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android / platform / frameworks / base / c3cb6c9b22ffd9907fd602fcace763c4ba9525e9 / . / core / java / android / os / BatteryStats.java
blob: adc84bc26ebd4d7bc31e334b518849bc64a29bec [file] [log] [blame]
/*
* Copyright (C) 2008 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
package android.os;
import java.io.PrintWriter;
import java.util.ArrayList;
import java.util.Collections;
import java.util.Comparator;
import java.util.Formatter;
import java.util.HashMap;
import java.util.List;
import java.util.Map;
import android.content.Context;
import android.content.pm.ApplicationInfo;
import android.telephony.SignalStrength;
import android.text.format.DateFormat;
import android.util.ArrayMap;
import android.util.Printer;
import android.util.SparseArray;
import android.util.SparseIntArray;
import android.util.TimeUtils;
import android.view.Display;
import com.android.internal.os.BatterySipper;
import com.android.internal.os.BatteryStatsHelper;
/**
* A class providing access to battery usage statistics, including information on
* wakelocks, processes, packages, and services. All times are represented in microseconds
* except where indicated otherwise.
* @hide
*/
public abstract class BatteryStats implements Parcelable {
private static final boolean LOCAL_LOGV = false;
/** @hide */
public static final String SERVICE_NAME = "batterystats";
/**
* A constant indicating a partial wake lock timer.
*/
public static final int WAKE_TYPE_PARTIAL = 0;
/**
* A constant indicating a full wake lock timer.
*/
public static final int WAKE_TYPE_FULL = 1;
/**
* A constant indicating a window wake lock timer.
*/
public static final int WAKE_TYPE_WINDOW = 2;
/**
* A constant indicating a sensor timer.
*/
public static final int SENSOR = 3;
/**
* A constant indicating a a wifi running timer
*/
public static final int WIFI_RUNNING = 4;
/**
* A constant indicating a full wifi lock timer
*/
public static final int FULL_WIFI_LOCK = 5;
/**
* A constant indicating a wifi scan
*/
public static final int WIFI_SCAN = 6;
/**
* A constant indicating a wifi multicast timer
*/
public static final int WIFI_MULTICAST_ENABLED = 7;
/**
* A constant indicating a video turn on timer
*/
public static final int VIDEO_TURNED_ON = 8;
/**
* A constant indicating a vibrator on timer
*/
public static final int VIBRATOR_ON = 9;
/**
* A constant indicating a foreground activity timer
*/
public static final int FOREGROUND_ACTIVITY = 10;
/**
* A constant indicating a wifi batched scan is active
*/
public static final int WIFI_BATCHED_SCAN = 11;
/**
* A constant indicating a process state timer
*/
public static final int PROCESS_STATE = 12;
/**
* A constant indicating a sync timer
*/
public static final int SYNC = 13;
/**
* A constant indicating a job timer
*/
public static final int JOB = 14;
/**
* A constant indicating an audio turn on timer
*/
public static final int AUDIO_TURNED_ON = 15;
/**
* A constant indicating a flashlight turn on timer
*/
public static final int FLASHLIGHT_TURNED_ON = 16;
/**
* A constant indicating a camera turn on timer
*/
public static final int CAMERA_TURNED_ON = 17;
/**
* A constant indicating a draw wake lock timer.
*/
public static final int WAKE_TYPE_DRAW = 18;
/**
* Include all of the data in the stats, including previously saved data.
*/
public static final int STATS_SINCE_CHARGED = 0;
/**
* Include only the current run in the stats.
*/
public static final int STATS_CURRENT = 1;
/**
* Include only the run since the last time the device was unplugged in the stats.
*/
public static final int STATS_SINCE_UNPLUGGED = 2;
// NOTE: Update this list if you add/change any stats above.
// These characters are supposed to represent "total", "last", "current",
// and "unplugged". They were shortened for efficiency sake.
private static final String[] STAT_NAMES = { "l", "c", "u" };
/**
* Current version of checkin data format.
*/
static final String CHECKIN_VERSION = "14";
/**
* Old version, we hit 9 and ran out of room, need to remove.
*/
private static final int BATTERY_STATS_CHECKIN_VERSION = 9;
private static final long BYTES_PER_KB = 1024;
private static final long BYTES_PER_MB = 1048576; // 1024^2
private static final long BYTES_PER_GB = 1073741824; //1024^3
private static final String VERSION_DATA = "vers";
private static final String UID_DATA = "uid";
private static final String APK_DATA = "apk";
private static final String PROCESS_DATA = "pr";
private static final String CPU_DATA = "cpu";
private static final String SENSOR_DATA = "sr";
private static final String VIBRATOR_DATA = "vib";
private static final String FOREGROUND_DATA = "fg";
private static final String STATE_TIME_DATA = "st";
private static final String WAKELOCK_DATA = "wl";
private static final String SYNC_DATA = "sy";
private static final String JOB_DATA = "jb";
private static final String KERNEL_WAKELOCK_DATA = "kwl";
private static final String WAKEUP_REASON_DATA = "wr";
private static final String NETWORK_DATA = "nt";
private static final String USER_ACTIVITY_DATA = "ua";
private static final String BATTERY_DATA = "bt";
private static final String BATTERY_DISCHARGE_DATA = "dc";
private static final String BATTERY_LEVEL_DATA = "lv";
private static final String GLOBAL_WIFI_DATA = "gwfl";
private static final String WIFI_DATA = "wfl";
private static final String GLOBAL_BLUETOOTH_DATA = "gble";
private static final String MISC_DATA = "m";
private static final String GLOBAL_NETWORK_DATA = "gn";
private static final String HISTORY_STRING_POOL = "hsp";
private static final String HISTORY_DATA = "h";
private static final String SCREEN_BRIGHTNESS_DATA = "br";
private static final String SIGNAL_STRENGTH_TIME_DATA = "sgt";
private static final String SIGNAL_SCANNING_TIME_DATA = "sst";
private static final String SIGNAL_STRENGTH_COUNT_DATA = "sgc";
private static final String DATA_CONNECTION_TIME_DATA = "dct";
private static final String DATA_CONNECTION_COUNT_DATA = "dcc";
private static final String WIFI_STATE_TIME_DATA = "wst";
private static final String WIFI_STATE_COUNT_DATA = "wsc";
private static final String WIFI_SUPPL_STATE_TIME_DATA = "wsst";
private static final String WIFI_SUPPL_STATE_COUNT_DATA = "wssc";
private static final String WIFI_SIGNAL_STRENGTH_TIME_DATA = "wsgt";
private static final String WIFI_SIGNAL_STRENGTH_COUNT_DATA = "wsgc";
private static final String POWER_USE_SUMMARY_DATA = "pws";
private static final String POWER_USE_ITEM_DATA = "pwi";
private static final String DISCHARGE_STEP_DATA = "dsd";
private static final String CHARGE_STEP_DATA = "csd";
private static final String DISCHARGE_TIME_REMAIN_DATA = "dtr";
private static final String CHARGE_TIME_REMAIN_DATA = "ctr";
private static final String FLASHLIGHT_DATA = "fla";
private static final String CAMERA_DATA = "cam";
private static final String VIDEO_DATA = "vid";
private static final String AUDIO_DATA = "aud";
private final StringBuilder mFormatBuilder = new StringBuilder(32);
private final Formatter mFormatter = new Formatter(mFormatBuilder);
/**
* State for keeping track of counting information.
*/
public static abstract class Counter {
/**
* Returns the count associated with this Counter for the
* selected type of statistics.
*
* @param which one of STATS_SINCE_CHARGED, STATS_SINCE_UNPLUGGED, or STATS_CURRENT
*/
public abstract int getCountLocked(int which);
/**
* Temporary for debugging.
*/
public abstract void logState(Printer pw, String prefix);
}
/**
* State for keeping track of long counting information.
*/
public static abstract class LongCounter {
/**
* Returns the count associated with this Counter for the
* selected type of statistics.
*
* @param which one of STATS_SINCE_CHARGED, STATS_SINCE_UNPLUGGED, or STATS_CURRENT
*/
public abstract long getCountLocked(int which);
/**
* Temporary for debugging.
*/
public abstract void logState(Printer pw, String prefix);
}
/**
* State for keeping track of timing information.
*/
public static abstract class Timer {
/**
* Returns the count associated with this Timer for the
* selected type of statistics.
*
* @param which one of STATS_SINCE_CHARGED, STATS_SINCE_UNPLUGGED, or STATS_CURRENT
*/
public abstract int getCountLocked(int which);
/**
* Returns the total time in microseconds associated with this Timer for the
* selected type of statistics.
*
* @param elapsedRealtimeUs current elapsed realtime of system in microseconds
* @param which one of STATS_SINCE_CHARGED, STATS_SINCE_UNPLUGGED, or STATS_CURRENT
* @return a time in microseconds
*/
public abstract long getTotalTimeLocked(long elapsedRealtimeUs, int which);
/**
* Returns the total time in microseconds associated with this Timer since the
* 'mark' was last set.
*
* @param elapsedRealtimeUs current elapsed realtime of system in microseconds
* @return a time in microseconds
*/
public abstract long getTimeSinceMarkLocked(long elapsedRealtimeUs);
/**
* Temporary for debugging.
*/
public abstract void logState(Printer pw, String prefix);
}
/**
* The statistics associated with a particular uid.
*/
public static abstract class Uid {
/**
* Returns a mapping containing wakelock statistics.
*
* @return a Map from Strings to Uid.Wakelock objects.
*/
public abstract ArrayMap<String, ? extends Wakelock> getWakelockStats();
/**
* Returns a mapping containing sync statistics.
*
* @return a Map from Strings to Timer objects.
*/
public abstract ArrayMap<String, ? extends Timer> getSyncStats();
/**
* Returns a mapping containing scheduled job statistics.
*
* @return a Map from Strings to Timer objects.
*/
public abstract ArrayMap<String, ? extends Timer> getJobStats();
/**
* The statistics associated with a particular wake lock.
*/
public static abstract class Wakelock {
public abstract Timer getWakeTime(int type);
}
/**
* Returns a mapping containing sensor statistics.
*
* @return a Map from Integer sensor ids to Uid.Sensor objects.
*/
public abstract SparseArray<? extends Sensor> getSensorStats();
/**
* Returns a mapping containing active process data.
*/
public abstract SparseArray<? extends Pid> getPidStats();
/**
* Returns a mapping containing process statistics.
*
* @return a Map from Strings to Uid.Proc objects.
*/
public abstract ArrayMap<String, ? extends Proc> getProcessStats();
/**
* Returns a mapping containing package statistics.
*
* @return a Map from Strings to Uid.Pkg objects.
*/
public abstract ArrayMap<String, ? extends Pkg> getPackageStats();
/**
* Returns the time in milliseconds that this app kept the WiFi controller in the
* specified state <code>type</code>.
* @param type one of {@link #CONTROLLER_IDLE_TIME}, {@link #CONTROLLER_RX_TIME}, or
* {@link #CONTROLLER_TX_TIME}.
* @param which one of {@link #STATS_CURRENT}, {@link #STATS_SINCE_CHARGED}, or
* {@link #STATS_SINCE_UNPLUGGED}.
*/
public abstract long getWifiControllerActivity(int type, int which);
/**
* {@hide}
*/
public abstract int getUid();
public abstract void noteWifiRunningLocked(long elapsedRealtime);
public abstract void noteWifiStoppedLocked(long elapsedRealtime);
public abstract void noteFullWifiLockAcquiredLocked(long elapsedRealtime);
public abstract void noteFullWifiLockReleasedLocked(long elapsedRealtime);
public abstract void noteWifiScanStartedLocked(long elapsedRealtime);
public abstract void noteWifiScanStoppedLocked(long elapsedRealtime);
public abstract void noteWifiBatchedScanStartedLocked(int csph, long elapsedRealtime);
public abstract void noteWifiBatchedScanStoppedLocked(long elapsedRealtime);
public abstract void noteWifiMulticastEnabledLocked(long elapsedRealtime);
public abstract void noteWifiMulticastDisabledLocked(long elapsedRealtime);
public abstract void noteActivityResumedLocked(long elapsedRealtime);
public abstract void noteActivityPausedLocked(long elapsedRealtime);
public abstract long getWifiRunningTime(long elapsedRealtimeUs, int which);
public abstract long getFullWifiLockTime(long elapsedRealtimeUs, int which);
public abstract long getWifiScanTime(long elapsedRealtimeUs, int which);
public abstract int getWifiScanCount(int which);
public abstract long getWifiBatchedScanTime(int csphBin, long elapsedRealtimeUs, int which);
public abstract int getWifiBatchedScanCount(int csphBin, int which);
public abstract long getWifiMulticastTime(long elapsedRealtimeUs, int which);
public abstract Timer getAudioTurnedOnTimer();
public abstract Timer getVideoTurnedOnTimer();
public abstract Timer getFlashlightTurnedOnTimer();
public abstract Timer getCameraTurnedOnTimer();
public abstract Timer getForegroundActivityTimer();
// Time this uid has any processes in foreground state.
public static final int PROCESS_STATE_FOREGROUND = 0;
// Time this uid has any process in active state (not cached).
public static final int PROCESS_STATE_ACTIVE = 1;
// Time this uid has any processes running at all.
public static final int PROCESS_STATE_RUNNING = 2;
// Total number of process states we track.
public static final int NUM_PROCESS_STATE = 3;
static final String[] PROCESS_STATE_NAMES = {
"Foreground", "Active", "Running"
};
public abstract long getProcessStateTime(int state, long elapsedRealtimeUs, int which);
public abstract Timer getVibratorOnTimer();
public static final int NUM_WIFI_BATCHED_SCAN_BINS = 5;
/**
* Note that these must match the constants in android.os.PowerManager.
* Also, if the user activity types change, the BatteryStatsImpl.VERSION must
* also be bumped.
*/
static final String[] USER_ACTIVITY_TYPES = {
"other", "button", "touch"
};
public static final int NUM_USER_ACTIVITY_TYPES = 3;
public abstract void noteUserActivityLocked(int type);
public abstract boolean hasUserActivity();
public abstract int getUserActivityCount(int type, int which);
public abstract boolean hasNetworkActivity();
public abstract long getNetworkActivityBytes(int type, int which);
public abstract long getNetworkActivityPackets(int type, int which);
public abstract long getMobileRadioActiveTime(int which);
public abstract int getMobileRadioActiveCount(int which);
/**
* Get the total cpu time (in microseconds) this UID had processes executing in userspace.
*/
public abstract long getUserCpuTimeUs(int which);
/**
* Get the total cpu time (in microseconds) this UID had processes executing kernel syscalls.
*/
public abstract long getSystemCpuTimeUs(int which);
/**
* Get the total cpu power consumed (in milli-ampere-microseconds).
*/
public abstract long getCpuPowerMaUs(int which);
/**
* Returns the approximate cpu time (in milliseconds) spent at a certain CPU speed.
* @param step the index of the CPU speed. This is not the actual speed of the CPU.
* @param which one of STATS_SINCE_CHARGED, STATS_SINCE_UNPLUGGED, or STATS_CURRENT.
* @see BatteryStats#getCpuSpeedSteps()
*/
public abstract long getTimeAtCpuSpeed(int step, int which);
public static abstract class Sensor {
/*
* FIXME: it's not correct to use this magic value because it
* could clash with a sensor handle (which are defined by
* the sensor HAL, and therefore out of our control
*/
// Magic sensor number for the GPS.
public static final int GPS = -10000;
public abstract int getHandle();
public abstract Timer getSensorTime();
}
public class Pid {
public int mWakeNesting;
public long mWakeSumMs;
public long mWakeStartMs;
}
/**
* The statistics associated with a particular process.
*/
public static abstract class Proc {
public static class ExcessivePower {
public static final int TYPE_WAKE = 1;
public static final int TYPE_CPU = 2;
public int type;
public long overTime;
public long usedTime;
}
/**
* Returns true if this process is still active in the battery stats.
*/
public abstract boolean isActive();
/**
* Returns the total time (in milliseconds) spent executing in user code.
*
* @param which one of STATS_SINCE_CHARGED, STATS_SINCE_UNPLUGGED, or STATS_CURRENT.
*/
public abstract long getUserTime(int which);
/**
* Returns the total time (in milliseconds) spent executing in system code.
*
* @param which one of STATS_SINCE_CHARGED, STATS_SINCE_UNPLUGGED, or STATS_CURRENT.
*/
public abstract long getSystemTime(int which);
/**
* Returns the number of times the process has been started.
*
* @param which one of STATS_SINCE_CHARGED, STATS_SINCE_UNPLUGGED, or STATS_CURRENT.
*/
public abstract int getStarts(int which);
/**
* Returns the number of times the process has crashed.
*
* @param which one of STATS_SINCE_CHARGED, STATS_SINCE_UNPLUGGED, or STATS_CURRENT.
*/
public abstract int getNumCrashes(int which);
/**
* Returns the number of times the process has ANRed.
*
* @param which one of STATS_SINCE_CHARGED, STATS_SINCE_UNPLUGGED, or STATS_CURRENT.
*/
public abstract int getNumAnrs(int which);
/**
* Returns the cpu time (milliseconds) spent while the process was in the foreground.
* @param which one of STATS_SINCE_CHARGED, STATS_SINCE_UNPLUGGED, or STATS_CURRENT.
* @return foreground cpu time in microseconds
*/
public abstract long getForegroundTime(int which);
public abstract int countExcessivePowers();
public abstract ExcessivePower getExcessivePower(int i);
}
/**
* The statistics associated with a particular package.
*/
public static abstract class Pkg {
/**
* Returns information about all wakeup alarms that have been triggered for this
* package. The mapping keys are tag names for the alarms, the counter contains
* the number of times the alarm was triggered while on battery.
*/
public abstract ArrayMap<String, ? extends Counter> getWakeupAlarmStats();
/**
* Returns a mapping containing service statistics.
*/
public abstract ArrayMap<String, ? extends Serv> getServiceStats();
/**
* The statistics associated with a particular service.
*/
public abstract class Serv {
/**
* Returns the amount of time spent started.
*
* @param batteryUptime elapsed uptime on battery in microseconds.
* @param which one of STATS_SINCE_CHARGED, STATS_SINCE_UNPLUGGED, or STATS_CURRENT.
* @return
*/
public abstract long getStartTime(long batteryUptime, int which);
/**
* Returns the total number of times startService() has been called.
*
* @param which one of STATS_SINCE_CHARGED, STATS_SINCE_UNPLUGGED, or STATS_CURRENT.
*/
public abstract int getStarts(int which);
/**
* Returns the total number times the service has been launched.
*
* @param which one of STATS_SINCE_CHARGED, STATS_SINCE_UNPLUGGED, or STATS_CURRENT.
*/
public abstract int getLaunches(int which);
}
}
}
public static final class LevelStepTracker {
public long mLastStepTime = -1;
public int mNumStepDurations;
public final long[] mStepDurations;
public LevelStepTracker(int maxLevelSteps) {
mStepDurations = new long[maxLevelSteps];
}
public LevelStepTracker(int numSteps, long[] steps) {
mNumStepDurations = numSteps;
mStepDurations = new long[numSteps];
System.arraycopy(steps, 0, mStepDurations, 0, numSteps);
}
public long getDurationAt(int index) {
return mStepDurations[index] & STEP_LEVEL_TIME_MASK;
}
public int getLevelAt(int index) {
return (int)((mStepDurations[index] & STEP_LEVEL_LEVEL_MASK)
>> STEP_LEVEL_LEVEL_SHIFT);
}
public int getInitModeAt(int index) {
return (int)((mStepDurations[index] & STEP_LEVEL_INITIAL_MODE_MASK)
>> STEP_LEVEL_INITIAL_MODE_SHIFT);
}
public int getModModeAt(int index) {
return (int)((mStepDurations[index] & STEP_LEVEL_MODIFIED_MODE_MASK)
>> STEP_LEVEL_MODIFIED_MODE_SHIFT);
}
private void appendHex(long val, int topOffset, StringBuilder out) {
boolean hasData = false;
while (topOffset >= 0) {
int digit = (int)( (val>>topOffset) & 0xf );
topOffset -= 4;
if (!hasData && digit == 0) {
continue;
}
hasData = true;
if (digit >= 0 && digit <= 9) {
out.append((char)('0' + digit));
} else {
out.append((char)('a' + digit - 10));
}
}
}
public void encodeEntryAt(int index, StringBuilder out) {
long item = mStepDurations[index];
long duration = item & STEP_LEVEL_TIME_MASK;
int level = (int)((item & STEP_LEVEL_LEVEL_MASK)
>> STEP_LEVEL_LEVEL_SHIFT);
int initMode = (int)((item & STEP_LEVEL_INITIAL_MODE_MASK)
>> STEP_LEVEL_INITIAL_MODE_SHIFT);
int modMode = (int)((item & STEP_LEVEL_MODIFIED_MODE_MASK)
>> STEP_LEVEL_MODIFIED_MODE_SHIFT);
switch ((initMode&STEP_LEVEL_MODE_SCREEN_STATE) + 1) {
case Display.STATE_OFF: out.append('f'); break;
case Display.STATE_ON: out.append('o'); break;
case Display.STATE_DOZE: out.append('d'); break;
case Display.STATE_DOZE_SUSPEND: out.append('z'); break;
}
if ((initMode&STEP_LEVEL_MODE_POWER_SAVE) != 0) {
out.append('p');
}
if ((initMode&STEP_LEVEL_MODE_DEVICE_IDLE) != 0) {
out.append('i');
}
switch ((modMode&STEP_LEVEL_MODE_SCREEN_STATE) + 1) {
case Display.STATE_OFF: out.append('F'); break;
case Display.STATE_ON: out.append('O'); break;
case Display.STATE_DOZE: out.append('D'); break;
case Display.STATE_DOZE_SUSPEND: out.append('Z'); break;
}
if ((modMode&STEP_LEVEL_MODE_POWER_SAVE) != 0) {
out.append('P');
}
if ((modMode&STEP_LEVEL_MODE_DEVICE_IDLE) != 0) {
out.append('I');
}
out.append('-');
appendHex(level, 4, out);
out.append('-');
appendHex(duration, STEP_LEVEL_LEVEL_SHIFT-4, out);
}
public void decodeEntryAt(int index, String value) {
final int N = value.length();
int i = 0;
char c;
long out = 0;
while (i < N && (c=value.charAt(i)) != '-') {
i++;
switch (c) {
case 'f': out |= (((long)Display.STATE_OFF-1)<<STEP_LEVEL_INITIAL_MODE_SHIFT);
break;
case 'o': out |= (((long)Display.STATE_ON-1)<<STEP_LEVEL_INITIAL_MODE_SHIFT);
break;
case 'd': out |= (((long)Display.STATE_DOZE-1)<<STEP_LEVEL_INITIAL_MODE_SHIFT);
break;
case 'z': out |= (((long)Display.STATE_DOZE_SUSPEND-1)
<< STEP_LEVEL_INITIAL_MODE_SHIFT);
break;
case 'p': out |= (((long)STEP_LEVEL_MODE_POWER_SAVE)
<< STEP_LEVEL_INITIAL_MODE_SHIFT);
break;
case 'i': out |= (((long)STEP_LEVEL_MODE_DEVICE_IDLE)
<< STEP_LEVEL_INITIAL_MODE_SHIFT);
break;
case 'F': out |= (((long)Display.STATE_OFF-1)<<STEP_LEVEL_MODIFIED_MODE_SHIFT);
break;
case 'O': out |= (((long)Display.STATE_ON-1)<<STEP_LEVEL_MODIFIED_MODE_SHIFT);
break;
case 'D': out |= (((long)Display.STATE_DOZE-1)<<STEP_LEVEL_MODIFIED_MODE_SHIFT);
break;
case 'Z': out |= (((long)Display.STATE_DOZE_SUSPEND-1)
<< STEP_LEVEL_MODIFIED_MODE_SHIFT);
break;
case 'P': out |= (((long)STEP_LEVEL_MODE_POWER_SAVE)
<< STEP_LEVEL_MODIFIED_MODE_SHIFT);
break;
case 'I': out |= (((long)STEP_LEVEL_MODE_DEVICE_IDLE)
<< STEP_LEVEL_MODIFIED_MODE_SHIFT);
break;
}
}
i++;
long level = 0;
while (i < N && (c=value.charAt(i)) != '-') {
i++;
level <<= 4;
if (c >= '0' && c <= '9') {
level += c - '0';
} else if (c >= 'a' && c <= 'f') {
level += c - 'a' + 10;
} else if (c >= 'A' && c <= 'F') {
level += c - 'A' + 10;
}
}
i++;
out |= (level << STEP_LEVEL_LEVEL_SHIFT) & STEP_LEVEL_LEVEL_MASK;
long duration = 0;
while (i < N && (c=value.charAt(i)) != '-') {
i++;
duration <<= 4;
if (c >= '0' && c <= '9') {
duration += c - '0';
} else if (c >= 'a' && c <= 'f') {
duration += c - 'a' + 10;
} else if (c >= 'A' && c <= 'F') {
duration += c - 'A' + 10;
}
}
mStepDurations[index] = out | (duration & STEP_LEVEL_TIME_MASK);
}
public void init() {
mLastStepTime = -1;
mNumStepDurations = 0;
}
public void clearTime() {
mLastStepTime = -1;
}
public long computeTimePerLevel() {
final long[] steps = mStepDurations;
final int numSteps = mNumStepDurations;
// For now we'll do a simple average across all steps.
if (numSteps <= 0) {
return -1;
}
long total = 0;
for (int i=0; i<numSteps; i++) {
total += steps[i] & STEP_LEVEL_TIME_MASK;
}
return total / numSteps;
/*
long[] buckets = new long[numSteps];
int numBuckets = 0;
int numToAverage = 4;
int i = 0;
while (i < numSteps) {
long totalTime = 0;
int num = 0;
for (int j=0; j<numToAverage && (i+j)<numSteps; j++) {
totalTime += steps[i+j] & STEP_LEVEL_TIME_MASK;
num++;
}
buckets[numBuckets] = totalTime / num;
numBuckets++;
numToAverage *= 2;
i += num;
}
if (numBuckets < 1) {
return -1;
}
long averageTime = buckets[numBuckets-1];
for (i=numBuckets-2; i>=0; i--) {
averageTime = (averageTime + buckets[i]) / 2;
}
return averageTime;
*/
}
public long computeTimeEstimate(long modesOfInterest, long modeValues,
int[] outNumOfInterest) {
final long[] steps = mStepDurations;
final int count = mNumStepDurations;
if (count <= 0) {
return -1;
}
long total = 0;
int numOfInterest = 0;
for (int i=0; i<count; i++) {
long initMode = (steps[i] & STEP_LEVEL_INITIAL_MODE_MASK)
>> STEP_LEVEL_INITIAL_MODE_SHIFT;
long modMode = (steps[i] & STEP_LEVEL_MODIFIED_MODE_MASK)
>> STEP_LEVEL_MODIFIED_MODE_SHIFT;
// If the modes of interest didn't change during this step period...
if ((modMode&modesOfInterest) == 0) {
// And the mode values during this period match those we are measuring...
if ((initMode&modesOfInterest) == modeValues) {
// Then this can be used to estimate the total time!
numOfInterest++;
total += steps[i] & STEP_LEVEL_TIME_MASK;
}
}
}
if (numOfInterest <= 0) {
return -1;
}
if (outNumOfInterest != null) {
outNumOfInterest[0] = numOfInterest;
}
// The estimated time is the average time we spend in each level, multipled
// by 100 -- the total number of battery levels
return (total / numOfInterest) * 100;
}
public void addLevelSteps(int numStepLevels, long modeBits, long elapsedRealtime) {
int stepCount = mNumStepDurations;
final long lastStepTime = mLastStepTime;
if (lastStepTime >= 0 && numStepLevels > 0) {
final long[] steps = mStepDurations;
long duration = elapsedRealtime - lastStepTime;
for (int i=0; i<numStepLevels; i++) {
System.arraycopy(steps, 0, steps, 1, steps.length-1);
long thisDuration = duration / (numStepLevels-i);
duration -= thisDuration;
if (thisDuration > STEP_LEVEL_TIME_MASK) {
thisDuration = STEP_LEVEL_TIME_MASK;
}
steps[0] = thisDuration | modeBits;
}
stepCount += numStepLevels;
if (stepCount > steps.length) {
stepCount = steps.length;
}
}
mNumStepDurations = stepCount;
mLastStepTime = elapsedRealtime;
}
public void readFromParcel(Parcel in) {
final int N = in.readInt();
if (N > mStepDurations.length) {
throw new ParcelFormatException("more step durations than available: " + N);
}
mNumStepDurations = N;
for (int i=0; i<N; i++) {
mStepDurations[i] = in.readLong();
}
}
public void writeToParcel(Parcel out) {
final int N = mNumStepDurations;
out.writeInt(N);
for (int i=0; i<N; i++) {
out.writeLong(mStepDurations[i]);
}
}
}
public static final class PackageChange {
public String mPackageName;
public boolean mUpdate;
public int mVersionCode;
}
public static final class DailyItem {
public long mStartTime;
public long mEndTime;
public LevelStepTracker mDischargeSteps;
public LevelStepTracker mChargeSteps;
public ArrayList<PackageChange> mPackageChanges;
}
public abstract DailyItem getDailyItemLocked(int daysAgo);
public abstract long getCurrentDailyStartTime();
public abstract long getNextMinDailyDeadline();
public abstract long getNextMaxDailyDeadline();
public final static class HistoryTag {
public String string;
public int uid;
public int poolIdx;
public void setTo(HistoryTag o) {
string = o.string;
uid = o.uid;
poolIdx = o.poolIdx;
}
public void setTo(String _string, int _uid) {
string = _string;
uid = _uid;
poolIdx = -1;
}
public void writeToParcel(Parcel dest, int flags) {
dest.writeString(string);
dest.writeInt(uid);
}
public void readFromParcel(Parcel src) {
string = src.readString();
uid = src.readInt();
poolIdx = -1;
}
@Override
public boolean equals(Object o) {
if (this == o) return true;
if (o == null || getClass() != o.getClass()) return false;
HistoryTag that = (HistoryTag) o;
if (uid != that.uid) return false;
if (!string.equals(that.string)) return false;
return true;
}
@Override
public int hashCode() {
int result = string.hashCode();
result = 31 * result + uid;
return result;
}
}
/**
* Optional detailed information that can go into a history step. This is typically
* generated each time the battery level changes.
*/
public final static class HistoryStepDetails {
// Time (in 1/100 second) spent in user space and the kernel since the last step.
public int userTime;
public int systemTime;
// Top three apps using CPU in the last step, with times in 1/100 second.
public int appCpuUid1;
public int appCpuUTime1;
public int appCpuSTime1;
public int appCpuUid2;
public int appCpuUTime2;
public int appCpuSTime2;
public int appCpuUid3;
public int appCpuUTime3;
public int appCpuSTime3;
// Information from /proc/stat
public int statUserTime;
public int statSystemTime;
public int statIOWaitTime;
public int statIrqTime;
public int statSoftIrqTime;
public int statIdlTime;
public HistoryStepDetails() {
clear();
}
public void clear() {
userTime = systemTime = 0;
appCpuUid1 = appCpuUid2 = appCpuUid3 = -1;
appCpuUTime1 = appCpuSTime1 = appCpuUTime2 = appCpuSTime2
= appCpuUTime3 = appCpuSTime3 = 0;
}
public void writeToParcel(Parcel out) {
out.writeInt(userTime);
out.writeInt(systemTime);
out.writeInt(appCpuUid1);
out.writeInt(appCpuUTime1);
out.writeInt(appCpuSTime1);
out.writeInt(appCpuUid2);
out.writeInt(appCpuUTime2);
out.writeInt(appCpuSTime2);
out.writeInt(appCpuUid3);
out.writeInt(appCpuUTime3);
out.writeInt(appCpuSTime3);
out.writeInt(statUserTime);
out.writeInt(statSystemTime);
out.writeInt(statIOWaitTime);
out.writeInt(statIrqTime);
out.writeInt(statSoftIrqTime);
out.writeInt(statIdlTime);
}
public void readFromParcel(Parcel in) {
userTime = in.readInt();
systemTime = in.readInt();
appCpuUid1 = in.readInt();
appCpuUTime1 = in.readInt();
appCpuSTime1 = in.readInt();
appCpuUid2 = in.readInt();
appCpuUTime2 = in.readInt();
appCpuSTime2 = in.readInt();
appCpuUid3 = in.readInt();
appCpuUTime3 = in.readInt();
appCpuSTime3 = in.readInt();
statUserTime = in.readInt();
statSystemTime = in.readInt();
statIOWaitTime = in.readInt();
statIrqTime = in.readInt();
statSoftIrqTime = in.readInt();
statIdlTime = in.readInt();
}
}
public final static class HistoryItem implements Parcelable {
public HistoryItem next;
// The time of this event in milliseconds, as per SystemClock.elapsedRealtime().
public long time;
public static final byte CMD_UPDATE = 0; // These can be written as deltas
public static final byte CMD_NULL = -1;
public static final byte CMD_START = 4;
public static final byte CMD_CURRENT_TIME = 5;
public static final byte CMD_OVERFLOW = 6;
public static final byte CMD_RESET = 7;
public static final byte CMD_SHUTDOWN = 8;
public byte cmd = CMD_NULL;
/**
* Return whether the command code is a delta data update.
*/
public boolean isDeltaData() {
return cmd == CMD_UPDATE;
}
public byte batteryLevel;
public byte batteryStatus;
public byte batteryHealth;
public byte batteryPlugType;
public short batteryTemperature;
public char batteryVoltage;
// Constants from SCREEN_BRIGHTNESS_*
public static final int STATE_BRIGHTNESS_SHIFT = 0;
public static final int STATE_BRIGHTNESS_MASK = 0x7;
// Constants from SIGNAL_STRENGTH_*
public static final int STATE_PHONE_SIGNAL_STRENGTH_SHIFT = 3;
public static final int STATE_PHONE_SIGNAL_STRENGTH_MASK = 0x7 << STATE_PHONE_SIGNAL_STRENGTH_SHIFT;
// Constants from ServiceState.STATE_*
public static final int STATE_PHONE_STATE_SHIFT = 6;
public static final int STATE_PHONE_STATE_MASK = 0x7 << STATE_PHONE_STATE_SHIFT;
// Constants from DATA_CONNECTION_*
public static final int STATE_DATA_CONNECTION_SHIFT = 9;
public static final int STATE_DATA_CONNECTION_MASK = 0x1f << STATE_DATA_CONNECTION_SHIFT;
// These states always appear directly in the first int token
// of a delta change; they should be ones that change relatively
// frequently.
public static final int STATE_CPU_RUNNING_FLAG = 1<<31;
public static final int STATE_WAKE_LOCK_FLAG = 1<<30;
public static final int STATE_GPS_ON_FLAG = 1<<29;
public static final int STATE_WIFI_FULL_LOCK_FLAG = 1<<28;
public static final int STATE_WIFI_SCAN_FLAG = 1<<27;
public static final int STATE_WIFI_RADIO_ACTIVE_FLAG = 1<<26;
public static final int STATE_MOBILE_RADIO_ACTIVE_FLAG = 1<<25;
// These are on the lower bits used for the command; if they change
// we need to write another int of data.
public static final int STATE_SENSOR_ON_FLAG = 1<<23;
public static final int STATE_AUDIO_ON_FLAG = 1<<22;
public static final int STATE_PHONE_SCANNING_FLAG = 1<<21;
public static final int STATE_SCREEN_ON_FLAG = 1<<20; // consider moving to states2
public static final int STATE_BATTERY_PLUGGED_FLAG = 1<<19; // consider moving to states2
// empty slot
// empty slot
public static final int STATE_WIFI_MULTICAST_ON_FLAG = 1<<16;
public static final int MOST_INTERESTING_STATES =
STATE_BATTERY_PLUGGED_FLAG | STATE_SCREEN_ON_FLAG;
public static final int SETTLE_TO_ZERO_STATES = 0xffff0000 & ~MOST_INTERESTING_STATES;
public int states;
// Constants from WIFI_SUPPL_STATE_*
public static final int STATE2_WIFI_SUPPL_STATE_SHIFT = 0;
public static final int STATE2_WIFI_SUPPL_STATE_MASK = 0xf;
// Values for NUM_WIFI_SIGNAL_STRENGTH_BINS
public static final int STATE2_WIFI_SIGNAL_STRENGTH_SHIFT = 4;
public static final int STATE2_WIFI_SIGNAL_STRENGTH_MASK =
0x7 << STATE2_WIFI_SIGNAL_STRENGTH_SHIFT;
public static final int STATE2_POWER_SAVE_FLAG = 1<<31;
public static final int STATE2_VIDEO_ON_FLAG = 1<<30;
public static final int STATE2_WIFI_RUNNING_FLAG = 1<<29;
public static final int STATE2_WIFI_ON_FLAG = 1<<28;
public static final int STATE2_FLASHLIGHT_FLAG = 1<<27;
public static final int STATE2_DEVICE_IDLE_FLAG = 1<<26;
public static final int STATE2_CHARGING_FLAG = 1<<25;
public static final int STATE2_PHONE_IN_CALL_FLAG = 1<<24;
public static final int STATE2_BLUETOOTH_ON_FLAG = 1<<23;
public static final int STATE2_CAMERA_FLAG = 1<<22;
public static final int MOST_INTERESTING_STATES2 =
STATE2_POWER_SAVE_FLAG | STATE2_WIFI_ON_FLAG | STATE2_DEVICE_IDLE_FLAG
| STATE2_CHARGING_FLAG | STATE2_PHONE_IN_CALL_FLAG | STATE2_BLUETOOTH_ON_FLAG;
public static final int SETTLE_TO_ZERO_STATES2 = 0xffff0000 & ~MOST_INTERESTING_STATES2;
public int states2;
// The wake lock that was acquired at this point.
public HistoryTag wakelockTag;
// Kernel wakeup reason at this point.
public HistoryTag wakeReasonTag;
// Non-null when there is more detailed information at this step.
public HistoryStepDetails stepDetails;
public static final int EVENT_FLAG_START = 0x8000;
public static final int EVENT_FLAG_FINISH = 0x4000;
// No event in this item.
public static final int EVENT_NONE = 0x0000;
// Event is about a process that is running.
public static final int EVENT_PROC = 0x0001;
// Event is about an application package that is in the foreground.
public static final int EVENT_FOREGROUND = 0x0002;
// Event is about an application package that is at the top of the screen.
public static final int EVENT_TOP = 0x0003;
// Event is about active sync operations.
public static final int EVENT_SYNC = 0x0004;
// Events for all additional wake locks aquired/release within a wake block.
// These are not generated by default.
public static final int EVENT_WAKE_LOCK = 0x0005;
// Event is about an application executing a scheduled job.
public static final int EVENT_JOB = 0x0006;
// Events for users running.
public static final int EVENT_USER_RUNNING = 0x0007;
// Events for foreground user.
public static final int EVENT_USER_FOREGROUND = 0x0008;
// Event for connectivity changed.
public static final int EVENT_CONNECTIVITY_CHANGED = 0x0009;
// Event for becoming active taking us out of idle mode.
public static final int EVENT_ACTIVE = 0x000a;
// Event for a package being installed.
public static final int EVENT_PACKAGE_INSTALLED = 0x000b;
// Event for a package being uninstalled.
public static final int EVENT_PACKAGE_UNINSTALLED = 0x000c;
// Event for a package being uninstalled.
public static final int EVENT_ALARM = 0x000d;
// Record that we have decided we need to collect new stats data.
public static final int EVENT_COLLECT_EXTERNAL_STATS = 0x000e;
// Event for a package becoming inactive due to being unused for a period of time.
public static final int EVENT_PACKAGE_INACTIVE = 0x000f;
// Event for a package becoming active due to an interaction.
public static final int EVENT_PACKAGE_ACTIVE = 0x0010;
// Number of event types.
public static final int EVENT_COUNT = 0x0011;
// Mask to extract out only the type part of the event.
public static final int EVENT_TYPE_MASK = ~(EVENT_FLAG_START|EVENT_FLAG_FINISH);
public static final int EVENT_PROC_START = EVENT_PROC | EVENT_FLAG_START;
public static final int EVENT_PROC_FINISH = EVENT_PROC | EVENT_FLAG_FINISH;
public static final int EVENT_FOREGROUND_START = EVENT_FOREGROUND | EVENT_FLAG_START;
public static final int EVENT_FOREGROUND_FINISH = EVENT_FOREGROUND | EVENT_FLAG_FINISH;
public static final int EVENT_TOP_START = EVENT_TOP | EVENT_FLAG_START;
public static final int EVENT_TOP_FINISH = EVENT_TOP | EVENT_FLAG_FINISH;
public static final int EVENT_SYNC_START = EVENT_SYNC | EVENT_FLAG_START;
public static final int EVENT_SYNC_FINISH = EVENT_SYNC | EVENT_FLAG_FINISH;
public static final int EVENT_WAKE_LOCK_START = EVENT_WAKE_LOCK | EVENT_FLAG_START;
public static final int EVENT_WAKE_LOCK_FINISH = EVENT_WAKE_LOCK | EVENT_FLAG_FINISH;
public static final int EVENT_JOB_START = EVENT_JOB | EVENT_FLAG_START;
public static final int EVENT_JOB_FINISH = EVENT_JOB | EVENT_FLAG_FINISH;
public static final int EVENT_USER_RUNNING_START = EVENT_USER_RUNNING | EVENT_FLAG_START;
public static final int EVENT_USER_RUNNING_FINISH = EVENT_USER_RUNNING | EVENT_FLAG_FINISH;
public static final int EVENT_USER_FOREGROUND_START =
EVENT_USER_FOREGROUND | EVENT_FLAG_START;
public static final int EVENT_USER_FOREGROUND_FINISH =
EVENT_USER_FOREGROUND | EVENT_FLAG_FINISH;
public static final int EVENT_ALARM_START = EVENT_ALARM | EVENT_FLAG_START;
public static final int EVENT_ALARM_FINISH = EVENT_ALARM | EVENT_FLAG_FINISH;
// For CMD_EVENT.
public int eventCode;
public HistoryTag eventTag;
// Only set for CMD_CURRENT_TIME or CMD_RESET, as per System.currentTimeMillis().
public long currentTime;
// Meta-data when reading.
public int numReadInts;
// Pre-allocated objects.
public final HistoryTag localWakelockTag = new HistoryTag();
public final HistoryTag localWakeReasonTag = new HistoryTag();
public final HistoryTag localEventTag = new HistoryTag();
public HistoryItem() {
}
public HistoryItem(long time, Parcel src) {
this.time = time;
numReadInts = 2;
readFromParcel(src);
}
public int describeContents() {
return 0;
}
public void writeToParcel(Parcel dest, int flags) {
dest.writeLong(time);
int bat = (((int)cmd)&0xff)
| ((((int)batteryLevel)<<8)&0xff00)
| ((((int)batteryStatus)<<16)&0xf0000)
| ((((int)batteryHealth)<<20)&0xf00000)
| ((((int)batteryPlugType)<<24)&0xf000000)
| (wakelockTag != null ? 0x10000000 : 0)
| (wakeReasonTag != null ? 0x20000000 : 0)
| (eventCode != EVENT_NONE ? 0x40000000 : 0);
dest.writeInt(bat);
bat = (((int)batteryTemperature)&0xffff)
| ((((int)batteryVoltage)<<16)&0xffff0000);
dest.writeInt(bat);
dest.writeInt(states);
dest.writeInt(states2);
if (wakelockTag != null) {
wakelockTag.writeToParcel(dest, flags);
}
if (wakeReasonTag != null) {
wakeReasonTag.writeToParcel(dest, flags);
}
if (eventCode != EVENT_NONE) {
dest.writeInt(eventCode);
eventTag.writeToParcel(dest, flags);
}
if (cmd == CMD_CURRENT_TIME || cmd == CMD_RESET) {
dest.writeLong(currentTime);
}
}
public void readFromParcel(Parcel src) {
int start = src.dataPosition();
int bat = src.readInt();
cmd = (byte)(bat&0xff);
batteryLevel = (byte)((bat>>8)&0xff);
batteryStatus = (byte)((bat>>16)&0xf);
batteryHealth = (byte)((bat>>20)&0xf);
batteryPlugType = (byte)((bat>>24)&0xf);
int bat2 = src.readInt();
batteryTemperature = (short)(bat2&0xffff);
batteryVoltage = (char)((bat2>>16)&0xffff);
states = src.readInt();
states2 = src.readInt();
if ((bat&0x10000000) != 0) {
wakelockTag = localWakelockTag;
wakelockTag.readFromParcel(src);
} else {
wakelockTag = null;
}
if ((bat&0x20000000) != 0) {
wakeReasonTag = localWakeReasonTag;
wakeReasonTag.readFromParcel(src);
} else {
wakeReasonTag = null;
}
if ((bat&0x40000000) != 0) {
eventCode = src.readInt();
eventTag = localEventTag;
eventTag.readFromParcel(src);
} else {
eventCode = EVENT_NONE;
eventTag = null;
}
if (cmd == CMD_CURRENT_TIME || cmd == CMD_RESET) {
currentTime = src.readLong();
} else {
currentTime = 0;
}
numReadInts += (src.dataPosition()-start)/4;
}
public void clear() {
time = 0;
cmd = CMD_NULL;
batteryLevel = 0;
batteryStatus = 0;
batteryHealth = 0;
batteryPlugType = 0;
batteryTemperature = 0;
batteryVoltage = 0;
states = 0;
states2 = 0;
wakelockTag = null;
wakeReasonTag = null;
eventCode = EVENT_NONE;
eventTag = null;
}
public void setTo(HistoryItem o) {
time = o.time;
cmd = o.cmd;
setToCommon(o);
}
public void setTo(long time, byte cmd, HistoryItem o) {
this.time = time;
this.cmd = cmd;
setToCommon(o);
}
private void setToCommon(HistoryItem o) {
batteryLevel = o.batteryLevel;
batteryStatus = o.batteryStatus;
batteryHealth = o.batteryHealth;
batteryPlugType = o.batteryPlugType;
batteryTemperature = o.batteryTemperature;
batteryVoltage = o.batteryVoltage;
states = o.states;
states2 = o.states2;
if (o.wakelockTag != null) {
wakelockTag = localWakelockTag;
wakelockTag.setTo(o.wakelockTag);
} else {
wakelockTag = null;
}
if (o.wakeReasonTag != null) {
wakeReasonTag = localWakeReasonTag;
wakeReasonTag.setTo(o.wakeReasonTag);
} else {
wakeReasonTag = null;
}
eventCode = o.eventCode;
if (o.eventTag != null) {
eventTag = localEventTag;
eventTag.setTo(o.eventTag);
} else {
eventTag = null;
}
currentTime = o.currentTime;
}
public boolean sameNonEvent(HistoryItem o) {
return batteryLevel == o.batteryLevel
&& batteryStatus == o.batteryStatus
&& batteryHealth == o.batteryHealth
&& batteryPlugType == o.batteryPlugType
&& batteryTemperature == o.batteryTemperature
&& batteryVoltage == o.batteryVoltage
&& states == o.states
&& states2 == o.states2
&& currentTime == o.currentTime;
}
public boolean same(HistoryItem o) {
if (!sameNonEvent(o) || eventCode != o.eventCode) {
return false;
}
if (wakelockTag != o.wakelockTag) {
if (wakelockTag == null || o.wakelockTag == null) {
return false;
}
if (!wakelockTag.equals(o.wakelockTag)) {
return false;
}
}
if (wakeReasonTag != o.wakeReasonTag) {
if (wakeReasonTag == null || o.wakeReasonTag == null) {
return false;
}
if (!wakeReasonTag.equals(o.wakeReasonTag)) {
return false;
}
}
if (eventTag != o.eventTag) {
if (eventTag == null || o.eventTag == null) {
return false;
}
if (!eventTag.equals(o.eventTag)) {
return false;
}
}
return true;
}
}
public final static class HistoryEventTracker {
private final HashMap<String, SparseIntArray>[] mActiveEvents
= (HashMap<String, SparseIntArray>[]) new HashMap[HistoryItem.EVENT_COUNT];
public boolean updateState(int code, String name, int uid, int poolIdx) {
if ((code&HistoryItem.EVENT_FLAG_START) != 0) {
int idx = code&HistoryItem.EVENT_TYPE_MASK;
HashMap<String, SparseIntArray> active = mActiveEvents[idx];
if (active == null) {
active = new HashMap<>();
mActiveEvents[idx] = active;
}
SparseIntArray uids = active.get(name);
if (uids == null) {
uids = new SparseIntArray();
active.put(name, uids);
}
if (uids.indexOfKey(uid) >= 0) {
// Already set, nothing to do!
return false;
}
uids.put(uid, poolIdx);
} else if ((code&HistoryItem.EVENT_FLAG_FINISH) != 0) {
int idx = code&HistoryItem.EVENT_TYPE_MASK;
HashMap<String, SparseIntArray> active = mActiveEvents[idx];
if (active == null) {
// not currently active, nothing to do.
return false;
}
SparseIntArray uids = active.get(name);
if (uids == null) {
// not currently active, nothing to do.
return false;
}
idx = uids.indexOfKey(uid);
if (idx < 0) {
// not currently active, nothing to do.
return false;
}
uids.removeAt(idx);
if (uids.size() <= 0) {
active.remove(name);
}
}
return true;
}
public void removeEvents(int code) {
int idx = code&HistoryItem.EVENT_TYPE_MASK;
mActiveEvents[idx] = null;
}
public HashMap<String, SparseIntArray> getStateForEvent(int code) {
return mActiveEvents[code];
}
}
public static final class BitDescription {
public final int mask;
public final int shift;
public final String name;
public final String shortName;
public final String[] values;
public final String[] shortValues;
public BitDescription(int mask, String name, String shortName) {
this.mask = mask;
this.shift = -1;
this.name = name;
this.shortName = shortName;
this.values = null;
this.shortValues = null;
}
public BitDescription(int mask, int shift, String name, String shortName,
String[] values, String[] shortValues) {
this.mask = mask;
this.shift = shift;
this.name = name;
this.shortName = shortName;
this.values = values;
this.shortValues = shortValues;
}
}
/**
* Don't allow any more batching in to the current history event. This
* is called when printing partial histories, so to ensure that the next
* history event will go in to a new batch after what was printed in the
* last partial history.
*/
public abstract void commitCurrentHistoryBatchLocked();
public abstract int getHistoryTotalSize();
public abstract int getHistoryUsedSize();
public abstract boolean startIteratingHistoryLocked();
public abstract int getHistoryStringPoolSize();
public abstract int getHistoryStringPoolBytes();
public abstract String getHistoryTagPoolString(int index);
public abstract int getHistoryTagPoolUid(int index);
public abstract boolean getNextHistoryLocked(HistoryItem out);
public abstract void finishIteratingHistoryLocked();
public abstract boolean startIteratingOldHistoryLocked();
public abstract boolean getNextOldHistoryLocked(HistoryItem out);
public abstract void finishIteratingOldHistoryLocked();
/**
* Return the base time offset for the battery history.
*/
public abstract long getHistoryBaseTime();
/**
* Returns the number of times the device has been started.
*/
public abstract int getStartCount();
/**
* Returns the time in microseconds that the screen has been on while the device was
* running on battery.
*
* {@hide}
*/
public abstract long getScreenOnTime(long elapsedRealtimeUs, int which);
/**
* Returns the number of times the screen was turned on.
*
* {@hide}
*/
public abstract int getScreenOnCount(int which);
public abstract long getInteractiveTime(long elapsedRealtimeUs, int which);
public static final int SCREEN_BRIGHTNESS_DARK = 0;
public static final int SCREEN_BRIGHTNESS_DIM = 1;
public static final int SCREEN_BRIGHTNESS_MEDIUM = 2;
public static final int SCREEN_BRIGHTNESS_LIGHT = 3;
public static final int SCREEN_BRIGHTNESS_BRIGHT = 4;
static final String[] SCREEN_BRIGHTNESS_NAMES = {
"dark", "dim", "medium", "light", "bright"
};
static final String[] SCREEN_BRIGHTNESS_SHORT_NAMES = {
"0", "1", "2", "3", "4"
};
public static final int NUM_SCREEN_BRIGHTNESS_BINS = 5;
/**
* Returns the time in microseconds that the screen has been on with
* the given brightness
*
* {@hide}
*/
public abstract long getScreenBrightnessTime(int brightnessBin,
long elapsedRealtimeUs, int which);
/**
* Returns the time in microseconds that power save mode has been enabled while the device was
* running on battery.
*
* {@hide}
*/
public abstract long getPowerSaveModeEnabledTime(long elapsedRealtimeUs, int which);
/**
* Returns the number of times that power save mode was enabled.
*
* {@hide}
*/
public abstract int getPowerSaveModeEnabledCount(int which);
/**
* Returns the time in microseconds that device has been in idle mode while
* running on battery.
*
* {@hide}
*/
public abstract long getDeviceIdleModeEnabledTime(long elapsedRealtimeUs, int which);
/**
* Returns the number of times that the devie has gone in to idle mode.
*
* {@hide}
*/
public abstract int getDeviceIdleModeEnabledCount(int which);
/**
* Returns the time in microseconds that device has been in idling while on
* battery. This is broader than {@link #getDeviceIdleModeEnabledTime} -- it
* counts all of the time that we consider the device to be idle, whether or not
* it is currently in the actual device idle mode.
*
* {@hide}
*/
public abstract long getDeviceIdlingTime(long elapsedRealtimeUs, int which);
/**
* Returns the number of times that the devie has started idling.
*
* {@hide}
*/
public abstract int getDeviceIdlingCount(int which);
/**
* Returns the number of times that connectivity state changed.
*
* {@hide}
*/
public abstract int getNumConnectivityChange(int which);
/**
* Returns the time in microseconds that the phone has been on while the device was
* running on battery.
*
* {@hide}
*/
public abstract long getPhoneOnTime(long elapsedRealtimeUs, int which);
/**
* Returns the number of times a phone call was activated.
*
* {@hide}
*/
public abstract int getPhoneOnCount(int which);
/**
* Returns the time in microseconds that the phone has been running with
* the given signal strength.
*
* {@hide}
*/
public abstract long getPhoneSignalStrengthTime(int strengthBin,
long elapsedRealtimeUs, int which);
/**
* Returns the time in microseconds that the phone has been trying to
* acquire a signal.
*
* {@hide}
*/
public abstract long getPhoneSignalScanningTime(
long elapsedRealtimeUs, int which);
/**
* Returns the number of times the phone has entered the given signal strength.
*
* {@hide}
*/
public abstract int getPhoneSignalStrengthCount(int strengthBin, int which);
/**
* Returns the time in microseconds that the mobile network has been active
* (in a high power state).
*
* {@hide}
*/
public abstract long getMobileRadioActiveTime(long elapsedRealtimeUs, int which);
/**
* Returns the number of times that the mobile network has transitioned to the
* active state.
*
* {@hide}
*/
public abstract int getMobileRadioActiveCount(int which);
/**
* Returns the time in microseconds that is the difference between the mobile radio
* time we saw based on the elapsed timestamp when going down vs. the given time stamp
* from the radio.
*
* {@hide}
*/
public abstract long getMobileRadioActiveAdjustedTime(int which);
/**
* Returns the time in microseconds that the mobile network has been active
* (in a high power state) but not being able to blame on an app.
*
* {@hide}
*/
public abstract long getMobileRadioActiveUnknownTime(int which);
/**
* Return count of number of times radio was up that could not be blamed on apps.
*
* {@hide}
*/
public abstract int getMobileRadioActiveUnknownCount(int which);
public static final int DATA_CONNECTION_NONE = 0;
public static final int DATA_CONNECTION_GPRS = 1;
public static final int DATA_CONNECTION_EDGE = 2;
public static final int DATA_CONNECTION_UMTS = 3;
public static final int DATA_CONNECTION_CDMA = 4;
public static final int DATA_CONNECTION_EVDO_0 = 5;
public static final int DATA_CONNECTION_EVDO_A = 6;
public static final int DATA_CONNECTION_1xRTT = 7;
public static final int DATA_CONNECTION_HSDPA = 8;
public static final int DATA_CONNECTION_HSUPA = 9;
public static final int DATA_CONNECTION_HSPA = 10;
public static final int DATA_CONNECTION_IDEN = 11;
public static final int DATA_CONNECTION_EVDO_B = 12;
public static final int DATA_CONNECTION_LTE = 13;
public static final int DATA_CONNECTION_EHRPD = 14;
public static final int DATA_CONNECTION_HSPAP = 15;
public static final int DATA_CONNECTION_OTHER = 16;
static final String[] DATA_CONNECTION_NAMES = {
"none", "gprs", "edge", "umts", "cdma", "evdo_0", "evdo_A",
"1xrtt", "hsdpa", "hsupa", "hspa", "iden", "evdo_b", "lte",
"ehrpd", "hspap", "other"
};
public static final int NUM_DATA_CONNECTION_TYPES = DATA_CONNECTION_OTHER+1;
/**
* Returns the time in microseconds that the phone has been running with
* the given data connection.
*
* {@hide}
*/
public abstract long getPhoneDataConnectionTime(int dataType,
long elapsedRealtimeUs, int which);
/**
* Returns the number of times the phone has entered the given data
* connection type.
*
* {@hide}
*/
public abstract int getPhoneDataConnectionCount(int dataType, int which);
public static final int WIFI_SUPPL_STATE_INVALID = 0;
public static final int WIFI_SUPPL_STATE_DISCONNECTED = 1;
public static final int WIFI_SUPPL_STATE_INTERFACE_DISABLED = 2;
public static final int WIFI_SUPPL_STATE_INACTIVE = 3;
public static final int WIFI_SUPPL_STATE_SCANNING = 4;
public static final int WIFI_SUPPL_STATE_AUTHENTICATING = 5;
public static final int WIFI_SUPPL_STATE_ASSOCIATING = 6;
public static final int WIFI_SUPPL_STATE_ASSOCIATED = 7;
public static final int WIFI_SUPPL_STATE_FOUR_WAY_HANDSHAKE = 8;
public static final int WIFI_SUPPL_STATE_GROUP_HANDSHAKE = 9;
public static final int WIFI_SUPPL_STATE_COMPLETED = 10;
public static final int WIFI_SUPPL_STATE_DORMANT = 11;
public static final int WIFI_SUPPL_STATE_UNINITIALIZED = 12;
public static final int NUM_WIFI_SUPPL_STATES = WIFI_SUPPL_STATE_UNINITIALIZED+1;
static final String[] WIFI_SUPPL_STATE_NAMES = {
"invalid", "disconn", "disabled", "inactive", "scanning",
"authenticating", "associating", "associated", "4-way-handshake",
"group-handshake", "completed", "dormant", "uninit"
};
static final String[] WIFI_SUPPL_STATE_SHORT_NAMES = {
"inv", "dsc", "dis", "inact", "scan",
"auth", "ascing", "asced", "4-way",
"group", "compl", "dorm", "uninit"
};
public static final BitDescription[] HISTORY_STATE_DESCRIPTIONS
= new BitDescription[] {
new BitDescription(HistoryItem.STATE_CPU_RUNNING_FLAG, "running", "r"),
new BitDescription(HistoryItem.STATE_WAKE_LOCK_FLAG, "wake_lock", "w"),
new BitDescription(HistoryItem.STATE_SENSOR_ON_FLAG, "sensor", "s"),
new BitDescription(HistoryItem.STATE_GPS_ON_FLAG, "gps", "g"),
new BitDescription(HistoryItem.STATE_WIFI_FULL_LOCK_FLAG, "wifi_full_lock", "Wl"),
new BitDescription(HistoryItem.STATE_WIFI_SCAN_FLAG, "wifi_scan", "Ws"),
new BitDescription(HistoryItem.STATE_WIFI_MULTICAST_ON_FLAG, "wifi_multicast", "Wm"),
new BitDescription(HistoryItem.STATE_WIFI_RADIO_ACTIVE_FLAG, "wifi_radio", "Wr"),
new BitDescription(HistoryItem.STATE_MOBILE_RADIO_ACTIVE_FLAG, "mobile_radio", "Pr"),
new BitDescription(HistoryItem.STATE_PHONE_SCANNING_FLAG, "phone_scanning", "Psc"),
new BitDescription(HistoryItem.STATE_AUDIO_ON_FLAG, "audio", "a"),
new BitDescription(HistoryItem.STATE_SCREEN_ON_FLAG, "screen", "S"),
new BitDescription(HistoryItem.STATE_BATTERY_PLUGGED_FLAG, "plugged", "BP"),
new BitDescription(HistoryItem.STATE_DATA_CONNECTION_MASK,
HistoryItem.STATE_DATA_CONNECTION_SHIFT, "data_conn", "Pcn",
DATA_CONNECTION_NAMES, DATA_CONNECTION_NAMES),
new BitDescription(HistoryItem.STATE_PHONE_STATE_MASK,
HistoryItem.STATE_PHONE_STATE_SHIFT, "phone_state", "Pst",
new String[] {"in", "out", "emergency", "off"},
new String[] {"in", "out", "em", "off"}),
new BitDescription(HistoryItem.STATE_PHONE_SIGNAL_STRENGTH_MASK,
HistoryItem.STATE_PHONE_SIGNAL_STRENGTH_SHIFT, "phone_signal_strength", "Pss",
SignalStrength.SIGNAL_STRENGTH_NAMES,
new String[] { "0", "1", "2", "3", "4" }),
new BitDescription(HistoryItem.STATE_BRIGHTNESS_MASK,
HistoryItem.STATE_BRIGHTNESS_SHIFT, "brightness", "Sb",
SCREEN_BRIGHTNESS_NAMES, SCREEN_BRIGHTNESS_SHORT_NAMES),
};
public static final BitDescription[] HISTORY_STATE2_DESCRIPTIONS
= new BitDescription[] {
new BitDescription(HistoryItem.STATE2_POWER_SAVE_FLAG, "power_save", "ps"),
new BitDescription(HistoryItem.STATE2_VIDEO_ON_FLAG, "video", "v"),
new BitDescription(HistoryItem.STATE2_WIFI_RUNNING_FLAG, "wifi_running", "Ww"),
new BitDescription(HistoryItem.STATE2_WIFI_ON_FLAG, "wifi", "W"),
new BitDescription(HistoryItem.STATE2_FLASHLIGHT_FLAG, "flashlight", "fl"),
new BitDescription(HistoryItem.STATE2_DEVICE_IDLE_FLAG, "device_idle", "di"),
new BitDescription(HistoryItem.STATE2_CHARGING_FLAG, "charging", "ch"),
new BitDescription(HistoryItem.STATE2_PHONE_IN_CALL_FLAG, "phone_in_call", "Pcl"),
new BitDescription(HistoryItem.STATE2_BLUETOOTH_ON_FLAG, "bluetooth", "b"),
new BitDescription(HistoryItem.STATE2_WIFI_SIGNAL_STRENGTH_MASK,
HistoryItem.STATE2_WIFI_SIGNAL_STRENGTH_SHIFT, "wifi_signal_strength", "Wss",
new String[] { "0", "1", "2", "3", "4" },
new String[] { "0", "1", "2", "3", "4" }),
new BitDescription(HistoryItem.STATE2_WIFI_SUPPL_STATE_MASK,
HistoryItem.STATE2_WIFI_SUPPL_STATE_SHIFT, "wifi_suppl", "Wsp",
WIFI_SUPPL_STATE_NAMES, WIFI_SUPPL_STATE_SHORT_NAMES),
new BitDescription(HistoryItem.STATE2_CAMERA_FLAG, "camera", "ca"),
};
public static final String[] HISTORY_EVENT_NAMES = new String[] {
"null", "proc", "fg", "top", "sync", "wake_lock_in", "job", "user", "userfg", "conn",
"active", "pkginst", "pkgunin", "alarm", "stats", "inactive", "active"
};
public static final String[] HISTORY_EVENT_CHECKIN_NAMES = new String[] {
"Enl", "Epr", "Efg", "Etp", "Esy", "Ewl", "Ejb", "Eur", "Euf", "Ecn",
"Eac", "Epi", "Epu", "Eal", "Est", "Eai", "Eaa"
};
/**
* Returns the time in microseconds that wifi has been on while the device was
* running on battery.
*
* {@hide}
*/
public abstract long getWifiOnTime(long elapsedRealtimeUs, int which);
/**
* Returns the time in microseconds that wifi has been on and the driver has
* been in the running state while the device was running on battery.
*
* {@hide}
*/
public abstract long getGlobalWifiRunningTime(long elapsedRealtimeUs, int which);
public static final int WIFI_STATE_OFF = 0;
public static final int WIFI_STATE_OFF_SCANNING = 1;
public static final int WIFI_STATE_ON_NO_NETWORKS = 2;
public static final int WIFI_STATE_ON_DISCONNECTED = 3;
public static final int WIFI_STATE_ON_CONNECTED_STA = 4;
public static final int WIFI_STATE_ON_CONNECTED_P2P = 5;
public static final int WIFI_STATE_ON_CONNECTED_STA_P2P = 6;
public static final int WIFI_STATE_SOFT_AP = 7;
static final String[] WIFI_STATE_NAMES = {
"off", "scanning", "no_net", "disconn",
"sta", "p2p", "sta_p2p", "soft_ap"
};
public static final int NUM_WIFI_STATES = WIFI_STATE_SOFT_AP+1;
/**
* Returns the time in microseconds that WiFi has been running in the given state.
*
* {@hide}
*/
public abstract long getWifiStateTime(int wifiState,
long elapsedRealtimeUs, int which);
/**
* Returns the number of times that WiFi has entered the given state.
*
* {@hide}
*/
public abstract int getWifiStateCount(int wifiState, int which);
/**
* Returns the time in microseconds that the wifi supplicant has been
* in a given state.
*
* {@hide}
*/
public abstract long getWifiSupplStateTime(int state, long elapsedRealtimeUs, int which);
/**
* Returns the number of times that the wifi supplicant has transitioned
* to a given state.
*
* {@hide}
*/
public abstract int getWifiSupplStateCount(int state, int which);
public static final int NUM_WIFI_SIGNAL_STRENGTH_BINS = 5;
/**
* Returns the time in microseconds that WIFI has been running with
* the given signal strength.
*
* {@hide}
*/
public abstract long getWifiSignalStrengthTime(int strengthBin,
long elapsedRealtimeUs, int which);
/**
* Returns the number of times WIFI has entered the given signal strength.
*
* {@hide}
*/
public abstract int getWifiSignalStrengthCount(int strengthBin, int which);
/**
* Returns the time in microseconds that the flashlight has been on while the device was
* running on battery.
*
* {@hide}
*/
public abstract long getFlashlightOnTime(long elapsedRealtimeUs, int which);
/**
* Returns the number of times that the flashlight has been turned on while the device was
* running on battery.
*
* {@hide}
*/
public abstract long getFlashlightOnCount(int which);
/**
* Returns the time in microseconds that the camera has been on while the device was
* running on battery.
*
* {@hide}
*/
public abstract long getCameraOnTime(long elapsedRealtimeUs, int which);
public static final int NETWORK_MOBILE_RX_DATA = 0;
public static final int NETWORK_MOBILE_TX_DATA = 1;
public static final int NETWORK_WIFI_RX_DATA = 2;
public static final int NETWORK_WIFI_TX_DATA = 3;
public static final int NUM_NETWORK_ACTIVITY_TYPES = NETWORK_WIFI_TX_DATA + 1;
public abstract long getNetworkActivityBytes(int type, int which);
public abstract long getNetworkActivityPackets(int type, int which);
public static final int CONTROLLER_IDLE_TIME = 0;
public static final int CONTROLLER_RX_TIME = 1;
public static final int CONTROLLER_TX_TIME = 2;
public static final int CONTROLLER_POWER_DRAIN = 3;
public static final int NUM_CONTROLLER_ACTIVITY_TYPES = CONTROLLER_POWER_DRAIN + 1;
/**
* Returns true if the BatteryStats object has detailed bluetooth power reports.
* When true, calling {@link #getBluetoothControllerActivity(int, int)} will yield the
* actual power data.
*/
public abstract boolean hasBluetoothActivityReporting();
/**
* For {@link #CONTROLLER_IDLE_TIME}, {@link #CONTROLLER_RX_TIME}, and
* {@link #CONTROLLER_TX_TIME}, returns the time spent (in milliseconds) in the
* respective state.
* For {@link #CONTROLLER_POWER_DRAIN}, returns the power used by the controller in
* milli-ampere-milliseconds (mAms).
*/
public abstract long getBluetoothControllerActivity(int type, int which);
/**
* Returns true if the BatteryStats object has detailed WiFi power reports.
* When true, calling {@link #getWifiControllerActivity(int, int)} will yield the
* actual power data.
*/
public abstract boolean hasWifiActivityReporting();
/**
* For {@link #CONTROLLER_IDLE_TIME}, {@link #CONTROLLER_RX_TIME}, and
* {@link #CONTROLLER_TX_TIME}, returns the time spent (in milliseconds) in the
* respective state.
* For {@link #CONTROLLER_POWER_DRAIN}, returns the power used by the controller in
* milli-ampere-milliseconds (mAms).
*/
public abstract long getWifiControllerActivity(int type, int which);
/**
* Return the wall clock time when battery stats data collection started.
*/
public abstract long getStartClockTime();
/**
* Return platform version tag that we were running in when the battery stats started.
*/
public abstract String getStartPlatformVersion();
/**
* Return platform version tag that we were running in when the battery stats ended.
*/
public abstract String getEndPlatformVersion();
/**
* Return the internal version code of the parcelled format.
*/
public abstract int getParcelVersion();
/**
* Return whether we are currently running on battery.
*/
public abstract boolean getIsOnBattery();
/**
* Returns a SparseArray containing the statistics for each uid.
*/
public abstract SparseArray<? extends Uid> getUidStats();
/**
* Returns the current battery uptime in microseconds.
*
* @param curTime the amount of elapsed realtime in microseconds.
*/
public abstract long getBatteryUptime(long curTime);
/**
* Returns the current battery realtime in microseconds.
*
* @param curTime the amount of elapsed realtime in microseconds.
*/
public abstract long getBatteryRealtime(long curTime);
/**
* Returns the battery percentage level at the last time the device was unplugged from power, or
* the last time it booted on battery power.
*/
public abstract int getDischargeStartLevel();
/**
* Returns the current battery percentage level if we are in a discharge cycle, otherwise
* returns the level at the last plug event.
*/
public abstract int getDischargeCurrentLevel();
/**
* Get the amount the battery has discharged since the stats were
* last reset after charging, as a lower-end approximation.
*/
public abstract int getLowDischargeAmountSinceCharge();
/**
* Get the amount the battery has discharged since the stats were
* last reset after charging, as an upper-end approximation.
*/
public abstract int getHighDischargeAmountSinceCharge();
/**
* Retrieve the discharge amount over the selected discharge period <var>which</var>.
*/
public abstract int getDischargeAmount(int which);
/**
* Get the amount the battery has discharged while the screen was on,
* since the last time power was unplugged.
*/
public abstract int getDischargeAmountScreenOn();
/**
* Get the amount the battery has discharged while the screen was on,
* since the last time the device was charged.
*/
public abstract int getDischargeAmountScreenOnSinceCharge();
/**
* Get the amount the battery has discharged while the screen was off,
* since the last time power was unplugged.
*/
public abstract int getDischargeAmountScreenOff();
/**
* Get the amount the battery has discharged while the screen was off,
* since the last time the device was charged.
*/
public abstract int getDischargeAmountScreenOffSinceCharge();
/**
* Returns the total, last, or current battery uptime in microseconds.
*
* @param curTime the elapsed realtime in microseconds.
* @param which one of STATS_SINCE_CHARGED, STATS_SINCE_UNPLUGGED, or STATS_CURRENT.
*/
public abstract long computeBatteryUptime(long curTime, int which);
/**
* Returns the total, last, or current battery realtime in microseconds.
*
* @param curTime the current elapsed realtime in microseconds.
* @param which one of STATS_SINCE_CHARGED, STATS_SINCE_UNPLUGGED, or STATS_CURRENT.
*/
public abstract long computeBatteryRealtime(long curTime, int which);
/**
* Returns the total, last, or current battery screen off uptime in microseconds.
*
* @param curTime the elapsed realtime in microseconds.
* @param which one of STATS_SINCE_CHARGED, STATS_SINCE_UNPLUGGED, or STATS_CURRENT.
*/
public abstract long computeBatteryScreenOffUptime(long curTime, int which);
/**
* Returns the total, last, or current battery screen off realtime in microseconds.
*
* @param curTime the current elapsed realtime in microseconds.
* @param which one of STATS_SINCE_CHARGED, STATS_SINCE_UNPLUGGED, or STATS_CURRENT.
*/
public abstract long computeBatteryScreenOffRealtime(long curTime, int which);
/**
* Returns the total, last, or current uptime in microseconds.
*
* @param curTime the current elapsed realtime in microseconds.
* @param which one of STATS_SINCE_CHARGED, STATS_SINCE_UNPLUGGED, or STATS_CURRENT.
*/
public abstract long computeUptime(long curTime, int which);
/**
* Returns the total, last, or current realtime in microseconds.
*
* @param curTime the current elapsed realtime in microseconds.
* @param which one of STATS_SINCE_CHARGED, STATS_SINCE_UNPLUGGED, or STATS_CURRENT.
*/
public abstract long computeRealtime(long curTime, int which);
/**
* Compute an approximation for how much run time (in microseconds) is remaining on
* the battery. Returns -1 if no time can be computed: either there is not
* enough current data to make a decision, or the battery is currently
* charging.
*
* @param curTime The current elepsed realtime in microseconds.
*/
public abstract long computeBatteryTimeRemaining(long curTime);
// The part of a step duration that is the actual time.
public static final long STEP_LEVEL_TIME_MASK = 0x000000ffffffffffL;
// Bits in a step duration that are the new battery level we are at.
public static final long STEP_LEVEL_LEVEL_MASK = 0x0000ff0000000000L;
public static final int STEP_LEVEL_LEVEL_SHIFT = 40;
// Bits in a step duration that are the initial mode we were in at that step.
public static final long STEP_LEVEL_INITIAL_MODE_MASK = 0x00ff000000000000L;
public static final int STEP_LEVEL_INITIAL_MODE_SHIFT = 48;
// Bits in a step duration that indicate which modes changed during that step.
public static final long STEP_LEVEL_MODIFIED_MODE_MASK = 0xff00000000000000L;
public static final int STEP_LEVEL_MODIFIED_MODE_SHIFT = 56;
// Step duration mode: the screen is on, off, dozed, etc; value is Display.STATE_* - 1.
public static final int STEP_LEVEL_MODE_SCREEN_STATE = 0x03;
// Step duration mode: power save is on.
public static final int STEP_LEVEL_MODE_POWER_SAVE = 0x04;
// Step duration mode: device is currently in idle mode.
public static final int STEP_LEVEL_MODE_DEVICE_IDLE = 0x08;
public static final int[] STEP_LEVEL_MODES_OF_INTEREST = new int[] {
STEP_LEVEL_MODE_SCREEN_STATE|STEP_LEVEL_MODE_POWER_SAVE,
STEP_LEVEL_MODE_SCREEN_STATE|STEP_LEVEL_MODE_POWER_SAVE|STEP_LEVEL_MODE_DEVICE_IDLE,
STEP_LEVEL_MODE_SCREEN_STATE|STEP_LEVEL_MODE_DEVICE_IDLE,
STEP_LEVEL_MODE_SCREEN_STATE|STEP_LEVEL_MODE_POWER_SAVE,
STEP_LEVEL_MODE_SCREEN_STATE|STEP_LEVEL_MODE_POWER_SAVE,
STEP_LEVEL_MODE_SCREEN_STATE|STEP_LEVEL_MODE_POWER_SAVE,
STEP_LEVEL_MODE_SCREEN_STATE|STEP_LEVEL_MODE_POWER_SAVE,
STEP_LEVEL_MODE_SCREEN_STATE|STEP_LEVEL_MODE_POWER_SAVE,
STEP_LEVEL_MODE_SCREEN_STATE|STEP_LEVEL_MODE_POWER_SAVE|STEP_LEVEL_MODE_DEVICE_IDLE,
STEP_LEVEL_MODE_SCREEN_STATE|STEP_LEVEL_MODE_DEVICE_IDLE,
};
public static final int[] STEP_LEVEL_MODE_VALUES = new int[] {
(Display.STATE_OFF-1),
(Display.STATE_OFF-1)|STEP_LEVEL_MODE_POWER_SAVE,
(Display.STATE_OFF-1)|STEP_LEVEL_MODE_DEVICE_IDLE,
(Display.STATE_ON-1),
(Display.STATE_ON-1)|STEP_LEVEL_MODE_POWER_SAVE,
(Display.STATE_DOZE-1),
(Display.STATE_DOZE-1)|STEP_LEVEL_MODE_POWER_SAVE,
(Display.STATE_DOZE_SUSPEND-1),
(Display.STATE_DOZE_SUSPEND-1)|STEP_LEVEL_MODE_POWER_SAVE,
(Display.STATE_DOZE_SUSPEND-1)|STEP_LEVEL_MODE_DEVICE_IDLE,
};
public static final String[] STEP_LEVEL_MODE_LABELS = new String[] {
"screen off",
"screen off power save",
"screen off device idle",
"screen on",
"screen on power save",
"screen doze",
"screen doze power save",
"screen doze-suspend",
"screen doze-suspend power save",
"screen doze-suspend device idle",
};
/**
* Return the array of discharge step durations.
*/
public abstract LevelStepTracker getDischargeLevelStepTracker();
/**
* Return the array of daily discharge step durations.
*/
public abstract LevelStepTracker getDailyDischargeLevelStepTracker();
/**
* Compute an approximation for how much time (in microseconds) remains until the battery
* is fully charged. Returns -1 if no time can be computed: either there is not
* enough current data to make a decision, or the battery is currently
* discharging.
*
* @param curTime The current elepsed realtime in microseconds.
*/
public abstract long computeChargeTimeRemaining(long curTime);
/**
* Return the array of charge step durations.
*/
public abstract LevelStepTracker getChargeLevelStepTracker();
/**
* Return the array of daily charge step durations.
*/
public abstract LevelStepTracker getDailyChargeLevelStepTracker();
public abstract ArrayList<PackageChange> getDailyPackageChanges();
public abstract Map<String, ? extends Timer> getWakeupReasonStats();
public abstract Map<String, ? extends Timer> getKernelWakelockStats();
/** Returns the number of different speeds that the CPU can run at */
public abstract int getCpuSpeedSteps();
public abstract void writeToParcelWithoutUids(Parcel out, int flags);
private final static void formatTimeRaw(StringBuilder out, long seconds) {
long days = seconds / (60 * 60 * 24);
if (days != 0) {
out.append(days);
out.append("d ");
}
long used = days * 60 * 60 * 24;
long hours = (seconds - used) / (60 * 60);
if (hours != 0 || used != 0) {
out.append(hours);
out.append("h ");
}
used += hours * 60 * 60;
long mins = (seconds-used) / 60;
if (mins != 0 || used != 0) {
out.append(mins);
out.append("m ");
}
used += mins * 60;
if (seconds != 0 || used != 0) {
out.append(seconds-used);
out.append("s ");
}
}
public final static void formatTimeMs(StringBuilder sb, long time) {
long sec = time / 1000;
formatTimeRaw(sb, sec);
sb.append(time - (sec * 1000));
sb.append("ms ");
}
public final static void formatTimeMsNoSpace(StringBuilder sb, long time) {
long sec = time / 1000;
formatTimeRaw(sb, sec);
sb.append(time - (sec * 1000));
sb.append("ms");
}
public final String formatRatioLocked(long num, long den) {
if (den == 0L) {
return "--%";
}
float perc = ((float)num) / ((float)den) * 100;
mFormatBuilder.setLength(0);
mFormatter.format("%.1f%%", perc);
return mFormatBuilder.toString();
}
final String formatBytesLocked(long bytes) {
mFormatBuilder.setLength(0);
if (bytes < BYTES_PER_KB) {
return bytes + "B";
} else if (bytes < BYTES_PER_MB) {
mFormatter.format("%.2fKB", bytes / (double) BYTES_PER_KB);
return mFormatBuilder.toString();
} else if (bytes < BYTES_PER_GB){
mFormatter.format("%.2fMB", bytes / (double) BYTES_PER_MB);
return mFormatBuilder.toString();
} else {
mFormatter.format("%.2fGB", bytes / (double) BYTES_PER_GB);
return mFormatBuilder.toString();
}
}
private static long computeWakeLock(Timer timer, long elapsedRealtimeUs, int which) {
if (timer != null) {
// Convert from microseconds to milliseconds with rounding
long totalTimeMicros = timer.getTotalTimeLocked(elapsedRealtimeUs, which);
long totalTimeMillis = (totalTimeMicros + 500) / 1000;
return totalTimeMillis;
}
return 0;
}
/**
*
* @param sb a StringBuilder object.
* @param timer a Timer object contining the wakelock times.
* @param elapsedRealtimeUs the current on-battery time in microseconds.
* @param name the name of the wakelock.
* @param which which one of STATS_SINCE_CHARGED, STATS_SINCE_UNPLUGGED, or STATS_CURRENT.
* @param linePrefix a String to be prepended to each line of output.
* @return the line prefix
*/
private static final String printWakeLock(StringBuilder sb, Timer timer,
long elapsedRealtimeUs, String name, int which, String linePrefix) {
if (timer != null) {
long totalTimeMillis = computeWakeLock(timer, elapsedRealtimeUs, which);
int count = timer.getCountLocked(which);
if (totalTimeMillis != 0) {
sb.append(linePrefix);
formatTimeMs(sb, totalTimeMillis);
if (name != null) {
sb.append(name);
sb.append(' ');
}
sb.append('(');
sb.append(count);
sb.append(" times)");
return ", ";
}
}
return linePrefix;
}
/**
*
* @param pw a PrintWriter object to print to.
* @param sb a StringBuilder object.
* @param timer a Timer object contining the wakelock times.
* @param rawRealtime the current on-battery time in microseconds.
* @param which which one of STATS_SINCE_CHARGED, STATS_SINCE_UNPLUGGED, or STATS_CURRENT.
* @param prefix a String to be prepended to each line of output.
* @param type the name of the timer.
*/
private static final boolean printTimer(PrintWriter pw, StringBuilder sb, Timer timer,
long rawRealtime, int which, String prefix, String type) {
if (timer != null) {
// Convert from microseconds to milliseconds with rounding
final long totalTime = (timer.getTotalTimeLocked(
rawRealtime, which) + 500) / 1000;
final int count = timer.getCountLocked(which);
if (totalTime != 0) {
sb.setLength(0);
sb.append(prefix);
sb.append(" ");
sb.append(type);
sb.append(": ");
formatTimeMs(sb, totalTime);
sb.append("realtime (");
sb.append(count);
sb.append(" times)");
pw.println(sb.toString());
return true;
}
}
return false;
}
/**
* Checkin version of wakelock printer. Prints simple comma-separated list.
*
* @param sb a StringBuilder object.
* @param timer a Timer object contining the wakelock times.
* @param elapsedRealtimeUs the current time in microseconds.
* @param name the name of the wakelock.
* @param which which one of STATS_SINCE_CHARGED, STATS_SINCE_UNPLUGGED, or STATS_CURRENT.
* @param linePrefix a String to be prepended to each line of output.
* @return the line prefix
*/
private static final String printWakeLockCheckin(StringBuilder sb, Timer timer,
long elapsedRealtimeUs, String name, int which, String linePrefix) {
long totalTimeMicros = 0;
int count = 0;
if (timer != null) {
totalTimeMicros = timer.getTotalTimeLocked(elapsedRealtimeUs, which);
count = timer.getCountLocked(which);
}
sb.append(linePrefix);
sb.append((totalTimeMicros + 500) / 1000); // microseconds to milliseconds with rounding
sb.append(',');
sb.append(name != null ? name + "," : "");
sb.append(count);
return ",";
}
/**
* Dump a comma-separated line of values for terse checkin mode.
*
* @param pw the PageWriter to dump log to
* @param category category of data (e.g. "total", "last", "unplugged", "current" )
* @param type type of data (e.g. "wakelock", "sensor", "process", "apk" , "process", "network")
* @param args type-dependent data arguments
*/
private static final void dumpLine(PrintWriter pw, int uid, String category, String type,
Object... args ) {
pw.print(BATTERY_STATS_CHECKIN_VERSION);
pw.print(',');
pw.print(uid);
pw.print(',');
pw.print(category);
pw.print(',');
pw.print(type);
for (Object arg : args) {
pw.print(',');
pw.print(arg);
}
pw.println();
}
/**
* Dump a given timer stat for terse checkin mode.
*
* @param pw the PageWriter to dump log to
* @param uid the UID to log
* @param category category of data (e.g. "total", "last", "unplugged", "current" )
* @param type type of data (e.g. "wakelock", "sensor", "process", "apk" , "process", "network")
* @param timer a {@link Timer} to dump stats for
* @param rawRealtime the current elapsed realtime of the system in microseconds
* @param which one of STATS_SINCE_CHARGED, STATS_SINCE_UNPLUGGED, or STATS_CURRENT
*/
private static final void dumpTimer(PrintWriter pw, int uid, String category, String type,
Timer timer, long rawRealtime, int which) {
if (timer != null) {
// Convert from microseconds to milliseconds with rounding
final long totalTime = (timer.getTotalTimeLocked(rawRealtime, which) + 500)
/ 1000;
final int count = timer.getCountLocked(which);
if (totalTime != 0) {
dumpLine(pw, uid, category, type, totalTime, count);
}
}
}
/**
* Temporary for settings.
*/
public final void dumpCheckinLocked(Context context, PrintWriter pw, int which, int reqUid) {
dumpCheckinLocked(context, pw, which, reqUid, BatteryStatsHelper.checkWifiOnly(context));
}
/**
* Checkin server version of dump to produce more compact, computer-readable log.
*
* NOTE: all times are expressed in 'ms'.
*/
public final void dumpCheckinLocked(Context context, PrintWriter pw, int which, int reqUid,
boolean wifiOnly) {
final long rawUptime = SystemClock.uptimeMillis() * 1000;
final long rawRealtime = SystemClock.elapsedRealtime() * 1000;
final long batteryUptime = getBatteryUptime(rawUptime);
final long whichBatteryUptime = computeBatteryUptime(rawUptime, which);
final long whichBatteryRealtime = computeBatteryRealtime(rawRealtime, which);
final long whichBatteryScreenOffUptime = computeBatteryScreenOffUptime(rawUptime, which);
final long whichBatteryScreenOffRealtime = computeBatteryScreenOffRealtime(rawRealtime,
which);
final long totalRealtime = computeRealtime(rawRealtime, which);
final long totalUptime = computeUptime(rawUptime, which);
final long screenOnTime = getScreenOnTime(rawRealtime, which);
final long interactiveTime = getInteractiveTime(rawRealtime, which);
final long powerSaveModeEnabledTime = getPowerSaveModeEnabledTime(rawRealtime, which);
final long deviceIdleModeEnabledTime = getDeviceIdleModeEnabledTime(rawRealtime, which);
final long deviceIdlingTime = getDeviceIdlingTime(rawRealtime, which);
final int connChanges = getNumConnectivityChange(which);
final long phoneOnTime = getPhoneOnTime(rawRealtime, which);
final StringBuilder sb = new StringBuilder(128);
final SparseArray<? extends Uid> uidStats = getUidStats();
final int NU = uidStats.size();
final String category = STAT_NAMES[which];
// Dump "battery" stat
dumpLine(pw, 0 /* uid */, category, BATTERY_DATA,
which == STATS_SINCE_CHARGED ? getStartCount() : "N/A",
whichBatteryRealtime / 1000, whichBatteryUptime / 1000,
totalRealtime / 1000, totalUptime / 1000,
getStartClockTime(),
whichBatteryScreenOffRealtime / 1000, whichBatteryScreenOffUptime / 1000);
// Calculate wakelock times across all uids.
long fullWakeLockTimeTotal = 0;
long partialWakeLockTimeTotal = 0;
for (int iu = 0; iu < NU; iu++) {
final Uid u = uidStats.valueAt(iu);
final ArrayMap<String, ? extends BatteryStats.Uid.Wakelock> wakelocks
= u.getWakelockStats();
for (int iw=wakelocks.size()-1; iw>=0; iw--) {
final Uid.Wakelock wl = wakelocks.valueAt(iw);
final Timer fullWakeTimer = wl.getWakeTime(WAKE_TYPE_FULL);
if (fullWakeTimer != null) {
fullWakeLockTimeTotal += fullWakeTimer.getTotalTimeLocked(rawRealtime,
which);
}
final Timer partialWakeTimer = wl.getWakeTime(WAKE_TYPE_PARTIAL);
if (partialWakeTimer != null) {
partialWakeLockTimeTotal += partialWakeTimer.getTotalTimeLocked(
rawRealtime, which);
}
}
}
// Dump network stats
final long mobileRxTotalBytes = getNetworkActivityBytes(NETWORK_MOBILE_RX_DATA, which);
final long mobileTxTotalBytes = getNetworkActivityBytes(NETWORK_MOBILE_TX_DATA, which);
final long wifiRxTotalBytes = getNetworkActivityBytes(NETWORK_WIFI_RX_DATA, which);
final long wifiTxTotalBytes = getNetworkActivityBytes(NETWORK_WIFI_TX_DATA, which);
final long mobileRxTotalPackets = getNetworkActivityPackets(NETWORK_MOBILE_RX_DATA, which);
final long mobileTxTotalPackets = getNetworkActivityPackets(NETWORK_MOBILE_TX_DATA, which);
final long wifiRxTotalPackets = getNetworkActivityPackets(NETWORK_WIFI_RX_DATA, which);
final long wifiTxTotalPackets = getNetworkActivityPackets(NETWORK_WIFI_TX_DATA, which);
dumpLine(pw, 0 /* uid */, category, GLOBAL_NETWORK_DATA,
mobileRxTotalBytes, mobileTxTotalBytes, wifiRxTotalBytes, wifiTxTotalBytes,
mobileRxTotalPackets, mobileTxTotalPackets, wifiRxTotalPackets, wifiTxTotalPackets);
// Dump Wifi controller stats
final long wifiOnTime = getWifiOnTime(rawRealtime, which);
final long wifiRunningTime = getGlobalWifiRunningTime(rawRealtime, which);
final long wifiIdleTimeMs = getWifiControllerActivity(CONTROLLER_IDLE_TIME, which);
final long wifiRxTimeMs = getWifiControllerActivity(CONTROLLER_RX_TIME, which);
final long wifiTxTimeMs = getWifiControllerActivity(CONTROLLER_TX_TIME, which);
final long wifiPowerMaMs = getWifiControllerActivity(CONTROLLER_POWER_DRAIN, which);
dumpLine(pw, 0 /* uid */, category, GLOBAL_WIFI_DATA,
wifiOnTime / 1000, wifiRunningTime / 1000,
wifiIdleTimeMs, wifiRxTimeMs, wifiTxTimeMs, wifiPowerMaMs / (1000*60*60));
// Dump Bluetooth controller stats
final long btIdleTimeMs = getBluetoothControllerActivity(CONTROLLER_IDLE_TIME, which);
final long btRxTimeMs = getBluetoothControllerActivity(CONTROLLER_RX_TIME, which);
final long btTxTimeMs = getBluetoothControllerActivity(CONTROLLER_TX_TIME, which);
final long btPowerMaMs = getBluetoothControllerActivity(CONTROLLER_POWER_DRAIN, which);
dumpLine(pw, 0 /* uid */, category, GLOBAL_BLUETOOTH_DATA,
btIdleTimeMs, btRxTimeMs, btTxTimeMs, btPowerMaMs / (1000*60*60));
// Dump misc stats
dumpLine(pw, 0 /* uid */, category, MISC_DATA,
screenOnTime / 1000, phoneOnTime / 1000,
fullWakeLockTimeTotal / 1000, partialWakeLockTimeTotal / 1000,
getMobileRadioActiveTime(rawRealtime, which) / 1000,
getMobileRadioActiveAdjustedTime(which) / 1000, interactiveTime / 1000,
powerSaveModeEnabledTime / 1000, connChanges, deviceIdleModeEnabledTime / 1000,
getDeviceIdleModeEnabledCount(which), deviceIdlingTime / 1000,
getDeviceIdlingCount(which));
// Dump screen brightness stats
Object[] args = new Object[NUM_SCREEN_BRIGHTNESS_BINS];
for (int i=0; i<NUM_SCREEN_BRIGHTNESS_BINS; i++) {
args[i] = getScreenBrightnessTime(i, rawRealtime, which) / 1000;
}
dumpLine(pw, 0 /* uid */, category, SCREEN_BRIGHTNESS_DATA, args);
// Dump signal strength stats
args = new Object[SignalStrength.NUM_SIGNAL_STRENGTH_BINS];
for (int i=0; i<SignalStrength.NUM_SIGNAL_STRENGTH_BINS; i++) {
args[i] = getPhoneSignalStrengthTime(i, rawRealtime, which) / 1000;
}
dumpLine(pw, 0 /* uid */, category, SIGNAL_STRENGTH_TIME_DATA, args);
dumpLine(pw, 0 /* uid */, category, SIGNAL_SCANNING_TIME_DATA,
getPhoneSignalScanningTime(rawRealtime, which) / 1000);
for (int i=0; i<SignalStrength.NUM_SIGNAL_STRENGTH_BINS; i++) {
args[i] = getPhoneSignalStrengthCount(i, which);
}
dumpLine(pw, 0 /* uid */, category, SIGNAL_STRENGTH_COUNT_DATA, args);
// Dump network type stats
args = new Object[NUM_DATA_CONNECTION_TYPES];
for (int i=0; i<NUM_DATA_CONNECTION_TYPES; i++) {
args[i] = getPhoneDataConnectionTime(i, rawRealtime, which) / 1000;
}
dumpLine(pw, 0 /* uid */, category, DATA_CONNECTION_TIME_DATA, args);
for (int i=0; i<NUM_DATA_CONNECTION_TYPES; i++) {
args[i] = getPhoneDataConnectionCount(i, which);
}
dumpLine(pw, 0 /* uid */, category, DATA_CONNECTION_COUNT_DATA, args);
// Dump wifi state stats
args = new Object[NUM_WIFI_STATES];
for (int i=0; i<NUM_WIFI_STATES; i++) {
args[i] = getWifiStateTime(i, rawRealtime, which) / 1000;
}
dumpLine(pw, 0 /* uid */, category, WIFI_STATE_TIME_DATA, args);
for (int i=0; i<NUM_WIFI_STATES; i++) {
args[i] = getWifiStateCount(i, which);
}
dumpLine(pw, 0 /* uid */, category, WIFI_STATE_COUNT_DATA, args);
// Dump wifi suppl state stats
args = new Object[NUM_WIFI_SUPPL_STATES];
for (int i=0; i<NUM_WIFI_SUPPL_STATES; i++) {
args[i] = getWifiSupplStateTime(i, rawRealtime, which) / 1000;
}
dumpLine(pw, 0 /* uid */, category, WIFI_SUPPL_STATE_TIME_DATA, args);
for (int i=0; i<NUM_WIFI_SUPPL_STATES; i++) {
args[i] = getWifiSupplStateCount(i, which);
}
dumpLine(pw, 0 /* uid */, category, WIFI_SUPPL_STATE_COUNT_DATA, args);
// Dump wifi signal strength stats
args = new Object[NUM_WIFI_SIGNAL_STRENGTH_BINS];
for (int i=0; i<NUM_WIFI_SIGNAL_STRENGTH_BINS; i++) {
args[i] = getWifiSignalStrengthTime(i, rawRealtime, which) / 1000;
}
dumpLine(pw, 0 /* uid */, category, WIFI_SIGNAL_STRENGTH_TIME_DATA, args);
for (int i=0; i<NUM_WIFI_SIGNAL_STRENGTH_BINS; i++) {
args[i] = getWifiSignalStrengthCount(i, which);
}
dumpLine(pw, 0 /* uid */, category, WIFI_SIGNAL_STRENGTH_COUNT_DATA, args);
if (which == STATS_SINCE_UNPLUGGED) {
dumpLine(pw, 0 /* uid */, category, BATTERY_LEVEL_DATA, getDischargeStartLevel(),
getDischargeCurrentLevel());
}
if (which == STATS_SINCE_UNPLUGGED) {
dumpLine(pw, 0 /* uid */, category, BATTERY_DISCHARGE_DATA,
getDischargeStartLevel()-getDischargeCurrentLevel(),
getDischargeStartLevel()-getDischargeCurrentLevel(),
getDischargeAmountScreenOn(), getDischargeAmountScreenOff());
} else {
dumpLine(pw, 0 /* uid */, category, BATTERY_DISCHARGE_DATA,
getLowDischargeAmountSinceCharge(), getHighDischargeAmountSinceCharge(),
getDischargeAmountScreenOnSinceCharge(),
getDischargeAmountScreenOffSinceCharge());
}
if (reqUid < 0) {
final Map<String, ? extends Timer> kernelWakelocks = getKernelWakelockStats();
if (kernelWakelocks.size() > 0) {
for (Map.Entry<String, ? extends Timer> ent : kernelWakelocks.entrySet()) {
sb.setLength(0);
printWakeLockCheckin(sb, ent.getValue(), rawRealtime, null, which, "");
dumpLine(pw, 0 /* uid */, category, KERNEL_WAKELOCK_DATA, ent.getKey(),
sb.toString());
}
}
final Map<String, ? extends Timer> wakeupReasons = getWakeupReasonStats();
if (wakeupReasons.size() > 0) {
for (Map.Entry<String, ? extends Timer> ent : wakeupReasons.entrySet()) {
// Not doing the regular wake lock formatting to remain compatible
// with the old checkin format.
long totalTimeMicros = ent.getValue().getTotalTimeLocked(rawRealtime, which);
int count = ent.getValue().getCountLocked(which);
dumpLine(pw, 0 /* uid */, category, WAKEUP_REASON_DATA,
"\"" + ent.getKey() + "\"", (totalTimeMicros + 500) / 1000, count);
}
}
}
final BatteryStatsHelper helper = new BatteryStatsHelper(context, false, wifiOnly);
helper.create(this);
helper.refreshStats(which, UserHandle.USER_ALL);
final List<BatterySipper> sippers = helper.getUsageList();
if (sippers != null && sippers.size() > 0) {
dumpLine(pw, 0 /* uid */, category, POWER_USE_SUMMARY_DATA,
BatteryStatsHelper.makemAh(helper.getPowerProfile().getBatteryCapacity()),
BatteryStatsHelper.makemAh(helper.getComputedPower()),
BatteryStatsHelper.makemAh(helper.getMinDrainedPower()),
BatteryStatsHelper.makemAh(helper.getMaxDrainedPower()));
for (int i=0; i<sippers.size(); i++) {
final BatterySipper bs = sippers.get(i);
int uid = 0;
String label;
switch (bs.drainType) {
case IDLE:
label="idle";
break;
case CELL:
label="cell";
break;
case PHONE:
label="phone";
break;
case WIFI:
label="wifi";
break;
case BLUETOOTH:
label="blue";
break;
case SCREEN:
label="scrn";
break;
case FLASHLIGHT:
label="flashlight";
break;
case APP:
uid = bs.uidObj.getUid();
label = "uid";
break;
case USER:
uid = UserHandle.getUid(bs.userId, 0);
label = "user";
break;
case UNACCOUNTED:
label = "unacc";
break;
case OVERCOUNTED:
label = "over";
break;
case CAMERA:
label = "camera";
break;
default:
label = "???";
}
dumpLine(pw, uid, category, POWER_USE_ITEM_DATA, label,
BatteryStatsHelper.makemAh(bs.totalPowerMah));
}
}
for (int iu = 0; iu < NU; iu++) {
final int uid = uidStats.keyAt(iu);
if (reqUid >= 0 && uid != reqUid) {
continue;
}
final Uid u = uidStats.valueAt(iu);
// Dump Network stats per uid, if any
final long mobileBytesRx = u.getNetworkActivityBytes(NETWORK_MOBILE_RX_DATA, which);
final long mobileBytesTx = u.getNetworkActivityBytes(NETWORK_MOBILE_TX_DATA, which);
final long wifiBytesRx = u.getNetworkActivityBytes(NETWORK_WIFI_RX_DATA, which);
final long wifiBytesTx = u.getNetworkActivityBytes(NETWORK_WIFI_TX_DATA, which);
final long mobilePacketsRx = u.getNetworkActivityPackets(NETWORK_MOBILE_RX_DATA, which);
final long mobilePacketsTx = u.getNetworkActivityPackets(NETWORK_MOBILE_TX_DATA, which);
final long mobileActiveTime = u.getMobileRadioActiveTime(which);
final int mobileActiveCount = u.getMobileRadioActiveCount(which);
final long wifiPacketsRx = u.getNetworkActivityPackets(NETWORK_WIFI_RX_DATA, which);
final long wifiPacketsTx = u.getNetworkActivityPackets(NETWORK_WIFI_TX_DATA, which);
if (mobileBytesRx > 0 || mobileBytesTx > 0 || wifiBytesRx > 0 || wifiBytesTx > 0
|| mobilePacketsRx > 0 || mobilePacketsTx > 0 || wifiPacketsRx > 0
|| wifiPacketsTx > 0 || mobileActiveTime > 0 || mobileActiveCount > 0) {
dumpLine(pw, uid, category, NETWORK_DATA, mobileBytesRx, mobileBytesTx,
wifiBytesRx, wifiBytesTx,
mobilePacketsRx, mobilePacketsTx,
wifiPacketsRx, wifiPacketsTx,
mobileActiveTime, mobileActiveCount);
}
final long fullWifiLockOnTime = u.getFullWifiLockTime(rawRealtime, which);
final long wifiScanTime = u.getWifiScanTime(rawRealtime, which);
final int wifiScanCount = u.getWifiScanCount(which);
final long uidWifiRunningTime = u.getWifiRunningTime(rawRealtime, which);
final long uidWifiIdleTimeMs = u.getWifiControllerActivity(CONTROLLER_IDLE_TIME, which);
final long uidWifiRxTimeMs = u.getWifiControllerActivity(CONTROLLER_RX_TIME, which);
final long uidWifiTxTimeMs = u.getWifiControllerActivity(CONTROLLER_TX_TIME, which);
if (fullWifiLockOnTime != 0 || wifiScanTime != 0 || wifiScanCount != 0
|| uidWifiRunningTime != 0 || uidWifiIdleTimeMs != 0 || uidWifiRxTimeMs != 0
|| uidWifiTxTimeMs != 0) {
dumpLine(pw, uid, category, WIFI_DATA,
fullWifiLockOnTime, wifiScanTime, uidWifiRunningTime, wifiScanCount,
uidWifiIdleTimeMs, uidWifiRxTimeMs, uidWifiTxTimeMs);
}
if (u.hasUserActivity()) {
args = new Object[Uid.NUM_USER_ACTIVITY_TYPES];
boolean hasData = false;
for (int i=0; i<Uid.NUM_USER_ACTIVITY_TYPES; i++) {
int val = u.getUserActivityCount(i, which);
args[i] = val;
if (val != 0) hasData = true;
}
if (hasData) {
dumpLine(pw, uid /* uid */, category, USER_ACTIVITY_DATA, args);
}
}
final ArrayMap<String, ? extends Uid.Wakelock> wakelocks = u.getWakelockStats();
for (int iw=wakelocks.size()-1; iw>=0; iw--) {
final Uid.Wakelock wl = wakelocks.valueAt(iw);
String linePrefix = "";
sb.setLength(0);
linePrefix = printWakeLockCheckin(sb, wl.getWakeTime(WAKE_TYPE_FULL),
rawRealtime, "f", which, linePrefix);
linePrefix = printWakeLockCheckin(sb, wl.getWakeTime(WAKE_TYPE_PARTIAL),
rawRealtime, "p", which, linePrefix);
linePrefix = printWakeLockCheckin(sb, wl.getWakeTime(WAKE_TYPE_WINDOW),
rawRealtime, "w", which, linePrefix);
// Only log if we had at lease one wakelock...
if (sb.length() > 0) {
String name = wakelocks.keyAt(iw);
if (name.indexOf(',') >= 0) {
name = name.replace(',', '_');
}
dumpLine(pw, uid, category, WAKELOCK_DATA, name, sb.toString());
}
}
final ArrayMap<String, ? extends Timer> syncs = u.getSyncStats();
for (int isy=syncs.size()-1; isy>=0; isy--) {
final Timer timer = syncs.valueAt(isy);
// Convert from microseconds to milliseconds with rounding
final long totalTime = (timer.getTotalTimeLocked(rawRealtime, which) + 500) / 1000;
final int count = timer.getCountLocked(which);
if (totalTime != 0) {
dumpLine(pw, uid, category, SYNC_DATA, syncs.keyAt(isy), totalTime, count);
}
}
final ArrayMap<String, ? extends Timer> jobs = u.getJobStats();
for (int ij=jobs.size()-1; ij>=0; ij--) {
final Timer timer = jobs.valueAt(ij);
// Convert from microseconds to milliseconds with rounding
final long totalTime = (timer.getTotalTimeLocked(rawRealtime, which) + 500) / 1000;
final int count = timer.getCountLocked(which);
if (totalTime != 0) {
dumpLine(pw, uid, category, JOB_DATA, jobs.keyAt(ij), totalTime, count);
}
}
dumpTimer(pw, uid, category, FLASHLIGHT_DATA, u.getFlashlightTurnedOnTimer(),
rawRealtime, which);
dumpTimer(pw, uid, category, CAMERA_DATA, u.getCameraTurnedOnTimer(),
rawRealtime, which);
dumpTimer(pw, uid, category, VIDEO_DATA, u.getVideoTurnedOnTimer(),
rawRealtime, which);
dumpTimer(pw, uid, category, AUDIO_DATA, u.getAudioTurnedOnTimer(),
rawRealtime, which);
final SparseArray<? extends BatteryStats.Uid.Sensor> sensors = u.getSensorStats();
final int NSE = sensors.size();
for (int ise=0; ise<NSE; ise++) {
final Uid.Sensor se = sensors.valueAt(ise);
final int sensorNumber = sensors.keyAt(ise);
final Timer timer = se.getSensorTime();
if (timer != null) {
// Convert from microseconds to milliseconds with rounding
final long totalTime = (timer.getTotalTimeLocked(rawRealtime, which) + 500)
/ 1000;
final int count = timer.getCountLocked(which);
if (totalTime != 0) {
dumpLine(pw, uid, category, SENSOR_DATA, sensorNumber, totalTime, count);
}
}
}
dumpTimer(pw, uid, category, VIBRATOR_DATA, u.getVibratorOnTimer(),
rawRealtime, which);
dumpTimer(pw, uid, category, FOREGROUND_DATA, u.getForegroundActivityTimer(),
rawRealtime, which);
final Object[] stateTimes = new Object[Uid.NUM_PROCESS_STATE];
long totalStateTime = 0;
for (int ips=0; ips<Uid.NUM_PROCESS_STATE; ips++) {
totalStateTime += u.getProcessStateTime(ips, rawRealtime, which);
stateTimes[ips] = (totalStateTime + 500) / 1000;
}
if (totalStateTime > 0) {
dumpLine(pw, uid, category, STATE_TIME_DATA, stateTimes);
}
final long userCpuTimeUs = u.getUserCpuTimeUs(which);
final long systemCpuTimeUs = u.getSystemCpuTimeUs(which);
final long powerCpuMaUs = u.getCpuPowerMaUs(which);
if (userCpuTimeUs > 0 || systemCpuTimeUs > 0 || powerCpuMaUs > 0) {
dumpLine(pw, uid, category, CPU_DATA, userCpuTimeUs / 1000, systemCpuTimeUs / 1000,
powerCpuMaUs / 1000);
}
final ArrayMap<String, ? extends BatteryStats.Uid.Proc> processStats
= u.getProcessStats();
for (int ipr=processStats.size()-1; ipr>=0; ipr--) {
final Uid.Proc ps = processStats.valueAt(ipr);
final long userMillis = ps.getUserTime(which);
final long systemMillis = ps.getSystemTime(which);
final long foregroundMillis = ps.getForegroundTime(which);
final int starts = ps.getStarts(which);
final int numCrashes = ps.getNumCrashes(which);
final int numAnrs = ps.getNumAnrs(which);
if (userMillis != 0 || systemMillis != 0 || foregroundMillis != 0
|| starts != 0 || numAnrs != 0 || numCrashes != 0) {
dumpLine(pw, uid, category, PROCESS_DATA, processStats.keyAt(ipr), userMillis,
systemMillis, foregroundMillis, starts, numAnrs, numCrashes);
}
}
final ArrayMap<String, ? extends BatteryStats.Uid.Pkg> packageStats
= u.getPackageStats();
for (int ipkg=packageStats.size()-1; ipkg>=0; ipkg--) {
final Uid.Pkg ps = packageStats.valueAt(ipkg);
int wakeups = 0;
final ArrayMap<String, ? extends Counter> alarms = ps.getWakeupAlarmStats();
for (int iwa=alarms.size()-1; iwa>=0; iwa--) {
wakeups += alarms.valueAt(iwa).getCountLocked(which);
}
final ArrayMap<String, ? extends Uid.Pkg.Serv> serviceStats = ps.getServiceStats();
for (int isvc=serviceStats.size()-1; isvc>=0; isvc--) {
final BatteryStats.Uid.Pkg.Serv ss = serviceStats.valueAt(isvc);
final long startTime = ss.getStartTime(batteryUptime, which);
final int starts = ss.getStarts(which);
final int launches = ss.getLaunches(which);
if (startTime != 0 || starts != 0 || launches != 0) {
dumpLine(pw, uid, category, APK_DATA,
wakeups, // wakeup alarms
packageStats.keyAt(ipkg), // Apk
serviceStats.keyAt(isvc), // service
startTime / 1000, // time spent started, in ms
starts,
launches);
}
}
}
}
}
static final class TimerEntry {
final String mName;
final int mId;
final BatteryStats.Timer mTimer;
final long mTime;
TimerEntry(String name, int id, BatteryStats.Timer timer, long time) {
mName = name;
mId = id;
mTimer = timer;
mTime = time;
}
}
private void printmAh(PrintWriter printer, double power) {
printer.print(BatteryStatsHelper.makemAh(power));
}
private void printmAh(StringBuilder sb, double power) {
sb.append(BatteryStatsHelper.makemAh(power));
}
/**
* Temporary for settings.
*/
public final void dumpLocked(Context context, PrintWriter pw, String prefix, int which,
int reqUid) {
dumpLocked(context, pw, prefix, which, reqUid, BatteryStatsHelper.checkWifiOnly(context));
}
@SuppressWarnings("unused")
public final void dumpLocked(Context context, PrintWriter pw, String prefix, final int which,
int reqUid, boolean wifiOnly) {
final long rawUptime = SystemClock.uptimeMillis() * 1000;
final long rawRealtime = SystemClock.elapsedRealtime() * 1000;
final long batteryUptime = getBatteryUptime(rawUptime);
final long whichBatteryUptime = computeBatteryUptime(rawUptime, which);
final long whichBatteryRealtime = computeBatteryRealtime(rawRealtime, which);
final long totalRealtime = computeRealtime(rawRealtime, which);
final long totalUptime = computeUptime(rawUptime, which);
final long whichBatteryScreenOffUptime = computeBatteryScreenOffUptime(rawUptime, which);
final long whichBatteryScreenOffRealtime = computeBatteryScreenOffRealtime(rawRealtime,
which);
final long batteryTimeRemaining = computeBatteryTimeRemaining(rawRealtime);
final long chargeTimeRemaining = computeChargeTimeRemaining(rawRealtime);
final StringBuilder sb = new StringBuilder(128);
final SparseArray<? extends Uid> uidStats = getUidStats();
final int NU = uidStats.size();
sb.setLength(0);
sb.append(prefix);
sb.append(" Time on battery: ");
formatTimeMs(sb, whichBatteryRealtime / 1000); sb.append("(");
sb.append(formatRatioLocked(whichBatteryRealtime, totalRealtime));
sb.append(") realtime, ");
formatTimeMs(sb, whichBatteryUptime / 1000);
sb.append("("); sb.append(formatRatioLocked(whichBatteryUptime, totalRealtime));
sb.append(") uptime");
pw.println(sb.toString());
sb.setLength(0);
sb.append(prefix);
sb.append(" Time on battery screen off: ");
formatTimeMs(sb, whichBatteryScreenOffRealtime / 1000); sb.append("(");
sb.append(formatRatioLocked(whichBatteryScreenOffRealtime, totalRealtime));
sb.append(") realtime, ");
formatTimeMs(sb, whichBatteryScreenOffUptime / 1000);
sb.append("(");
sb.append(formatRatioLocked(whichBatteryScreenOffUptime, totalRealtime));
sb.append(") uptime");
pw.println(sb.toString());
sb.setLength(0);
sb.append(prefix);
sb.append(" Total run time: ");
formatTimeMs(sb, totalRealtime / 1000);
sb.append("realtime, ");
formatTimeMs(sb, totalUptime / 1000);
sb.append("uptime");
pw.println(sb.toString());
if (batteryTimeRemaining >= 0) {
sb.setLength(0);
sb.append(prefix);
sb.append(" Battery time remaining: ");
formatTimeMs(sb, batteryTimeRemaining / 1000);
pw.println(sb.toString());
}
if (chargeTimeRemaining >= 0) {
sb.setLength(0);
sb.append(prefix);
sb.append(" Charge time remaining: ");
formatTimeMs(sb, chargeTimeRemaining / 1000);
pw.println(sb.toString());
}
pw.print(" Start clock time: ");
pw.println(DateFormat.format("yyyy-MM-dd-HH-mm-ss", getStartClockTime()).toString());
final long screenOnTime = getScreenOnTime(rawRealtime, which);
final long interactiveTime = getInteractiveTime(rawRealtime, which);
final long powerSaveModeEnabledTime = getPowerSaveModeEnabledTime(rawRealtime, which);
final long deviceIdleModeEnabledTime = getDeviceIdleModeEnabledTime(rawRealtime, which);
final long deviceIdlingTime = getDeviceIdlingTime(rawRealtime, which);
final long phoneOnTime = getPhoneOnTime(rawRealtime, which);
final long wifiRunningTime = getGlobalWifiRunningTime(rawRealtime, which);
final long wifiOnTime = getWifiOnTime(rawRealtime, which);
sb.setLength(0);
sb.append(prefix);
sb.append(" Screen on: "); formatTimeMs(sb, screenOnTime / 1000);
sb.append("("); sb.append(formatRatioLocked(screenOnTime, whichBatteryRealtime));
sb.append(") "); sb.append(getScreenOnCount(which));
sb.append("x, Interactive: "); formatTimeMs(sb, interactiveTime / 1000);
sb.append("("); sb.append(formatRatioLocked(interactiveTime, whichBatteryRealtime));
sb.append(")");
pw.println(sb.toString());
sb.setLength(0);
sb.append(prefix);
sb.append(" Screen brightnesses:");
boolean didOne = false;
for (int i=0; i<NUM_SCREEN_BRIGHTNESS_BINS; i++) {
final long time = getScreenBrightnessTime(i, rawRealtime, which);
if (time == 0) {
continue;
}
sb.append("\n ");
sb.append(prefix);
didOne = true;
sb.append(SCREEN_BRIGHTNESS_NAMES[i]);
sb.append(" ");
formatTimeMs(sb, time/1000);
sb.append("(");
sb.append(formatRatioLocked(time, screenOnTime));
sb.append(")");
}
if (!didOne) sb.append(" (no activity)");
pw.println(sb.toString());
if (powerSaveModeEnabledTime != 0) {
sb.setLength(0);
sb.append(prefix);
sb.append(" Power save mode enabled: ");
formatTimeMs(sb, powerSaveModeEnabledTime / 1000);
sb.append("(");
sb.append(formatRatioLocked(powerSaveModeEnabledTime, whichBatteryRealtime));
sb.append(")");
pw.println(sb.toString());
}
if (deviceIdlingTime != 0) {
sb.setLength(0);
sb.append(prefix);
sb.append(" Device idling: ");
formatTimeMs(sb, deviceIdlingTime / 1000);
sb.append("(");
sb.append(formatRatioLocked(deviceIdlingTime, whichBatteryRealtime));
sb.append(") "); sb.append(getDeviceIdlingCount(which));
sb.append("x");
pw.println(sb.toString());
}
if (deviceIdleModeEnabledTime != 0) {
sb.setLength(0);
sb.append(prefix);
sb.append(" Idle mode time: ");
formatTimeMs(sb, deviceIdleModeEnabledTime / 1000);
sb.append("(");
sb.append(formatRatioLocked(deviceIdleModeEnabledTime, whichBatteryRealtime));
sb.append(") "); sb.append(getDeviceIdleModeEnabledCount(which));
sb.append("x");
pw.println(sb.toString());
}
if (phoneOnTime != 0) {
sb.setLength(0);
sb.append(prefix);
sb.append(" Active phone call: "); formatTimeMs(sb, phoneOnTime / 1000);
sb.append("("); sb.append(formatRatioLocked(phoneOnTime, whichBatteryRealtime));
sb.append(") "); sb.append(getPhoneOnCount(which)); sb.append("x");
}
final int connChanges = getNumConnectivityChange(which);
if (connChanges != 0) {
pw.print(prefix);
pw.print(" Connectivity changes: "); pw.println(connChanges);
}
// Calculate wakelock times across all uids.
long fullWakeLockTimeTotalMicros = 0;
long partialWakeLockTimeTotalMicros = 0;
final ArrayList<TimerEntry> timers = new ArrayList<>();
for (int iu = 0; iu < NU; iu++) {
final Uid u = uidStats.valueAt(iu);
final ArrayMap<String, ? extends BatteryStats.Uid.Wakelock> wakelocks
= u.getWakelockStats();
for (int iw=wakelocks.size()-1; iw>=0; iw--) {
final Uid.Wakelock wl = wakelocks.valueAt(iw);
final Timer fullWakeTimer = wl.getWakeTime(WAKE_TYPE_FULL);
if (fullWakeTimer != null) {
fullWakeLockTimeTotalMicros += fullWakeTimer.getTotalTimeLocked(
rawRealtime, which);
}
final Timer partialWakeTimer = wl.getWakeTime(WAKE_TYPE_PARTIAL);
if (partialWakeTimer != null) {
final long totalTimeMicros = partialWakeTimer.getTotalTimeLocked(
rawRealtime, which);
if (totalTimeMicros > 0) {
if (reqUid < 0) {
// Only show the ordered list of all wake
// locks if the caller is not asking for data
// about a specific uid.
timers.add(new TimerEntry(wakelocks.keyAt(iw), u.getUid(),
partialWakeTimer, totalTimeMicros));
}
partialWakeLockTimeTotalMicros += totalTimeMicros;
}
}
}
}
final long mobileRxTotalBytes = getNetworkActivityBytes(NETWORK_MOBILE_RX_DATA, which);
final long mobileTxTotalBytes = getNetworkActivityBytes(NETWORK_MOBILE_TX_DATA, which);
final long wifiRxTotalBytes = getNetworkActivityBytes(NETWORK_WIFI_RX_DATA, which);
final long wifiTxTotalBytes = getNetworkActivityBytes(NETWORK_WIFI_TX_DATA, which);
final long mobileRxTotalPackets = getNetworkActivityPackets(NETWORK_MOBILE_RX_DATA, which);
final long mobileTxTotalPackets = getNetworkActivityPackets(NETWORK_MOBILE_TX_DATA, which);
final long wifiRxTotalPackets = getNetworkActivityPackets(NETWORK_WIFI_RX_DATA, which);
final long wifiTxTotalPackets = getNetworkActivityPackets(NETWORK_WIFI_TX_DATA, which);
if (fullWakeLockTimeTotalMicros != 0) {
sb.setLength(0);
sb.append(prefix);
sb.append(" Total full wakelock time: "); formatTimeMsNoSpace(sb,
(fullWakeLockTimeTotalMicros + 500) / 1000);
pw.println(sb.toString());
}
if (partialWakeLockTimeTotalMicros != 0) {
sb.setLength(0);
sb.append(prefix);
sb.append(" Total partial wakelock time: "); formatTimeMsNoSpace(sb,
(partialWakeLockTimeTotalMicros + 500) / 1000);
pw.println(sb.toString());
}
pw.print(prefix);
pw.print(" Mobile total received: "); pw.print(formatBytesLocked(mobileRxTotalBytes));
pw.print(", sent: "); pw.print(formatBytesLocked(mobileTxTotalBytes));
pw.print(" (packets received "); pw.print(mobileRxTotalPackets);
pw.print(", sent "); pw.print(mobileTxTotalPackets); pw.println(")");
sb.setLength(0);
sb.append(prefix);
sb.append(" Phone signal levels:");
didOne = false;
for (int i=0; i<SignalStrength.NUM_SIGNAL_STRENGTH_BINS; i++) {
final long time = getPhoneSignalStrengthTime(i, rawRealtime, which);
if (time == 0) {
continue;
}
sb.append("\n ");
sb.append(prefix);
didOne = true;
sb.append(SignalStrength.SIGNAL_STRENGTH_NAMES[i]);
sb.append(" ");
formatTimeMs(sb, time/1000);
sb.append("(");
sb.append(formatRatioLocked(time, whichBatteryRealtime));
sb.append(") ");
sb.append(getPhoneSignalStrengthCount(i, which));
sb.append("x");
}
if (!didOne) sb.append(" (no activity)");
pw.println(sb.toString());
sb.setLength(0);
sb.append(prefix);
sb.append(" Signal scanning time: ");
formatTimeMsNoSpace(sb, getPhoneSignalScanningTime(rawRealtime, which) / 1000);
pw.println(sb.toString());
sb.setLength(0);
sb.append(prefix);
sb.append(" Radio types:");
didOne = false;
for (int i=0; i<NUM_DATA_CONNECTION_TYPES; i++) {
final long time = getPhoneDataConnectionTime(i, rawRealtime, which);
if (time == 0) {
continue;
}
sb.append("\n ");
sb.append(prefix);
didOne = true;
sb.append(DATA_CONNECTION_NAMES[i]);
sb.append(" ");
formatTimeMs(sb, time/1000);
sb.append("(");
sb.append(formatRatioLocked(time, whichBatteryRealtime));
sb.append(") ");
sb.append(getPhoneDataConnectionCount(i, which));
sb.append("x");
}
if (!didOne) sb.append(" (no activity)");
pw.println(sb.toString());
sb.setLength(0);
sb.append(prefix);
sb.append(" Mobile radio active time: ");
final long mobileActiveTime = getMobileRadioActiveTime(rawRealtime, which);
formatTimeMs(sb, mobileActiveTime / 1000);
sb.append("("); sb.append(formatRatioLocked(mobileActiveTime, whichBatteryRealtime));
sb.append(") "); sb.append(getMobileRadioActiveCount(which));
sb.append("x");
pw.println(sb.toString());
final long mobileActiveUnknownTime = getMobileRadioActiveUnknownTime(which);
if (mobileActiveUnknownTime != 0) {
sb.setLength(0);
sb.append(prefix);
sb.append(" Mobile radio active unknown time: ");
formatTimeMs(sb, mobileActiveUnknownTime / 1000);
sb.append("(");
sb.append(formatRatioLocked(mobileActiveUnknownTime, whichBatteryRealtime));
sb.append(") "); sb.append(getMobileRadioActiveUnknownCount(which));
sb.append("x");
pw.println(sb.toString());
}
final long mobileActiveAdjustedTime = getMobileRadioActiveAdjustedTime(which);
if (mobileActiveAdjustedTime != 0) {
sb.setLength(0);
sb.append(prefix);
sb.append(" Mobile radio active adjusted time: ");
formatTimeMs(sb, mobileActiveAdjustedTime / 1000);
sb.append("(");
sb.append(formatRatioLocked(mobileActiveAdjustedTime, whichBatteryRealtime));
sb.append(")");
pw.println(sb.toString());
}
pw.print(prefix);
pw.print(" Wi-Fi total received: "); pw.print(formatBytesLocked(wifiRxTotalBytes));
pw.print(", sent: "); pw.print(formatBytesLocked(wifiTxTotalBytes));
pw.print(" (packets received "); pw.print(wifiRxTotalPackets);
pw.print(", sent "); pw.print(wifiTxTotalPackets); pw.println(")");
sb.setLength(0);
sb.append(prefix);
sb.append(" Wifi on: "); formatTimeMs(sb, wifiOnTime / 1000);
sb.append("("); sb.append(formatRatioLocked(wifiOnTime, whichBatteryRealtime));
sb.append("), Wifi running: "); formatTimeMs(sb, wifiRunningTime / 1000);
sb.append("("); sb.append(formatRatioLocked(wifiRunningTime, whichBatteryRealtime));
sb.append(")");
pw.println(sb.toString());
sb.setLength(0);
sb.append(prefix);
sb.append(" Wifi states:");
didOne = false;
for (int i=0; i<NUM_WIFI_STATES; i++) {
final long time = getWifiStateTime(i, rawRealtime, which);
if (time == 0) {
continue;
}
sb.append("\n ");
didOne = true;
sb.append(WIFI_STATE_NAMES[i]);
sb.append(" ");
formatTimeMs(sb, time/1000);
sb.append("(");
sb.append(formatRatioLocked(time, whichBatteryRealtime));
sb.append(") ");
sb.append(getWifiStateCount(i, which));
sb.append("x");
}
if (!didOne) sb.append(" (no activity)");
pw.println(sb.toString());
sb.setLength(0);
sb.append(prefix);
sb.append(" Wifi supplicant states:");
didOne = false;
for (int i=0; i<NUM_WIFI_SUPPL_STATES; i++) {
final long time = getWifiSupplStateTime(i, rawRealtime, which);
if (time == 0) {
continue;
}
sb.append("\n ");
didOne = true;
sb.append(WIFI_SUPPL_STATE_NAMES[i]);
sb.append(" ");
formatTimeMs(sb, time/1000);
sb.append("(");
sb.append(formatRatioLocked(time, whichBatteryRealtime));
sb.append(") ");
sb.append(getWifiSupplStateCount(i, which));
sb.append("x");
}
if (!didOne) sb.append(" (no activity)");
pw.println(sb.toString());
sb.setLength(0);
sb.append(prefix);
sb.append(" Wifi signal levels:");
didOne = false;
for (int i=0; i<NUM_WIFI_SIGNAL_STRENGTH_BINS; i++) {
final long time = getWifiSignalStrengthTime(i, rawRealtime, which);
if (time == 0) {
continue;
}
sb.append("\n ");
sb.append(prefix);
didOne = true;
sb.append("level(");
sb.append(i);
sb.append(") ");
formatTimeMs(sb, time/1000);
sb.append("(");
sb.append(formatRatioLocked(time, whichBatteryRealtime));
sb.append(") ");
sb.append(getWifiSignalStrengthCount(i, which));
sb.append("x");
}
if (!didOne) sb.append(" (no activity)");
pw.println(sb.toString());
final long wifiIdleTimeMs = getWifiControllerActivity(CONTROLLER_IDLE_TIME, which);
final long wifiRxTimeMs = getWifiControllerActivity(CONTROLLER_RX_TIME, which);
final long wifiTxTimeMs = getWifiControllerActivity(CONTROLLER_TX_TIME, which);
final long wifiPowerDrainMaMs = getWifiControllerActivity(CONTROLLER_POWER_DRAIN, which);
final long wifiTotalTimeMs = wifiIdleTimeMs + wifiRxTimeMs + wifiTxTimeMs;
sb.setLength(0);
sb.append(prefix);
sb.append(" WiFi Idle time: "); formatTimeMs(sb, wifiIdleTimeMs);
sb.append("(");
sb.append(formatRatioLocked(wifiIdleTimeMs, wifiTotalTimeMs));
sb.append(")");
pw.println(sb.toString());
sb.setLength(0);
sb.append(prefix);
sb.append(" WiFi Rx time: "); formatTimeMs(sb, wifiRxTimeMs);
sb.append("(");
sb.append(formatRatioLocked(wifiRxTimeMs, wifiTotalTimeMs));
sb.append(")");
pw.println(sb.toString());
sb.setLength(0);
sb.append(prefix);
sb.append(" WiFi Tx time: "); formatTimeMs(sb, wifiTxTimeMs);
sb.append("(");
sb.append(formatRatioLocked(wifiTxTimeMs, wifiTotalTimeMs));
sb.append(")");
pw.println(sb.toString());
sb.setLength(0);
sb.append(prefix);
sb.append(" WiFi Power drain: ").append(
BatteryStatsHelper.makemAh(wifiPowerDrainMaMs / (double) (1000*60*60)));
sb.append("mAh");
pw.println(sb.toString());
final long bluetoothIdleTimeMs =
getBluetoothControllerActivity(CONTROLLER_IDLE_TIME, which);
final long bluetoothRxTimeMs = getBluetoothControllerActivity(CONTROLLER_RX_TIME, which);
final long bluetoothTxTimeMs = getBluetoothControllerActivity(CONTROLLER_TX_TIME, which);
final long bluetoothTotalTimeMs = bluetoothIdleTimeMs + bluetoothRxTimeMs +
bluetoothTxTimeMs;
sb.setLength(0);
sb.append(prefix);
sb.append(" Bluetooth Idle time: "); formatTimeMs(sb, bluetoothIdleTimeMs);
sb.append("(");
sb.append(formatRatioLocked(bluetoothIdleTimeMs, bluetoothTotalTimeMs));
sb.append(")");
pw.println(sb.toString());
sb.setLength(0);
sb.append(prefix);
sb.append(" Bluetooth Rx time: "); formatTimeMs(sb, bluetoothRxTimeMs);
sb.append("(");
sb.append(formatRatioLocked(bluetoothRxTimeMs, bluetoothTotalTimeMs));
sb.append(")");
pw.println(sb.toString());
sb.setLength(0);
sb.append(prefix);
sb.append(" Bluetooth Tx time: "); formatTimeMs(sb, bluetoothTxTimeMs);
sb.append("(");
sb.append(formatRatioLocked(bluetoothTxTimeMs, bluetoothTotalTimeMs));
sb.append(")");
pw.println(sb.toString());
sb.setLength(0);
sb.append(prefix);
sb.append(" Bluetooth Power drain: ").append(BatteryStatsHelper.makemAh(
getBluetoothControllerActivity(CONTROLLER_POWER_DRAIN, which) /
(double)(1000*60*60)));
sb.append("mAh");
pw.println(sb.toString());
pw.println();
if (which == STATS_SINCE_UNPLUGGED) {
if (getIsOnBattery()) {
pw.print(prefix); pw.println(" Device is currently unplugged");
pw.print(prefix); pw.print(" Discharge cycle start level: ");
pw.println(getDischargeStartLevel());
pw.print(prefix); pw.print(" Discharge cycle current level: ");
pw.println(getDischargeCurrentLevel());
} else {
pw.print(prefix); pw.println(" Device is currently plugged into power");
pw.print(prefix); pw.print(" Last discharge cycle start level: ");
pw.println(getDischargeStartLevel());
pw.print(prefix); pw.print(" Last discharge cycle end level: ");
pw.println(getDischargeCurrentLevel());
}
pw.print(prefix); pw.print(" Amount discharged while screen on: ");
pw.println(getDischargeAmountScreenOn());
pw.print(prefix); pw.print(" Amount discharged while screen off: ");
pw.println(getDischargeAmountScreenOff());
pw.println(" ");
} else {
pw.print(prefix); pw.println(" Device battery use since last full charge");
pw.print(prefix); pw.print(" Amount discharged (lower bound): ");
pw.println(getLowDischargeAmountSinceCharge());
pw.print(prefix); pw.print(" Amount discharged (upper bound): ");
pw.println(getHighDischargeAmountSinceCharge());
pw.print(prefix); pw.print(" Amount discharged while screen on: ");
pw.println(getDischargeAmountScreenOnSinceCharge());
pw.print(prefix); pw.print(" Amount discharged while screen off: ");
pw.println(getDischargeAmountScreenOffSinceCharge());
pw.println();
}
final BatteryStatsHelper helper = new BatteryStatsHelper(context, false, wifiOnly);
helper.create(this);
helper.refreshStats(which, UserHandle.USER_ALL);
List<BatterySipper> sippers = helper.getUsageList();
if (sippers != null && sippers.size() > 0) {
pw.print(prefix); pw.println(" Estimated power use (mAh):");
pw.print(prefix); pw.print(" Capacity: ");
printmAh(pw, helper.getPowerProfile().getBatteryCapacity());
pw.print(", Computed drain: "); printmAh(pw, helper.getComputedPower());
pw.print(", actual drain: "); printmAh(pw, helper.getMinDrainedPower());
if (helper.getMinDrainedPower() != helper.getMaxDrainedPower()) {
pw.print("-"); printmAh(pw, helper.getMaxDrainedPower());
}
pw.println();
for (int i=0; i<sippers.size(); i++) {
final BatterySipper bs = sippers.get(i);
pw.print(prefix);
switch (bs.drainType) {
case IDLE:
pw.print(" Idle: ");
break;
case CELL:
pw.print(" Cell standby: ");
break;
case PHONE:
pw.print(" Phone calls: ");
break;
case WIFI:
pw.print(" Wifi: ");
break;
case BLUETOOTH:
pw.print(" Bluetooth: ");
break;
case SCREEN:
pw.print(" Screen: ");
break;
case FLASHLIGHT:
pw.print(" Flashlight: ");
break;
case APP:
pw.print(" Uid ");
UserHandle.formatUid(pw, bs.uidObj.getUid());
pw.print(": ");
break;
case USER:
pw.print(" User "); pw.print(bs.userId);
pw.print(": ");
break;
case UNACCOUNTED:
pw.print(" Unaccounted: ");
break;
case OVERCOUNTED:
pw.print(" Over-counted: ");
break;
case CAMERA:
pw.print(" Camera: ");
break;
default:
pw.print(" ???: ");
break;
}
printmAh(pw, bs.totalPowerMah);
if (bs.usagePowerMah != bs.totalPowerMah) {
// If the usage (generic power) isn't the whole amount, we list out
// what components are involved in the calculation.
pw.print(" (");
if (bs.usagePowerMah != 0) {
pw.print(" usage=");
printmAh(pw, bs.usagePowerMah);
}
if (bs.cpuPowerMah != 0) {
pw.print(" cpu=");
printmAh(pw, bs.cpuPowerMah);
}
if (bs.wakeLockPowerMah != 0) {
pw.print(" wake=");
printmAh(pw, bs.wakeLockPowerMah);
}
if (bs.mobileRadioPowerMah != 0) {
pw.print(" radio=");
printmAh(pw, bs.mobileRadioPowerMah);
}
if (bs.wifiPowerMah != 0) {
pw.print(" wifi=");
printmAh(pw, bs.wifiPowerMah);
}
if (bs.gpsPowerMah != 0) {
pw.print(" gps=");
printmAh(pw, bs.gpsPowerMah);
}
if (bs.sensorPowerMah != 0) {
pw.print(" sensor=");
printmAh(pw, bs.sensorPowerMah);
}
if (bs.cameraPowerMah != 0) {
pw.print(" camera=");
printmAh(pw, bs.cameraPowerMah);
}
if (bs.flashlightPowerMah != 0) {
pw.print(" flash=");
printmAh(pw, bs.flashlightPowerMah);
}
pw.print(" )");
}
pw.println();
}
pw.println();
}
sippers = helper.getMobilemsppList();
if (sippers != null && sippers.size() > 0) {
pw.print(prefix); pw.println(" Per-app mobile ms per packet:");
long totalTime = 0;
for (int i=0; i<sippers.size(); i++) {
final BatterySipper bs = sippers.get(i);
sb.setLength(0);
sb.append(prefix); sb.append(" Uid ");
UserHandle.formatUid(sb, bs.uidObj.getUid());
sb.append(": "); sb.append(BatteryStatsHelper.makemAh(bs.mobilemspp));
sb.append(" ("); sb.append(bs.mobileRxPackets+bs.mobileTxPackets);
sb.append(" packets over "); formatTimeMsNoSpace(sb, bs.mobileActive);
sb.append(") "); sb.append(bs.mobileActiveCount); sb.append("x");
pw.println(sb.toString());
totalTime += bs.mobileActive;
}
sb.setLength(0);
sb.append(prefix);
sb.append(" TOTAL TIME: ");
formatTimeMs(sb, totalTime);
sb.append("("); sb.append(formatRatioLocked(totalTime, whichBatteryRealtime));
sb.append(")");
pw.println(sb.toString());
pw.println();
}
final Comparator<TimerEntry> timerComparator = new Comparator<TimerEntry>() {
@Override
public int compare(TimerEntry lhs, TimerEntry rhs) {
long lhsTime = lhs.mTime;
long rhsTime = rhs.mTime;
if (lhsTime < rhsTime) {
return 1;
}
if (lhsTime > rhsTime) {
return -1;
}
return 0;
}
};
if (reqUid < 0) {
final Map<String, ? extends BatteryStats.Timer> kernelWakelocks
= getKernelWakelockStats();
if (kernelWakelocks.size() > 0) {
final ArrayList<TimerEntry> ktimers = new ArrayList<>();
for (Map.Entry<String, ? extends BatteryStats.Timer> ent
: kernelWakelocks.entrySet()) {
final BatteryStats.Timer timer = ent.getValue();
final long totalTimeMillis = computeWakeLock(timer, rawRealtime, which);
if (totalTimeMillis > 0) {
ktimers.add(new TimerEntry(ent.getKey(), 0, timer, totalTimeMillis));
}
}
if (ktimers.size() > 0) {
Collections.sort(ktimers, timerComparator);
pw.print(prefix); pw.println(" All kernel wake locks:");
for (int i=0; i<ktimers.size(); i++) {
final TimerEntry timer = ktimers.get(i);
String linePrefix = ": ";
sb.setLength(0);
sb.append(prefix);
sb.append(" Kernel Wake lock ");
sb.append(timer.mName);
linePrefix = printWakeLock(sb, timer.mTimer, rawRealtime, null,
which, linePrefix);
if (!linePrefix.equals(": ")) {
sb.append(" realtime");
// Only print out wake locks that were held
pw.println(sb.toString());
}
}
pw.println();
}
}
if (timers.size() > 0) {
Collections.sort(timers, timerComparator);
pw.print(prefix); pw.println(" All partial wake locks:");
for (int i=0; i<timers.size(); i++) {
TimerEntry timer = timers.get(i);
sb.setLength(0);
sb.append(" Wake lock ");
UserHandle.formatUid(sb, timer.mId);
sb.append(" ");
sb.append(timer.mName);
printWakeLock(sb, timer.mTimer, rawRealtime, null, which, ": ");
sb.append(" realtime");
pw.println(sb.toString());
}
timers.clear();
pw.println();
}
final Map<String, ? extends Timer> wakeupReasons = getWakeupReasonStats();
if (wakeupReasons.size() > 0) {
pw.print(prefix); pw.println(" All wakeup reasons:");
final ArrayList<TimerEntry> reasons = new ArrayList<>();
for (Map.Entry<String, ? extends Timer> ent : wakeupReasons.entrySet()) {
final Timer timer = ent.getValue();
reasons.add(new TimerEntry(ent.getKey(), 0, timer,
timer.getCountLocked(which)));
}
Collections.sort(reasons, timerComparator);
for (int i=0; i<reasons.size(); i++) {
TimerEntry timer = reasons.get(i);
String linePrefix = ": ";
sb.setLength(0);
sb.append(prefix);
sb.append(" Wakeup reason ");
sb.append(timer.mName);
printWakeLock(sb, timer.mTimer, rawRealtime, null, which, ": ");
sb.append(" realtime");
pw.println(sb.toString());
}
pw.println();
}
}
for (int iu=0; iu<NU; iu++) {
final int uid = uidStats.keyAt(iu);
if (reqUid >= 0 && uid != reqUid && uid != Process.SYSTEM_UID) {
continue;
}
final Uid u = uidStats.valueAt(iu);
pw.print(prefix);
pw.print(" ");
UserHandle.formatUid(pw, uid);
pw.println(":");
boolean uidActivity = false;
final long mobileRxBytes = u.getNetworkActivityBytes(NETWORK_MOBILE_RX_DATA, which);
final long mobileTxBytes = u.getNetworkActivityBytes(NETWORK_MOBILE_TX_DATA, which);
final long wifiRxBytes = u.getNetworkActivityBytes(NETWORK_WIFI_RX_DATA, which);
final long wifiTxBytes = u.getNetworkActivityBytes(NETWORK_WIFI_TX_DATA, which);
final long mobileRxPackets = u.getNetworkActivityPackets(NETWORK_MOBILE_RX_DATA, which);
final long mobileTxPackets = u.getNetworkActivityPackets(NETWORK_MOBILE_TX_DATA, which);
final long uidMobileActiveTime = u.getMobileRadioActiveTime(which);
final int uidMobileActiveCount = u.getMobileRadioActiveCount(which);
final long wifiRxPackets = u.getNetworkActivityPackets(NETWORK_WIFI_RX_DATA, which);
final long wifiTxPackets = u.getNetworkActivityPackets(NETWORK_WIFI_TX_DATA, which);
final long fullWifiLockOnTime = u.getFullWifiLockTime(rawRealtime, which);
final long wifiScanTime = u.getWifiScanTime(rawRealtime, which);
final int wifiScanCount = u.getWifiScanCount(which);
final long uidWifiRunningTime = u.getWifiRunningTime(rawRealtime, which);
if (mobileRxBytes > 0 || mobileTxBytes > 0
|| mobileRxPackets > 0 || mobileTxPackets > 0) {
pw.print(prefix); pw.print(" Mobile network: ");
pw.print(formatBytesLocked(mobileRxBytes)); pw.print(" received, ");
pw.print(formatBytesLocked(mobileTxBytes));
pw.print(" sent (packets "); pw.print(mobileRxPackets);
pw.print(" received, "); pw.print(mobileTxPackets); pw.println(" sent)");
}
if (uidMobileActiveTime > 0 || uidMobileActiveCount > 0) {
sb.setLength(0);
sb.append(prefix); sb.append(" Mobile radio active: ");
formatTimeMs(sb, uidMobileActiveTime / 1000);
sb.append("(");
sb.append(formatRatioLocked(uidMobileActiveTime, mobileActiveTime));
sb.append(") "); sb.append(uidMobileActiveCount); sb.append("x");
long packets = mobileRxPackets + mobileTxPackets;
if (packets == 0) {
packets = 1;
}
sb.append(" @ ");
sb.append(BatteryStatsHelper.makemAh(uidMobileActiveTime / 1000 / (double)packets));
sb.append(" mspp");
pw.println(sb.toString());
}
if (wifiRxBytes > 0 || wifiTxBytes > 0 || wifiRxPackets > 0 || wifiTxPackets > 0) {
pw.print(prefix); pw.print(" Wi-Fi network: ");
pw.print(formatBytesLocked(wifiRxBytes)); pw.print(" received, ");
pw.print(formatBytesLocked(wifiTxBytes));
pw.print(" sent (packets "); pw.print(wifiRxPackets);
pw.print(" received, "); pw.print(wifiTxPackets); pw.println(" sent)");
}
if (fullWifiLockOnTime != 0 || wifiScanTime != 0 || wifiScanCount != 0
|| uidWifiRunningTime != 0) {
sb.setLength(0);
sb.append(prefix); sb.append(" Wifi Running: ");
formatTimeMs(sb, uidWifiRunningTime / 1000);
sb.append("("); sb.append(formatRatioLocked(uidWifiRunningTime,
whichBatteryRealtime)); sb.append(")\n");
sb.append(prefix); sb.append(" Full Wifi Lock: ");
formatTimeMs(sb, fullWifiLockOnTime / 1000);
sb.append("("); sb.append(formatRatioLocked(fullWifiLockOnTime,
whichBatteryRealtime)); sb.append(")\n");
sb.append(prefix); sb.append(" Wifi Scan: ");
formatTimeMs(sb, wifiScanTime / 1000);
sb.append("("); sb.append(formatRatioLocked(wifiScanTime,
whichBatteryRealtime)); sb.append(") ");
sb.append(wifiScanCount);
sb.append("x");
pw.println(sb.toString());
}
final long uidWifiIdleTimeMs = u.getWifiControllerActivity(CONTROLLER_IDLE_TIME, which);
final long uidWifiRxTimeMs = u.getWifiControllerActivity(CONTROLLER_RX_TIME, which);
final long uidWifiTxTimeMs = u.getWifiControllerActivity(CONTROLLER_TX_TIME, which);
final long uidWifiTotalTimeMs = uidWifiIdleTimeMs + uidWifiRxTimeMs + uidWifiTxTimeMs;
if (uidWifiTotalTimeMs > 0) {
sb.setLength(0);
sb.append(prefix).append(" WiFi Idle time: ");
formatTimeMs(sb, uidWifiIdleTimeMs);
sb.append("(").append(formatRatioLocked(uidWifiIdleTimeMs, uidWifiTotalTimeMs))
.append(")\n");
sb.append(prefix).append(" WiFi Rx time: "); formatTimeMs(sb, uidWifiRxTimeMs);
sb.append("(").append(formatRatioLocked(uidWifiRxTimeMs, uidWifiTotalTimeMs))
.append(")\n");
sb.append(prefix).append(" WiFi Tx time: "); formatTimeMs(sb, uidWifiTxTimeMs);
sb.append("(").append(formatRatioLocked(uidWifiTxTimeMs, uidWifiTotalTimeMs))
.append(")");
pw.println(sb.toString());
}
if (u.hasUserActivity()) {
boolean hasData = false;
for (int i=0; i<Uid.NUM_USER_ACTIVITY_TYPES; i++) {
final int val = u.getUserActivityCount(i, which);
if (val != 0) {
if (!hasData) {
sb.setLength(0);
sb.append(" User activity: ");
hasData = true;
} else {
sb.append(", ");
}
sb.append(val);
sb.append(" ");
sb.append(Uid.USER_ACTIVITY_TYPES[i]);
}
}
if (hasData) {
pw.println(sb.toString());
}
}
final ArrayMap<String, ? extends BatteryStats.Uid.Wakelock> wakelocks
= u.getWakelockStats();
long totalFullWakelock = 0, totalPartialWakelock = 0, totalWindowWakelock = 0;
long totalDrawWakelock = 0;
int countWakelock = 0;
for (int iw=wakelocks.size()-1; iw>=0; iw--) {
final Uid.Wakelock wl = wakelocks.valueAt(iw);
String linePrefix = ": ";
sb.setLength(0);
sb.append(prefix);
sb.append(" Wake lock ");
sb.append(wakelocks.keyAt(iw));
linePrefix = printWakeLock(sb, wl.getWakeTime(WAKE_TYPE_FULL), rawRealtime,
"full", which, linePrefix);
linePrefix = printWakeLock(sb, wl.getWakeTime(WAKE_TYPE_PARTIAL), rawRealtime,
"partial", which, linePrefix);
linePrefix = printWakeLock(sb, wl.getWakeTime(WAKE_TYPE_WINDOW), rawRealtime,
"window", which, linePrefix);
linePrefix = printWakeLock(sb, wl.getWakeTime(WAKE_TYPE_DRAW), rawRealtime,
"draw", which, linePrefix);
sb.append(" realtime");
pw.println(sb.toString());
uidActivity = true;
countWakelock++;
totalFullWakelock += computeWakeLock(wl.getWakeTime(WAKE_TYPE_FULL),
rawRealtime, which);
totalPartialWakelock += computeWakeLock(wl.getWakeTime(WAKE_TYPE_PARTIAL),
rawRealtime, which);
totalWindowWakelock += computeWakeLock(wl.getWakeTime(WAKE_TYPE_WINDOW),
rawRealtime, which);
totalDrawWakelock += computeWakeLock(wl.getWakeTime(WAKE_TYPE_DRAW),
rawRealtime, which);
}
if (countWakelock > 1) {
if (totalFullWakelock != 0 || totalPartialWakelock != 0
|| totalWindowWakelock != 0) {
sb.setLength(0);
sb.append(prefix);
sb.append(" TOTAL wake: ");
boolean needComma = false;
if (totalFullWakelock != 0) {
needComma = true;
formatTimeMs(sb, totalFullWakelock);
sb.append("full");
}
if (totalPartialWakelock != 0) {
if (needComma) {
sb.append(", ");
}
needComma = true;
formatTimeMs(sb, totalPartialWakelock);
sb.append("partial");
}
if (totalWindowWakelock != 0) {
if (needComma) {
sb.append(", ");
}
needComma = true;
formatTimeMs(sb, totalWindowWakelock);
sb.append("window");
}
if (totalDrawWakelock != 0) {
if (needComma) {
sb.append(",");
}
needComma = true;
formatTimeMs(sb, totalDrawWakelock);
sb.append("draw");
}
sb.append(" realtime");
pw.println(sb.toString());
}
}
final ArrayMap<String, ? extends Timer> syncs = u.getSyncStats();
for (int isy=syncs.size()-1; isy>=0; isy--) {
final Timer timer = syncs.valueAt(isy);
// Convert from microseconds to milliseconds with rounding
final long totalTime = (timer.getTotalTimeLocked(rawRealtime, which) + 500) / 1000;
final int count = timer.getCountLocked(which);
sb.setLength(0);
sb.append(prefix);
sb.append(" Sync ");
sb.append(syncs.keyAt(isy));
sb.append(": ");
if (totalTime != 0) {
formatTimeMs(sb, totalTime);
sb.append("realtime (");
sb.append(count);
sb.append(" times)");
} else {
sb.append("(not used)");
}
pw.println(sb.toString());
uidActivity = true;
}
final ArrayMap<String, ? extends Timer> jobs = u.getJobStats();
for (int ij=jobs.size()-1; ij>=0; ij--) {
final Timer timer = jobs.valueAt(ij);
// Convert from microseconds to milliseconds with rounding
final long totalTime = (timer.getTotalTimeLocked(rawRealtime, which) + 500) / 1000;
final int count = timer.getCountLocked(which);
sb.setLength(0);
sb.append(prefix);
sb.append(" Job ");
sb.append(jobs.keyAt(ij));
sb.append(": ");
if (totalTime != 0) {
formatTimeMs(sb, totalTime);
sb.append("realtime (");
sb.append(count);
sb.append(" times)");
} else {
sb.append("(not used)");
}
pw.println(sb.toString());
uidActivity = true;
}
uidActivity |= printTimer(pw, sb, u.getFlashlightTurnedOnTimer(), rawRealtime, which,
prefix, "Flashlight");
uidActivity |= printTimer(pw, sb, u.getCameraTurnedOnTimer(), rawRealtime, which,
prefix, "Camera");
uidActivity |= printTimer(pw, sb, u.getVideoTurnedOnTimer(), rawRealtime, which,
prefix, "Video");
uidActivity |= printTimer(pw, sb, u.getAudioTurnedOnTimer(), rawRealtime, which,
prefix, "Audio");
final SparseArray<? extends BatteryStats.Uid.Sensor> sensors = u.getSensorStats();
final int NSE = sensors.size();
for (int ise=0; ise<NSE; ise++) {
final Uid.Sensor se = sensors.valueAt(ise);
final int sensorNumber = sensors.keyAt(ise);
sb.setLength(0);
sb.append(prefix);
sb.append(" Sensor ");
int handle = se.getHandle();
if (handle == Uid.Sensor.GPS) {
sb.append("GPS");
} else {
sb.append(handle);
}
sb.append(": ");
final Timer timer = se.getSensorTime();
if (timer != null) {
// Convert from microseconds to milliseconds with rounding
final long totalTime = (timer.getTotalTimeLocked(
rawRealtime, which) + 500) / 1000;
final int count = timer.getCountLocked(which);
//timer.logState();
if (totalTime != 0) {
formatTimeMs(sb, totalTime);
sb.append("realtime (");
sb.append(count);
sb.append(" times)");
} else {
sb.append("(not used)");
}
} else {
sb.append("(not used)");
}
pw.println(sb.toString());
uidActivity = true;
}
uidActivity |= printTimer(pw, sb, u.getVibratorOnTimer(), rawRealtime, which, prefix,
"Vibrator");
uidActivity |= printTimer(pw, sb, u.getForegroundActivityTimer(), rawRealtime, which,
prefix, "Foreground activities");
long totalStateTime = 0;
for (int ips=0; ips<Uid.NUM_PROCESS_STATE; ips++) {
long time = u.getProcessStateTime(ips, rawRealtime, which);
if (time > 0) {
totalStateTime += time;
sb.setLength(0);
sb.append(prefix);
sb.append(" ");
sb.append(Uid.PROCESS_STATE_NAMES[ips]);
sb.append(" for: ");
formatTimeMs(sb, (totalStateTime + 500) / 1000);
pw.println(sb.toString());
uidActivity = true;
}
}
final long userCpuTimeUs = u.getUserCpuTimeUs(which);
final long systemCpuTimeUs = u.getSystemCpuTimeUs(which);
final long powerCpuMaUs = u.getCpuPowerMaUs(which);
if (userCpuTimeUs > 0 || systemCpuTimeUs > 0 || powerCpuMaUs > 0) {
sb.setLength(0);
sb.append(prefix);
sb.append(" Total cpu time: u=");
formatTimeMs(sb, userCpuTimeUs / 1000);
sb.append("s=");
formatTimeMs(sb, systemCpuTimeUs / 1000);
sb.append("p=");
printmAh(sb, powerCpuMaUs / (1000.0 * 1000.0 * 60.0 * 60.0));
sb.append("mAh");
pw.println(sb.toString());
}
final ArrayMap<String, ? extends BatteryStats.Uid.Proc> processStats
= u.getProcessStats();
for (int ipr=processStats.size()-1; ipr>=0; ipr--) {
final Uid.Proc ps = processStats.valueAt(ipr);
long userTime;
long systemTime;
long foregroundTime;
int starts;
int numExcessive;
userTime = ps.getUserTime(which);
systemTime = ps.getSystemTime(which);
foregroundTime = ps.getForegroundTime(which);
starts = ps.getStarts(which);
final int numCrashes = ps.getNumCrashes(which);
final int numAnrs = ps.getNumAnrs(which);
numExcessive = which == STATS_SINCE_CHARGED
? ps.countExcessivePowers() : 0;
if (userTime != 0 || systemTime != 0 || foregroundTime != 0 || starts != 0
|| numExcessive != 0 || numCrashes != 0 || numAnrs != 0) {
sb.setLength(0);
sb.append(prefix); sb.append(" Proc ");
sb.append(processStats.keyAt(ipr)); sb.append(":\n");
sb.append(prefix); sb.append(" CPU: ");
formatTimeMs(sb, userTime); sb.append("usr + ");
formatTimeMs(sb, systemTime); sb.append("krn ; ");
formatTimeMs(sb, foregroundTime); sb.append("fg");
if (starts != 0 || numCrashes != 0 || numAnrs != 0) {
sb.append("\n"); sb.append(prefix); sb.append(" ");
boolean hasOne = false;
if (starts != 0) {
hasOne = true;
sb.append(starts); sb.append(" starts");
}
if (numCrashes != 0) {
if (hasOne) {
sb.append(", ");
}
hasOne = true;
sb.append(numCrashes); sb.append(" crashes");
}
if (numAnrs != 0) {
if (hasOne) {
sb.append(", ");
}
sb.append(numAnrs); sb.append(" anrs");
}
}
pw.println(sb.toString());
for (int e=0; e<numExcessive; e++) {
Uid.Proc.ExcessivePower ew = ps.getExcessivePower(e);
if (ew != null) {
pw.print(prefix); pw.print(" * Killed for ");
if (ew.type == Uid.Proc.ExcessivePower.TYPE_WAKE) {
pw.print("wake lock");
} else if (ew.type == Uid.Proc.ExcessivePower.TYPE_CPU) {
pw.print("cpu");
} else {
pw.print("unknown");
}
pw.print(" use: ");
TimeUtils.formatDuration(ew.usedTime, pw);
pw.print(" over ");
TimeUtils.formatDuration(ew.overTime, pw);
if (ew.overTime != 0) {
pw.print(" (");
pw.print((ew.usedTime*100)/ew.overTime);
pw.println("%)");
}
}
}
uidActivity = true;
}
}
final ArrayMap<String, ? extends BatteryStats.Uid.Pkg> packageStats
= u.getPackageStats();
for (int ipkg=packageStats.size()-1; ipkg>=0; ipkg--) {
pw.print(prefix); pw.print(" Apk "); pw.print(packageStats.keyAt(ipkg));
pw.println(":");
boolean apkActivity = false;
final Uid.Pkg ps = packageStats.valueAt(ipkg);
final ArrayMap<String, ? extends Counter> alarms = ps.getWakeupAlarmStats();
for (int iwa=alarms.size()-1; iwa>=0; iwa--) {
pw.print(prefix); pw.print(" Wakeup alarm ");
pw.print(alarms.keyAt(iwa)); pw.print(": ");
pw.print(alarms.valueAt(iwa).getCountLocked(which));
pw.println(" times");
apkActivity = true;
}
final ArrayMap<String, ? extends Uid.Pkg.Serv> serviceStats = ps.getServiceStats();
for (int isvc=serviceStats.size()-1; isvc>=0; isvc--) {
final BatteryStats.Uid.Pkg.Serv ss = serviceStats.valueAt(isvc);
final long startTime = ss.getStartTime(batteryUptime, which);
final int starts = ss.getStarts(which);
final int launches = ss.getLaunches(which);
if (startTime != 0 || starts != 0 || launches != 0) {
sb.setLength(0);
sb.append(prefix); sb.append(" Service ");
sb.append(serviceStats.keyAt(isvc)); sb.append(":\n");
sb.append(prefix); sb.append(" Created for: ");
formatTimeMs(sb, startTime / 1000);
sb.append("uptime\n");
sb.append(prefix); sb.append(" Starts: ");
sb.append(starts);
sb.append(", launches: "); sb.append(launches);
pw.println(sb.toString());
apkActivity = true;
}
}
if (!apkActivity) {
pw.print(prefix); pw.println(" (nothing executed)");
}
uidActivity = true;
}
if (!uidActivity) {
pw.print(prefix); pw.println(" (nothing executed)");
}
}
}
static void printBitDescriptions(PrintWriter pw, int oldval, int newval, HistoryTag wakelockTag,
BitDescription[] descriptions, boolean longNames) {
int diff = oldval ^ newval;
if (diff == 0) return;
boolean didWake = false;
for (int i=0; i<descriptions.length; i++) {
BitDescription bd = descriptions[i];
if ((diff&bd.mask) != 0) {
pw.print(longNames ? " " : ",");
if (bd.shift < 0) {
pw.print((newval&bd.mask) != 0 ? "+" : "-");
pw.print(longNames ? bd.name : bd.shortName);
if (bd.mask == HistoryItem.STATE_WAKE_LOCK_FLAG && wakelockTag != null) {
didWake = true;
pw.print("=");
if (longNames) {
UserHandle.formatUid(pw, wakelockTag.uid);
pw.print(":\"");
pw.print(wakelockTag.string);
pw.print("\"");
} else {
pw.print(wakelockTag.poolIdx);
}
}
} else {
pw.print(longNames ? bd.name : bd.shortName);
pw.print("=");
int val = (newval&bd.mask)>>bd.shift;
if (bd.values != null && val >= 0 && val < bd.values.length) {
pw.print(longNames? bd.values[val] : bd.shortValues[val]);
} else {
pw.print(val);
}
}
}
}
if (!didWake && wakelockTag != null) {
pw.print(longNames ? " wake_lock=" : ",w=");
if (longNames) {
UserHandle.formatUid(pw, wakelockTag.uid);
pw.print(":\"");
pw.print(wakelockTag.string);
pw.print("\"");
} else {
pw.print(wakelockTag.poolIdx);
}
}
}
public void prepareForDumpLocked() {
}
public static class HistoryPrinter {
int oldState = 0;
int oldState2 = 0;
int oldLevel = -1;
int oldStatus = -1;
int oldHealth = -1;
int oldPlug = -1;
int oldTemp = -1;
int oldVolt = -1;
long lastTime = -1;
void reset() {
oldState = oldState2 = 0;
oldLevel = -1;
oldStatus = -1;
oldHealth = -1;
oldPlug = -1;
oldTemp = -1;
oldVolt = -1;
}
public void printNextItem(PrintWriter pw, HistoryItem rec, long baseTime, boolean checkin,
boolean verbose) {
if (!checkin) {
pw.print(" ");
TimeUtils.formatDuration(rec.time - baseTime, pw, TimeUtils.HUNDRED_DAY_FIELD_LEN);
pw.print(" (");
pw.print(rec.numReadInts);
pw.print(") ");
} else {
pw.print(BATTERY_STATS_CHECKIN_VERSION); pw.print(',');
pw.print(HISTORY_DATA); pw.print(',');
if (lastTime < 0) {
pw.print(rec.time - baseTime);
} else {
pw.print(rec.time - lastTime);
}
lastTime = rec.time;
}
if (rec.cmd == HistoryItem.CMD_START) {
if (checkin) {
pw.print(":");
}
pw.println("START");
reset();
} else if (rec.cmd == HistoryItem.CMD_CURRENT_TIME
|| rec.cmd == HistoryItem.CMD_RESET) {
if (checkin) {
pw.print(":");
}
if (rec.cmd == HistoryItem.CMD_RESET) {
pw.print("RESET:");
reset();
}
pw.print("TIME:");
if (checkin) {
pw.println(rec.currentTime);
} else {
pw.print(" ");
pw.println(DateFormat.format("yyyy-MM-dd-HH-mm-ss",
rec.currentTime).toString());
}
} else if (rec.cmd == HistoryItem.CMD_SHUTDOWN) {
if (checkin) {
pw.print(":");
}
pw.println("SHUTDOWN");
} else if (rec.cmd == HistoryItem.CMD_OVERFLOW) {
if (checkin) {
pw.print(":");
}
pw.println("*OVERFLOW*");
} else {
if (!checkin) {
if (rec.batteryLevel < 10) pw.print("00");
else if (rec.batteryLevel < 100) pw.print("0");
pw.print(rec.batteryLevel);
if (verbose) {
pw.print(" ");
if (rec.states < 0) ;
else if (rec.states < 0x10) pw.print("0000000");
else if (rec.states < 0x100) pw.print("000000");
else if (rec.states < 0x1000) pw.print("00000");
else if (rec.states < 0x10000) pw.print("0000");
else if (rec.states < 0x100000) pw.print("000");
else if (rec.states < 0x1000000) pw.print("00");
else if (rec.states < 0x10000000) pw.print("0");
pw.print(Integer.toHexString(rec.states));
}
} else {
if (oldLevel != rec.batteryLevel) {
oldLevel = rec.batteryLevel;
pw.print(",Bl="); pw.print(rec.batteryLevel);
}
}
if (oldStatus != rec.batteryStatus) {
oldStatus = rec.batteryStatus;
pw.print(checkin ? ",Bs=" : " status=");
switch (oldStatus) {
case BatteryManager.BATTERY_STATUS_UNKNOWN:
pw.print(checkin ? "?" : "unknown");
break;
case BatteryManager.BATTERY_STATUS_CHARGING:
pw.print(checkin ? "c" : "charging");
break;
case BatteryManager.BATTERY_STATUS_DISCHARGING:
pw.print(checkin ? "d" : "discharging");
break;
case BatteryManager.BATTERY_STATUS_NOT_CHARGING:
pw.print(checkin ? "n" : "not-charging");
break;
case BatteryManager.BATTERY_STATUS_FULL:
pw.print(checkin ? "f" : "full");
break;
default:
pw.print(oldStatus);
break;
}
}
if (oldHealth != rec.batteryHealth) {
oldHealth = rec.batteryHealth;
pw.print(checkin ? ",Bh=" : " health=");
switch (oldHealth) {
case BatteryManager.BATTERY_HEALTH_UNKNOWN:
pw.print(checkin ? "?" : "unknown");
break;
case BatteryManager.BATTERY_HEALTH_GOOD:
pw.print(checkin ? "g" : "good");
break;
case BatteryManager.BATTERY_HEALTH_OVERHEAT:
pw.print(checkin ? "h" : "overheat");
break;
case BatteryManager.BATTERY_HEALTH_DEAD:
pw.print(checkin ? "d" : "dead");
break;
case BatteryManager.BATTERY_HEALTH_OVER_VOLTAGE:
pw.print(checkin ? "v" : "over-voltage");
break;
case BatteryManager.BATTERY_HEALTH_UNSPECIFIED_FAILURE:
pw.print(checkin ? "f" : "failure");
break;
case BatteryManager.BATTERY_HEALTH_COLD:
pw.print(checkin ? "c" : "cold");
break;
default:
pw.print(oldHealth);
break;
}
}
if (oldPlug != rec.batteryPlugType) {
oldPlug = rec.batteryPlugType;
pw.print(checkin ? ",Bp=" : " plug=");
switch (oldPlug) {
case 0:
pw.print(checkin ? "n" : "none");
break;
case BatteryManager.BATTERY_PLUGGED_AC:
pw.print(checkin ? "a" : "ac");
break;
case BatteryManager.BATTERY_PLUGGED_USB:
pw.print(checkin ? "u" : "usb");
break;
case BatteryManager.BATTERY_PLUGGED_WIRELESS:
pw.print(checkin ? "w" : "wireless");
break;
default:
pw.print(oldPlug);
break;
}
}
if (oldTemp != rec.batteryTemperature) {
oldTemp = rec.batteryTemperature;
pw.print(checkin ? ",Bt=" : " temp=");
pw.print(oldTemp);
}
if (oldVolt != rec.batteryVoltage) {
oldVolt = rec.batteryVoltage;
pw.print(checkin ? ",Bv=" : " volt=");
pw.print(oldVolt);
}
printBitDescriptions(pw, oldState, rec.states, rec.wakelockTag,
HISTORY_STATE_DESCRIPTIONS, !checkin);
printBitDescriptions(pw, oldState2, rec.states2, null,
HISTORY_STATE2_DESCRIPTIONS, !checkin);
if (rec.wakeReasonTag != null) {
if (checkin) {
pw.print(",wr=");
pw.print(rec.wakeReasonTag.poolIdx);
} else {
pw.print(" wake_reason=");
pw.print(rec.wakeReasonTag.uid);
pw.print(":\"");
pw.print(rec.wakeReasonTag.string);
pw.print("\"");
}
}
if (rec.eventCode != HistoryItem.EVENT_NONE) {
pw.print(checkin ? "," : " ");
if ((rec.eventCode&HistoryItem.EVENT_FLAG_START) != 0) {
pw.print("+");
} else if ((rec.eventCode&HistoryItem.EVENT_FLAG_FINISH) != 0) {
pw.print("-");
}
String[] eventNames = checkin ? HISTORY_EVENT_CHECKIN_NAMES
: HISTORY_EVENT_NAMES;
int idx = rec.eventCode & ~(HistoryItem.EVENT_FLAG_START
| HistoryItem.EVENT_FLAG_FINISH);
if (idx >= 0 && idx < eventNames.length) {
pw.print(eventNames[idx]);
} else {
pw.print(checkin ? "Ev" : "event");
pw.print(idx);
}
pw.print("=");
if (checkin) {
pw.print(rec.eventTag.poolIdx);
} else {
UserHandle.formatUid(pw, rec.eventTag.uid);
pw.print(":\"");
pw.print(rec.eventTag.string);
pw.print("\"");
}
}
pw.println();
if (rec.stepDetails != null) {
if (!checkin) {
pw.print(" Details: cpu=");
pw.print(rec.stepDetails.userTime);
pw.print("u+");
pw.print(rec.stepDetails.systemTime);
pw.print("s");
if (rec.stepDetails.appCpuUid1 >= 0) {
pw.print(" (");
printStepCpuUidDetails(pw, rec.stepDetails.appCpuUid1,
rec.stepDetails.appCpuUTime1, rec.stepDetails.appCpuSTime1);
if (rec.stepDetails.appCpuUid2 >= 0) {
pw.print(", ");
printStepCpuUidDetails(pw, rec.stepDetails.appCpuUid2,
rec.stepDetails.appCpuUTime2, rec.stepDetails.appCpuSTime2);
}
if (rec.stepDetails.appCpuUid3 >= 0) {
pw.print(", ");
printStepCpuUidDetails(pw, rec.stepDetails.appCpuUid3,
rec.stepDetails.appCpuUTime3, rec.stepDetails.appCpuSTime3);
}
pw.print(')');
}
pw.println();
pw.print(" /proc/stat=");
pw.print(rec.stepDetails.statUserTime);
pw.print(" usr, ");
pw.print(rec.stepDetails.statSystemTime);
pw.print(" sys, ");
pw.print(rec.stepDetails.statIOWaitTime);
pw.print(" io, ");
pw.print(rec.stepDetails.statIrqTime);
pw.print(" irq, ");
pw.print(rec.stepDetails.statSoftIrqTime);
pw.print(" sirq, ");
pw.print(rec.stepDetails.statIdlTime);
pw.print(" idle");
int totalRun = rec.stepDetails.statUserTime + rec.stepDetails.statSystemTime
+ rec.stepDetails.statIOWaitTime + rec.stepDetails.statIrqTime
+ rec.stepDetails.statSoftIrqTime;
int total = totalRun + rec.stepDetails.statIdlTime;
if (total > 0) {
pw.print(" (");
float perc = ((float)totalRun) / ((float)total) * 100;
pw.print(String.format("%.1f%%", perc));
pw.print(" of ");
StringBuilder sb = new StringBuilder(64);
formatTimeMsNoSpace(sb, total*10);
pw.print(sb);
pw.print(")");
}
pw.println();
} else {
pw.print(BATTERY_STATS_CHECKIN_VERSION); pw.print(',');
pw.print(HISTORY_DATA); pw.print(",0,Dcpu=");
pw.print(rec.stepDetails.userTime);
pw.print(":");
pw.print(rec.stepDetails.systemTime);
if (rec.stepDetails.appCpuUid1 >= 0) {
printStepCpuUidCheckinDetails(pw, rec.stepDetails.appCpuUid1,
rec.stepDetails.appCpuUTime1, rec.stepDetails.appCpuSTime1);
if (rec.stepDetails.appCpuUid2 >= 0) {
printStepCpuUidCheckinDetails(pw, rec.stepDetails.appCpuUid2,
rec.stepDetails.appCpuUTime2, rec.stepDetails.appCpuSTime2);
}
if (rec.stepDetails.appCpuUid3 >= 0) {
printStepCpuUidCheckinDetails(pw, rec.stepDetails.appCpuUid3,
rec.stepDetails.appCpuUTime3, rec.stepDetails.appCpuSTime3);
}
}
pw.println();
pw.print(BATTERY_STATS_CHECKIN_VERSION); pw.print(',');
pw.print(HISTORY_DATA); pw.print(",0,Dpst=");
pw.print(rec.stepDetails.statUserTime);
pw.print(',');
pw.print(rec.stepDetails.statSystemTime);
pw.print(',');
pw.print(rec.stepDetails.statIOWaitTime);
pw.print(',');
pw.print(rec.stepDetails.statIrqTime);
pw.print(',');
pw.print(rec.stepDetails.statSoftIrqTime);
pw.print(',');
pw.print(rec.stepDetails.statIdlTime);
pw.println();
}
}
oldState = rec.states;
oldState2 = rec.states2;
}
}
private void printStepCpuUidDetails(PrintWriter pw, int uid, int utime, int stime) {
UserHandle.formatUid(pw, uid);
pw.print("=");
pw.print(utime);
pw.print("u+");
pw.print(stime);
pw.print("s");
}
private void printStepCpuUidCheckinDetails(PrintWriter pw, int uid, int utime, int stime) {
pw.print('/');
pw.print(uid);
pw.print(":");
pw.print(utime);
pw.print(":");
pw.print(stime);
}
}
private void printSizeValue(PrintWriter pw, long size) {
float result = size;
String suffix = "";
if (result >= 10*1024) {
suffix = "KB";
result = result / 1024;
}
if (result >= 10*1024) {
suffix = "MB";
result = result / 1024;
}
if (result >= 10*1024) {
suffix = "GB";
result = result / 1024;
}
if (result >= 10*1024) {
suffix = "TB";
result = result / 1024;
}
if (result >= 10*1024) {
suffix = "PB";
result = result / 1024;
}
pw.print((int)result);
pw.print(suffix);
}
private static boolean dumpTimeEstimate(PrintWriter pw, String label1, String label2,
String label3, long estimatedTime) {
if (estimatedTime < 0) {
return false;
}
pw.print(label1);
pw.print(label2);
pw.print(label3);
StringBuilder sb = new StringBuilder(64);
formatTimeMs(sb, estimatedTime);
pw.print(sb);
pw.println();
return true;
}
private static boolean dumpDurationSteps(PrintWriter pw, String prefix, String header,
LevelStepTracker steps, boolean checkin) {
if (steps == null) {
return false;
}
int count = steps.mNumStepDurations;
if (count <= 0) {
return false;
}
if (!checkin) {
pw.println(header);
}
String[] lineArgs = new String[5];
for (int i=0; i<count; i++) {
long duration = steps.getDurationAt(i);
int level = steps.getLevelAt(i);
long initMode = steps.getInitModeAt(i);
long modMode = steps.getModModeAt(i);
if (checkin) {
lineArgs[0] = Long.toString(duration);
lineArgs[1] = Integer.toString(level);
if ((modMode&STEP_LEVEL_MODE_SCREEN_STATE) == 0) {
switch ((int)(initMode&STEP_LEVEL_MODE_SCREEN_STATE) + 1) {
case Display.STATE_OFF: lineArgs[2] = "s-"; break;
case Display.STATE_ON: lineArgs[2] = "s+"; break;
case Display.STATE_DOZE: lineArgs[2] = "sd"; break;
case Display.STATE_DOZE_SUSPEND: lineArgs[2] = "sds"; break;
default: lineArgs[2] = "?"; break;
}
} else {
lineArgs[2] = "";
}
if ((modMode&STEP_LEVEL_MODE_POWER_SAVE) == 0) {
lineArgs[3] = (initMode&STEP_LEVEL_MODE_POWER_SAVE) != 0 ? "p+" : "p-";
} else {
lineArgs[3] = "";
}
if ((modMode&STEP_LEVEL_MODE_DEVICE_IDLE) == 0) {
lineArgs[4] = (initMode&STEP_LEVEL_MODE_DEVICE_IDLE) != 0 ? "i+" : "i-";
} else {
lineArgs[4] = "";
}
dumpLine(pw, 0 /* uid */, "i" /* category */, header, (Object[])lineArgs);
} else {
pw.print(prefix);
pw.print("#"); pw.print(i); pw.print(": ");
TimeUtils.formatDuration(duration, pw);
pw.print(" to "); pw.print(level);
boolean haveModes = false;
if ((modMode&STEP_LEVEL_MODE_SCREEN_STATE) == 0) {
pw.print(" (");
switch ((int)(initMode&STEP_LEVEL_MODE_SCREEN_STATE) + 1) {
case Display.STATE_OFF: pw.print("screen-off"); break;
case Display.STATE_ON: pw.print("screen-on"); break;
case Display.STATE_DOZE: pw.print("screen-doze"); break;
case Display.STATE_DOZE_SUSPEND: pw.print("screen-doze-suspend"); break;
default: pw.print("screen-?"); break;
}
haveModes = true;
}
if ((modMode&STEP_LEVEL_MODE_POWER_SAVE) == 0) {
pw.print(haveModes ? ", " : " (");
pw.print((initMode&STEP_LEVEL_MODE_POWER_SAVE) != 0
? "power-save-on" : "power-save-off");
haveModes = true;
}
if ((modMode&STEP_LEVEL_MODE_DEVICE_IDLE) == 0) {
pw.print(haveModes ? ", " : " (");
pw.print((initMode&STEP_LEVEL_MODE_DEVICE_IDLE) != 0
? "device-idle-on" : "device-idle-off");
haveModes = true;
}
if (haveModes) {
pw.print(")");
}
pw.println();
}
}
return true;
}
public static final int DUMP_CHARGED_ONLY = 1<<1;
public static final int DUMP_DAILY_ONLY = 1<<2;
public static final int DUMP_HISTORY_ONLY = 1<<3;
public static final int DUMP_INCLUDE_HISTORY = 1<<4;
public static final int DUMP_VERBOSE = 1<<5;
public static final int DUMP_DEVICE_WIFI_ONLY = 1<<6;
private void dumpHistoryLocked(PrintWriter pw, int flags, long histStart, boolean checkin) {
final HistoryPrinter hprinter = new HistoryPrinter();
final HistoryItem rec = new HistoryItem();
long lastTime = -1;
long baseTime = -1;
boolean printed = false;
HistoryEventTracker tracker = null;
while (getNextHistoryLocked(rec)) {
lastTime = rec.time;
if (baseTime < 0) {
baseTime = lastTime;
}
if (rec.time >= histStart) {
if (histStart >= 0 && !printed) {
if (rec.cmd == HistoryItem.CMD_CURRENT_TIME
|| rec.cmd == HistoryItem.CMD_RESET
|| rec.cmd == HistoryItem.CMD_START
|| rec.cmd == HistoryItem.CMD_SHUTDOWN) {
printed = true;
hprinter.printNextItem(pw, rec, baseTime, checkin,
(flags&DUMP_VERBOSE) != 0);
rec.cmd = HistoryItem.CMD_UPDATE;
} else if (rec.currentTime != 0) {
printed = true;
byte cmd = rec.cmd;
rec.cmd = HistoryItem.CMD_CURRENT_TIME;
hprinter.printNextItem(pw, rec, baseTime, checkin,
(flags&DUMP_VERBOSE) != 0);
rec.cmd = cmd;
}
if (tracker != null) {
if (rec.cmd != HistoryItem.CMD_UPDATE) {
hprinter.printNextItem(pw, rec, baseTime, checkin,
(flags&DUMP_VERBOSE) != 0);
rec.cmd = HistoryItem.CMD_UPDATE;
}
int oldEventCode = rec.eventCode;
HistoryTag oldEventTag = rec.eventTag;
rec.eventTag = new HistoryTag();
for (int i=0; i<HistoryItem.EVENT_COUNT; i++) {
HashMap<String, SparseIntArray> active
= tracker.getStateForEvent(i);
if (active == null) {
continue;
}
for (HashMap.Entry<String, SparseIntArray> ent
: active.entrySet()) {
SparseIntArray uids = ent.getValue();
for (int j=0; j<uids.size(); j++) {
rec.eventCode = i;
rec.eventTag.string = ent.getKey();
rec.eventTag.uid = uids.keyAt(j);
rec.eventTag.poolIdx = uids.valueAt(j);
hprinter.printNextItem(pw, rec, baseTime, checkin,
(flags&DUMP_VERBOSE) != 0);
rec.wakeReasonTag = null;
rec.wakelockTag = null;
}
}
}
rec.eventCode = oldEventCode;
rec.eventTag = oldEventTag;
tracker = null;
}
}
hprinter.printNextItem(pw, rec, baseTime, checkin,
(flags&DUMP_VERBOSE) != 0);
} else if (false && rec.eventCode != HistoryItem.EVENT_NONE) {
// This is an attempt to aggregate the previous state and generate
// fake events to reflect that state at the point where we start
// printing real events. It doesn't really work right, so is turned off.
if (tracker == null) {
tracker = new HistoryEventTracker();
}
tracker.updateState(rec.eventCode, rec.eventTag.string,
rec.eventTag.uid, rec.eventTag.poolIdx);
}
}
if (histStart >= 0) {
commitCurrentHistoryBatchLocked();
pw.print(checkin ? "NEXT: " : " NEXT: "); pw.println(lastTime+1);
}
}
private void dumpDailyLevelStepSummary(PrintWriter pw, String prefix, String label,
LevelStepTracker steps, StringBuilder tmpSb, int[] tmpOutInt) {
if (steps == null) {
return;
}
long timeRemaining = steps.computeTimeEstimate(0, 0, tmpOutInt);
if (timeRemaining >= 0) {
pw.print(prefix); pw.print(label); pw.print(" total time: ");
tmpSb.setLength(0);
formatTimeMs(tmpSb, timeRemaining);
pw.print(tmpSb);
pw.print(" (from "); pw.print(tmpOutInt[0]);
pw.println(" steps)");
}
for (int i=0; i< STEP_LEVEL_MODES_OF_INTEREST.length; i++) {
long estimatedTime = steps.computeTimeEstimate(STEP_LEVEL_MODES_OF_INTEREST[i],
STEP_LEVEL_MODE_VALUES[i], tmpOutInt);
if (estimatedTime > 0) {
pw.print(prefix); pw.print(label); pw.print(" ");
pw.print(STEP_LEVEL_MODE_LABELS[i]);
pw.print(" time: ");
tmpSb.setLength(0);
formatTimeMs(tmpSb, estimatedTime);
pw.print(tmpSb);
pw.print(" (from "); pw.print(tmpOutInt[0]);
pw.println(" steps)");
}
}
}
private void dumpDailyPackageChanges(PrintWriter pw, String prefix,
ArrayList<PackageChange> changes) {
if (changes == null) {
return;
}
pw.print(prefix); pw.println("Package changes:");
for (int i=0; i<changes.size(); i++) {
PackageChange pc = changes.get(i);
if (pc.mUpdate) {
pw.print(prefix); pw.print(" Update "); pw.print(pc.mPackageName);
pw.print(" vers="); pw.println(pc.mVersionCode);
} else {
pw.print(prefix); pw.print(" Uninstall "); pw.println(pc.mPackageName);
}
}
}
/**
* Dumps a human-readable summary of the battery statistics to the given PrintWriter.
*
* @param pw a Printer to receive the dump output.
*/
@SuppressWarnings("unused")
public void dumpLocked(Context context, PrintWriter pw, int flags, int reqUid, long histStart) {
prepareForDumpLocked();
final boolean filtering = (flags
& (DUMP_HISTORY_ONLY|DUMP_CHARGED_ONLY|DUMP_DAILY_ONLY)) != 0;
if ((flags&DUMP_HISTORY_ONLY) != 0 || !filtering) {
final long historyTotalSize = getHistoryTotalSize();
final long historyUsedSize = getHistoryUsedSize();
if (startIteratingHistoryLocked()) {
try {
pw.print("Battery History (");
pw.print((100*historyUsedSize)/historyTotalSize);
pw.print("% used, ");
printSizeValue(pw, historyUsedSize);
pw.print(" used of ");
printSizeValue(pw, historyTotalSize);
pw.print(", ");
pw.print(getHistoryStringPoolSize());
pw.print(" strings using ");
printSizeValue(pw, getHistoryStringPoolBytes());
pw.println("):");
dumpHistoryLocked(pw, flags, histStart, false);
pw.println();
} finally {
finishIteratingHistoryLocked();
}
}
if (startIteratingOldHistoryLocked()) {
try {
final HistoryItem rec = new HistoryItem();
pw.println("Old battery History:");
HistoryPrinter hprinter = new HistoryPrinter();
long baseTime = -1;
while (getNextOldHistoryLocked(rec)) {
if (baseTime < 0) {
baseTime = rec.time;
}
hprinter.printNextItem(pw, rec, baseTime, false, (flags&DUMP_VERBOSE) != 0);
}
pw.println();
} finally {
finishIteratingOldHistoryLocked();
}
}
}
if (filtering && (flags&(DUMP_CHARGED_ONLY|DUMP_DAILY_ONLY)) == 0) {
return;
}
if (!filtering) {
SparseArray<? extends Uid> uidStats = getUidStats();
final int NU = uidStats.size();
boolean didPid = false;
long nowRealtime = SystemClock.elapsedRealtime();
for (int i=0; i<NU; i++) {
Uid uid = uidStats.valueAt(i);
SparseArray<? extends Uid.Pid> pids = uid.getPidStats();
if (pids != null) {
for (int j=0; j<pids.size(); j++) {
Uid.Pid pid = pids.valueAt(j);
if (!didPid) {
pw.println("Per-PID Stats:");
didPid = true;
}
long time = pid.mWakeSumMs + (pid.mWakeNesting > 0
? (nowRealtime - pid.mWakeStartMs) : 0);
pw.print(" PID "); pw.print(pids.keyAt(j));
pw.print(" wake time: ");
TimeUtils.formatDuration(time, pw);
pw.println("");
}
}
}
if (didPid) {
pw.println();
}
}
if (!filtering || (flags&DUMP_CHARGED_ONLY) != 0) {
if (dumpDurationSteps(pw, " ", "Discharge step durations:",
getDischargeLevelStepTracker(), false)) {
long timeRemaining = computeBatteryTimeRemaining(SystemClock.elapsedRealtime());
if (timeRemaining >= 0) {
pw.print(" Estimated discharge time remaining: ");
TimeUtils.formatDuration(timeRemaining / 1000, pw);
pw.println();
}
final LevelStepTracker steps = getDischargeLevelStepTracker();
for (int i=0; i< STEP_LEVEL_MODES_OF_INTEREST.length; i++) {
dumpTimeEstimate(pw, " Estimated ", STEP_LEVEL_MODE_LABELS[i], " time: ",
steps.computeTimeEstimate(STEP_LEVEL_MODES_OF_INTEREST[i],
STEP_LEVEL_MODE_VALUES[i], null));
}
pw.println();
}
if (dumpDurationSteps(pw, " ", "Charge step durations:",
getChargeLevelStepTracker(), false)) {
long timeRemaining = computeChargeTimeRemaining(SystemClock.elapsedRealtime());
if (timeRemaining >= 0) {
pw.print(" Estimated charge time remaining: ");
TimeUtils.formatDuration(timeRemaining / 1000, pw);
pw.println();
}
pw.println();
}
}
if (!filtering || (flags&(DUMP_CHARGED_ONLY|DUMP_DAILY_ONLY)) != 0) {
pw.println("Daily stats:");
pw.print(" Current start time: ");
pw.println(DateFormat.format("yyyy-MM-dd-HH-mm-ss",
getCurrentDailyStartTime()).toString());
pw.print(" Next min deadline: ");
pw.println(DateFormat.format("yyyy-MM-dd-HH-mm-ss",
getNextMinDailyDeadline()).toString());
pw.print(" Next max deadline: ");
pw.println(DateFormat.format("yyyy-MM-dd-HH-mm-ss",
getNextMaxDailyDeadline()).toString());
StringBuilder sb = new StringBuilder(64);
int[] outInt = new int[1];
LevelStepTracker dsteps = getDailyDischargeLevelStepTracker();
LevelStepTracker csteps = getDailyChargeLevelStepTracker();
ArrayList<PackageChange> pkgc = getDailyPackageChanges();
if (dsteps.mNumStepDurations > 0 || csteps.mNumStepDurations > 0 || pkgc != null) {
if ((flags&DUMP_DAILY_ONLY) != 0 || !filtering) {
if (dumpDurationSteps(pw, " ", " Current daily discharge step durations:",
dsteps, false)) {
dumpDailyLevelStepSummary(pw, " ", "Discharge", dsteps,
sb, outInt);
}
if (dumpDurationSteps(pw, " ", " Current daily charge step durations:",
csteps, false)) {
dumpDailyLevelStepSummary(pw, " ", "Charge", csteps,
sb, outInt);
}
dumpDailyPackageChanges(pw, " ", pkgc);
} else {
pw.println(" Current daily steps:");
dumpDailyLevelStepSummary(pw, " ", "Discharge", dsteps,
sb, outInt);
dumpDailyLevelStepSummary(pw, " ", "Charge", csteps,
sb, outInt);
}
}
DailyItem dit;
int curIndex = 0;
while ((dit=getDailyItemLocked(curIndex)) != null) {
curIndex++;
if ((flags&DUMP_DAILY_ONLY) != 0) {
pw.println();
}
pw.print(" Daily from ");
pw.print(DateFormat.format("yyyy-MM-dd-HH-mm-ss", dit.mStartTime).toString());
pw.print(" to ");
pw.print(DateFormat.format("yyyy-MM-dd-HH-mm-ss", dit.mEndTime).toString());
pw.println(":");
if ((flags&DUMP_DAILY_ONLY) != 0 || !filtering) {
if (dumpDurationSteps(pw, " ",
" Discharge step durations:", dit.mDischargeSteps, false)) {
dumpDailyLevelStepSummary(pw, " ", "Discharge", dit.mDischargeSteps,
sb, outInt);
}
if (dumpDurationSteps(pw, " ",
" Charge step durations:", dit.mChargeSteps, false)) {
dumpDailyLevelStepSummary(pw, " ", "Charge", dit.mChargeSteps,
sb, outInt);
}
dumpDailyPackageChanges(pw, " ", dit.mPackageChanges);
} else {
dumpDailyLevelStepSummary(pw, " ", "Discharge", dit.mDischargeSteps,
sb, outInt);
dumpDailyLevelStepSummary(pw, " ", "Charge", dit.mChargeSteps,
sb, outInt);
}
}
pw.println();
}
if (!filtering || (flags&DUMP_CHARGED_ONLY) != 0) {
pw.println("Statistics since last charge:");
pw.println(" System starts: " + getStartCount()
+ ", currently on battery: " + getIsOnBattery());
dumpLocked(context, pw, "", STATS_SINCE_CHARGED, reqUid,
(flags&DUMP_DEVICE_WIFI_ONLY) != 0);
pw.println();
}
}
@SuppressWarnings("unused")
public void dumpCheckinLocked(Context context, PrintWriter pw,
List<ApplicationInfo> apps, int flags, long histStart) {
prepareForDumpLocked();
dumpLine(pw, 0 /* uid */, "i" /* category */, VERSION_DATA,
CHECKIN_VERSION, getParcelVersion(), getStartPlatformVersion(),
getEndPlatformVersion());
long now = getHistoryBaseTime() + SystemClock.elapsedRealtime();
final boolean filtering = (flags &
(DUMP_HISTORY_ONLY|DUMP_CHARGED_ONLY|DUMP_DAILY_ONLY)) != 0;
if ((flags&DUMP_INCLUDE_HISTORY) != 0 || (flags&DUMP_HISTORY_ONLY) != 0) {
if (startIteratingHistoryLocked()) {
try {
for (int i=0; i<getHistoryStringPoolSize(); i++) {
pw.print(BATTERY_STATS_CHECKIN_VERSION); pw.print(',');
pw.print(HISTORY_STRING_POOL); pw.print(',');
pw.print(i);
pw.print(",");
pw.print(getHistoryTagPoolUid(i));
pw.print(",\"");
String str = getHistoryTagPoolString(i);
str = str.replace("\\", "\\\\");
str = str.replace("\"", "\\\"");
pw.print(str);
pw.print("\"");
pw.println();
}
dumpHistoryLocked(pw, flags, histStart, true);
} finally {
finishIteratingHistoryLocked();
}
}
}
if (filtering && (flags&(DUMP_CHARGED_ONLY|DUMP_DAILY_ONLY)) == 0) {
return;
}
if (apps != null) {
SparseArray<ArrayList<String>> uids = new SparseArray<ArrayList<String>>();
for (int i=0; i<apps.size(); i++) {
ApplicationInfo ai = apps.get(i);
ArrayList<String> pkgs = uids.get(ai.uid);
if (pkgs == null) {
pkgs = new ArrayList<String>();
uids.put(ai.uid, pkgs);
}
pkgs.add(ai.packageName);
}
SparseArray<? extends Uid> uidStats = getUidStats();
final int NU = uidStats.size();
String[] lineArgs = new String[2];
for (int i=0; i<NU; i++) {
int uid = uidStats.keyAt(i);
ArrayList<String> pkgs = uids.get(uid);
if (pkgs != null) {
for (int j=0; j<pkgs.size(); j++) {
lineArgs[0] = Integer.toString(uid);
lineArgs[1] = pkgs.get(j);
dumpLine(pw, 0 /* uid */, "i" /* category */, UID_DATA,
(Object[])lineArgs);
}
}
}
}
if (!filtering || (flags&DUMP_CHARGED_ONLY) != 0) {
dumpDurationSteps(pw, "", DISCHARGE_STEP_DATA, getDischargeLevelStepTracker(), true);
String[] lineArgs = new String[1];
long timeRemaining = computeBatteryTimeRemaining(SystemClock.elapsedRealtime());
if (timeRemaining >= 0) {
lineArgs[0] = Long.toString(timeRemaining);
dumpLine(pw, 0 /* uid */, "i" /* category */, DISCHARGE_TIME_REMAIN_DATA,
(Object[])lineArgs);
}
dumpDurationSteps(pw, "", CHARGE_STEP_DATA, getChargeLevelStepTracker(), true);
timeRemaining = computeChargeTimeRemaining(SystemClock.elapsedRealtime());
if (timeRemaining >= 0) {
lineArgs[0] = Long.toString(timeRemaining);
dumpLine(pw, 0 /* uid */, "i" /* category */, CHARGE_TIME_REMAIN_DATA,
(Object[])lineArgs);
}
dumpCheckinLocked(context, pw, STATS_SINCE_CHARGED, -1,
(flags&DUMP_DEVICE_WIFI_ONLY) != 0);
}
}
}