java线程池赏析
1、线程池的顶级接口(Executor)
线程池的顶级接口(jdk > 1.5)。仅仅定义了方法execute(Runnable)。
该方法接收一个Runnable实例,用来执行一个任务,该任务即是一个实现Runnable接口的类。
public interface Executor { /** * Executes the given command at some time in the future. The command * may execute in a new thread, in a pooled thread, or in the calling * thread, at the discretion of the <tt>Executor</tt> implementation. * * @param command the runnable task * @throws RejectedExecutionException if this task cannot be * accepted for execution. * @throws NullPointerException if command is null */ void execute(Runnable command); }
2、线程池二级接口ExecutorService
interface ExecutorService extends Executor
继承自Executor接口,提供了更多的方法调用
任务有两种: Runnable 可执行的任务, 无返回结果; Callable 可执行的任务,有返回值。 返回结果可以被Future接受。
- List<Future> invokeAll(Collect<Callable> tasks) 执行tasks,返回保持任务状态和结果的 Future 列表。
- List<Future> invokeAll(Collect<Callable> tasks,long timeout,TimeUnit unit) 执行tasks,当所有任务完成或超时(无论哪个首先发生),返回保持任务状态和结果的 Future 列表.
- T invokeAll(Collect<Callable> tasks,long timeout,TimeUnit unit) 随便执行task,返回其结果
- void shutdown() 准备关闭,继续执行已提交的任务,但不接受新任务。
- List<Runable> shutdownNow() 暂停处理正在等待的任务,并返回等待执行的任务列表。
- Future submit(Callable task) 执行一个任务,返回保持任务状态和结果的 Future
- Future submit(Runable task,T result) 执行一个任务,完成时返回result作为 结果 Future
/* * ORACLE PROPRIETARY/CONFIDENTIAL. Use is subject to license terms. * * * * * * * * * * * * * * * * * * * * */ /* * * * * * * 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/ */ package java.util.concurrent; import java.util.List; import java.util.Collection; import java.security.PrivilegedAction; import java.security.PrivilegedExceptionAction; /** * An {@link Executor} that provides methods to manage termination and * methods that can produce a {@link Future} for tracking progress of * one or more asynchronous tasks. * * <p> An <tt>ExecutorService</tt> can be shut down, which will cause * it to reject new tasks. Two different methods are provided for * shutting down an <tt>ExecutorService</tt>. The {@link #shutdown} * method will allow previously submitted tasks to execute before * terminating, while the {@link #shutdownNow} method prevents waiting * tasks from starting and attempts to stop currently executing tasks. * Upon termination, an executor has no tasks actively executing, no * tasks awaiting execution, and no new tasks can be submitted. An * unused <tt>ExecutorService</tt> should be shut down to allow * reclamation of its resources. * * <p> Method <tt>submit</tt> extends base method {@link * Executor#execute} by creating and returning a {@link Future} that * can be used to cancel execution and/or wait for completion. * Methods <tt>invokeAny</tt> and <tt>invokeAll</tt> perform the most * commonly useful forms of bulk execution, executing a collection of * tasks and then waiting for at least one, or all, to * complete. (Class {@link ExecutorCompletionService} can be used to * write customized variants of these methods.) * * <p>The {@link Executors} class provides factory methods for the * executor services provided in this package. * * <h3>Usage Examples</h3> * * Here is a sketch of a network service in which threads in a thread * pool service incoming requests. It uses the preconfigured {@link * Executors#newFixedThreadPool} factory method: * * <pre> * class NetworkService implements Runnable { * private final ServerSocket serverSocket; * private final ExecutorService pool; * * public NetworkService(int port, int poolSize) * throws IOException { * serverSocket = new ServerSocket(port); * pool = Executors.newFixedThreadPool(poolSize); * } * * public void run() { // run the service * try { * for (;;) { * pool.execute(new Handler(serverSocket.accept())); * } * } catch (IOException ex) { * pool.shutdown(); * } * } * } * * class Handler implements Runnable { * private final Socket socket; * Handler(Socket socket) { this.socket = socket; } * public void run() { * // read and service request on socket * } * } * </pre> * * The following method shuts down an <tt>ExecutorService</tt> in two phases, * first by calling <tt>shutdown</tt> to reject incoming tasks, and then * calling <tt>shutdownNow</tt>, if necessary, to cancel any lingering tasks: * * <pre> * void shutdownAndAwaitTermination(ExecutorService pool) { * pool.shutdown(); // Disable new tasks from being submitted * try { * // Wait a while for existing tasks to terminate * if (!pool.awaitTermination(60, TimeUnit.SECONDS)) { * pool.shutdownNow(); // Cancel currently executing tasks * // Wait a while for tasks to respond to being cancelled * if (!pool.awaitTermination(60, TimeUnit.SECONDS)) * System.err.println("Pool did not terminate"); * } * } catch (InterruptedException ie) { * // (Re-)Cancel if current thread also interrupted * pool.shutdownNow(); * // Preserve interrupt status * Thread.currentThread().interrupt(); * } * } * </pre> * * <p>Memory consistency effects: Actions in a thread prior to the * submission of a {@code Runnable} or {@code Callable} task to an * {@code ExecutorService} * <a href="package-summary.html#MemoryVisibility"><i>happen-before</i></a> * any actions taken by that task, which in turn <i>happen-before</i> the * result is retrieved via {@code Future.get()}. * * @since 1.5 * @author Doug Lea */ public interface ExecutorService extends Executor { /** * Initiates an orderly shutdown in which previously submitted * tasks are executed, but no new tasks will be accepted. * Invocation has no additional effect if already shut down. * * <p>This method does not wait for previously submitted tasks to * complete execution. Use {@link #awaitTermination awaitTermination} * to do that. * * @throws SecurityException if a security manager exists and * shutting down this ExecutorService may manipulate * threads that the caller is not permitted to modify * because it does not hold {@link * java.lang.RuntimePermission}<tt>("modifyThread")</tt>, * or the security manager's <tt>checkAccess</tt> method * denies access. */ void shutdown(); /** * Attempts to stop all actively executing tasks, halts the * processing of waiting tasks, and returns a list of the tasks * that were awaiting execution. * * <p>This method does not wait for actively executing tasks to * terminate. Use {@link #awaitTermination awaitTermination} to * do that. * * <p>There are no guarantees beyond best-effort attempts to stop * processing actively executing tasks. For example, typical * implementations will cancel via {@link Thread#interrupt}, so any * task that fails to respond to interrupts may never terminate. * * @return list of tasks that never commenced execution * @throws SecurityException if a security manager exists and * shutting down this ExecutorService may manipulate * threads that the caller is not permitted to modify * because it does not hold {@link * java.lang.RuntimePermission}<tt>("modifyThread")</tt>, * or the security manager's <tt>checkAccess</tt> method * denies access. */ List<Runnable> shutdownNow(); /** * Returns <tt>true</tt> if this executor has been shut down. * * @return <tt>true</tt> if this executor has been shut down */ boolean isShutdown(); /** * Returns <tt>true</tt> if all tasks have completed following shut down. * Note that <tt>isTerminated</tt> is never <tt>true</tt> unless * either <tt>shutdown</tt> or <tt>shutdownNow</tt> was called first. * * @return <tt>true</tt> if all tasks have completed following shut down */ boolean isTerminated(); /** * Blocks until all tasks have completed execution after a shutdown * request, or the timeout occurs, or the current thread is * interrupted, whichever happens first. * * @param timeout the maximum time to wait * @param unit the time unit of the timeout argument * @return <tt>true</tt> if this executor terminated and * <tt>false</tt> if the timeout elapsed before termination * @throws InterruptedException if interrupted while waiting */ boolean awaitTermination(long timeout, TimeUnit unit) throws InterruptedException; /** * Submits a value-returning task for execution and returns a * Future representing the pending results of the task. The * Future's <tt>get</tt> method will return the task's result upon * successful completion. * * <p> * If you would like to immediately block waiting * for a task, you can use constructions of the form * <tt>result = exec.submit(aCallable).get();</tt> * * <p> Note: The {@link Executors} class includes a set of methods * that can convert some other common closure-like objects, * for example, {@link java.security.PrivilegedAction} to * {@link Callable} form so they can be submitted. * * @param task the task to submit * @return a Future representing pending completion of the task * @throws RejectedExecutionException if the task cannot be * scheduled for execution * @throws NullPointerException if the task is null */ <T> Future<T> submit(Callable<T> task); /** * Submits a Runnable task for execution and returns a Future * representing that task. The Future's <tt>get</tt> method will * return the given result upon successful completion. * * @param task the task to submit * @param result the result to return * @return a Future representing pending completion of the task * @throws RejectedExecutionException if the task cannot be * scheduled for execution * @throws NullPointerException if the task is null */ <T> Future<T> submit(Runnable task, T result); /** * Submits a Runnable task for execution and returns a Future * representing that task. The Future's <tt>get</tt> method will * return <tt>null</tt> upon <em>successful</em> completion. * * @param task the task to submit * @return a Future representing pending completion of the task * @throws RejectedExecutionException if the task cannot be * scheduled for execution * @throws NullPointerException if the task is null */ Future<?> submit(Runnable task); /** * Executes the given tasks, returning a list of Futures holding * their status and results when all complete. * {@link Future#isDone} is <tt>true</tt> for each * element of the returned list. * Note that a <em>completed</em> task could have * terminated either normally or by throwing an exception. * The results of this method are undefined if the given * collection is modified while this operation is in progress. * * @param tasks the collection of tasks * @return A list of Futures representing the tasks, in the same * sequential order as produced by the iterator for the * given task list, each of which has completed. * @throws InterruptedException if interrupted while waiting, in * which case unfinished tasks are cancelled. * @throws NullPointerException if tasks or any of its elements are <tt>null</tt> * @throws RejectedExecutionException if any task cannot be * scheduled for execution */ <T> List<Future<T>> invokeAll(Collection<? extends Callable<T>> tasks) throws InterruptedException; /** * Executes the given tasks, returning a list of Futures holding * their status and results * when all complete or the timeout expires, whichever happens first. * {@link Future#isDone} is <tt>true</tt> for each * element of the returned list. * Upon return, tasks that have not completed are cancelled. * Note that a <em>completed</em> task could have * terminated either normally or by throwing an exception. * The results of this method are undefined if the given * collection is modified while this operation is in progress. * * @param tasks the collection of tasks * @param timeout the maximum time to wait * @param unit the time unit of the timeout argument * @return a list of Futures representing the tasks, in the same * sequential order as produced by the iterator for the * given task list. If the operation did not time out, * each task will have completed. If it did time out, some * of these tasks will not have completed. * @throws InterruptedException if interrupted while waiting, in * which case unfinished tasks are cancelled * @throws NullPointerException if tasks, any of its elements, or * unit are <tt>null</tt> * @throws RejectedExecutionException if any task cannot be scheduled * for execution */ <T> List<Future<T>> invokeAll(Collection<? extends Callable<T>> tasks, long timeout, TimeUnit unit) throws InterruptedException; /** * Executes the given tasks, returning the result * of one that has completed successfully (i.e., without throwing * an exception), if any do. Upon normal or exceptional return, * tasks that have not completed are cancelled. * The results of this method are undefined if the given * collection is modified while this operation is in progress. * * @param tasks the collection of tasks * @return the result returned by one of the tasks * @throws InterruptedException if interrupted while waiting * @throws NullPointerException if tasks or any element task * subject to execution is <tt>null</tt> * @throws IllegalArgumentException if tasks is empty * @throws ExecutionException if no task successfully completes * @throws RejectedExecutionException if tasks cannot be scheduled * for execution */ <T> T invokeAny(Collection<? extends Callable<T>> tasks) throws InterruptedException, ExecutionException; /** * Executes the given tasks, returning the result * of one that has completed successfully (i.e., without throwing * an exception), if any do before the given timeout elapses. * Upon normal or exceptional return, tasks that have not * completed are cancelled. * The results of this method are undefined if the given * collection is modified while this operation is in progress. * * @param tasks the collection of tasks * @param timeout the maximum time to wait * @param unit the time unit of the timeout argument * @return the result returned by one of the tasks. * @throws InterruptedException if interrupted while waiting * @throws NullPointerException if tasks, or unit, or any element * task subject to execution is <tt>null</tt> * @throws TimeoutException if the given timeout elapses before * any task successfully completes * @throws ExecutionException if no task successfully completes * @throws RejectedExecutionException if tasks cannot be scheduled * for execution */ <T> T invokeAny(Collection<? extends Callable<T>> tasks, long timeout, TimeUnit unit) throws InterruptedException, ExecutionException, TimeoutException; }
3、线程池计划任务ScheduledExecutorService
ScheduledExecutorService extends ExecutorService
是一个抽象类,可以 定时、 定期 执行任务
- ScheduleFuture<V> schedule(Callable<V> callable, long delay, TimeUnit unit) 在delay时间后 执行callable任务
- ScheduleFuture schedule(Runnable runnable, long delay, TimeUnit unit) 在delay时间后 执行runnable任务
- ScheduleFuture scheduleAtFixedRate(Runnable runnable, long initTime,long period, TimeUnit unit) 在initTime时间后 执行runnable任务,然后在init+period后再次执行,在inti+period*2后再次执行。。。。。
- ScheduleFuture scheduleWithFixedDely(Runnable runnable, long initTime,long delay, TimeUnit unit) 在initTime时间后 执行runnable任务,完毕后,在delay后再次执行
4、线程池工具Executors
这个工具类相当强大, 可以创建FixedThreadPool、CachedThreadPool、ScheduledThreadPool、SingleThreadExceutor 、callable(Runnable转为callable)
默认返回:ExecutorService 或 ScheduledExecutorService,极大的省去了复杂的创建工作。单元测试场景非常实用。
使用起来方便
ScheduledExecutorService scheduledExecutorService1 = Executors.newScheduledThreadPool(12);// 12个核心线程 ExecutorService executorService2 = Executors.newFixedThreadPool(10);// 10个核心线程 ExecutorService executorService1 = Executors.newSingleThreadExecutor();// 单个线程 ExecutorService executorService = Executors.newCachedThreadPool(); // 根据任务无限增加线程,存活60s,无任务则销毁 Callable<Object> callable1 = Executors.callable(privilegedAction); Callable<Object> callable2 = Executors.callable(a); Object call = callable1.call();
/* * ORACLE PROPRIETARY/CONFIDENTIAL. Use is subject to license terms. * * * * * * * * * * * * * * * * * * * * */ /* * * * * * * 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/ */ package java.util.concurrent; import java.util.*; import java.util.concurrent.atomic.AtomicInteger; import java.security.AccessControlContext; import java.security.AccessController; import java.security.PrivilegedAction; import java.security.PrivilegedExceptionAction; import java.security.PrivilegedActionException; import java.security.AccessControlException; import sun.security.util.SecurityConstants; /** * Factory and utility methods for {@link Executor}, {@link * ExecutorService}, {@link ScheduledExecutorService}, {@link * ThreadFactory}, and {@link Callable} classes defined in this * package. This class supports the following kinds of methods: * * <ul> * <li> Methods that create and return an {@link ExecutorService} * set up with commonly useful configuration settings. * <li> Methods that create and return a {@link ScheduledExecutorService} * set up with commonly useful configuration settings. * <li> Methods that create and return a "wrapped" ExecutorService, that * disables reconfiguration by making implementation-specific methods * inaccessible. * <li> Methods that create and return a {@link ThreadFactory} * that sets newly created threads to a known state. * <li> Methods that create and return a {@link Callable} * out of other closure-like forms, so they can be used * in execution methods requiring <tt>Callable</tt>. * </ul> * * @since 1.5 * @author Doug Lea */ public class Executors { /** * Creates a thread pool that reuses a fixed number of threads * operating off a shared unbounded queue. At any point, at most * <tt>nThreads</tt> threads will be active processing tasks. * If additional tasks are submitted when all threads are active, * they will wait in the queue until a thread is available. * If any thread terminates due to a failure during execution * prior to shutdown, a new one will take its place if needed to * execute subsequent tasks. The threads in the pool will exist * until it is explicitly {@link ExecutorService#shutdown shutdown}. * * @param nThreads the number of threads in the pool * @return the newly created thread pool * @throws IllegalArgumentException if {@code nThreads <= 0} */ public static ExecutorService newFixedThreadPool(int nThreads) { return new ThreadPoolExecutor(nThreads, nThreads, 0L, TimeUnit.MILLISECONDS, new LinkedBlockingQueue<Runnable>()); } /** * Creates a thread pool that reuses a fixed number of threads * operating off a shared unbounded queue, using the provided * ThreadFactory to create new threads when needed. At any point, * at most <tt>nThreads</tt> threads will be active processing * tasks. If additional tasks are submitted when all threads are * active, they will wait in the queue until a thread is * available. If any thread terminates due to a failure during * execution prior to shutdown, a new one will take its place if * needed to execute subsequent tasks. The threads in the pool will * exist until it is explicitly {@link ExecutorService#shutdown * shutdown}. * * @param nThreads the number of threads in the pool * @param threadFactory the factory to use when creating new threads * @return the newly created thread pool * @throws NullPointerException if threadFactory is null * @throws IllegalArgumentException if {@code nThreads <= 0} */ public static ExecutorService newFixedThreadPool(int nThreads, ThreadFactory threadFactory) { return new ThreadPoolExecutor(nThreads, nThreads, 0L, TimeUnit.MILLISECONDS, new LinkedBlockingQueue<Runnable>(), threadFactory); } /** * Creates an Executor that uses a single worker thread operating * off an unbounded queue. (Note however that if this single * thread terminates due to a failure during execution prior to * shutdown, a new one will take its place if needed to execute * subsequent tasks.) Tasks are guaranteed to execute * sequentially, and no more than one task will be active at any * given time. Unlike the otherwise equivalent * <tt>newFixedThreadPool(1)</tt> the returned executor is * guaranteed not to be reconfigurable to use additional threads. * * @return the newly created single-threaded Executor */ public static ExecutorService newSingleThreadExecutor() { return new FinalizableDelegatedExecutorService (new ThreadPoolExecutor(1, 1, 0L, TimeUnit.MILLISECONDS, new LinkedBlockingQueue<Runnable>())); } /** * Creates an Executor that uses a single worker thread operating * off an unbounded queue, and uses the provided ThreadFactory to * create a new thread when needed. Unlike the otherwise * equivalent <tt>newFixedThreadPool(1, threadFactory)</tt> the * returned executor is guaranteed not to be reconfigurable to use * additional threads. * * @param threadFactory the factory to use when creating new * threads * * @return the newly created single-threaded Executor * @throws NullPointerException if threadFactory is null */ public static ExecutorService newSingleThreadExecutor(ThreadFactory threadFactory) { return new FinalizableDelegatedExecutorService (new ThreadPoolExecutor(1, 1, 0L, TimeUnit.MILLISECONDS, new LinkedBlockingQueue<Runnable>(), threadFactory)); } /** * Creates a thread pool that creates new threads as needed, but * will reuse previously constructed threads when they are * available. These pools will typically improve the performance * of programs that execute many short-lived asynchronous tasks. * Calls to <tt>execute</tt> will reuse previously constructed * threads if available. If no existing thread is available, a new * thread will be created and added to the pool. Threads that have * not been used for sixty seconds are terminated and removed from * the cache. Thus, a pool that remains idle for long enough will * not consume any resources. Note that pools with similar * properties but different details (for example, timeout parameters) * may be created using {@link ThreadPoolExecutor} constructors. * * @return the newly created thread pool */ public static ExecutorService newCachedThreadPool() { return new ThreadPoolExecutor(0, Integer.MAX_VALUE, 60L, TimeUnit.SECONDS, new SynchronousQueue<Runnable>()); } /** * Creates a thread pool that creates new threads as needed, but * will reuse previously constructed threads when they are * available, and uses the provided * ThreadFactory to create new threads when needed. * @param threadFactory the factory to use when creating new threads * @return the newly created thread pool * @throws NullPointerException if threadFactory is null */ public static ExecutorService newCachedThreadPool(ThreadFactory threadFactory) { return new ThreadPoolExecutor(0, Integer.MAX_VALUE, 60L, TimeUnit.SECONDS, new SynchronousQueue<Runnable>(), threadFactory); } /** * Creates a single-threaded executor that can schedule commands * to run after a given delay, or to execute periodically. * (Note however that if this single * thread terminates due to a failure during execution prior to * shutdown, a new one will take its place if needed to execute * subsequent tasks.) Tasks are guaranteed to execute * sequentially, and no more than one task will be active at any * given time. Unlike the otherwise equivalent * <tt>newScheduledThreadPool(1)</tt> the returned executor is * guaranteed not to be reconfigurable to use additional threads. * @return the newly created scheduled executor */ public static ScheduledExecutorService newSingleThreadScheduledExecutor() { return new DelegatedScheduledExecutorService (new ScheduledThreadPoolExecutor(1)); } /** * Creates a single-threaded executor that can schedule commands * to run after a given delay, or to execute periodically. (Note * however that if this single thread terminates due to a failure * during execution prior to shutdown, a new one will take its * place if needed to execute subsequent tasks.) Tasks are * guaranteed to execute sequentially, and no more than one task * will be active at any given time. Unlike the otherwise * equivalent <tt>newScheduledThreadPool(1, threadFactory)</tt> * the returned executor is guaranteed not to be reconfigurable to * use additional threads. * @param threadFactory the factory to use when creating new * threads * @return a newly created scheduled executor * @throws NullPointerException if threadFactory is null */ public static ScheduledExecutorService newSingleThreadScheduledExecutor(ThreadFactory threadFactory) { return new DelegatedScheduledExecutorService (new ScheduledThreadPoolExecutor(1, threadFactory)); } /** * Creates a thread pool that can schedule commands to run after a * given delay, or to execute periodically. * @param corePoolSize the number of threads to keep in the pool, * even if they are idle. * @return a newly created scheduled thread pool * @throws IllegalArgumentException if {@code corePoolSize < 0} */ public static ScheduledExecutorService newScheduledThreadPool(int corePoolSize) { return new ScheduledThreadPoolExecutor(corePoolSize); } /** * Creates a thread pool that can schedule commands to run after a * given delay, or to execute periodically. * @param corePoolSize the number of threads to keep in the pool, * even if they are idle. * @param threadFactory the factory to use when the executor * creates a new thread. * @return a newly created scheduled thread pool * @throws IllegalArgumentException if {@code corePoolSize < 0} * @throws NullPointerException if threadFactory is null */ public static ScheduledExecutorService newScheduledThreadPool( int corePoolSize, ThreadFactory threadFactory) { return new ScheduledThreadPoolExecutor(corePoolSize, threadFactory); } /** * Returns an object that delegates all defined {@link * ExecutorService} methods to the given executor, but not any * other methods that might otherwise be accessible using * casts. This provides a way to safely "freeze" configuration and * disallow tuning of a given concrete implementation. * @param executor the underlying implementation * @return an <tt>ExecutorService</tt> instance * @throws NullPointerException if executor null */ public static ExecutorService unconfigurableExecutorService(ExecutorService executor) { if (executor == null) throw new NullPointerException(); return new DelegatedExecutorService(executor); } /** * Returns an object that delegates all defined {@link * ScheduledExecutorService} methods to the given executor, but * not any other methods that might otherwise be accessible using * casts. This provides a way to safely "freeze" configuration and * disallow tuning of a given concrete implementation. * @param executor the underlying implementation * @return a <tt>ScheduledExecutorService</tt> instance * @throws NullPointerException if executor null */ public static ScheduledExecutorService unconfigurableScheduledExecutorService(ScheduledExecutorService executor) { if (executor == null) throw new NullPointerException(); return new DelegatedScheduledExecutorService(executor); } /** * Returns a default thread factory used to create new threads. * This factory creates all new threads used by an Executor in the * same {@link ThreadGroup}. If there is a {@link * java.lang.SecurityManager}, it uses the group of {@link * System#getSecurityManager}, else the group of the thread * invoking this <tt>defaultThreadFactory</tt> method. Each new * thread is created as a non-daemon thread with priority set to * the smaller of <tt>Thread.NORM_PRIORITY</tt> and the maximum * priority permitted in the thread group. New threads have names * accessible via {@link Thread#getName} of * <em>pool-N-thread-M</em>, where <em>N</em> is the sequence * number of this factory, and <em>M</em> is the sequence number * of the thread created by this factory. * @return a thread factory */ public static ThreadFactory defaultThreadFactory() { return new DefaultThreadFactory(); } /** * Returns a thread factory used to create new threads that * have the same permissions as the current thread. * This factory creates threads with the same settings as {@link * Executors#defaultThreadFactory}, additionally setting the * AccessControlContext and contextClassLoader of new threads to * be the same as the thread invoking this * <tt>privilegedThreadFactory</tt> method. A new * <tt>privilegedThreadFactory</tt> can be created within an * {@link AccessController#doPrivileged} action setting the * current thread's access control context to create threads with * the selected permission settings holding within that action. * * <p> Note that while tasks running within such threads will have * the same access control and class loader settings as the * current thread, they need not have the same {@link * java.lang.ThreadLocal} or {@link * java.lang.InheritableThreadLocal} values. If necessary, * particular values of thread locals can be set or reset before * any task runs in {@link ThreadPoolExecutor} subclasses using * {@link ThreadPoolExecutor#beforeExecute}. Also, if it is * necessary to initialize worker threads to have the same * InheritableThreadLocal settings as some other designated * thread, you can create a custom ThreadFactory in which that * thread waits for and services requests to create others that * will inherit its values. * * @return a thread factory * @throws AccessControlException if the current access control * context does not have permission to both get and set context * class loader. */ public static ThreadFactory privilegedThreadFactory() { return new PrivilegedThreadFactory(); } /** * Returns a {@link Callable} object that, when * called, runs the given task and returns the given result. This * can be useful when applying methods requiring a * <tt>Callable</tt> to an otherwise resultless action. * @param task the task to run * @param result the result to return * @return a callable object * @throws NullPointerException if task null */ public static <T> Callable<T> callable(Runnable task, T result) { if (task == null) throw new NullPointerException(); return new RunnableAdapter<T>(task, result); } /** * Returns a {@link Callable} object that, when * called, runs the given task and returns <tt>null</tt>. * @param task the task to run * @return a callable object * @throws NullPointerException if task null */ public static Callable<Object> callable(Runnable task) { if (task == null) throw new NullPointerException(); return new RunnableAdapter<Object>(task, null); } /** * Returns a {@link Callable} object that, when * called, runs the given privileged action and returns its result. * @param action the privileged action to run * @return a callable object * @throws NullPointerException if action null */ public static Callable<Object> callable(final PrivilegedAction<?> action) { if (action == null) throw new NullPointerException(); return new Callable<Object>() { public Object call() { return action.run(); }}; } /** * Returns a {@link Callable} object that, when * called, runs the given privileged exception action and returns * its result. * @param action the privileged exception action to run * @return a callable object * @throws NullPointerException if action null */ public static Callable<Object> callable(final PrivilegedExceptionAction<?> action) { if (action == null) throw new NullPointerException(); return new Callable<Object>() { public Object call() throws Exception { return action.run(); }}; } /** * Returns a {@link Callable} object that will, when * called, execute the given <tt>callable</tt> under the current * access control context. This method should normally be * invoked within an {@link AccessController#doPrivileged} action * to create callables that will, if possible, execute under the * selected permission settings holding within that action; or if * not possible, throw an associated {@link * AccessControlException}. * @param callable the underlying task * @return a callable object * @throws NullPointerException if callable null * */ public static <T> Callable<T> privilegedCallable(Callable<T> callable) { if (callable == null) throw new NullPointerException(); return new PrivilegedCallable<T>(callable); } /** * Returns a {@link Callable} object that will, when * called, execute the given <tt>callable</tt> under the current * access control context, with the current context class loader * as the context class loader. This method should normally be * invoked within an {@link AccessController#doPrivileged} action * to create callables that will, if possible, execute under the * selected permission settings holding within that action; or if * not possible, throw an associated {@link * AccessControlException}. * @param callable the underlying task * * @return a callable object * @throws NullPointerException if callable null * @throws AccessControlException if the current access control * context does not have permission to both set and get context * class loader. */ public static <T> Callable<T> privilegedCallableUsingCurrentClassLoader(Callable<T> callable) { if (callable == null) throw new NullPointerException(); return new PrivilegedCallableUsingCurrentClassLoader<T>(callable); } // Non-public classes supporting the public methods /** * A callable that runs given task and returns given result */ static final class RunnableAdapter<T> implements Callable<T> { final Runnable task; final T result; RunnableAdapter(Runnable task, T result) { this.task = task; this.result = result; } public T call() { task.run(); return result; } } /** * A callable that runs under established access control settings */ static final class PrivilegedCallable<T> implements Callable<T> { private final Callable<T> task; private final AccessControlContext acc; PrivilegedCallable(Callable<T> task) { this.task = task; this.acc = AccessController.getContext(); } public T call() throws Exception { try { return AccessController.doPrivileged( new PrivilegedExceptionAction<T>() { public T run() throws Exception { return task.call(); } }, acc); } catch (PrivilegedActionException e) { throw e.getException(); } } } /** * A callable that runs under established access control settings and * current ClassLoader */ static final class PrivilegedCallableUsingCurrentClassLoader<T> implements Callable<T> { private final Callable<T> task; private final AccessControlContext acc; private final ClassLoader ccl; PrivilegedCallableUsingCurrentClassLoader(Callable<T> task) { SecurityManager sm = System.getSecurityManager(); if (sm != null) { // Calls to getContextClassLoader from this class // never trigger a security check, but we check // whether our callers have this permission anyways. sm.checkPermission(SecurityConstants.GET_CLASSLOADER_PERMISSION); // Whether setContextClassLoader turns out to be necessary // or not, we fail fast if permission is not available. sm.checkPermission(new RuntimePermission("setContextClassLoader")); } this.task = task; this.acc = AccessController.getContext(); this.ccl = Thread.currentThread().getContextClassLoader(); } public T call() throws Exception { try { return AccessController.doPrivileged( new PrivilegedExceptionAction<T>() { public T run() throws Exception { Thread t = Thread.currentThread(); ClassLoader cl = t.getContextClassLoader(); if (ccl == cl) { return task.call(); } else { t.setContextClassLoader(ccl); try { return task.call(); } finally { t.setContextClassLoader(cl); } } } }, acc); } catch (PrivilegedActionException e) { throw e.getException(); } } } /** * The default thread factory */ static class DefaultThreadFactory implements ThreadFactory { private static final AtomicInteger poolNumber = new AtomicInteger(1); private final ThreadGroup group; private final AtomicInteger threadNumber = new AtomicInteger(1); private final String namePrefix; DefaultThreadFactory() { SecurityManager s = System.getSecurityManager(); group = (s != null) ? s.getThreadGroup() : Thread.currentThread().getThreadGroup(); namePrefix = "pool-" + poolNumber.getAndIncrement() + "-thread-"; } public Thread newThread(Runnable r) { Thread t = new Thread(group, r, namePrefix + threadNumber.getAndIncrement(), 0); if (t.isDaemon()) t.setDaemon(false); if (t.getPriority() != Thread.NORM_PRIORITY) t.setPriority(Thread.NORM_PRIORITY); return t; } } /** * Thread factory capturing access control context and class loader */ static class PrivilegedThreadFactory extends DefaultThreadFactory { private final AccessControlContext acc; private final ClassLoader ccl; PrivilegedThreadFactory() { super(); SecurityManager sm = System.getSecurityManager(); if (sm != null) { // Calls to getContextClassLoader from this class // never trigger a security check, but we check // whether our callers have this permission anyways. sm.checkPermission(SecurityConstants.GET_CLASSLOADER_PERMISSION); // Fail fast sm.checkPermission(new RuntimePermission("setContextClassLoader")); } this.acc = AccessController.getContext(); this.ccl = Thread.currentThread().getContextClassLoader(); } public Thread newThread(final Runnable r) { return super.newThread(new Runnable() { public void run() { AccessController.doPrivileged(new PrivilegedAction<Void>() { public Void run() { Thread.currentThread().setContextClassLoader(ccl); r.run(); return null; } }, acc); } }); } } /** * A wrapper class that exposes only the ExecutorService methods * of an ExecutorService implementation. */ static class DelegatedExecutorService extends AbstractExecutorService { private final ExecutorService e; DelegatedExecutorService(ExecutorService executor) { e = executor; } public void execute(Runnable command) { e.execute(command); } public void shutdown() { e.shutdown(); } public List<Runnable> shutdownNow() { return e.shutdownNow(); } public boolean isShutdown() { return e.isShutdown(); } public boolean isTerminated() { return e.isTerminated(); } public boolean awaitTermination(long timeout, TimeUnit unit) throws InterruptedException { return e.awaitTermination(timeout, unit); } public Future<?> submit(Runnable task) { return e.submit(task); } public <T> Future<T> submit(Callable<T> task) { return e.submit(task); } public <T> Future<T> submit(Runnable task, T result) { return e.submit(task, result); } public <T> List<Future<T>> invokeAll(Collection<? extends Callable<T>> tasks) throws InterruptedException { return e.invokeAll(tasks); } public <T> List<Future<T>> invokeAll(Collection<? extends Callable<T>> tasks, long timeout, TimeUnit unit) throws InterruptedException { return e.invokeAll(tasks, timeout, unit); } public <T> T invokeAny(Collection<? extends Callable<T>> tasks) throws InterruptedException, ExecutionException { return e.invokeAny(tasks); } public <T> T invokeAny(Collection<? extends Callable<T>> tasks, long timeout, TimeUnit unit) throws InterruptedException, ExecutionException, TimeoutException { return e.invokeAny(tasks, timeout, unit); } } static class FinalizableDelegatedExecutorService extends DelegatedExecutorService { FinalizableDelegatedExecutorService(ExecutorService executor) { super(executor); } protected void finalize() { super.shutdown(); } } /** * A wrapper class that exposes only the ScheduledExecutorService * methods of a ScheduledExecutorService implementation. */ static class DelegatedScheduledExecutorService extends DelegatedExecutorService implements ScheduledExecutorService { private final ScheduledExecutorService e; DelegatedScheduledExecutorService(ScheduledExecutorService executor) { super(executor); e = executor; } public ScheduledFuture<?> schedule(Runnable command, long delay, TimeUnit unit) { return e.schedule(command, delay, unit); } public <V> ScheduledFuture<V> schedule(Callable<V> callable, long delay, TimeUnit unit) { return e.schedule(callable, delay, unit); } public ScheduledFuture<?> scheduleAtFixedRate(Runnable command, long initialDelay, long period, TimeUnit unit) { return e.scheduleAtFixedRate(command, initialDelay, period, unit); } public ScheduledFuture<?> scheduleWithFixedDelay(Runnable command, long initialDelay, long delay, TimeUnit unit) { return e.scheduleWithFixedDelay(command, initialDelay, delay, unit); } } /** Cannot instantiate. */ private Executors() {} }
5、线程池根基ThreadPoolExecutor
ThreadPoolExecutor extends AbstractExecutorService
AbstractExecutorService implements ExecutorService
工具类可以创建n种线程,那么这些线程实质还是来自于ThreadPoolExecutor类。
public ThreadPoolExecutor(int corePoolSize,//核心线程池大小 int maximumPoolSize,//最大线程池大小 long keepAliveTime,//线程池中超过corePoolSize数目的空闲线程最大存活时间 TimeUnit unit,//keepAliveTime的时间单位 BlockingQueue<Runnable> workQueue,//任务堆积时,进入任务队列 ThreadFactory threadFactory,//线程工厂,可null RejectedExecutionHandler handler) {//当提交任务数超过maxmumPoolSize+workQueue之和时,任务会交给RejectedExecutionHandler来处理,可null if (corePoolSize < 0 || maximumPoolSize <= 0 || maximumPoolSize < corePoolSize || keepAliveTime < 0) throw new IllegalArgumentException(); if (workQueue == null || threadFactory == null || handler == null) throw new NullPointerException(); this.corePoolSize = corePoolSize; this.maximumPoolSize = maximumPoolSize; this.workQueue = workQueue; this.keepAliveTime = unit.toNanos(keepAliveTime); this.threadFactory = threadFactory; this.handler = handler; }
其中比较容易让人误解的是:corePoolSize,maximumPoolSize,workQueue之间关系。
1.当线程池小于corePoolSize时,新提交任务将创建一个新线程执行任务,即使此时线程池中存在空闲线程。
2.当线程池达到corePoolSize时,新提交任务将被放入workQueue中,等待线程池中任务调度执行
3.当workQueue已满,且maximumPoolSize>corePoolSize时,新提交任务会创建新线程执行任务
4.当线程池中超过corePoolSize线程,空闲时间达到keepAliveTime时,关闭空闲线程
5.当设置allowCoreThreadTimeOut(true)时,线程池中corePoolSize线程空闲时间达到keepAliveTime也将关闭
6.当提交任务数超过maximumPoolSize+workQueue.size时,新提交任务由RejectedExecutionHandler处理
RejectedExecutionHandler(饱和策略)
当队列和线程池都满了,说明线程池处于饱和状态,那么必须采取一种策略处理提交的新任务。这个策略默认情况下是AbortPolicy
如: ThreadPoolExecutor.AbortPolicy
-
AbortPolicy:直接抛出异常
- CallerRunsPolicy:直接使用 调用线程(主线程) 来运行任务,如果主线程关闭,则丢弃该任务。
- DiscardOldestPolicy:丢弃队列里最旧的任务。
- DiscardPolicy:不再接受新任务(不处理丢弃掉)。
- 自定义:当然也可以根据应用场景需要来实现RejectedExecutionHandler接口自定义策略。如记录日志或持久化不能处理的任务
