org.HdrHistogram_voltpatches.Recorder Maven / Gradle / Ivy
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/**
* Written by Gil Tene of Azul Systems, and released to the public domain,
* as explained at http://creativecommons.org/publicdomain/zero/1.0/
*
* @author Gil Tene
*/
package org.HdrHistogram_voltpatches;
import java.util.concurrent.atomic.AtomicLong;
/**
* Records integer values, and provides stable interval {@link Histogram} samples from
* live recorded data without interrupting or stalling active recording of values. Each interval
* histogram provided contains all value counts accumulated since the previous interval histogram
* was taken.
*
* This pattern is commonly used in logging interval histogram information while recording is ongoing.
*
* {@link Recorder} supports concurrent
* {@link Recorder#recordValue} or
* {@link Recorder#recordValueWithExpectedInterval} calls.
* Recording calls are wait-free on architectures that support atomic increment operations, and
* are lock-free on architectures that do not.
*
*/
public class Recorder {
private static AtomicLong instanceIdSequencer = new AtomicLong(1);
private final long instanceId = instanceIdSequencer.getAndIncrement();
private final WriterReaderPhaser recordingPhaser = new WriterReaderPhaser();
private volatile Histogram activeHistogram;
private Histogram inactiveHistogram;
/**
* Construct an auto-resizing {@link Recorder} with a lowest discernible value of
* 1 and an auto-adjusting highestTrackableValue. Can auto-resize up to track values up to (Long.MAX_VALUE / 2).
*
* @param numberOfSignificantValueDigits Specifies the precision to use. This is the number of significant
* decimal digits to which the histogram will maintain value resolution
* and separation. Must be a non-negative integer between 0 and 5.
*/
public Recorder(final int numberOfSignificantValueDigits) {
activeHistogram = new InternalConcurrentHistogram(instanceId, numberOfSignificantValueDigits);
inactiveHistogram = new InternalConcurrentHistogram(instanceId, numberOfSignificantValueDigits);
activeHistogram.setStartTimeStamp(System.currentTimeMillis());
}
/**
* Construct a {@link Recorder} given the highest value to be tracked and a number of significant
* decimal digits. The histogram will be constructed to implicitly track (distinguish from 0) values as low as 1.
*
* @param highestTrackableValue The highest value to be tracked by the histogram. Must be a positive
* integer that is {@literal >=} 2.
* @param numberOfSignificantValueDigits Specifies the precision to use. This is the number of significant
* decimal digits to which the histogram will maintain value resolution
* and separation. Must be a non-negative integer between 0 and 5.
*/
public Recorder(final long highestTrackableValue,
final int numberOfSignificantValueDigits) {
this(1, highestTrackableValue, numberOfSignificantValueDigits);
}
/**
* Construct a {@link Recorder} given the Lowest and highest values to be tracked and a number
* of significant decimal digits. Providing a lowestDiscernibleValue is useful is situations where the units used
* for the histogram's values are much smaller that the minimal accuracy required. E.g. when tracking
* time values stated in nanosecond units, where the minimal accuracy required is a microsecond, the
* proper value for lowestDiscernibleValue would be 1000.
*
* @param lowestDiscernibleValue The lowest value that can be tracked (distinguished from 0) by the histogram.
* Must be a positive integer that is {@literal >=} 1. May be internally rounded
* down to nearest power of 2.
* @param highestTrackableValue The highest value to be tracked by the histogram. Must be a positive
* integer that is {@literal >=} (2 * lowestDiscernibleValue).
* @param numberOfSignificantValueDigits Specifies the precision to use. This is the number of significant
* decimal digits to which the histogram will maintain value resolution
* and separation. Must be a non-negative integer between 0 and 5.
*/
public Recorder(final long lowestDiscernibleValue,
final long highestTrackableValue,
final int numberOfSignificantValueDigits) {
activeHistogram = new InternalAtomicHistogram(
instanceId, lowestDiscernibleValue, highestTrackableValue, numberOfSignificantValueDigits);
inactiveHistogram = new InternalAtomicHistogram(
instanceId, lowestDiscernibleValue, highestTrackableValue, numberOfSignificantValueDigits);
activeHistogram.setStartTimeStamp(System.currentTimeMillis());
}
/**
* Record a value
* @param value the value to record
* @throws ArrayIndexOutOfBoundsException (may throw) if value is exceeds highestTrackableValue
*/
public void recordValue(final long value) throws ArrayIndexOutOfBoundsException {
long criticalValueAtEnter = recordingPhaser.writerCriticalSectionEnter();
try {
activeHistogram.recordValue(value);
} finally {
recordingPhaser.writerCriticalSectionExit(criticalValueAtEnter);
}
}
/**
* Record a value in the histogram (adding to the value's current count)
*
* @param value The value to be recorded
* @param count The number of occurrences of this value to record
* @throws ArrayIndexOutOfBoundsException (may throw) if value is exceeds highestTrackableValue
*/
public void recordValueWithCount(final long value, final long count) throws ArrayIndexOutOfBoundsException {
long criticalValueAtEnter = recordingPhaser.writerCriticalSectionEnter();
try {
activeHistogram.recordValueWithCount(value, count);
} finally {
recordingPhaser.writerCriticalSectionExit(criticalValueAtEnter);
}
}
/**
* Record a value
*
* To compensate for the loss of sampled values when a recorded value is larger than the expected
* interval between value samples, Histogram will auto-generate an additional series of decreasingly-smaller
* (down to the expectedIntervalBetweenValueSamples) value records.
*
* See related notes {@link AbstractHistogram#recordValueWithExpectedInterval(long, long)}
* for more explanations about coordinated omission and expected interval correction.
* *
* @param value The value to record
* @param expectedIntervalBetweenValueSamples If expectedIntervalBetweenValueSamples is larger than 0, add
* auto-generated value records as appropriate if value is larger
* than expectedIntervalBetweenValueSamples
* @throws ArrayIndexOutOfBoundsException (may throw) if value is exceeds highestTrackableValue
*/
public void recordValueWithExpectedInterval(final long value, final long expectedIntervalBetweenValueSamples)
throws ArrayIndexOutOfBoundsException {
long criticalValueAtEnter = recordingPhaser.writerCriticalSectionEnter();
try {
activeHistogram.recordValueWithExpectedInterval(value, expectedIntervalBetweenValueSamples);
} finally {
recordingPhaser.writerCriticalSectionExit(criticalValueAtEnter);
}
}
/**
* Get a new instance of an interval histogram, which will include a stable, consistent view of all value
* counts accumulated since the last interval histogram was taken.
*
* Calling {@link Recorder#getIntervalHistogram()} will reset
* the value counts, and start accumulating value counts for the next interval.
*
* @return a histogram containing the value counts accumulated since the last interval histogram was taken.
*/
public synchronized Histogram getIntervalHistogram() {
return getIntervalHistogram(null);
}
/**
* Get an interval histogram, which will include a stable, consistent view of all value counts
* accumulated since the last interval histogram was taken.
*
* {@link Recorder#getIntervalHistogram(Histogram histogramToRecycle)
* getIntervalHistogram(histogramToRecycle)}
* accepts a previously returned interval histogram that can be recycled internally to avoid allocation
* and content copying operations, and is therefore significantly more efficient for repeated use than
* {@link Recorder#getIntervalHistogram()} and
* {@link Recorder#getIntervalHistogramInto getIntervalHistogramInto()}. The provided
* {@code histogramToRecycle} must
* be either be null or an interval histogram returned by a previous call to
* {@link Recorder#getIntervalHistogram(Histogram histogramToRecycle)
* getIntervalHistogram(histogramToRecycle)} or
* {@link Recorder#getIntervalHistogram()}.
*
* NOTE: The caller is responsible for not recycling the same returned interval histogram more than once. If
* the same interval histogram instance is recycled more than once, behavior is undefined.
*
* Calling {@link Recorder#getIntervalHistogram(Histogram histogramToRecycle)
* getIntervalHistogram(histogramToRecycle)} will reset the value counts, and start accumulating value
* counts for the next interval
*
* @param histogramToRecycle a previously returned interval histogram that may be recycled to avoid allocation and
* copy operations.
* @return a histogram containing the value counts accumulated since the last interval histogram was taken.
*/
public synchronized Histogram getIntervalHistogram(Histogram histogramToRecycle) {
// Verify that replacement histogram can validly be used as an inactive histogram replacement:
validateFitAsReplacementHistogram(histogramToRecycle);
inactiveHistogram = histogramToRecycle;
performIntervalSample();
Histogram sampledHistogram = inactiveHistogram;
inactiveHistogram = null; // Once we expose the sample, we can't reuse it internally until it is recycled
return sampledHistogram;
}
/**
* Place a copy of the value counts accumulated since accumulated (since the last interval histogram
* was taken) into {@code targetHistogram}.
*
* Calling {@link Recorder#getIntervalHistogramInto getIntervalHistogramInto()} will reset
* the value counts, and start accumulating value counts for the next interval.
*
* @param targetHistogram the histogram into which the interval histogram's data should be copied
*/
public synchronized void getIntervalHistogramInto(Histogram targetHistogram) {
performIntervalSample();
inactiveHistogram.copyInto(targetHistogram);
}
/**
* Reset any value counts accumulated thus far.
*/
public synchronized void reset() {
// the currently inactive histogram is reset each time we flip. So flipping twice resets both:
performIntervalSample();
performIntervalSample();
}
private void performIntervalSample() {
try {
recordingPhaser.readerLock();
// Make sure we have an inactive version to flip in:
if (inactiveHistogram == null) {
if (activeHistogram instanceof InternalAtomicHistogram) {
inactiveHistogram = new InternalAtomicHistogram(
instanceId,
activeHistogram.getLowestDiscernibleValue(),
activeHistogram.getHighestTrackableValue(),
activeHistogram.getNumberOfSignificantValueDigits());
} else {
inactiveHistogram = new InternalConcurrentHistogram(
instanceId,
activeHistogram.getNumberOfSignificantValueDigits());
}
}
inactiveHistogram.reset();
// Swap active and inactive histograms:
final Histogram tempHistogram = inactiveHistogram;
inactiveHistogram = activeHistogram;
activeHistogram = tempHistogram;
// Mark end time of previous interval and start time of new one:
long now = System.currentTimeMillis();
activeHistogram.setStartTimeStamp(now);
inactiveHistogram.setEndTimeStamp(now);
// Make sure we are not in the middle of recording a value on the previously active histogram:
// Flip phase to make sure no recordings that were in flight pre-flip are still active:
recordingPhaser.flipPhase(500000L /* yield in 0.5 msec units if needed */);
} finally {
recordingPhaser.readerUnlock();
}
}
private class InternalAtomicHistogram extends AtomicHistogram {
private final long containingInstanceId;
private InternalAtomicHistogram(long id,
long lowestDiscernibleValue,
long highestTrackableValue,
int numberOfSignificantValueDigits) {
super(lowestDiscernibleValue, highestTrackableValue, numberOfSignificantValueDigits);
this.containingInstanceId = id;
}
}
private class InternalConcurrentHistogram extends ConcurrentHistogram {
private final long containingInstanceId;
private InternalConcurrentHistogram(long id, int numberOfSignificantValueDigits) {
super(numberOfSignificantValueDigits);
this.containingInstanceId = id;
}
}
void validateFitAsReplacementHistogram(Histogram replacementHistogram) {
boolean bad = true;
if (replacementHistogram == null) {
bad = false;
} else if (replacementHistogram instanceof InternalAtomicHistogram) {
if ((activeHistogram instanceof InternalAtomicHistogram)
&&
(((InternalAtomicHistogram)replacementHistogram).containingInstanceId ==
((InternalAtomicHistogram)activeHistogram).containingInstanceId)
) {
bad = false;
}
} else if (replacementHistogram instanceof InternalConcurrentHistogram) {
if ((activeHistogram instanceof InternalConcurrentHistogram)
&&
(((InternalConcurrentHistogram)replacementHistogram).containingInstanceId ==
((InternalConcurrentHistogram)activeHistogram).containingInstanceId)
) {
bad = false;
}
}
if (bad) {
throw new IllegalArgumentException("replacement histogram must have been obtained via a previous" +
" getIntervalHistogram() call from this " + this.getClass().getName() +" instance");
}
}
}