/*
* 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.cql3;
import java.nio.ByteBuffer;
import java.util.ArrayList;
import java.util.Collections;
import java.util.List;
import java.util.concurrent.atomic.AtomicReference;
import org.apache.cassandra.db.ColumnFamily;
import org.apache.cassandra.db.Column;
import org.apache.cassandra.db.marshal.CollectionType;
import org.apache.cassandra.db.marshal.Int32Type;
import org.apache.cassandra.db.marshal.ListType;
import org.apache.cassandra.exceptions.InvalidRequestException;
import org.apache.cassandra.serializers.MarshalException;
import org.apache.cassandra.utils.ByteBufferUtil;
import org.apache.cassandra.utils.FBUtilities;
import org.apache.cassandra.utils.Pair;
import org.apache.cassandra.utils.UUIDGen;
/**
* Static helper methods and classes for lists.
*/
public abstract class Lists
{
private Lists() {}
public static ColumnSpecification indexSpecOf(ColumnSpecification column)
{
return new ColumnSpecification(column.ksName, column.cfName, new ColumnIdentifier("idx(" + column.name + ")", true), Int32Type.instance);
}
public static ColumnSpecification valueSpecOf(ColumnSpecification column)
{
return new ColumnSpecification(column.ksName, column.cfName, new ColumnIdentifier("value(" + column.name + ")", true), ((ListType)column.type).elements);
}
public static class Literal implements Term.Raw
{
private final List<Term.Raw> elements;
public Literal(List<Term.Raw> elements)
{
this.elements = elements;
}
public Term prepare(ColumnSpecification receiver) throws InvalidRequestException
{
validateAssignableTo(receiver);
ColumnSpecification valueSpec = Lists.valueSpecOf(receiver);
List<Term> values = new ArrayList<Term>(elements.size());
boolean allTerminal = true;
for (Term.Raw rt : elements)
{
Term t = rt.prepare(valueSpec);
if (t.containsBindMarker())
throw new InvalidRequestException(String.format("Invalid list literal for %s: bind variables are not supported inside collection literals", receiver));
if (t instanceof Term.NonTerminal)
allTerminal = false;
values.add(t);
}
DelayedValue value = new DelayedValue(values);
return allTerminal ? value.bind(Collections.<ByteBuffer>emptyList()) : value;
}
private void validateAssignableTo(ColumnSpecification receiver) throws InvalidRequestException
{
if (!(receiver.type instanceof ListType))
throw new InvalidRequestException(String.format("Invalid list literal for %s of type %s", receiver, receiver.type.asCQL3Type()));
ColumnSpecification valueSpec = Lists.valueSpecOf(receiver);
for (Term.Raw rt : elements)
{
if (!rt.isAssignableTo(valueSpec))
throw new InvalidRequestException(String.format("Invalid list literal for %s: value %s is not of type %s", receiver, rt, valueSpec.type.asCQL3Type()));
}
}
public boolean isAssignableTo(ColumnSpecification receiver)
{
try
{
validateAssignableTo(receiver);
return true;
}
catch (InvalidRequestException e)
{
return false;
}
}
@Override
public String toString()
{
return elements.toString();
}
}
public static class Value extends Term.Terminal
{
public final List<ByteBuffer> elements;
public Value(List<ByteBuffer> elements)
{
this.elements = elements;
}
public static Value fromSerialized(ByteBuffer value, ListType type) throws InvalidRequestException
{
try
{
// Collections have this small hack that validate cannot be called on a serialized object,
// but compose does the validation (so we're fine).
List<?> l = (List<?>)type.compose(value);
List<ByteBuffer> elements = new ArrayList<ByteBuffer>(l.size());
for (Object element : l)
elements.add(type.elements.decompose(element));
return new Value(elements);
}
catch (MarshalException e)
{
throw new InvalidRequestException(e.getMessage());
}
}
public ByteBuffer get()
{
return CollectionType.pack(elements, elements.size());
}
}
/*
* Basically similar to a Value, but with some non-pure function (that need
* to be evaluated at execution time) in it.
*
* Note: this would also work for a list with bind markers, but we don't support
* that because 1) it's not excessively useful and 2) we wouldn't have a good
* column name to return in the ColumnSpecification for those markers (not a
* blocker per-se but we don't bother due to 1)).
*/
public static class DelayedValue extends Term.NonTerminal
{
private final List<Term> elements;
public DelayedValue(List<Term> elements)
{
this.elements = elements;
}
public boolean containsBindMarker()
{
// False since we don't support them in collection
return false;
}
public void collectMarkerSpecification(VariableSpecifications boundNames)
{
}
public Value bind(List<ByteBuffer> values) throws InvalidRequestException
{
List<ByteBuffer> buffers = new ArrayList<ByteBuffer>(elements.size());
for (Term t : elements)
{
ByteBuffer bytes = t.bindAndGet(values);
if (bytes == null)
throw new InvalidRequestException("null is not supported inside collections");
// We don't support value > 64K because the serialization format encode the length as an unsigned short.
if (bytes.remaining() > FBUtilities.MAX_UNSIGNED_SHORT)
throw new InvalidRequestException(String.format("List value is too long. List values are limited to %d bytes but %d bytes value provided",
FBUtilities.MAX_UNSIGNED_SHORT,
bytes.remaining()));
buffers.add(bytes);
}
return new Value(buffers);
}
}
public static class Marker extends AbstractMarker
{
protected Marker(int bindIndex, ColumnSpecification receiver)
{
super(bindIndex, receiver);
assert receiver.type instanceof ListType;
}
public Value bind(List<ByteBuffer> values) throws InvalidRequestException
{
ByteBuffer value = values.get(bindIndex);
return value == null ? null : Value.fromSerialized(value, (ListType)receiver.type);
}
}
/*
* For prepend, we need to be able to generate unique but decreasing time
* UUID, which is a bit challenging. To do that, given a time in milliseconds,
* we adds a number representing the 100-nanoseconds precision and make sure
* that within the same millisecond, that number is always decreasing. We
* do rely on the fact that the user will only provide decreasing
* milliseconds timestamp for that purpose.
*/
private static class PrecisionTime
{
// Our reference time (1 jan 2010, 00:00:00) in milliseconds.
private static final long REFERENCE_TIME = 1262304000000L;
private static final AtomicReference<PrecisionTime> last = new AtomicReference<PrecisionTime>(new PrecisionTime(Long.MAX_VALUE, 0));
public final long millis;
public final int nanos;
PrecisionTime(long millis, int nanos)
{
this.millis = millis;
this.nanos = nanos;
}
static PrecisionTime getNext(long millis)
{
while (true)
{
PrecisionTime current = last.get();
assert millis <= current.millis;
PrecisionTime next = millis < current.millis
? new PrecisionTime(millis, 9999)
: new PrecisionTime(millis, Math.max(0, current.nanos - 1));
if (last.compareAndSet(current, next))
return next;
}
}
}
public static class Setter extends Operation
{
public Setter(ColumnIdentifier column, Term t)
{
super(column, t);
}
public void execute(ByteBuffer rowKey, ColumnFamily cf, ColumnNameBuilder prefix, UpdateParameters params) throws InvalidRequestException
{
// delete + append
ColumnNameBuilder column = prefix.add(columnName.key);
cf.addAtom(params.makeTombstoneForOverwrite(column.build(), column.buildAsEndOfRange()));
Appender.doAppend(t, cf, column, params);
}
}
public static class SetterByIndex extends Operation
{
private final Term idx;
public SetterByIndex(ColumnIdentifier column, Term idx, Term t)
{
super(column, t);
this.idx = idx;
}
@Override
public boolean requiresRead()
{
return true;
}
@Override
public void collectMarkerSpecification(VariableSpecifications boundNames)
{
super.collectMarkerSpecification(boundNames);
idx.collectMarkerSpecification(boundNames);
}
public void execute(ByteBuffer rowKey, ColumnFamily cf, ColumnNameBuilder prefix, UpdateParameters params) throws InvalidRequestException
{
ByteBuffer index = idx.bindAndGet(params.variables);
ByteBuffer value = t.bindAndGet(params.variables);
if (index == null)
throw new InvalidRequestException("Invalid null value for list index");
List<Pair<ByteBuffer, Column>> existingList = params.getPrefetchedList(rowKey, columnName.key);
int idx = ByteBufferUtil.toInt(index);
if (idx < 0 || idx >= existingList.size())
throw new InvalidRequestException(String.format("List index %d out of bound, list has size %d", idx, existingList.size()));
ByteBuffer elementName = existingList.get(idx).right.name();
if (value == null)
{
cf.addColumn(params.makeTombstone(elementName));
}
else
{
// We don't support value > 64K because the serialization format encode the length as an unsigned short.
if (value.remaining() > FBUtilities.MAX_UNSIGNED_SHORT)
throw new InvalidRequestException(String.format("List value is too long. List values are limited to %d bytes but %d bytes value provided",
FBUtilities.MAX_UNSIGNED_SHORT,
value.remaining()));
cf.addColumn(params.makeColumn(elementName, value));
}
}
}
public static class Appender extends Operation
{
public Appender(ColumnIdentifier column, Term t)
{
super(column, t);
}
public void execute(ByteBuffer rowKey, ColumnFamily cf, ColumnNameBuilder prefix, UpdateParameters params) throws InvalidRequestException
{
doAppend(t, cf, prefix.add(columnName.key), params);
}
static void doAppend(Term t, ColumnFamily cf, ColumnNameBuilder columnName, UpdateParameters params) throws InvalidRequestException
{
Term.Terminal value = t.bind(params.variables);
// If we append null, do nothing. Note that for Setter, we've
// already removed the previous value so we're good here too
if (value == null)
return;
assert value instanceof Lists.Value;
List<ByteBuffer> toAdd = ((Lists.Value)value).elements;
for (int i = 0; i < toAdd.size(); i++)
{
ColumnNameBuilder b = i == toAdd.size() - 1 ? columnName : columnName.copy();
ByteBuffer uuid = ByteBuffer.wrap(UUIDGen.getTimeUUIDBytes());
ByteBuffer cellName = b.add(uuid).build();
cf.addColumn(params.makeColumn(cellName, toAdd.get(i)));
}
}
}
public static class Prepender extends Operation
{
public Prepender(ColumnIdentifier column, Term t)
{
super(column, t);
}
public void execute(ByteBuffer rowKey, ColumnFamily cf, ColumnNameBuilder prefix, UpdateParameters params) throws InvalidRequestException
{
Term.Terminal value = t.bind(params.variables);
if (value == null)
return;
assert value instanceof Lists.Value;
long time = PrecisionTime.REFERENCE_TIME - (System.currentTimeMillis() - PrecisionTime.REFERENCE_TIME);
List<ByteBuffer> toAdd = ((Lists.Value)value).elements;
ColumnNameBuilder column = prefix.add(columnName.key);
for (int i = 0; i < toAdd.size(); i++)
{
ColumnNameBuilder b = i == toAdd.size() - 1 ? column : column.copy();
PrecisionTime pt = PrecisionTime.getNext(time);
ByteBuffer uuid = ByteBuffer.wrap(UUIDGen.getTimeUUIDBytes(pt.millis, pt.nanos));
ByteBuffer cellName = b.add(uuid).build();
cf.addColumn(params.makeColumn(cellName, toAdd.get(i)));
}
}
}
public static class Discarder extends Operation
{
public Discarder(ColumnIdentifier column, Term t)
{
super(column, t);
}
@Override
public boolean requiresRead()
{
return true;
}
public void execute(ByteBuffer rowKey, ColumnFamily cf, ColumnNameBuilder prefix, UpdateParameters params) throws InvalidRequestException
{
List<Pair<ByteBuffer, Column>> existingList = params.getPrefetchedList(rowKey, columnName.key);
if (existingList.isEmpty())
return;
Term.Terminal value = t.bind(params.variables);
if (value == null)
return;
assert value instanceof Lists.Value;
// Note: below, we will call 'contains' on this toDiscard list for each element of existingList.
// Meaning that if toDiscard is big, converting it to a HashSet might be more efficient. However,
// the read-before-write this operation requires limits its usefulness on big lists, so in practice
// toDiscard will be small and keeping a list will be more efficient.
List<ByteBuffer> toDiscard = ((Lists.Value)value).elements;
for (Pair<ByteBuffer, Column> p : existingList)
{
Column element = p.right;
if (toDiscard.contains(element.value()))
cf.addColumn(params.makeTombstone(element.name()));
}
}
}
public static class DiscarderByIndex extends Operation
{
public DiscarderByIndex(ColumnIdentifier column, Term idx)
{
super(column, idx);
}
@Override
public boolean requiresRead()
{
return true;
}
public void execute(ByteBuffer rowKey, ColumnFamily cf, ColumnNameBuilder prefix, UpdateParameters params) throws InvalidRequestException
{
Term.Terminal index = t.bind(params.variables);
if (index == null)
throw new InvalidRequestException("Invalid null value for list index");
assert index instanceof Constants.Value;
List<Pair<ByteBuffer, Column>> existingList = params.getPrefetchedList(rowKey, columnName.key);
int idx = ByteBufferUtil.toInt(((Constants.Value)index).bytes);
if (idx < 0 || idx >= existingList.size())
throw new InvalidRequestException(String.format("List index %d out of bound, list has size %d", idx, existingList.size()));
ByteBuffer elementName = existingList.get(idx).right.name();
cf.addColumn(params.makeTombstone(elementName));
}
}
}