Google Git
Sign in
android / platform / frameworks / base / ee7805be22756970568334961daa23d0b5856846 / . / services / core / java / com / android / server / job / JobSchedulerService.java
blob: 9d931467d91482e86cca438058d9add0d4a44e0e [file] [log] [blame]
/*
* Copyright (C) 2014 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 com.android.server.job;
import static android.content.pm.PackageManager.COMPONENT_ENABLED_STATE_DISABLED;
import static android.content.pm.PackageManager.COMPONENT_ENABLED_STATE_DISABLED_USER;
import java.io.FileDescriptor;
import java.io.PrintWriter;
import java.util.ArrayList;
import java.util.Arrays;
import java.util.Collections;
import java.util.Comparator;
import java.util.Iterator;
import java.util.List;
import android.app.Activity;
import android.app.ActivityManager;
import android.app.ActivityManagerNative;
import android.app.AppGlobals;
import android.app.IUidObserver;
import android.app.job.JobInfo;
import android.app.job.JobParameters;
import android.app.job.JobScheduler;
import android.app.job.JobService;
import android.app.job.IJobScheduler;
import android.content.BroadcastReceiver;
import android.content.ComponentName;
import android.content.ContentResolver;
import android.content.Context;
import android.content.Intent;
import android.content.IntentFilter;
import android.content.pm.ApplicationInfo;
import android.content.pm.IPackageManager;
import android.content.pm.PackageInfo;
import android.content.pm.PackageManager;
import android.content.pm.ServiceInfo;
import android.content.pm.PackageManager.NameNotFoundException;
import android.database.ContentObserver;
import android.net.Uri;
import android.os.BatteryStats;
import android.os.Binder;
import android.os.Handler;
import android.os.Looper;
import android.os.Message;
import android.os.Process;
import android.os.PowerManager;
import android.os.RemoteException;
import android.os.ResultReceiver;
import android.os.ServiceManager;
import android.os.SystemClock;
import android.os.UserHandle;
import android.provider.Settings;
import android.util.KeyValueListParser;
import android.util.Slog;
import android.util.SparseArray;
import android.util.SparseIntArray;
import android.util.TimeUtils;
import com.android.internal.app.IBatteryStats;
import com.android.internal.app.procstats.ProcessStats;
import com.android.internal.util.ArrayUtils;
import com.android.server.DeviceIdleController;
import com.android.server.LocalServices;
import com.android.server.job.JobStore.JobStatusFunctor;
import com.android.server.job.controllers.AppIdleController;
import com.android.server.job.controllers.BatteryController;
import com.android.server.job.controllers.ConnectivityController;
import com.android.server.job.controllers.ContentObserverController;
import com.android.server.job.controllers.DeviceIdleJobsController;
import com.android.server.job.controllers.IdleController;
import com.android.server.job.controllers.JobStatus;
import com.android.server.job.controllers.StateController;
import com.android.server.job.controllers.TimeController;
import libcore.util.EmptyArray;
/**
* Responsible for taking jobs representing work to be performed by a client app, and determining
* based on the criteria specified when that job should be run against the client application's
* endpoint.
* Implements logic for scheduling, and rescheduling jobs. The JobSchedulerService knows nothing
* about constraints, or the state of active jobs. It receives callbacks from the various
* controllers and completed jobs and operates accordingly.
*
* Note on locking: Any operations that manipulate {@link #mJobs} need to lock on that object.
* Any function with the suffix 'Locked' also needs to lock on {@link #mJobs}.
* @hide
*/
public final class JobSchedulerService extends com.android.server.SystemService
implements StateChangedListener, JobCompletedListener {
static final String TAG = "JobSchedulerService";
public static final boolean DEBUG = false;
/** The maximum number of concurrent jobs we run at one time. */
private static final int MAX_JOB_CONTEXTS_COUNT = 16;
/** Enforce a per-app limit on scheduled jobs? */
private static final boolean ENFORCE_MAX_JOBS = true;
/** The maximum number of jobs that we allow an unprivileged app to schedule */
private static final int MAX_JOBS_PER_APP = 100;
/** Global local for all job scheduler state. */
final Object mLock = new Object();
/** Master list of jobs. */
final JobStore mJobs;
/** Tracking amount of time each package runs for. */
final JobPackageTracker mJobPackageTracker = new JobPackageTracker();
static final int MSG_JOB_EXPIRED = 0;
static final int MSG_CHECK_JOB = 1;
static final int MSG_STOP_JOB = 2;
static final int MSG_CHECK_JOB_GREEDY = 3;
/**
* Track Services that have currently active or pending jobs. The index is provided by
* {@link JobStatus#getServiceToken()}
*/
final List<JobServiceContext> mActiveServices = new ArrayList<>();
/** List of controllers that will notify this service of updates to jobs. */
List<StateController> mControllers;
/**
* Queue of pending jobs. The JobServiceContext class will receive jobs from this list
* when ready to execute them.
*/
final ArrayList<JobStatus> mPendingJobs = new ArrayList<>();
int[] mStartedUsers = EmptyArray.INT;
final JobHandler mHandler;
final JobSchedulerStub mJobSchedulerStub;
IBatteryStats mBatteryStats;
PowerManager mPowerManager;
DeviceIdleController.LocalService mLocalDeviceIdleController;
/**
* Set to true once we are allowed to run third party apps.
*/
boolean mReadyToRock;
/**
* What we last reported to DeviceIdleController about whether we are active.
*/
boolean mReportedActive;
/**
* Current limit on the number of concurrent JobServiceContext entries we want to
* keep actively running a job.
*/
int mMaxActiveJobs = 1;
/**
* Which uids are currently in the foreground.
*/
final SparseIntArray mUidPriorityOverride = new SparseIntArray();
// -- Pre-allocated temporaries only for use in assignJobsToContextsLocked --
/**
* This array essentially stores the state of mActiveServices array.
* The ith index stores the job present on the ith JobServiceContext.
* We manipulate this array until we arrive at what jobs should be running on
* what JobServiceContext.
*/
JobStatus[] mTmpAssignContextIdToJobMap = new JobStatus[MAX_JOB_CONTEXTS_COUNT];
/**
* Indicates whether we need to act on this jobContext id
*/
boolean[] mTmpAssignAct = new boolean[MAX_JOB_CONTEXTS_COUNT];
/**
* The uid whose jobs we would like to assign to a context.
*/
int[] mTmpAssignPreferredUidForContext = new int[MAX_JOB_CONTEXTS_COUNT];
/**
* All times are in milliseconds. These constants are kept synchronized with the system
* global Settings. Any access to this class or its fields should be done while
* holding the JobSchedulerService.mLock lock.
*/
private final class Constants extends ContentObserver {
// Key names stored in the settings value.
private static final String KEY_MIN_IDLE_COUNT = "min_idle_count";
private static final String KEY_MIN_CHARGING_COUNT = "min_charging_count";
private static final String KEY_MIN_CONNECTIVITY_COUNT = "min_connectivity_count";
private static final String KEY_MIN_CONTENT_COUNT = "min_content_count";
private static final String KEY_MIN_READY_JOBS_COUNT = "min_ready_jobs_count";
private static final String KEY_HEAVY_USE_FACTOR = "heavy_use_factor";
private static final String KEY_MODERATE_USE_FACTOR = "moderate_use_factor";
private static final String KEY_FG_JOB_COUNT = "fg_job_count";
private static final String KEY_BG_NORMAL_JOB_COUNT = "bg_normal_job_count";
private static final String KEY_BG_MODERATE_JOB_COUNT = "bg_moderate_job_count";
private static final String KEY_BG_LOW_JOB_COUNT = "bg_low_job_count";
private static final String KEY_BG_CRITICAL_JOB_COUNT = "bg_critical_job_count";
private static final int DEFAULT_MIN_IDLE_COUNT = 1;
private static final int DEFAULT_MIN_CHARGING_COUNT = 1;
private static final int DEFAULT_MIN_CONNECTIVITY_COUNT = 1;
private static final int DEFAULT_MIN_CONTENT_COUNT = 1;
private static final int DEFAULT_MIN_READY_JOBS_COUNT = 1;
private static final float DEFAULT_HEAVY_USE_FACTOR = .9f;
private static final float DEFAULT_MODERATE_USE_FACTOR = .5f;
private static final int DEFAULT_FG_JOB_COUNT = 4;
private static final int DEFAULT_BG_NORMAL_JOB_COUNT = 6;
private static final int DEFAULT_BG_MODERATE_JOB_COUNT = 4;
private static final int DEFAULT_BG_LOW_JOB_COUNT = 2;
private static final int DEFAULT_BG_CRITICAL_JOB_COUNT = 1;
/**
* Minimum # of idle jobs that must be ready in order to force the JMS to schedule things
* early.
*/
int MIN_IDLE_COUNT = DEFAULT_MIN_IDLE_COUNT;
/**
* Minimum # of charging jobs that must be ready in order to force the JMS to schedule
* things early.
*/
int MIN_CHARGING_COUNT = DEFAULT_MIN_CHARGING_COUNT;
/**
* Minimum # of connectivity jobs that must be ready in order to force the JMS to schedule
* things early. 1 == Run connectivity jobs as soon as ready.
*/
int MIN_CONNECTIVITY_COUNT = DEFAULT_MIN_CONNECTIVITY_COUNT;
/**
* Minimum # of content trigger jobs that must be ready in order to force the JMS to
* schedule things early.
*/
int MIN_CONTENT_COUNT = DEFAULT_MIN_CONTENT_COUNT;
/**
* Minimum # of jobs (with no particular constraints) for which the JMS will be happy
* running some work early. This (and thus the other min counts) is now set to 1, to
* prevent any batching at this level. Since we now do batching through doze, that is
* a much better mechanism.
*/
int MIN_READY_JOBS_COUNT = DEFAULT_MIN_READY_JOBS_COUNT;
/**
* This is the job execution factor that is considered to be heavy use of the system.
*/
float HEAVY_USE_FACTOR = DEFAULT_HEAVY_USE_FACTOR;
/**
* This is the job execution factor that is considered to be moderate use of the system.
*/
float MODERATE_USE_FACTOR = DEFAULT_MODERATE_USE_FACTOR;
/**
* The number of MAX_JOB_CONTEXTS_COUNT we reserve for the foreground app.
*/
int FG_JOB_COUNT = DEFAULT_FG_JOB_COUNT;
/**
* The maximum number of background jobs we allow when the system is in a normal
* memory state.
*/
int BG_NORMAL_JOB_COUNT = DEFAULT_BG_NORMAL_JOB_COUNT;
/**
* The maximum number of background jobs we allow when the system is in a moderate
* memory state.
*/
int BG_MODERATE_JOB_COUNT = DEFAULT_BG_MODERATE_JOB_COUNT;
/**
* The maximum number of background jobs we allow when the system is in a low
* memory state.
*/
int BG_LOW_JOB_COUNT = DEFAULT_BG_LOW_JOB_COUNT;
/**
* The maximum number of background jobs we allow when the system is in a critical
* memory state.
*/
int BG_CRITICAL_JOB_COUNT = DEFAULT_BG_CRITICAL_JOB_COUNT;
private ContentResolver mResolver;
private final KeyValueListParser mParser = new KeyValueListParser(',');
public Constants(Handler handler) {
super(handler);
}
public void start(ContentResolver resolver) {
mResolver = resolver;
mResolver.registerContentObserver(Settings.Global.getUriFor(
Settings.Global.JOB_SCHEDULER_CONSTANTS), false, this);
updateConstants();
}
@Override
public void onChange(boolean selfChange, Uri uri) {
updateConstants();
}
private void updateConstants() {
synchronized (mLock) {
try {
mParser.setString(Settings.Global.getString(mResolver,
Settings.Global.ALARM_MANAGER_CONSTANTS));
} catch (IllegalArgumentException e) {
// Failed to parse the settings string, log this and move on
// with defaults.
Slog.e(TAG, "Bad device idle settings", e);
}
MIN_IDLE_COUNT = mParser.getInt(KEY_MIN_IDLE_COUNT,
DEFAULT_MIN_IDLE_COUNT);
MIN_CHARGING_COUNT = mParser.getInt(KEY_MIN_CHARGING_COUNT,
DEFAULT_MIN_CHARGING_COUNT);
MIN_CONNECTIVITY_COUNT = mParser.getInt(KEY_MIN_CONNECTIVITY_COUNT,
DEFAULT_MIN_CONNECTIVITY_COUNT);
MIN_CONTENT_COUNT = mParser.getInt(KEY_MIN_CONTENT_COUNT,
DEFAULT_MIN_CONTENT_COUNT);
MIN_READY_JOBS_COUNT = mParser.getInt(KEY_MIN_READY_JOBS_COUNT,
DEFAULT_MIN_READY_JOBS_COUNT);
HEAVY_USE_FACTOR = mParser.getFloat(KEY_HEAVY_USE_FACTOR,
DEFAULT_HEAVY_USE_FACTOR);
MODERATE_USE_FACTOR = mParser.getFloat(KEY_MODERATE_USE_FACTOR,
DEFAULT_MODERATE_USE_FACTOR);
FG_JOB_COUNT = mParser.getInt(KEY_FG_JOB_COUNT,
DEFAULT_FG_JOB_COUNT);
BG_NORMAL_JOB_COUNT = mParser.getInt(KEY_BG_NORMAL_JOB_COUNT,
DEFAULT_BG_NORMAL_JOB_COUNT);
if ((FG_JOB_COUNT+BG_NORMAL_JOB_COUNT) > MAX_JOB_CONTEXTS_COUNT) {
BG_NORMAL_JOB_COUNT = MAX_JOB_CONTEXTS_COUNT - FG_JOB_COUNT;
}
BG_MODERATE_JOB_COUNT = mParser.getInt(KEY_BG_MODERATE_JOB_COUNT,
DEFAULT_BG_MODERATE_JOB_COUNT);
if ((FG_JOB_COUNT+BG_MODERATE_JOB_COUNT) > MAX_JOB_CONTEXTS_COUNT) {
BG_MODERATE_JOB_COUNT = MAX_JOB_CONTEXTS_COUNT - FG_JOB_COUNT;
}
BG_LOW_JOB_COUNT = mParser.getInt(KEY_BG_LOW_JOB_COUNT,
DEFAULT_BG_LOW_JOB_COUNT);
if ((FG_JOB_COUNT+BG_LOW_JOB_COUNT) > MAX_JOB_CONTEXTS_COUNT) {
BG_LOW_JOB_COUNT = MAX_JOB_CONTEXTS_COUNT - FG_JOB_COUNT;
}
BG_CRITICAL_JOB_COUNT = mParser.getInt(KEY_BG_CRITICAL_JOB_COUNT,
DEFAULT_BG_CRITICAL_JOB_COUNT);
if ((FG_JOB_COUNT+BG_CRITICAL_JOB_COUNT) > MAX_JOB_CONTEXTS_COUNT) {
BG_CRITICAL_JOB_COUNT = MAX_JOB_CONTEXTS_COUNT - FG_JOB_COUNT;
}
}
}
void dump(PrintWriter pw) {
pw.println(" Settings:");
pw.print(" "); pw.print(KEY_MIN_IDLE_COUNT); pw.print("=");
pw.print(MIN_IDLE_COUNT); pw.println();
pw.print(" "); pw.print(KEY_MIN_CHARGING_COUNT); pw.print("=");
pw.print(MIN_CHARGING_COUNT); pw.println();
pw.print(" "); pw.print(KEY_MIN_CONNECTIVITY_COUNT); pw.print("=");
pw.print(MIN_CONNECTIVITY_COUNT); pw.println();
pw.print(" "); pw.print(KEY_MIN_CONTENT_COUNT); pw.print("=");
pw.print(MIN_CONTENT_COUNT); pw.println();
pw.print(" "); pw.print(KEY_MIN_READY_JOBS_COUNT); pw.print("=");
pw.print(MIN_READY_JOBS_COUNT); pw.println();
pw.print(" "); pw.print(KEY_HEAVY_USE_FACTOR); pw.print("=");
pw.print(HEAVY_USE_FACTOR); pw.println();
pw.print(" "); pw.print(KEY_MODERATE_USE_FACTOR); pw.print("=");
pw.print(MODERATE_USE_FACTOR); pw.println();
pw.print(" "); pw.print(KEY_FG_JOB_COUNT); pw.print("=");
pw.print(FG_JOB_COUNT); pw.println();
pw.print(" "); pw.print(KEY_BG_NORMAL_JOB_COUNT); pw.print("=");
pw.print(BG_NORMAL_JOB_COUNT); pw.println();
pw.print(" "); pw.print(KEY_BG_MODERATE_JOB_COUNT); pw.print("=");
pw.print(BG_MODERATE_JOB_COUNT); pw.println();
pw.print(" "); pw.print(KEY_BG_LOW_JOB_COUNT); pw.print("=");
pw.print(BG_LOW_JOB_COUNT); pw.println();
pw.print(" "); pw.print(KEY_BG_CRITICAL_JOB_COUNT); pw.print("=");
pw.print(BG_CRITICAL_JOB_COUNT); pw.println();
}
}
final Constants mConstants;
/**
* Cleans up outstanding jobs when a package is removed. Even if it's being replaced later we
* still clean up. On reinstall the package will have a new uid.
*/
private final BroadcastReceiver mBroadcastReceiver = new BroadcastReceiver() {
@Override
public void onReceive(Context context, Intent intent) {
final String action = intent.getAction();
if (DEBUG) {
Slog.d(TAG, "Receieved: " + action);
}
if (Intent.ACTION_PACKAGE_CHANGED.equals(action)) {
// Purge the app's jobs if the whole package was just disabled. When this is
// the case the component name will be a bare package name.
final String pkgName = getPackageName(intent);
final int pkgUid = intent.getIntExtra(Intent.EXTRA_UID, -1);
if (pkgName != null && pkgUid != -1) {
final String[] changedComponents = intent.getStringArrayExtra(
Intent.EXTRA_CHANGED_COMPONENT_NAME_LIST);
if (changedComponents != null) {
for (String component : changedComponents) {
if (component.equals(pkgName)) {
if (DEBUG) {
Slog.d(TAG, "Package state change: " + pkgName);
}
try {
final int userId = UserHandle.getUserId(pkgUid);
IPackageManager pm = AppGlobals.getPackageManager();
final int state = pm.getApplicationEnabledSetting(pkgName, userId);
if (state == COMPONENT_ENABLED_STATE_DISABLED
|| state == COMPONENT_ENABLED_STATE_DISABLED_USER) {
if (DEBUG) {
Slog.d(TAG, "Removing jobs for package " + pkgName
+ " in user " + userId);
}
cancelJobsForUid(pkgUid, true);
}
} catch (RemoteException e) { /* cannot happen */ }
break;
}
}
}
} else {
Slog.w(TAG, "PACKAGE_CHANGED for " + pkgName + " / uid " + pkgUid);
}
} else if (Intent.ACTION_PACKAGE_REMOVED.equals(action)) {
// If this is an outright uninstall rather than the first half of an
// app update sequence, cancel the jobs associated with the app.
if (!intent.getBooleanExtra(Intent.EXTRA_REPLACING, false)) {
int uidRemoved = intent.getIntExtra(Intent.EXTRA_UID, -1);
if (DEBUG) {
Slog.d(TAG, "Removing jobs for uid: " + uidRemoved);
}
cancelJobsForUid(uidRemoved, true);
}
} else if (Intent.ACTION_USER_REMOVED.equals(action)) {
final int userId = intent.getIntExtra(Intent.EXTRA_USER_HANDLE, 0);
if (DEBUG) {
Slog.d(TAG, "Removing jobs for user: " + userId);
}
cancelJobsForUser(userId);
} else if (Intent.ACTION_QUERY_PACKAGE_RESTART.equals(action)) {
// Has this package scheduled any jobs, such that we will take action
// if it were to be force-stopped?
final int pkgUid = intent.getIntExtra(Intent.EXTRA_UID, -1);
final String pkgName = intent.getData().getSchemeSpecificPart();
if (pkgUid != -1) {
List<JobStatus> jobsForUid;
synchronized (mLock) {
jobsForUid = mJobs.getJobsByUid(pkgUid);
}
for (int i = jobsForUid.size() - 1; i >= 0; i--) {
if (jobsForUid.get(i).getSourcePackageName().equals(pkgName)) {
if (DEBUG) {
Slog.d(TAG, "Restart query: package " + pkgName + " at uid "
+ pkgUid + " has jobs");
}
setResultCode(Activity.RESULT_OK);
break;
}
}
}
} else if (Intent.ACTION_PACKAGE_RESTARTED.equals(action)) {
// possible force-stop
final int pkgUid = intent.getIntExtra(Intent.EXTRA_UID, -1);
final String pkgName = intent.getData().getSchemeSpecificPart();
if (pkgUid != -1) {
if (DEBUG) {
Slog.d(TAG, "Removing jobs for pkg " + pkgName + " at uid " + pkgUid);
}
cancelJobsForPackageAndUid(pkgName, pkgUid);
}
}
}
};
private String getPackageName(Intent intent) {
Uri uri = intent.getData();
String pkg = uri != null ? uri.getSchemeSpecificPart() : null;
return pkg;
}
final private IUidObserver mUidObserver = new IUidObserver.Stub() {
@Override public void onUidStateChanged(int uid, int procState) throws RemoteException {
updateUidState(uid, procState);
}
@Override public void onUidGone(int uid) throws RemoteException {
updateUidState(uid, ActivityManager.PROCESS_STATE_CACHED_EMPTY);
}
@Override public void onUidActive(int uid) throws RemoteException {
}
@Override public void onUidIdle(int uid) throws RemoteException {
cancelJobsForUid(uid, false);
}
};
public Object getLock() {
return mLock;
}
public JobStore getJobStore() {
return mJobs;
}
@Override
public void onStartUser(int userHandle) {
mStartedUsers = ArrayUtils.appendInt(mStartedUsers, userHandle);
// Let's kick any outstanding jobs for this user.
mHandler.obtainMessage(MSG_CHECK_JOB).sendToTarget();
}
@Override
public void onUnlockUser(int userHandle) {
// Let's kick any outstanding jobs for this user.
mHandler.obtainMessage(MSG_CHECK_JOB).sendToTarget();
}
@Override
public void onStopUser(int userHandle) {
mStartedUsers = ArrayUtils.removeInt(mStartedUsers, userHandle);
}
/**
* Entry point from client to schedule the provided job.
* This cancels the job if it's already been scheduled, and replaces it with the one provided.
* @param job JobInfo object containing execution parameters
* @param uId The package identifier of the application this job is for.
* @return Result of this operation. See <code>JobScheduler#RESULT_*</code> return codes.
*/
public int schedule(JobInfo job, int uId) {
return scheduleAsPackage(job, uId, null, -1, null);
}
public int scheduleAsPackage(JobInfo job, int uId, String packageName, int userId,
String tag) {
JobStatus jobStatus = JobStatus.createFromJobInfo(job, uId, packageName, userId, tag);
try {
if (ActivityManagerNative.getDefault().getAppStartMode(uId,
job.getService().getPackageName()) == ActivityManager.APP_START_MODE_DISABLED) {
Slog.w(TAG, "Not scheduling job " + uId + ":" + job.toString()
+ " -- package not allowed to start");
return JobScheduler.RESULT_FAILURE;
}
} catch (RemoteException e) {
}
if (DEBUG) Slog.d(TAG, "SCHEDULE: " + jobStatus.toShortString());
JobStatus toCancel;
synchronized (mLock) {
// Jobs on behalf of others don't apply to the per-app job cap
if (ENFORCE_MAX_JOBS && packageName == null) {
if (mJobs.countJobsForUid(uId) > MAX_JOBS_PER_APP) {
Slog.w(TAG, "Too many jobs for uid " + uId);
throw new IllegalStateException("Apps may not schedule more than "
+ MAX_JOBS_PER_APP + " distinct jobs");
}
}
toCancel = mJobs.getJobByUidAndJobId(uId, job.getId());
if (toCancel != null) {
cancelJobImpl(toCancel, jobStatus);
}
startTrackingJob(jobStatus, toCancel);
}
mHandler.obtainMessage(MSG_CHECK_JOB).sendToTarget();
return JobScheduler.RESULT_SUCCESS;
}
public List<JobInfo> getPendingJobs(int uid) {
synchronized (mLock) {
List<JobStatus> jobs = mJobs.getJobsByUid(uid);
ArrayList<JobInfo> outList = new ArrayList<JobInfo>(jobs.size());
for (int i = jobs.size() - 1; i >= 0; i--) {
JobStatus job = jobs.get(i);
outList.add(job.getJob());
}
return outList;
}
}
public JobInfo getPendingJob(int uid, int jobId) {
synchronized (mLock) {
List<JobStatus> jobs = mJobs.getJobsByUid(uid);
for (int i = jobs.size() - 1; i >= 0; i--) {
JobStatus job = jobs.get(i);
if (job.getJobId() == jobId) {
return job.getJob();
}
}
return null;
}
}
void cancelJobsForUser(int userHandle) {
List<JobStatus> jobsForUser;
synchronized (mLock) {
jobsForUser = mJobs.getJobsByUser(userHandle);
}
for (int i=0; i<jobsForUser.size(); i++) {
JobStatus toRemove = jobsForUser.get(i);
cancelJobImpl(toRemove, null);
}
}
void cancelJobsForPackageAndUid(String pkgName, int uid) {
List<JobStatus> jobsForUid;
synchronized (mLock) {
jobsForUid = mJobs.getJobsByUid(uid);
}
for (int i = jobsForUid.size() - 1; i >= 0; i--) {
final JobStatus job = jobsForUid.get(i);
if (job.getSourcePackageName().equals(pkgName)) {
cancelJobImpl(job, null);
}
}
}
/**
* Entry point from client to cancel all jobs originating from their uid.
* This will remove the job from the master list, and cancel the job if it was staged for
* execution or being executed.
* @param uid Uid to check against for removal of a job.
* @param forceAll If true, all jobs for the uid will be canceled; if false, only those
* whose apps are stopped.
*/
public void cancelJobsForUid(int uid, boolean forceAll) {
List<JobStatus> jobsForUid;
synchronized (mLock) {
jobsForUid = mJobs.getJobsByUid(uid);
}
for (int i=0; i<jobsForUid.size(); i++) {
JobStatus toRemove = jobsForUid.get(i);
if (!forceAll) {
String packageName = toRemove.getServiceComponent().getPackageName();
try {
if (ActivityManagerNative.getDefault().getAppStartMode(uid, packageName)
!= ActivityManager.APP_START_MODE_DISABLED) {
continue;
}
} catch (RemoteException e) {
}
}
cancelJobImpl(toRemove, null);
}
}
/**
* Entry point from client to cancel the job corresponding to the jobId provided.
* This will remove the job from the master list, and cancel the job if it was staged for
* execution or being executed.
* @param uid Uid of the calling client.
* @param jobId Id of the job, provided at schedule-time.
*/
public void cancelJob(int uid, int jobId) {
JobStatus toCancel;
synchronized (mLock) {
toCancel = mJobs.getJobByUidAndJobId(uid, jobId);
}
if (toCancel != null) {
cancelJobImpl(toCancel, null);
}
}
private void cancelJobImpl(JobStatus cancelled, JobStatus incomingJob) {
if (DEBUG) Slog.d(TAG, "CANCEL: " + cancelled.toShortString());
stopTrackingJob(cancelled, incomingJob, true /* writeBack */);
synchronized (mLock) {
// Remove from pending queue.
if (mPendingJobs.remove(cancelled)) {
mJobPackageTracker.noteNonpending(cancelled);
}
// Cancel if running.
stopJobOnServiceContextLocked(cancelled, JobParameters.REASON_CANCELED);
reportActive();
}
}
void updateUidState(int uid, int procState) {
synchronized (mLock) {
if (procState == ActivityManager.PROCESS_STATE_TOP) {
// Only use this if we are exactly the top app. All others can live
// with just the foreground priority. This means that persistent processes
// can never be the top app priority... that is fine.
mUidPriorityOverride.put(uid, JobInfo.PRIORITY_TOP_APP);
} else if (procState <= ActivityManager.PROCESS_STATE_FOREGROUND_SERVICE) {
mUidPriorityOverride.put(uid, JobInfo.PRIORITY_FOREGROUND_APP);
} else {
mUidPriorityOverride.delete(uid);
}
}
}
@Override
public void onDeviceIdleStateChanged(boolean deviceIdle) {
synchronized (mLock) {
if (deviceIdle) {
// When becoming idle, make sure no jobs are actively running,
// except those using the idle exemption flag.
for (int i=0; i<mActiveServices.size(); i++) {
JobServiceContext jsc = mActiveServices.get(i);
final JobStatus executing = jsc.getRunningJob();
if (executing != null
&& (executing.getFlags() & JobInfo.FLAG_WILL_BE_FOREGROUND) == 0) {
jsc.cancelExecutingJob(JobParameters.REASON_DEVICE_IDLE);
}
}
} else {
// When coming out of idle, allow thing to start back up.
if (mReadyToRock) {
if (mLocalDeviceIdleController != null) {
if (!mReportedActive) {
mReportedActive = true;
mLocalDeviceIdleController.setJobsActive(true);
}
}
}
mHandler.obtainMessage(MSG_CHECK_JOB).sendToTarget();
}
}
}
void reportActive() {
// active is true if pending queue contains jobs OR some job is running.
boolean active = mPendingJobs.size() > 0;
if (mPendingJobs.size() <= 0) {
for (int i=0; i<mActiveServices.size(); i++) {
final JobServiceContext jsc = mActiveServices.get(i);
final JobStatus job = jsc.getRunningJob();
if (job != null
&& (job.getJob().getFlags() & JobInfo.FLAG_WILL_BE_FOREGROUND) == 0
&& !job.dozeWhitelisted) {
// We will report active if we have a job running and it is not an exception
// due to being in the foreground or whitelisted.
active = true;
break;
}
}
}
if (mReportedActive != active) {
mReportedActive = active;
if (mLocalDeviceIdleController != null) {
mLocalDeviceIdleController.setJobsActive(active);
}
}
}
/**
* Initializes the system service.
* <p>
* Subclasses must define a single argument constructor that accepts the context
* and passes it to super.
* </p>
*
* @param context The system server context.
*/
public JobSchedulerService(Context context) {
super(context);
mHandler = new JobHandler(context.getMainLooper());
mConstants = new Constants(mHandler);
mJobSchedulerStub = new JobSchedulerStub();
mJobs = JobStore.initAndGet(this);
// Create the controllers.
mControllers = new ArrayList<StateController>();
mControllers.add(ConnectivityController.get(this));
mControllers.add(TimeController.get(this));
mControllers.add(IdleController.get(this));
mControllers.add(BatteryController.get(this));
mControllers.add(AppIdleController.get(this));
mControllers.add(ContentObserverController.get(this));
mControllers.add(DeviceIdleJobsController.get(this));
}
@Override
public void onStart() {
publishLocalService(JobSchedulerInternal.class, new LocalService());
publishBinderService(Context.JOB_SCHEDULER_SERVICE, mJobSchedulerStub);
}
@Override
public void onBootPhase(int phase) {
if (PHASE_SYSTEM_SERVICES_READY == phase) {
mConstants.start(getContext().getContentResolver());
// Register br for package removals and user removals.
final IntentFilter filter = new IntentFilter();
filter.addAction(Intent.ACTION_PACKAGE_REMOVED);
filter.addAction(Intent.ACTION_PACKAGE_CHANGED);
filter.addAction(Intent.ACTION_PACKAGE_RESTARTED);
filter.addAction(Intent.ACTION_QUERY_PACKAGE_RESTART);
filter.addDataScheme("package");
getContext().registerReceiverAsUser(
mBroadcastReceiver, UserHandle.ALL, filter, null, null);
final IntentFilter userFilter = new IntentFilter(Intent.ACTION_USER_REMOVED);
getContext().registerReceiverAsUser(
mBroadcastReceiver, UserHandle.ALL, userFilter, null, null);
mPowerManager = (PowerManager)getContext().getSystemService(Context.POWER_SERVICE);
try {
ActivityManagerNative.getDefault().registerUidObserver(mUidObserver,
ActivityManager.UID_OBSERVER_PROCSTATE | ActivityManager.UID_OBSERVER_GONE
| ActivityManager.UID_OBSERVER_IDLE);
} catch (RemoteException e) {
// ignored; both services live in system_server
}
} else if (phase == PHASE_THIRD_PARTY_APPS_CAN_START) {
synchronized (mLock) {
// Let's go!
mReadyToRock = true;
mBatteryStats = IBatteryStats.Stub.asInterface(ServiceManager.getService(
BatteryStats.SERVICE_NAME));
mLocalDeviceIdleController
= LocalServices.getService(DeviceIdleController.LocalService.class);
// Create the "runners".
for (int i = 0; i < MAX_JOB_CONTEXTS_COUNT; i++) {
mActiveServices.add(
new JobServiceContext(this, mBatteryStats, mJobPackageTracker,
getContext().getMainLooper()));
}
// Attach jobs to their controllers.
mJobs.forEachJob(new JobStatusFunctor() {
@Override
public void process(JobStatus job) {
for (int controller = 0; controller < mControllers.size(); controller++) {
final StateController sc = mControllers.get(controller);
sc.maybeStartTrackingJobLocked(job, null);
}
}
});
// GO GO GO!
mHandler.obtainMessage(MSG_CHECK_JOB).sendToTarget();
}
}
}
/**
* Called when we have a job status object that we need to insert in our
* {@link com.android.server.job.JobStore}, and make sure all the relevant controllers know
* about.
*/
private void startTrackingJob(JobStatus jobStatus, JobStatus lastJob) {
synchronized (mLock) {
final boolean update = mJobs.add(jobStatus);
if (mReadyToRock) {
for (int i = 0; i < mControllers.size(); i++) {
StateController controller = mControllers.get(i);
if (update) {
controller.maybeStopTrackingJobLocked(jobStatus, null, true);
}
controller.maybeStartTrackingJobLocked(jobStatus, lastJob);
}
}
}
}
/**
* Called when we want to remove a JobStatus object that we've finished executing. Returns the
* object removed.
*/
private boolean stopTrackingJob(JobStatus jobStatus, JobStatus incomingJob,
boolean writeBack) {
synchronized (mLock) {
// Remove from store as well as controllers.
final boolean removed = mJobs.remove(jobStatus, writeBack);
if (removed && mReadyToRock) {
for (int i=0; i<mControllers.size(); i++) {
StateController controller = mControllers.get(i);
controller.maybeStopTrackingJobLocked(jobStatus, incomingJob, false);
}
}
return removed;
}
}
private boolean stopJobOnServiceContextLocked(JobStatus job, int reason) {
for (int i=0; i<mActiveServices.size(); i++) {
JobServiceContext jsc = mActiveServices.get(i);
final JobStatus executing = jsc.getRunningJob();
if (executing != null && executing.matches(job.getUid(), job.getJobId())) {
jsc.cancelExecutingJob(reason);
return true;
}
}
return false;
}
/**
* @param job JobStatus we are querying against.
* @return Whether or not the job represented by the status object is currently being run or
* is pending.
*/
private boolean isCurrentlyActiveLocked(JobStatus job) {
for (int i=0; i<mActiveServices.size(); i++) {
JobServiceContext serviceContext = mActiveServices.get(i);
final JobStatus running = serviceContext.getRunningJob();
if (running != null && running.matches(job.getUid(), job.getJobId())) {
return true;
}
}
return false;
}
void noteJobsPending(List<JobStatus> jobs) {
for (int i = jobs.size() - 1; i >= 0; i--) {
JobStatus job = jobs.get(i);
mJobPackageTracker.notePending(job);
}
}
void noteJobsNonpending(List<JobStatus> jobs) {
for (int i = jobs.size() - 1; i >= 0; i--) {
JobStatus job = jobs.get(i);
mJobPackageTracker.noteNonpending(job);
}
}
/**
* Reschedules the given job based on the job's backoff policy. It doesn't make sense to
* specify an override deadline on a failed job (the failed job will run even though it's not
* ready), so we reschedule it with {@link JobStatus#NO_LATEST_RUNTIME}, but specify that any
* ready job with {@link JobStatus#numFailures} > 0 will be executed.
*
* @param failureToReschedule Provided job status that we will reschedule.
* @return A newly instantiated JobStatus with the same constraints as the last job except
* with adjusted timing constraints.
*
* @see JobHandler#maybeQueueReadyJobsForExecutionLockedH
*/
private JobStatus getRescheduleJobForFailure(JobStatus failureToReschedule) {
final long elapsedNowMillis = SystemClock.elapsedRealtime();
final JobInfo job = failureToReschedule.getJob();
final long initialBackoffMillis = job.getInitialBackoffMillis();
final int backoffAttempts = failureToReschedule.getNumFailures() + 1;
long delayMillis;
switch (job.getBackoffPolicy()) {
case JobInfo.BACKOFF_POLICY_LINEAR:
delayMillis = initialBackoffMillis * backoffAttempts;
break;
default:
if (DEBUG) {
Slog.v(TAG, "Unrecognised back-off policy, defaulting to exponential.");
}
case JobInfo.BACKOFF_POLICY_EXPONENTIAL:
delayMillis =
(long) Math.scalb(initialBackoffMillis, backoffAttempts - 1);
break;
}
delayMillis =
Math.min(delayMillis, JobInfo.MAX_BACKOFF_DELAY_MILLIS);
JobStatus newJob = new JobStatus(failureToReschedule, elapsedNowMillis + delayMillis,
JobStatus.NO_LATEST_RUNTIME, backoffAttempts);
for (int ic=0; ic<mControllers.size(); ic++) {
StateController controller = mControllers.get(ic);
controller.rescheduleForFailure(newJob, failureToReschedule);
}
return newJob;
}
/**
* Called after a periodic has executed so we can reschedule it. We take the last execution
* time of the job to be the time of completion (i.e. the time at which this function is
* called).
* This could be inaccurate b/c the job can run for as long as
* {@link com.android.server.job.JobServiceContext#EXECUTING_TIMESLICE_MILLIS}, but will lead
* to underscheduling at least, rather than if we had taken the last execution time to be the
* start of the execution.
* @return A new job representing the execution criteria for this instantiation of the
* recurring job.
*/
private JobStatus getRescheduleJobForPeriodic(JobStatus periodicToReschedule) {
final long elapsedNow = SystemClock.elapsedRealtime();
// Compute how much of the period is remaining.
long runEarly = 0L;
// If this periodic was rescheduled it won't have a deadline.
if (periodicToReschedule.hasDeadlineConstraint()) {
runEarly = Math.max(periodicToReschedule.getLatestRunTimeElapsed() - elapsedNow, 0L);
}
long flex = periodicToReschedule.getJob().getFlexMillis();
long period = periodicToReschedule.getJob().getIntervalMillis();
long newLatestRuntimeElapsed = elapsedNow + runEarly + period;
long newEarliestRunTimeElapsed = newLatestRuntimeElapsed - flex;
if (DEBUG) {
Slog.v(TAG, "Rescheduling executed periodic. New execution window [" +
newEarliestRunTimeElapsed/1000 + ", " + newLatestRuntimeElapsed/1000 + "]s");
}
return new JobStatus(periodicToReschedule, newEarliestRunTimeElapsed,
newLatestRuntimeElapsed, 0 /* backoffAttempt */);
}
// JobCompletedListener implementations.
/**
* A job just finished executing. We fetch the
* {@link com.android.server.job.controllers.JobStatus} from the store and depending on
* whether we want to reschedule we readd it to the controllers.
* @param jobStatus Completed job.
* @param needsReschedule Whether the implementing class should reschedule this job.
*/
@Override
public void onJobCompleted(JobStatus jobStatus, boolean needsReschedule) {
if (DEBUG) {
Slog.d(TAG, "Completed " + jobStatus + ", reschedule=" + needsReschedule);
}
// Do not write back immediately if this is a periodic job. The job may get lost if system
// shuts down before it is added back.
if (!stopTrackingJob(jobStatus, null, !jobStatus.getJob().isPeriodic())) {
if (DEBUG) {
Slog.d(TAG, "Could not find job to remove. Was job removed while executing?");
}
// We still want to check for jobs to execute, because this job may have
// scheduled a new job under the same job id, and now we can run it.
mHandler.obtainMessage(MSG_CHECK_JOB_GREEDY).sendToTarget();
return;
}
// Note: there is a small window of time in here where, when rescheduling a job,
// we will stop monitoring its content providers. This should be fixed by stopping
// the old job after scheduling the new one, but since we have no lock held here
// that may cause ordering problems if the app removes jobStatus while in here.
if (needsReschedule) {
JobStatus rescheduled = getRescheduleJobForFailure(jobStatus);
startTrackingJob(rescheduled, jobStatus);
} else if (jobStatus.getJob().isPeriodic()) {
JobStatus rescheduledPeriodic = getRescheduleJobForPeriodic(jobStatus);
startTrackingJob(rescheduledPeriodic, jobStatus);
}
reportActive();
mHandler.obtainMessage(MSG_CHECK_JOB_GREEDY).sendToTarget();
}
// StateChangedListener implementations.
/**
* Posts a message to the {@link com.android.server.job.JobSchedulerService.JobHandler} that
* some controller's state has changed, so as to run through the list of jobs and start/stop
* any that are eligible.
*/
@Override
public void onControllerStateChanged() {
mHandler.obtainMessage(MSG_CHECK_JOB).sendToTarget();
}
@Override
public void onRunJobNow(JobStatus jobStatus) {
mHandler.obtainMessage(MSG_JOB_EXPIRED, jobStatus).sendToTarget();
}
private class JobHandler extends Handler {
public JobHandler(Looper looper) {
super(looper);
}
@Override
public void handleMessage(Message message) {
synchronized (mLock) {
if (!mReadyToRock) {
return;
}
}
switch (message.what) {
case MSG_JOB_EXPIRED:
synchronized (mLock) {
JobStatus runNow = (JobStatus) message.obj;
// runNow can be null, which is a controller's way of indicating that its
// state is such that all ready jobs should be run immediately.
if (runNow != null && !mPendingJobs.contains(runNow)
&& mJobs.containsJob(runNow)) {
mJobPackageTracker.notePending(runNow);
mPendingJobs.add(runNow);
}
queueReadyJobsForExecutionLockedH();
}
break;
case MSG_CHECK_JOB:
synchronized (mLock) {
if (mReportedActive) {
// if jobs are currently being run, queue all ready jobs for execution.
queueReadyJobsForExecutionLockedH();
} else {
// Check the list of jobs and run some of them if we feel inclined.
maybeQueueReadyJobsForExecutionLockedH();
}
}
break;
case MSG_CHECK_JOB_GREEDY:
synchronized (mLock) {
queueReadyJobsForExecutionLockedH();
}
break;
case MSG_STOP_JOB:
cancelJobImpl((JobStatus)message.obj, null);
break;
}
maybeRunPendingJobsH();
// Don't remove JOB_EXPIRED in case one came along while processing the queue.
removeMessages(MSG_CHECK_JOB);
}
/**
* Run through list of jobs and execute all possible - at least one is expired so we do
* as many as we can.
*/
private void queueReadyJobsForExecutionLockedH() {
if (DEBUG) {
Slog.d(TAG, "queuing all ready jobs for execution:");
}
noteJobsNonpending(mPendingJobs);
mPendingJobs.clear();
mJobs.forEachJob(mReadyQueueFunctor);
mReadyQueueFunctor.postProcess();
if (DEBUG) {
final int queuedJobs = mPendingJobs.size();
if (queuedJobs == 0) {
Slog.d(TAG, "No jobs pending.");
} else {
Slog.d(TAG, queuedJobs + " jobs queued.");
}
}
}
class ReadyJobQueueFunctor implements JobStatusFunctor {
ArrayList<JobStatus> newReadyJobs;
@Override
public void process(JobStatus job) {
if (isReadyToBeExecutedLocked(job)) {
if (DEBUG) {
Slog.d(TAG, " queued " + job.toShortString());
}
if (newReadyJobs == null) {
newReadyJobs = new ArrayList<JobStatus>();
}
newReadyJobs.add(job);
} else if (areJobConstraintsNotSatisfiedLocked(job)) {
stopJobOnServiceContextLocked(job,
JobParameters.REASON_CONSTRAINTS_NOT_SATISFIED);
}
}
public void postProcess() {
if (newReadyJobs != null) {
noteJobsPending(newReadyJobs);
mPendingJobs.addAll(newReadyJobs);
}
newReadyJobs = null;
}
}
private final ReadyJobQueueFunctor mReadyQueueFunctor = new ReadyJobQueueFunctor();
/**
* The state of at least one job has changed. Here is where we could enforce various
* policies on when we want to execute jobs.
* Right now the policy is such:
* If >1 of the ready jobs is idle mode we send all of them off
* if more than 2 network connectivity jobs are ready we send them all off.
* If more than 4 jobs total are ready we send them all off.
* TODO: It would be nice to consolidate these sort of high-level policies somewhere.
*/
class MaybeReadyJobQueueFunctor implements JobStatusFunctor {
int chargingCount;
int idleCount;
int backoffCount;
int connectivityCount;
int contentCount;
List<JobStatus> runnableJobs;
public MaybeReadyJobQueueFunctor() {
reset();
}
// Functor method invoked for each job via JobStore.forEachJob()
@Override
public void process(JobStatus job) {
if (isReadyToBeExecutedLocked(job)) {
try {
if (ActivityManagerNative.getDefault().getAppStartMode(job.getUid(),
job.getJob().getService().getPackageName())
== ActivityManager.APP_START_MODE_DISABLED) {
Slog.w(TAG, "Aborting job " + job.getUid() + ":"
+ job.getJob().toString() + " -- package not allowed to start");
mHandler.obtainMessage(MSG_STOP_JOB, job).sendToTarget();
return;
}
} catch (RemoteException e) {
}
if (job.getNumFailures() > 0) {
backoffCount++;
}
if (job.hasIdleConstraint()) {
idleCount++;
}
if (job.hasConnectivityConstraint() || job.hasUnmeteredConstraint()
|| job.hasNotRoamingConstraint()) {
connectivityCount++;
}
if (job.hasChargingConstraint()) {
chargingCount++;
}
if (job.hasContentTriggerConstraint()) {
contentCount++;
}
if (runnableJobs == null) {
runnableJobs = new ArrayList<>();
}
runnableJobs.add(job);
} else if (areJobConstraintsNotSatisfiedLocked(job)) {
stopJobOnServiceContextLocked(job,
JobParameters.REASON_CONSTRAINTS_NOT_SATISFIED);
}
}
public void postProcess() {
if (backoffCount > 0 ||
idleCount >= mConstants.MIN_IDLE_COUNT ||
connectivityCount >= mConstants.MIN_CONNECTIVITY_COUNT ||
chargingCount >= mConstants.MIN_CHARGING_COUNT ||
contentCount >= mConstants.MIN_CONTENT_COUNT ||
(runnableJobs != null
&& runnableJobs.size() >= mConstants.MIN_READY_JOBS_COUNT)) {
if (DEBUG) {
Slog.d(TAG, "maybeQueueReadyJobsForExecutionLockedH: Running jobs.");
}
noteJobsPending(runnableJobs);
mPendingJobs.addAll(runnableJobs);
} else {
if (DEBUG) {
Slog.d(TAG, "maybeQueueReadyJobsForExecutionLockedH: Not running anything.");
}
}
// Be ready for next time
reset();
}
private void reset() {
chargingCount = 0;
idleCount = 0;
backoffCount = 0;
connectivityCount = 0;
contentCount = 0;
runnableJobs = null;
}
}
private final MaybeReadyJobQueueFunctor mMaybeQueueFunctor = new MaybeReadyJobQueueFunctor();
private void maybeQueueReadyJobsForExecutionLockedH() {
if (DEBUG) Slog.d(TAG, "Maybe queuing ready jobs...");
noteJobsNonpending(mPendingJobs);
mPendingJobs.clear();
mJobs.forEachJob(mMaybeQueueFunctor);
mMaybeQueueFunctor.postProcess();
}
/**
* Criteria for moving a job into the pending queue:
* - It's ready.
* - It's not pending.
* - It's not already running on a JSC.
* - The user that requested the job is running.
* - The component is enabled and runnable.
*/
private boolean isReadyToBeExecutedLocked(JobStatus job) {
final boolean jobReady = job.isReady();
final boolean jobPending = mPendingJobs.contains(job);
final boolean jobActive = isCurrentlyActiveLocked(job);
final int userId = job.getUserId();
final boolean userStarted = ArrayUtils.contains(mStartedUsers, userId);
final boolean componentPresent;
try {
componentPresent = (AppGlobals.getPackageManager().getServiceInfo(
job.getServiceComponent(), PackageManager.MATCH_DEBUG_TRIAGED_MISSING,
userId) != null);
} catch (RemoteException e) {
throw e.rethrowAsRuntimeException();
}
if (DEBUG) {
Slog.v(TAG, "isReadyToBeExecutedLocked: " + job.toShortString()
+ " ready=" + jobReady + " pending=" + jobPending
+ " active=" + jobActive + " userStarted=" + userStarted
+ " componentPresent=" + componentPresent);
}
return userStarted && componentPresent && jobReady && !jobPending && !jobActive;
}
/**
* Criteria for cancelling an active job:
* - It's not ready
* - It's running on a JSC.
*/
private boolean areJobConstraintsNotSatisfiedLocked(JobStatus job) {
return !job.isReady() && isCurrentlyActiveLocked(job);
}
/**
* Reconcile jobs in the pending queue against available execution contexts.
* A controller can force a job into the pending queue even if it's already running, but
* here is where we decide whether to actually execute it.
*/
private void maybeRunPendingJobsH() {
synchronized (mLock) {
if (DEBUG) {
Slog.d(TAG, "pending queue: " + mPendingJobs.size() + " jobs.");
}
assignJobsToContextsLocked();
reportActive();
}
}
}
private int adjustJobPriority(int curPriority, JobStatus job) {
if (curPriority < JobInfo.PRIORITY_TOP_APP) {
float factor = mJobPackageTracker.getLoadFactor(job);
if (factor >= mConstants.HEAVY_USE_FACTOR) {
curPriority += JobInfo.PRIORITY_ADJ_ALWAYS_RUNNING;
} else if (factor >= mConstants.MODERATE_USE_FACTOR) {
curPriority += JobInfo.PRIORITY_ADJ_OFTEN_RUNNING;
}
}
return curPriority;
}
private int evaluateJobPriorityLocked(JobStatus job) {
int priority = job.getPriority();
if (priority >= JobInfo.PRIORITY_FOREGROUND_APP) {
return adjustJobPriority(priority, job);
}
int override = mUidPriorityOverride.get(job.getSourceUid(), 0);
if (override != 0) {
return adjustJobPriority(override, job);
}
return adjustJobPriority(priority, job);
}
/**
* Takes jobs from pending queue and runs them on available contexts.
* If no contexts are available, preempts lower priority jobs to
* run higher priority ones.
* Lock on mJobs before calling this function.
*/
private void assignJobsToContextsLocked() {
if (DEBUG) {
Slog.d(TAG, printPendingQueue());
}
int memLevel;
try {
memLevel = ActivityManagerNative.getDefault().getMemoryTrimLevel();
} catch (RemoteException e) {
memLevel = ProcessStats.ADJ_MEM_FACTOR_NORMAL;
}
switch (memLevel) {
case ProcessStats.ADJ_MEM_FACTOR_MODERATE:
mMaxActiveJobs = mConstants.BG_MODERATE_JOB_COUNT;
break;
case ProcessStats.ADJ_MEM_FACTOR_LOW:
mMaxActiveJobs = mConstants.BG_LOW_JOB_COUNT;
break;
case ProcessStats.ADJ_MEM_FACTOR_CRITICAL:
mMaxActiveJobs = mConstants.BG_CRITICAL_JOB_COUNT;
break;
default:
mMaxActiveJobs = mConstants.BG_NORMAL_JOB_COUNT;
break;
}
JobStatus[] contextIdToJobMap = mTmpAssignContextIdToJobMap;
boolean[] act = mTmpAssignAct;
int[] preferredUidForContext = mTmpAssignPreferredUidForContext;
int numActive = 0;
int numForeground = 0;
for (int i=0; i<MAX_JOB_CONTEXTS_COUNT; i++) {
final JobServiceContext js = mActiveServices.get(i);
final JobStatus status = js.getRunningJob();
if ((contextIdToJobMap[i] = status) != null) {
numActive++;
if (status.lastEvaluatedPriority >= JobInfo.PRIORITY_TOP_APP) {
numForeground++;
}
}
act[i] = false;
preferredUidForContext[i] = js.getPreferredUid();
}
if (DEBUG) {
Slog.d(TAG, printContextIdToJobMap(contextIdToJobMap, "running jobs initial"));
}
for (int i=0; i<mPendingJobs.size(); i++) {
JobStatus nextPending = mPendingJobs.get(i);
// If job is already running, go to next job.
int jobRunningContext = findJobContextIdFromMap(nextPending, contextIdToJobMap);
if (jobRunningContext != -1) {
continue;
}
final int priority = evaluateJobPriorityLocked(nextPending);
nextPending.lastEvaluatedPriority = priority;
// Find a context for nextPending. The context should be available OR
// it should have lowest priority among all running jobs
// (sharing the same Uid as nextPending)
int minPriority = Integer.MAX_VALUE;
int minPriorityContextId = -1;
for (int j=0; j<MAX_JOB_CONTEXTS_COUNT; j++) {
JobStatus job = contextIdToJobMap[j];
int preferredUid = preferredUidForContext[j];
if (job == null) {
if ((numActive < mMaxActiveJobs ||
(priority >= JobInfo.PRIORITY_TOP_APP &&
numForeground < mConstants.FG_JOB_COUNT)) &&
(preferredUid == nextPending.getUid() ||
preferredUid == JobServiceContext.NO_PREFERRED_UID)) {
// This slot is free, and we haven't yet hit the limit on
// concurrent jobs... we can just throw the job in to here.
minPriorityContextId = j;
break;
}
// No job on this context, but nextPending can't run here because
// the context has a preferred Uid or we have reached the limit on
// concurrent jobs.
continue;
}
if (job.getUid() != nextPending.getUid()) {
continue;
}
if (evaluateJobPriorityLocked(job) >= nextPending.lastEvaluatedPriority) {
continue;
}
if (minPriority > nextPending.lastEvaluatedPriority) {
minPriority = nextPending.lastEvaluatedPriority;
minPriorityContextId = j;
}
}
if (minPriorityContextId != -1) {
contextIdToJobMap[minPriorityContextId] = nextPending;
act[minPriorityContextId] = true;
numActive++;
if (priority >= JobInfo.PRIORITY_TOP_APP) {
numForeground++;
}
}
}
if (DEBUG) {
Slog.d(TAG, printContextIdToJobMap(contextIdToJobMap, "running jobs final"));
}
mJobPackageTracker.noteConcurrency(numActive, numForeground);
for (int i=0; i<MAX_JOB_CONTEXTS_COUNT; i++) {
boolean preservePreferredUid = false;
if (act[i]) {
JobStatus js = mActiveServices.get(i).getRunningJob();
if (js != null) {
if (DEBUG) {
Slog.d(TAG, "preempting job: " + mActiveServices.get(i).getRunningJob());
}
// preferredUid will be set to uid of currently running job.
mActiveServices.get(i).preemptExecutingJob();
preservePreferredUid = true;
} else {
final JobStatus pendingJob = contextIdToJobMap[i];
if (DEBUG) {
Slog.d(TAG, "About to run job on context "
+ String.valueOf(i) + ", job: " + pendingJob);
}
for (int ic=0; ic<mControllers.size(); ic++) {
mControllers.get(ic).prepareForExecutionLocked(pendingJob);
}
if (!mActiveServices.get(i).executeRunnableJob(pendingJob)) {
Slog.d(TAG, "Error executing " + pendingJob);
}
if (mPendingJobs.remove(pendingJob)) {
mJobPackageTracker.noteNonpending(pendingJob);
}
}
}
if (!preservePreferredUid) {
mActiveServices.get(i).clearPreferredUid();
}
}
}
int findJobContextIdFromMap(JobStatus jobStatus, JobStatus[] map) {
for (int i=0; i<map.length; i++) {
if (map[i] != null && map[i].matches(jobStatus.getUid(), jobStatus.getJobId())) {
return i;
}
}
return -1;
}
final class LocalService implements JobSchedulerInternal {
/**
* Returns a list of all pending jobs. A running job is not considered pending. Periodic
* jobs are always considered pending.
*/
@Override
public List<JobInfo> getSystemScheduledPendingJobs() {
synchronized (mLock) {
final List<JobInfo> pendingJobs = new ArrayList<JobInfo>();
mJobs.forEachJob(Process.SYSTEM_UID, new JobStatusFunctor() {
@Override
public void process(JobStatus job) {
if (job.getJob().isPeriodic() || !isCurrentlyActiveLocked(job)) {
pendingJobs.add(job.getJob());
}
}
});
return pendingJobs;
}
}
}
/**
* Binder stub trampoline implementation
*/
final class JobSchedulerStub extends IJobScheduler.Stub {
/** Cache determination of whether a given app can persist jobs
* key is uid of the calling app; value is undetermined/true/false
*/
private final SparseArray<Boolean> mPersistCache = new SparseArray<Boolean>();
// Enforce that only the app itself (or shared uid participant) can schedule a
// job that runs one of the app's services, as well as verifying that the
// named service properly requires the BIND_JOB_SERVICE permission
private void enforceValidJobRequest(int uid, JobInfo job) {
final IPackageManager pm = AppGlobals.getPackageManager();
final ComponentName service = job.getService();
try {
ServiceInfo si = pm.getServiceInfo(service,
PackageManager.MATCH_DIRECT_BOOT_AWARE
| PackageManager.MATCH_DIRECT_BOOT_UNAWARE,
UserHandle.getUserId(uid));
if (si == null) {
throw new IllegalArgumentException("No such service " + service);
}
if (si.applicationInfo.uid != uid) {
throw new IllegalArgumentException("uid " + uid +
" cannot schedule job in " + service.getPackageName());
}
if (!JobService.PERMISSION_BIND.equals(si.permission)) {
throw new IllegalArgumentException("Scheduled service " + service
+ " does not require android.permission.BIND_JOB_SERVICE permission");
}
} catch (RemoteException e) {
// Can't happen; the Package Manager is in this same process
}
}
private boolean canPersistJobs(int pid, int uid) {
// If we get this far we're good to go; all we need to do now is check
// whether the app is allowed to persist its scheduled work.
final boolean canPersist;
synchronized (mPersistCache) {
Boolean cached = mPersistCache.get(uid);
if (cached != null) {
canPersist = cached.booleanValue();
} else {
// Persisting jobs is tantamount to running at boot, so we permit
// it when the app has declared that it uses the RECEIVE_BOOT_COMPLETED
// permission
int result = getContext().checkPermission(
android.Manifest.permission.RECEIVE_BOOT_COMPLETED, pid, uid);
canPersist = (result == PackageManager.PERMISSION_GRANTED);
mPersistCache.put(uid, canPersist);
}
}
return canPersist;
}
// IJobScheduler implementation
@Override
public int schedule(JobInfo job) throws RemoteException {
if (DEBUG) {
Slog.d(TAG, "Scheduling job: " + job.toString());
}
final int pid = Binder.getCallingPid();
final int uid = Binder.getCallingUid();
enforceValidJobRequest(uid, job);
if (job.isPersisted()) {
if (!canPersistJobs(pid, uid)) {
throw new IllegalArgumentException("Error: requested job be persisted without"
+ " holding RECEIVE_BOOT_COMPLETED permission.");
}
}
if ((job.getFlags() & JobInfo.FLAG_WILL_BE_FOREGROUND) != 0) {
getContext().enforceCallingOrSelfPermission(
android.Manifest.permission.CONNECTIVITY_INTERNAL, TAG);
}
long ident = Binder.clearCallingIdentity();
try {
return JobSchedulerService.this.schedule(job, uid);
} finally {
Binder.restoreCallingIdentity(ident);
}
}
@Override
public int scheduleAsPackage(JobInfo job, String packageName, int userId, String tag)
throws RemoteException {
final int callerUid = Binder.getCallingUid();
if (DEBUG) {
Slog.d(TAG, "Caller uid " + callerUid + " scheduling job: " + job.toString()
+ " on behalf of " + packageName);
}
if (packageName == null) {
throw new NullPointerException("Must specify a package for scheduleAsPackage()");
}
int mayScheduleForOthers = getContext().checkCallingOrSelfPermission(
android.Manifest.permission.UPDATE_DEVICE_STATS);
if (mayScheduleForOthers != PackageManager.PERMISSION_GRANTED) {
throw new SecurityException("Caller uid " + callerUid
+ " not permitted to schedule jobs for other apps");
}
if ((job.getFlags() & JobInfo.FLAG_WILL_BE_FOREGROUND) != 0) {
getContext().enforceCallingOrSelfPermission(
android.Manifest.permission.CONNECTIVITY_INTERNAL, TAG);
}
long ident = Binder.clearCallingIdentity();
try {
return JobSchedulerService.this.scheduleAsPackage(job, callerUid,
packageName, userId, tag);
} finally {
Binder.restoreCallingIdentity(ident);
}
}
@Override
public List<JobInfo> getAllPendingJobs() throws RemoteException {
final int uid = Binder.getCallingUid();
long ident = Binder.clearCallingIdentity();
try {
return JobSchedulerService.this.getPendingJobs(uid);
} finally {
Binder.restoreCallingIdentity(ident);
}
}
@Override
public JobInfo getPendingJob(int jobId) throws RemoteException {
final int uid = Binder.getCallingUid();
long ident = Binder.clearCallingIdentity();
try {
return JobSchedulerService.this.getPendingJob(uid, jobId);
} finally {
Binder.restoreCallingIdentity(ident);
}
}
@Override
public void cancelAll() throws RemoteException {
final int uid = Binder.getCallingUid();
long ident = Binder.clearCallingIdentity();
try {
JobSchedulerService.this.cancelJobsForUid(uid, true);
} finally {
Binder.restoreCallingIdentity(ident);
}
}
@Override
public void cancel(int jobId) throws RemoteException {
final int uid = Binder.getCallingUid();
long ident = Binder.clearCallingIdentity();
try {
JobSchedulerService.this.cancelJob(uid, jobId);
} finally {
Binder.restoreCallingIdentity(ident);
}
}
/**
* "dumpsys" infrastructure
*/
@Override
public void dump(FileDescriptor fd, PrintWriter pw, String[] args) {
getContext().enforceCallingOrSelfPermission(android.Manifest.permission.DUMP, TAG);
long identityToken = Binder.clearCallingIdentity();
try {
JobSchedulerService.this.dumpInternal(pw, args);
} finally {
Binder.restoreCallingIdentity(identityToken);
}
}
@Override
public void onShellCommand(FileDescriptor in, FileDescriptor out, FileDescriptor err,
String[] args, ResultReceiver resultReceiver) throws RemoteException {
(new JobSchedulerShellCommand(JobSchedulerService.this)).exec(
this, in, out, err, args, resultReceiver);
}
};
// Shell command infrastructure: run the given job immediately
int executeRunCommand(String pkgName, int userId, int jobId, boolean force) {
if (DEBUG) {
Slog.v(TAG, "executeRunCommand(): " + pkgName + "/" + userId
+ " " + jobId + " f=" + force);
}
try {
final int uid = AppGlobals.getPackageManager().getPackageUid(pkgName, 0, userId);
if (uid < 0) {
return JobSchedulerShellCommand.CMD_ERR_NO_PACKAGE;
}
synchronized (mLock) {
final JobStatus js = mJobs.getJobByUidAndJobId(uid, jobId);
if (js == null) {
return JobSchedulerShellCommand.CMD_ERR_NO_JOB;
}
js.overrideState = (force) ? JobStatus.OVERRIDE_FULL : JobStatus.OVERRIDE_SOFT;
if (!js.isConstraintsSatisfied()) {
js.overrideState = 0;
return JobSchedulerShellCommand.CMD_ERR_CONSTRAINTS;
}
mHandler.obtainMessage(MSG_CHECK_JOB_GREEDY).sendToTarget();
}
} catch (RemoteException e) {
// can't happen
}
return 0;
}
private String printContextIdToJobMap(JobStatus[] map, String initial) {
StringBuilder s = new StringBuilder(initial + ": ");
for (int i=0; i<map.length; i++) {
s.append("(")
.append(map[i] == null? -1: map[i].getJobId())
.append(map[i] == null? -1: map[i].getUid())
.append(")" );
}
return s.toString();
}
private String printPendingQueue() {
StringBuilder s = new StringBuilder("Pending queue: ");
Iterator<JobStatus> it = mPendingJobs.iterator();
while (it.hasNext()) {
JobStatus js = it.next();
s.append("(")
.append(js.getJob().getId())
.append(", ")
.append(js.getUid())
.append(") ");
}
return s.toString();
}
static void dumpHelp(PrintWriter pw) {
pw.println("Job Scheduler (jobscheduler) dump options:");
pw.println(" [-h] [package] ...");
pw.println(" -h: print this help");
pw.println(" [package] is an optional package name to limit the output to.");
}
void dumpInternal(final PrintWriter pw, String[] args) {
int filterUid = -1;
if (!ArrayUtils.isEmpty(args)) {
int opti = 0;
while (opti < args.length) {
String arg = args[opti];
if ("-h".equals(arg)) {
dumpHelp(pw);
return;
} else if ("-a".equals(arg)) {
// Ignore, we always dump all.
} else if (arg.length() > 0 && arg.charAt(0) == '-') {
pw.println("Unknown option: " + arg);
return;
} else {
break;
}
opti++;
}
if (opti < args.length) {
String pkg = args[opti];
try {
filterUid = getContext().getPackageManager().getPackageUid(pkg,
PackageManager.MATCH_UNINSTALLED_PACKAGES);
} catch (NameNotFoundException ignored) {
pw.println("Invalid package: " + pkg);
return;
}
}
}
final int filterUidFinal = UserHandle.getAppId(filterUid);
final long now = SystemClock.elapsedRealtime();
synchronized (mLock) {
mConstants.dump(pw);
pw.println();
pw.println("Started users: " + Arrays.toString(mStartedUsers));
pw.print("Registered ");
pw.print(mJobs.size());
pw.println(" jobs:");
if (mJobs.size() > 0) {
final List<JobStatus> jobs = mJobs.mJobSet.getAllJobs();
Collections.sort(jobs, new Comparator<JobStatus>() {
@Override
public int compare(JobStatus o1, JobStatus o2) {
int uid1 = o1.getUid();
int uid2 = o2.getUid();
int id1 = o1.getJobId();
int id2 = o2.getJobId();
if (uid1 != uid2) {
return uid1 < uid2 ? -1 : 1;
}
return id1 < id2 ? -1 : (id1 > id2 ? 1 : 0);
}
});
for (JobStatus job : jobs) {
pw.print(" JOB #"); job.printUniqueId(pw); pw.print(": ");
pw.println(job.toShortStringExceptUniqueId());
// Skip printing details if the caller requested a filter
if (!job.shouldDump(filterUidFinal)) {
continue;
}
job.dump(pw, " ", true);
pw.print(" Ready: ");
pw.print(mHandler.isReadyToBeExecutedLocked(job));
pw.print(" (job=");
pw.print(job.isReady());
pw.print(" pending=");
pw.print(mPendingJobs.contains(job));
pw.print(" active=");
pw.print(isCurrentlyActiveLocked(job));
pw.print(" user=");
pw.print(ArrayUtils.contains(mStartedUsers, job.getUserId()));
pw.println(")");
}
} else {
pw.println(" None.");
}
for (int i=0; i<mControllers.size(); i++) {
pw.println();
mControllers.get(i).dumpControllerStateLocked(pw, filterUidFinal);
}
pw.println();
pw.println("Uid priority overrides:");
for (int i=0; i< mUidPriorityOverride.size(); i++) {
int uid = mUidPriorityOverride.keyAt(i);
if (filterUidFinal == -1 || filterUidFinal == UserHandle.getAppId(uid)) {
pw.print(" "); pw.print(UserHandle.formatUid(uid));
pw.print(": "); pw.println(mUidPriorityOverride.valueAt(i));
}
}
pw.println();
mJobPackageTracker.dump(pw, "", filterUidFinal);
pw.println();
if (mJobPackageTracker.dumpHistory(pw, "", filterUidFinal)) {
pw.println();
}
pw.println("Pending queue:");
for (int i=0; i<mPendingJobs.size(); i++) {
JobStatus job = mPendingJobs.get(i);
pw.print(" Pending #"); pw.print(i); pw.print(": ");
pw.println(job.toShortString());
job.dump(pw, " ", false);
int priority = evaluateJobPriorityLocked(job);
if (priority != JobInfo.PRIORITY_DEFAULT) {
pw.print(" Evaluated priority: "); pw.println(priority);
}
pw.print(" Tag: "); pw.println(job.getTag());
}
pw.println();
pw.println("Active jobs:");
for (int i=0; i<mActiveServices.size(); i++) {
JobServiceContext jsc = mActiveServices.get(i);
pw.print(" Slot #"); pw.print(i); pw.print(": ");
if (jsc.getRunningJob() == null) {
pw.println("inactive");
continue;
} else {
pw.println(jsc.getRunningJob().toShortString());
pw.print(" Running for: ");
TimeUtils.formatDuration(now - jsc.getExecutionStartTimeElapsed(), pw);
pw.print(", timeout at: ");
TimeUtils.formatDuration(jsc.getTimeoutElapsed() - now, pw);
pw.println();
jsc.getRunningJob().dump(pw, " ", false);
int priority = evaluateJobPriorityLocked(jsc.getRunningJob());
if (priority != JobInfo.PRIORITY_DEFAULT) {
pw.print(" Evaluated priority: "); pw.println(priority);
}
}
}
if (filterUid == -1) {
pw.println();
pw.print("mReadyToRock="); pw.println(mReadyToRock);
pw.print("mReportedActive="); pw.println(mReportedActive);
pw.print("mMaxActiveJobs="); pw.println(mMaxActiveJobs);
}
}
pw.println();
}
}