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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.
/*
* 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.index.sasi.plan;
import java.io.IOException;
import java.nio.ByteBuffer;
import java.util.*;
import org.apache.cassandra.config.ColumnDefinition;
import org.apache.cassandra.config.ColumnDefinition.Kind;
import org.apache.cassandra.cql3.Operator;
import org.apache.cassandra.db.filter.RowFilter;
import org.apache.cassandra.db.rows.Row;
import org.apache.cassandra.db.rows.Unfiltered;
import org.apache.cassandra.index.sasi.conf.ColumnIndex;
import org.apache.cassandra.index.sasi.analyzer.AbstractAnalyzer;
import org.apache.cassandra.index.sasi.disk.Token;
import org.apache.cassandra.index.sasi.plan.Expression.Op;
import org.apache.cassandra.index.sasi.utils.RangeIntersectionIterator;
import org.apache.cassandra.index.sasi.utils.RangeIterator;
import org.apache.cassandra.index.sasi.utils.RangeUnionIterator;
import com.google.common.annotations.VisibleForTesting;
import com.google.common.collect.*;
import org.apache.cassandra.utils.FBUtilities;
@SuppressWarnings("resource")
public class Operation extends RangeIterator
{
public enum OperationType
{
AND, OR;
public boolean apply(boolean a, boolean b)
{
switch (this)
{
case OR:
return a | b;
case AND:
return a & b;
default:
throw new AssertionError();
}
}
}
private final QueryController controller;
protected final OperationType op;
protected final ListMultimap expressions;
protected final RangeIterator range;
protected Operation left, right;
private Operation(OperationType operation,
QueryController controller,
ListMultimap expressions,
RangeIterator range,
Operation left, Operation right)
{
super(range);
this.op = operation;
this.controller = controller;
this.expressions = expressions;
this.range = range;
this.left = left;
this.right = right;
}
/**
* Recursive "satisfies" checks based on operation
* and data from the lower level members using depth-first search
* and bubbling the results back to the top level caller.
*
* Most of the work here is done by {@link #localSatisfiedBy(Unfiltered, Row, boolean)}
* see it's comment for details, if there are no local expressions
* assigned to Operation it will call satisfiedBy(Row) on it's children.
*
* Query: first_name = X AND (last_name = Y OR address = XYZ AND street = IL AND city = C) OR (state = 'CA' AND country = 'US')
* Row: key1: (first_name: X, last_name: Z, address: XYZ, street: IL, city: C, state: NY, country:US)
*
* #1 OR
* / \
* #2 (first_name) AND AND (state, country)
* \
* #3 (last_name) OR
* \
* #4 AND (address, street, city)
*
*
* Evaluation of the key1 is top-down depth-first search:
*
* --- going down ---
* Level #1 is evaluated, OR expression has to pull results from it's children which are at level #2 and OR them together,
* Level #2 AND (state, country) could be be evaluated right away, AND (first_name) refers to it's "right" child from level #3
* Level #3 OR (last_name) requests results from level #4
* Level #4 AND (address, street, city) does logical AND between it's 3 fields, returns result back to level #3.
* --- bubbling up ---
* Level #3 computes OR between AND (address, street, city) result and it's "last_name" expression
* Level #2 computes AND between "first_name" and result of level #3, AND (state, country) which is already computed
* Level #1 does OR between results of AND (first_name) and AND (state, country) and returns final result.
*
* @param currentCluster The row cluster to check.
* @param staticRow The static row associated with current cluster.
* @param allowMissingColumns allow columns value to be null.
* @return true if give Row satisfied all of the expressions in the tree,
* false otherwise.
*/
public boolean satisfiedBy(Unfiltered currentCluster, Row staticRow, boolean allowMissingColumns)
{
boolean sideL, sideR;
if (expressions == null || expressions.isEmpty())
{
sideL = left != null && left.satisfiedBy(currentCluster, staticRow, allowMissingColumns);
sideR = right != null && right.satisfiedBy(currentCluster, staticRow, allowMissingColumns);
// one of the expressions was skipped
// because it had no indexes attached
if (left == null)
return sideR;
}
else
{
sideL = localSatisfiedBy(currentCluster, staticRow, allowMissingColumns);
// if there is no right it means that this expression
// is last in the sequence, we can just return result from local expressions
if (right == null)
return sideL;
sideR = right.satisfiedBy(currentCluster, staticRow, allowMissingColumns);
}
return op.apply(sideL, sideR);
}
/**
* Check every expression in the analyzed list to figure out if the
* columns in the give row match all of the based on the operation
* set to the current operation node.
*
* The algorithm is as follows: for every given expression from analyzed
* list get corresponding column from the Row:
* - apply {@link Expression#isSatisfiedBy(ByteBuffer)}
* method to figure out if it's satisfied;
* - apply logical operation between boolean accumulator and current boolean result;
* - if result == false and node's operation is AND return right away;
*
* After all of the expressions have been evaluated return resulting accumulator variable.
*
* Example:
*
* Operation = (op: AND, columns: [first_name = p, 5 < age < 7, last_name: y])
* Row = (first_name: pavel, last_name: y, age: 6, timestamp: 15)
*
* #1 get "first_name" = p (expressions)
* - row-get "first_name" => "pavel"
* - compare "pavel" against "p" => true (current)
* - set accumulator current => true (because this is expression #1)
*
* #2 get "last_name" = y (expressions)
* - row-get "last_name" => "y"
* - compare "y" against "y" => true (current)
* - set accumulator to accumulator & current => true
*
* #3 get 5 < "age" < 7 (expressions)
* - row-get "age" => "6"
* - compare 5 < 6 < 7 => true (current)
* - set accumulator to accumulator & current => true
*
* #4 return accumulator => true (row satisfied all of the conditions)
*
* @param currentCluster The row cluster to check.
* @param staticRow The static row associated with current cluster.
* @param allowMissingColumns allow columns value to be null.
* @return true if give Row satisfied all of the analyzed expressions,
* false otherwise.
*/
private boolean localSatisfiedBy(Unfiltered currentCluster, Row staticRow, boolean allowMissingColumns)
{
if (currentCluster == null || !currentCluster.isRow())
return false;
final int now = FBUtilities.nowInSeconds();
boolean result = false;
int idx = 0;
for (ColumnDefinition column : expressions.keySet())
{
if (column.kind == Kind.PARTITION_KEY)
continue;
ByteBuffer value = ColumnIndex.getValueOf(column, column.kind == Kind.STATIC ? staticRow : (Row) currentCluster, now);
boolean isMissingColumn = value == null;
if (!allowMissingColumns && isMissingColumn)
throw new IllegalStateException("All indexed columns should be included into the column slice, missing: " + column);
boolean isMatch = false;
// If there is a column with multiple expressions that effectively means an OR
// e.g. comment = 'x y z' could be split into 'comment' EQ 'x', 'comment' EQ 'y', 'comment' EQ 'z'
// by analyzer, in situation like that we only need to check if at least one of expressions matches,
// and there is no hit on the NOT_EQ (if any) which are always at the end of the filter list.
// Loop always starts from the end of the list, which makes it possible to break after the last
// NOT_EQ condition on first EQ/RANGE condition satisfied, instead of checking every
// single expression in the column filter list.
List filters = expressions.get(column);
for (int i = filters.size() - 1; i >= 0; i--)
{
Expression expression = filters.get(i);
isMatch = !isMissingColumn && expression.isSatisfiedBy(value);
if (expression.getOp() == Op.NOT_EQ)
{
// since this is NOT_EQ operation we have to
// inverse match flag (to check against other expressions),
// and break in case of negative inverse because that means
// that it's a positive hit on the not-eq clause.
isMatch = !isMatch;
if (!isMatch)
break;
} // if it was a match on EQ/RANGE or column is missing
else if (isMatch || isMissingColumn)
break;
}
if (idx++ == 0)
{
result = isMatch;
continue;
}
result = op.apply(result, isMatch);
// exit early because we already got a single false
if (op == OperationType.AND && !result)
return false;
}
return idx == 0 || result;
}
@VisibleForTesting
protected static ListMultimap analyzeGroup(QueryController controller,
OperationType op,
List expressions)
{
ListMultimap analyzed = ArrayListMultimap.create();
// sort all of the expressions in the operation by name and priority of the logical operator
// this gives us an efficient way to handle inequality and combining into ranges without extra processing
// and converting expressions from one type to another.
Collections.sort(expressions, (a, b) -> {
int cmp = a.column().compareTo(b.column());
return cmp == 0 ? -Integer.compare(getPriority(a.operator()), getPriority(b.operator())) : cmp;
});
for (final RowFilter.Expression e : expressions)
{
ColumnIndex columnIndex = controller.getIndex(e);
List perColumn = analyzed.get(e.column());
if (columnIndex == null)
columnIndex = new ColumnIndex(controller.getKeyValidator(), e.column(), null);
AbstractAnalyzer analyzer = columnIndex.getAnalyzer();
analyzer.reset(e.getIndexValue().duplicate());
// EQ/LIKE_*/NOT_EQ can have multiple expressions e.g. text = "Hello World",
// becomes text = "Hello" OR text = "World" because "space" is always interpreted as a split point (by analyzer),
// NOT_EQ is made an independent expression only in case of pre-existing multiple EQ expressions, or
// if there is no EQ operations and NOT_EQ is met or a single NOT_EQ expression present,
// in such case we know exactly that there would be no more EQ/RANGE expressions for given column
// since NOT_EQ has the lowest priority.
boolean isMultiExpression = false;
switch (e.operator())
{
case EQ:
isMultiExpression = false;
break;
case LIKE_PREFIX:
case LIKE_SUFFIX:
case LIKE_CONTAINS:
case LIKE_MATCHES:
isMultiExpression = true;
break;
case NEQ:
isMultiExpression = (perColumn.size() == 0 || perColumn.size() > 1
|| (perColumn.size() == 1 && perColumn.get(0).getOp() == Op.NOT_EQ));
break;
}
if (isMultiExpression)
{
while (analyzer.hasNext())
{
final ByteBuffer token = analyzer.next();
perColumn.add(new Expression(controller, columnIndex).add(e.operator(), token));
}
}
else
// "range" or not-equals operator, combines both bounds together into the single expression,
// iff operation of the group is AND, otherwise we are forced to create separate expressions,
// not-equals is combined with the range iff operator is AND.
{
Expression range;
if (perColumn.size() == 0 || op != OperationType.AND)
perColumn.add((range = new Expression(controller, columnIndex)));
else
range = Iterables.getLast(perColumn);
while (analyzer.hasNext())
range.add(e.operator(), analyzer.next());
}
}
return analyzed;
}
private static int getPriority(Operator op)
{
switch (op)
{
case EQ:
return 5;
case LIKE_PREFIX:
case LIKE_SUFFIX:
case LIKE_CONTAINS:
case LIKE_MATCHES:
return 4;
case GTE:
case GT:
return 3;
case LTE:
case LT:
return 2;
case NEQ:
return 1;
default:
return 0;
}
}
protected Token computeNext()
{
return range != null && range.hasNext() ? range.next() : endOfData();
}
protected void performSkipTo(Long nextToken)
{
if (range != null)
range.skipTo(nextToken);
}
public void close() throws IOException
{
controller.releaseIndexes(this);
}
public static class Builder
{
private final QueryController controller;
protected final OperationType op;
protected final List expressions;
protected Builder left, right;
public Builder(OperationType operation, QueryController controller, RowFilter.Expression... columns)
{
this.op = operation;
this.controller = controller;
this.expressions = new ArrayList<>();
Collections.addAll(expressions, columns);
}
public Builder setRight(Builder operation)
{
this.right = operation;
return this;
}
public Builder setLeft(Builder operation)
{
this.left = operation;
return this;
}
public void add(RowFilter.Expression e)
{
expressions.add(e);
}
public void add(Collection newExpressions)
{
if (expressions != null)
expressions.addAll(newExpressions);
}
public Operation complete()
{
if (!expressions.isEmpty())
{
ListMultimap analyzedExpressions = analyzeGroup(controller, op, expressions);
RangeIterator.Builder range = controller.getIndexes(op, analyzedExpressions.values());
Operation rightOp = null;
if (right != null)
{
rightOp = right.complete();
range.add(rightOp);
}
return new Operation(op, controller, analyzedExpressions, range.build(), null, rightOp);
}
else
{
Operation leftOp = null, rightOp = null;
boolean leftIndexes = false, rightIndexes = false;
if (left != null)
{
leftOp = left.complete();
leftIndexes = leftOp != null && leftOp.range != null;
}
if (right != null)
{
rightOp = right.complete();
rightIndexes = rightOp != null && rightOp.range != null;
}
RangeIterator join;
/**
* Operation should allow one of it's sub-trees to wrap no indexes, that is related to the fact that we
* have to accept defined-but-not-indexed columns as well as key range as IndexExpressions.
*
* Two cases are possible:
*
* only left child produced indexed iterators, that could happen when there are two columns
* or key range on the right:
*
* AND
* / \
* OR \
* / \ AND
* a b / \
* key key
*
* only right child produced indexed iterators:
*
* AND
* / \
* AND a
* / \
* key key
*/
if (leftIndexes && !rightIndexes)
join = leftOp;
else if (!leftIndexes && rightIndexes)
join = rightOp;
else if (leftIndexes)
{
RangeIterator.Builder builder = op == OperationType.OR
? RangeUnionIterator.builder()
: RangeIntersectionIterator.builder();
join = builder.add(leftOp).add(rightOp).build();
}
else
throw new AssertionError("both sub-trees have 0 indexes.");
return new Operation(op, controller, null, join, leftOp, rightOp);
}
}
}
}