MemoPatterns.java
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//
// http://www.apache.org/licenses/LICENSE-2.0
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package org.apache.doris.nereids.pattern;
import org.apache.doris.nereids.trees.plans.BinaryPlan;
import org.apache.doris.nereids.trees.plans.GroupPlan;
import org.apache.doris.nereids.trees.plans.LeafPlan;
import org.apache.doris.nereids.trees.plans.Plan;
import org.apache.doris.nereids.trees.plans.UnaryPlan;
import org.apache.doris.nereids.trees.plans.algebra.Aggregate;
import org.apache.doris.nereids.trees.plans.logical.LogicalBinary;
import org.apache.doris.nereids.trees.plans.logical.LogicalExcept;
import org.apache.doris.nereids.trees.plans.logical.LogicalIntersect;
import org.apache.doris.nereids.trees.plans.logical.LogicalLeaf;
import org.apache.doris.nereids.trees.plans.logical.LogicalPlan;
import org.apache.doris.nereids.trees.plans.logical.LogicalRelation;
import org.apache.doris.nereids.trees.plans.logical.LogicalSetOperation;
import org.apache.doris.nereids.trees.plans.logical.LogicalUnary;
import org.apache.doris.nereids.trees.plans.logical.LogicalUnion;
import org.apache.doris.nereids.trees.plans.physical.PhysicalBinary;
import org.apache.doris.nereids.trees.plans.physical.PhysicalLeaf;
import org.apache.doris.nereids.trees.plans.physical.PhysicalRelation;
import org.apache.doris.nereids.trees.plans.physical.PhysicalUnary;
import java.util.Arrays;
/** MemoPatterns */
public interface MemoPatterns extends Patterns {
default PatternDescriptor<GroupPlan> group() {
return new PatternDescriptor<>(Pattern.GROUP, defaultPromise());
}
default PatternDescriptor<GroupPlan> multiGroup() {
return new PatternDescriptor<>(Pattern.MULTI_GROUP, defaultPromise());
}
/* abstract plan operator patterns */
/**
* create a leafPlan pattern.
*/
default PatternDescriptor<LeafPlan> leafPlan() {
return new PatternDescriptor(new TypePattern(LeafPlan.class), defaultPromise());
}
/**
* create a unaryPlan pattern.
*/
default PatternDescriptor<UnaryPlan<GroupPlan>> unaryPlan() {
return new PatternDescriptor(new TypePattern(UnaryPlan.class, Pattern.GROUP), defaultPromise());
}
/**
* create a unaryPlan pattern.
*/
default <C extends Plan> PatternDescriptor<UnaryPlan<C>>
unaryPlan(PatternDescriptor<C> child) {
return new PatternDescriptor(new TypePattern(UnaryPlan.class, child.pattern), defaultPromise());
}
/**
* create a binaryPlan pattern.
*/
default PatternDescriptor<BinaryPlan<GroupPlan, GroupPlan>> binaryPlan() {
return new PatternDescriptor(
new TypePattern(BinaryPlan.class, Pattern.GROUP, Pattern.GROUP),
defaultPromise()
);
}
/**
* create a binaryPlan pattern.
*/
default <LEFT_CHILD_TYPE extends Plan, RIGHT_CHILD_TYPE extends Plan>
PatternDescriptor<BinaryPlan<LEFT_CHILD_TYPE, RIGHT_CHILD_TYPE>> binaryPlan(
PatternDescriptor<LEFT_CHILD_TYPE> leftChild,
PatternDescriptor<RIGHT_CHILD_TYPE> rightChild) {
return new PatternDescriptor(
new TypePattern(BinaryPlan.class, leftChild.pattern, rightChild.pattern),
defaultPromise()
);
}
/* abstract logical plan patterns */
/**
* create a logicalPlan pattern.
*/
default PatternDescriptor<LogicalPlan> logicalPlan() {
return new PatternDescriptor(new TypePattern(LogicalPlan.class, multiGroup().pattern), defaultPromise());
}
/**
* create a logicalLeaf pattern.
*/
default PatternDescriptor<LogicalLeaf> logicalLeaf() {
return new PatternDescriptor(new TypePattern(LogicalLeaf.class), defaultPromise());
}
/**
* create a logicalUnary pattern.
*/
default PatternDescriptor<LogicalUnary<GroupPlan>> logicalUnary() {
return new PatternDescriptor(new TypePattern(LogicalUnary.class, Pattern.GROUP), defaultPromise());
}
/**
* create a logicalUnary pattern.
*/
default <C extends Plan> PatternDescriptor<LogicalUnary<C>>
logicalUnary(PatternDescriptor<C> child) {
return new PatternDescriptor(new TypePattern(LogicalUnary.class, child.pattern), defaultPromise());
}
/**
* create a logicalBinary pattern.
*/
default PatternDescriptor<LogicalBinary<GroupPlan, GroupPlan>> logicalBinary() {
return new PatternDescriptor(
new TypePattern(LogicalBinary.class, Pattern.GROUP, Pattern.GROUP),
defaultPromise()
);
}
/**
* create a logicalBinary pattern.
*/
default <LEFT_CHILD_TYPE extends Plan, RIGHT_CHILD_TYPE extends Plan>
PatternDescriptor<LogicalBinary<LEFT_CHILD_TYPE, RIGHT_CHILD_TYPE>>
logicalBinary(
PatternDescriptor<LEFT_CHILD_TYPE> leftChild,
PatternDescriptor<RIGHT_CHILD_TYPE> rightChild) {
return new PatternDescriptor(
new TypePattern(LogicalBinary.class, leftChild.pattern, rightChild.pattern),
defaultPromise()
);
}
/**
* create a logicalRelation pattern.
*/
default PatternDescriptor<LogicalRelation> logicalRelation() {
return new PatternDescriptor(new TypePattern(LogicalRelation.class), defaultPromise());
}
/**
* create a logicalSetOperation pattern.
*/
default PatternDescriptor<LogicalSetOperation>
logicalSetOperation(
PatternDescriptor... children) {
return new PatternDescriptor(
new TypePattern(LogicalSetOperation.class,
Arrays.stream(children)
.map(PatternDescriptor::getPattern)
.toArray(Pattern[]::new)),
defaultPromise());
}
/**
* create a logicalSetOperation group.
*/
default PatternDescriptor<LogicalSetOperation> logicalSetOperation() {
return new PatternDescriptor(
new TypePattern(LogicalSetOperation.class, multiGroup().pattern),
defaultPromise());
}
/**
* create a logicalUnion pattern.
*/
default PatternDescriptor<LogicalUnion>
logicalUnion(
PatternDescriptor... children) {
return new PatternDescriptor(
new TypePattern(LogicalUnion.class,
Arrays.stream(children)
.map(PatternDescriptor::getPattern)
.toArray(Pattern[]::new)),
defaultPromise());
}
/**
* create a logicalUnion group.
*/
default PatternDescriptor<LogicalUnion> logicalUnion() {
return new PatternDescriptor(
new TypePattern(LogicalUnion.class, multiGroup().pattern),
defaultPromise());
}
/**
* create a logicalExcept pattern.
*/
default PatternDescriptor<LogicalExcept>
logicalExcept(
PatternDescriptor... children) {
return new PatternDescriptor(
new TypePattern(LogicalExcept.class,
Arrays.stream(children)
.map(PatternDescriptor::getPattern)
.toArray(Pattern[]::new)),
defaultPromise());
}
/**
* create a logicalExcept group.
*/
default PatternDescriptor<LogicalExcept> logicalExcept() {
return new PatternDescriptor(
new TypePattern(LogicalExcept.class, multiGroup().pattern),
defaultPromise());
}
/**
* create a logicalUnion pattern.
*/
default PatternDescriptor<LogicalIntersect>
logicalIntersect(
PatternDescriptor... children) {
return new PatternDescriptor(
new TypePattern(LogicalIntersect.class,
Arrays.stream(children)
.map(PatternDescriptor::getPattern)
.toArray(Pattern[]::new)),
defaultPromise());
}
/**
* create a logicalUnion group.
*/
default PatternDescriptor<LogicalIntersect> logicalIntersect() {
return new PatternDescriptor(
new TypePattern(LogicalIntersect.class, multiGroup().pattern),
defaultPromise());
}
/* abstract physical plan patterns */
/**
* create a physicalLeaf pattern.
*/
default PatternDescriptor<PhysicalLeaf> physicalLeaf() {
return new PatternDescriptor(new TypePattern(PhysicalLeaf.class), defaultPromise());
}
/**
* create a physicalUnary pattern.
*/
default PatternDescriptor<PhysicalUnary<GroupPlan>> physicalUnary() {
return new PatternDescriptor(new TypePattern(PhysicalUnary.class, Pattern.GROUP), defaultPromise());
}
/**
* create a physicalUnary pattern.
*/
default <C extends Plan> PatternDescriptor<PhysicalUnary<C>>
physicalUnary(PatternDescriptor<C> child) {
return new PatternDescriptor(new TypePattern(PhysicalUnary.class, child.pattern), defaultPromise());
}
/**
* create a physicalBinary pattern.
*/
default PatternDescriptor<PhysicalBinary<GroupPlan, GroupPlan>> physicalBinary() {
return new PatternDescriptor(
new TypePattern(PhysicalBinary.class, Pattern.GROUP, Pattern.GROUP),
defaultPromise()
);
}
/**
* create a physicalBinary pattern.
*/
default <LEFT_CHILD_TYPE extends Plan, RIGHT_CHILD_TYPE extends Plan>
PatternDescriptor<PhysicalBinary<LEFT_CHILD_TYPE, RIGHT_CHILD_TYPE>>
physicalBinary(
PatternDescriptor<LEFT_CHILD_TYPE> leftChild,
PatternDescriptor<RIGHT_CHILD_TYPE> rightChild) {
return new PatternDescriptor(
new TypePattern(PhysicalBinary.class, leftChild.pattern, rightChild.pattern),
defaultPromise()
);
}
/**
* create a physicalRelation pattern.
*/
default PatternDescriptor<PhysicalRelation> physicalRelation() {
return new PatternDescriptor(new TypePattern(PhysicalRelation.class), defaultPromise());
}
/**
* create a aggregate pattern.
*/
default PatternDescriptor<Aggregate<GroupPlan>> aggregate() {
return new PatternDescriptor(new TypePattern(Aggregate.class, Pattern.GROUP), defaultPromise());
}
/**
* create a aggregate pattern.
*/
default <C extends Plan> PatternDescriptor<Aggregate<C>> aggregate(PatternDescriptor<C> child) {
return new PatternDescriptor(new TypePattern(Aggregate.class, child.pattern), defaultPromise());
}
}