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//  Copyright (c) 1995-2022 Mort Bay Consulting Pty Ltd and others.
//  ------------------------------------------------------------------------
//  All rights reserved. This program and the accompanying materials
//  are made available under the terms of the Eclipse Public License v1.0
//  and Apache License v2.0 which accompanies this distribution.
//
//      The Eclipse Public License is available at
//      http://www.eclipse.org/legal/epl-v10.html
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//      The Apache License v2.0 is available at
//      http://www.opensource.org/licenses/apache2.0.php
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//  You may elect to redistribute this code under either of these licenses.
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package com.signalfx.shaded.jetty.util.thread;

import java.io.IOException;
import java.util.Objects;
import java.util.Set;
import java.util.concurrent.ConcurrentHashMap;
import java.util.concurrent.Executor;
import java.util.concurrent.RejectedExecutionException;
import java.util.concurrent.SynchronousQueue;
import java.util.concurrent.TimeUnit;
import java.util.concurrent.atomic.AtomicLong;
import java.util.stream.Collectors;

import com.signalfx.shaded.jetty.util.AtomicBiInteger;
import com.signalfx.shaded.jetty.util.ProcessorUtils;
import com.signalfx.shaded.jetty.util.annotation.ManagedAttribute;
import com.signalfx.shaded.jetty.util.annotation.ManagedObject;
import com.signalfx.shaded.jetty.util.component.AbstractLifeCycle;
import com.signalfx.shaded.jetty.util.component.Dumpable;
import com.signalfx.shaded.jetty.util.component.DumpableCollection;
import com.signalfx.shaded.jetty.util.log.Log;
import com.signalfx.shaded.jetty.util.log.Logger;

import static java.util.concurrent.TimeUnit.NANOSECONDS;
import static com.signalfx.shaded.jetty.util.AtomicBiInteger.getHi;
import static com.signalfx.shaded.jetty.util.AtomicBiInteger.getLo;

/**
 * 

A TryExecutor using pre-allocated/reserved threads from an external Executor.

*

Calls to {@link #tryExecute(Runnable)} on ReservedThreadExecutor will either * succeed with a reserved thread immediately being assigned the task, or fail if * no reserved thread is available.

*

Threads are reserved lazily, with new reserved threads being allocated from the external * {@link Executor} passed to the constructor. Whenever 1 or more reserved threads have been * idle for more than {@link #getIdleTimeoutMs()} then one reserved thread will return to * the external Executor.

*/ @ManagedObject("A pool for reserved threads") public class ReservedThreadExecutor extends AbstractLifeCycle implements TryExecutor, Dumpable { private static final Logger LOG = Log.getLogger(ReservedThreadExecutor.class); private static final long DEFAULT_IDLE_TIMEOUT = TimeUnit.MINUTES.toNanos(1); private static final Runnable STOP = new Runnable() { @Override public void run() { } @Override public String toString() { return "STOP"; } }; private final Executor _executor; private final int _capacity; private final Set _threads = ConcurrentHashMap.newKeySet(); private final SynchronousQueue _queue = new SynchronousQueue<>(false); private final AtomicBiInteger _count = new AtomicBiInteger(); // hi=pending; lo=size; private final AtomicLong _lastEmptyTime = new AtomicLong(System.nanoTime()); private ThreadPoolBudget.Lease _lease; private long _idleTimeNanos = DEFAULT_IDLE_TIMEOUT; /** * @param executor The executor to use to obtain threads * @param capacity The number of threads to preallocate. If less than 0 then capacity * is calculated based on a heuristic from the number of available processors and * thread pool size. */ public ReservedThreadExecutor(Executor executor, int capacity) { _executor = executor; _capacity = reservedThreads(executor, capacity); if (LOG.isDebugEnabled()) LOG.debug("{}", this); } /** * @param executor The executor to use to obtain threads * @param capacity The number of threads to preallocate, If less than 0 then capacity * is calculated based on a heuristic from the number of available processors and * thread pool size. * @return the number of reserved threads that would be used by a ReservedThreadExecutor * constructed with these arguments. */ private static int reservedThreads(Executor executor, int capacity) { if (capacity >= 0) return capacity; int cpus = ProcessorUtils.availableProcessors(); if (executor instanceof ThreadPool.SizedThreadPool) { int threads = ((ThreadPool.SizedThreadPool)executor).getMaxThreads(); return Math.max(1, Math.min(cpus, threads / 10)); } return cpus; } public Executor getExecutor() { return _executor; } /** * @return the maximum number of reserved threads */ @ManagedAttribute(value = "max number of reserved threads", readonly = true) public int getCapacity() { return _capacity; } /** * @return the number of threads available to {@link #tryExecute(Runnable)} */ @ManagedAttribute(value = "available reserved threads", readonly = true) public int getAvailable() { return _count.getLo(); } @ManagedAttribute(value = "pending reserved threads", readonly = true) public int getPending() { return _count.getHi(); } @ManagedAttribute(value = "idle timeout in ms", readonly = true) public long getIdleTimeoutMs() { return NANOSECONDS.toMillis(_idleTimeNanos); } /** * Set the idle timeout for shrinking the reserved thread pool * * @param idleTime Time to wait before shrinking, or 0 for default timeout. * @param idleTimeUnit Time units for idle timeout */ public void setIdleTimeout(long idleTime, TimeUnit idleTimeUnit) { if (isRunning()) throw new IllegalStateException(); _idleTimeNanos = (idleTime <= 0 || idleTimeUnit == null) ? DEFAULT_IDLE_TIMEOUT : idleTimeUnit.toNanos(idleTime); } @Override public void doStart() throws Exception { _lease = ThreadPoolBudget.leaseFrom(getExecutor(), this, _capacity); _count.set(0, 0); super.doStart(); } @Override public void doStop() throws Exception { if (_lease != null) _lease.close(); super.doStop(); // Mark this instance as stopped. int size = _count.getAndSetLo(-1); // Offer the STOP task to all waiting reserved threads. for (int i = 0; i < size; ++i) { // Yield to wait for any reserved threads that // have incremented the size but not yet polled. Thread.yield(); _queue.offer(STOP); } // Interrupt any reserved thread missed the offer, // so they do not wait for the whole idle timeout. _threads.stream() .filter(ReservedThread::isReserved) .map(t -> t._thread) .filter(Objects::nonNull) .forEach(Thread::interrupt); _threads.clear(); _count.getAndSetHi(0); } @Override public void execute(Runnable task) throws RejectedExecutionException { _executor.execute(task); } /** *

Executes the given task if and only if a reserved thread is available.

* * @param task the task to run * @return true if and only if a reserved thread was available and has been assigned the task to run. */ @Override public boolean tryExecute(Runnable task) { if (LOG.isDebugEnabled()) LOG.debug("{} tryExecute {}", this, task); if (task == null) return false; // Offer will only succeed if there is a reserved thread waiting boolean offered = _queue.offer(task); // If the offer succeeded we need to reduce the size, unless it is set to -1 in the meantime int size = _count.getLo(); while (offered && size > 0 && !_count.compareAndSetLo(size, --size)) size = _count.getLo(); // If size is 0 and we are not stopping, start a new reserved thread if (size == 0 && task != STOP) startReservedThread(); return offered; } private void startReservedThread() { while (true) { long count = _count.get(); int pending = getHi(count); int size = getLo(count); if (size < 0 || pending + size >= _capacity) return; if (size == 0) _lastEmptyTime.set(System.nanoTime()); if (!_count.compareAndSet(count, pending + 1, size)) continue; if (LOG.isDebugEnabled()) LOG.debug("{} startReservedThread p={}", this, pending + 1); try { ReservedThread thread = new ReservedThread(); _threads.add(thread); _executor.execute(thread); } catch (Throwable e) { _count.add(-1, 0); LOG.ignore(e); } return; } } @Override public void dump(Appendable out, String indent) throws IOException { Dumpable.dumpObjects(out, indent, this, new DumpableCollection("threads", _threads.stream() .filter(ReservedThread::isReserved) .collect(Collectors.toList()))); } @Override public String toString() { return String.format("%s@%x{reserved=%d/%d,pending=%d}", getClass().getSimpleName(), hashCode(), _count.getLo(), _capacity, _count.getHi()); } private enum State { PENDING, RESERVED, RUNNING, IDLE, STOPPED } private class ReservedThread implements Runnable { // The state and thread are kept only for dumping private volatile State _state = State.PENDING; private volatile Thread _thread; private boolean isReserved() { return _state == State.RESERVED; } private Runnable reservedWait() { if (LOG.isDebugEnabled()) LOG.debug("{} waiting {}", this, ReservedThreadExecutor.this); // Keep waiting until stopped, tasked or idle while (_count.getLo() >= 0) { try { // Always poll at some period as safety to ensure we don't poll forever. Runnable task = _queue.poll(_idleTimeNanos, NANOSECONDS); if (LOG.isDebugEnabled()) LOG.debug("{} task={} {}", this, task, ReservedThreadExecutor.this); if (task != null) return task; // we have idled out int size = _count.getLo(); // decrement size if we have not also been stopped. while (size > 0) { if (_count.compareAndSetLo(size, --size)) break; size = _count.getLo(); } _state = size >= 0 ? State.IDLE : State.STOPPED; return STOP; } catch (InterruptedException e) { LOG.ignore(e); } } _state = State.STOPPED; return STOP; } @Override public void run() { _thread = Thread.currentThread(); try { while (true) { long count = _count.get(); // reduce pending if this thread was pending int pending = getHi(count) - (_state == State.PENDING ? 1 : 0); int size = getLo(count); State next; if (size < 0 || size >= _capacity) { // The executor has stopped or this thread is excess to capacity next = State.STOPPED; } else { long now = System.nanoTime(); long lastEmpty = _lastEmptyTime.get(); if (size > 0 && _idleTimeNanos < (now - lastEmpty) && _lastEmptyTime.compareAndSet(lastEmpty, now)) { // it has been too long since we hit zero reserved threads, so are "busy" idle next = State.IDLE; } else { // We will become a reserved thread if we can update the count below. next = State.RESERVED; size++; } } // Update count for pending and size if (!_count.compareAndSet(count, pending, size)) continue; if (LOG.isDebugEnabled()) LOG.debug("{} was={} next={} size={}+{} capacity={}", this, _state, next, pending, size, _capacity); _state = next; if (next != State.RESERVED) break; // We are reserved whilst we are waiting for an offered _task. Runnable task = reservedWait(); // Is the task the STOP poison pill? if (task == STOP) break; // Run the task try { _state = State.RUNNING; task.run(); } catch (Throwable e) { LOG.warn("Unable to run task", e); } finally { // Clear any interrupted status. Thread.interrupted(); } } } finally { if (LOG.isDebugEnabled()) LOG.debug("{} exited {}", this, ReservedThreadExecutor.this); _threads.remove(this); _thread = null; } } @Override public String toString() { return String.format("%s@%x{%s,thread=%s}", getClass().getSimpleName(), hashCode(), _state, _thread); } } }




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