org.glassfish.jersey.server.internal.monitoring.AggregatingTrimmer Maven / Gradle / Ivy
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package org.glassfish.jersey.server.internal.monitoring;
import java.util.Collection;
import java.util.List;
import java.util.Map;
import java.util.NavigableMap;
import java.util.SortedMap;
import java.util.concurrent.ConcurrentNavigableMap;
import java.util.concurrent.CopyOnWriteArrayList;
import java.util.concurrent.TimeUnit;
import java.util.concurrent.atomic.AtomicBoolean;
import static org.glassfish.jersey.server.internal.monitoring.ReservoirConstants.COLLISION_BUFFER_POWER;
import jersey.repackaged.com.google.common.collect.TreeMultimap;
/**
* An aggregating trimmer for sliding window measurements. This trimmer updates registered time reservoirs with the aggregated
* measurements for the values it trimmed.
*
* @author Stepan Vavra (stepan.vavra at oracle.com)
*/
class AggregatingTrimmer implements SlidingWindowTrimmer {
private final List> aggregatedReservoirListeners = new CopyOnWriteArrayList<>();
private TimeReservoir timeReservoirNotifier;
private final long startTime;
private final TimeUnit startUnitTime;
private final long chunkSize;
/**
* The lock that prevents other threads to trim the associated reservoir in parallel.
*/
private final AtomicBoolean locked = new AtomicBoolean(false);
/**
* Creates the trimmer that updates the registered time reservoirs with the aggregated measurements for the values it
* trimmed.
*
* @param startTime The start time that determines the offset for the chunks.
* @param startUnitTime The time unit of the start time.
* @param chunkTimeSize The size of one "time chunk".
* @param chunkTimeSizeUnit The time unit of the time chunk.
*/
public AggregatingTrimmer(final long startTime,
final TimeUnit startUnitTime,
final long chunkTimeSize,
final TimeUnit chunkTimeSizeUnit) {
this.startTime = startTime;
this.startUnitTime = startUnitTime;
this.chunkSize = TimeUnit.NANOSECONDS.convert(chunkTimeSize, chunkTimeSizeUnit) << COLLISION_BUFFER_POWER;
}
@Override
public void trim(final ConcurrentNavigableMap map, final long key) {
if (!locked.compareAndSet(false, true)) {
return;
}
final TreeMultimap trimMultiMap = TreeMultimap.create();
final NavigableMap> trimMap = trimMultiMap.asMap();
try {
final ConcurrentNavigableMap headMap = map.headMap(key);
while (!headMap.isEmpty()) {
// headMap itself is being accessed with updates from other threads
final Map.Entry entry = headMap.pollFirstEntry();
trimMultiMap.put(entry.getKey(), entry.getValue());
}
// now the headMap is trimmed...
} finally {
locked.set(false);
}
for (Map.Entry> firstEntry = trimMap.firstEntry(); firstEntry != null;
firstEntry = trimMap.firstEntry()) {
long chunkLowerBound = lowerBound(firstEntry.getKey());
long chunkUpperBound = upperBound(chunkLowerBound, key);
// now, we need to process and then remove entries at interval [chunkLowerBound, chunkUpperBound)
SortedMap> chunkMap = trimMap.headMap(chunkUpperBound);
final AggregatedValueObject aggregatedValueObject = AggregatedValueObject.createFromMultiValues(chunkMap.values());
// update all listening aggregated reservoirs
for (TimeReservoir aggregatedReservoir : aggregatedReservoirListeners) {
aggregatedReservoir
.update(aggregatedValueObject, chunkLowerBound >> COLLISION_BUFFER_POWER, TimeUnit.NANOSECONDS);
}
// clean up the chunk, which also removes its items from the 'trimMap'
chunkMap.clear();
}
}
private long upperBound(final long chunkLowerBound, final long key) {
final long chunkUpperBoundCandidate = chunkLowerBound + chunkSize;
return chunkUpperBoundCandidate < key ? chunkUpperBoundCandidate : key;
}
private long lowerBound(final Long key) {
return lowerBound(key, TimeUnit.NANOSECONDS.convert(startTime, startUnitTime), chunkSize,
COLLISION_BUFFER_POWER);
}
/**
* Calculates lower bound for given key so that following conditions are true
*
* - {@code lowerBound <= key && key < lowerBound + chunkSize}
* - The lower bound is a multiple of chunk size with an offset calculated as {@code (startTime % chunkSize) <<
* power}
*
The power is used to shift the offset because all the keys are also expected * to be shifted with the power. * * @param key The key to find the lower bound for. * @param startTime The start time that determines the offset for the chunks. * @param chunkSize The size of one chunk. * @param power The power the keys are expected to be shifted with. * @return The lower bound for given arguments satisfying conditions stated above. */ static long lowerBound(final long key, final long startTime, final long chunkSize, final int power) { final long offset = (startTime % chunkSize) << power; if (key - offset >= 0) { return ((key - offset) / chunkSize * chunkSize) + offset; } else { return ((key - offset - chunkSize + 1)) / chunkSize * chunkSize + offset; } } /** * Registers given aggregating sliding window reservoir to get updates from this trimmer. * * @param timeReservoirListener The aggregated sliding window reservoir to update with trimmed measurements */ public void register(final TimeReservoir