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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
//
// The Apache License v2.0 is available at
// http://www.opensource.org/licenses/apache2.0.php
//
// You may elect to redistribute this code under either of these licenses.
// ========================================================================
//
package org.eclipse.jetty.util;
import java.io.IOException;
import org.eclipse.jetty.util.thread.Locker;
/**
* This specialized callback implements a pattern that allows
* a large asynchronous task to be broken into smaller
* asynchronous sub-tasks using iteration rather than recursion.
*
* A typical example is the write of a large content to a socket,
* divided in chunks. Chunk C1 is written by thread T1, which
* also invokes the callback, which writes chunk C2, which invokes
* the callback again, which writes chunk C3, and so forth.
*
* The problem with the example above is that if the callback thread
* is the same that performs the I/O operation, then the process
* is recursive and may result in a stack overflow.
* To avoid the stack overflow, a thread dispatch must be performed,
* causing context switching and cache misses, affecting performance.
*
* To avoid this issue, this callback atomically records whether
* the callback for an asynchronous sub-task has been called
* during the processing of the asynchronous sub-task, and if so
* then the processing of the large asynchronous task iterates
* rather than recursing.
*
* Subclasses must implement method {@link #process()} where the
* asynchronous sub-task is initiated and a suitable {@link Action}
* is returned to this callback to indicate the overall progress of
* the large asynchronous task.
* This callback is passed to the asynchronous sub-task, and a call
* to {@link #succeeded()} on this callback represents the successful
* completion of the asynchronous sub-task, while a call to
* {@link #failed(Throwable)} on this callback represents the
* completion with a failure of the large asynchronous task.
*
* @deprecated The Eclipse Jetty and Apache Felix Http Jetty packages are no longer supported.
*/
@Deprecated(since = "2021-05-27")
public abstract class IteratingCallback implements Callback {
/**
* The internal states of this callback.
*/
private enum State {
/**
* This callback is idle, ready to iterate.
*/
IDLE,
/**
* This callback is just about to call {@link #process()},
* or within it, or just exited from it, either normally
* or by throwing.
*/
PROCESSING,
/**
* Method {@link #process()} returned {@link Action#SCHEDULED}
* and this callback is waiting for the asynchronous sub-task
* to complete.
*/
PENDING,
/**
* The asynchronous sub-task was completed successfully
* via a call to {@link #succeeded()} while in
* {@link #PROCESSING} state.
*/
CALLED,
/**
* The iteration terminated successfully as indicated by
* {@link Action#SUCCEEDED} returned from
* {@link IteratingCallback#process()}.
*/
SUCCEEDED,
/**
* The iteration terminated with a failure via a call
* to {@link IteratingCallback#failed(Throwable)}.
*/
FAILED,
/**
* This callback has been {@link #close() closed} and
* cannot be {@link #reset() reset}.
*/
CLOSED
}
/**
* The indication of the overall progress of the iteration
* that implementations of {@link #process()} must return.
*/
protected enum Action {
/**
* Indicates that {@link #process()} has no more work to do,
* but the iteration is not completed yet, probably waiting
* for additional events to trigger more work.
*/
IDLE,
/**
* Indicates that {@link #process()} has initiated an asynchronous
* sub-task, where the execution has started but the callback
* that signals the completion of the asynchronous sub-task
* may have not yet been invoked.
*/
SCHEDULED,
/**
* Indicates that {@link #process()} has completed the whole
* iteration successfully.
*/
SUCCEEDED
}
private Locker _locker = new Locker();
private State _state;
private Throwable _failure;
private boolean _iterate;
protected IteratingCallback() {
_state = State.IDLE;
}
protected IteratingCallback(boolean needReset) {
_state = needReset ? State.SUCCEEDED : State.IDLE;
}
/**
* Method called by {@link #iterate()} to process the asynchronous sub-task.
*
* Implementations must initiate the asynchronous execution of the sub-task
* (if any) and return an appropriate action:
*
* - {@link Action#IDLE} when no sub tasks are available for execution
* but the overall job is not completed yet
* - {@link Action#SCHEDULED} when the sub task asynchronous execution
* has been started
* - {@link Action#SUCCEEDED} when the overall job is completed
*
*
* @return the appropriate Action
* @throws Throwable if the sub-task processing throws
*/
protected abstract Action process() throws Throwable;
/**
* Invoked when the overall task has completed successfully.
*
* @see #onCompleteFailure(Throwable)
*/
protected void onCompleteSuccess() {
}
/**
* Invoked when the overall task has completed with a failure.
*
* @param cause the throwable to indicate cause of failure
* @see #onCompleteSuccess()
*/
protected void onCompleteFailure(Throwable cause) {
}
/**
* This method must be invoked by applications to start the processing
* of asynchronous sub-tasks.
*
* It can be called at any time by any thread, and its contract is that
* when called, then the {@link #process()} method will be called during
* or soon after, either by the calling thread or by another thread, but
* in either case by one thread only.
*/
public void iterate() {
boolean process = false;
try (Locker.Lock lock = _locker.lock()) {
switch(_state) {
case PENDING:
case CALLED:
// process will be called when callback is handled
break;
case IDLE:
_state = State.PROCESSING;
process = true;
break;
case PROCESSING:
_iterate = true;
break;
case FAILED:
case SUCCEEDED:
break;
case CLOSED:
default:
throw new IllegalStateException(toString());
}
}
if (process)
processing();
}
private void processing() {
// This should only ever be called when in processing state, however a failed or close call
// may happen concurrently, so state is not assumed.
boolean notifyCompleteSuccess = false;
Throwable notifyCompleteFailure = null;
// While we are processing
processing: while (true) {
// Call process to get the action that we have to take.
Action action = null;
try {
action = process();
} catch (Throwable x) {
failed(x);
// Fall through to possibly invoke onCompleteFailure().
}
// acted on the action we have just received
try (Locker.Lock lock = _locker.lock()) {
switch(_state) {
case PROCESSING:
{
if (action != null) {
switch(action) {
case IDLE:
{
// Has iterate been called while we were processing?
if (_iterate) {
// yes, so skip idle and keep processing
_iterate = false;
continue;
}
// No, so we can go idle
_state = State.IDLE;
break processing;
}
case SCHEDULED:
{
// we won the race against the callback, so the callback has to process and we can break processing
_state = State.PENDING;
break processing;
}
case SUCCEEDED:
{
// we lost the race against the callback,
_iterate = false;
_state = State.SUCCEEDED;
notifyCompleteSuccess = true;
break processing;
}
default:
{
break;
}
}
}
throw new IllegalStateException(String.format("%s[action=%s]", this, action));
}
case CALLED:
{
if (action != Action.SCHEDULED)
throw new IllegalStateException(String.format("%s[action=%s]", this, action));
// we lost the race, so we have to keep processing
_state = State.PROCESSING;
continue;
}
case FAILED:
case CLOSED:
notifyCompleteFailure = _failure;
_failure = null;
break processing;
case SUCCEEDED:
break processing;
case IDLE:
case PENDING:
default:
throw new IllegalStateException(String.format("%s[action=%s]", this, action));
}
}
}
if (notifyCompleteSuccess)
onCompleteSuccess();
else if (notifyCompleteFailure != null)
onCompleteFailure(notifyCompleteFailure);
}
/**
* Method to invoke when the asynchronous sub-task succeeds.
*
* Subclasses that override this method must always remember
* to call {@code super.succeeded()}.
*/
@Override
public void succeeded() {
boolean process = false;
try (Locker.Lock lock = _locker.lock()) {
switch(_state) {
case PROCESSING:
{
_state = State.CALLED;
break;
}
case PENDING:
{
_state = State.PROCESSING;
process = true;
break;
}
case CLOSED:
case FAILED:
{
// Too late!
break;
}
default:
{
throw new IllegalStateException(toString());
}
}
}
if (process)
processing();
}
/**
* Method to invoke when the asynchronous sub-task fails,
* or to fail the overall asynchronous task and therefore
* terminate the iteration.
*
* Subclasses that override this method must always remember
* to call {@code super.failed(Throwable)}.
*
* Eventually, {@link #onCompleteFailure(Throwable)} is
* called, either by the caller thread or by the processing
* thread.
*
* @see #isFailed()
*/
@Override
public void failed(Throwable x) {
boolean failure = false;
try (Locker.Lock lock = _locker.lock()) {
switch(_state) {
case SUCCEEDED:
case FAILED:
case IDLE:
case CLOSED:
case CALLED:
// too late!.
break;
case PENDING:
{
_state = State.FAILED;
failure = true;
break;
}
case PROCESSING:
{
_state = State.FAILED;
_failure = x;
break;
}
default:
throw new IllegalStateException(toString());
}
}
if (failure)
onCompleteFailure(x);
}
/**
* Method to invoke to forbid further invocations to {@link #iterate()}
* and {@link #reset()}.
*
* When this method is invoked during processing, it behaves like invoking
* {@link #failed(Throwable)}.
*
* @see #isClosed()
*/
public void close() {
String failure = null;
try (Locker.Lock lock = _locker.lock()) {
switch(_state) {
case IDLE:
case SUCCEEDED:
case FAILED:
_state = State.CLOSED;
break;
case PROCESSING:
_failure = new IOException(String.format("Close %s in state %s", this, _state));
_state = State.CLOSED;
break;
case CLOSED:
break;
default:
failure = String.format("Close %s in state %s", this, _state);
_state = State.CLOSED;
break;
}
}
if (failure != null)
onCompleteFailure(new IOException(failure));
}
/**
* @return whether this callback is idle, and {@link #iterate()} needs to be called
*/
boolean isIdle() {
try (Locker.Lock lock = _locker.lock()) {
return _state == State.IDLE;
}
}
/**
* @return whether this callback has been {@link #close() closed}
*/
public boolean isClosed() {
try (Locker.Lock lock = _locker.lock()) {
return _state == State.CLOSED;
}
}
/**
* @return whether this callback has been {@link #failed(Throwable) failed}
*/
public boolean isFailed() {
try (Locker.Lock lock = _locker.lock()) {
return _state == State.FAILED;
}
}
/**
* @return whether this callback and the overall asynchronous task has been succeeded
*
* @see #onCompleteSuccess()
*/
public boolean isSucceeded() {
try (Locker.Lock lock = _locker.lock()) {
return _state == State.SUCCEEDED;
}
}
/**
* Resets this callback.
*
* A callback can only be reset to the idle state from the
* {@link #isSucceeded() succeeded} or {@link #isFailed() failed} states
* or if it is already idle.
*
* @return true if the reset was successful
*/
public boolean reset() {
try (Locker.Lock lock = _locker.lock()) {
switch(_state) {
case IDLE:
return true;
case SUCCEEDED:
case FAILED:
_state = State.IDLE;
_failure = null;
_iterate = false;
return true;
default:
return false;
}
}
}
@Override
public String toString() {
return String.format("%s@%x[%s]", getClass().getSimpleName(), hashCode(), _state);
}
}