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The Apache Cassandra Project develops a highly scalable second-generation distributed database, bringing together Dynamo's fully distributed design and Bigtable's ColumnFamily-based data model.

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/*
 * Licensed to the Apache Software Foundation (ASF) under one
 * or more contributor license agreements.  See the NOTICE file
 * distributed with this work for additional information
 * regarding copyright ownership.  The ASF licenses this file
 * to you under the Apache License, Version 2.0 (the
 * "License"); you may not use this file except in compliance
 * with the License.  You may obtain a copy of the License at
 *
 *     http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License 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 org.apache.cassandra.schema;

import java.nio.ByteBuffer;
import java.util.ArrayList;
import java.util.Collections;
import java.util.EnumSet;
import java.util.HashMap;
import java.util.Iterator;
import java.util.LinkedHashSet;
import java.util.List;
import java.util.Map;
import java.util.Map.Entry;
import java.util.Objects;
import java.util.Optional;
import java.util.Set;
import javax.annotation.Nullable;

import com.google.common.base.MoreObjects;
import com.google.common.collect.ImmutableCollection;
import com.google.common.collect.ImmutableList;
import com.google.common.collect.ImmutableMap;
import com.google.common.collect.ImmutableSet;
import com.google.common.collect.Iterables;
import com.google.common.collect.Sets;
import org.slf4j.Logger;
import org.slf4j.LoggerFactory;

import org.apache.cassandra.auth.DataResource;
import org.apache.cassandra.config.DatabaseDescriptor;
import org.apache.cassandra.cql3.ColumnIdentifier;
import org.apache.cassandra.cql3.CqlBuilder;
import org.apache.cassandra.cql3.SchemaElement;
import org.apache.cassandra.cql3.functions.Function;
import org.apache.cassandra.cql3.functions.masking.ColumnMask;
import org.apache.cassandra.db.Clustering;
import org.apache.cassandra.db.ClusteringComparator;
import org.apache.cassandra.db.Columns;
import org.apache.cassandra.db.Directories;
import org.apache.cassandra.db.Keyspace;
import org.apache.cassandra.db.RegularAndStaticColumns;
import org.apache.cassandra.db.marshal.AbstractType;
import org.apache.cassandra.db.marshal.BytesType;
import org.apache.cassandra.db.marshal.CompositeType;
import org.apache.cassandra.db.marshal.EmptyType;
import org.apache.cassandra.db.marshal.UTF8Type;
import org.apache.cassandra.db.marshal.UserType;
import org.apache.cassandra.dht.IPartitioner;
import org.apache.cassandra.exceptions.ConfigurationException;
import org.apache.cassandra.exceptions.InvalidRequestException;
import org.apache.cassandra.service.reads.SpeculativeRetryPolicy;
import org.apache.cassandra.utils.AbstractIterator;
import org.github.jamm.Unmetered;

import static com.google.common.collect.Iterables.any;
import static com.google.common.collect.Iterables.transform;
import static java.lang.String.format;
import static java.util.stream.Collectors.toList;
import static java.util.stream.Collectors.toSet;
import static org.apache.cassandra.schema.IndexMetadata.isNameValid;

@Unmetered
public class TableMetadata implements SchemaElement
{
    private static final Logger logger = LoggerFactory.getLogger(TableMetadata.class);

    // Please note that currently the only one truly useful flag is COUNTER, as the rest of the flags were about
    // differencing between CQL tables and the various types of COMPACT STORAGE tables (pre-4.0). As those "compact"
    // tables are not supported anymore, no tables should be either SUPER or DENSE, and they should all be COMPOUND.
    public enum Flag
    {
        // As mentioned above, all tables on 4.0+ will have the COMPOUND flag, making the flag of little value. However,
        // on upgrade from pre-4.0, we want to detect if a tables does _not_ have this flag, in which case this would
        // be a compact table on which DROP COMPACT STORAGE has _not_ be used and fail startup. This is also why we
        // still write this flag for all tables. Once we drop support for upgrading from pre-4.0 versions (and so are
        // sure all tables do have the flag), we can stop writing this flag and ignore it when present (deprecate it).
        // Later, we'll be able to drop the flag from this enum completely.
        COMPOUND,
        DENSE,
        COUNTER,
        // The only reason we still have those is that on the first startup after an upgrade from pre-4.0, we cannot
        // guarantee some tables won't have those flags (users having forgotten to use DROP COMPACT STORAGE before
        // upgrading). So we still "deserialize" those flags correctly, but otherwise prevent startup if any table
        // have them. Once we drop support for upgrading from pre-4.0, we can remove those values.
        @Deprecated SUPER;

        /*
         *  We call dense a CF for which each component of the comparator is a clustering column, i.e. no
         * component is used to store a regular column names. In other words, non-composite static "thrift"
         * and CQL3 CF are *not* dense.
         */
        public static boolean isDense(Set flags)
        {
            return flags.contains(TableMetadata.Flag.DENSE);
        }

        public static boolean isCompound(Set flags)
        {
            return flags.contains(TableMetadata.Flag.COMPOUND);
        }


        public static boolean isSuper(Set flags)
        {
            return flags.contains(TableMetadata.Flag.SUPER);
        }

        public static boolean isCQLTable(Set flags)
        {
            return !isSuper(flags) && !isDense(flags) && isCompound(flags);
        }

        public static boolean isStaticCompactTable(Set flags)
        {
            return !Flag.isSuper(flags) && !Flag.isDense(flags) && !Flag.isCompound(flags);
        }

        public static Set fromStringSet(Set strings)
        {
            return strings.stream().map(String::toUpperCase).map(Flag::valueOf).collect(toSet());
        }

        public static Set toStringSet(Set flags)
        {
            return flags.stream().map(Flag::toString).map(String::toLowerCase).collect(toSet());
        }
    }

    public enum Kind
    {
        REGULAR, INDEX, VIEW, VIRTUAL
    }

    public final String keyspace;
    public final String name;
    public final TableId id;

    public final IPartitioner partitioner;
    public final Kind kind;
    public final TableParams params;
    public final ImmutableSet flags;

    @Nullable
    private final String indexName; // derived from table name

    /*
     * All CQL3 columns definition are stored in the columns map.
     * On top of that, we keep separated collection of each kind of definition, to
     * 1) allow easy access to each kind and
     * 2) for the partition key and clustering key ones, those list are ordered by the "component index" of the elements.
     */
    public final ImmutableMap droppedColumns;
    final ImmutableMap columns;

    protected final ImmutableList partitionKeyColumns;
    protected final ImmutableList clusteringColumns;
    protected final RegularAndStaticColumns regularAndStaticColumns;

    public final Indexes indexes;
    public final Triggers triggers;

    // derived automatically from flags and columns
    public final AbstractType partitionKeyType;
    public final ClusteringComparator comparator;

    // performance hacks; TODO see if all are really necessary
    public final DataResource resource;

    protected TableMetadata(Builder builder)
    {
        flags = Sets.immutableEnumSet(builder.flags);
        keyspace = builder.keyspace;
        name = builder.name;
        id = builder.id;

        partitioner = builder.partitioner;
        kind = builder.kind;
        params = builder.params.build();

        indexName = kind == Kind.INDEX ? name.substring(name.indexOf('.') + 1) : null;

        droppedColumns = ImmutableMap.copyOf(builder.droppedColumns);
        Collections.sort(builder.partitionKeyColumns);
        partitionKeyColumns = ImmutableList.copyOf(builder.partitionKeyColumns);
        Collections.sort(builder.clusteringColumns);
        clusteringColumns = ImmutableList.copyOf(builder.clusteringColumns);
        regularAndStaticColumns = RegularAndStaticColumns.builder().addAll(builder.regularAndStaticColumns).build();
        columns = ImmutableMap.copyOf(builder.columns);

        indexes = builder.indexes;
        triggers = builder.triggers;

        partitionKeyType = partitionKeyColumns.size() == 1
                         ? partitionKeyColumns.get(0).type
                         : CompositeType.getInstance(transform(partitionKeyColumns, t -> t.type));

        comparator = new ClusteringComparator(transform(clusteringColumns, c -> c.type));

        resource = DataResource.table(keyspace, name);
    }

    public static Builder builder(String keyspace, String table)
    {
        return new Builder(keyspace, table);
    }

    public static Builder builder(String keyspace, String table, TableId id)
    {
        return new Builder(keyspace, table, id);
    }

    public Builder unbuild()
    {
        return builder(keyspace, name, id)
               .partitioner(partitioner)
               .kind(kind)
               .params(params)
               .flags(flags)
               .addColumns(columns())
               .droppedColumns(droppedColumns)
               .indexes(indexes)
               .triggers(triggers);
    }

    public boolean isIndex()
    {
        return kind == Kind.INDEX;
    }

    public TableMetadata withSwapped(TableParams params)
    {
        return unbuild().params(params).build();
    }

    public TableMetadata withSwapped(Set flags)
    {
        return unbuild().flags(flags).build();
    }

    public TableMetadata withSwapped(Triggers triggers)
    {
        return unbuild().triggers(triggers).build();
    }

    public TableMetadata withSwapped(Indexes indexes)
    {
        return unbuild().indexes(indexes).build();
    }

    public boolean isView()
    {
        return kind == Kind.VIEW;
    }

    public boolean isVirtual()
    {
        return kind == Kind.VIRTUAL;
    }

    public Optional indexName()
    {
        return Optional.ofNullable(indexName);
    }

    public boolean isCounter()
    {
        return flags.contains(Flag.COUNTER);
    }

    public boolean isCompactTable()
    {
        return false;
    }
    
    public boolean isIncrementalBackupsEnabled()
    {
        return params.incrementalBackups;
    }

    public boolean isStaticCompactTable()
    {
        return false;
    }

    public ImmutableCollection columns()
    {
        return columns.values();
    }

    public Iterable primaryKeyColumns()
    {
        return Iterables.concat(partitionKeyColumns, clusteringColumns);
    }

    public ImmutableList partitionKeyColumns()
    {
        return partitionKeyColumns;
    }

    public ImmutableList clusteringColumns()
    {
        return clusteringColumns;
    }

    public RegularAndStaticColumns regularAndStaticColumns()
    {
        return regularAndStaticColumns;
    }

    public Columns regularColumns()
    {
        return regularAndStaticColumns.regulars;
    }

    public Columns staticColumns()
    {
        return regularAndStaticColumns.statics;
    }

    /*
     * An iterator over all column definitions but that respect the order of a SELECT *.
     */
    public Iterator allColumnsInSelectOrder()
    {
        Iterator partitionKeyIter = partitionKeyColumns.iterator();
        Iterator clusteringIter = clusteringColumns.iterator();
        Iterator otherColumns = regularAndStaticColumns.selectOrderIterator();

        return columnsIterator(partitionKeyIter, clusteringIter, otherColumns);
    }

    /**
     * Returns an iterator over all column definitions that respect the order of the CREATE statement.
     */
    public Iterator allColumnsInCreateOrder()
    {
        Iterator partitionKeyIter = partitionKeyColumns.iterator();
        Iterator clusteringIter = clusteringColumns.iterator();
        Iterator otherColumns = regularAndStaticColumns.iterator();

        return columnsIterator(partitionKeyIter, clusteringIter, otherColumns);
    }

    private static Iterator columnsIterator(Iterator partitionKeys,
                                                            Iterator clusteringColumns,
                                                            Iterator otherColumns)
    {
        return new AbstractIterator()
        {
            protected ColumnMetadata computeNext()
            {
                if (partitionKeys.hasNext())
                    return partitionKeys.next();

                if (clusteringColumns.hasNext())
                    return clusteringColumns.next();

                return otherColumns.hasNext() ? otherColumns.next() : endOfData();
            }
        };
    }

    /**
     * Returns the ColumnMetadata for {@code name}.
     */
    public ColumnMetadata getColumn(ColumnIdentifier name)
    {
        return columns.get(name.bytes);
    }
    /**
     * Returns the column of the provided name if it exists, but throws a user-visible exception if that column doesn't
     * exist.
     *
     * 

This method is for finding columns from a name provided by the user, and as such it does _not_ returne hidden * columns (throwing that the column is unknown instead). * * @param name the name of an existing non-hidden column of this table. * @return the column metadata corresponding to {@code name}. * * @throws InvalidRequestException if there is no non-hidden column named {@code name} in this table. */ public ColumnMetadata getExistingColumn(ColumnIdentifier name) { ColumnMetadata def = getColumn(name); if (def == null) throw new InvalidRequestException(format("Undefined column name %s in table %s", name.toCQLString(), this)); return def; } /* * In general it is preferable to work with ColumnIdentifier to make it * clear that we are talking about a CQL column, not a cell name, but there * is a few cases where all we have is a ByteBuffer (when dealing with IndexExpression * for instance) so... */ public ColumnMetadata getColumn(ByteBuffer name) { return columns.get(name); } public ColumnMetadata getDroppedColumn(ByteBuffer name) { DroppedColumn dropped = droppedColumns.get(name); return dropped == null ? null : dropped.column; } /** * Returns a "fake" ColumnMetadata corresponding to the dropped column {@code name} * of {@code null} if there is no such dropped column. * * @param name - the column name * @param isStatic - whether the column was a static column, if known */ public ColumnMetadata getDroppedColumn(ByteBuffer name, boolean isStatic) { DroppedColumn dropped = droppedColumns.get(name); if (dropped == null) return null; if (isStatic && !dropped.column.isStatic()) return ColumnMetadata.staticColumn(this, name, dropped.column.type); return dropped.column; } public boolean hasStaticColumns() { return !staticColumns().isEmpty(); } /** * @return {@code true} if the table has any masked column, {@code false} otherwise. */ public boolean hasMaskedColumns() { for (ColumnMetadata column : columns.values()) { if (column.isMasked()) return true; } return false; } /** * @param function a user function * @return {@code true} if the table has any masked column depending on the specified user function, * {@code false} otherwise. */ public boolean dependsOn(Function function) { for (ColumnMetadata column : columns.values()) { ColumnMask mask = column.getMask(); if (mask != null && mask.function.name().equals(function.name())) return true; } return false; } public void validate() { if (!isNameValid(keyspace)) except("Keyspace name must not be empty, more than %s characters long, or contain non-alphanumeric-underscore characters (got \"%s\")", SchemaConstants.NAME_LENGTH, keyspace); if (!isNameValid(name)) except("Table name must not be empty, more than %s characters long, or contain non-alphanumeric-underscore characters (got \"%s\")", SchemaConstants.NAME_LENGTH, name); params.validate(); if (partitionKeyColumns.stream().anyMatch(c -> c.type.isCounter())) except("PRIMARY KEY columns cannot contain counters"); // Mixing counter with non counter columns is not supported (#2614) if (isCounter()) { for (ColumnMetadata column : regularAndStaticColumns) if (!(column.type.isCounter()) && !isSuperColumnMapColumnName(column.name)) except("Cannot have a non counter column (\"%s\") in a counter table", column.name); } else { for (ColumnMetadata column : regularAndStaticColumns) if (column.type.isCounter()) except("Cannot have a counter column (\"%s\") in a non counter table", column.name); } // All tables should have a partition key if (partitionKeyColumns.isEmpty()) except("Missing partition keys for table %s", toString()); indexes.validate(this); } /** * To support backward compatibility with thrift super columns in the C* 3.0+ storage engine, we encode said super * columns as a CQL {@code map}. To ensure the name of this map did not conflict with any other user * defined columns, we used the empty name (which is otherwise not allowed for user created columns). *

* While all thrift-based tables must have been converted to "CQL" ones with "DROP COMPACT STORAGE" (before * upgrading to C* 4.0, which stop supporting non-CQL tables completely), a converted super-column table will still * have this map with an empty name. And the reason we need to recognize it still, is that for backward * compatibility we need to support counters in values of this map while it's not supported in any other map. * * TODO: it's probably worth lifting the limitation of not allowing counters as map values. It works fully * internally (since we had to support it for this special map) and doesn't feel particularly dangerous to * support. Doing so would remove this special case, but would also let user that do have an upgraded super-column * table with counters to rename that weirdly name map to something more meaningful (it's not possible today * as after renaming the validation in {@link #validate)} would trigger). */ private static boolean isSuperColumnMapColumnName(ColumnIdentifier columnName) { return !columnName.bytes.hasRemaining(); } public void validateCompatibility(TableMetadata previous) { if (isIndex()) return; if (!previous.keyspace.equals(keyspace)) except("Keyspace mismatch (found %s; expected %s)", keyspace, previous.keyspace); if (!previous.name.equals(name)) except("Table mismatch (found %s; expected %s)", name, previous.name); if (!previous.id.equals(id)) except("Table ID mismatch (found %s; expected %s)", id, previous.id); if (!previous.flags.equals(flags) && (!Flag.isCQLTable(flags) || Flag.isCQLTable(previous.flags))) except("Table type mismatch (found %s; expected %s)", flags, previous.flags); if (previous.partitionKeyColumns.size() != partitionKeyColumns.size()) { except("Partition keys of different length (found %s; expected %s)", partitionKeyColumns.size(), previous.partitionKeyColumns.size()); } for (int i = 0; i < partitionKeyColumns.size(); i++) { if (!partitionKeyColumns.get(i).type.isCompatibleWith(previous.partitionKeyColumns.get(i).type)) { except("Partition key column mismatch (found %s; expected %s)", partitionKeyColumns.get(i).type, previous.partitionKeyColumns.get(i).type); } } if (previous.clusteringColumns.size() != clusteringColumns.size()) { except("Clustering columns of different length (found %s; expected %s)", clusteringColumns.size(), previous.clusteringColumns.size()); } for (int i = 0; i < clusteringColumns.size(); i++) { if (!clusteringColumns.get(i).type.isCompatibleWith(previous.clusteringColumns.get(i).type)) { except("Clustering column mismatch (found %s; expected %s)", clusteringColumns.get(i).type, previous.clusteringColumns.get(i).type); } } for (ColumnMetadata previousColumn : previous.regularAndStaticColumns) { ColumnMetadata column = getColumn(previousColumn.name); if (column != null && !column.type.isCompatibleWith(previousColumn.type)) except("Column mismatch (found %s; expected %s)", column, previousColumn); } } public ClusteringComparator partitionKeyAsClusteringComparator() { return new ClusteringComparator(partitionKeyColumns.stream().map(c -> c.type).collect(toList())); } /** * Generate a table name for an index corresponding to the given column. * This is NOT the same as the index's name! This is only used in sstable filenames and is not exposed to users. * * @param info A definition of the column with index * * @return name of the index table */ public String indexTableName(IndexMetadata info) { // TODO simplify this when info.index_name is guaranteed to be set return name + Directories.SECONDARY_INDEX_NAME_SEPARATOR + info.name; } /** * @return true if the change as made impacts queries/updates on the table, * e.g. any columns or indexes were added, removed, or altered; otherwise, false is returned. * Used to determine whether prepared statements against this table need to be re-prepared. */ boolean changeAffectsPreparedStatements(TableMetadata updated) { return !partitionKeyColumns.equals(updated.partitionKeyColumns) || !clusteringColumns.equals(updated.clusteringColumns) || !regularAndStaticColumns.equals(updated.regularAndStaticColumns) || !indexes.equals(updated.indexes) || params.defaultTimeToLive != updated.params.defaultTimeToLive || params.gcGraceSeconds != updated.params.gcGraceSeconds || ( !Flag.isCQLTable(flags) && Flag.isCQLTable(updated.flags) ); } /** * There is a couple of places in the code where we need a TableMetadata object and don't have one readily available * and know that only the keyspace and name matter. This creates such "fake" metadata. Use only if you know what * you're doing. */ public static TableMetadata minimal(String keyspace, String name) { return TableMetadata.builder(keyspace, name) .addPartitionKeyColumn("key", BytesType.instance) .build(); } public TableMetadata updateIndexTableMetadata(TableParams baseTableParams) { TableParams.Builder builder = baseTableParams.unbuild().gcGraceSeconds(0); // Depends on parent's cache setting, turn on its index table's cache. // Row caching is never enabled; see CASSANDRA-5732 builder.caching(baseTableParams.caching.cacheKeys() ? CachingParams.CACHE_KEYS : CachingParams.CACHE_NOTHING); return unbuild().params(builder.build()).build(); } boolean referencesUserType(ByteBuffer name) { return any(columns(), c -> c.type.referencesUserType(name)); } public TableMetadata withUpdatedUserType(UserType udt) { if (!referencesUserType(udt.name)) return this; Builder builder = unbuild(); columns().forEach(c -> builder.alterColumnType(c.name, c.type.withUpdatedUserType(udt))); return builder.build(); } protected void except(String format, Object... args) { throw new ConfigurationException(keyspace + "." + name + ": " + format(format, args)); } @Override public boolean equals(Object o) { if (this == o) return true; if (!(o instanceof TableMetadata)) return false; TableMetadata tm = (TableMetadata) o; return equalsWithoutColumns(tm) && columns.equals(tm.columns); } private boolean equalsWithoutColumns(TableMetadata tm) { return keyspace.equals(tm.keyspace) && name.equals(tm.name) && id.equals(tm.id) && partitioner.equals(tm.partitioner) && kind == tm.kind && params.equals(tm.params) && flags.equals(tm.flags) && droppedColumns.equals(tm.droppedColumns) && indexes.equals(tm.indexes) && triggers.equals(tm.triggers); } Optional compare(TableMetadata other) { return equalsWithoutColumns(other) ? compareColumns(other.columns) : Optional.of(Difference.SHALLOW); } private Optional compareColumns(Map other) { if (!columns.keySet().equals(other.keySet())) return Optional.of(Difference.SHALLOW); boolean differsDeeply = false; for (Map.Entry entry : columns.entrySet()) { ColumnMetadata thisColumn = entry.getValue(); ColumnMetadata thatColumn = other.get(entry.getKey()); Optional difference = thisColumn.compare(thatColumn); if (difference.isPresent()) { switch (difference.get()) { case SHALLOW: return difference; case DEEP: differsDeeply = true; } } } return differsDeeply ? Optional.of(Difference.DEEP) : Optional.empty(); } @Override public int hashCode() { return Objects.hash(keyspace, name, id, partitioner, kind, params, flags, columns, droppedColumns, indexes, triggers); } @Override public String toString() { return format("%s.%s", ColumnIdentifier.maybeQuote(keyspace), ColumnIdentifier.maybeQuote(name)); } public String toDebugString() { return MoreObjects.toStringHelper(this) .add("keyspace", keyspace) .add("table", name) .add("id", id) .add("partitioner", partitioner) .add("kind", kind) .add("params", params) .add("flags", flags) .add("columns", columns()) .add("droppedColumns", droppedColumns.values()) .add("indexes", indexes) .add("triggers", triggers) .toString(); } public static final class Builder { final String keyspace; final String name; private TableId id; private IPartitioner partitioner; private Kind kind = Kind.REGULAR; private TableParams.Builder params = TableParams.builder(); // See the comment on Flag.COMPOUND definition for why we (still) inconditionally add this flag. private Set flags = EnumSet.of(Flag.COMPOUND); private Triggers triggers = Triggers.none(); private Indexes indexes = Indexes.none(); private final Map droppedColumns = new HashMap<>(); private final Map columns = new HashMap<>(); private final List partitionKeyColumns = new ArrayList<>(); private final List clusteringColumns = new ArrayList<>(); private final List regularAndStaticColumns = new ArrayList<>(); private Builder(String keyspace, String name, TableId id) { this.keyspace = keyspace; this.name = name; this.id = id; } private Builder(String keyspace, String name) { this.keyspace = keyspace; this.name = name; } public TableMetadata build() { if (partitioner == null) partitioner = DatabaseDescriptor.getPartitioner(); if (id == null) { // make sure vtables use determiniestic ids so they can be referenced in calls cross-nodes // see CASSANDRA-17295 if (DatabaseDescriptor.useDeterministicTableID() || kind == Kind.VIRTUAL) id = TableId.unsafeDeterministic(keyspace, name); else id = TableId.generate(); } if (Flag.isCQLTable(flags)) return new TableMetadata(this); else return new CompactTableMetadata(this); } public Builder id(TableId val) { id = val; return this; } public Builder partitioner(IPartitioner val) { partitioner = val; return this; } public Builder kind(Kind val) { kind = val; return this; } public Builder params(TableParams val) { params = val.unbuild(); return this; } public Builder allowAutoSnapshot(boolean val) { params.allowAutoSnapshot(val); return this; } public Builder bloomFilterFpChance(double val) { params.bloomFilterFpChance(val); return this; } public Builder caching(CachingParams val) { params.caching(val); return this; } public Builder comment(String val) { params.comment(val); return this; } public Builder compaction(CompactionParams val) { params.compaction(val); return this; } public Builder compression(CompressionParams val) { params.compression(val); return this; } public Builder defaultTimeToLive(int val) { params.defaultTimeToLive(val); return this; } public Builder gcGraceSeconds(int val) { params.gcGraceSeconds(val); return this; } public Builder maxIndexInterval(int val) { params.maxIndexInterval(val); return this; } public Builder memtableFlushPeriod(int val) { params.memtableFlushPeriodInMs(val); return this; } public Builder minIndexInterval(int val) { params.minIndexInterval(val); return this; } public Builder crcCheckChance(double val) { params.crcCheckChance(val); return this; } public Builder speculativeRetry(SpeculativeRetryPolicy val) { params.speculativeRetry(val); return this; } public Builder additionalWritePolicy(SpeculativeRetryPolicy val) { params.additionalWritePolicy(val); return this; } public Builder extensions(Map val) { params.extensions(val); return this; } public Builder flags(Set val) { flags = val; return this; } public Builder memtable(MemtableParams val) { params.memtable(val); return this; } public Builder isCounter(boolean val) { return flag(Flag.COUNTER, val); } private Builder flag(Flag flag, boolean set) { if (set) flags.add(flag); else flags.remove(flag); return this; } public Builder triggers(Triggers val) { triggers = val; return this; } public Builder indexes(Indexes val) { indexes = val; return this; } public Builder addPartitionKeyColumn(String name, AbstractType type) { return addPartitionKeyColumn(name, type, null); } public Builder addPartitionKeyColumn(String name, AbstractType type, @Nullable ColumnMask mask) { return addPartitionKeyColumn(ColumnIdentifier.getInterned(name, false), type, mask); } public Builder addPartitionKeyColumn(ColumnIdentifier name, AbstractType type) { return addPartitionKeyColumn(name, type, null); } public Builder addPartitionKeyColumn(ColumnIdentifier name, AbstractType type, @Nullable ColumnMask mask) { return addColumn(new ColumnMetadata(keyspace, this.name, name, type, partitionKeyColumns.size(), ColumnMetadata.Kind.PARTITION_KEY, mask)); } public Builder addClusteringColumn(String name, AbstractType type) { return addClusteringColumn(name, type, null); } public Builder addClusteringColumn(String name, AbstractType type, @Nullable ColumnMask mask) { return addClusteringColumn(ColumnIdentifier.getInterned(name, false), type, mask); } public Builder addClusteringColumn(ColumnIdentifier name, AbstractType type) { return addClusteringColumn(name, type, null); } public Builder addClusteringColumn(ColumnIdentifier name, AbstractType type, @Nullable ColumnMask mask) { return addColumn(new ColumnMetadata(keyspace, this.name, name, type, clusteringColumns.size(), ColumnMetadata.Kind.CLUSTERING, mask)); } public Builder addRegularColumn(String name, AbstractType type) { return addRegularColumn(name, type, null); } public Builder addRegularColumn(String name, AbstractType type, @Nullable ColumnMask mask) { return addRegularColumn(ColumnIdentifier.getInterned(name, false), type, mask); } public Builder addRegularColumn(ColumnIdentifier name, AbstractType type) { return addRegularColumn(name, type, null); } public Builder addRegularColumn(ColumnIdentifier name, AbstractType type, @Nullable ColumnMask mask) { return addColumn(new ColumnMetadata(keyspace, this.name, name, type, ColumnMetadata.NO_POSITION, ColumnMetadata.Kind.REGULAR, mask)); } public Builder addStaticColumn(String name, AbstractType type) { return addStaticColumn(name, type, null); } public Builder addStaticColumn(String name, AbstractType type, @Nullable ColumnMask mask) { return addStaticColumn(ColumnIdentifier.getInterned(name, false), type, mask); } public Builder addStaticColumn(ColumnIdentifier name, AbstractType type) { return addStaticColumn(name, type, null); } public Builder addStaticColumn(ColumnIdentifier name, AbstractType type, @Nullable ColumnMask mask) { return addColumn(new ColumnMetadata(keyspace, this.name, name, type, ColumnMetadata.NO_POSITION, ColumnMetadata.Kind.STATIC, mask)); } public Builder addColumn(ColumnMetadata column) { if (columns.containsKey(column.name.bytes)) throw new IllegalArgumentException(); switch (column.kind) { case PARTITION_KEY: partitionKeyColumns.add(column); Collections.sort(partitionKeyColumns); break; case CLUSTERING: column.type.checkComparable(); clusteringColumns.add(column); Collections.sort(clusteringColumns); break; default: regularAndStaticColumns.add(column); } columns.put(column.name.bytes, column); return this; } public Builder addColumns(Iterable columns) { columns.forEach(this::addColumn); return this; } public Builder droppedColumns(Map droppedColumns) { this.droppedColumns.clear(); this.droppedColumns.putAll(droppedColumns); return this; } /** * Records a deprecated column for a system table. */ public Builder recordDeprecatedSystemColumn(String name, AbstractType type) { // As we play fast and loose with the removal timestamp, make sure this is misued for a non system table. assert SchemaConstants.isLocalSystemKeyspace(keyspace); recordColumnDrop(ColumnMetadata.regularColumn(keyspace, this.name, name, type), Long.MAX_VALUE); return this; } public Builder recordColumnDrop(ColumnMetadata column, long timeMicros) { droppedColumns.put(column.name.bytes, new DroppedColumn(column.withNewType(column.type.expandUserTypes()), timeMicros)); return this; } public Iterable columns() { return columns.values(); } public int numColumns() { return columns.size(); } public Set columnNames() { return columns.values().stream().map(c -> c.name.toString()).collect(toSet()); } public ColumnMetadata getColumn(ColumnIdentifier identifier) { return columns.get(identifier.bytes); } public ColumnMetadata getColumn(ByteBuffer name) { return columns.get(name); } public boolean hasRegularColumns() { return regularAndStaticColumns.stream().anyMatch(ColumnMetadata::isRegular); } /* * The following methods all assume a Builder with valid set of partition key, clustering, regular and static columns. */ public Builder removeRegularOrStaticColumn(ColumnIdentifier identifier) { ColumnMetadata column = columns.get(identifier.bytes); if (column == null || column.isPrimaryKeyColumn()) throw new IllegalArgumentException(); columns.remove(identifier.bytes); regularAndStaticColumns.remove(column); return this; } public Builder renamePrimaryKeyColumn(ColumnIdentifier from, ColumnIdentifier to) { if (columns.containsKey(to.bytes)) throw new IllegalArgumentException(); ColumnMetadata column = columns.get(from.bytes); if (column == null || !column.isPrimaryKeyColumn()) throw new IllegalArgumentException(); ColumnMetadata newColumn = column.withNewName(to); if (column.isPartitionKey()) partitionKeyColumns.set(column.position(), newColumn); else clusteringColumns.set(column.position(), newColumn); columns.remove(from.bytes); columns.put(to.bytes, newColumn); return this; } public Builder alterColumnMask(ColumnIdentifier name, @Nullable ColumnMask mask) { ColumnMetadata column = columns.get(name.bytes); if (column == null) throw new IllegalArgumentException(); ColumnMetadata newColumn = column.withNewMask(mask); updateColumn(column, newColumn); return this; } Builder alterColumnType(ColumnIdentifier name, AbstractType type) { ColumnMetadata column = columns.get(name.bytes); if (column == null) throw new IllegalArgumentException(); ColumnMetadata newColumn = column.withNewType(type); updateColumn(column, newColumn); return this; } private void updateColumn(ColumnMetadata column, ColumnMetadata newColumn) { switch (column.kind) { case PARTITION_KEY: partitionKeyColumns.set(column.position(), newColumn); break; case CLUSTERING: clusteringColumns.set(column.position(), newColumn); break; case REGULAR: case STATIC: regularAndStaticColumns.remove(column); regularAndStaticColumns.add(newColumn); break; } columns.put(column.name.bytes, newColumn); } } /** * A table with strict liveness filters/ignores rows without PK liveness info, * effectively tying the row liveness to its primary key liveness. * * Currently this is only used by views with normal base column as PK column * so updates to other columns do not make the row live when the base column * is not live. See CASSANDRA-11500. * * TODO: does not belong here, should be gone */ public boolean enforceStrictLiveness() { return isView() && Keyspace.open(keyspace).viewManager.getByName(name).enforceStrictLiveness(); } /** * Returns the names of all the user types referenced by this table. * * @return the names of all the user types referenced by this table. */ public Set getReferencedUserTypes() { Set types = new LinkedHashSet<>(); columns().forEach(c -> addUserTypes(c.type, types)); return types; } /** * Find all user types used by the specified type and add them to the set. * * @param type the type to check for user types. * @param types the set of UDT names to which to add new user types found in {@code type}. Note that the * insertion ordering is important and ensures that if a user type A uses another user type B, then B will appear * before A in iteration order. */ private static void addUserTypes(AbstractType type, Set types) { // Reach into subtypes first, so that if the type is a UDT, it's dependencies are recreated first. type.subTypes().forEach(t -> addUserTypes(t, types)); if (type.isUDT()) types.add(((UserType)type).name); } @Override public SchemaElementType elementType() { return SchemaElementType.TABLE; } @Override public String elementKeyspace() { return keyspace; } @Override public String elementName() { return name; } @Override public String toCqlString(boolean withInternals, boolean ifNotExists) { CqlBuilder builder = new CqlBuilder(2048); appendCqlTo(builder, withInternals, withInternals, ifNotExists); return builder.toString(); } public String toCqlString(boolean includeDroppedColumns, boolean withInternals, boolean ifNotExists) { CqlBuilder builder = new CqlBuilder(2048); appendCqlTo(builder, includeDroppedColumns, withInternals, ifNotExists); return builder.toString(); } public void appendCqlTo(CqlBuilder builder, boolean includeDroppedColumns, boolean withInternals, boolean ifNotExists) { assert !isView(); String createKeyword = "CREATE"; if (isVirtual()) { builder.append(String.format("/*\n" + "Warning: Table %s is a virtual table and cannot be recreated with CQL.\n" + "Structure, for reference:\n", toString())); createKeyword = "VIRTUAL"; } builder.append(createKeyword) .append(" TABLE "); if (ifNotExists) builder.append("IF NOT EXISTS "); builder.append(toString()) .append(" (") .newLine() .increaseIndent(); boolean hasSingleColumnPrimaryKey = partitionKeyColumns.size() == 1 && clusteringColumns.isEmpty(); appendColumnDefinitions(builder, includeDroppedColumns, hasSingleColumnPrimaryKey); if (!hasSingleColumnPrimaryKey) appendPrimaryKey(builder); builder.decreaseIndent() .append(')'); builder.append(" WITH ") .increaseIndent(); appendTableOptions(builder, withInternals); builder.decreaseIndent(); if (isVirtual()) { builder.newLine() .append("*/"); } if (includeDroppedColumns) appendDropColumns(builder); } private void appendColumnDefinitions(CqlBuilder builder, boolean includeDroppedColumns, boolean hasSingleColumnPrimaryKey) { Iterator iter = allColumnsInCreateOrder(); while (iter.hasNext()) { ColumnMetadata column = iter.next(); // If the column has been re-added after a drop, we don't include it right away. Instead, we'll add the // dropped one first below, then we'll issue the DROP and then the actual ADD for this column, thus // simulating the proper sequence of events. if (includeDroppedColumns && droppedColumns.containsKey(column.name.bytes)) continue; column.appendCqlTo(builder); if (hasSingleColumnPrimaryKey && column.isPartitionKey()) builder.append(" PRIMARY KEY"); if (!hasSingleColumnPrimaryKey || (includeDroppedColumns && !droppedColumns.isEmpty()) || iter.hasNext()) builder.append(','); builder.newLine(); } if (includeDroppedColumns) { Iterator iterDropped = droppedColumns.values().iterator(); while (iterDropped.hasNext()) { DroppedColumn dropped = iterDropped.next(); dropped.column.appendCqlTo(builder); if (!hasSingleColumnPrimaryKey || iter.hasNext()) builder.append(','); builder.newLine(); } } } void appendPrimaryKey(CqlBuilder builder) { List partitionKeyColumns = partitionKeyColumns(); List clusteringColumns = clusteringColumns(); if (isStaticCompactTable()) clusteringColumns = Collections.emptyList(); builder.append("PRIMARY KEY ("); if (partitionKeyColumns.size() > 1) { builder.append('(') .appendWithSeparators(partitionKeyColumns, (b, c) -> b.append(c.name), ", ") .append(')'); } else { builder.append(partitionKeyColumns.get(0).name); } if (!clusteringColumns.isEmpty()) builder.append(", ") .appendWithSeparators(clusteringColumns, (b, c) -> b.append(c.name), ", "); builder.append(')') .newLine(); } void appendTableOptions(CqlBuilder builder, boolean withInternals) { if (withInternals) builder.append("ID = ") .append(id.toString()) .newLine() .append("AND "); List clusteringColumns = clusteringColumns(); if (!clusteringColumns.isEmpty()) { builder.append("CLUSTERING ORDER BY (") .appendWithSeparators(clusteringColumns, (b, c) -> c.appendNameAndOrderTo(b), ", ") .append(')') .newLine() .append("AND "); } if (isVirtual()) { builder.append("comment = ").appendWithSingleQuotes(params.comment); } else { params.appendCqlTo(builder, isView()); } builder.append(";"); } private void appendDropColumns(CqlBuilder builder) { for (Entry entry : droppedColumns.entrySet()) { DroppedColumn dropped = entry.getValue(); builder.newLine() .append("ALTER TABLE ") .append(toString()) .append(" DROP ") .append(dropped.column.name) .append(" USING TIMESTAMP ") .append(dropped.droppedTime) .append(';'); ColumnMetadata column = getColumn(entry.getKey()); if (column != null) { builder.newLine() .append("ALTER TABLE ") .append(toString()) .append(" ADD "); column.appendCqlTo(builder); builder.append(';'); } } } /** * Returns a string representation of a partition in a CQL-friendly format. * * For non-composite types it returns the result of {@link org.apache.cassandra.cql3.CQL3Type#toCQLLiteral} * applied to the partition key. * For composite types it applies {@link org.apache.cassandra.cql3.CQL3Type#toCQLLiteral} to each subkey and * combines the results into a tuple. * * @param partitionKey a partition key * @return CQL-like string representation of a partition key */ public String partitionKeyAsCQLLiteral(ByteBuffer partitionKey) { return primaryKeyAsCQLLiteral(partitionKey, Clustering.EMPTY); } /** * Returns a string representation of a primary key in a CQL-friendly format. * * @param partitionKey the partition key part of the primary key * @param clustering the clustering key part of the primary key * @return a CQL-like string representation of the specified primary key */ public String primaryKeyAsCQLLiteral(ByteBuffer partitionKey, Clustering clustering) { int clusteringSize = clustering.size(); String[] literals; int i = 0; if (partitionKeyType instanceof CompositeType) { List> components = partitionKeyType.getComponents(); int size = components.size(); literals = new String[size + clusteringSize]; ByteBuffer[] values = ((CompositeType) partitionKeyType).split(partitionKey); for (i = 0; i < size; i++) { literals[i] = asCQLLiteral(components.get(i), values[i]); } } else { literals = new String[1 + clusteringSize]; literals[i++] = asCQLLiteral(partitionKeyType, partitionKey); } for (int j = 0; j < clusteringSize; j++) { literals[i++] = asCQLLiteral(clusteringColumns().get(j).type, clustering.bufferAt(j)); } return i == 1 ? literals[0] : "(" + String.join(", ", literals) + ")"; } private static String asCQLLiteral(AbstractType type, ByteBuffer value) { return type.asCQL3Type().toCQLLiteral(value); } public static class CompactTableMetadata extends TableMetadata { /* * For dense tables, this alias the single non-PK column the table contains (since it can only have one). We keep * that as convenience to access that column more easily (but we could replace calls by regularAndStaticColumns().iterator().next() * for those tables in practice). */ public final ColumnMetadata compactValueColumn; private final Set hiddenColumns; protected CompactTableMetadata(Builder builder) { super(builder); compactValueColumn = getCompactValueColumn(regularAndStaticColumns); if (isCompactTable() && Flag.isDense(this.flags) && hasEmptyCompactValue()) { hiddenColumns = Collections.singleton(compactValueColumn); } else if (isCompactTable() && !Flag.isDense(this.flags)) { hiddenColumns = Sets.newHashSetWithExpectedSize(clusteringColumns.size() + 1); hiddenColumns.add(compactValueColumn); hiddenColumns.addAll(clusteringColumns); } else { hiddenColumns = Collections.emptySet(); } } @Override public boolean isCompactTable() { return true; } public ColumnMetadata getExistingColumn(ColumnIdentifier name) { ColumnMetadata def = getColumn(name); if (def == null || isHiddenColumn(def)) throw new InvalidRequestException(format("Undefined column name %s in table %s", name.toCQLString(), this)); return def; } public boolean isHiddenColumn(ColumnMetadata def) { return hiddenColumns.contains(def); } @Override public Iterator allColumnsInSelectOrder() { boolean isStaticCompactTable = isStaticCompactTable(); boolean noNonPkColumns = hasEmptyCompactValue(); Iterator partitionKeyIter = partitionKeyColumns.iterator(); Iterator clusteringIter = isStaticCompactTable ? Collections.emptyIterator() : clusteringColumns.iterator(); Iterator otherColumns = noNonPkColumns ? Collections.emptyIterator() : (isStaticCompactTable ? staticColumns().selectOrderIterator() : regularAndStaticColumns.selectOrderIterator()); return columnsIterator(partitionKeyIter, clusteringIter, otherColumns); } public ImmutableList createStatementClusteringColumns() { return isStaticCompactTable() ? ImmutableList.of() : clusteringColumns; } public Iterator allColumnsInCreateOrder() { boolean isStaticCompactTable = isStaticCompactTable(); boolean noNonPkColumns = !Flag.isCQLTable(flags) && hasEmptyCompactValue(); Iterator partitionKeyIter = partitionKeyColumns.iterator(); Iterator clusteringIter; if (isStaticCompactTable()) clusteringIter = Collections.EMPTY_LIST.iterator(); else clusteringIter = createStatementClusteringColumns().iterator(); Iterator otherColumns; if (noNonPkColumns) { otherColumns = Collections.emptyIterator(); } else if (isStaticCompactTable) { List columns = new ArrayList<>(); for (ColumnMetadata c : regularAndStaticColumns) { if (c.isStatic()) columns.add(new ColumnMetadata(c.ksName, c.cfName, c.name, c.type, -1, ColumnMetadata.Kind.REGULAR, c.getMask())); } otherColumns = columns.iterator(); } else { otherColumns = regularAndStaticColumns.iterator(); } return columnsIterator(partitionKeyIter, clusteringIter, otherColumns); } public boolean hasEmptyCompactValue() { return compactValueColumn.type instanceof EmptyType; } public void validate() { super.validate(); // A compact table should always have a clustering if (!Flag.isCQLTable(flags) && clusteringColumns.isEmpty()) except("For table %s, isDense=%b, isCompound=%b, clustering=%s", toString(), Flag.isDense(flags), Flag.isCompound(flags), clusteringColumns); } AbstractType staticCompactOrSuperTableColumnNameType() { assert isStaticCompactTable(); return clusteringColumns.get(0).type; } public AbstractType columnDefinitionNameComparator(ColumnMetadata.Kind kind) { return (Flag.isSuper(this.flags) && kind == ColumnMetadata.Kind.REGULAR) || (isStaticCompactTable() && kind == ColumnMetadata.Kind.STATIC) ? staticCompactOrSuperTableColumnNameType() : UTF8Type.instance; } @Override public boolean isStaticCompactTable() { return !Flag.isSuper(flags) && !Flag.isDense(flags) && !Flag.isCompound(flags); } public void appendCqlTo(CqlBuilder builder, boolean includeDroppedColumns, boolean internals, boolean ifNotExists) { builder.append("/*") .newLine() .append("Warning: Table ") .append(toString()) .append(" omitted because it has constructs not compatible with CQL (was created via legacy API).") .newLine() .append("Approximate structure, for reference:") .newLine() .append("(this should not be used to reproduce this schema)") .newLine() .newLine(); super.appendCqlTo(builder, includeDroppedColumns, internals, ifNotExists); builder.newLine() .append("*/"); } void appendTableOptions(CqlBuilder builder, boolean internals) { builder.append("COMPACT STORAGE") .newLine() .append("AND "); super.appendTableOptions(builder, internals); } public static ColumnMetadata getCompactValueColumn(RegularAndStaticColumns columns) { assert columns.regulars.simpleColumnCount() == 1 && columns.regulars.complexColumnCount() == 0; return columns.regulars.getSimple(0); } } }





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