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The Amazon Kinesis Video Streams Parser Library for Java enables Java developers to parse the streams
returned by GetMedia calls to Amazon Kinesis Video.
// Generated by delombok at Thu Mar 10 20:43:17 UTC 2022
/*
Copyright 2017-2017 Amazon.com, Inc. or its affiliates. All Rights Reserved.
Licensed under the Apache License, Version 2.0 (the "License").
You may not use this file except in compliance with the License.
A copy of the License is located at
http://aws.amazon.com/apache2.0/
or in the "license" file accompanying this file.
This file is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
See the License for the specific language governing permissions and limitations under the License.
*/
package com.amazonaws.kinesisvideo.parser.utilities;
import com.amazonaws.kinesisvideo.parser.ebml.EBMLTypeInfo;
import com.amazonaws.kinesisvideo.parser.ebml.MkvTypeInfos;
import com.amazonaws.kinesisvideo.parser.mkv.Frame;
import com.amazonaws.kinesisvideo.parser.mkv.MkvDataElement;
import com.amazonaws.kinesisvideo.parser.mkv.MkvElement;
import com.amazonaws.kinesisvideo.parser.mkv.MkvElementVisitException;
import com.amazonaws.kinesisvideo.parser.mkv.MkvElementVisitor;
import com.amazonaws.kinesisvideo.parser.mkv.MkvEndMasterElement;
import com.amazonaws.kinesisvideo.parser.mkv.MkvStartMasterElement;
import com.amazonaws.kinesisvideo.parser.mkv.visitors.CompositeMkvElementVisitor;
import com.amazonaws.kinesisvideo.parser.mkv.visitors.CountVisitor;
import com.google.common.collect.ImmutableList;
import org.apache.commons.lang3.Validate;
import java.io.ByteArrayOutputStream;
import java.io.IOException;
import java.io.OutputStream;
import java.math.BigInteger;
import java.nio.ByteBuffer;
import java.nio.channels.Channels;
import java.nio.channels.WritableByteChannel;
import java.util.ArrayList;
import java.util.Collections;
import java.util.List;
import java.util.Optional;
import java.util.stream.Collectors;
import static com.amazonaws.kinesisvideo.parser.utilities.OutputSegmentMerger.MergeState.BUFFERING_CLUSTER_START;
import static com.amazonaws.kinesisvideo.parser.utilities.OutputSegmentMerger.MergeState.EMITTING;
/**
* Merge the individual consecutive mkv streams output by a GetMedia call into one or more mkv streams.
* Each mkv stream has one segment.
* This class merges consecutive mkv streams as long as they share the same track and EBML information.
* It merges based on the elements that are the child elements of the track and EBML master elements.
* It collects all the child elements for each master element for each mkv stream.
* It compares the collected child elements of each master element in one mkv stream
* with the collected child elements of the same master element in the previous mkv stream.
* If the test passes for both thr track and EBML master elements in an mkv stream,
* its headers up to its first cluster are not emitted to the output stream, otherwise they are emitted.
* All data within or after cluster is emitted.
*
* The Merger can also be configured for different merging behaviors. See {@link Configuration}.
*/
public class OutputSegmentMerger extends CompositeMkvElementVisitor {
@SuppressWarnings("all")
private static final org.slf4j.Logger log = org.slf4j.LoggerFactory.getLogger(OutputSegmentMerger.class);
private final OutputStream outputStream;
private final List collectorStates;
private final Configuration configuration;
enum MergeState {
NEW, BUFFERING_SEGMENT, BUFFERING_CLUSTER_START, EMITTING, DONE;
}
private MergeState state = MergeState.NEW;
private final MergeVisitor mergeVisitor = new MergeVisitor();
private final ByteArrayOutputStream bufferingSegmentStream = new ByteArrayOutputStream();
private WritableByteChannel bufferingSegmentChannel;
private final ByteArrayOutputStream bufferingClusterStream = new ByteArrayOutputStream();
private WritableByteChannel bufferingClusterChannel;
private final CountVisitor countVisitor;
private final WritableByteChannel outputChannel;
private long emittedSegments = 0;
// fields for tracking cluster and cluster durations
private Optional lastClusterTimecode = Optional.empty();
private final List clusterFrameTimeCodes = new ArrayList<>();
public static final List DEFAULT_MASTER_ELEMENTS_TO_MERGE_ON = ImmutableList.of(MkvTypeInfos.TRACKS, MkvTypeInfos.EBML);
private static final ByteBuffer SEGMENT_ELEMENT_WITH_UNKNOWN_LENGTH = ByteBuffer.wrap(new byte[] {(byte) 24, (byte) 83, (byte) 128, (byte) 103, (byte) 1, (byte) 255, (byte) 255, (byte) 255, (byte) 255, (byte) 255, (byte) 255, (byte) 255});
private static final ByteBuffer VOID_ELEMENT_WITH_SIZE_ONE = ByteBuffer.wrap(new byte[] {(byte) 236, (byte) 129, (byte) 66});
private OutputSegmentMerger(final OutputStream outputStream, final CountVisitor countVisitor, final Configuration configuration) {
super(countVisitor);
childVisitors.add(mergeVisitor);
this.countVisitor = countVisitor;
this.outputStream = outputStream;
this.outputChannel = Channels.newChannel(this.outputStream);
this.bufferingSegmentChannel = Channels.newChannel(bufferingSegmentStream);
this.bufferingClusterChannel = Channels.newChannel(bufferingClusterStream);
this.collectorStates = configuration.typeInfosToMergeOn.stream().map(CollectorState::new).collect(Collectors.toList());
this.configuration = configuration;
}
/**
* Create an OutputSegmentMerger.
*
* @param outputStream The output stream to write the merged segments to.
* @param configuration Configuration options for how to manage merging.
* @return an OutputSegmentMerger that can be used to merge the segments from Kinesis Video that share a common header.
*/
public static OutputSegmentMerger create(final OutputStream outputStream, final Configuration configuration) {
return new OutputSegmentMerger(outputStream, getCountVisitor(), configuration);
}
/**
* Create an OutputSegmentMerger.
*
* @param outputStream The output stream to write the merged segments to.
* @return an OutputSegmentMerger that can be used to merge the segments from Kinesis Video that share a common header.
*/
public static OutputSegmentMerger createDefault(final OutputStream outputStream) {
return new OutputSegmentMerger(outputStream, getCountVisitor(), Configuration.builder().build());
}
/**
* Create an OutputSegmentMerger that stops emitting after detecting the first non matching segment.
*
* @param outputStream The output stream to write the merged segments to.
* @return an OutputSegmentMerger that can be used to merge the segments from Kinesis Video that share a common header.
* @deprecated Use {@link #create(OutputStream, Configuration)} instead.
*/
public static OutputSegmentMerger createToStopAtFirstNonMatchingSegment(final OutputStream outputStream) {
return new OutputSegmentMerger(outputStream, getCountVisitor(), Configuration.builder().stopAtFirstNonMatchingSegment(true).build());
}
/**
* Configuration options for modifying the behavior of the {@link OutputSegmentMerger}.
*/
public static class Configuration {
/**
* When true, the Merger will stop emitting data after detecting the first segment that does not match the
* previous segments. This is useful when the user wants the different merged mkv streams to go to different
* destinations such as files.
*/
private final boolean stopAtFirstNonMatchingSegment;
/**
* When true, the cluster timecodes will be modified to remove any gaps in the media between clusters. This is
* useful for merging sparse streams. Also starts the first cluster with a timecode of 0.
*
* When false, the cluster timecodes are not altered.
*/
private final boolean packClusters;
/**
*/
private final List typeInfosToMergeOn;
@SuppressWarnings("all")
private static boolean $default$stopAtFirstNonMatchingSegment() {
return false;
}
@SuppressWarnings("all")
private static boolean $default$packClusters() {
return false;
}
@SuppressWarnings("all")
private static List $default$typeInfosToMergeOn() {
return DEFAULT_MASTER_ELEMENTS_TO_MERGE_ON;
}
@SuppressWarnings("all")
Configuration(final boolean stopAtFirstNonMatchingSegment, final boolean packClusters, final List typeInfosToMergeOn) {
this.stopAtFirstNonMatchingSegment = stopAtFirstNonMatchingSegment;
this.packClusters = packClusters;
this.typeInfosToMergeOn = typeInfosToMergeOn;
}
@SuppressWarnings("all")
public static class ConfigurationBuilder {
@SuppressWarnings("all")
private boolean stopAtFirstNonMatchingSegment$set;
@SuppressWarnings("all")
private boolean stopAtFirstNonMatchingSegment$value;
@SuppressWarnings("all")
private boolean packClusters$set;
@SuppressWarnings("all")
private boolean packClusters$value;
@SuppressWarnings("all")
private boolean typeInfosToMergeOn$set;
@SuppressWarnings("all")
private List typeInfosToMergeOn$value;
@SuppressWarnings("all")
ConfigurationBuilder() {
}
/**
* When true, the Merger will stop emitting data after detecting the first segment that does not match the
* previous segments. This is useful when the user wants the different merged mkv streams to go to different
* destinations such as files.
* @return {@code this}.
*/
@SuppressWarnings("all")
public OutputSegmentMerger.Configuration.ConfigurationBuilder stopAtFirstNonMatchingSegment(final boolean stopAtFirstNonMatchingSegment) {
this.stopAtFirstNonMatchingSegment$value = stopAtFirstNonMatchingSegment;
stopAtFirstNonMatchingSegment$set = true;
return this;
}
/**
* When true, the cluster timecodes will be modified to remove any gaps in the media between clusters. This is
* useful for merging sparse streams. Also starts the first cluster with a timecode of 0.
*
* When false, the cluster timecodes are not altered.
* @return {@code this}.
*/
@SuppressWarnings("all")
public OutputSegmentMerger.Configuration.ConfigurationBuilder packClusters(final boolean packClusters) {
this.packClusters$value = packClusters;
packClusters$set = true;
return this;
}
/**
* @return {@code this}.
*/
@SuppressWarnings("all")
public OutputSegmentMerger.Configuration.ConfigurationBuilder typeInfosToMergeOn(final List typeInfosToMergeOn) {
this.typeInfosToMergeOn$value = typeInfosToMergeOn;
typeInfosToMergeOn$set = true;
return this;
}
@SuppressWarnings("all")
public OutputSegmentMerger.Configuration build() {
boolean stopAtFirstNonMatchingSegment$value = this.stopAtFirstNonMatchingSegment$value;
if (!this.stopAtFirstNonMatchingSegment$set) stopAtFirstNonMatchingSegment$value = Configuration.$default$stopAtFirstNonMatchingSegment();
boolean packClusters$value = this.packClusters$value;
if (!this.packClusters$set) packClusters$value = Configuration.$default$packClusters();
List typeInfosToMergeOn$value = this.typeInfosToMergeOn$value;
if (!this.typeInfosToMergeOn$set) typeInfosToMergeOn$value = Configuration.$default$typeInfosToMergeOn();
return new OutputSegmentMerger.Configuration(stopAtFirstNonMatchingSegment$value, packClusters$value, typeInfosToMergeOn$value);
}
@Override
@SuppressWarnings("all")
public String toString() {
return "OutputSegmentMerger.Configuration.ConfigurationBuilder(stopAtFirstNonMatchingSegment$value=" + this.stopAtFirstNonMatchingSegment$value + ", packClusters$value=" + this.packClusters$value + ", typeInfosToMergeOn$value=" + this.typeInfosToMergeOn$value + ")";
}
}
@SuppressWarnings("all")
public static OutputSegmentMerger.Configuration.ConfigurationBuilder builder() {
return new OutputSegmentMerger.Configuration.ConfigurationBuilder();
}
}
private static CountVisitor getCountVisitor() {
return CountVisitor.create(MkvTypeInfos.CLUSTER, MkvTypeInfos.SEGMENT, MkvTypeInfos.SIMPLEBLOCK);
}
public int getClustersCount() {
return countVisitor.getCount(MkvTypeInfos.CLUSTER);
}
public int getSegmentsCount() {
return countVisitor.getCount(MkvTypeInfos.SEGMENT);
}
public int getSimpleBlocksCount() {
return countVisitor.getCount(MkvTypeInfos.SIMPLEBLOCK);
}
@Override
public boolean isDone() {
return MergeState.DONE == state;
}
private class MergeVisitor extends MkvElementVisitor {
@Override
public void visit(final MkvStartMasterElement startMasterElement) throws MkvElementVisitException {
try {
switch (state) {
case NEW:
//Only the ebml header is expected in the new state
Validate.isTrue(MkvTypeInfos.EBML.equals(startMasterElement.getElementMetaData().getTypeInfo()), "EBML should be the only expected element type when a new MKV stream is expected");
log.info("Detected start of EBML element, transitioning from {} to BUFFERING", state);
//Change state to buffering and bufferAndCollect this element.
state = MergeState.BUFFERING_SEGMENT;
bufferAndCollect(startMasterElement);
break;
case BUFFERING_SEGMENT:
//if it is the cluster start element check if the buffered elements should be emitted and
// then change state to emitting, emit this the element as well.
final EBMLTypeInfo startElementTypeInfo = startMasterElement.getElementMetaData().getTypeInfo();
if (MkvTypeInfos.CLUSTER.equals(startElementTypeInfo) || MkvTypeInfos.TAGS.equals(startElementTypeInfo)) {
final boolean shouldEmitSegment = shouldEmitBufferedSegmentData();
if (shouldEmitSegment) {
if (configuration.stopAtFirstNonMatchingSegment && emittedSegments >= 1) {
log.info("Detected start of element {} transitioning from {} to DONE", startElementTypeInfo, state);
state = MergeState.DONE;
} else {
emitBufferedSegmentData(true);
resetChannels();
log.info("Detected start of element {} transitioning from {} to EMITTING", startElementTypeInfo, state);
state = EMITTING;
emit(startMasterElement);
}
} else {
log.info("Detected start of element {} transitioning from {} to BUFFERING_CLUSTER_START", startElementTypeInfo, state);
state = BUFFERING_CLUSTER_START;
bufferAndCollect(startMasterElement);
}
} else {
bufferAndCollect(startMasterElement);
}
break;
case BUFFERING_CLUSTER_START:
bufferAndCollect(startMasterElement);
break;
case EMITTING:
emit(startMasterElement);
break;
case DONE:
log.warn("OutputSegmentMerger is already done. It will not process any more elements.");
break;
}
} catch (final IOException ie) {
wrapIOException(ie);
}
}
private void wrapIOException(final IOException ie) throws MkvElementVisitException {
String exceptionMessage = "IOException in merge visitor ";
if (lastClusterTimecode.isPresent()) {
exceptionMessage += "in or immediately after cluster with timecode " + lastClusterTimecode.get();
} else {
exceptionMessage += "in first cluster";
}
throw new MkvElementVisitException(exceptionMessage, ie);
}
@Override
public void visit(final MkvEndMasterElement endMasterElement) throws MkvElementVisitException {
switch (state) {
case NEW:
Validate.isTrue(false, "Should not start with an EndMasterElement " + endMasterElement.toString());
break;
case BUFFERING_SEGMENT:
case BUFFERING_CLUSTER_START:
collect(endMasterElement);
break;
case EMITTING:
if (MkvTypeInfos.SEGMENT.equals(endMasterElement.getElementMetaData().getTypeInfo())) {
log.info("Detected end of segment element, transitioning from {} to NEW", state);
state = MergeState.NEW;
resetCollectors();
}
break;
case DONE:
log.warn("OutputSegmentMerger is already done. It will not process any more elements.");
break;
}
}
@Override
public void visit(final MkvDataElement dataElement) throws MkvElementVisitException {
try {
switch (state) {
case NEW:
Validate.isTrue(false, "Should not start with a data element " + dataElement.toString());
break;
case BUFFERING_SEGMENT:
bufferAndCollect(dataElement);
break;
case BUFFERING_CLUSTER_START:
if (MkvTypeInfos.TIMECODE.equals(dataElement.getElementMetaData().getTypeInfo())) {
final BigInteger currentTimeCode = (BigInteger) dataElement.getValueCopy().getVal();
if (lastClusterTimecode.isPresent() && currentTimeCode.compareTo(lastClusterTimecode.get()) <= 0) {
if (configuration.stopAtFirstNonMatchingSegment && emittedSegments >= 1) {
log.info("Detected time code going back from {} to {}, state from {} to DONE", lastClusterTimecode, currentTimeCode, state);
state = MergeState.DONE;
} else {
//emit buffered segment start
emitBufferedSegmentData(true);
}
}
if (!isDone()) {
emitClusterStart();
resetChannels();
state = EMITTING;
emitAdjustedTimeCode(dataElement);
}
} else {
bufferAndCollect(dataElement);
}
break;
case EMITTING:
if (MkvTypeInfos.TIMECODE.equals(dataElement.getElementMetaData().getTypeInfo())) {
emitAdjustedTimeCode(dataElement);
} else if (MkvTypeInfos.SIMPLEBLOCK.equals(dataElement.getElementMetaData().getTypeInfo())) {
emitFrame(dataElement);
} else {
emit(dataElement);
}
break;
case DONE:
log.warn("OutputSegmentMerger is already done. It will not process any more elements.");
break;
}
} catch (final IOException ie) {
wrapIOException(ie);
}
}
@Override
public boolean isDone() {
return MergeState.DONE == state;
}
}
private void emitClusterStart() throws IOException {
bufferingClusterChannel.close();
final int numBytes = outputChannel.write(ByteBuffer.wrap(bufferingClusterStream.toByteArray()));
log.debug("Wrote buffered cluster start data to output stream {} bytes", numBytes);
}
private void emitAdjustedTimeCode(final MkvDataElement timeCodeElement) throws MkvElementVisitException {
if (configuration.packClusters) {
final int dataSize = (int) timeCodeElement.getDataSize();
final BigInteger adjustedTimeCode;
if (lastClusterTimecode.isPresent()) {
// The timecode of the cluster should be the timecode of the previous cluster plus the previous cluster duration.
// c.timecode = (c-1).timecode + (c-1).duration
// However, neither the cluster nor the frames in the cluster have an explicit duration to use as the cluster
// duration. So, we calculate the frame duration as the difference between frame timecodes, and then add
// those durations to get the cluster duration. But this does not work for the last frame since there is
// no frame after it to take the diff with. So, we just estimate the frame duration as the average of all
// the other frame durations.
// Sort cluster frame timecodes (this handles b-frames)
Collections.sort(clusterFrameTimeCodes);
// Get frame durations
final List frameDurations = new ArrayList<>();
for (int i = 1; i < clusterFrameTimeCodes.size(); i++) {
frameDurations.add(clusterFrameTimeCodes.get(i) - clusterFrameTimeCodes.get(i - 1));
}
// Get average duration and add it to the other durations to account for the last frame
final int averageFrameDuration;
if (frameDurations.isEmpty()) {
averageFrameDuration = 1;
} else {
averageFrameDuration = frameDurations.stream().mapToInt(Integer::intValue).sum() / frameDurations.size();
}
frameDurations.add(averageFrameDuration);
// Sum up the frame durations to get the cluster duration
final int clusterDuration = frameDurations.stream().mapToInt(Integer::intValue).sum();
// Add duration to the previous cluster timecode
adjustedTimeCode = lastClusterTimecode.get().add(BigInteger.valueOf(clusterDuration));
} else {
// For the first cluster set the timecode to 0
adjustedTimeCode = BigInteger.valueOf(0L);
}
// When replacing the cluster timecode value, we want to use the same size data value so that parent element
// sizes are not impacted.
final byte[] newDataBytes = adjustedTimeCode.toByteArray();
Validate.isTrue(dataSize >= newDataBytes.length, "Adjusted timecode is not compatible with the existing data size");
final ByteBuffer newDataBuffer = ByteBuffer.allocate(dataSize);
newDataBuffer.position(dataSize - newDataBytes.length);
newDataBuffer.put(newDataBytes);
newDataBuffer.rewind();
final MkvDataElement adjustedTimeCodeElement = MkvDataElement.builder().idAndSizeRawBytes(timeCodeElement.getIdAndSizeRawBytes()).elementMetaData(timeCodeElement.getElementMetaData()).elementPath(timeCodeElement.getElementPath()).dataSize(timeCodeElement.getDataSize()).dataBuffer(newDataBuffer).build();
emit(adjustedTimeCodeElement);
lastClusterTimecode = Optional.of(adjustedTimeCode);
// Since we are at the start of a new cluster, reset the frame state from the previous cluster.
// Note: this could also be done directly on the "cluster start" event, but resetting the values here because
// they are currently only used for cluster packing, so keeping cluster packing code together.
clusterFrameTimeCodes.clear();
} else {
emit(timeCodeElement);
lastClusterTimecode = Optional.of((BigInteger) timeCodeElement.getValueCopy().getVal());
}
}
private void emitFrame(final MkvDataElement simpleBlockElement) throws MkvElementVisitException {
if (configuration.packClusters) {
final Frame frame = (Frame) simpleBlockElement.getValueCopy().getVal();
clusterFrameTimeCodes.add(frame.getTimeCode());
}
emit(simpleBlockElement);
}
private void bufferAndCollect(final MkvStartMasterElement startMasterElement) throws IOException, MkvElementVisitException {
Validate.isTrue(state == MergeState.BUFFERING_SEGMENT || state == MergeState.BUFFERING_CLUSTER_START, "Trying to buffer in wrong state " + state);
//Buffer and collect
if (MergeState.BUFFERING_SEGMENT == state) {
if (!collectorStates.isEmpty() && MkvTypeInfos.SEGMENT.equals(startMasterElement.getElementMetaData().getTypeInfo()) && !startMasterElement.isUnknownLength()) {
//if the start master element belongs to a segment that has a defined length,
//change it to one with an unknown length since we will be changing the length of the segment
//element.
SEGMENT_ELEMENT_WITH_UNKNOWN_LENGTH.rewind();
bufferingSegmentChannel.write(SEGMENT_ELEMENT_WITH_UNKNOWN_LENGTH);
} else {
startMasterElement.writeToChannel(bufferingSegmentChannel);
}
} else {
startMasterElement.writeToChannel(bufferingClusterChannel);
}
this.sendElementToAllCollectors(startMasterElement);
}
private void bufferAndCollect(final MkvDataElement dataElement) throws MkvElementVisitException {
Validate.isTrue(state == MergeState.BUFFERING_SEGMENT || state == MergeState.BUFFERING_CLUSTER_START, "Trying to buffer in wrong state " + state);
if (MergeState.BUFFERING_SEGMENT == state) {
writeToChannel(bufferingSegmentChannel, dataElement);
} else {
writeToChannel(bufferingClusterChannel, dataElement);
}
this.sendElementToAllCollectors(dataElement);
}
private static void writeToChannel(final WritableByteChannel byteChannel, final MkvDataElement dataElement) throws MkvElementVisitException {
dataElement.writeToChannel(byteChannel);
}
private void emit(final MkvStartMasterElement startMasterElement) throws MkvElementVisitException {
Validate.isTrue(state == EMITTING, "emitting in wrong state " + state);
startMasterElement.writeToChannel(outputChannel);
}
private void emit(final MkvDataElement dataElement) throws MkvElementVisitException {
Validate.isTrue(state == EMITTING, "emitting in wrong state " + state);
dataElement.writeToChannel(outputChannel);
}
private void collect(final MkvEndMasterElement endMasterElement) throws MkvElementVisitException {
//only trigger collectors since endelements do not have any data to buffer.
this.sendElementToAllCollectors(endMasterElement);
}
private void sendElementToAllCollectors(final MkvElement dataElement) throws MkvElementVisitException {
for (final CollectorState cs : collectorStates) {
dataElement.accept(cs.getCollector());
}
}
private void emitBufferedSegmentData(final boolean shouldEmitSegmentData) throws IOException {
bufferingSegmentChannel.close();
if (shouldEmitSegmentData) {
final int numBytes = outputChannel.write(ByteBuffer.wrap(bufferingSegmentStream.toByteArray()));
log.debug("Wrote buffered header data to output stream {} bytes", numBytes);
emittedSegments++;
} else {
//We can merge the segments, so we dont need to write the buffered headers
// However, we still need to introduce a dummy void element to prevent consumers
//getting confused by two consecutive elements of the same type.
VOID_ELEMENT_WITH_SIZE_ONE.rewind();
outputChannel.write(VOID_ELEMENT_WITH_SIZE_ONE);
}
}
private void resetChannels() {
bufferingSegmentStream.reset();
bufferingSegmentChannel = Channels.newChannel(bufferingSegmentStream);
bufferingClusterStream.reset();
bufferingClusterChannel = Channels.newChannel(bufferingClusterStream);
}
private boolean shouldEmitBufferedSegmentData() {
boolean doAllCollectorsMatchPreviousResults = false;
if (!collectorStates.isEmpty()) {
doAllCollectorsMatchPreviousResults = collectorStates.stream().allMatch(CollectorState::doCurrentAndOldResultsMatch);
}
log.info("Number of collectors {}. Did all collectors match previous results: {} ", collectorStates.size(), doAllCollectorsMatchPreviousResults);
return !doAllCollectorsMatchPreviousResults;
}
private void resetCollectors() {
collectorStates.forEach(CollectorState::reset);
}
private static class CollectorState {
private final EBMLTypeInfo parentTypeInfo;
private final MkvChildElementCollector collector;
private List previousResult = new ArrayList<>();
public CollectorState(final EBMLTypeInfo parentTypeInfo) {
this.parentTypeInfo = parentTypeInfo;
this.collector = new MkvChildElementCollector(parentTypeInfo);
}
public void reset() {
previousResult = collector.copyOfCollection();
collector.clearCollection();
}
boolean doCurrentAndOldResultsMatch() {
return collector.equivalent(previousResult);
}
@SuppressWarnings("all")
public EBMLTypeInfo getParentTypeInfo() {
return this.parentTypeInfo;
}
@SuppressWarnings("all")
public MkvChildElementCollector getCollector() {
return this.collector;
}
}
}