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//
//  ========================================================================
//  Copyright (c) 1995-2018 Mort Bay Consulting Pty. Ltd.
//  ------------------------------------------------------------------------
//  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.http2;

import java.util.Map;
import java.util.concurrent.ConcurrentHashMap;
import java.util.concurrent.atomic.AtomicInteger;

import org.eclipse.jetty.http2.frames.Frame;
import org.eclipse.jetty.http2.frames.WindowUpdateFrame;
import org.eclipse.jetty.util.Atomics;
import org.eclipse.jetty.util.Callback;
import org.eclipse.jetty.util.annotation.ManagedAttribute;
import org.eclipse.jetty.util.annotation.ManagedObject;

/**
 * 

A flow control strategy that accumulates updates and emits window control * frames when the accumulated value reaches a threshold.

*

The sender flow control window is represented in the receiver as two * buckets: a bigger bucket, initially full, that is drained when data is * received, and a smaller bucket, initially empty, that is filled when data is * consumed. Only the smaller bucket can refill the bigger bucket.

*

The smaller bucket is defined as a fraction of the bigger bucket.

*

For a more visual representation, see the * rocking bamboo fountain.

*

The algorithm works in this way.

*

The initial bigger bucket (BB) capacity is 100, and let's imagine the smaller * bucket (SB) being 40% of the bigger bucket: 40.

*

The receiver receives a data frame of 60, so now BB=40; the data frame is * passed to the application that consumes 25, so now SB=25. Since SB is not full, * no window control frames are emitted.

*

The application consumes other 20, so now SB=45. Since SB is full, its 45 * are transferred to BB, which is now BB=85, and a window control frame is sent * with delta=45.

*

The application consumes the remaining 15, so now SB=15, and no window * control frame is emitted.

*/ @ManagedObject public class BufferingFlowControlStrategy extends AbstractFlowControlStrategy { private final AtomicInteger maxSessionRecvWindow = new AtomicInteger(DEFAULT_WINDOW_SIZE); private final AtomicInteger sessionLevel = new AtomicInteger(); private final Map streamLevels = new ConcurrentHashMap<>(); private float bufferRatio; public BufferingFlowControlStrategy(float bufferRatio) { this(DEFAULT_WINDOW_SIZE, bufferRatio); } public BufferingFlowControlStrategy(int initialStreamSendWindow, float bufferRatio) { super(initialStreamSendWindow); this.bufferRatio = bufferRatio; } @ManagedAttribute("The ratio between the receive buffer and the consume buffer") public float getBufferRatio() { return bufferRatio; } public void setBufferRatio(float bufferRatio) { this.bufferRatio = bufferRatio; } @Override public void onStreamCreated(IStream stream) { super.onStreamCreated(stream); streamLevels.put(stream, new AtomicInteger()); } @Override public void onStreamDestroyed(IStream stream) { streamLevels.remove(stream); super.onStreamDestroyed(stream); } @Override public void onDataConsumed(ISession session, IStream stream, int length) { if (length <= 0) return; float ratio = bufferRatio; int level = sessionLevel.addAndGet(length); int maxLevel = (int)(maxSessionRecvWindow.get() * ratio); if (level > maxLevel) { if (sessionLevel.compareAndSet(level, 0)) { session.updateRecvWindow(level); if (LOG.isDebugEnabled()) LOG.debug("Data consumed, {} bytes, updated session recv window by {}/{} for {}", length, level, maxLevel, session); session.frames(null, Callback.NOOP, new WindowUpdateFrame(0, level), Frame.EMPTY_ARRAY); } else { if (LOG.isDebugEnabled()) LOG.debug("Data consumed, {} bytes, concurrent session recv window level {}/{} for {}", length, sessionLevel, maxLevel, session); } } else { if (LOG.isDebugEnabled()) LOG.debug("Data consumed, {} bytes, session recv window level {}/{} for {}", length, level, maxLevel, session); } if (stream != null) { if (stream.isRemotelyClosed()) { if (LOG.isDebugEnabled()) LOG.debug("Data consumed, {} bytes, ignoring update stream recv window for remotely closed {}", length, stream); } else { AtomicInteger streamLevel = streamLevels.get(stream); if (streamLevel != null) { level = streamLevel.addAndGet(length); maxLevel = (int)(getInitialStreamRecvWindow() * ratio); if (level > maxLevel) { level = streamLevel.getAndSet(0); stream.updateRecvWindow(level); if (LOG.isDebugEnabled()) LOG.debug("Data consumed, {} bytes, updated stream recv window by {}/{} for {}", length, level, maxLevel, stream); session.frames(stream, Callback.NOOP, new WindowUpdateFrame(stream.getId(), level), Frame.EMPTY_ARRAY); } else { if (LOG.isDebugEnabled()) LOG.debug("Data consumed, {} bytes, stream recv window level {}/{} for {}", length, level, maxLevel, stream); } } } } } @Override public void windowUpdate(ISession session, IStream stream, WindowUpdateFrame frame) { super.windowUpdate(session, stream, frame); // Window updates cannot be negative. // The SettingsFrame.INITIAL_WINDOW_SIZE setting // only influences the *stream* window size. // Therefore the session window can only be enlarged, // and here we keep track of its max value. // Updating the max session recv window is done here // so that if a peer decides to send an unilateral // window update to enlarge the session window, // without the corresponding data consumption, here // we can track it. // Note that it is not perfect, since there is a time // window between the session recv window being updated // before the window update frame is sent, and the // invocation of this method: in between data may arrive // and reduce the session recv window size. // But eventually the max value will be seen. // Note that we cannot avoid the time window described // above by updating the session recv window from here // because there is a race between the sender and the // receiver: the sender may receive a window update and // send more data, while this method has not yet been // invoked; when the data is received the session recv // window may become negative and the connection will // be closed (per specification). if (frame.getStreamId() == 0) { int sessionWindow = session.updateRecvWindow(0); Atomics.updateMax(maxSessionRecvWindow, sessionWindow); } } @Override public String toString() { return String.format("%s@%x[ratio=%.2f,sessionLevel=%s,sessionStallTime=%dms,streamsStallTime=%dms]", getClass().getSimpleName(), hashCode(), bufferRatio, sessionLevel, getSessionStallTime(), getStreamsStallTime()); } }




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