/* * Copyright (C) 2010 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 android.animation.ValueAnimator; import android.app.ActivityManagerNative; import android.app.ActivityThread; import android.app.ApplicationErrorReport; import android.content.Intent; import android.util.Log; import android.util.Printer; import com.android.internal.os.RuntimeInit; import dalvik.system.BlockGuard; import dalvik.system.CloseGuard; import java.io.PrintWriter; import java.io.StringWriter; import java.util.ArrayList; import java.util.HashMap; /** *

StrictMode is a developer tool which detects things you might be * doing by accident and brings them to your attention so you can fix * them. * *

StrictMode is most commonly used to catch accidental disk or * network access on the application's main thread, where UI * operations are received and animations take place. Keeping disk * and network operations off the main thread makes for much smoother, * more responsive applications. By keeping your application's main thread * responsive, you also prevent * ANR dialogs * from being shown to users. * *

Note that even though an Android device's disk is * often on flash memory, many devices run a filesystem on top of that * memory with very limited concurrency. It's often the case that * almost all disk accesses are fast, but may in individual cases be * dramatically slower when certain I/O is happening in the background * from other processes. If possible, it's best to assume that such * things are not fast.

* *

Example code to enable from early in your * {@link android.app.Application}, {@link android.app.Activity}, or * other application component's * {@link android.app.Application#onCreate} method: * *

 * public void onCreate() {
 *     if (DEVELOPER_MODE) {
 *         StrictMode.setThreadPolicy(new {@link ThreadPolicy.Builder StrictMode.ThreadPolicy.Builder}()
 *                 .detectDiskReads()
 *                 .detectDiskWrites()
 *                 .detectNetwork()   // or .detectAll() for all detectable problems
 *                 .penaltyLog()
 *                 .build());
 *         StrictMode.setVmPolicy(new {@link VmPolicy.Builder StrictMode.VmPolicy.Builder}()
 *                 .detectLeakedSqlLiteObjects()
 *                 .detectLeakedClosableObjects()
 *                 .penaltyLog()
 *                 .penaltyDeath()
 *                 .build());
 *     }
 *     super.onCreate();
 * }
 *

* *

You can decide what should happen when a violation is detected. * For example, using {@link ThreadPolicy.Builder#penaltyLog} you can * watch the output of adb logcat while you use your * application to see the violations as they happen. * *

If you find violations that you feel are problematic, there are * a variety of tools to help solve them: threads, {@link android.os.Handler}, * {@link android.os.AsyncTask}, {@link android.app.IntentService}, etc. * But don't feel compelled to fix everything that StrictMode finds. In particular, * many cases of disk access are often necessary during the normal activity lifecycle. Use * StrictMode to find things you did by accident. Network requests on the UI thread * are almost always a problem, though. * *

StrictMode is not a security mechanism and is not * guaranteed to find all disk or network accesses. While it does * propagate its state across process boundaries when doing * {@link android.os.Binder} calls, it's still ultimately a best * effort mechanism. Notably, disk or network access from JNI calls * won't necessarily trigger it. Future versions of Android may catch * more (or fewer) operations, so you should never leave StrictMode * enabled in shipping applications on the Android Market. */ public final class StrictMode { private static final String TAG = "StrictMode"; private static final boolean LOG_V = false; // Only log a duplicate stack trace to the logs every second. private static final long MIN_LOG_INTERVAL_MS = 1000; // Only show an annoying dialog at most every 30 seconds private static final long MIN_DIALOG_INTERVAL_MS = 30000; // How many offending stacks to keep track of (and time) per loop // of the Looper. private static final int MAX_OFFENSES_PER_LOOP = 10; // Thread-policy: /** * @hide */ public static final int DETECT_DISK_WRITE = 0x01; // for ThreadPolicy /** * @hide */ public static final int DETECT_DISK_READ = 0x02; // for ThreadPolicy /** * @hide */ public static final int DETECT_NETWORK = 0x04; // for ThreadPolicy // Process-policy: /** * Note, a "VM_" bit, not thread. * @hide */ public static final int DETECT_VM_CURSOR_LEAKS = 0x200; // for ProcessPolicy /** * Note, a "VM_" bit, not thread. * @hide */ public static final int DETECT_VM_CLOSABLE_LEAKS = 0x400; // for ProcessPolicy /** * @hide */ public static final int PENALTY_LOG = 0x10; // normal android.util.Log // Used for both process and thread policy: /** * @hide */ public static final int PENALTY_DIALOG = 0x20; /** * Death on any detected violation. * * @hide */ public static final int PENALTY_DEATH = 0x40; /** * Death just for detected network usage. * * @hide */ public static final int PENALTY_DEATH_ON_NETWORK = 0x200; /** * @hide */ public static final int PENALTY_DROPBOX = 0x80; /** * Non-public penalty mode which overrides all the other penalty * bits and signals that we're in a Binder call and we should * ignore the other penalty bits and instead serialize back all * our offending stack traces to the caller to ultimately handle * in the originating process. * * This must be kept in sync with the constant in libs/binder/Parcel.cpp * * @hide */ public static final int PENALTY_GATHER = 0x100; /** * Mask of all the penalty bits. */ private static final int PENALTY_MASK = PENALTY_LOG | PENALTY_DIALOG | PENALTY_DEATH | PENALTY_DROPBOX | PENALTY_GATHER | PENALTY_DEATH_ON_NETWORK; /** * The current VmPolicy in effect. */ private static volatile int sVmPolicyMask = 0; private StrictMode() {} /** * {@link StrictMode} policy applied to a certain thread. * *

The policy is enabled by {@link #setThreadPolicy}. The current policy * can be retrieved with {@link #getThreadPolicy}. * *

Note that multiple penalties may be provided and they're run * in order from least to most severe (logging before process * death, for example). There's currently no mechanism to choose * different penalties for different detected actions. */ public static final class ThreadPolicy { /** * The default, lax policy which doesn't catch anything. */ public static final ThreadPolicy LAX = new ThreadPolicy(0); final int mask; private ThreadPolicy(int mask) { this.mask = mask; } @Override public String toString() { return "[StrictMode.ThreadPolicy; mask=" + mask + "]"; } /** * Creates ThreadPolicy instances. Methods whose names start * with {@code detect} specify what problems we should look * for. Methods whose names start with {@code penalty} specify what * we should do when we detect a problem. * *

You can call as many {@code detect} and {@code penalty} * methods as you like. Currently order is insignificant: all * penalties apply to all detected problems. * *

For example, detect everything and log anything that's found: *

         * StrictMode.VmPolicy policy = new StrictMode.VmPolicy.Builder()
         *     .detectAll()
         *     .penaltyLog()
         *     .build();
         * StrictMode.setVmPolicy(policy);
         *

*/ public static final class Builder { private int mMask = 0; /** * Create a Builder that detects nothing and has no * violations. (but note that {@link #build} will default * to enabling {@link #penaltyLog} if no other penalties * are specified) */ public Builder() { mMask = 0; } /** * Initialize a Builder from an existing ThreadPolicy. */ public Builder(ThreadPolicy policy) { mMask = policy.mask; } /** * Detect everything that's potentially suspect. * *

As of the Gingerbread release this includes network and * disk operations but will likely expand in future releases. */ public Builder detectAll() { return enable(DETECT_DISK_WRITE | DETECT_DISK_READ | DETECT_NETWORK); } /** * Disable the detection of everything. */ public Builder permitAll() { return disable(DETECT_DISK_WRITE | DETECT_DISK_READ | DETECT_NETWORK); } /** * Enable detection of network operations. */ public Builder detectNetwork() { return enable(DETECT_NETWORK); } /** * Disable detection of network operations. */ public Builder permitNetwork() { return disable(DETECT_NETWORK); } /** * Enable detection of disk reads. */ public Builder detectDiskReads() { return enable(DETECT_DISK_READ); } /** * Disable detection of disk reads. */ public Builder permitDiskReads() { return disable(DETECT_DISK_READ); } /** * Enable detection of disk writes. */ public Builder detectDiskWrites() { return enable(DETECT_DISK_WRITE); } /** * Disable detection of disk writes. */ public Builder permitDiskWrites() { return disable(DETECT_DISK_WRITE); } /** * Show an annoying dialog to the developer on detected * violations, rate-limited to be only a little annoying. */ public Builder penaltyDialog() { return enable(PENALTY_DIALOG); } /** * Crash the whole process on violation. This penalty runs at * the end of all enabled penalties so you'll still get * see logging or other violations before the process dies. * *

Unlike {@link #penaltyDeathOnNetwork}, this applies * to disk reads, disk writes, and network usage if their * corresponding detect flags are set. */ public Builder penaltyDeath() { return enable(PENALTY_DEATH); } /** * Crash the whole process on any network usage. Unlike * {@link #penaltyDeath}, this penalty runs * before anything else. You must still have * called {@link #detectNetwork} to enable this. * *

In the Honeycomb or later SDKs, this is on by default. */ public Builder penaltyDeathOnNetwork() { return enable(PENALTY_DEATH_ON_NETWORK); } /** * Log detected violations to the system log. */ public Builder penaltyLog() { return enable(PENALTY_LOG); } /** * Enable detected violations log a stacktrace and timing data * to the {@link android.os.DropBoxManager DropBox} on policy * violation. Intended mostly for platform integrators doing * beta user field data collection. */ public Builder penaltyDropBox() { return enable(PENALTY_DROPBOX); } private Builder enable(int bit) { mMask |= bit; return this; } private Builder disable(int bit) { mMask &= ~bit; return this; } /** * Construct the ThreadPolicy instance. * *

Note: if no penalties are enabled before calling * build, {@link #penaltyLog} is implicitly * set. */ public ThreadPolicy build() { // If there are detection bits set but no violation bits // set, enable simple logging. if (mMask != 0 && (mMask & (PENALTY_DEATH | PENALTY_LOG | PENALTY_DROPBOX | PENALTY_DIALOG)) == 0) { penaltyLog(); } return new ThreadPolicy(mMask); } } } /** * {@link StrictMode} policy applied to all threads in the virtual machine's process. * *

The policy is enabled by {@link #setVmPolicy}. */ public static final class VmPolicy { /** * The default, lax policy which doesn't catch anything. */ public static final VmPolicy LAX = new VmPolicy(0); final int mask; private VmPolicy(int mask) { this.mask = mask; } @Override public String toString() { return "[StrictMode.VmPolicy; mask=" + mask + "]"; } /** * Creates {@link VmPolicy} instances. Methods whose names start * with {@code detect} specify what problems we should look * for. Methods whose names start with {@code penalty} specify what * we should do when we detect a problem. * *

You can call as many {@code detect} and {@code penalty} * methods as you like. Currently order is insignificant: all * penalties apply to all detected problems. * *

For example, detect everything and log anything that's found: *

         * StrictMode.VmPolicy policy = new StrictMode.VmPolicy.Builder()
         *     .detectAll()
         *     .penaltyLog()
         *     .build();
         * StrictMode.setVmPolicy(policy);
         *

*/ public static final class Builder { private int mMask; /** * Detect everything that's potentially suspect. * *

In the Honeycomb release this includes leaks of * SQLite cursors and other closable objects but will * likely expand in future releases. */ public Builder detectAll() { return enable(DETECT_VM_CURSOR_LEAKS | DETECT_VM_CLOSABLE_LEAKS); } /** * Detect when an * {@link android.database.sqlite.SQLiteCursor} or other * SQLite object is finalized without having been closed. * *

You always want to explicitly close your SQLite * cursors to avoid unnecessary database contention and * temporary memory leaks. */ public Builder detectLeakedSqlLiteObjects() { return enable(DETECT_VM_CURSOR_LEAKS); } /** * Detect when an {@link java.io.Closeable} or other * object with a explict termination method is finalized * without having been closed. * *

You always want to explicitly close such objects to * avoid unnecessary resources leaks. */ public Builder detectLeakedClosableObjects() { return enable(DETECT_VM_CLOSABLE_LEAKS); } /** * Crashes the whole process on violation. This penalty runs at * the end of all enabled penalties so yo you'll still get * your logging or other violations before the process dies. */ public Builder penaltyDeath() { return enable(PENALTY_DEATH); } /** * Log detected violations to the system log. */ public Builder penaltyLog() { return enable(PENALTY_LOG); } /** * Enable detected violations log a stacktrace and timing data * to the {@link android.os.DropBoxManager DropBox} on policy * violation. Intended mostly for platform integrators doing * beta user field data collection. */ public Builder penaltyDropBox() { return enable(PENALTY_DROPBOX); } private Builder enable(int bit) { mMask |= bit; return this; } /** * Construct the VmPolicy instance. * *

Note: if no penalties are enabled before calling * build, {@link #penaltyLog} is implicitly * set. */ public VmPolicy build() { // If there are detection bits set but no violation bits // set, enable simple logging. if (mMask != 0 && (mMask & (PENALTY_DEATH | PENALTY_LOG | PENALTY_DROPBOX | PENALTY_DIALOG)) == 0) { penaltyLog(); } return new VmPolicy(mMask); } } } /** * Log of strict mode violation stack traces that have occurred * during a Binder call, to be serialized back later to the caller * via Parcel.writeNoException() (amusingly) where the caller can * choose how to react. */ private static final ThreadLocal> gatheredViolations = new ThreadLocal>() { @Override protected ArrayList initialValue() { // Starts null to avoid unnecessary allocations when // checking whether there are any violations or not in // hasGatheredViolations() below. return null; } }; /** * Sets the policy for what actions on the current thread should * be detected, as well as the penalty if such actions occur. * *

Internally this sets a thread-local variable which is * propagated across cross-process IPC calls, meaning you can * catch violations when a system service or another process * accesses the disk or network on your behalf. * * @param policy the policy to put into place */ public static void setThreadPolicy(final ThreadPolicy policy) { setThreadPolicyMask(policy.mask); } private static void setThreadPolicyMask(final int policyMask) { // In addition to the Java-level thread-local in Dalvik's // BlockGuard, we also need to keep a native thread-local in // Binder in order to propagate the value across Binder calls, // even across native-only processes. The two are kept in // sync via the callback to onStrictModePolicyChange, below. setBlockGuardPolicy(policyMask); // And set the Android native version... Binder.setThreadStrictModePolicy(policyMask); } // Sets the policy in Dalvik/libcore (BlockGuard) private static void setBlockGuardPolicy(final int policyMask) { if (policyMask == 0) { BlockGuard.setThreadPolicy(BlockGuard.LAX_POLICY); return; } BlockGuard.Policy policy = BlockGuard.getThreadPolicy(); if (!(policy instanceof AndroidBlockGuardPolicy)) { BlockGuard.setThreadPolicy(new AndroidBlockGuardPolicy(policyMask)); } else { AndroidBlockGuardPolicy androidPolicy = (AndroidBlockGuardPolicy) policy; androidPolicy.setPolicyMask(policyMask); } } private static class StrictModeNetworkViolation extends BlockGuard.BlockGuardPolicyException { public StrictModeNetworkViolation(int policyMask) { super(policyMask, DETECT_NETWORK); } } private static class StrictModeDiskReadViolation extends BlockGuard.BlockGuardPolicyException { public StrictModeDiskReadViolation(int policyMask) { super(policyMask, DETECT_DISK_READ); } } private static class StrictModeDiskWriteViolation extends BlockGuard.BlockGuardPolicyException { public StrictModeDiskWriteViolation(int policyMask) { super(policyMask, DETECT_DISK_WRITE); } } /** * Returns the bitmask of the current thread's policy. * * @return the bitmask of all the DETECT_* and PENALTY_* bits currently enabled * * @hide */ public static int getThreadPolicyMask() { return BlockGuard.getThreadPolicy().getPolicyMask(); } /** * Returns the current thread's policy. */ public static ThreadPolicy getThreadPolicy() { return new ThreadPolicy(getThreadPolicyMask()); } /** * A convenience wrapper that takes the current * {@link ThreadPolicy} from {@link #getThreadPolicy}, modifies it * to permit both disk reads & writes, and sets the new policy * with {@link #setThreadPolicy}, returning the old policy so you * can restore it at the end of a block. * * @return the old policy, to be passed to {@link #setThreadPolicy} to * restore the policy at the end of a block */ public static ThreadPolicy allowThreadDiskWrites() { int oldPolicyMask = getThreadPolicyMask(); int newPolicyMask = oldPolicyMask & ~(DETECT_DISK_WRITE | DETECT_DISK_READ); if (newPolicyMask != oldPolicyMask) { setThreadPolicyMask(newPolicyMask); } return new ThreadPolicy(oldPolicyMask); } /** * A convenience wrapper that takes the current * {@link ThreadPolicy} from {@link #getThreadPolicy}, modifies it * to permit disk reads, and sets the new policy * with {@link #setThreadPolicy}, returning the old policy so you * can restore it at the end of a block. * * @return the old policy, to be passed to setThreadPolicy to * restore the policy. */ public static ThreadPolicy allowThreadDiskReads() { int oldPolicyMask = getThreadPolicyMask(); int newPolicyMask = oldPolicyMask & ~(DETECT_DISK_READ); if (newPolicyMask != oldPolicyMask) { setThreadPolicyMask(newPolicyMask); } return new ThreadPolicy(oldPolicyMask); } /** * Enable DropBox logging for debug phone builds. * * @hide */ public static boolean conditionallyEnableDebugLogging() { // For debug builds, log event loop stalls to dropbox for analysis. // Similar logic also appears in ActivityThread.java for system apps. if ("user".equals(Build.TYPE)) { return false; } StrictMode.setThreadPolicyMask( StrictMode.DETECT_DISK_WRITE | StrictMode.DETECT_DISK_READ | StrictMode.DETECT_NETWORK | StrictMode.PENALTY_DROPBOX); sVmPolicyMask = StrictMode.DETECT_VM_CURSOR_LEAKS | StrictMode.DETECT_VM_CLOSABLE_LEAKS | StrictMode.PENALTY_DROPBOX | StrictMode.PENALTY_LOG; return true; } /** * Used by the framework to make network usage on the main * thread a fatal error. * * @hide */ public static void enableDeathOnNetwork() { int oldPolicy = getThreadPolicyMask(); int newPolicy = oldPolicy | DETECT_NETWORK | PENALTY_DEATH_ON_NETWORK; setThreadPolicyMask(newPolicy); } /** * Parses the BlockGuard policy mask out from the Exception's * getMessage() String value. Kinda gross, but least * invasive. :/ * * Input is of form "policy=137 violation=64" * * Returns 0 on failure, which is a valid policy, but not a * valid policy during a violation (else there must've been * some policy in effect to violate). */ private static int parsePolicyFromMessage(String message) { if (message == null || !message.startsWith("policy=")) { return 0; } int spaceIndex = message.indexOf(' '); if (spaceIndex == -1) { return 0; } String policyString = message.substring(7, spaceIndex); try { return Integer.valueOf(policyString).intValue(); } catch (NumberFormatException e) { return 0; } } /** * Like parsePolicyFromMessage(), but returns the violation. */ private static int parseViolationFromMessage(String message) { if (message == null) { return 0; } int violationIndex = message.indexOf("violation="); if (violationIndex == -1) { return 0; } String violationString = message.substring(violationIndex + 10); try { return Integer.valueOf(violationString).intValue(); } catch (NumberFormatException e) { return 0; } } private static final ThreadLocal> violationsBeingTimed = new ThreadLocal>() { @Override protected ArrayList initialValue() { return new ArrayList(); } }; private static boolean tooManyViolationsThisLoop() { return violationsBeingTimed.get().size() >= MAX_OFFENSES_PER_LOOP; } private static class AndroidBlockGuardPolicy implements BlockGuard.Policy { private int mPolicyMask; // Map from violation stacktrace hashcode -> uptimeMillis of // last violation. No locking needed, as this is only // accessed by the same thread. private final HashMap mLastViolationTime = new HashMap(); public AndroidBlockGuardPolicy(final int policyMask) { mPolicyMask = policyMask; } @Override public String toString() { return "AndroidBlockGuardPolicy; mPolicyMask=" + mPolicyMask; } // Part of BlockGuard.Policy interface: public int getPolicyMask() { return mPolicyMask; } // Part of BlockGuard.Policy interface: public void onWriteToDisk() { if ((mPolicyMask & DETECT_DISK_WRITE) == 0) { return; } if (tooManyViolationsThisLoop()) { return; } BlockGuard.BlockGuardPolicyException e = new StrictModeDiskWriteViolation(mPolicyMask); e.fillInStackTrace(); startHandlingViolationException(e); } // Part of BlockGuard.Policy interface: public void onReadFromDisk() { if ((mPolicyMask & DETECT_DISK_READ) == 0) { return; } if (tooManyViolationsThisLoop()) { return; } BlockGuard.BlockGuardPolicyException e = new StrictModeDiskReadViolation(mPolicyMask); e.fillInStackTrace(); startHandlingViolationException(e); } // Part of BlockGuard.Policy interface: public void onNetwork() { if ((mPolicyMask & DETECT_NETWORK) == 0) { return; } if ((mPolicyMask & PENALTY_DEATH_ON_NETWORK) != 0) { throw new NetworkOnMainThreadException(); } if (tooManyViolationsThisLoop()) { return; } BlockGuard.BlockGuardPolicyException e = new StrictModeNetworkViolation(mPolicyMask); e.fillInStackTrace(); startHandlingViolationException(e); } public void setPolicyMask(int policyMask) { mPolicyMask = policyMask; } // Start handling a violation that just started and hasn't // actually run yet (e.g. no disk write or network operation // has yet occurred). This sees if we're in an event loop // thread and, if so, uses it to roughly measure how long the // violation took. void startHandlingViolationException(BlockGuard.BlockGuardPolicyException e) { final ViolationInfo info = new ViolationInfo(e, e.getPolicy()); info.violationUptimeMillis = SystemClock.uptimeMillis(); handleViolationWithTimingAttempt(info); } // Attempts to fill in the provided ViolationInfo's // durationMillis field if this thread has a Looper we can use // to measure with. We measure from the time of violation // until the time the looper is idle again (right before // the next epoll_wait) void handleViolationWithTimingAttempt(final ViolationInfo info) { Looper looper = Looper.myLooper(); // Without a Looper, we're unable to time how long the // violation takes place. This case should be rare, as // most users will care about timing violations that // happen on their main UI thread. Note that this case is // also hit when a violation takes place in a Binder // thread, in "gather" mode. In this case, the duration // of the violation is computed by the ultimate caller and // its Looper, if any. // TODO: if in gather mode, ignore Looper.myLooper() and always // go into this immediate mode? if (looper == null) { info.durationMillis = -1; // unknown (redundant, already set) handleViolation(info); return; } MessageQueue queue = Looper.myQueue(); final ArrayList records = violationsBeingTimed.get(); if (records.size() >= MAX_OFFENSES_PER_LOOP) { // Not worth measuring. Too many offenses in one loop. return; } records.add(info); if (records.size() > 1) { // There's already been a violation this loop, so we've already // registered an idle handler to process the list of violations // at the end of this Looper's loop. return; } queue.addIdleHandler(new MessageQueue.IdleHandler() { public boolean queueIdle() { long loopFinishTime = SystemClock.uptimeMillis(); for (int n = 0; n < records.size(); ++n) { ViolationInfo v = records.get(n); v.violationNumThisLoop = n + 1; v.durationMillis = (int) (loopFinishTime - v.violationUptimeMillis); handleViolation(v); } records.clear(); return false; // remove this idle handler from the array } }); } // Note: It's possible (even quite likely) that the // thread-local policy mask has changed from the time the // violation fired and now (after the violating code ran) due // to people who push/pop temporary policy in regions of code, // hence the policy being passed around. void handleViolation(final ViolationInfo info) { if (info == null || info.crashInfo == null || info.crashInfo.stackTrace == null) { Log.wtf(TAG, "unexpected null stacktrace"); return; } if (LOG_V) Log.d(TAG, "handleViolation; policy=" + info.policy); if ((info.policy & PENALTY_GATHER) != 0) { ArrayList violations = gatheredViolations.get(); if (violations == null) { violations = new ArrayList(1); gatheredViolations.set(violations); } else if (violations.size() >= 5) { // Too many. In a loop or something? Don't gather them all. return; } for (ViolationInfo previous : violations) { if (info.crashInfo.stackTrace.equals(previous.crashInfo.stackTrace)) { // Duplicate. Don't log. return; } } violations.add(info); return; } // Not perfect, but fast and good enough for dup suppression. Integer crashFingerprint = info.crashInfo.stackTrace.hashCode(); long lastViolationTime = 0; if (mLastViolationTime.containsKey(crashFingerprint)) { lastViolationTime = mLastViolationTime.get(crashFingerprint); } long now = SystemClock.uptimeMillis(); mLastViolationTime.put(crashFingerprint, now); long timeSinceLastViolationMillis = lastViolationTime == 0 ? Long.MAX_VALUE : (now - lastViolationTime); if ((info.policy & PENALTY_LOG) != 0 && timeSinceLastViolationMillis > MIN_LOG_INTERVAL_MS) { if (info.durationMillis != -1) { Log.d(TAG, "StrictMode policy violation; ~duration=" + info.durationMillis + " ms: " + info.crashInfo.stackTrace); } else { Log.d(TAG, "StrictMode policy violation: " + info.crashInfo.stackTrace); } } // The violationMaskSubset, passed to ActivityManager, is a // subset of the original StrictMode policy bitmask, with // only the bit violated and penalty bits to be executed // by the ActivityManagerService remaining set. int violationMaskSubset = 0; if ((info.policy & PENALTY_DIALOG) != 0 && timeSinceLastViolationMillis > MIN_DIALOG_INTERVAL_MS) { violationMaskSubset |= PENALTY_DIALOG; } if ((info.policy & PENALTY_DROPBOX) != 0 && lastViolationTime == 0) { violationMaskSubset |= PENALTY_DROPBOX; } if (violationMaskSubset != 0) { int violationBit = parseViolationFromMessage(info.crashInfo.exceptionMessage); violationMaskSubset |= violationBit; final int violationMaskSubsetFinal = violationMaskSubset; final int savedPolicyMask = getThreadPolicyMask(); final boolean justDropBox = (info.policy & PENALTY_MASK) == PENALTY_DROPBOX; if (justDropBox) { // If all we're going to ask the activity manager // to do is dropbox it (the common case during // platform development), we can avoid doing this // call synchronously which Binder data suggests // isn't always super fast, despite the implementation // in the ActivityManager trying to be mostly async. new Thread("callActivityManagerForStrictModeDropbox") { public void run() { Process.setThreadPriority(Process.THREAD_PRIORITY_BACKGROUND); try { ActivityManagerNative.getDefault(). handleApplicationStrictModeViolation( RuntimeInit.getApplicationObject(), violationMaskSubsetFinal, info); } catch (RemoteException e) { Log.e(TAG, "RemoteException handling StrictMode violation", e); } } }.start(); return; } // Normal synchronous call to the ActivityManager. try { // First, remove any policy before we call into the Activity Manager, // otherwise we'll infinite recurse as we try to log policy violations // to disk, thus violating policy, thus requiring logging, etc... // We restore the current policy below, in the finally block. setThreadPolicyMask(0); ActivityManagerNative.getDefault().handleApplicationStrictModeViolation( RuntimeInit.getApplicationObject(), violationMaskSubset, info); } catch (RemoteException e) { Log.e(TAG, "RemoteException trying to handle StrictMode violation", e); } finally { // Restore the policy. setThreadPolicyMask(savedPolicyMask); } } if ((info.policy & PENALTY_DEATH) != 0) { System.err.println("StrictMode policy violation with POLICY_DEATH; shutting down."); Process.killProcess(Process.myPid()); System.exit(10); } } } /** * Called from Parcel.writeNoException() */ /* package */ static boolean hasGatheredViolations() { return gatheredViolations.get() != null; } /** * Called from Parcel.writeException(), so we drop this memory and * don't incorrectly attribute it to the wrong caller on the next * Binder call on this thread. */ /* package */ static void clearGatheredViolations() { gatheredViolations.set(null); } /** * Sets the policy for what actions in the VM process (on any * thread) should be detected, as well as the penalty if such * actions occur. * * @param policy the policy to put into place */ public static void setVmPolicy(final VmPolicy policy) { sVmPolicyMask = policy.mask; CloseGuard.setEnabled(vmClosableObjectLeaksEnabled()); } /** * Gets the current VM policy. */ public static VmPolicy getVmPolicy() { return new VmPolicy(sVmPolicyMask); } /** * Enable the recommended StrictMode defaults, with violations just being logged. * *

This catches disk and network access on the main thread, as * well as leaked SQLite cursors and unclosed resources. This is * simply a wrapper around {@link #setVmPolicy} and {@link * #setThreadPolicy}. */ public static void enableDefaults() { StrictMode.setThreadPolicy(new StrictMode.ThreadPolicy.Builder() .detectAll() .penaltyLog() .build()); StrictMode.setVmPolicy(new StrictMode.VmPolicy.Builder() .detectLeakedSqlLiteObjects() .detectLeakedClosableObjects() .penaltyLog() .build()); } /** * @hide */ public static boolean vmSqliteObjectLeaksEnabled() { return (sVmPolicyMask & DETECT_VM_CURSOR_LEAKS) != 0; } /** * @hide */ public static boolean vmClosableObjectLeaksEnabled() { return (sVmPolicyMask & DETECT_VM_CLOSABLE_LEAKS) != 0; } /** * @hide */ public static void onSqliteObjectLeaked(String message, Throwable originStack) { if ((sVmPolicyMask & PENALTY_LOG) != 0) { Log.e(TAG, message, originStack); } if ((sVmPolicyMask & PENALTY_DROPBOX) != 0) { final ViolationInfo info = new ViolationInfo(originStack, sVmPolicyMask); // The violationMask, passed to ActivityManager, is a // subset of the original StrictMode policy bitmask, with // only the bit violated and penalty bits to be executed // by the ActivityManagerService remaining set. int violationMaskSubset = PENALTY_DROPBOX | DETECT_VM_CURSOR_LEAKS; final int savedPolicyMask = getThreadPolicyMask(); try { // First, remove any policy before we call into the Activity Manager, // otherwise we'll infinite recurse as we try to log policy violations // to disk, thus violating policy, thus requiring logging, etc... // We restore the current policy below, in the finally block. setThreadPolicyMask(0); ActivityManagerNative.getDefault().handleApplicationStrictModeViolation( RuntimeInit.getApplicationObject(), violationMaskSubset, info); } catch (RemoteException e) { Log.e(TAG, "RemoteException trying to handle StrictMode violation", e); } finally { // Restore the policy. setThreadPolicyMask(savedPolicyMask); } } if ((sVmPolicyMask & PENALTY_DEATH) != 0) { System.err.println("StrictMode VmPolicy violation with POLICY_DEATH; shutting down."); Process.killProcess(Process.myPid()); System.exit(10); } } /** * Called from Parcel.writeNoException() */ /* package */ static void writeGatheredViolationsToParcel(Parcel p) { ArrayList violations = gatheredViolations.get(); if (violations == null) { p.writeInt(0); } else { p.writeInt(violations.size()); for (int i = 0; i < violations.size(); ++i) { violations.get(i).writeToParcel(p, 0 /* unused flags? */); } if (LOG_V) Log.d(TAG, "wrote violations to response parcel; num=" + violations.size()); violations.clear(); // somewhat redundant, as we're about to null the threadlocal } gatheredViolations.set(null); } private static class LogStackTrace extends Exception {} /** * Called from Parcel.readException() when the exception is EX_STRICT_MODE_VIOLATIONS, * we here read back all the encoded violations. */ /* package */ static void readAndHandleBinderCallViolations(Parcel p) { // Our own stack trace to append StringWriter sw = new StringWriter(); new LogStackTrace().printStackTrace(new PrintWriter(sw)); String ourStack = sw.toString(); int policyMask = getThreadPolicyMask(); boolean currentlyGathering = (policyMask & PENALTY_GATHER) != 0; int numViolations = p.readInt(); for (int i = 0; i < numViolations; ++i) { if (LOG_V) Log.d(TAG, "strict mode violation stacks read from binder call. i=" + i); ViolationInfo info = new ViolationInfo(p, !currentlyGathering); info.crashInfo.stackTrace += "# via Binder call with stack:\n" + ourStack; BlockGuard.Policy policy = BlockGuard.getThreadPolicy(); if (policy instanceof AndroidBlockGuardPolicy) { ((AndroidBlockGuardPolicy) policy).handleViolationWithTimingAttempt(info); } } } /** * Called from android_util_Binder.cpp's * android_os_Parcel_enforceInterface when an incoming Binder call * requires changing the StrictMode policy mask. The role of this * function is to ask Binder for its current (native) thread-local * policy value and synchronize it to libcore's (Java) * thread-local policy value. */ private static void onBinderStrictModePolicyChange(int newPolicy) { setBlockGuardPolicy(newPolicy); } /** * Parcelable that gets sent in Binder call headers back to callers * to report violations that happened during a cross-process call. * * @hide */ public static class ViolationInfo { /** * Stack and other stuff info. */ public final ApplicationErrorReport.CrashInfo crashInfo; /** * The strict mode policy mask at the time of violation. */ public final int policy; /** * The wall time duration of the violation, when known. -1 when * not known. */ public int durationMillis = -1; /** * The number of animations currently running. */ public int numAnimationsRunning = 0; /** * Which violation number this was (1-based) since the last Looper loop, * from the perspective of the root caller (if it crossed any processes * via Binder calls). The value is 0 if the root caller wasn't on a Looper * thread. */ public int violationNumThisLoop; /** * The time (in terms of SystemClock.uptimeMillis()) that the * violation occurred. */ public long violationUptimeMillis; /** * The action of the Intent being broadcast to somebody's onReceive * on this thread right now, or null. */ public String broadcastIntentAction; /** * Create an uninitialized instance of ViolationInfo */ public ViolationInfo() { crashInfo = null; policy = 0; } /** * Create an instance of ViolationInfo initialized from an exception. */ public ViolationInfo(Throwable tr, int policy) { crashInfo = new ApplicationErrorReport.CrashInfo(tr); violationUptimeMillis = SystemClock.uptimeMillis(); this.policy = policy; this.numAnimationsRunning = ValueAnimator.getCurrentAnimationsCount(); Intent broadcastIntent = ActivityThread.getIntentBeingBroadcast(); if (broadcastIntent != null) { broadcastIntentAction = broadcastIntent.getAction(); } } /** * Create an instance of ViolationInfo initialized from a Parcel. */ public ViolationInfo(Parcel in) { this(in, false); } /** * Create an instance of ViolationInfo initialized from a Parcel. * * @param unsetGatheringBit if true, the caller is the root caller * and the gathering penalty should be removed. */ public ViolationInfo(Parcel in, boolean unsetGatheringBit) { crashInfo = new ApplicationErrorReport.CrashInfo(in); int rawPolicy = in.readInt(); if (unsetGatheringBit) { policy = rawPolicy & ~PENALTY_GATHER; } else { policy = rawPolicy; } durationMillis = in.readInt(); violationNumThisLoop = in.readInt(); numAnimationsRunning = in.readInt(); violationUptimeMillis = in.readLong(); broadcastIntentAction = in.readString(); } /** * Save a ViolationInfo instance to a parcel. */ public void writeToParcel(Parcel dest, int flags) { crashInfo.writeToParcel(dest, flags); dest.writeInt(policy); dest.writeInt(durationMillis); dest.writeInt(violationNumThisLoop); dest.writeInt(numAnimationsRunning); dest.writeLong(violationUptimeMillis); dest.writeString(broadcastIntentAction); } /** * Dump a ViolationInfo instance to a Printer. */ public void dump(Printer pw, String prefix) { crashInfo.dump(pw, prefix); pw.println(prefix + "policy: " + policy); if (durationMillis != -1) { pw.println(prefix + "durationMillis: " + durationMillis); } if (violationNumThisLoop != 0) { pw.println(prefix + "violationNumThisLoop: " + violationNumThisLoop); } if (numAnimationsRunning != 0) { pw.println(prefix + "numAnimationsRunning: " + numAnimationsRunning); } pw.println(prefix + "violationUptimeMillis: " + violationUptimeMillis); if (broadcastIntentAction != null) { pw.println(prefix + "broadcastIntentAction: " + broadcastIntentAction); } } } }