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 * 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
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package org.apache.flink.api.java.functions;

import org.apache.flink.annotation.Internal;
import org.apache.flink.annotation.Public;
import org.apache.flink.annotation.PublicEvolving;
import org.apache.flink.api.common.InvalidProgramException;

import java.lang.annotation.Annotation;
import java.lang.annotation.ElementType;
import java.lang.annotation.Retention;
import java.lang.annotation.RetentionPolicy;
import java.lang.annotation.Target;
import java.util.HashSet;
import java.util.Set;

/**
 * This class defines Java annotations for semantic assertions that can be added to Flink functions.
 * Semantic annotations can help the Flink optimizer to generate more efficient execution plans for
 * Flink programs. For example, a ForwardedFields assertion for a map-type function can be
 * declared as:
 *
 * 
{@code
 * {@literal @}ForwardedFields({"f0; f2->f1"})
 * public class MyMapper extends MapFunction, Tuple3>
 * {
 *     public Tuple3 map(Tuple3 val) {
 *
 *         return new Tuple3(val.f0, val.f2, 1);
 *     }
 * }
 * }
* *

All annotations take Strings with expressions that refer to (nested) value fields of the input * and output types of a function. Field expressions for of composite data types (tuples, POJOs, * Scala case classes) can be expressed in different ways, depending on the data type they refer to. * *

    *
  • Java tuple data types (such as {@link org.apache.flink.api.java.tuple.Tuple3}): A tuple * field can be addressed using its 0-offset index or name, e.g., the second field of a Java * tuple is addressed by "1" or "f1". *
  • Java POJO data types: A POJO field is addressed using its names, e.g., "xValue" * for the member field xValue of a POJO type that describes a * 2d-coordinate. *
  • Scala tuple data types (such as {@link scala.Tuple3}): A tuple field can be addressed using * its 1-offset name (following Scala conventions) or 0-offset index, e.g., the second field * of a Scala tuple is addressed by "_2" or 1 *
  • Scala case classes: A case class field is addressed using its names, e.g., "xValue" * for the field xValue of a case class that describes a 2d-coordinate. *
* *

Nested fields are addressed by navigation, e.g., "f1.xValue" addresses the field * xValue of a POJO type, that is stored at the second field of a Java tuple. In order * to refer to all fields of a composite type (or the composite type itself) such as a tuple, POJO, * or case class type, a "*" wildcard can be used, e.g., f2.* or f2 * reference all fields of a composite type at the third position of a Java tuple. * *

NOTE: The use of semantic annotation is optional! If used correctly, semantic annotations * can help the Flink optimizer to generate more efficient execution plans. However, incorrect * semantic annotations can cause the optimizer to generate incorrect execution plans which compute * wrong results! So be careful when adding semantic annotations. */ @Public public class FunctionAnnotation { /** * The ForwardedFields annotation declares fields which are never modified by the annotated * function and which are forwarded at the same position to the output or unchanged copied to * another position in the output. * *

Fields that are forwarded at the same position can be specified by their position. The * specified position must be valid for the input and output data type and have the same type. * For example {@code {@literal @}ForwardedFields({"f2"})} declares that the third field of a * Java input tuple is copied to the third field of an output tuple. * *

Fields which are unchanged copied to another position in the output are declared by * specifying the source field expression in the input and the target field expression in the * output. {@code {@literal @}ForwardedFields({"f0->f2"})} denotes that the first field of the * Java input tuple is unchanged copied to the third field of the Java output tuple. When using * the wildcard ("*") ensure that the number of declared fields and their types in input and * output type match. * *

Multiple forwarded fields can be annotated in one ({@code * {@literal @}ForwardedFields({"f2; f3->f0; f4"})}) or separate Strings ({@code * {@literal @}ForwardedFields({"f2", "f3->f0", "f4"})}). * *

NOTE: The use of the ForwardedFields annotation is optional. If used correctly, it can * help the Flink optimizer to generate more efficient execution plans. However if used * incorrectly, it can cause invalid plan choices and the computation of wrong results! It is * NOT required that all forwarded fields are declared, but all declarations must be correct. * * *

Please refer to the JavaDoc of {@link org.apache.flink.api.common.functions.Function} or * Flink's documentation for details on field expressions such as nested fields and wildcard. */ @Target(ElementType.TYPE) @Retention(RetentionPolicy.RUNTIME) public @interface ForwardedFields { String[] value(); } /** * The ForwardedFieldsFirst annotation declares fields of the first input of a function which * are never modified by the annotated function and which are forwarded at the same position to * the output or unchanged copied to another position in the output. * *

Fields that are forwarded from the first input at the same position in the output can be * specified by their position. The specified position must be valid for the input and output * data type and have the same type. For example {@code * {@literal @}ForwardedFieldsFirst({"f2"})} declares that the third field of a Java input tuple * at the first input is copied to the third field of an output tuple. * *

Fields which are unchanged copied to another position in the output are declared by * specifying the source field expression in the input and the target field expression in the * output. {@code {@literal @}ForwardedFieldsFirst({"f0->f2"})} denotes that the first field of * the Java input tuple at the first input is unchanged copied to the third field of the Java * output tuple. When using the wildcard ("*") ensure that the number of declared fields and * their types in input and output type match. * *

Multiple forwarded fields can be annotated in one ({@code * {@literal @}ForwardedFieldsFirst({"f2; f3->f0; f4"})}) or separate Strings ({@code * {@literal @}ForwardedFieldsFirst({"f2", "f3->f0", "f4"})}). * *

NOTE: The use of the ForwardedFieldsFirst annotation is optional. If used correctly, it * can help the Flink optimizer to generate more efficient execution plans. However if used * incorrectly, it can cause invalid plan choices and the computation of wrong results! It is * NOT required that all forwarded fields are declared, but all declarations must be correct. * * *

Please refer to the JavaDoc of {@link org.apache.flink.api.common.functions.Function} or * Flink's documentation for details on field expressions such as nested fields and wildcard. * *

Forwarded fields from the second input can be specified using the {@link * org.apache.flink.api.java.functions.FunctionAnnotation.ForwardedFieldsSecond} annotation. */ @Target(ElementType.TYPE) @Retention(RetentionPolicy.RUNTIME) public @interface ForwardedFieldsFirst { String[] value(); } /** * The ForwardedFieldsSecond annotation declares fields of the second input of a function which * are never modified by the annotated function and which are forwarded at the same position to * the output or unchanged copied to another position in the output. * *

Fields that are forwarded from the second input at the same position in the output can be * specified by their position. The specified position must be valid for the input and output * data type and have the same type. For example {@code * {@literal @}ForwardedFieldsSecond({"f2"})} declares that the third field of a Java input * tuple at the second input is copied to the third field of an output tuple. * *

Fields which are unchanged copied to another position in the output are declared by * specifying the source field expression in the input and the target field expression in the * output. {@code {@literal @}ForwardedFieldsSecond({"f0->f2"})} denotes that the first field of * the Java input tuple at the second input is unchanged copied to the third field of the Java * output tuple. When using the wildcard ("*") ensure that the number of declared fields and * their types in input and output type match. * *

Multiple forwarded fields can be annotated in one ({@code * {@literal @}ForwardedFieldsSecond({"f2; f3->f0; f4"})}) or separate Strings ({@code * {@literal @}ForwardedFieldsSecond({"f2", "f3->f0", "f4"})}). * *

NOTE: The use of the ForwardedFieldsSecond annotation is optional. If used correctly, * it can help the Flink optimizer to generate more efficient execution plans. However if used * incorrectly, it can cause invalid plan choices and the computation of wrong results! It is * NOT required that all forwarded fields are declared, but all declarations must be correct. * * *

Please refer to the JavaDoc of {@link org.apache.flink.api.common.functions.Function} or * Flink's documentation for details on field expressions such as nested fields and wildcard. * *

Forwarded fields from the first input can be specified using the {@link * org.apache.flink.api.java.functions.FunctionAnnotation.ForwardedFieldsFirst} annotation. */ @Target(ElementType.TYPE) @Retention(RetentionPolicy.RUNTIME) public @interface ForwardedFieldsSecond { String[] value(); } /** * The NonForwardedFields annotation declares ALL fields which not preserved on the same * position in a functions output. ALL other fields are considered to be unmodified at the same * position. Hence, the NonForwardedFields annotation is inverse to the {@link * org.apache.flink.api.java.functions.FunctionAnnotation.ForwardedFields} annotation. * *

NOTE: The use of the NonForwardedFields annotation is optional. If used correctly, it * can help the Flink optimizer to generate more efficient execution plans. However if used * incorrectly, it can cause invalid plan choices and the computation of wrong results! Since * all not declared fields are considered to be forwarded, it is required that ALL non-forwarded * fields are declared. * *

Non-forwarded fields are declared as a list of field expressions, e.g., * \@NonForwardedFields({"f1; f3"}) declares that the second and fourth field of a Java * tuple are modified and all other fields are are not changed and remain on their position. A * NonForwardedFields annotation can only be used on functions where the type of the input and * output are identical. * *

Multiple non-forwarded fields can be annotated in one ( * \@NonForwardedFields({"f1; f3"})) or separate Strings ( * \@NonForwardedFields({"f1", "f3"})). * *

Please refer to the JavaDoc of {@link org.apache.flink.api.common.functions.Function} or * Flink's documentation for details on field expressions such as nested fields and wildcard. * * @see org.apache.flink.api.java.functions.FunctionAnnotation.ForwardedFields */ @Target(ElementType.TYPE) @Retention(RetentionPolicy.RUNTIME) public @interface NonForwardedFields { String[] value(); } /** * The NonForwardedFieldsFirst annotation declares for a function ALL fields of its first input * which are not preserved on the same position in its output. ALL other fields are considered * to be unmodified at the same position. Hence, the NonForwardedFieldsFirst annotation is * inverse to the {@link * org.apache.flink.api.java.functions.FunctionAnnotation.ForwardedFieldsFirst} annotation. * *

NOTE: The use of the NonForwardedFieldsFirst annotation is optional. If used correctly, * it can help the Flink optimizer to generate more efficient execution plans. However if used * incorrectly, it can cause invalid plan choices and the computation of wrong results! Since * all not declared fields are considered to be forwarded, it is required that ALL non-forwarded * fields of the first input are declared. * *

Non-forwarded fields are declared as a list of field expressions, e.g., * \@NonForwardedFieldsFirst({"f1; f3"}) declares that the second and fourth field of a * Java tuple from the first input are modified and all other fields of the first input are are * not changed and remain on their position. A NonForwardedFieldsFirst annotation can only be * used on functions where the type of the first input and the output are identical. * *

Multiple non-forwarded fields can be annotated in one ( * \@NonForwardedFieldsFirst({"f1; f3"})) or separate Strings ( * \@NonForwardedFieldsFirst({"f1", "f3"})). * *

Please refer to the JavaDoc of {@link org.apache.flink.api.common.functions.Function} or * Flink's documentation for details on field expressions such as nested fields and wildcard. * * @see org.apache.flink.api.java.functions.FunctionAnnotation.NonForwardedFields * @see org.apache.flink.api.java.functions.FunctionAnnotation.ForwardedFieldsFirst */ @Target(ElementType.TYPE) @Retention(RetentionPolicy.RUNTIME) public @interface NonForwardedFieldsFirst { String[] value(); } /** * The NonForwardedFieldsSecond annotation declares for a function ALL fields of its second * input which are not preserved on the same position in its output. ALL other fields are * considered to be unmodified at the same position. Hence, the NonForwardedFieldsSecond * annotation is inverse to the {@link * org.apache.flink.api.java.functions.FunctionAnnotation.ForwardedFieldsSecond} annotation. * *

NOTE: The use of the NonForwardedFieldsSecond annotation is optional. If used * correctly, it can help the Flink optimizer to generate more efficient execution plans. * However if used incorrectly, it can cause invalid plan choices and the computation of wrong * results! Since all not declared fields are considered to be forwarded, it is required that * ALL non-forwarded fields of the second input are declared. * *

Non-forwarded fields are declared as a list of field expressions, e.g., * \@NonForwardedFieldsSecond({"f1; f3"}) declares that the second and fourth field of a * Java tuple from the second input are modified and all other fields of the second input are * are not changed and remain on their position. A NonForwardedFieldsSecond annotation can only * be used on functions where the type of the second input and the output are identical. * *

Multiple non-forwarded fields can be annotated in one ( * \@NonForwardedFieldsSecond({"f1; f3"})) or separate Strings ( * \@NonForwardedFieldsSecond({"f1", "f3"})). * *

Please refer to the JavaDoc of {@link org.apache.flink.api.common.functions.Function} or * Flink's documentation for details on field expressions such as nested fields and wildcard. * * @see org.apache.flink.api.java.functions.FunctionAnnotation.NonForwardedFields * @see org.apache.flink.api.java.functions.FunctionAnnotation.ForwardedFieldsSecond */ @Target(ElementType.TYPE) @Retention(RetentionPolicy.RUNTIME) public @interface NonForwardedFieldsSecond { String[] value(); } /** * The ReadFields annotation declares for a function all fields which it accesses and evaluates, * i.e., all fields that are used by the function to compute its result. For example, fields * which are evaluated in conditional statements or used for computations are considered to be * read. Fields which are only unmodified copied to the output without evaluating their values * are NOT considered to be read. * *

NOTE: The use of the ReadFields annotation is optional. If used correctly, it can help * the Flink optimizer to generate more efficient execution plans. The ReadFields annotation * requires that ALL read fields are declared. Otherwise, it can cause invalid plan choices and * the computation of wrong results! Declaring a non-read field as read is not harmful but might * reduce optimization potential. * *

Read fields are declared as a list of field expressions, e.g., * \@ReadFields({"f0; f2"}) declares the first and third field of a Java input tuple to * be read. All other fields are considered to not influence the behavior of the function. * *

Multiple read fields can be declared in one \@ReadFields({"f0; f2"}) or * multiple separate Strings \@ReadFields({"f0", "f2"}). * *

Please refer to the JavaDoc of {@link org.apache.flink.api.common.functions.Function} or * Flink's documentation for details on field expressions such as nested fields and wildcard. */ @Target(ElementType.TYPE) @Retention(RetentionPolicy.RUNTIME) @PublicEvolving public @interface ReadFields { String[] value(); } /** * The ReadFieldsFirst annotation declares for a function all fields of the first input which it * accesses and evaluates, i.e., all fields of the first input that are used by the function to * compute its result. For example, fields which are evaluated in conditional statements or used * for computations are considered to be read. Fields which are only unmodified copied to the * output without evaluating their values are NOT considered to be read. * *

NOTE: The use of the ReadFieldsFirst annotation is optional. If used correctly, it can * help the Flink optimizer to generate more efficient execution plans. The ReadFieldsFirst * annotation requires that ALL read fields of the first input are declared. Otherwise, it can * cause invalid plan choices and the computation of wrong results! Declaring a non-read field * as read is not harmful but might reduce optimization potential. * *

Read fields are declared as a list of field expressions, e.g., * \@ReadFieldsFirst({"f0; f2"}) declares the first and third field of a Java input tuple * of the first input to be read. All other fields of the first input are considered to not * influence the behavior of the function. * *

Multiple read fields can be declared in one \@ReadFieldsFirst({"f0; f2"}) or * multiple separate Strings \@ReadFieldsFirst({"f0", "f2"}). * *

Please refer to the JavaDoc of {@link org.apache.flink.api.common.functions.Function} or * Flink's documentation for details on field expressions such as nested fields and wildcard. */ @Target(ElementType.TYPE) @Retention(RetentionPolicy.RUNTIME) @PublicEvolving public @interface ReadFieldsFirst { String[] value(); } /** * The ReadFieldsSecond annotation declares for a function all fields of the second input which * it accesses and evaluates, i.e., all fields of the second input that are used by the function * to compute its result. For example, fields which are evaluated in conditional statements or * used for computations are considered to be read. Fields which are only unmodified copied to * the output without evaluating their values are NOT considered to be read. * *

NOTE: The use of the ReadFieldsSecond annotation is optional. If used correctly, it can * help the Flink optimizer to generate more efficient execution plans. The ReadFieldsSecond * annotation requires that ALL read fields of the second input are declared. Otherwise, it can * cause invalid plan choices and the computation of wrong results! Declaring a non-read field * as read is not harmful but might reduce optimization potential. * *

Read fields are declared as a list of field expressions, e.g., * \@ReadFieldsSecond({"f0; f2"}) declares the first and third field of a Java input * tuple of the second input to be read. All other fields of the second input are considered to * not influence the behavior of the function. * *

Multiple read fields can be declared in one \@ReadFieldsSecond({"f0; f2"}) or * multiple separate Strings \@ReadFieldsSecond({"f0", "f2"}). * *

Please refer to the JavaDoc of {@link org.apache.flink.api.common.functions.Function} or * Flink's documentation for details on field expressions such as nested fields and wildcard. */ @Target(ElementType.TYPE) @Retention(RetentionPolicy.RUNTIME) @PublicEvolving public @interface ReadFieldsSecond { String[] value(); } /** Private constructor to prevent instantiation. This class is intended only as a container. */ private FunctionAnnotation() {} // -------------------------------------------------------------------------------------------- // Function Annotation Handling // -------------------------------------------------------------------------------------------- /** * Reads the annotations of a user defined function with one input and returns semantic * properties according to the forwarded fields annotated. * * @param udfClass The user defined function, represented by its class. * @return The DualInputSemanticProperties containing the forwarded fields. */ @Internal public static Set readSingleForwardAnnotations(Class udfClass) { ForwardedFields forwardedFields = udfClass.getAnnotation(ForwardedFields.class); NonForwardedFields nonForwardedFields = udfClass.getAnnotation(NonForwardedFields.class); ReadFields readSet = udfClass.getAnnotation(ReadFields.class); Set annotations = new HashSet(); if (forwardedFields != null) { annotations.add(forwardedFields); } if (nonForwardedFields != null) { if (!annotations.isEmpty()) { throw new InvalidProgramException( "Either " + ForwardedFields.class.getSimpleName() + " or " + NonForwardedFields.class.getSimpleName() + " can be annotated to a function, not both."); } annotations.add(nonForwardedFields); } if (readSet != null) { annotations.add(readSet); } return !annotations.isEmpty() ? annotations : null; } // -------------------------------------------------------------------------------------------- /** * Reads the annotations of a user defined function with two inputs and returns semantic * properties according to the forwarded fields annotated. * * @param udfClass The user defined function, represented by its class. * @return The DualInputSemanticProperties containing the forwarded fields. */ @Internal public static Set readDualForwardAnnotations(Class udfClass) { // get readSet annotation from stub ForwardedFieldsFirst forwardedFields1 = udfClass.getAnnotation(ForwardedFieldsFirst.class); ForwardedFieldsSecond forwardedFields2 = udfClass.getAnnotation(ForwardedFieldsSecond.class); // get readSet annotation from stub NonForwardedFieldsFirst nonForwardedFields1 = udfClass.getAnnotation(NonForwardedFieldsFirst.class); NonForwardedFieldsSecond nonForwardedFields2 = udfClass.getAnnotation(NonForwardedFieldsSecond.class); ReadFieldsFirst readSet1 = udfClass.getAnnotation(ReadFieldsFirst.class); ReadFieldsSecond readSet2 = udfClass.getAnnotation(ReadFieldsSecond.class); Set annotations = new HashSet(); if (nonForwardedFields1 != null && forwardedFields1 != null) { throw new InvalidProgramException( "Either " + ForwardedFieldsFirst.class.getSimpleName() + " or " + NonForwardedFieldsFirst.class.getSimpleName() + " can be annotated to a function, not both."); } else if (forwardedFields1 != null) { annotations.add(forwardedFields1); } else if (nonForwardedFields1 != null) { annotations.add(nonForwardedFields1); } if (forwardedFields2 != null && nonForwardedFields2 != null) { throw new InvalidProgramException( "Either " + ForwardedFieldsSecond.class.getSimpleName() + " or " + NonForwardedFieldsSecond.class.getSimpleName() + " can be annotated to a function, not both."); } else if (forwardedFields2 != null) { annotations.add(forwardedFields2); } else if (nonForwardedFields2 != null) { annotations.add(nonForwardedFields2); } if (readSet1 != null) { annotations.add(readSet1); } if (readSet2 != null) { annotations.add(readSet2); } return !annotations.isEmpty() ? annotations : null; } }





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