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/*
 * Copyright (c) 2016 Cisco Systems, Inc. and others.  All rights reserved.
 *
 * This program and the accompanying materials are made available under the
 * terms of the Eclipse Public License v1.0 which accompanies this distribution,
 * and is available at http://www.eclipse.org/legal/epl-v10.html
 */

package org.opendaylight.controller.cluster.access.client;

import java.util.concurrent.TimeUnit;

/**
 * A ProgressTracker subclass which uses {@code ticksWorkedPerClosedTask} to compute delays.
 *
 * 

This class has {@code tasksOpenLimit} used as a (weak) limit, * as number of open tasks approaches that value, delays computed are increasing. * *

In order to keep {@code estimateIsolatedDelay} values from raising unreasonably high, * {@code defaultTicksPerTask} acts as a maximal value. {@code openTask} may return * higher value if there are tasks above the limit. * *

On the other hand, there is no delay when number of open tasks is half the limit or less, * in order to prevent backend from running out of tasks while there may be waiting frontend threads. * *

* This class is NOT thread-safe. * * @author Vratko Polak */ final class AveragingProgressTracker extends ProgressTracker { private static final long DEFAULT_TICKS_PER_TASK = TimeUnit.MILLISECONDS.toNanos(500); /** * The implementation will avoid having more that this number of tasks open. */ private final long tasksOpenLimit; /** * We do not delay tasks until their count hits this threshold. */ private final long noDelayThreshold; /** * Create an idle tracker with limit and specified ticks per task value to use as default. * * @param limit of open tasks to avoid exceeding * @param ticksPerTask value to use as default */ private AveragingProgressTracker(final long limit, final long ticksPerTask) { super(ticksPerTask); tasksOpenLimit = limit; noDelayThreshold = limit / 2; } /** * Create a default idle tracker with given limit. * * @param limit of open tasks to avoid exceeding */ AveragingProgressTracker(final long limit) { this(limit, DEFAULT_TICKS_PER_TASK); } /** * Construct a new tracker suitable for a new task queue related to a "reconnect". * *

The limit is set independently of the old tracker. * * @param oldTracker the tracker used for the previously used backend * @param limit of open tasks to avoid exceeding * @param now tick number corresponding to caller's present */ AveragingProgressTracker(final ProgressTracker oldTracker, final long limit, final long now) { super(oldTracker, now); tasksOpenLimit = limit; noDelayThreshold = limit / 2; } /** * Construct a new tracker suitable for a new task queue related to a "reconnect". * *

The limit is copied from the old tracker. * * @param oldTracker the tracker used for the previously used backend * @param now tick number corresponding to caller's present */ AveragingProgressTracker(final AveragingProgressTracker oldTracker, final long now) { this(oldTracker, oldTracker.tasksOpenLimit, now); } // Protected read-only methods /** * Give an estimate of a fair delay, assuming delays caused by other opened tasks are ignored. * *

This implementation returns zero delay if number of open tasks is half of limit or less. * Else the delay is computed, aiming to keep number of open tasks at 3/4 of limit, * assuming backend throughput remains constant. * *

As the number of open tasks approaches the limit, * the computed delay increases, but it never exceeds defaultTicksPerTask. * That means the actual number of open tasks can exceed the limit. * * @param now tick number corresponding to caller's present * @return delay (in ticks) after which another openTask() would be fair to be called by the same thread again */ @Override protected long estimateIsolatedDelay(final long now) { final long open = tasksOpen(); if (open <= noDelayThreshold) { return 0L; } if (open >= tasksOpenLimit) { return defaultTicksPerTask(); } /* * Calculate the task capacity relative to the limit on open tasks. In real terms this value can be * in the open interval (0.0, 0.5). */ final double relativeRemainingCapacity = 1.0 - (double) open / tasksOpenLimit; /* * Calculate delay coefficient. It increases in inverse proportion to relative remaining capacity, approaching * infinity as remaining capacity approaches 0.0. */ final double delayCoefficient = (0.5 - relativeRemainingCapacity) / relativeRemainingCapacity; final long delay = (long) (ticksWorkedPerClosedTask(now) * delayCoefficient); /* * Cap the result to defaultTicksPerTask, since the calculated delay may overstep it. */ return Math.min(delay, defaultTicksPerTask()); } }





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