com.hazelcast.org.apache.calcite.adapter.enumerable.EnumerableJoinRule Maven / Gradle / Ivy
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* 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,
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package com.hazelcast.org.apache.calcite.adapter.enumerable;
import com.hazelcast.org.apache.calcite.plan.Convention;
import com.hazelcast.org.apache.calcite.rel.RelNode;
import com.hazelcast.org.apache.calcite.rel.convert.ConverterRule;
import com.hazelcast.org.apache.calcite.rel.core.Join;
import com.hazelcast.org.apache.calcite.rel.core.JoinInfo;
import com.hazelcast.org.apache.calcite.rel.logical.LogicalJoin;
import com.hazelcast.org.apache.calcite.rex.RexBuilder;
import com.hazelcast.org.apache.calcite.rex.RexNode;
import com.hazelcast.org.apache.calcite.rex.RexUtil;
import java.util.ArrayList;
import java.util.Arrays;
import java.util.List;
/** Planner rule that converts a
* {@link LogicalJoin} relational expression
* {@link com.hazelcast.org.apache.calcite.adapter.enumerable.EnumerableConvention enumerable calling convention}.
* You may provide a custom config to convert other nodes that extend {@link Join}.
*
* @see EnumerableRules#ENUMERABLE_JOIN_RULE */
class EnumerableJoinRule extends ConverterRule {
/** Default configuration. */
public static final Config DEFAULT_CONFIG = Config.INSTANCE
.withConversion(LogicalJoin.class, Convention.NONE,
EnumerableConvention.INSTANCE, "EnumerableJoinRule")
.withRuleFactory(EnumerableJoinRule::new);
/** Called from the Config. */
protected EnumerableJoinRule(Config config) {
super(config);
}
@Override public RelNode convert(RelNode rel) {
Join join = (Join) rel;
List newInputs = new ArrayList<>();
for (RelNode input : join.getInputs()) {
if (!(input.getConvention() instanceof EnumerableConvention)) {
input =
convert(
input,
input.getTraitSet()
.replace(EnumerableConvention.INSTANCE));
}
newInputs.add(input);
}
final RexBuilder rexBuilder = join.getCluster().getRexBuilder();
final RelNode left = newInputs.get(0);
final RelNode right = newInputs.get(1);
final JoinInfo info = join.analyzeCondition();
// If the join has equiKeys (i.e. complete or partial equi-join),
// create an EnumerableHashJoin, which supports all types of joins,
// even if the join condition contains partial non-equi sub-conditions;
// otherwise (complete non-equi-join), create an EnumerableNestedLoopJoin,
// since a hash join strategy in this case would not be beneficial.
final boolean hasEquiKeys = !info.leftKeys.isEmpty()
&& !info.rightKeys.isEmpty();
if (hasEquiKeys) {
// Re-arrange condition: first the equi-join elements, then the non-equi-join ones (if any);
// this is not strictly necessary but it will be useful to avoid spurious errors in the
// unit tests when verifying the plan.
final RexNode equi = info.getEquiCondition(left, right, rexBuilder);
final RexNode condition;
if (info.isEqui()) {
condition = equi;
} else {
final RexNode nonEqui = RexUtil.composeConjunction(rexBuilder, info.nonEquiConditions);
condition = RexUtil.composeConjunction(rexBuilder, Arrays.asList(equi, nonEqui));
}
return EnumerableHashJoin.create(
left,
right,
condition,
join.getVariablesSet(),
join.getJoinType());
}
return EnumerableNestedLoopJoin.create(
left,
right,
join.getCondition(),
join.getVariablesSet(),
join.getJoinType());
}
}
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