1 /* 2 * Copyright (C) 2015 The Android Open Source Project 3 * 4 * Licensed under the Apache License, Version 2.0 (the "License"); 5 * you may not use this file except in compliance with the License. 6 * You may obtain a copy of the License at 7 * 8 * http://www.apache.org/licenses/LICENSE-2.0 9 * 10 * Unless required by applicable law or agreed to in writing, software 11 * distributed under the License is distributed on an "AS IS" BASIS, 12 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. 13 * See the License for the specific language governing permissions and 14 * limitations under the License. 15 */ 16 package com.android.internal.os; 17 18 import android.os.BatteryConsumer; 19 import android.os.BatteryStats; 20 import android.os.BatteryUsageStats; 21 import android.os.BatteryUsageStatsQuery; 22 import android.os.UidBatteryConsumer; 23 import android.util.ArrayMap; 24 import android.util.Log; 25 import android.util.SparseArray; 26 27 import java.util.Arrays; 28 29 public class CpuPowerCalculator extends PowerCalculator { 30 private static final String TAG = "CpuPowerCalculator"; 31 private static final boolean DEBUG = PowerCalculator.DEBUG; 32 private static final BatteryConsumer.Key[] UNINITIALIZED_KEYS = new BatteryConsumer.Key[0]; 33 private final int mNumCpuClusters; 34 35 // Time-in-state based CPU power estimation model computes the estimated power 36 // by adding up three components: 37 // - CPU Active power: the constant amount of charge consumed by the CPU when it is on 38 // - Per Cluster power: the additional amount of charge consumed by a CPU cluster 39 // when it is running 40 // - Per frequency power: the additional amount of charge caused by dynamic frequency scaling 41 42 private final UsageBasedPowerEstimator mCpuActivePowerEstimator; 43 // One estimator per cluster 44 private final UsageBasedPowerEstimator[] mPerClusterPowerEstimators; 45 // Multiple estimators per cluster: one per available scaling frequency. Note that different 46 // clusters have different sets of frequencies and corresponding power consumption averages. 47 private final UsageBasedPowerEstimator[][] mPerCpuFreqPowerEstimatorsByCluster; 48 // Flattened array of estimators across clusters 49 private final UsageBasedPowerEstimator[] mPerCpuFreqPowerEstimators; 50 51 private static class Result { 52 public long durationMs; 53 public double powerMah; 54 public long durationFgMs; 55 public String packageWithHighestDrain; 56 public double[] perProcStatePowerMah; 57 public long[] cpuFreqTimes; 58 } 59 CpuPowerCalculator(PowerProfile profile)60 public CpuPowerCalculator(PowerProfile profile) { 61 mNumCpuClusters = profile.getNumCpuClusters(); 62 63 mCpuActivePowerEstimator = new UsageBasedPowerEstimator( 64 profile.getAveragePower(PowerProfile.POWER_CPU_ACTIVE)); 65 66 mPerClusterPowerEstimators = new UsageBasedPowerEstimator[mNumCpuClusters]; 67 for (int cluster = 0; cluster < mNumCpuClusters; cluster++) { 68 mPerClusterPowerEstimators[cluster] = new UsageBasedPowerEstimator( 69 profile.getAveragePowerForCpuCluster(cluster)); 70 } 71 72 int freqCount = 0; 73 for (int cluster = 0; cluster < mNumCpuClusters; cluster++) { 74 freqCount += profile.getNumSpeedStepsInCpuCluster(cluster); 75 } 76 77 mPerCpuFreqPowerEstimatorsByCluster = new UsageBasedPowerEstimator[mNumCpuClusters][]; 78 mPerCpuFreqPowerEstimators = new UsageBasedPowerEstimator[freqCount]; 79 int index = 0; 80 for (int cluster = 0; cluster < mNumCpuClusters; cluster++) { 81 final int speedsForCluster = profile.getNumSpeedStepsInCpuCluster(cluster); 82 mPerCpuFreqPowerEstimatorsByCluster[cluster] = 83 new UsageBasedPowerEstimator[speedsForCluster]; 84 for (int speed = 0; speed < speedsForCluster; speed++) { 85 final UsageBasedPowerEstimator estimator = new UsageBasedPowerEstimator( 86 profile.getAveragePowerForCpuCore(cluster, speed)); 87 mPerCpuFreqPowerEstimatorsByCluster[cluster][speed] = estimator; 88 mPerCpuFreqPowerEstimators[index++] = estimator; 89 } 90 } 91 } 92 93 @Override isPowerComponentSupported(@atteryConsumer.PowerComponent int powerComponent)94 public boolean isPowerComponentSupported(@BatteryConsumer.PowerComponent int powerComponent) { 95 return powerComponent == BatteryConsumer.POWER_COMPONENT_CPU; 96 } 97 98 @Override calculate(BatteryUsageStats.Builder builder, BatteryStats batteryStats, long rawRealtimeUs, long rawUptimeUs, BatteryUsageStatsQuery query)99 public void calculate(BatteryUsageStats.Builder builder, BatteryStats batteryStats, 100 long rawRealtimeUs, long rawUptimeUs, BatteryUsageStatsQuery query) { 101 double totalPowerMah = 0; 102 103 BatteryConsumer.Key[] keys = UNINITIALIZED_KEYS; 104 Result result = new Result(); 105 if (query.isProcessStateDataNeeded()) { 106 result.cpuFreqTimes = new long[batteryStats.getCpuFreqCount()]; 107 } 108 final SparseArray<UidBatteryConsumer.Builder> uidBatteryConsumerBuilders = 109 builder.getUidBatteryConsumerBuilders(); 110 for (int i = uidBatteryConsumerBuilders.size() - 1; i >= 0; i--) { 111 final UidBatteryConsumer.Builder app = uidBatteryConsumerBuilders.valueAt(i); 112 if (keys == UNINITIALIZED_KEYS) { 113 if (query.isProcessStateDataNeeded()) { 114 keys = app.getKeys(BatteryConsumer.POWER_COMPONENT_CPU); 115 } else { 116 keys = null; 117 } 118 } 119 calculateApp(app, app.getBatteryStatsUid(), query, result, keys); 120 if (!app.isVirtualUid()) { 121 totalPowerMah += result.powerMah; 122 } 123 } 124 125 final long consumptionUC = batteryStats.getCpuMeasuredBatteryConsumptionUC(); 126 final int powerModel = getPowerModel(consumptionUC, query); 127 128 builder.getAggregateBatteryConsumerBuilder( 129 BatteryUsageStats.AGGREGATE_BATTERY_CONSUMER_SCOPE_ALL_APPS) 130 .setConsumedPower(BatteryConsumer.POWER_COMPONENT_CPU, totalPowerMah); 131 builder.getAggregateBatteryConsumerBuilder( 132 BatteryUsageStats.AGGREGATE_BATTERY_CONSUMER_SCOPE_DEVICE) 133 .setConsumedPower(BatteryConsumer.POWER_COMPONENT_CPU, 134 powerModel == BatteryConsumer.POWER_MODEL_MEASURED_ENERGY 135 ? uCtoMah(consumptionUC) : totalPowerMah, powerModel); 136 } 137 calculateApp(UidBatteryConsumer.Builder app, BatteryStats.Uid u, BatteryUsageStatsQuery query, Result result, BatteryConsumer.Key[] keys)138 private void calculateApp(UidBatteryConsumer.Builder app, BatteryStats.Uid u, 139 BatteryUsageStatsQuery query, Result result, BatteryConsumer.Key[] keys) { 140 final long consumptionUC = u.getCpuMeasuredBatteryConsumptionUC(); 141 final int powerModel = getPowerModel(consumptionUC, query); 142 calculatePowerAndDuration(u, powerModel, consumptionUC, BatteryStats.STATS_SINCE_CHARGED, 143 result); 144 145 app.setConsumedPower(BatteryConsumer.POWER_COMPONENT_CPU, result.powerMah, powerModel) 146 .setUsageDurationMillis(BatteryConsumer.POWER_COMPONENT_CPU, result.durationMs) 147 .setPackageWithHighestDrain(result.packageWithHighestDrain); 148 149 if (query.isProcessStateDataNeeded() && keys != null) { 150 switch (powerModel) { 151 case BatteryConsumer.POWER_MODEL_MEASURED_ENERGY: 152 calculateMeasuredPowerPerProcessState(app, u, keys); 153 break; 154 case BatteryConsumer.POWER_MODEL_POWER_PROFILE: 155 calculateModeledPowerPerProcessState(app, u, keys, result); 156 break; 157 } 158 } 159 } 160 calculateMeasuredPowerPerProcessState(UidBatteryConsumer.Builder app, BatteryStats.Uid u, BatteryConsumer.Key[] keys)161 private void calculateMeasuredPowerPerProcessState(UidBatteryConsumer.Builder app, 162 BatteryStats.Uid u, BatteryConsumer.Key[] keys) { 163 for (BatteryConsumer.Key key : keys) { 164 // The key for PROCESS_STATE_UNSPECIFIED aka PROCESS_STATE_ANY has already been 165 // populated with the full energy across all states. We don't want to override it with 166 // the energy for "other" states, which excludes the tracked states like 167 // foreground, background etc. 168 if (key.processState == BatteryConsumer.PROCESS_STATE_UNSPECIFIED) { 169 continue; 170 } 171 172 final long consumptionUC = u.getCpuMeasuredBatteryConsumptionUC(key.processState); 173 if (consumptionUC != 0) { 174 app.setConsumedPower(key, uCtoMah(consumptionUC), 175 BatteryConsumer.POWER_MODEL_MEASURED_ENERGY); 176 } 177 } 178 } 179 calculateModeledPowerPerProcessState(UidBatteryConsumer.Builder app, BatteryStats.Uid u, BatteryConsumer.Key[] keys, Result result)180 private void calculateModeledPowerPerProcessState(UidBatteryConsumer.Builder app, 181 BatteryStats.Uid u, BatteryConsumer.Key[] keys, Result result) { 182 if (result.perProcStatePowerMah == null) { 183 result.perProcStatePowerMah = new double[BatteryConsumer.PROCESS_STATE_COUNT]; 184 } else { 185 Arrays.fill(result.perProcStatePowerMah, 0); 186 } 187 188 for (int uidProcState = 0; uidProcState < BatteryStats.Uid.NUM_PROCESS_STATE; 189 uidProcState++) { 190 @BatteryConsumer.ProcessState int procState = 191 BatteryStats.mapUidProcessStateToBatteryConsumerProcessState(uidProcState); 192 if (procState == BatteryConsumer.PROCESS_STATE_UNSPECIFIED) { 193 continue; 194 } 195 196 // TODO(b/191921016): use per-state CPU cluster times 197 final long[] cpuClusterTimes = null; 198 199 boolean hasCpuFreqTimes = u.getCpuFreqTimes(result.cpuFreqTimes, uidProcState); 200 if (cpuClusterTimes != null || hasCpuFreqTimes) { 201 result.perProcStatePowerMah[procState] += calculateUidModeledPowerMah(u, 202 0, cpuClusterTimes, result.cpuFreqTimes); 203 } 204 } 205 206 for (BatteryConsumer.Key key : keys) { 207 if (key.processState == BatteryConsumer.PROCESS_STATE_UNSPECIFIED) { 208 continue; 209 } 210 211 final long cpuActiveTime = u.getCpuActiveTime(key.processState); 212 213 double powerMah = result.perProcStatePowerMah[key.processState]; 214 powerMah += mCpuActivePowerEstimator.calculatePower(cpuActiveTime); 215 app.setConsumedPower(key, powerMah, BatteryConsumer.POWER_MODEL_POWER_PROFILE) 216 .setUsageDurationMillis(key, cpuActiveTime); 217 } 218 } 219 calculatePowerAndDuration(BatteryStats.Uid u, @BatteryConsumer.PowerModel int powerModel, long consumptionUC, int statsType, Result result)220 private void calculatePowerAndDuration(BatteryStats.Uid u, 221 @BatteryConsumer.PowerModel int powerModel, long consumptionUC, int statsType, 222 Result result) { 223 long durationMs = (u.getUserCpuTimeUs(statsType) + u.getSystemCpuTimeUs(statsType)) / 1000; 224 225 final double powerMah; 226 switch (powerModel) { 227 case BatteryConsumer.POWER_MODEL_MEASURED_ENERGY: 228 powerMah = uCtoMah(consumptionUC); 229 break; 230 case BatteryConsumer.POWER_MODEL_POWER_PROFILE: 231 default: 232 powerMah = calculateUidModeledPowerMah(u, statsType); 233 break; 234 } 235 236 if (DEBUG && (durationMs != 0 || powerMah != 0)) { 237 Log.d(TAG, "UID " + u.getUid() + ": CPU time=" + durationMs + " ms power=" 238 + BatteryStats.formatCharge(powerMah)); 239 } 240 241 // Keep track of the package with highest drain. 242 double highestDrain = 0; 243 String packageWithHighestDrain = null; 244 long durationFgMs = 0; 245 final ArrayMap<String, ? extends BatteryStats.Uid.Proc> processStats = u.getProcessStats(); 246 final int processStatsCount = processStats.size(); 247 for (int i = 0; i < processStatsCount; i++) { 248 final BatteryStats.Uid.Proc ps = processStats.valueAt(i); 249 final String processName = processStats.keyAt(i); 250 durationFgMs += ps.getForegroundTime(statsType); 251 252 final long costValue = ps.getUserTime(statsType) + ps.getSystemTime(statsType) 253 + ps.getForegroundTime(statsType); 254 255 // Each App can have multiple packages and with multiple running processes. 256 // Keep track of the package who's process has the highest drain. 257 if (packageWithHighestDrain == null || packageWithHighestDrain.startsWith("*")) { 258 highestDrain = costValue; 259 packageWithHighestDrain = processName; 260 } else if (highestDrain < costValue && !processName.startsWith("*")) { 261 highestDrain = costValue; 262 packageWithHighestDrain = processName; 263 } 264 } 265 266 // Ensure that the CPU times make sense. 267 if (durationFgMs > durationMs) { 268 if (DEBUG && durationFgMs > durationMs + 10000) { 269 Log.d(TAG, "WARNING! Cputime is more than 10 seconds behind Foreground time"); 270 } 271 272 // Statistics may not have been gathered yet. 273 durationMs = durationFgMs; 274 } 275 276 result.durationMs = durationMs; 277 result.durationFgMs = durationFgMs; 278 result.powerMah = powerMah; 279 result.packageWithHighestDrain = packageWithHighestDrain; 280 } 281 282 /** 283 * Calculates CPU power consumed by the specified app, using the PowerProfile model. 284 */ calculateUidModeledPowerMah(BatteryStats.Uid u, int statsType)285 public double calculateUidModeledPowerMah(BatteryStats.Uid u, int statsType) { 286 return calculateUidModeledPowerMah(u, u.getCpuActiveTime(), u.getCpuClusterTimes(), 287 u.getCpuFreqTimes(statsType)); 288 } 289 calculateUidModeledPowerMah(BatteryStats.Uid u, long cpuActiveTime, long[] cpuClusterTimes, long[] cpuFreqTimes)290 private double calculateUidModeledPowerMah(BatteryStats.Uid u, long cpuActiveTime, 291 long[] cpuClusterTimes, long[] cpuFreqTimes) { 292 // Constant battery drain when CPU is active 293 double powerMah = calculateActiveCpuPowerMah(cpuActiveTime); 294 295 // Additional per-cluster battery drain 296 if (cpuClusterTimes != null) { 297 if (cpuClusterTimes.length == mNumCpuClusters) { 298 for (int cluster = 0; cluster < mNumCpuClusters; cluster++) { 299 final double power = mPerClusterPowerEstimators[cluster] 300 .calculatePower(cpuClusterTimes[cluster]); 301 powerMah += power; 302 if (DEBUG) { 303 Log.d(TAG, "UID " + u.getUid() + ": CPU cluster #" + cluster 304 + " clusterTimeMs=" + cpuClusterTimes[cluster] 305 + " power=" + BatteryStats.formatCharge(power)); 306 } 307 } 308 } else { 309 Log.w(TAG, "UID " + u.getUid() + " CPU cluster # mismatch: Power Profile # " 310 + mNumCpuClusters + " actual # " + cpuClusterTimes.length); 311 } 312 } 313 314 if (cpuFreqTimes != null) { 315 if (cpuFreqTimes.length == mPerCpuFreqPowerEstimators.length) { 316 for (int i = 0; i < cpuFreqTimes.length; i++) { 317 powerMah += mPerCpuFreqPowerEstimators[i].calculatePower(cpuFreqTimes[i]); 318 } 319 } else { 320 Log.w(TAG, "UID " + u.getUid() + " CPU freq # mismatch: Power Profile # " 321 + mPerCpuFreqPowerEstimators.length + " actual # " + cpuFreqTimes.length); 322 } 323 } 324 325 return powerMah; 326 } 327 328 /** 329 * Calculates active CPU power consumption. 330 * 331 * @param durationsMs duration of CPU usage. 332 * @return a double in milliamp-hours of estimated active CPU power consumption. 333 */ calculateActiveCpuPowerMah(long durationsMs)334 public double calculateActiveCpuPowerMah(long durationsMs) { 335 return mCpuActivePowerEstimator.calculatePower(durationsMs); 336 } 337 338 /** 339 * Calculates CPU cluster power consumption. 340 * 341 * @param cluster CPU cluster used. 342 * @param clusterDurationMs duration of CPU cluster usage. 343 * @return a double in milliamp-hours of estimated CPU cluster power consumption. 344 */ calculatePerCpuClusterPowerMah(int cluster, long clusterDurationMs)345 public double calculatePerCpuClusterPowerMah(int cluster, long clusterDurationMs) { 346 return mPerClusterPowerEstimators[cluster].calculatePower(clusterDurationMs); 347 } 348 349 /** 350 * Calculates CPU cluster power consumption at a specific speedstep. 351 * 352 * @param cluster CPU cluster used. 353 * @param speedStep which speedstep used. 354 * @param clusterSpeedDurationsMs duration of CPU cluster usage at the specified speed step. 355 * @return a double in milliamp-hours of estimated CPU cluster-speed power consumption. 356 */ calculatePerCpuFreqPowerMah(int cluster, int speedStep, long clusterSpeedDurationsMs)357 public double calculatePerCpuFreqPowerMah(int cluster, int speedStep, 358 long clusterSpeedDurationsMs) { 359 return mPerCpuFreqPowerEstimatorsByCluster[cluster][speedStep].calculatePower( 360 clusterSpeedDurationsMs); 361 } 362 } 363