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package org.apache.cassandra.db.partitions;

import java.io.IOException;
import java.nio.ByteBuffer;
import java.util.ArrayList;
import java.util.Iterator;
import java.util.List;

import com.google.common.collect.Iterables;
import com.google.common.collect.Lists;
import org.slf4j.Logger;
import org.slf4j.LoggerFactory;

import org.apache.cassandra.config.CFMetaData;
import org.apache.cassandra.config.ColumnDefinition;
import org.apache.cassandra.db.*;
import org.apache.cassandra.db.filter.ColumnFilter;
import org.apache.cassandra.db.rows.*;
import org.apache.cassandra.io.util.*;
import org.apache.cassandra.net.MessagingService;
import org.apache.cassandra.utils.FBUtilities;
import org.apache.cassandra.utils.btree.BTree;
import org.apache.cassandra.utils.btree.UpdateFunction;

/**
 * Stores updates made on a partition.
 * 

* A PartitionUpdate object requires that all writes/additions are performed before we * try to read the updates (attempts to write to the PartitionUpdate after a read method * has been called will result in an exception being thrown). In other words, a Partition * is mutable while it's written but becomes immutable as soon as it is read. *

* A typical usage is to create a new update ({@code new PartitionUpdate(metadata, key, columns, capacity)}) * and then add rows and range tombstones through the {@code add()} methods (the partition * level deletion time can also be set with {@code addPartitionDeletion()}). However, there * is also a few static helper constructor methods for special cases ({@code emptyUpdate()}, * {@code fullPartitionDelete} and {@code singleRowUpdate}). */ public class PartitionUpdate extends AbstractBTreePartition { protected static final Logger logger = LoggerFactory.getLogger(PartitionUpdate.class); public static final PartitionUpdateSerializer serializer = new PartitionUpdateSerializer(); private final int createdAtInSec = FBUtilities.nowInSeconds(); // Records whether this update is "built", i.e. if the build() method has been called, which // happens when the update is read. Further writing is then rejected though a manual call // to allowNewUpdates() allow new writes. We could make that more implicit but only triggers // really requires that so we keep it simple for now). private boolean isBuilt; private boolean canReOpen = true; private Holder holder; private BTree.Builder rowBuilder; private MutableDeletionInfo deletionInfo; private final boolean canHaveShadowedData; private PartitionUpdate(CFMetaData metadata, DecoratedKey key, PartitionColumns columns, MutableDeletionInfo deletionInfo, int initialRowCapacity, boolean canHaveShadowedData) { super(metadata, key); this.deletionInfo = deletionInfo; this.holder = new Holder(columns, BTree.empty(), deletionInfo, Rows.EMPTY_STATIC_ROW, EncodingStats.NO_STATS); this.canHaveShadowedData = canHaveShadowedData; rowBuilder = builder(initialRowCapacity); } private PartitionUpdate(CFMetaData metadata, DecoratedKey key, Holder holder, MutableDeletionInfo deletionInfo, boolean canHaveShadowedData) { super(metadata, key); this.holder = holder; this.deletionInfo = deletionInfo; this.isBuilt = true; this.canHaveShadowedData = canHaveShadowedData; } public PartitionUpdate(CFMetaData metadata, DecoratedKey key, PartitionColumns columns, int initialRowCapacity) { this(metadata, key, columns, MutableDeletionInfo.live(), initialRowCapacity, true); } public PartitionUpdate(CFMetaData metadata, ByteBuffer key, PartitionColumns columns, int initialRowCapacity) { this(metadata, metadata.decorateKey(key), columns, initialRowCapacity); } /** * Creates a empty immutable partition update. * * @param metadata the metadata for the created update. * @param key the partition key for the created update. * * @return the newly created empty (and immutable) update. */ public static PartitionUpdate emptyUpdate(CFMetaData metadata, DecoratedKey key) { MutableDeletionInfo deletionInfo = MutableDeletionInfo.live(); Holder holder = new Holder(PartitionColumns.NONE, BTree.empty(), deletionInfo, Rows.EMPTY_STATIC_ROW, EncodingStats.NO_STATS); return new PartitionUpdate(metadata, key, holder, deletionInfo, false); } /** * Creates an immutable partition update that entirely deletes a given partition. * * @param metadata the metadata for the created update. * @param key the partition key for the partition that the created update should delete. * @param timestamp the timestamp for the deletion. * @param nowInSec the current time in seconds to use as local deletion time for the partition deletion. * * @return the newly created partition deletion update. */ public static PartitionUpdate fullPartitionDelete(CFMetaData metadata, DecoratedKey key, long timestamp, int nowInSec) { MutableDeletionInfo deletionInfo = new MutableDeletionInfo(timestamp, nowInSec); Holder holder = new Holder(PartitionColumns.NONE, BTree.empty(), deletionInfo, Rows.EMPTY_STATIC_ROW, EncodingStats.NO_STATS); return new PartitionUpdate(metadata, key, holder, deletionInfo, false); } /** * Creates an immutable partition update that contains a single row update. * * @param metadata the metadata for the created update. * @param key the partition key for the partition to update. * @param row the row for the update. * * @return the newly created partition update containing only {@code row}. */ public static PartitionUpdate singleRowUpdate(CFMetaData metadata, DecoratedKey key, Row row) { MutableDeletionInfo deletionInfo = MutableDeletionInfo.live(); if (row.isStatic()) { Holder holder = new Holder(new PartitionColumns(Columns.from(row.columns()), Columns.NONE), BTree.empty(), deletionInfo, row, EncodingStats.NO_STATS); return new PartitionUpdate(metadata, key, holder, deletionInfo, false); } else { Holder holder = new Holder(new PartitionColumns(Columns.NONE, Columns.from(row.columns())), BTree.singleton(row), deletionInfo, Rows.EMPTY_STATIC_ROW, EncodingStats.NO_STATS); return new PartitionUpdate(metadata, key, holder, deletionInfo, false); } } /** * Creates an immutable partition update that contains a single row update. * * @param metadata the metadata for the created update. * @param key the partition key for the partition to update. * @param row the row for the update. * * @return the newly created partition update containing only {@code row}. */ public static PartitionUpdate singleRowUpdate(CFMetaData metadata, ByteBuffer key, Row row) { return singleRowUpdate(metadata, metadata.decorateKey(key), row); } /** * Turns the given iterator into an update. * * @param iterator the iterator to turn into updates. * @param filter the column filter used when querying {@code iterator}. This is used to make * sure we don't include data for which the value has been skipped while reading (as we would * then be writing something incorrect). * * Warning: this method does not close the provided iterator, it is up to * the caller to close it. */ public static PartitionUpdate fromIterator(UnfilteredRowIterator iterator, ColumnFilter filter) { iterator = UnfilteredRowIterators.withOnlyQueriedData(iterator, filter); Holder holder = build(iterator, 16); MutableDeletionInfo deletionInfo = (MutableDeletionInfo) holder.deletionInfo; return new PartitionUpdate(iterator.metadata(), iterator.partitionKey(), holder, deletionInfo, false); } /** * Turns the given iterator into an update. * * @param iterator the iterator to turn into updates. * @param filter the column filter used when querying {@code iterator}. This is used to make * sure we don't include data for which the value has been skipped while reading (as we would * then be writing something incorrect). * * Warning: this method does not close the provided iterator, it is up to * the caller to close it. */ public static PartitionUpdate fromIterator(RowIterator iterator, ColumnFilter filter) { iterator = RowIterators.withOnlyQueriedData(iterator, filter); MutableDeletionInfo deletionInfo = MutableDeletionInfo.live(); Holder holder = build(iterator, deletionInfo, true, 16); return new PartitionUpdate(iterator.metadata(), iterator.partitionKey(), holder, deletionInfo, false); } protected boolean canHaveShadowedData() { return canHaveShadowedData; } /** * Deserialize a partition update from a provided byte buffer. * * @param bytes the byte buffer that contains the serialized update. * @param version the version with which the update is serialized. * @param key the partition key for the update. This is only used if {@code version < 3.0} * and can be {@code null} otherwise. * * @return the deserialized update or {@code null} if {@code bytes == null}. */ public static PartitionUpdate fromBytes(ByteBuffer bytes, int version, DecoratedKey key) { if (bytes == null) return null; try { return serializer.deserialize(new DataInputBuffer(bytes, true), version, SerializationHelper.Flag.LOCAL, version < MessagingService.VERSION_30 ? key : null); } catch (IOException e) { throw new RuntimeException(e); } } /** * Serialize a partition update as a byte buffer. * * @param update the partition update to serialize. * @param version the version to serialize the update into. * * @return a newly allocated byte buffer containing the serialized update. */ public static ByteBuffer toBytes(PartitionUpdate update, int version) { try (DataOutputBuffer out = new DataOutputBuffer()) { serializer.serialize(update, out, version); return out.buffer(); } catch (IOException e) { throw new RuntimeException(e); } } /** * Creates a partition update that entirely deletes a given partition. * * @param metadata the metadata for the created update. * @param key the partition key for the partition that the created update should delete. * @param timestamp the timestamp for the deletion. * @param nowInSec the current time in seconds to use as local deletion time for the partition deletion. * * @return the newly created partition deletion update. */ public static PartitionUpdate fullPartitionDelete(CFMetaData metadata, ByteBuffer key, long timestamp, int nowInSec) { return fullPartitionDelete(metadata, metadata.decorateKey(key), timestamp, nowInSec); } /** * Merges the provided updates, yielding a new update that incorporates all those updates. * * @param updates the collection of updates to merge. This shouldn't be empty. * * @return a partition update that include (merge) all the updates from {@code updates}. */ public static PartitionUpdate merge(List updates) { assert !updates.isEmpty(); final int size = updates.size(); if (size == 1) return Iterables.getOnlyElement(updates); int nowInSecs = FBUtilities.nowInSeconds(); List asIterators = Lists.transform(updates, AbstractBTreePartition::unfilteredIterator); return fromIterator(UnfilteredRowIterators.merge(asIterators, nowInSecs), ColumnFilter.all(updates.get(0).metadata())); } /** * Modify this update to set every timestamp for live data to {@code newTimestamp} and * every deletion timestamp to {@code newTimestamp - 1}. * * There is no reason to use that expect on the Paxos code path, where we need ensure that * anything inserted use the ballot timestamp (to respect the order of update decided by * the Paxos algorithm). We use {@code newTimestamp - 1} for deletions because tombstones * always win on timestamp equality and we don't want to delete our own insertions * (typically, when we overwrite a collection, we first set a complex deletion to delete the * previous collection before adding new elements. If we were to set that complex deletion * to the same timestamp that the new elements, it would delete those elements). And since * tombstones always wins on timestamp equality, using -1 guarantees our deletion will still * delete anything from a previous update. */ public void updateAllTimestamp(long newTimestamp) { Holder holder = holder(); deletionInfo.updateAllTimestamp(newTimestamp - 1); Object[] tree = BTree.transformAndFilter(holder.tree, (x) -> x.updateAllTimestamp(newTimestamp)); Row staticRow = holder.staticRow.updateAllTimestamp(newTimestamp); EncodingStats newStats = EncodingStats.Collector.collect(staticRow, BTree.iterator(tree), deletionInfo); this.holder = new Holder(holder.columns, tree, deletionInfo, staticRow, newStats); } /** * The number of "operations" contained in the update. *

* This is used by {@code Memtable} to approximate how much work this update does. In practice, this * count how many rows are updated and how many ranges are deleted by the partition update. * * @return the number of "operations" performed by the update. */ public int operationCount() { return rowCount() + (staticRow().isEmpty() ? 0 : 1) + deletionInfo.rangeCount() + (deletionInfo.getPartitionDeletion().isLive() ? 0 : 1); } /** * The size of the data contained in this update. * * @return the size of the data contained in this update. */ public int dataSize() { int size = 0; for (Row row : this) { size += row.clustering().dataSize(); for (ColumnData cd : row) size += cd.dataSize(); } return size; } @Override public PartitionColumns columns() { // The superclass implementation calls holder(), but that triggers a build of the PartitionUpdate. But since // the columns are passed to the ctor, we know the holder always has the proper columns even if it doesn't have // the built rows yet, so just bypass the holder() method. return holder.columns; } protected Holder holder() { maybeBuild(); return holder; } public EncodingStats stats() { return holder().stats; } /** * If a partition update has been read (and is thus unmodifiable), a call to this method * makes the update modifiable again. *

* Please note that calling this method won't result in optimal behavior in the sense that * even if very little is added to the update after this call, the whole update will be sorted * again on read. This should thus be used sparingly (and if it turns that we end up using * this often, we should consider optimizing the behavior). */ public synchronized void allowNewUpdates() { if (!canReOpen) throw new IllegalStateException("You cannot do more updates on collectCounterMarks has been called"); // This is synchronized to make extra sure things work properly even if this is // called concurrently with sort() (which should be avoided in the first place, but // better safe than sorry). isBuilt = false; if (rowBuilder == null) rowBuilder = builder(16); } private BTree.Builder builder(int initialCapacity) { return BTree.builder(metadata.comparator, initialCapacity) .setQuickResolver((a, b) -> Rows.merge(a, b, createdAtInSec)); } /** * Returns an iterator that iterates over the rows of this update in clustering order. *

* Note that this might trigger a sorting of the update, and as such the update will not * be modifiable anymore after this call. * * @return an iterator over the rows of this update. */ @Override public Iterator iterator() { maybeBuild(); return super.iterator(); } /** * Validates the data contained in this update. * * @throws org.apache.cassandra.serializers.MarshalException if some of the data contained in this update is corrupted. */ public void validate() { for (Row row : this) { metadata().comparator.validate(row.clustering()); for (ColumnData cd : row) cd.validate(); } } /** * The maximum timestamp used in this update. * * @return the maximum timestamp used in this update. */ public long maxTimestamp() { maybeBuild(); long maxTimestamp = deletionInfo.maxTimestamp(); for (Row row : this) { maxTimestamp = Math.max(maxTimestamp, row.primaryKeyLivenessInfo().timestamp()); for (ColumnData cd : row) { if (cd.column().isSimple()) { maxTimestamp = Math.max(maxTimestamp, ((Cell)cd).timestamp()); } else { ComplexColumnData complexData = (ComplexColumnData)cd; maxTimestamp = Math.max(maxTimestamp, complexData.complexDeletion().markedForDeleteAt()); for (Cell cell : complexData) maxTimestamp = Math.max(maxTimestamp, cell.timestamp()); } } } return maxTimestamp; } /** * For an update on a counter table, returns a list containing a {@code CounterMark} for * every counter contained in the update. * * @return a list with counter marks for every counter in this update. */ public List collectCounterMarks() { assert metadata().isCounter(); maybeBuild(); // We will take aliases on the rows of this update, and update them in-place. So we should be sure the // update is now immutable for all intent and purposes. canReOpen = false; List marks = new ArrayList<>(); addMarksForRow(staticRow(), marks); for (Row row : this) addMarksForRow(row, marks); return marks; } private void addMarksForRow(Row row, List marks) { for (Cell cell : row.cells()) { if (cell.isCounterCell()) marks.add(new CounterMark(row, cell.column(), cell.path())); } } private void assertNotBuilt() { if (isBuilt) throw new IllegalStateException("An update should not be written again once it has been read"); } public void addPartitionDeletion(DeletionTime deletionTime) { assertNotBuilt(); deletionInfo.add(deletionTime); } public void add(RangeTombstone range) { assertNotBuilt(); deletionInfo.add(range, metadata.comparator); } /** * Adds a row to this update. * * There is no particular assumption made on the order of row added to a partition update. It is further * allowed to add the same row (more precisely, multiple row objects for the same clustering). * * Note however that the columns contained in the added row must be a subset of the columns used when * creating this update. * * @param row the row to add. */ public void add(Row row) { if (row.isEmpty()) return; assertNotBuilt(); if (row.isStatic()) { // this assert is expensive, and possibly of limited value; we should consider removing it // or introducing a new class of assertions for test purposes assert columns().statics.containsAll(row.columns()) : columns().statics + " is not superset of " + row.columns(); Row staticRow = holder.staticRow.isEmpty() ? row : Rows.merge(holder.staticRow, row, createdAtInSec); holder = new Holder(holder.columns, holder.tree, holder.deletionInfo, staticRow, holder.stats); } else { // this assert is expensive, and possibly of limited value; we should consider removing it // or introducing a new class of assertions for test purposes assert columns().regulars.containsAll(row.columns()) : columns().regulars + " is not superset of " + row.columns(); rowBuilder.add(row); } } private void maybeBuild() { if (isBuilt) return; build(); } private synchronized void build() { if (isBuilt) return; Holder holder = this.holder; Object[] cur = holder.tree; Object[] add = rowBuilder.build(); Object[] merged = BTree.merge(cur, add, metadata.comparator, UpdateFunction.Simple.of((a, b) -> Rows.merge(a, b, createdAtInSec))); assert deletionInfo == holder.deletionInfo; EncodingStats newStats = EncodingStats.Collector.collect(holder.staticRow, BTree.iterator(merged), deletionInfo); this.holder = new Holder(holder.columns, merged, holder.deletionInfo, holder.staticRow, newStats); rowBuilder = null; isBuilt = true; } @Override public String toString() { if (isBuilt) return super.toString(); // We intentionally override AbstractBTreePartition#toString() to avoid iterating over the rows in the // partition, which can result in build() being triggered and lead to errors if the PartitionUpdate is later // modified. StringBuilder sb = new StringBuilder(); sb.append(String.format("[%s.%s] key=%s columns=%s", metadata.ksName, metadata.cfName, metadata.getKeyValidator().getString(partitionKey().getKey()), columns())); sb.append("\n deletionInfo=").append(deletionInfo); sb.append(" (not built)"); return sb.toString(); } /** * Creates a new simple partition update builder. * * @param metadata the metadata for the table this is a partition of. * @param partitionKeyValues the values for partition key columns identifying this partition. The values for each * partition key column can be passed either directly as {@code ByteBuffer} or using a "native" value (int for * Int32Type, string for UTF8Type, ...). It is also allowed to pass a single {@code DecoratedKey} value directly. * @return a newly created builder. */ public static SimpleBuilder simpleBuilder(CFMetaData metadata, Object... partitionKeyValues) { return new SimpleBuilders.PartitionUpdateBuilder(metadata, partitionKeyValues); } /** * Interface for building partition updates geared towards human. *

* This should generally not be used when performance matters too much, but provides a more convenient interface to * build an update than using the class constructor when performance is not of the utmost importance. */ public interface SimpleBuilder { /** * The metadata of the table this is a builder on. */ public CFMetaData metadata(); /** * Sets the timestamp to use for the following additions to this builder or any derived (row) builder. * * @param timestamp the timestamp to use for following additions. If that timestamp hasn't been set, the current * time in microseconds will be used. * @return this builder. */ public SimpleBuilder timestamp(long timestamp); /** * Sets the ttl to use for the following additions to this builder or any derived (row) builder. * * @param ttl the ttl to use for following additions. If that ttl hasn't been set, no ttl will be used. * @return this builder. */ public SimpleBuilder ttl(int ttl); /** * Sets the current time to use for the following additions to this builder or any derived (row) builder. * * @param nowInSec the current time to use for following additions. If the current time hasn't been set, the current * time in seconds will be used. * @return this builder. */ public SimpleBuilder nowInSec(int nowInSec); /** * Adds the row identifier by the provided clustering and return a builder for that row. * * @param clusteringValues the value for the clustering columns of the row to add to this build. There may be no * values if either the table has no clustering column, or if you want to edit the static row. Note that as a * shortcut it is also allowed to pass a {@code Clustering} object directly, in which case that should be the * only argument. * @return a builder for the row identified by {@code clusteringValues}. */ public Row.SimpleBuilder row(Object... clusteringValues); /** * Deletes the partition identified by this builder (using a partition level deletion). * * @return this builder. */ public SimpleBuilder delete(); /** * Adds a new range tombstone to this update, returning a builder for that range. * * @return the range tombstone builder for the newly added range. */ public RangeTombstoneBuilder addRangeTombstone(); /** * Build the update represented by this builder. * * @return the built update. */ public PartitionUpdate build(); /** * As shortcut for {@code new Mutation(build())}. * * @return the built update, wrapped in a {@code Mutation}. */ public Mutation buildAsMutation(); /** * Interface to build range tombstone. * * By default, if no other methods are called, the represented range is inclusive of both start and end and * includes everything (its start is {@code BOTTOM} and it's end is {@code TOP}). */ public interface RangeTombstoneBuilder { /** * Sets the start for the built range using the provided values. * * @param values the value for the start of the range. They act like the {@code clusteringValues} argument * of the {@link SimpleBuilder#row(Object...)} method, except that it doesn't have to be a full * clustering, it can only be a prefix. * @return this builder. */ public RangeTombstoneBuilder start(Object... values); /** * Sets the end for the built range using the provided values. * * @param values the value for the end of the range. They act like the {@code clusteringValues} argument * of the {@link SimpleBuilder#row(Object...)} method, except that it doesn't have to be a full * clustering, it can only be a prefix. * @return this builder. */ public RangeTombstoneBuilder end(Object... values); /** * Sets the start of this range as inclusive. *

* This is the default and don't need to be called, but can for explicitness. * * @return this builder. */ public RangeTombstoneBuilder inclStart(); /** * Sets the start of this range as exclusive. * * @return this builder. */ public RangeTombstoneBuilder exclStart(); /** * Sets the end of this range as inclusive. *

* This is the default and don't need to be called, but can for explicitness. * * @return this builder. */ public RangeTombstoneBuilder inclEnd(); /** * Sets the end of this range as exclusive. * * @return this builder. */ public RangeTombstoneBuilder exclEnd(); } } public static class PartitionUpdateSerializer { public void serialize(PartitionUpdate update, DataOutputPlus out, int version) throws IOException { try (UnfilteredRowIterator iter = update.unfilteredIterator()) { assert !iter.isReverseOrder(); if (version < MessagingService.VERSION_30) { LegacyLayout.serializeAsLegacyPartition(null, iter, out, version); } else { CFMetaData.serializer.serialize(update.metadata(), out, version); UnfilteredRowIteratorSerializer.serializer.serialize(iter, null, out, version, update.rowCount()); } } } public PartitionUpdate deserialize(DataInputPlus in, int version, SerializationHelper.Flag flag, ByteBuffer key) throws IOException { if (version >= MessagingService.VERSION_30) { assert key == null; // key is only there for the old format return deserialize30(in, version, flag); } else { assert key != null; return deserializePre30(in, version, flag, key); } } // Used to share same decorated key between updates. public PartitionUpdate deserialize(DataInputPlus in, int version, SerializationHelper.Flag flag, DecoratedKey key) throws IOException { if (version >= MessagingService.VERSION_30) { return deserialize30(in, version, flag); } else { assert key != null; return deserializePre30(in, version, flag, key.getKey()); } } private static PartitionUpdate deserialize30(DataInputPlus in, int version, SerializationHelper.Flag flag) throws IOException { CFMetaData metadata = CFMetaData.serializer.deserialize(in, version); UnfilteredRowIteratorSerializer.Header header = UnfilteredRowIteratorSerializer.serializer.deserializeHeader(metadata, null, in, version, flag); if (header.isEmpty) return emptyUpdate(metadata, header.key); assert !header.isReversed; assert header.rowEstimate >= 0; MutableDeletionInfo.Builder deletionBuilder = MutableDeletionInfo.builder(header.partitionDeletion, metadata.comparator, false); BTree.Builder rows = BTree.builder(metadata.comparator, header.rowEstimate); rows.auto(false); try (UnfilteredRowIterator partition = UnfilteredRowIteratorSerializer.serializer.deserialize(in, version, metadata, flag, header)) { while (partition.hasNext()) { Unfiltered unfiltered = partition.next(); if (unfiltered.kind() == Unfiltered.Kind.ROW) rows.add((Row)unfiltered); else deletionBuilder.add((RangeTombstoneMarker)unfiltered); } } MutableDeletionInfo deletionInfo = deletionBuilder.build(); return new PartitionUpdate(metadata, header.key, new Holder(header.sHeader.columns(), rows.build(), deletionInfo, header.staticRow, header.sHeader.stats()), deletionInfo, false); } private static PartitionUpdate deserializePre30(DataInputPlus in, int version, SerializationHelper.Flag flag, ByteBuffer key) throws IOException { try (UnfilteredRowIterator iterator = LegacyLayout.deserializeLegacyPartition(in, version, flag, key)) { assert iterator != null; // This is only used in mutation, and mutation have never allowed "null" column families return PartitionUpdate.fromIterator(iterator, ColumnFilter.all(iterator.metadata())); } } public long serializedSize(PartitionUpdate update, int version) { try (UnfilteredRowIterator iter = update.unfilteredIterator()) { if (version < MessagingService.VERSION_30) return LegacyLayout.serializedSizeAsLegacyPartition(null, iter, version); return CFMetaData.serializer.serializedSize(update.metadata(), version) + UnfilteredRowIteratorSerializer.serializer.serializedSize(iter, null, version, update.rowCount()); } } } /** * A counter mark is basically a pointer to a counter update inside this partition update. That pointer allows * us to update the counter value based on the pre-existing value read during the read-before-write that counters * do. See {@link CounterMutation} to understand how this is used. */ public static class CounterMark { private final Row row; private final ColumnDefinition column; private final CellPath path; private CounterMark(Row row, ColumnDefinition column, CellPath path) { this.row = row; this.column = column; this.path = path; } public Clustering clustering() { return row.clustering(); } public ColumnDefinition column() { return column; } public CellPath path() { return path; } public ByteBuffer value() { return path == null ? row.getCell(column).value() : row.getCell(column, path).value(); } public void setValue(ByteBuffer value) { // This is a bit of a giant hack as this is the only place where we mutate a Row object. This makes it more efficient // for counters however and this won't be needed post-#6506 so that's probably fine. assert row instanceof BTreeRow; ((BTreeRow)row).setValue(column, path, value); } } }





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