/* * Written by Doug Lea with assistance from members of JCP JSR-166 * Expert Group and released to the public domain, as explained at * http://creativecommons.org/publicdomain/zero/1.0/ * Other contributors include Andrew Wright, Jeffrey Hayes, * Pat Fisher, Mike Judd. */ /* * Source: * http://gee.cs.oswego.edu/cgi-bin/viewcvs.cgi/jsr166/src/test/tck/JSR166TestCase.java?revision=1.90 * (We have made some trivial local modifications (commented out * uncompilable code).) */ package com.google.common.util.concurrent; import junit.framework.*; import java.io.ByteArrayInputStream; import java.io.ByteArrayOutputStream; import java.io.ObjectInputStream; import java.io.ObjectOutputStream; import java.util.Arrays; import java.util.Date; import java.util.NoSuchElementException; import java.util.PropertyPermission; import java.util.concurrent.*; import java.util.concurrent.atomic.AtomicBoolean; import java.util.concurrent.atomic.AtomicReference; import static java.util.concurrent.TimeUnit.MILLISECONDS; import static java.util.concurrent.TimeUnit.NANOSECONDS; import java.security.CodeSource; import java.security.Permission; import java.security.PermissionCollection; import java.security.Permissions; import java.security.Policy; import java.security.ProtectionDomain; import java.security.SecurityPermission; /** * Base class for JSR166 Junit TCK tests. Defines some constants, * utility methods and classes, as well as a simple framework for * helping to make sure that assertions failing in generated threads * cause the associated test that generated them to itself fail (which * JUnit does not otherwise arrange). The rules for creating such * tests are: * * <ol> * * <li> All assertions in code running in generated threads must use * the forms {@link #threadFail}, {@link #threadAssertTrue}, {@link * #threadAssertEquals}, or {@link #threadAssertNull}, (not * {@code fail}, {@code assertTrue}, etc.) It is OK (but not * particularly recommended) for other code to use these forms too. * Only the most typically used JUnit assertion methods are defined * this way, but enough to live with.</li> * * <li> If you override {@link #setUp} or {@link #tearDown}, make sure * to invoke {@code super.setUp} and {@code super.tearDown} within * them. These methods are used to clear and check for thread * assertion failures.</li> * * <li>All delays and timeouts must use one of the constants {@code * SHORT_DELAY_MS}, {@code SMALL_DELAY_MS}, {@code MEDIUM_DELAY_MS}, * {@code LONG_DELAY_MS}. The idea here is that a SHORT is always * discriminable from zero time, and always allows enough time for the * small amounts of computation (creating a thread, calling a few * methods, etc) needed to reach a timeout point. Similarly, a SMALL * is always discriminable as larger than SHORT and smaller than * MEDIUM. And so on. These constants are set to conservative values, * but even so, if there is ever any doubt, they can all be increased * in one spot to rerun tests on slower platforms.</li> * * <li> All threads generated must be joined inside each test case * method (or {@code fail} to do so) before returning from the * method. The {@code joinPool} method can be used to do this when * using Executors.</li> * * </ol> * * <p> <b>Other notes</b> * <ul> * * <li> Usually, there is one testcase method per JSR166 method * covering "normal" operation, and then as many exception-testing * methods as there are exceptions the method can throw. Sometimes * there are multiple tests per JSR166 method when the different * "normal" behaviors differ significantly. And sometimes testcases * cover multiple methods when they cannot be tested in * isolation.</li> * * <li> The documentation style for testcases is to provide as javadoc * a simple sentence or two describing the property that the testcase * method purports to test. The javadocs do not say anything about how * the property is tested. To find out, read the code.</li> * * <li> These tests are "conformance tests", and do not attempt to * test throughput, latency, scalability or other performance factors * (see the separate "jtreg" tests for a set intended to check these * for the most central aspects of functionality.) So, most tests use * the smallest sensible numbers of threads, collection sizes, etc * needed to check basic conformance.</li> * * <li>The test classes currently do not declare inclusion in * any particular package to simplify things for people integrating * them in TCK test suites.</li> * * <li> As a convenience, the {@code main} of this class (JSR166TestCase) * runs all JSR166 unit tests.</li> * * </ul> */ abstract class JSR166TestCase extends TestCase { private static final boolean useSecurityManager = Boolean.getBoolean("jsr166.useSecurityManager"); protected static final boolean expensiveTests = Boolean.getBoolean("jsr166.expensiveTests"); /** * If true, report on stdout all "slow" tests, that is, ones that * take more than profileThreshold milliseconds to execute. */ private static final boolean profileTests = Boolean.getBoolean("jsr166.profileTests"); /** * The number of milliseconds that tests are permitted for * execution without being reported, when profileTests is set. */ private static final long profileThreshold = Long.getLong("jsr166.profileThreshold", 100); protected void runTest() throws Throwable { if (profileTests) runTestProfiled(); else super.runTest(); } protected void runTestProfiled() throws Throwable { long t0 = System.nanoTime(); try { super.runTest(); } finally { long elapsedMillis = (System.nanoTime() - t0) / (1000L * 1000L); if (elapsedMillis >= profileThreshold) System.out.printf("%n%s: %d%n", toString(), elapsedMillis); } } // /** // * Runs all JSR166 unit tests using junit.textui.TestRunner // */ // public static void main(String[] args) { // if (useSecurityManager) { // System.err.println("Setting a permissive security manager"); // Policy.setPolicy(permissivePolicy()); // System.setSecurityManager(new SecurityManager()); // } // int iters = (args.length == 0) ? 1 : Integer.parseInt(args[0]); // Test s = suite(); // for (int i = 0; i < iters; ++i) { // junit.textui.TestRunner.run(s); // System.gc(); // System.runFinalization(); // } // System.exit(0); // } // public static TestSuite newTestSuite(Object... suiteOrClasses) { // TestSuite suite = new TestSuite(); // for (Object suiteOrClass : suiteOrClasses) { // if (suiteOrClass instanceof TestSuite) // suite.addTest((TestSuite) suiteOrClass); // else if (suiteOrClass instanceof Class) // suite.addTest(new TestSuite((Class<?>) suiteOrClass)); // else // throw new ClassCastException("not a test suite or class"); // } // return suite; // } // /** // * Collects all JSR166 unit tests as one suite. // */ // public static Test suite() { // return newTestSuite( // ForkJoinPoolTest.suite(), // ForkJoinTaskTest.suite(), // RecursiveActionTest.suite(), // RecursiveTaskTest.suite(), // LinkedTransferQueueTest.suite(), // PhaserTest.suite(), // ThreadLocalRandomTest.suite(), // AbstractExecutorServiceTest.suite(), // AbstractQueueTest.suite(), // AbstractQueuedSynchronizerTest.suite(), // AbstractQueuedLongSynchronizerTest.suite(), // ArrayBlockingQueueTest.suite(), // ArrayDequeTest.suite(), // AtomicBooleanTest.suite(), // AtomicIntegerArrayTest.suite(), // AtomicIntegerFieldUpdaterTest.suite(), // AtomicIntegerTest.suite(), // AtomicLongArrayTest.suite(), // AtomicLongFieldUpdaterTest.suite(), // AtomicLongTest.suite(), // AtomicMarkableReferenceTest.suite(), // AtomicReferenceArrayTest.suite(), // AtomicReferenceFieldUpdaterTest.suite(), // AtomicReferenceTest.suite(), // AtomicStampedReferenceTest.suite(), // ConcurrentHashMapTest.suite(), // ConcurrentLinkedDequeTest.suite(), // ConcurrentLinkedQueueTest.suite(), // ConcurrentSkipListMapTest.suite(), // ConcurrentSkipListSubMapTest.suite(), // ConcurrentSkipListSetTest.suite(), // ConcurrentSkipListSubSetTest.suite(), // CopyOnWriteArrayListTest.suite(), // CopyOnWriteArraySetTest.suite(), // CountDownLatchTest.suite(), // CyclicBarrierTest.suite(), // DelayQueueTest.suite(), // EntryTest.suite(), // ExchangerTest.suite(), // ExecutorsTest.suite(), // ExecutorCompletionServiceTest.suite(), // FutureTaskTest.suite(), // LinkedBlockingDequeTest.suite(), // LinkedBlockingQueueTest.suite(), // LinkedListTest.suite(), // LockSupportTest.suite(), // PriorityBlockingQueueTest.suite(), // PriorityQueueTest.suite(), // ReentrantLockTest.suite(), // ReentrantReadWriteLockTest.suite(), // ScheduledExecutorTest.suite(), // ScheduledExecutorSubclassTest.suite(), // SemaphoreTest.suite(), // SynchronousQueueTest.suite(), // SystemTest.suite(), // ThreadLocalTest.suite(), // ThreadPoolExecutorTest.suite(), // ThreadPoolExecutorSubclassTest.suite(), // ThreadTest.suite(), // TimeUnitTest.suite(), // TreeMapTest.suite(), // TreeSetTest.suite(), // TreeSubMapTest.suite(), // TreeSubSetTest.suite()); // } public static long SHORT_DELAY_MS; public static long SMALL_DELAY_MS; public static long MEDIUM_DELAY_MS; public static long LONG_DELAY_MS; /** * Returns the shortest timed delay. This could * be reimplemented to use for example a Property. */ protected long getShortDelay() { return 50; } /** * Sets delays as multiples of SHORT_DELAY. */ protected void setDelays() { SHORT_DELAY_MS = getShortDelay(); SMALL_DELAY_MS = SHORT_DELAY_MS * 5; MEDIUM_DELAY_MS = SHORT_DELAY_MS * 10; LONG_DELAY_MS = SHORT_DELAY_MS * 200; } /** * Returns a timeout in milliseconds to be used in tests that * verify that operations block or time out. */ long timeoutMillis() { return SHORT_DELAY_MS / 4; } /** * Returns a new Date instance representing a time delayMillis * milliseconds in the future. */ Date delayedDate(long delayMillis) { return new Date(System.currentTimeMillis() + delayMillis); } /** * The first exception encountered if any threadAssertXXX method fails. */ private final AtomicReference<Throwable> threadFailure = new AtomicReference<Throwable>(null); /** * Records an exception so that it can be rethrown later in the test * harness thread, triggering a test case failure. Only the first * failure is recorded; subsequent calls to this method from within * the same test have no effect. */ public void threadRecordFailure(Throwable t) { threadFailure.compareAndSet(null, t); } public void setUp() { setDelays(); } /** * Extra checks that get done for all test cases. * * Triggers test case failure if any thread assertions have failed, * by rethrowing, in the test harness thread, any exception recorded * earlier by threadRecordFailure. * * Triggers test case failure if interrupt status is set in the main thread. */ public void tearDown() throws Exception { Throwable t = threadFailure.getAndSet(null); if (t != null) { if (t instanceof Error) throw (Error) t; else if (t instanceof RuntimeException) throw (RuntimeException) t; else if (t instanceof Exception) throw (Exception) t; else { AssertionFailedError afe = new AssertionFailedError(t.toString()); afe.initCause(t); throw afe; } } if (Thread.interrupted()) throw new AssertionFailedError("interrupt status set in main thread"); } /** * Just like fail(reason), but additionally recording (using * threadRecordFailure) any AssertionFailedError thrown, so that * the current testcase will fail. */ public void threadFail(String reason) { try { fail(reason); } catch (AssertionFailedError t) { threadRecordFailure(t); fail(reason); } } /** * Just like assertTrue(b), but additionally recording (using * threadRecordFailure) any AssertionFailedError thrown, so that * the current testcase will fail. */ public void threadAssertTrue(boolean b) { try { assertTrue(b); } catch (AssertionFailedError t) { threadRecordFailure(t); throw t; } } /** * Just like assertFalse(b), but additionally recording (using * threadRecordFailure) any AssertionFailedError thrown, so that * the current testcase will fail. */ public void threadAssertFalse(boolean b) { try { assertFalse(b); } catch (AssertionFailedError t) { threadRecordFailure(t); throw t; } } /** * Just like assertNull(x), but additionally recording (using * threadRecordFailure) any AssertionFailedError thrown, so that * the current testcase will fail. */ public void threadAssertNull(Object x) { try { assertNull(x); } catch (AssertionFailedError t) { threadRecordFailure(t); throw t; } } /** * Just like assertEquals(x, y), but additionally recording (using * threadRecordFailure) any AssertionFailedError thrown, so that * the current testcase will fail. */ public void threadAssertEquals(long x, long y) { try { assertEquals(x, y); } catch (AssertionFailedError t) { threadRecordFailure(t); throw t; } } /** * Just like assertEquals(x, y), but additionally recording (using * threadRecordFailure) any AssertionFailedError thrown, so that * the current testcase will fail. */ public void threadAssertEquals(Object x, Object y) { try { assertEquals(x, y); } catch (AssertionFailedError t) { threadRecordFailure(t); throw t; } catch (Throwable t) { threadUnexpectedException(t); } } /** * Just like assertSame(x, y), but additionally recording (using * threadRecordFailure) any AssertionFailedError thrown, so that * the current testcase will fail. */ public void threadAssertSame(Object x, Object y) { try { assertSame(x, y); } catch (AssertionFailedError t) { threadRecordFailure(t); throw t; } } /** * Calls threadFail with message "should throw exception". */ public void threadShouldThrow() { threadFail("should throw exception"); } /** * Calls threadFail with message "should throw" + exceptionName. */ public void threadShouldThrow(String exceptionName) { threadFail("should throw " + exceptionName); } /** * Records the given exception using {@link #threadRecordFailure}, * then rethrows the exception, wrapping it in an * AssertionFailedError if necessary. */ public void threadUnexpectedException(Throwable t) { threadRecordFailure(t); t.printStackTrace(); if (t instanceof RuntimeException) throw (RuntimeException) t; else if (t instanceof Error) throw (Error) t; else { AssertionFailedError afe = new AssertionFailedError("unexpected exception: " + t); afe.initCause(t); throw afe; } } /** * Delays, via Thread.sleep, for the given millisecond delay, but * if the sleep is shorter than specified, may re-sleep or yield * until time elapses. */ static void delay(long millis) throws InterruptedException { long startTime = System.nanoTime(); long ns = millis * 1000 * 1000; for (;;) { if (millis > 0L) Thread.sleep(millis); else // too short to sleep Thread.yield(); long d = ns - (System.nanoTime() - startTime); if (d > 0L) millis = d / (1000 * 1000); else break; } } /** * Waits out termination of a thread pool or fails doing so. */ void joinPool(ExecutorService exec) { try { exec.shutdown(); assertTrue("ExecutorService did not terminate in a timely manner", exec.awaitTermination(2 * LONG_DELAY_MS, MILLISECONDS)); } catch (SecurityException ok) { // Allowed in case test doesn't have privs } catch (InterruptedException ie) { fail("Unexpected InterruptedException"); } } /** * Checks that thread does not terminate within the default * millisecond delay of {@code timeoutMillis()}. */ void assertThreadStaysAlive(Thread thread) { assertThreadStaysAlive(thread, timeoutMillis()); } /** * Checks that thread does not terminate within the given millisecond delay. */ void assertThreadStaysAlive(Thread thread, long millis) { try { // No need to optimize the failing case via Thread.join. delay(millis); assertTrue(thread.isAlive()); } catch (InterruptedException ie) { fail("Unexpected InterruptedException"); } } /** * Checks that the threads do not terminate within the default * millisecond delay of {@code timeoutMillis()}. */ void assertThreadsStayAlive(Thread... threads) { assertThreadsStayAlive(timeoutMillis(), threads); } /** * Checks that the threads do not terminate within the given millisecond delay. */ void assertThreadsStayAlive(long millis, Thread... threads) { try { // No need to optimize the failing case via Thread.join. delay(millis); for (Thread thread : threads) assertTrue(thread.isAlive()); } catch (InterruptedException ie) { fail("Unexpected InterruptedException"); } } /** * Checks that future.get times out, with the default timeout of * {@code timeoutMillis()}. */ void assertFutureTimesOut(Future future) { assertFutureTimesOut(future, timeoutMillis()); } /** * Checks that future.get times out, with the given millisecond timeout. */ void assertFutureTimesOut(Future future, long timeoutMillis) { long startTime = System.nanoTime(); try { future.get(timeoutMillis, MILLISECONDS); shouldThrow(); } catch (TimeoutException success) { } catch (Exception e) { threadUnexpectedException(e); } finally { future.cancel(true); } assertTrue(millisElapsedSince(startTime) >= timeoutMillis); } /** * Fails with message "should throw exception". */ public void shouldThrow() { fail("Should throw exception"); } /** * Fails with message "should throw " + exceptionName. */ public void shouldThrow(String exceptionName) { fail("Should throw " + exceptionName); } /** * The number of elements to place in collections, arrays, etc. */ public static final int SIZE = 20; // Some convenient Integer constants public static final Integer zero = new Integer(0); public static final Integer one = new Integer(1); public static final Integer two = new Integer(2); public static final Integer three = new Integer(3); public static final Integer four = new Integer(4); public static final Integer five = new Integer(5); public static final Integer six = new Integer(6); public static final Integer seven = new Integer(7); public static final Integer eight = new Integer(8); public static final Integer nine = new Integer(9); public static final Integer m1 = new Integer(-1); public static final Integer m2 = new Integer(-2); public static final Integer m3 = new Integer(-3); public static final Integer m4 = new Integer(-4); public static final Integer m5 = new Integer(-5); public static final Integer m6 = new Integer(-6); public static final Integer m10 = new Integer(-10); /** * Runs Runnable r with a security policy that permits precisely * the specified permissions. If there is no current security * manager, the runnable is run twice, both with and without a * security manager. We require that any security manager permit * getPolicy/setPolicy. */ public void runWithPermissions(Runnable r, Permission... permissions) { SecurityManager sm = System.getSecurityManager(); if (sm == null) { r.run(); Policy savedPolicy = Policy.getPolicy(); try { Policy.setPolicy(permissivePolicy()); System.setSecurityManager(new SecurityManager()); runWithPermissions(r, permissions); } finally { System.setSecurityManager(null); Policy.setPolicy(savedPolicy); } } else { Policy savedPolicy = Policy.getPolicy(); AdjustablePolicy policy = new AdjustablePolicy(permissions); Policy.setPolicy(policy); try { r.run(); } finally { policy.addPermission(new SecurityPermission("setPolicy")); Policy.setPolicy(savedPolicy); } } } /** * Runs a runnable without any permissions. */ public void runWithoutPermissions(Runnable r) { runWithPermissions(r); } /** * A security policy where new permissions can be dynamically added * or all cleared. */ public static class AdjustablePolicy extends java.security.Policy { Permissions perms = new Permissions(); AdjustablePolicy(Permission... permissions) { for (Permission permission : permissions) perms.add(permission); } void addPermission(Permission perm) { perms.add(perm); } void clearPermissions() { perms = new Permissions(); } public PermissionCollection getPermissions(CodeSource cs) { return perms; } public PermissionCollection getPermissions(ProtectionDomain pd) { return perms; } public boolean implies(ProtectionDomain pd, Permission p) { return perms.implies(p); } public void refresh() {} } /** * Returns a policy containing all the permissions we ever need. */ public static Policy permissivePolicy() { return new AdjustablePolicy // Permissions j.u.c. needs directly (new RuntimePermission("modifyThread"), new RuntimePermission("getClassLoader"), new RuntimePermission("setContextClassLoader"), // Permissions needed to change permissions! new SecurityPermission("getPolicy"), new SecurityPermission("setPolicy"), new RuntimePermission("setSecurityManager"), // Permissions needed by the junit test harness new RuntimePermission("accessDeclaredMembers"), new PropertyPermission("*", "read"), new java.io.FilePermission("<<ALL FILES>>", "read")); } /** * Sleeps until the given time has elapsed. * Throws AssertionFailedError if interrupted. */ void sleep(long millis) { try { delay(millis); } catch (InterruptedException ie) { AssertionFailedError afe = new AssertionFailedError("Unexpected InterruptedException"); afe.initCause(ie); throw afe; } } /** * Spin-waits up to the specified number of milliseconds for the given * thread to enter a wait state: BLOCKED, WAITING, or TIMED_WAITING. */ void waitForThreadToEnterWaitState(Thread thread, long timeoutMillis) { long startTime = System.nanoTime(); for (;;) { Thread.State s = thread.getState(); if (s == Thread.State.BLOCKED || s == Thread.State.WAITING || s == Thread.State.TIMED_WAITING) return; else if (s == Thread.State.TERMINATED) fail("Unexpected thread termination"); else if (millisElapsedSince(startTime) > timeoutMillis) { threadAssertTrue(thread.isAlive()); return; } Thread.yield(); } } /** * Waits up to LONG_DELAY_MS for the given thread to enter a wait * state: BLOCKED, WAITING, or TIMED_WAITING. */ void waitForThreadToEnterWaitState(Thread thread) { waitForThreadToEnterWaitState(thread, LONG_DELAY_MS); } /** * Returns the number of milliseconds since time given by * startNanoTime, which must have been previously returned from a * call to {@link System.nanoTime()}. */ long millisElapsedSince(long startNanoTime) { return NANOSECONDS.toMillis(System.nanoTime() - startNanoTime); } /** * Returns a new started daemon Thread running the given runnable. */ Thread newStartedThread(Runnable runnable) { Thread t = new Thread(runnable); t.setDaemon(true); t.start(); return t; } /** * Waits for the specified time (in milliseconds) for the thread * to terminate (using {@link Thread#join(long)}), else interrupts * the thread (in the hope that it may terminate later) and fails. */ void awaitTermination(Thread t, long timeoutMillis) { try { t.join(timeoutMillis); } catch (InterruptedException ie) { threadUnexpectedException(ie); } finally { if (t.getState() != Thread.State.TERMINATED) { t.interrupt(); fail("Test timed out"); } } } /** * Waits for LONG_DELAY_MS milliseconds for the thread to * terminate (using {@link Thread#join(long)}), else interrupts * the thread (in the hope that it may terminate later) and fails. */ void awaitTermination(Thread t) { awaitTermination(t, LONG_DELAY_MS); } // Some convenient Runnable classes public abstract class CheckedRunnable implements Runnable { protected abstract void realRun() throws Throwable; public final void run() { try { realRun(); } catch (Throwable t) { threadUnexpectedException(t); } } } public abstract class RunnableShouldThrow implements Runnable { protected abstract void realRun() throws Throwable; final Class<?> exceptionClass; <T extends Throwable> RunnableShouldThrow(Class<T> exceptionClass) { this.exceptionClass = exceptionClass; } public final void run() { try { realRun(); threadShouldThrow(exceptionClass.getSimpleName()); } catch (Throwable t) { if (! exceptionClass.isInstance(t)) threadUnexpectedException(t); } } } public abstract class ThreadShouldThrow extends Thread { protected abstract void realRun() throws Throwable; final Class<?> exceptionClass; <T extends Throwable> ThreadShouldThrow(Class<T> exceptionClass) { this.exceptionClass = exceptionClass; } public final void run() { try { realRun(); threadShouldThrow(exceptionClass.getSimpleName()); } catch (Throwable t) { if (! exceptionClass.isInstance(t)) threadUnexpectedException(t); } } } public abstract class CheckedInterruptedRunnable implements Runnable { protected abstract void realRun() throws Throwable; public final void run() { try { realRun(); threadShouldThrow("InterruptedException"); } catch (InterruptedException success) { threadAssertFalse(Thread.interrupted()); } catch (Throwable t) { threadUnexpectedException(t); } } } public abstract class CheckedCallable<T> implements Callable<T> { protected abstract T realCall() throws Throwable; public final T call() { try { return realCall(); } catch (Throwable t) { threadUnexpectedException(t); return null; } } } public abstract class CheckedInterruptedCallable<T> implements Callable<T> { protected abstract T realCall() throws Throwable; public final T call() { try { T result = realCall(); threadShouldThrow("InterruptedException"); return result; } catch (InterruptedException success) { threadAssertFalse(Thread.interrupted()); } catch (Throwable t) { threadUnexpectedException(t); } return null; } } public static class NoOpRunnable implements Runnable { public void run() {} } public static class NoOpCallable implements Callable { public Object call() { return Boolean.TRUE; } } public static final String TEST_STRING = "a test string"; public static class StringTask implements Callable<String> { public String call() { return TEST_STRING; } } public Callable<String> latchAwaitingStringTask(final CountDownLatch latch) { return new CheckedCallable<String>() { protected String realCall() { try { latch.await(); } catch (InterruptedException quittingTime) {} return TEST_STRING; }}; } public Runnable awaiter(final CountDownLatch latch) { return new CheckedRunnable() { public void realRun() throws InterruptedException { await(latch); }}; } public void await(CountDownLatch latch) { try { assertTrue(latch.await(LONG_DELAY_MS, MILLISECONDS)); } catch (Throwable t) { threadUnexpectedException(t); } } public void await(Semaphore semaphore) { try { assertTrue(semaphore.tryAcquire(LONG_DELAY_MS, MILLISECONDS)); } catch (Throwable t) { threadUnexpectedException(t); } } // /** // * Spin-waits up to LONG_DELAY_MS until flag becomes true. // */ // public void await(AtomicBoolean flag) { // await(flag, LONG_DELAY_MS); // } // /** // * Spin-waits up to the specified timeout until flag becomes true. // */ // public void await(AtomicBoolean flag, long timeoutMillis) { // long startTime = System.nanoTime(); // while (!flag.get()) { // if (millisElapsedSince(startTime) > timeoutMillis) // throw new AssertionFailedError("timed out"); // Thread.yield(); // } // } public static class NPETask implements Callable<String> { public String call() { throw new NullPointerException(); } } public static class CallableOne implements Callable<Integer> { public Integer call() { return one; } } public class ShortRunnable extends CheckedRunnable { protected void realRun() throws Throwable { delay(SHORT_DELAY_MS); } } public class ShortInterruptedRunnable extends CheckedInterruptedRunnable { protected void realRun() throws InterruptedException { delay(SHORT_DELAY_MS); } } public class SmallRunnable extends CheckedRunnable { protected void realRun() throws Throwable { delay(SMALL_DELAY_MS); } } public class SmallPossiblyInterruptedRunnable extends CheckedRunnable { protected void realRun() { try { delay(SMALL_DELAY_MS); } catch (InterruptedException ok) {} } } public class SmallCallable extends CheckedCallable { protected Object realCall() throws InterruptedException { delay(SMALL_DELAY_MS); return Boolean.TRUE; } } public class MediumRunnable extends CheckedRunnable { protected void realRun() throws Throwable { delay(MEDIUM_DELAY_MS); } } public class MediumInterruptedRunnable extends CheckedInterruptedRunnable { protected void realRun() throws InterruptedException { delay(MEDIUM_DELAY_MS); } } public Runnable possiblyInterruptedRunnable(final long timeoutMillis) { return new CheckedRunnable() { protected void realRun() { try { delay(timeoutMillis); } catch (InterruptedException ok) {} }}; } public class MediumPossiblyInterruptedRunnable extends CheckedRunnable { protected void realRun() { try { delay(MEDIUM_DELAY_MS); } catch (InterruptedException ok) {} } } public class LongPossiblyInterruptedRunnable extends CheckedRunnable { protected void realRun() { try { delay(LONG_DELAY_MS); } catch (InterruptedException ok) {} } } /** * For use as ThreadFactory in constructors */ public static class SimpleThreadFactory implements ThreadFactory { public Thread newThread(Runnable r) { return new Thread(r); } } public interface TrackedRunnable extends Runnable { boolean isDone(); } public static TrackedRunnable trackedRunnable(final long timeoutMillis) { return new TrackedRunnable() { private volatile boolean done = false; public boolean isDone() { return done; } public void run() { try { delay(timeoutMillis); done = true; } catch (InterruptedException ok) {} } }; } public static class TrackedShortRunnable implements Runnable { public volatile boolean done = false; public void run() { try { delay(SHORT_DELAY_MS); done = true; } catch (InterruptedException ok) {} } } public static class TrackedSmallRunnable implements Runnable { public volatile boolean done = false; public void run() { try { delay(SMALL_DELAY_MS); done = true; } catch (InterruptedException ok) {} } } public static class TrackedMediumRunnable implements Runnable { public volatile boolean done = false; public void run() { try { delay(MEDIUM_DELAY_MS); done = true; } catch (InterruptedException ok) {} } } public static class TrackedLongRunnable implements Runnable { public volatile boolean done = false; public void run() { try { delay(LONG_DELAY_MS); done = true; } catch (InterruptedException ok) {} } } public static class TrackedNoOpRunnable implements Runnable { public volatile boolean done = false; public void run() { done = true; } } public static class TrackedCallable implements Callable { public volatile boolean done = false; public Object call() { try { delay(SMALL_DELAY_MS); done = true; } catch (InterruptedException ok) {} return Boolean.TRUE; } } // /** // * Analog of CheckedRunnable for RecursiveAction // */ // public abstract class CheckedRecursiveAction extends RecursiveAction { // protected abstract void realCompute() throws Throwable; // public final void compute() { // try { // realCompute(); // } catch (Throwable t) { // threadUnexpectedException(t); // } // } // } // /** // * Analog of CheckedCallable for RecursiveTask // */ // public abstract class CheckedRecursiveTask<T> extends RecursiveTask<T> { // protected abstract T realCompute() throws Throwable; // public final T compute() { // try { // return realCompute(); // } catch (Throwable t) { // threadUnexpectedException(t); // return null; // } // } // } /** * For use as RejectedExecutionHandler in constructors */ public static class NoOpREHandler implements RejectedExecutionHandler { public void rejectedExecution(Runnable r, ThreadPoolExecutor executor) {} } /** * A CyclicBarrier that uses timed await and fails with * AssertionFailedErrors instead of throwing checked exceptions. */ public class CheckedBarrier extends CyclicBarrier { public CheckedBarrier(int parties) { super(parties); } public int await() { try { return super.await(2 * LONG_DELAY_MS, MILLISECONDS); } catch (TimeoutException e) { throw new AssertionFailedError("timed out"); } catch (Exception e) { AssertionFailedError afe = new AssertionFailedError("Unexpected exception: " + e); afe.initCause(e); throw afe; } } } void checkEmpty(BlockingQueue q) { try { assertTrue(q.isEmpty()); assertEquals(0, q.size()); assertNull(q.peek()); assertNull(q.poll()); assertNull(q.poll(0, MILLISECONDS)); assertEquals(q.toString(), "[]"); assertTrue(Arrays.equals(q.toArray(), new Object[0])); assertFalse(q.iterator().hasNext()); try { q.element(); shouldThrow(); } catch (NoSuchElementException success) {} try { q.iterator().next(); shouldThrow(); } catch (NoSuchElementException success) {} try { q.remove(); shouldThrow(); } catch (NoSuchElementException success) {} } catch (InterruptedException ie) { threadUnexpectedException(ie); } } @SuppressWarnings("unchecked") <T> T serialClone(T o) { try { ByteArrayOutputStream bos = new ByteArrayOutputStream(); ObjectOutputStream oos = new ObjectOutputStream(bos); oos.writeObject(o); oos.flush(); oos.close(); ObjectInputStream ois = new ObjectInputStream (new ByteArrayInputStream(bos.toByteArray())); T clone = (T) ois.readObject(); assertSame(o.getClass(), clone.getClass()); return clone; } catch (Throwable t) { threadUnexpectedException(t); return null; } } }