/* * Copyright (c) 1994, 2018, Oracle and/or its affiliates. All rights reserved. * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. * * This code is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License version 2 only, as * published by the Free Software Foundation. Oracle designates this * particular file as subject to the "Classpath" exception as provided * by Oracle in the LICENSE file that accompanied this code. * * This code is distributed in the hope that it will be useful, but WITHOUT * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License * version 2 for more details (a copy is included in the LICENSE file that * accompanied this code). * * You should have received a copy of the GNU General Public License version * 2 along with this work; if not, write to the Free Software Foundation, * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. * * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA * or visit www.oracle.com if you need additional information or have any * questions. */ package java.lang; import java.lang.ref.Reference; import java.lang.ref.ReferenceQueue; import java.lang.ref.WeakReference; import java.security.AccessController; import java.security.AccessControlContext; import java.security.PrivilegedAction; import java.util.Map; import java.util.HashMap; import java.util.concurrent.ConcurrentHashMap; import java.util.concurrent.ConcurrentMap; import java.util.concurrent.locks.LockSupport; import sun.nio.ch.Interruptible; import jdk.internal.reflect.CallerSensitive; import jdk.internal.reflect.Reflection; import sun.security.util.SecurityConstants; import jdk.internal.HotSpotIntrinsicCandidate; /** * A thread is a thread of execution in a program. The Java * Virtual Machine allows an application to have multiple threads of * execution running concurrently. *

* Every thread has a priority. Threads with higher priority are * executed in preference to threads with lower priority. Each thread * may or may not also be marked as a daemon. When code running in * some thread creates a new {@code Thread} object, the new * thread has its priority initially set equal to the priority of the * creating thread, and is a daemon thread if and only if the * creating thread is a daemon. *

* When a Java Virtual Machine starts up, there is usually a single * non-daemon thread (which typically calls the method named * {@code main} of some designated class). The Java Virtual * Machine continues to execute threads until either of the following * occurs: *

*

* There are two ways to create a new thread of execution. One is to * declare a class to be a subclass of {@code Thread}. This * subclass should override the {@code run} method of class * {@code Thread}. An instance of the subclass can then be * allocated and started. For example, a thread that computes primes * larger than a stated value could be written as follows: * 

 *     class PrimeThread extends Thread {
 *         long minPrime;
 *         PrimeThread(long minPrime) {
 *             this.minPrime = minPrime;
 *         }
 *
 *         public void run() {
 *             // compute primes larger than minPrime
 *              . . .
 *         }
 *     }
 *
*

* The following code would then create a thread and start it running: * 

 *     PrimeThread p = new PrimeThread(143);
 *     p.start();
 *
*

* The other way to create a thread is to declare a class that * implements the {@code Runnable} interface. That class then * implements the {@code run} method. An instance of the class can * then be allocated, passed as an argument when creating * {@code Thread}, and started. The same example in this other * style looks like the following: * 

 *     class PrimeRun implements Runnable {
 *         long minPrime;
 *         PrimeRun(long minPrime) {
 *             this.minPrime = minPrime;
 *         }
 *
 *         public void run() {
 *             // compute primes larger than minPrime
 *              . . .
 *         }
 *     }
 *
*

* The following code would then create a thread and start it running: * 

 *     PrimeRun p = new PrimeRun(143);
 *     new Thread(p).start();
 *
*

* Every thread has a name for identification purposes. More than * one thread may have the same name. If a name is not specified when * a thread is created, a new name is generated for it. *

* Unless otherwise noted, passing a {@code null} argument to a constructor * or method in this class will cause a {@link NullPointerException} to be * thrown. * * @author unascribed * @see Runnable * @see Runtime#exit(int) * @see #run() * @see #stop() * @since 1.0 */ public class Thread implements Runnable { /* Make sure registerNatives is the first thing does. */ private static native void registerNatives(); static { registerNatives(); } private volatile String name; private int priority; /* Whether or not the thread is a daemon thread. */ private boolean daemon = false; /* Fields reserved for exclusive use by the JVM */ private boolean stillborn = false; private long eetop; /* What will be run. */ private Runnable target; /* The group of this thread */ private ThreadGroup group; /* The context ClassLoader for this thread */ private ClassLoader contextClassLoader; /* The inherited AccessControlContext of this thread */ private AccessControlContext inheritedAccessControlContext; /* For autonumbering anonymous threads. */ private static int threadInitNumber; private static synchronized int nextThreadNum() { return threadInitNumber++; } /* ThreadLocal values pertaining to this thread. This map is maintained * by the ThreadLocal class. */ ThreadLocal.ThreadLocalMap threadLocals = null; /* * InheritableThreadLocal values pertaining to this thread. This map is * maintained by the InheritableThreadLocal class. */ ThreadLocal.ThreadLocalMap inheritableThreadLocals = null; /* * The requested stack size for this thread, or 0 if the creator did * not specify a stack size. It is up to the VM to do whatever it * likes with this number; some VMs will ignore it. */ private long stackSize; /* * JVM-private state that persists after native thread termination. */ private long nativeParkEventPointer; /* * Thread ID */ private long tid; /* For generating thread ID */ private static long threadSeqNumber; /* * Java thread status for tools, default indicates thread 'not yet started' */ private volatile int threadStatus; private static synchronized long nextThreadID() { return ++threadSeqNumber; } /** * The argument supplied to the current call to * java.util.concurrent.locks.LockSupport.park. * Set by (private) java.util.concurrent.locks.LockSupport.setBlocker * Accessed using java.util.concurrent.locks.LockSupport.getBlocker */ volatile Object parkBlocker; /* The object in which this thread is blocked in an interruptible I/O * operation, if any. The blocker's interrupt method should be invoked * after setting this thread's interrupt status. */ private volatile Interruptible blocker; private final Object blockerLock = new Object(); /* Set the blocker field; invoked via jdk.internal.misc.SharedSecrets * from java.nio code */ static void blockedOn(Interruptible b) { Thread me = Thread.currentThread(); synchronized (me.blockerLock) { me.blocker = b; } } /** * The minimum priority that a thread can have. */ public static final int MIN_PRIORITY = 1; /** * The default priority that is assigned to a thread. */ public static final int NORM_PRIORITY = 5; /** * The maximum priority that a thread can have. */ public static final int MAX_PRIORITY = 10; /** * Returns a reference to the currently executing thread object. * * @return the currently executing thread. */ @HotSpotIntrinsicCandidate public static native Thread currentThread(); /** * A hint to the scheduler that the current thread is willing to yield * its current use of a processor. The scheduler is free to ignore this * hint. * *

Yield is a heuristic attempt to improve relative progression * between threads that would otherwise over-utilise a CPU. Its use * should be combined with detailed profiling and benchmarking to * ensure that it actually has the desired effect. * *

It is rarely appropriate to use this method. It may be useful * for debugging or testing purposes, where it may help to reproduce * bugs due to race conditions. It may also be useful when designing * concurrency control constructs such as the ones in the * {@link java.util.concurrent.locks} package. */ public static native void yield(); /** * Causes the currently executing thread to sleep (temporarily cease * execution) for the specified number of milliseconds, subject to * the precision and accuracy of system timers and schedulers. The thread * does not lose ownership of any monitors. * * @param millis * the length of time to sleep in milliseconds * * @throws IllegalArgumentException * if the value of {@code millis} is negative * * @throws InterruptedException * if any thread has interrupted the current thread. The * interrupted status of the current thread is * cleared when this exception is thrown. */ public static native void sleep(long millis) throws InterruptedException; /** * Causes the currently executing thread to sleep (temporarily cease * execution) for the specified number of milliseconds plus the specified * number of nanoseconds, subject to the precision and accuracy of system * timers and schedulers. The thread does not lose ownership of any * monitors. * * @param millis * the length of time to sleep in milliseconds * * @param nanos * {@code 0-999999} additional nanoseconds to sleep * * @throws IllegalArgumentException * if the value of {@code millis} is negative, or the value of * {@code nanos} is not in the range {@code 0-999999} * * @throws InterruptedException * if any thread has interrupted the current thread. The * interrupted status of the current thread is * cleared when this exception is thrown. */ public static void sleep(long millis, int nanos) throws InterruptedException { if (millis < 0) { throw new IllegalArgumentException("timeout value is negative"); } if (nanos < 0 || nanos > 999999) { throw new IllegalArgumentException( "nanosecond timeout value out of range"); } if (nanos >= 500000 || (nanos != 0 && millis == 0)) { millis++; } sleep(millis); } /** * Indicates that the caller is momentarily unable to progress, until the * occurrence of one or more actions on the part of other activities. By * invoking this method within each iteration of a spin-wait loop construct, * the calling thread indicates to the runtime that it is busy-waiting. * The runtime may take action to improve the performance of invoking * spin-wait loop constructions. * * @apiNote * As an example consider a method in a class that spins in a loop until * some flag is set outside of that method. A call to the {@code onSpinWait} * method should be placed inside the spin loop. * 

{@code
     *     class EventHandler {
     *         volatile boolean eventNotificationNotReceived;
     *         void waitForEventAndHandleIt() {
     *             while ( eventNotificationNotReceived ) {
     *                 java.lang.Thread.onSpinWait();
     *             }
     *             readAndProcessEvent();
     *         }
     *
     *         void readAndProcessEvent() {
     *             // Read event from some source and process it
     *              . . .
     *         }
     *     }
     * }
*

* The code above would remain correct even if the {@code onSpinWait} * method was not called at all. However on some architectures the Java * Virtual Machine may issue the processor instructions to address such * code patterns in a more beneficial way. * * @since 9 */ @HotSpotIntrinsicCandidate public static void onSpinWait() {} /** * Initializes a Thread with the current AccessControlContext. * @see #init(ThreadGroup,Runnable,String,long,AccessControlContext,boolean) */ private void init(ThreadGroup g, Runnable target, String name, long stackSize) { init(g, target, name, stackSize, null, true); } /** * Initializes a Thread. * * @param g the Thread group * @param target the object whose run() method gets called * @param name the name of the new Thread * @param stackSize the desired stack size for the new thread, or * zero to indicate that this parameter is to be ignored. * @param acc the AccessControlContext to inherit, or * AccessController.getContext() if null * @param inheritThreadLocals if {@code true}, inherit initial values for * inheritable thread-locals from the constructing thread */ private void init(ThreadGroup g, Runnable target, String name, long stackSize, AccessControlContext acc, boolean inheritThreadLocals) { if (name == null) { throw new NullPointerException("name cannot be null"); } this.name = name; Thread parent = currentThread(); SecurityManager security = System.getSecurityManager(); if (g == null) { /* Determine if it's an applet or not */ /* If there is a security manager, ask the security manager what to do. */ if (security != null) { g = security.getThreadGroup(); } /* If the security doesn't have a strong opinion of the matter use the parent thread group. */ if (g == null) { g = parent.getThreadGroup(); } } /* checkAccess regardless of whether or not threadgroup is explicitly passed in. */ g.checkAccess(); /* * Do we have the required permissions? */ if (security != null) { if (isCCLOverridden(getClass())) { security.checkPermission(SUBCLASS_IMPLEMENTATION_PERMISSION); } } g.addUnstarted(); this.group = g; this.daemon = parent.isDaemon(); this.priority = parent.getPriority(); if (security == null || isCCLOverridden(parent.getClass())) this.contextClassLoader = parent.getContextClassLoader(); else this.contextClassLoader = parent.contextClassLoader; this.inheritedAccessControlContext = acc != null ? acc : AccessController.getContext(); this.target = target; setPriority(priority); if (inheritThreadLocals && parent.inheritableThreadLocals != null) this.inheritableThreadLocals = ThreadLocal.createInheritedMap(parent.inheritableThreadLocals); /* Stash the specified stack size in case the VM cares */ this.stackSize = stackSize; /* Set thread ID */ tid = nextThreadID(); } /** * Throws CloneNotSupportedException as a Thread can not be meaningfully * cloned. Construct a new Thread instead. * * @throws CloneNotSupportedException * always */ @Override protected Object clone() throws CloneNotSupportedException { throw new CloneNotSupportedException(); } /** * Allocates a new {@code Thread} object. This constructor has the same * effect as {@linkplain #Thread(ThreadGroup,Runnable,String) Thread} * {@code (null, null, gname)}, where {@code gname} is a newly generated * name. Automatically generated names are of the form * {@code "Thread-"+}n, where n is an integer. */ public Thread() { init(null, null, "Thread-" + nextThreadNum(), 0); } /** * Allocates a new {@code Thread} object. This constructor has the same * effect as {@linkplain #Thread(ThreadGroup,Runnable,String) Thread} * {@code (null, target, gname)}, where {@code gname} is a newly generated * name. Automatically generated names are of the form * {@code "Thread-"+}n, where n is an integer. * * @param target * the object whose {@code run} method is invoked when this thread * is started. If {@code null}, this classes {@code run} method does * nothing. */ public Thread(Runnable target) { init(null, target, "Thread-" + nextThreadNum(), 0); } /** * Creates a new Thread that inherits the given AccessControlContext * but thread-local variables are not inherited. * This is not a public constructor. */ Thread(Runnable target, AccessControlContext acc) { init(null, target, "Thread-" + nextThreadNum(), 0, acc, false); } /** * Allocates a new {@code Thread} object. This constructor has the same * effect as {@linkplain #Thread(ThreadGroup,Runnable,String) Thread} * {@code (group, target, gname)} ,where {@code gname} is a newly generated * name. Automatically generated names are of the form * {@code "Thread-"+}n, where n is an integer. * * @param group * the thread group. If {@code null} and there is a security * manager, the group is determined by {@linkplain * SecurityManager#getThreadGroup SecurityManager.getThreadGroup()}. * If there is not a security manager or {@code * SecurityManager.getThreadGroup()} returns {@code null}, the group * is set to the current thread's thread group. * * @param target * the object whose {@code run} method is invoked when this thread * is started. If {@code null}, this thread's run method is invoked. * * @throws SecurityException * if the current thread cannot create a thread in the specified * thread group */ public Thread(ThreadGroup group, Runnable target) { init(group, target, "Thread-" + nextThreadNum(), 0); } /** * Allocates a new {@code Thread} object. This constructor has the same * effect as {@linkplain #Thread(ThreadGroup,Runnable,String) Thread} * {@code (null, null, name)}. * * @param name * the name of the new thread */ public Thread(String name) { init(null, null, name, 0); } /** * Allocates a new {@code Thread} object. This constructor has the same * effect as {@linkplain #Thread(ThreadGroup,Runnable,String) Thread} * {@code (group, null, name)}. * * @param group * the thread group. If {@code null} and there is a security * manager, the group is determined by {@linkplain * SecurityManager#getThreadGroup SecurityManager.getThreadGroup()}. * If there is not a security manager or {@code * SecurityManager.getThreadGroup()} returns {@code null}, the group * is set to the current thread's thread group. * * @param name * the name of the new thread * * @throws SecurityException * if the current thread cannot create a thread in the specified * thread group */ public Thread(ThreadGroup group, String name) { init(group, null, name, 0); } /** * Allocates a new {@code Thread} object. This constructor has the same * effect as {@linkplain #Thread(ThreadGroup,Runnable,String) Thread} * {@code (null, target, name)}. * * @param target * the object whose {@code run} method is invoked when this thread * is started. If {@code null}, this thread's run method is invoked. * * @param name * the name of the new thread */ public Thread(Runnable target, String name) { init(null, target, name, 0); } /** * Allocates a new {@code Thread} object so that it has {@code target} * as its run object, has the specified {@code name} as its name, * and belongs to the thread group referred to by {@code group}. * *

If there is a security manager, its * {@link SecurityManager#checkAccess(ThreadGroup) checkAccess} * method is invoked with the ThreadGroup as its argument. * *

In addition, its {@code checkPermission} method is invoked with * the {@code RuntimePermission("enableContextClassLoaderOverride")} * permission when invoked directly or indirectly by the constructor * of a subclass which overrides the {@code getContextClassLoader} * or {@code setContextClassLoader} methods. * *

The priority of the newly created thread is set equal to the * priority of the thread creating it, that is, the currently running * thread. The method {@linkplain #setPriority setPriority} may be * used to change the priority to a new value. * *

The newly created thread is initially marked as being a daemon * thread if and only if the thread creating it is currently marked * as a daemon thread. The method {@linkplain #setDaemon setDaemon} * may be used to change whether or not a thread is a daemon. * * @param group * the thread group. If {@code null} and there is a security * manager, the group is determined by {@linkplain * SecurityManager#getThreadGroup SecurityManager.getThreadGroup()}. * If there is not a security manager or {@code * SecurityManager.getThreadGroup()} returns {@code null}, the group * is set to the current thread's thread group. * * @param target * the object whose {@code run} method is invoked when this thread * is started. If {@code null}, this thread's run method is invoked. * * @param name * the name of the new thread * * @throws SecurityException * if the current thread cannot create a thread in the specified * thread group or cannot override the context class loader methods. */ public Thread(ThreadGroup group, Runnable target, String name) { init(group, target, name, 0); } /** * Allocates a new {@code Thread} object so that it has {@code target} * as its run object, has the specified {@code name} as its name, * and belongs to the thread group referred to by {@code group}, and has * the specified stack size. * *

This constructor is identical to {@link * #Thread(ThreadGroup,Runnable,String)} with the exception of the fact * that it allows the thread stack size to be specified. The stack size * is the approximate number of bytes of address space that the virtual * machine is to allocate for this thread's stack. The effect of the * {@code stackSize} parameter, if any, is highly platform dependent. * *

On some platforms, specifying a higher value for the * {@code stackSize} parameter may allow a thread to achieve greater * recursion depth before throwing a {@link StackOverflowError}. * Similarly, specifying a lower value may allow a greater number of * threads to exist concurrently without throwing an {@link * OutOfMemoryError} (or other internal error). The details of * the relationship between the value of the {@code stackSize} parameter * and the maximum recursion depth and concurrency level are * platform-dependent. On some platforms, the value of the * {@code stackSize} parameter may have no effect whatsoever. * *

The virtual machine is free to treat the {@code stackSize} * parameter as a suggestion. If the specified value is unreasonably low * for the platform, the virtual machine may instead use some * platform-specific minimum value; if the specified value is unreasonably * high, the virtual machine may instead use some platform-specific * maximum. Likewise, the virtual machine is free to round the specified * value up or down as it sees fit (or to ignore it completely). * *

Specifying a value of zero for the {@code stackSize} parameter will * cause this constructor to behave exactly like the * {@code Thread(ThreadGroup, Runnable, String)} constructor. * *

Due to the platform-dependent nature of the behavior of this * constructor, extreme care should be exercised in its use. * The thread stack size necessary to perform a given computation will * likely vary from one JRE implementation to another. In light of this * variation, careful tuning of the stack size parameter may be required, * and the tuning may need to be repeated for each JRE implementation on * which an application is to run. * *

Implementation note: Java platform implementers are encouraged to * document their implementation's behavior with respect to the * {@code stackSize} parameter. * * * @param group * the thread group. If {@code null} and there is a security * manager, the group is determined by {@linkplain * SecurityManager#getThreadGroup SecurityManager.getThreadGroup()}. * If there is not a security manager or {@code * SecurityManager.getThreadGroup()} returns {@code null}, the group * is set to the current thread's thread group. * * @param target * the object whose {@code run} method is invoked when this thread * is started. If {@code null}, this thread's run method is invoked. * * @param name * the name of the new thread * * @param stackSize * the desired stack size for the new thread, or zero to indicate * that this parameter is to be ignored. * * @throws SecurityException * if the current thread cannot create a thread in the specified * thread group * * @since 1.4 */ public Thread(ThreadGroup group, Runnable target, String name, long stackSize) { init(group, target, name, stackSize); } /** * Allocates a new {@code Thread} object so that it has {@code target} * as its run object, has the specified {@code name} as its name, * belongs to the thread group referred to by {@code group}, has * the specified {@code stackSize}, and inherits initial values for * {@linkplain InheritableThreadLocal inheritable thread-local} variables * if {@code inheritThreadLocals} is {@code true}. * *

This constructor is identical to {@link * #Thread(ThreadGroup,Runnable,String,long)} with the added ability to * suppress, or not, the inheriting of initial values for inheritable * thread-local variables from the constructing thread. This allows for * finer grain control over inheritable thread-locals. Care must be taken * when passing a value of {@code false} for {@code inheritThreadLocals}, * as it may lead to unexpected behavior if the new thread executes code * that expects a specific thread-local value to be inherited. * *

Specifying a value of {@code true} for the {@code inheritThreadLocals} * parameter will cause this constructor to behave exactly like the * {@code Thread(ThreadGroup, Runnable, String, long)} constructor. * * @param group * the thread group. If {@code null} and there is a security * manager, the group is determined by {@linkplain * SecurityManager#getThreadGroup SecurityManager.getThreadGroup()}. * If there is not a security manager or {@code * SecurityManager.getThreadGroup()} returns {@code null}, the group * is set to the current thread's thread group. * * @param target * the object whose {@code run} method is invoked when this thread * is started. If {@code null}, this thread's run method is invoked. * * @param name * the name of the new thread * * @param stackSize * the desired stack size for the new thread, or zero to indicate * that this parameter is to be ignored * * @param inheritThreadLocals * if {@code true}, inherit initial values for inheritable * thread-locals from the constructing thread, otherwise no initial * values are inherited * * @throws SecurityException * if the current thread cannot create a thread in the specified * thread group * * @since 9 */ public Thread(ThreadGroup group, Runnable target, String name, long stackSize, boolean inheritThreadLocals) { init(group, target, name, stackSize, null, inheritThreadLocals); } /** * Causes this thread to begin execution; the Java Virtual Machine * calls the {@code run} method of this thread. *

* The result is that two threads are running concurrently: the * current thread (which returns from the call to the * {@code start} method) and the other thread (which executes its * {@code run} method). *

* It is never legal to start a thread more than once. * In particular, a thread may not be restarted once it has completed * execution. * * @throws IllegalThreadStateException if the thread was already started. * @see #run() * @see #stop() */ public synchronized void start() { /** * This method is not invoked for the main method thread or "system" * group threads created/set up by the VM. Any new functionality added * to this method in the future may have to also be added to the VM. * * A zero status value corresponds to state "NEW". */ if (threadStatus != 0) throw new IllegalThreadStateException(); /* Notify the group that this thread is about to be started * so that it can be added to the group's list of threads * and the group's unstarted count can be decremented. */ group.add(this); boolean started = false; try { start0(); started = true; } finally { try { if (!started) { group.threadStartFailed(this); } } catch (Throwable ignore) { /* do nothing. If start0 threw a Throwable then it will be passed up the call stack */ } } } private native void start0(); /** * If this thread was constructed using a separate * {@code Runnable} run object, then that * {@code Runnable} object's {@code run} method is called; * otherwise, this method does nothing and returns. *

* Subclasses of {@code Thread} should override this method. * * @see #start() * @see #stop() * @see #Thread(ThreadGroup, Runnable, String) */ @Override public void run() { if (target != null) { target.run(); } } /** * This method is called by the system to give a Thread * a chance to clean up before it actually exits. */ private void exit() { if (group != null) { group.threadTerminated(this); group = null; } /* Aggressively null out all reference fields: see bug 4006245 */ target = null; /* Speed the release of some of these resources */ threadLocals = null; inheritableThreadLocals = null; inheritedAccessControlContext = null; blocker = null; uncaughtExceptionHandler = null; } /** * Forces the thread to stop executing. *

* If there is a security manager installed, its {@code checkAccess} * method is called with {@code this} * as its argument. This may result in a * {@code SecurityException} being raised (in the current thread). *

* If this thread is different from the current thread (that is, the current * thread is trying to stop a thread other than itself), the * security manager's {@code checkPermission} method (with a * {@code RuntimePermission("stopThread")} argument) is called in * addition. * Again, this may result in throwing a * {@code SecurityException} (in the current thread). *

* The thread represented by this thread is forced to stop whatever * it is doing abnormally and to throw a newly created * {@code ThreadDeath} object as an exception. *

* It is permitted to stop a thread that has not yet been started. * If the thread is eventually started, it immediately terminates. *

* An application should not normally try to catch * {@code ThreadDeath} unless it must do some extraordinary * cleanup operation (note that the throwing of * {@code ThreadDeath} causes {@code finally} clauses of * {@code try} statements to be executed before the thread * officially dies). If a {@code catch} clause catches a * {@code ThreadDeath} object, it is important to rethrow the * object so that the thread actually dies. *

* The top-level error handler that reacts to otherwise uncaught * exceptions does not print out a message or otherwise notify the * application if the uncaught exception is an instance of * {@code ThreadDeath}. * * @throws SecurityException if the current thread cannot * modify this thread. * @see #interrupt() * @see #checkAccess() * @see #run() * @see #start() * @see ThreadDeath * @see ThreadGroup#uncaughtException(Thread,Throwable) * @see SecurityManager#checkAccess(Thread) * @see SecurityManager#checkPermission * @deprecated This method is inherently unsafe. Stopping a thread with * Thread.stop causes it to unlock all of the monitors that it * has locked (as a natural consequence of the unchecked * {@code ThreadDeath} exception propagating up the stack). If * any of the objects previously protected by these monitors were in * an inconsistent state, the damaged objects become visible to * other threads, potentially resulting in arbitrary behavior. Many * uses of {@code stop} should be replaced by code that simply * modifies some variable to indicate that the target thread should * stop running. The target thread should check this variable * regularly, and return from its run method in an orderly fashion * if the variable indicates that it is to stop running. If the * target thread waits for long periods (on a condition variable, * for example), the {@code interrupt} method should be used to * interrupt the wait. * For more information, see * Why * are Thread.stop, Thread.suspend and Thread.resume Deprecated?. */ @Deprecated(since="1.2") public final void stop() { SecurityManager security = System.getSecurityManager(); if (security != null) { checkAccess(); if (this != Thread.currentThread()) { security.checkPermission(SecurityConstants.STOP_THREAD_PERMISSION); } } // A zero status value corresponds to "NEW", it can't change to // not-NEW because we hold the lock. if (threadStatus != 0) { resume(); // Wake up thread if it was suspended; no-op otherwise } // The VM can handle all thread states stop0(new ThreadDeath()); } /** * Throws {@code UnsupportedOperationException}. * * @param obj ignored * * @deprecated This method was originally designed to force a thread to stop * and throw a given {@code Throwable} as an exception. It was * inherently unsafe (see {@link #stop()} for details), and furthermore * could be used to generate exceptions that the target thread was * not prepared to handle. * For more information, see * Why * are Thread.stop, Thread.suspend and Thread.resume Deprecated?. * This method is subject to removal in a future version of Java SE. */ @Deprecated(since="1.2", forRemoval=true) public final synchronized void stop(Throwable obj) { throw new UnsupportedOperationException(); } /** * Interrupts this thread. * *

Unless the current thread is interrupting itself, which is * always permitted, the {@link #checkAccess() checkAccess} method * of this thread is invoked, which may cause a {@link * SecurityException} to be thrown. * *

If this thread is blocked in an invocation of the {@link * Object#wait() wait()}, {@link Object#wait(long) wait(long)}, or {@link * Object#wait(long, int) wait(long, int)} methods of the {@link Object} * class, or of the {@link #join()}, {@link #join(long)}, {@link * #join(long, int)}, {@link #sleep(long)}, or {@link #sleep(long, int)}, * methods of this class, then its interrupt status will be cleared and it * will receive an {@link InterruptedException}. * *

If this thread is blocked in an I/O operation upon an {@link * java.nio.channels.InterruptibleChannel InterruptibleChannel} * then the channel will be closed, the thread's interrupt * status will be set, and the thread will receive a {@link * java.nio.channels.ClosedByInterruptException}. * *

If this thread is blocked in a {@link java.nio.channels.Selector} * then the thread's interrupt status will be set and it will return * immediately from the selection operation, possibly with a non-zero * value, just as if the selector's {@link * java.nio.channels.Selector#wakeup wakeup} method were invoked. * *

If none of the previous conditions hold then this thread's interrupt * status will be set.

* *

Interrupting a thread that is not alive need not have any effect. * * @throws SecurityException * if the current thread cannot modify this thread * * @revised 6.0 * @spec JSR-51 */ public void interrupt() { if (this != Thread.currentThread()) { checkAccess(); // thread may be blocked in an I/O operation synchronized (blockerLock) { Interruptible b = blocker; if (b != null) { interrupt0(); // set interrupt status b.interrupt(this); return; } } } // set interrupt status interrupt0(); } /** * Tests whether the current thread has been interrupted. The * interrupted status of the thread is cleared by this method. In * other words, if this method were to be called twice in succession, the * second call would return false (unless the current thread were * interrupted again, after the first call had cleared its interrupted * status and before the second call had examined it). * *

A thread interruption ignored because a thread was not alive * at the time of the interrupt will be reflected by this method * returning false. * * @return {@code true} if the current thread has been interrupted; * {@code false} otherwise. * @see #isInterrupted() * @revised 6.0 */ public static boolean interrupted() { return currentThread().isInterrupted(true); } /** * Tests whether this thread has been interrupted. The interrupted * status of the thread is unaffected by this method. * *

A thread interruption ignored because a thread was not alive * at the time of the interrupt will be reflected by this method * returning false. * * @return {@code true} if this thread has been interrupted; * {@code false} otherwise. * @see #interrupted() * @revised 6.0 */ public boolean isInterrupted() { return isInterrupted(false); } /** * Tests if some Thread has been interrupted. The interrupted state * is reset or not based on the value of ClearInterrupted that is * passed. */ @HotSpotIntrinsicCandidate private native boolean isInterrupted(boolean ClearInterrupted); /** * Throws {@link NoSuchMethodError}. * * @deprecated This method was originally designed to destroy this * thread without any cleanup. Any monitors it held would have * remained locked. However, the method was never implemented. * If it were to be implemented, it would be deadlock-prone in * much the manner of {@link #suspend}. If the target thread held * a lock protecting a critical system resource when it was * destroyed, no thread could ever access this resource again. * If another thread ever attempted to lock this resource, deadlock * would result. Such deadlocks typically manifest themselves as * "frozen" processes. For more information, see * * Why are Thread.stop, Thread.suspend and Thread.resume Deprecated?. * This method is subject to removal in a future version of Java SE. * @throws NoSuchMethodError always */ @Deprecated(since="1.5", forRemoval=true) public void destroy() { throw new NoSuchMethodError(); } /** * Tests if this thread is alive. A thread is alive if it has * been started and has not yet died. * * @return {@code true} if this thread is alive; * {@code false} otherwise. */ public final native boolean isAlive(); /** * Suspends this thread. *

* First, the {@code checkAccess} method of this thread is called * with no arguments. This may result in throwing a * {@code SecurityException }(in the current thread). *

* If the thread is alive, it is suspended and makes no further * progress unless and until it is resumed. * * @throws SecurityException if the current thread cannot modify * this thread. * @see #checkAccess * @deprecated This method has been deprecated, as it is * inherently deadlock-prone. If the target thread holds a lock on the * monitor protecting a critical system resource when it is suspended, no * thread can access this resource until the target thread is resumed. If * the thread that would resume the target thread attempts to lock this * monitor prior to calling {@code resume}, deadlock results. Such * deadlocks typically manifest themselves as "frozen" processes. * For more information, see * Why * are Thread.stop, Thread.suspend and Thread.resume Deprecated?. */ @Deprecated(since="1.2") public final void suspend() { checkAccess(); suspend0(); } /** * Resumes a suspended thread. *

* First, the {@code checkAccess} method of this thread is called * with no arguments. This may result in throwing a * {@code SecurityException} (in the current thread). *

* If the thread is alive but suspended, it is resumed and is * permitted to make progress in its execution. * * @throws SecurityException if the current thread cannot modify this * thread. * @see #checkAccess * @see #suspend() * @deprecated This method exists solely for use with {@link #suspend}, * which has been deprecated because it is deadlock-prone. * For more information, see * Why * are Thread.stop, Thread.suspend and Thread.resume Deprecated?. */ @Deprecated(since="1.2") public final void resume() { checkAccess(); resume0(); } /** * Changes the priority of this thread. *

* First the {@code checkAccess} method of this thread is called * with no arguments. This may result in throwing a {@code SecurityException}. *

* Otherwise, the priority of this thread is set to the smaller of * the specified {@code newPriority} and the maximum permitted * priority of the thread's thread group. * * @param newPriority priority to set this thread to * @throws IllegalArgumentException If the priority is not in the * range {@code MIN_PRIORITY} to * {@code MAX_PRIORITY}. * @throws SecurityException if the current thread cannot modify * this thread. * @see #getPriority * @see #checkAccess() * @see #getThreadGroup() * @see #MAX_PRIORITY * @see #MIN_PRIORITY * @see ThreadGroup#getMaxPriority() */ public final void setPriority(int newPriority) { ThreadGroup g; checkAccess(); if (newPriority > MAX_PRIORITY || newPriority < MIN_PRIORITY) { throw new IllegalArgumentException(); } if((g = getThreadGroup()) != null) { if (newPriority > g.getMaxPriority()) { newPriority = g.getMaxPriority(); } setPriority0(priority = newPriority); } } /** * Returns this thread's priority. * * @return this thread's priority. * @see #setPriority */ public final int getPriority() { return priority; } /** * Changes the name of this thread to be equal to the argument {@code name}. *

* First the {@code checkAccess} method of this thread is called * with no arguments. This may result in throwing a * {@code SecurityException}. * * @param name the new name for this thread. * @throws SecurityException if the current thread cannot modify this * thread. * @see #getName * @see #checkAccess() */ public final synchronized void setName(String name) { checkAccess(); if (name == null) { throw new NullPointerException("name cannot be null"); } this.name = name; if (threadStatus != 0) { setNativeName(name); } } /** * Returns this thread's name. * * @return this thread's name. * @see #setName(String) */ public final String getName() { return name; } /** * Returns the thread group to which this thread belongs. * This method returns null if this thread has died * (been stopped). * * @return this thread's thread group. */ public final ThreadGroup getThreadGroup() { return group; } /** * Returns an estimate of the number of active threads in the current * thread's {@linkplain java.lang.ThreadGroup thread group} and its * subgroups. Recursively iterates over all subgroups in the current * thread's thread group. * *

The value returned is only an estimate because the number of * threads may change dynamically while this method traverses internal * data structures, and might be affected by the presence of certain * system threads. This method is intended primarily for debugging * and monitoring purposes. * * @return an estimate of the number of active threads in the current * thread's thread group and in any other thread group that * has the current thread's thread group as an ancestor */ public static int activeCount() { return currentThread().getThreadGroup().activeCount(); } /** * Copies into the specified array every active thread in the current * thread's thread group and its subgroups. This method simply * invokes the {@link java.lang.ThreadGroup#enumerate(Thread[])} * method of the current thread's thread group. * *

An application might use the {@linkplain #activeCount activeCount} * method to get an estimate of how big the array should be, however * if the array is too short to hold all the threads, the extra threads * are silently ignored. If it is critical to obtain every active * thread in the current thread's thread group and its subgroups, the * invoker should verify that the returned int value is strictly less * than the length of {@code tarray}. * *

Due to the inherent race condition in this method, it is recommended * that the method only be used for debugging and monitoring purposes. * * @param tarray * an array into which to put the list of threads * * @return the number of threads put into the array * * @throws SecurityException * if {@link java.lang.ThreadGroup#checkAccess} determines that * the current thread cannot access its thread group */ public static int enumerate(Thread tarray[]) { return currentThread().getThreadGroup().enumerate(tarray); } /** * Counts the number of stack frames in this thread. The thread must * be suspended. * * @return the number of stack frames in this thread. * @throws IllegalThreadStateException if this thread is not * suspended. * @deprecated The definition of this call depends on {@link #suspend}, * which is deprecated. Further, the results of this call * were never well-defined. * This method is subject to removal in a future version of Java SE. * @see StackWalker */ @Deprecated(since="1.2", forRemoval=true) public native int countStackFrames(); /** * Waits at most {@code millis} milliseconds for this thread to * die. A timeout of {@code 0} means to wait forever. * *

This implementation uses a loop of {@code this.wait} calls * conditioned on {@code this.isAlive}. As a thread terminates the * {@code this.notifyAll} method is invoked. It is recommended that * applications not use {@code wait}, {@code notify}, or * {@code notifyAll} on {@code Thread} instances. * * @param millis * the time to wait in milliseconds * * @throws IllegalArgumentException * if the value of {@code millis} is negative * * @throws InterruptedException * if any thread has interrupted the current thread. The * interrupted status of the current thread is * cleared when this exception is thrown. */ public final synchronized void join(long millis) throws InterruptedException { long base = System.currentTimeMillis(); long now = 0; if (millis < 0) { throw new IllegalArgumentException("timeout value is negative"); } if (millis == 0) { while (isAlive()) { wait(0); } } else { while (isAlive()) { long delay = millis - now; if (delay <= 0) { break; } wait(delay); now = System.currentTimeMillis() - base; } } } /** * Waits at most {@code millis} milliseconds plus * {@code nanos} nanoseconds for this thread to die. * *

This implementation uses a loop of {@code this.wait} calls * conditioned on {@code this.isAlive}. As a thread terminates the * {@code this.notifyAll} method is invoked. It is recommended that * applications not use {@code wait}, {@code notify}, or * {@code notifyAll} on {@code Thread} instances. * * @param millis * the time to wait in milliseconds * * @param nanos * {@code 0-999999} additional nanoseconds to wait * * @throws IllegalArgumentException * if the value of {@code millis} is negative, or the value * of {@code nanos} is not in the range {@code 0-999999} * * @throws InterruptedException * if any thread has interrupted the current thread. The * interrupted status of the current thread is * cleared when this exception is thrown. */ public final synchronized void join(long millis, int nanos) throws InterruptedException { if (millis < 0) { throw new IllegalArgumentException("timeout value is negative"); } if (nanos < 0 || nanos > 999999) { throw new IllegalArgumentException( "nanosecond timeout value out of range"); } if (nanos >= 500000 || (nanos != 0 && millis == 0)) { millis++; } join(millis); } /** * Waits for this thread to die. * *

An invocation of this method behaves in exactly the same * way as the invocation * *

* {@linkplain #join(long) join}{@code (0)} *
* * @throws InterruptedException * if any thread has interrupted the current thread. The * interrupted status of the current thread is * cleared when this exception is thrown. */ public final void join() throws InterruptedException { join(0); } /** * Prints a stack trace of the current thread to the standard error stream. * This method is used only for debugging. */ public static void dumpStack() { new Exception("Stack trace").printStackTrace(); } /** * Marks this thread as either a {@linkplain #isDaemon daemon} thread * or a user thread. The Java Virtual Machine exits when the only * threads running are all daemon threads. * *

This method must be invoked before the thread is started. * * @param on * if {@code true}, marks this thread as a daemon thread * * @throws IllegalThreadStateException * if this thread is {@linkplain #isAlive alive} * * @throws SecurityException * if {@link #checkAccess} determines that the current * thread cannot modify this thread */ public final void setDaemon(boolean on) { checkAccess(); if (isAlive()) { throw new IllegalThreadStateException(); } daemon = on; } /** * Tests if this thread is a daemon thread. * * @return {@code true} if this thread is a daemon thread; * {@code false} otherwise. * @see #setDaemon(boolean) */ public final boolean isDaemon() { return daemon; } /** * Determines if the currently running thread has permission to * modify this thread. *

* If there is a security manager, its {@code checkAccess} method * is called with this thread as its argument. This may result in * throwing a {@code SecurityException}. * * @throws SecurityException if the current thread is not allowed to * access this thread. * @see SecurityManager#checkAccess(Thread) */ public final void checkAccess() { SecurityManager security = System.getSecurityManager(); if (security != null) { security.checkAccess(this); } } /** * Returns a string representation of this thread, including the * thread's name, priority, and thread group. * * @return a string representation of this thread. */ public String toString() { ThreadGroup group = getThreadGroup(); if (group != null) { return "Thread[" + getName() + "," + getPriority() + "," + group.getName() + "]"; } else { return "Thread[" + getName() + "," + getPriority() + "," + "" + "]"; } } /** * Returns the context {@code ClassLoader} for this thread. The context * {@code ClassLoader} is provided by the creator of the thread for use * by code running in this thread when loading classes and resources. * If not {@linkplain #setContextClassLoader set}, the default is the * {@code ClassLoader} context of the parent thread. The context * {@code ClassLoader} of the * primordial thread is typically set to the class loader used to load the * application. * * * @return the context {@code ClassLoader} for this thread, or {@code null} * indicating the system class loader (or, failing that, the * bootstrap class loader) * * @throws SecurityException * if a security manager is present, and the caller's class loader * is not {@code null} and is not the same as or an ancestor of the * context class loader, and the caller does not have the * {@link RuntimePermission}{@code ("getClassLoader")} * * @since 1.2 */ @CallerSensitive public ClassLoader getContextClassLoader() { if (contextClassLoader == null) return null; SecurityManager sm = System.getSecurityManager(); if (sm != null) { ClassLoader.checkClassLoaderPermission(contextClassLoader, Reflection.getCallerClass()); } return contextClassLoader; } /** * Sets the context ClassLoader for this Thread. The context * ClassLoader can be set when a thread is created, and allows * the creator of the thread to provide the appropriate class loader, * through {@code getContextClassLoader}, to code running in the thread * when loading classes and resources. * *

If a security manager is present, its {@link * SecurityManager#checkPermission(java.security.Permission) checkPermission} * method is invoked with a {@link RuntimePermission RuntimePermission}{@code * ("setContextClassLoader")} permission to see if setting the context * ClassLoader is permitted. * * @param cl * the context ClassLoader for this Thread, or null indicating the * system class loader (or, failing that, the bootstrap class loader) * * @throws SecurityException * if the current thread cannot set the context ClassLoader * * @since 1.2 */ public void setContextClassLoader(ClassLoader cl) { SecurityManager sm = System.getSecurityManager(); if (sm != null) { sm.checkPermission(new RuntimePermission("setContextClassLoader")); } contextClassLoader = cl; } /** * Returns {@code true} if and only if the current thread holds the * monitor lock on the specified object. * *

This method is designed to allow a program to assert that * the current thread already holds a specified lock: * 

     *     assert Thread.holdsLock(obj);
     *
* * @param obj the object on which to test lock ownership * @throws NullPointerException if obj is {@code null} * @return {@code true} if the current thread holds the monitor lock on * the specified object. * @since 1.4 */ public static native boolean holdsLock(Object obj); private static final StackTraceElement[] EMPTY_STACK_TRACE = new StackTraceElement[0]; /** * Returns an array of stack trace elements representing the stack dump * of this thread. This method will return a zero-length array if * this thread has not started, has started but has not yet been * scheduled to run by the system, or has terminated. * If the returned array is of non-zero length then the first element of * the array represents the top of the stack, which is the most recent * method invocation in the sequence. The last element of the array * represents the bottom of the stack, which is the least recent method * invocation in the sequence. * *

If there is a security manager, and this thread is not * the current thread, then the security manager's * {@code checkPermission} method is called with a * {@code RuntimePermission("getStackTrace")} permission * to see if it's ok to get the stack trace. * *

Some virtual machines may, under some circumstances, omit one * or more stack frames from the stack trace. In the extreme case, * a virtual machine that has no stack trace information concerning * this thread is permitted to return a zero-length array from this * method. * * @return an array of {@code StackTraceElement}, * each represents one stack frame. * * @throws SecurityException * if a security manager exists and its * {@code checkPermission} method doesn't allow * getting the stack trace of thread. * @see SecurityManager#checkPermission * @see RuntimePermission * @see Throwable#getStackTrace * * @since 1.5 */ public StackTraceElement[] getStackTrace() { if (this != Thread.currentThread()) { // check for getStackTrace permission SecurityManager security = System.getSecurityManager(); if (security != null) { security.checkPermission( SecurityConstants.GET_STACK_TRACE_PERMISSION); } // optimization so we do not call into the vm for threads that // have not yet started or have terminated if (!isAlive()) { return EMPTY_STACK_TRACE; } StackTraceElement[][] stackTraceArray = dumpThreads(new Thread[] {this}); StackTraceElement[] stackTrace = stackTraceArray[0]; // a thread that was alive during the previous isAlive call may have // since terminated, therefore not having a stacktrace. if (stackTrace == null) { stackTrace = EMPTY_STACK_TRACE; } return stackTrace; } else { return (new Exception()).getStackTrace(); } } /** * Returns a map of stack traces for all live threads. * The map keys are threads and each map value is an array of * {@code StackTraceElement} that represents the stack dump * of the corresponding {@code Thread}. * The returned stack traces are in the format specified for * the {@link #getStackTrace getStackTrace} method. * *

The threads may be executing while this method is called. * The stack trace of each thread only represents a snapshot and * each stack trace may be obtained at different time. A zero-length * array will be returned in the map value if the virtual machine has * no stack trace information about a thread. * *

If there is a security manager, then the security manager's * {@code checkPermission} method is called with a * {@code RuntimePermission("getStackTrace")} permission as well as * {@code RuntimePermission("modifyThreadGroup")} permission * to see if it is ok to get the stack trace of all threads. * * @return a {@code Map} from {@code Thread} to an array of * {@code StackTraceElement} that represents the stack trace of * the corresponding thread. * * @throws SecurityException * if a security manager exists and its * {@code checkPermission} method doesn't allow * getting the stack trace of thread. * @see #getStackTrace * @see SecurityManager#checkPermission * @see RuntimePermission * @see Throwable#getStackTrace * * @since 1.5 */ public static Map getAllStackTraces() { // check for getStackTrace permission SecurityManager security = System.getSecurityManager(); if (security != null) { security.checkPermission( SecurityConstants.GET_STACK_TRACE_PERMISSION); security.checkPermission( SecurityConstants.MODIFY_THREADGROUP_PERMISSION); } // Get a snapshot of the list of all threads Thread[] threads = getThreads(); StackTraceElement[][] traces = dumpThreads(threads); Map m = new HashMap<>(threads.length); for (int i = 0; i < threads.length; i++) { StackTraceElement[] stackTrace = traces[i]; if (stackTrace != null) { m.put(threads[i], stackTrace); } // else terminated so we don't put it in the map } return m; } private static final RuntimePermission SUBCLASS_IMPLEMENTATION_PERMISSION = new RuntimePermission("enableContextClassLoaderOverride"); /** cache of subclass security audit results */ /* Replace with ConcurrentReferenceHashMap when/if it appears in a future * release */ private static class Caches { /** cache of subclass security audit results */ static final ConcurrentMap subclassAudits = new ConcurrentHashMap<>(); /** queue for WeakReferences to audited subclasses */ static final ReferenceQueue> subclassAuditsQueue = new ReferenceQueue<>(); } /** * Verifies that this (possibly subclass) instance can be constructed * without violating security constraints: the subclass must not override * security-sensitive non-final methods, or else the * "enableContextClassLoaderOverride" RuntimePermission is checked. */ private static boolean isCCLOverridden(Class cl) { if (cl == Thread.class) return false; processQueue(Caches.subclassAuditsQueue, Caches.subclassAudits); WeakClassKey key = new WeakClassKey(cl, Caches.subclassAuditsQueue); Boolean result = Caches.subclassAudits.get(key); if (result == null) { result = Boolean.valueOf(auditSubclass(cl)); Caches.subclassAudits.putIfAbsent(key, result); } return result.booleanValue(); } /** * Performs reflective checks on given subclass to verify that it doesn't * override security-sensitive non-final methods. Returns true if the * subclass overrides any of the methods, false otherwise. */ private static boolean auditSubclass(final Class subcl) { Boolean result = AccessController.doPrivileged( new PrivilegedAction<>() { public Boolean run() { for (Class cl = subcl; cl != Thread.class; cl = cl.getSuperclass()) { try { cl.getDeclaredMethod("getContextClassLoader", new Class[0]); return Boolean.TRUE; } catch (NoSuchMethodException ex) { } try { Class[] params = {ClassLoader.class}; cl.getDeclaredMethod("setContextClassLoader", params); return Boolean.TRUE; } catch (NoSuchMethodException ex) { } } return Boolean.FALSE; } } ); return result.booleanValue(); } private static native StackTraceElement[][] dumpThreads(Thread[] threads); private static native Thread[] getThreads(); /** * Returns the identifier of this Thread. The thread ID is a positive * {@code long} number generated when this thread was created. * The thread ID is unique and remains unchanged during its lifetime. * When a thread is terminated, this thread ID may be reused. * * @return this thread's ID. * @since 1.5 */ public long getId() { return tid; } /** * A thread state. A thread can be in one of the following states: *

* *

* A thread can be in only one state at a given point in time. * These states are virtual machine states which do not reflect * any operating system thread states. * * @since 1.5 * @see #getState */ public enum State { /** * Thread state for a thread which has not yet started. */ NEW, /** * Thread state for a runnable thread. A thread in the runnable * state is executing in the Java virtual machine but it may * be waiting for other resources from the operating system * such as processor. */ RUNNABLE, /** * Thread state for a thread blocked waiting for a monitor lock. * A thread in the blocked state is waiting for a monitor lock * to enter a synchronized block/method or * reenter a synchronized block/method after calling * {@link Object#wait() Object.wait}. */ BLOCKED, /** * Thread state for a waiting thread. * A thread is in the waiting state due to calling one of the * following methods: *

* *

A thread in the waiting state is waiting for another thread to * perform a particular action. * * For example, a thread that has called {@code Object.wait()} * on an object is waiting for another thread to call * {@code Object.notify()} or {@code Object.notifyAll()} on * that object. A thread that has called {@code Thread.join()} * is waiting for a specified thread to terminate. */ WAITING, /** * Thread state for a waiting thread with a specified waiting time. * A thread is in the timed waiting state due to calling one of * the following methods with a specified positive waiting time: *

*/ TIMED_WAITING, /** * Thread state for a terminated thread. * The thread has completed execution. */ TERMINATED; } /** * Returns the state of this thread. * This method is designed for use in monitoring of the system state, * not for synchronization control. * * @return this thread's state. * @since 1.5 */ public State getState() { // get current thread state return jdk.internal.misc.VM.toThreadState(threadStatus); } // Added in JSR-166 /** * Interface for handlers invoked when a {@code Thread} abruptly * terminates due to an uncaught exception. *

When a thread is about to terminate due to an uncaught exception * the Java Virtual Machine will query the thread for its * {@code UncaughtExceptionHandler} using * {@link #getUncaughtExceptionHandler} and will invoke the handler's * {@code uncaughtException} method, passing the thread and the * exception as arguments. * If a thread has not had its {@code UncaughtExceptionHandler} * explicitly set, then its {@code ThreadGroup} object acts as its * {@code UncaughtExceptionHandler}. If the {@code ThreadGroup} object * has no * special requirements for dealing with the exception, it can forward * the invocation to the {@linkplain #getDefaultUncaughtExceptionHandler * default uncaught exception handler}. * * @see #setDefaultUncaughtExceptionHandler * @see #setUncaughtExceptionHandler * @see ThreadGroup#uncaughtException * @since 1.5 */ @FunctionalInterface public interface UncaughtExceptionHandler { /** * Method invoked when the given thread terminates due to the * given uncaught exception. *

Any exception thrown by this method will be ignored by the * Java Virtual Machine. * @param t the thread * @param e the exception */ void uncaughtException(Thread t, Throwable e); } // null unless explicitly set private volatile UncaughtExceptionHandler uncaughtExceptionHandler; // null unless explicitly set private static volatile UncaughtExceptionHandler defaultUncaughtExceptionHandler; /** * Set the default handler invoked when a thread abruptly terminates * due to an uncaught exception, and no other handler has been defined * for that thread. * *

Uncaught exception handling is controlled first by the thread, then * by the thread's {@link ThreadGroup} object and finally by the default * uncaught exception handler. If the thread does not have an explicit * uncaught exception handler set, and the thread's thread group * (including parent thread groups) does not specialize its * {@code uncaughtException} method, then the default handler's * {@code uncaughtException} method will be invoked. *

By setting the default uncaught exception handler, an application * can change the way in which uncaught exceptions are handled (such as * logging to a specific device, or file) for those threads that would * already accept whatever "default" behavior the system * provided. * *

Note that the default uncaught exception handler should not usually * defer to the thread's {@code ThreadGroup} object, as that could cause * infinite recursion. * * @param eh the object to use as the default uncaught exception handler. * If {@code null} then there is no default handler. * * @throws SecurityException if a security manager is present and it denies * {@link RuntimePermission}{@code ("setDefaultUncaughtExceptionHandler")} * * @see #setUncaughtExceptionHandler * @see #getUncaughtExceptionHandler * @see ThreadGroup#uncaughtException * @since 1.5 */ public static void setDefaultUncaughtExceptionHandler(UncaughtExceptionHandler eh) { SecurityManager sm = System.getSecurityManager(); if (sm != null) { sm.checkPermission( new RuntimePermission("setDefaultUncaughtExceptionHandler") ); } defaultUncaughtExceptionHandler = eh; } /** * Returns the default handler invoked when a thread abruptly terminates * due to an uncaught exception. If the returned value is {@code null}, * there is no default. * @since 1.5 * @see #setDefaultUncaughtExceptionHandler * @return the default uncaught exception handler for all threads */ public static UncaughtExceptionHandler getDefaultUncaughtExceptionHandler(){ return defaultUncaughtExceptionHandler; } /** * Returns the handler invoked when this thread abruptly terminates * due to an uncaught exception. If this thread has not had an * uncaught exception handler explicitly set then this thread's * {@code ThreadGroup} object is returned, unless this thread * has terminated, in which case {@code null} is returned. * @since 1.5 * @return the uncaught exception handler for this thread */ public UncaughtExceptionHandler getUncaughtExceptionHandler() { return uncaughtExceptionHandler != null ? uncaughtExceptionHandler : group; } /** * Set the handler invoked when this thread abruptly terminates * due to an uncaught exception. *

A thread can take full control of how it responds to uncaught * exceptions by having its uncaught exception handler explicitly set. * If no such handler is set then the thread's {@code ThreadGroup} * object acts as its handler. * @param eh the object to use as this thread's uncaught exception * handler. If {@code null} then this thread has no explicit handler. * @throws SecurityException if the current thread is not allowed to * modify this thread. * @see #setDefaultUncaughtExceptionHandler * @see ThreadGroup#uncaughtException * @since 1.5 */ public void setUncaughtExceptionHandler(UncaughtExceptionHandler eh) { checkAccess(); uncaughtExceptionHandler = eh; } /** * Dispatch an uncaught exception to the handler. This method is * intended to be called only by the JVM. */ private void dispatchUncaughtException(Throwable e) { getUncaughtExceptionHandler().uncaughtException(this, e); } /** * Removes from the specified map any keys that have been enqueued * on the specified reference queue. */ static void processQueue(ReferenceQueue> queue, ConcurrentMap>, ?> map) { Reference> ref; while((ref = queue.poll()) != null) { map.remove(ref); } } /** * Weak key for Class objects. **/ static class WeakClassKey extends WeakReference> { /** * saved value of the referent's identity hash code, to maintain * a consistent hash code after the referent has been cleared */ private final int hash; /** * Create a new WeakClassKey to the given object, registered * with a queue. */ WeakClassKey(Class cl, ReferenceQueue> refQueue) { super(cl, refQueue); hash = System.identityHashCode(cl); } /** * Returns the identity hash code of the original referent. */ @Override public int hashCode() { return hash; } /** * Returns true if the given object is this identical * WeakClassKey instance, or, if this object's referent has not * been cleared, if the given object is another WeakClassKey * instance with the identical non-null referent as this one. */ @Override public boolean equals(Object obj) { if (obj == this) return true; if (obj instanceof WeakClassKey) { Object referent = get(); return (referent != null) && (referent == ((WeakClassKey) obj).get()); } else { return false; } } } // The following three initially uninitialized fields are exclusively // managed by class java.util.concurrent.ThreadLocalRandom. These // fields are used to build the high-performance PRNGs in the // concurrent code, and we can not risk accidental false sharing. // Hence, the fields are isolated with @Contended. /** The current seed for a ThreadLocalRandom */ @jdk.internal.vm.annotation.Contended("tlr") long threadLocalRandomSeed; /** Probe hash value; nonzero if threadLocalRandomSeed initialized */ @jdk.internal.vm.annotation.Contended("tlr") int threadLocalRandomProbe; /** Secondary seed isolated from public ThreadLocalRandom sequence */ @jdk.internal.vm.annotation.Contended("tlr") int threadLocalRandomSecondarySeed; /* Some private helper methods */ private native void setPriority0(int newPriority); private native void stop0(Object o); private native void suspend0(); private native void resume0(); private native void interrupt0(); private native void setNativeName(String name); }