/* * Copyright (C) 2011 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 java.lang; import android.system.Os; import android.system.OsConstants; import dalvik.system.VMRuntime; import java.lang.ref.FinalizerReference; import java.lang.ref.Reference; import java.lang.ref.ReferenceQueue; import java.util.concurrent.atomic.AtomicBoolean; import java.util.concurrent.atomic.AtomicInteger; import java.util.concurrent.TimeoutException; import libcore.util.EmptyArray; /** * Calls Object.finalize() on objects in the finalizer reference queue. The VM * will abort if any finalize() call takes more than the maximum finalize time * to complete. * * @hide */ public final class Daemons { private static final int NANOS_PER_MILLI = 1000 * 1000; private static final int NANOS_PER_SECOND = NANOS_PER_MILLI * 1000; private static final long MAX_FINALIZE_NANOS = 10L * NANOS_PER_SECOND; public static void start() { ReferenceQueueDaemon.INSTANCE.start(); FinalizerDaemon.INSTANCE.start(); FinalizerWatchdogDaemon.INSTANCE.start(); HeapTaskDaemon.INSTANCE.start(); } public static void startPostZygoteFork() { ReferenceQueueDaemon.INSTANCE.startPostZygoteFork(); FinalizerDaemon.INSTANCE.startPostZygoteFork(); FinalizerWatchdogDaemon.INSTANCE.startPostZygoteFork(); HeapTaskDaemon.INSTANCE.startPostZygoteFork(); } public static void stop() { HeapTaskDaemon.INSTANCE.stop(); ReferenceQueueDaemon.INSTANCE.stop(); FinalizerDaemon.INSTANCE.stop(); FinalizerWatchdogDaemon.INSTANCE.stop(); } /** * A background task that provides runtime support to the application. * Daemons can be stopped and started, but only so that the zygote can be a * single-threaded process when it forks. */ private static abstract class Daemon implements Runnable { private Thread thread; private String name; private boolean postZygoteFork; protected Daemon(String name) { this.name = name; } public synchronized void start() { startInternal(); } public synchronized void startPostZygoteFork() { postZygoteFork = true; startInternal(); } public void startInternal() { if (thread != null) { throw new IllegalStateException("already running"); } thread = new Thread(ThreadGroup.systemThreadGroup, this, name); thread.setDaemon(true); thread.start(); } public void run() { if (postZygoteFork) { // We don't set the priority before the Thread.start() call above because // Thread.start() will call SetNativePriority and overwrite the desired native // priority. We (may) use a native priority that doesn't have a corresponding // java.lang.Thread-level priority (native priorities are more coarse-grained.) VMRuntime.getRuntime().setSystemDaemonThreadPriority(); } runInternal(); } public abstract void runInternal(); /** * Returns true while the current thread should continue to run; false * when it should return. */ protected synchronized boolean isRunning() { return thread != null; } public synchronized void interrupt() { interrupt(thread); } public synchronized void interrupt(Thread thread) { if (thread == null) { throw new IllegalStateException("not running"); } thread.interrupt(); } /** * Waits for the runtime thread to stop. This interrupts the thread * currently running the runnable and then waits for it to exit. */ public void stop() { Thread threadToStop; synchronized (this) { threadToStop = thread; thread = null; } if (threadToStop == null) { throw new IllegalStateException("not running"); } interrupt(threadToStop); while (true) { try { threadToStop.join(); return; } catch (InterruptedException ignored) { } catch (OutOfMemoryError ignored) { // An OOME may be thrown if allocating the InterruptedException failed. } } } /** * Returns the current stack trace of the thread, or an empty stack trace * if the thread is not currently running. */ public synchronized StackTraceElement[] getStackTrace() { return thread != null ? thread.getStackTrace() : EmptyArray.STACK_TRACE_ELEMENT; } } /** * This heap management thread moves elements from the garbage collector's * pending list to the managed reference queue. */ private static class ReferenceQueueDaemon extends Daemon { private static final ReferenceQueueDaemon INSTANCE = new ReferenceQueueDaemon(); ReferenceQueueDaemon() { super("ReferenceQueueDaemon"); } @Override public void runInternal() { while (isRunning()) { Reference list; try { synchronized (ReferenceQueue.class) { while (ReferenceQueue.unenqueued == null) { ReferenceQueue.class.wait(); } list = ReferenceQueue.unenqueued; ReferenceQueue.unenqueued = null; } } catch (InterruptedException e) { continue; } catch (OutOfMemoryError e) { continue; } ReferenceQueue.enqueuePending(list); } } } private static class FinalizerDaemon extends Daemon { private static final FinalizerDaemon INSTANCE = new FinalizerDaemon(); private final ReferenceQueue queue = FinalizerReference.queue; private final AtomicInteger progressCounter = new AtomicInteger(0); // Object (not reference!) being finalized. Accesses may race! private Object finalizingObject = null; FinalizerDaemon() { super("FinalizerDaemon"); } @Override public void runInternal() { // This loop may be performance critical, since we need to keep up with mutator // generation of finalizable objects. // We minimize the amount of work we do per finalizable object. For example, we avoid // reading the current time here, since that involves a kernel call per object. We // limit fast path communication with FinalizerWatchDogDaemon to what's unavoidable: A // non-volatile store to communicate the current finalizable object, e.g. for // reporting, and a release store (lazySet) to a counter. // We do stop the FinalizerWatchDogDaemon if we have nothing to do for a // potentially extended period. This prevents the device from waking up regularly // during idle times. // Local copy of progressCounter; saves a fence per increment on ARM and MIPS. int localProgressCounter = progressCounter.get(); while (isRunning()) { try { // Use non-blocking poll to avoid FinalizerWatchdogDaemon communication // when busy. FinalizerReference finalizingReference = (FinalizerReference)queue.poll(); if (finalizingReference != null) { finalizingObject = finalizingReference.get(); progressCounter.lazySet(++localProgressCounter); } else { finalizingObject = null; progressCounter.lazySet(++localProgressCounter); // Slow path; block. FinalizerWatchdogDaemon.INSTANCE.goToSleep(); finalizingReference = (FinalizerReference)queue.remove(); finalizingObject = finalizingReference.get(); progressCounter.set(++localProgressCounter); FinalizerWatchdogDaemon.INSTANCE.wakeUp(); } doFinalize(finalizingReference); } catch (InterruptedException ignored) { } catch (OutOfMemoryError ignored) { } } } @FindBugsSuppressWarnings("FI_EXPLICIT_INVOCATION") private void doFinalize(FinalizerReference reference) { FinalizerReference.remove(reference); Object object = reference.get(); reference.clear(); try { object.finalize(); } catch (Throwable ex) { // The RI silently swallows these, but Android has always logged. System.logE("Uncaught exception thrown by finalizer", ex); } finally { // Done finalizing, stop holding the object as live. finalizingObject = null; } } } /** * The watchdog exits the VM if the finalizer ever gets stuck. We consider * the finalizer to be stuck if it spends more than MAX_FINALIZATION_MILLIS * on one instance. */ private static class FinalizerWatchdogDaemon extends Daemon { private static final FinalizerWatchdogDaemon INSTANCE = new FinalizerWatchdogDaemon(); private boolean needToWork = true; // Only accessed in synchronized methods. FinalizerWatchdogDaemon() { super("FinalizerWatchdogDaemon"); } @Override public void runInternal() { while (isRunning()) { if (!sleepUntilNeeded()) { // We have been interrupted, need to see if this daemon has been stopped. continue; } final Object finalizing = waitForFinalization(); if (finalizing != null && !VMRuntime.getRuntime().isDebuggerActive()) { finalizerTimedOut(finalizing); break; } } } /** * Wait until something is ready to be finalized. * Return false if we have been interrupted * See also http://code.google.com/p/android/issues/detail?id=22778. */ private synchronized boolean sleepUntilNeeded() { while (!needToWork) { try { wait(); } catch (InterruptedException e) { // Daemon.stop may have interrupted us. return false; } catch (OutOfMemoryError e) { return false; } } return true; } /** * Notify daemon that it's OK to sleep until notified that something is ready to be * finalized. */ private synchronized void goToSleep() { needToWork = false; } /** * Notify daemon that there is something ready to be finalized. */ private synchronized void wakeUp() { needToWork = true; notify(); } private synchronized boolean getNeedToWork() { return needToWork; } /** * Sleep for the given number of nanoseconds. * @return false if we were interrupted. */ private boolean sleepFor(long durationNanos) { long startNanos = System.nanoTime(); while (true) { long elapsedNanos = System.nanoTime() - startNanos; long sleepNanos = durationNanos - elapsedNanos; long sleepMills = sleepNanos / NANOS_PER_MILLI; if (sleepMills <= 0) { return true; } try { Thread.sleep(sleepMills); } catch (InterruptedException e) { if (!isRunning()) { return false; } } catch (OutOfMemoryError ignored) { if (!isRunning()) { return false; } } } } /** * Return an object that took too long to finalize or return null. * Wait MAX_FINALIZE_NANOS. If the FinalizerDaemon took essentially the whole time * processing a single reference, return that reference. Otherwise return null. */ private Object waitForFinalization() { long startCount = FinalizerDaemon.INSTANCE.progressCounter.get(); // Avoid remembering object being finalized, so as not to keep it alive. if (!sleepFor(MAX_FINALIZE_NANOS)) { // Don't report possibly spurious timeout if we are interrupted. return null; } if (getNeedToWork() && FinalizerDaemon.INSTANCE.progressCounter.get() == startCount) { // We assume that only remove() and doFinalize() may take time comparable to // MAX_FINALIZE_NANOS. // We observed neither the effect of the gotoSleep() nor the increment preceding a // later wakeUp. Any remove() call by the FinalizerDaemon during our sleep // interval must have been followed by a wakeUp call before we checked needToWork. // But then we would have seen the counter increment. Thus there cannot have // been such a remove() call. // The FinalizerDaemon must not have progressed (from either the beginning or the // last progressCounter increment) to either the next increment or gotoSleep() // call. Thus we must have taken essentially the whole MAX_FINALIZE_NANOS in a // single doFinalize() call. Thus it's OK to time out. finalizingObject was set // just before the counter increment, which preceded the doFinalize call. Thus we // are guaranteed to get the correct finalizing value below, unless doFinalize() // just finished as we were timing out, in which case we may get null or a later // one. In this last case, we are very likely to discard it below. Object finalizing = FinalizerDaemon.INSTANCE.finalizingObject; sleepFor(NANOS_PER_SECOND / 2); // Recheck to make it even less likely we report the wrong finalizing object in // the case which a very slow finalization just finished as we were timing out. if (getNeedToWork() && FinalizerDaemon.INSTANCE.progressCounter.get() == startCount) { return finalizing; } } return null; } private static void finalizerTimedOut(Object object) { // The current object has exceeded the finalization deadline; abort! String message = object.getClass().getName() + ".finalize() timed out after " + (MAX_FINALIZE_NANOS / NANOS_PER_SECOND) + " seconds"; Exception syntheticException = new TimeoutException(message); // We use the stack from where finalize() was running to show where it was stuck. syntheticException.setStackTrace(FinalizerDaemon.INSTANCE.getStackTrace()); // Send SIGQUIT to get native stack traces. try { Os.kill(Os.getpid(), OsConstants.SIGQUIT); // Sleep a few seconds to let the stack traces print. Thread.sleep(5000); } catch (Exception e) { System.logE("failed to send SIGQUIT", e); } catch (OutOfMemoryError ignored) { // May occur while trying to allocate the exception. } // Ideally, we'd want to do this if this Thread had no handler to dispatch to. // Unfortunately, it's extremely to messy to query whether a given Thread has *some* // handler to dispatch to, either via a handler set on itself, via its ThreadGroup // object or via the defaultUncaughtExceptionHandler. // // As an approximation, we log by hand an exit if there's no pre-exception handler nor // a default uncaught exception handler. // // Note that this condition will only ever be hit by ART host tests and standalone // dalvikvm invocations. All zygote forked process *will* have a pre-handler set // in RuntimeInit and they cannot subsequently override it. if (Thread.getUncaughtExceptionPreHandler() == null && Thread.getDefaultUncaughtExceptionHandler() == null) { // If we have no handler, log and exit. System.logE(message, syntheticException); System.exit(2); } // Otherwise call the handler to do crash reporting. // We don't just throw because we're not the thread that // timed out; we're the thread that detected it. Thread.currentThread().dispatchUncaughtException(syntheticException); } } // Adds a heap trim task to the heap event processor, not called from java. Left for // compatibility purposes due to reflection. public static void requestHeapTrim() { VMRuntime.getRuntime().requestHeapTrim(); } // Adds a concurrent GC request task ot the heap event processor, not called from java. Left // for compatibility purposes due to reflection. public static void requestGC() { VMRuntime.getRuntime().requestConcurrentGC(); } private static class HeapTaskDaemon extends Daemon { private static final HeapTaskDaemon INSTANCE = new HeapTaskDaemon(); HeapTaskDaemon() { super("HeapTaskDaemon"); } // Overrides the Daemon.interupt method which is called from Daemons.stop. public synchronized void interrupt(Thread thread) { VMRuntime.getRuntime().stopHeapTaskProcessor(); } @Override public void runInternal() { synchronized (this) { if (isRunning()) { // Needs to be synchronized or else we there is a race condition where we start // the thread, call stopHeapTaskProcessor before we start the heap task // processor, resulting in a deadlock since startHeapTaskProcessor restarts it // while the other thread is waiting in Daemons.stop(). VMRuntime.getRuntime().startHeapTaskProcessor(); } } // This runs tasks until we are stopped and there is no more pending task. VMRuntime.getRuntime().runHeapTasks(); } } }