vdd0Domain.calcTivEnergy(c.numberofrefbBanks[i] * tRefBlocal, idd5Blocal); 224 energy.pre_stdby_energy_banks[i] = vdd0Domain.calcTivEnergy(c.precycles, mps.idd2n) / static_cast<double>(nbrofBanks); 225 energy.act_stdby_energy_banks[i] = vdd0Domain.calcTivEnergy(c.actcyclesBanks[i], (mps.idd3n - iddrho) / static_cast<double>(nbrofBanks)) 226 + esharedActStdby / static_cast<double>(nbrofBanks); 227 energy.idle_energy_act_banks[i] = vdd0Domain.calcTivEnergy(c.idlecycles_act, mps.idd3n) / static_cast<double>(nbrofBanks); 228 energy.idle_energy_pre_banks[i] = vdd0Domain.calcTivEnergy(c.idlecycles_pre, mps.idd2n) / static_cast<double>(nbrofBanks); 229 energy.f_act_pd_energy_banks[i] = vdd0Domain.calcTivEnergy(c.f_act_pdcycles, mps.idd3p1) / static_cast<double>(nbrofBanks); 230 energy.f_pre_pd_energy_banks[i] = vdd0Domain.calcTivEnergy(c.f_pre_pdcycles, mps.idd2p1) / static_cast<double>(nbrofBanks); 231 energy.s_act_pd_energy_banks[i] = vdd0Domain.calcTivEnergy(c.s_act_pdcycles, mps.idd3p0) / static_cast<double>(nbrofBanks); 232 energy.s_pre_pd_energy_banks[i] = vdd0Domain.calcTivEnergy(c.s_pre_pdcycles, mps.idd2p0) / static_cast<double>(nbrofBanks); 233 234 energy.sref_energy_banks[i] = engy_sref_banks(mps.idd6, mps.idd3n, 235 mps.idd5, mps.vdd, 236 static_cast<double>(c.sref_cycles), static_cast<double>(c.sref_ref_act_cycles), 237 static_cast<double>(c.sref_ref_pre_cycles), static_cast<double>(c.spup_ref_act_cycles), 238 static_cast<double>(c.spup_ref_pre_cycles), t.clkPeriod,esharedPASR,bwPowerParams,i,nbrofBanks 239 ); 240 energy.sref_ref_act_energy_banks[i] = vdd0Domain.calcTivEnergy(c.sref_ref_act_cycles, mps.idd3p0) / static_cast<double>(nbrofBanks); 241 energy.sref_ref_pre_energy_banks[i] = vdd0Domain.calcTivEnergy(c.sref_ref_pre_cycles, mps.idd2p0) / static_cast<double>(nbrofBanks); 242 energy.sref_ref_energy_banks[i] = energy.sref_ref_act_energy_banks[i] + energy.sref_ref_pre_energy_banks[i] ;// 243 244 energy.spup_energy_banks[i] = vdd0Domain.calcTivEnergy(c.spup_cycles, mps.idd2n) / static_cast<double>(nbrofBanks); 245 energy.spup_ref_act_energy_banks[i] = vdd0Domain.calcTivEnergy(c.spup_ref_act_cycles, mps.idd3n) / static_cast<double>(nbrofBanks);// 246 energy.spup_ref_pre_energy_banks[i] = vdd0Domain.calcTivEnergy(c.spup_ref_pre_cycles, mps.idd2n) / static_cast<double>(nbrofBanks); 247 energy.spup_ref_energy_banks[i] = ( energy.spup_ref_act_energy + energy.spup_ref_pre_energy ) / static_cast<double>(nbrofBanks); 248 energy.pup_act_energy_banks[i] = vdd0Domain.calcTivEnergy(c.pup_act_cycles, mps.idd3n) / static_cast<double>(nbrofBanks); 249 energy.pup_pre_energy_banks[i] = vdd0Domain.calcTivEnergy(c.pup_pre_cycles, mps.idd2n) / static_cast<double>(nbrofBanks); 250 } 251 |
252 // Idle energy in the active standby clock cycles 253 energy.idle_energy_act = vdd0Domain.calcTivEnergy(c.idlecycles_act, mps.idd3n); 254 // Idle energy in the precharge standby clock cycles 255 energy.idle_energy_pre = vdd0Domain.calcTivEnergy(c.idlecycles_pre, mps.idd2n); 256 // fast-exit active power-down cycles energy 257 energy.f_act_pd_energy = vdd0Domain.calcTivEnergy(c.f_act_pdcycles, mps.idd3p1); 258 // fast-exit precharged power-down cycles energy 259 energy.f_pre_pd_energy = vdd0Domain.calcTivEnergy(c.f_pre_pdcycles, mps.idd2p1); --- 24 unchanged lines hidden (view full) --- 284 // precharged power-up cycles energy - same as precharged standby -- included 285 energy.pup_pre_energy = vdd0Domain.calcTivEnergy(c.pup_pre_cycles, mps.idd2n); 286 287 // similar equations as before to support multiple voltage domains in LPDDR2 288 // and WIDEIO memories 289 if (memArchSpec.twoVoltageDomains) { 290 EnergyDomain vdd2Domain(mps.vdd2, t.clkPeriod); 291 |
292 energy.act_energy += vdd2Domain.calcTivEnergy(sum(c.numberofactsBanks) * t.RAS , mps.idd02 - mps.idd3n2); 293 energy.pre_energy += vdd2Domain.calcTivEnergy(sum(c.numberofpresBanks) * (t.RC - t.RAS) , mps.idd02 - mps.idd2n2); 294 energy.read_energy += vdd2Domain.calcTivEnergy(sum(c.numberofreadsBanks) * burstCc , mps.idd4r2 - mps.idd3n2); 295 energy.write_energy += vdd2Domain.calcTivEnergy(sum(c.numberofwritesBanks) * burstCc , mps.idd4w2 - mps.idd3n2); |
296 energy.ref_energy += vdd2Domain.calcTivEnergy(c.numberofrefs * t.RFC , mps.idd52 - mps.idd3n2); 297 energy.pre_stdby_energy += vdd2Domain.calcTivEnergy(c.precycles, mps.idd2n2); 298 energy.act_stdby_energy += vdd2Domain.calcTivEnergy(c.actcycles, mps.idd3n2); |
299 |
300 // Idle energy in the active standby clock cycles 301 energy.idle_energy_act += vdd2Domain.calcTivEnergy(c.idlecycles_act, mps.idd3n2); 302 // Idle energy in the precharge standby clock cycles 303 energy.idle_energy_pre += vdd2Domain.calcTivEnergy(c.idlecycles_pre, mps.idd2n2); 304 // fast-exit active power-down cycles energy 305 energy.f_act_pd_energy += vdd2Domain.calcTivEnergy(c.f_act_pdcycles, mps.idd3p12); 306 // fast-exit precharged power-down cycles energy 307 energy.f_pre_pd_energy += vdd2Domain.calcTivEnergy(c.f_pre_pdcycles, mps.idd2p12); --- 27 unchanged lines hidden (view full) --- 335 // auto-refresh energy during self-refresh cycles 336 energy.sref_ref_energy = energy.sref_ref_act_energy + energy.sref_ref_pre_energy; 337 338 // auto-refresh energy during self-refresh exit cycles 339 energy.spup_ref_energy = energy.spup_ref_act_energy + energy.spup_ref_pre_energy; 340 341 // adding all energy components for the active rank and all background and idle 342 // energy components for both ranks (in a dual-rank system) |
343 |
344 if (bwPowerParams.bwMode) { 345 // Calculate total energy per bank. 346 for (unsigned i = 0; i < nbrofBanks; i++) { 347 energy.total_energy_banks[i] = energy.act_energy_banks[i] + energy.pre_energy_banks[i] + energy.read_energy_banks[i] 348 + energy.ref_energy_banks[i] + energy.write_energy_banks[i] + energy.refb_energy_banks[i] 349 + static_cast<double>(memArchSpec.nbrOfRanks) * energy.act_stdby_energy_banks[i] 350 + energy.pre_stdby_energy_banks[i] + energy.f_pre_pd_energy_banks[i] + energy.s_act_pd_energy_banks[i] 351 + energy.s_pre_pd_energy_banks[i]+ energy.sref_ref_energy_banks[i] + energy.spup_ref_energy_banks[i]; 352 } 353 // Calculate total energy for all banks. 354 energy.window_energy = sum(energy.total_energy_banks) + energy.io_term_energy; 355 356 } else { 357 energy.window_energy = energy.act_energy + energy.pre_energy + energy.read_energy + energy.write_energy 358 + energy.ref_energy + energy.io_term_energy + sum(energy.refb_energy_banks) 359 + static_cast<double>(memArchSpec.nbrOfRanks) * (energy.act_stdby_energy 360 + energy.pre_stdby_energy + energy.sref_energy + energy.f_act_pd_energy 361 + energy.f_pre_pd_energy + energy.s_act_pd_energy + energy.s_pre_pd_energy 362 + energy.sref_ref_energy + energy.spup_ref_energy); 363 } 364 365 power.window_average_power = energy.window_energy / (static_cast<double>(window_cycles) * t.clkPeriod); 366 367 total_cycles += window_cycles; 368 369 energy.total_energy += energy.window_energy; 370 |
371 // Calculate the average power consumption 372 power.average_power = energy.total_energy / (static_cast<double>(total_cycles) * t.clkPeriod); 373} // MemoryPowerModel::power_calc 374 |
375void MemoryPowerModel::power_print(const MemorySpecification& memSpec, int term, const CommandAnalysis& c, bool bankwiseMode) const |
376{ 377 const MemTimingSpec& memTimingSpec = memSpec.memTimingSpec; 378 const MemArchitectureSpec& memArchSpec = memSpec.memArchSpec; 379 const uint64_t nRanks = static_cast<uint64_t>(memArchSpec.nbrOfRanks); 380 const char eUnit[] = " pJ"; |
381 const int64_t nbrofBanks = memSpec.memArchSpec.nbrOfBanks; 382 double nRanksDouble = static_cast<double>(nRanks); |
383 384 ios_base::fmtflags flags = cout.flags(); 385 streamsize precision = cout.precision(); 386 cout.precision(0); |
387 388 if (bankwiseMode) { 389 cout << endl << "* Bankwise Details:"; 390 for (unsigned i = 0; i < nbrofBanks; i++) { 391 cout << endl << "## @ Bank " << i << fixed 392 << endl << " #ACT commands: " << c.numberofactsBanks[i] 393 << endl << " #RD + #RDA commands: " << c.numberofreadsBanks[i] 394 << endl << " #WR + #WRA commands: " << c.numberofwritesBanks[i] 395 << endl << " #PRE (+ PREA) commands: " << c.numberofpresBanks[i]; 396 } 397 cout << endl; 398 } 399 400 cout << endl << "* Trace Details:" << fixed << endl 401 << endl << "#ACT commands: " << sum(c.numberofactsBanks) 402 << endl << "#RD + #RDA commands: " << sum(c.numberofreadsBanks) 403 << endl << "#WR + #WRA commands: " << sum(c.numberofwritesBanks) |
404 /* #PRE commands (precharge all counts a number of #PRE commands equal to the number of active banks) */ |
405 << endl << "#PRE (+ PREA) commands: " << sum(c.numberofpresBanks) |
406 << endl << "#REF commands: " << c.numberofrefs |
407 << endl << "#REFB commands: " << sum(c.numberofrefbBanks) |
408 << endl << "#Active Cycles: " << c.actcycles 409 << endl << " #Active Idle Cycles: " << c.idlecycles_act 410 << endl << " #Active Power-Up Cycles: " << c.pup_act_cycles 411 << endl << " #Auto-Refresh Active cycles during Self-Refresh Power-Up: " << c.spup_ref_act_cycles 412 << endl << "#Precharged Cycles: " << c.precycles 413 << endl << " #Precharged Idle Cycles: " << c.idlecycles_pre 414 << endl << " #Precharged Power-Up Cycles: " << c.pup_pre_cycles 415 << endl << " #Auto-Refresh Precharged cycles during Self-Refresh Power-Up: " << c.spup_ref_pre_cycles --- 13 unchanged lines hidden (view full) --- 429 << endl << " #Auto-Refresh Precharged cycles during Self-Refresh: " << c.sref_ref_pre_cycles 430 << endl << "#Auto-Refresh Cycles: " << c.numberofrefs * memTimingSpec.RFC 431 << endl << "#Self-Refreshes: " << c.numberofsrefs 432 << endl << "#Self-Refresh Cycles: " << c.sref_cycles 433 << endl << "----------------------------------------" 434 << endl << "Total Trace Length (clock cycles): " << total_cycles 435 << endl << "----------------------------------------" << endl; 436 |
437 if (bankwiseMode) { 438 cout << endl << "* Bankwise Details:"; 439 for (unsigned i = 0; i < nbrofBanks; i++) { 440 cout << endl << "## @ Bank " << i << fixed 441 << endl << " ACT Cmd Energy: " << energy.act_energy_banks[i] << eUnit 442 << endl << " PRE Cmd Energy: " << energy.pre_energy_banks[i] << eUnit 443 << endl << " RD Cmd Energy: " << energy.read_energy_banks[i] << eUnit 444 << endl << " WR Cmd Energy: " << energy.write_energy_banks[i] << eUnit 445 << endl << " Auto-Refresh Energy: " << energy.ref_energy_banks[i] << eUnit 446 << endl << " Bankwise-Refresh Energy: " << energy.refb_energy_banks[i] << eUnit 447 << endl << " ACT Stdby Energy: " << nRanksDouble * energy.act_stdby_energy_banks[i] << eUnit 448 << endl << " PRE Stdby Energy: " << nRanksDouble * energy.pre_stdby_energy_banks[i] << eUnit 449 << endl << " Active Idle Energy: "<< nRanksDouble * energy.idle_energy_act_banks[i] << eUnit 450 << endl << " Precharge Idle Energy: "<< nRanksDouble * energy.idle_energy_pre_banks[i] << eUnit 451 << endl << " Fast-Exit Active Power-Down Energy: "<< nRanksDouble * energy.f_act_pd_energy_banks[i] << eUnit 452 << endl << " Fast-Exit Precharged Power-Down Energy: "<< nRanksDouble * energy.f_pre_pd_energy_banks[i] << eUnit 453 << endl << " Slow-Exit Active Power-Down Energy: "<< nRanksDouble * energy.s_act_pd_energy_banks[i] << eUnit 454 << endl << " Slow-Exit Precharged Power-Down Energy: "<< nRanksDouble * energy.s_pre_pd_energy_banks[i] << eUnit 455 << endl << " Self-Refresh Energy: "<< nRanksDouble * energy.sref_energy_banks[i] << eUnit 456 << endl << " Slow-Exit Active Power-Down Energy during Auto-Refresh cycles in Self-Refresh: "<< nRanksDouble * energy.sref_ref_act_energy_banks[i] << eUnit 457 << endl << " Slow-Exit Precharged Power-Down Energy during Auto-Refresh cycles in Self-Refresh: " << nRanksDouble * energy.sref_ref_pre_energy_banks[i] << eUnit 458 << endl << " Self-Refresh Power-Up Energy: "<< nRanksDouble * energy.spup_energy_banks[i] << eUnit 459 << endl << " Active Stdby Energy during Auto-Refresh cycles in Self-Refresh Power-Up: "<< nRanksDouble * energy.spup_ref_act_energy_banks[i] << eUnit 460 << endl << " Precharge Stdby Energy during Auto-Refresh cycles in Self-Refresh Power-Up: "<< nRanksDouble * energy.spup_ref_pre_energy_banks[i] << eUnit 461 << endl << " Active Power-Up Energy: "<< nRanksDouble * energy.pup_act_energy_banks[i] << eUnit 462 << endl << " Precharged Power-Up Energy: "<< nRanksDouble * energy.pup_pre_energy_banks[i] << eUnit 463 << endl << " Total Energy: "<< energy.total_energy_banks[i] << eUnit 464 << endl; 465 } 466 cout << endl; 467 } 468 |
469 cout.precision(2); 470 cout << endl << "* Trace Power and Energy Estimates:" << endl 471 << endl << "ACT Cmd Energy: " << energy.act_energy << eUnit 472 << endl << "PRE Cmd Energy: " << energy.pre_energy << eUnit 473 << endl << "RD Cmd Energy: " << energy.read_energy << eUnit 474 << endl << "WR Cmd Energy: " << energy.write_energy << eUnit; 475 476 if (term) { |
477 cout << endl << "RD I/O Energy: " << energy.read_io_energy << eUnit << endl; |
478 // No Termination for LPDDR/2/3 and DDR memories 479 if (memSpec.memArchSpec.termination) { 480 cout << "WR Termination Energy: " << energy.write_term_energy << eUnit << endl; 481 } 482 483 if (nRanks > 1 && memSpec.memArchSpec.termination) { 484 cout << "RD Termination Energy (Idle rank): " << energy.read_oterm_energy << eUnit 485 << endl << "WR Termination Energy (Idle rank): " << energy.write_oterm_energy << eUnit << endl; 486 } 487 } 488 |
489 cout << "ACT Stdby Energy: " << nRanksDouble * energy.act_stdby_energy << eUnit 490 << endl << " Active Idle Energy: " << nRanksDouble * energy.idle_energy_act << eUnit 491 << endl << " Active Power-Up Energy: " << nRanksDouble * energy.pup_act_energy << eUnit 492 << endl << " Active Stdby Energy during Auto-Refresh cycles in Self-Refresh Power-Up: " << nRanksDouble * energy.spup_ref_act_energy << eUnit 493 << endl << "PRE Stdby Energy: " << nRanksDouble * energy.pre_stdby_energy << eUnit 494 << endl << " Precharge Idle Energy: " << nRanksDouble * energy.idle_energy_pre << eUnit 495 << endl << " Precharged Power-Up Energy: " << nRanksDouble * energy.pup_pre_energy << eUnit 496 << endl << " Precharge Stdby Energy during Auto-Refresh cycles in Self-Refresh Power-Up: " << nRanksDouble * energy.spup_ref_pre_energy << eUnit 497 << endl << " Self-Refresh Power-Up Energy: " << nRanksDouble * energy.spup_energy << eUnit 498 << endl << "Total Idle Energy (Active + Precharged): " << nRanksDouble * (energy.idle_energy_act + energy.idle_energy_pre) << eUnit 499 << endl << "Total Power-Down Energy: " << nRanksDouble * (energy.f_act_pd_energy + energy.f_pre_pd_energy + energy.s_act_pd_energy + energy.s_pre_pd_energy) << eUnit 500 << endl << " Fast-Exit Active Power-Down Energy: " << nRanksDouble * energy.f_act_pd_energy << eUnit 501 << endl << " Slow-Exit Active Power-Down Energy: " << nRanksDouble * energy.s_act_pd_energy << eUnit 502 << endl << " Slow-Exit Active Power-Down Energy during Auto-Refresh cycles in Self-Refresh: " << nRanksDouble * energy.sref_ref_act_energy << eUnit 503 << endl << " Fast-Exit Precharged Power-Down Energy: " << nRanksDouble * energy.f_pre_pd_energy << eUnit 504 << endl << " Slow-Exit Precharged Power-Down Energy: " << nRanksDouble * energy.s_pre_pd_energy << eUnit 505 << endl << " Slow-Exit Precharged Power-Down Energy during Auto-Refresh cycles in Self-Refresh: " << nRanksDouble * energy.sref_ref_pre_energy << eUnit 506 << endl << "Auto-Refresh Energy: " << energy.ref_energy << eUnit |
507 << endl << "Bankwise-Refresh Energy: " << sum(energy.refb_energy_banks) << eUnit |
508 << endl << "Self-Refresh Energy: " << nRanksDouble * energy.sref_energy << eUnit 509 << endl << "----------------------------------------" 510 << endl << "Total Trace Energy: " << energy.total_energy << eUnit 511 << endl << "Average Power: " << power.average_power << " mW" 512 << endl << "----------------------------------------" << endl; 513 514 cout.flags(flags); 515 cout.precision(precision); --- 8 unchanged lines hidden (view full) --- 524 double sref_energy; 525 526 sref_energy = ((idd6 * sref_cycles) + ((idd5 - idd3n) * (sref_ref_act_cycles 527 + spup_ref_act_cycles + sref_ref_pre_cycles + spup_ref_pre_cycles))) 528 * vdd * clk; 529 return sref_energy; 530} 531 |
532// Self-refresh active energy estimation per banks 533double MemoryPowerModel::engy_sref_banks(double idd6, double idd3n, double idd5, 534 double vdd, double sref_cycles, double sref_ref_act_cycles, 535 double sref_ref_pre_cycles, double spup_ref_act_cycles, 536 double spup_ref_pre_cycles, double clk, 537 double esharedPASR, const MemBankWiseParams& bwPowerParams, 538 unsigned bnkIdx, int64_t nbrofBanks) 539{ 540 // Bankwise Self-refresh energy 541 double sref_energy_banks; 542 // Dynamic componenents for PASR energy varying based on PASR mode 543 double iddsigmaDynBanks; 544 double pasr_energy_dyn; 545 // This component is distributed among all banks 546 double sref_energy_shared; 547 //Is PASR Active 548 if (bwPowerParams.flgPASR){ 549 sref_energy_shared = (((idd5 - idd3n) * (sref_ref_act_cycles 550 + spup_ref_act_cycles + sref_ref_pre_cycles + spup_ref_pre_cycles)) * vdd * clk) 551 / static_cast<double>(nbrofBanks); 552 //if the bank is active under current PASR mode 553 if (bwPowerParams.isBankActiveInPasr(bnkIdx)){ 554 // Distribute the sref energy to the active banks 555 iddsigmaDynBanks = (static_cast<double>(100 - bwPowerParams.bwPowerFactSigma) / (100.0 * static_cast<double>(nbrofBanks))) * idd6; 556 pasr_energy_dyn = vdd * iddsigmaDynBanks * sref_cycles; 557 // Add the static components 558 sref_energy_banks = sref_energy_shared + pasr_energy_dyn + (esharedPASR /static_cast<double>(nbrofBanks)); 559 560 }else{ 561 sref_energy_banks = (esharedPASR /static_cast<double>(nbrofBanks)); 562 } 563 } 564 //When PASR is not active total all the banks are in Self-Refresh. Thus total Self-Refresh energy is distributed across all banks 565 else{ 566 567 568 sref_energy_banks = (((idd6 * sref_cycles) + ((idd5 - idd3n) * (sref_ref_act_cycles 569 + spup_ref_act_cycles + sref_ref_pre_cycles + spup_ref_pre_cycles))) 570 * vdd * clk) 571 / static_cast<double>(nbrofBanks); 572 } 573 return sref_energy_banks; 574} 575 576 |
577// IO and Termination power calculation based on Micron Power Calculators 578// Absolute power measures are obtained from Micron Power Calculator (mentioned in mW) 579void MemoryPowerModel::io_term_power(const MemorySpecification& memSpec) 580{ 581 const MemTimingSpec& memTimingSpec = memSpec.memTimingSpec; 582 const MemArchitectureSpec& memArchSpec = memSpec.memArchSpec; 583 const MemPowerSpec& memPowerSpec = memSpec.memPowerSpec; 584 --- 17 unchanged lines hidden (view full) --- 602 return static_cast<double>(cycles) * period * power * static_cast<double>(numBits); 603} 604 605// time (t) * current (I) * voltage (V) energy calculation 606double EnergyDomain::calcTivEnergy(int64_t cycles, double current) const 607{ 608 return static_cast<double>(cycles) * clkPeriod * current * voltage; 609} |
610 |