@ -21,7 +21,7 @@ See also xref:repositories/core-concepts.adoc#is-new-state-detection[Entity Stat
@@ -21,7 +21,7 @@ See also xref:repositories/core-concepts.adoc#is-new-state-detection[Entity Stat
Spring Data JDBC offers two ways how it can load aggregates:
. The traditional and before version 3.2 the only way is really simple:
Each query loads the aggregate roots, independently if the query is based on a `CrudRepository` method, a derived query or a annotated query.
Each query loads the aggregate roots, independently if the query is based on a `CrudRepository` method, a derived query or an annotated query.
If the aggregate root references other entities those are loaded with separate statements.
. Spring Data JDBC 3.2 allows the use of _Single Query Loading_.
@ -42,7 +42,7 @@ H2 and HSQL don't support analytic functions (aka windowing functions).
@@ -42,7 +42,7 @@ H2 and HSQL don't support analytic functions (aka windowing functions).
4. It only works for the find methods in `CrudRepository`, not for derived queries and not for annotated queries.
The plan is to remove this constraint in the future.
5. Single Query Loading needs to be enabled in the `JdbcMappingContext`, by calling `setSingleQueryLoadingEnabled(true)`
5. Single Query Loading needs to be enabled in the `JdbcMappingContext`, by calling `setSingleQueryLoadingEnabled(true)`.
If any condition is not fulfilled Spring Data JDBC falls back to the default approach of loading aggregates.
@ -77,7 +77,7 @@ Operating on single aggregates, named exactly as mentioned above, and with an `A
@@ -77,7 +77,7 @@ Operating on single aggregates, named exactly as mentioned above, and with an `A
`save` does the same as the method of same name in a repository.
`insert` and `update` skip the test if the entity is new and assume a new or existing aggregate as indicated by their name.
`insert` and `update` skip the test if the entity is new and assume a new or existing aggregate as indicated by their names.
@ -21,7 +21,7 @@ Spring Data JDBC includes direct support for the following databases:
@@ -21,7 +21,7 @@ Spring Data JDBC includes direct support for the following databases:
* Microsoft SQL Server
* MySQL
* Oracle
* Postgres
* PostgreSQL
If you use a different database then your application won’t start up.
The <<jdbc.dialects,dialect>> section contains further detail on how to proceed in such case.
@ -33,7 +33,7 @@ To create a Spring project in STS:
@@ -33,7 +33,7 @@ To create a Spring project in STS:
. Go to File -> New -> Spring Template Project -> Simple Spring Utility Project, and press Yes when prompted.
Then enter a project and a package name, such as `org.spring.jdbc.example`.
. Add the following to the `pom.xml` files `dependencies` element:
. Add the following to the `pom.xml` file `dependencies` element:
+
[source,xml,subs="+attributes"]
----
@ -77,7 +77,7 @@ The repository is also https://repo.spring.io/milestone/org/springframework/data
@@ -77,7 +77,7 @@ The repository is also https://repo.spring.io/milestone/org/springframework/data
Spring Data JDBC does little to no logging on its own.
Instead, the mechanics of `JdbcTemplate` to issue SQL statements provide logging.
Thus, if you want to inspect what SQL statements are run, activate logging for Spring's {spring-framework-docs}/data-access.html#jdbc-JdbcTemplate[`NamedParameterJdbcTemplate`] or https://www.mybatis.org/mybatis-3/logging.html[MyBatis].
Thus, if you want to inspect what SQL statements are run, activate logging for Spring's {spring-framework-docs}/data-access/jdbc/core.html#jdbc-NamedParameterJdbcTemplate[`NamedParameterJdbcTemplate`] or https://www.mybatis.org/mybatis-3/logging.html[MyBatis].
You may also want to set the logging level to `DEBUG` to see some additional information.
To do so, edit the `application.properties` file to have the following content:
@ -125,8 +125,8 @@ class ApplicationConfig extends AbstractJdbcConfiguration {
@@ -125,8 +125,8 @@ class ApplicationConfig extends AbstractJdbcConfiguration {
}
----
<1> `@EnableJdbcRepositories` creates implementations for interfaces derived from `Repository`
<2> javadoc:org.springframework.data.jdbc.repository.config.AbstractJdbcConfiguration[] provides various default beans required by Spring Data JDBC
<1> `@EnableJdbcRepositories` creates implementations for interfaces derived from `Repository`.
<2> javadoc:org.springframework.data.jdbc.repository.config.AbstractJdbcConfiguration[] provides various default beans required by Spring Data JDBC.
<3> Creates a `DataSource` connecting to a database.
This is required by the following two bean methods.
<4> Creates the `NamedParameterJdbcOperations` used by Spring Data JDBC to access the database.
@ -158,13 +158,13 @@ Alternatively, you can implement your own `Dialect`.
@@ -158,13 +158,13 @@ Alternatively, you can implement your own `Dialect`.
[TIP]
====
Dialects are resolved by javadoc:org.springframework.data.jdbc.repository.config.DialectResolver[] from a `JdbcOperations` instance, typically by inspecting `Connection.getMetaData()`.
+ You can let Spring auto-discover your javadoc:org.springframework.data.jdbc.core.dialect.JdbcDialect[] by registering a class that implements `org.springframework.data.jdbc.repository.config.DialectResolver$JdbcDialectProvider` through `META-INF/spring.factories`.
Dialects are resolved by javadoc:org.springframework.data.jdbc.repository.config.DialectResolver[] from a `JdbcOperations` instance, typically by inspecting `Connection.getMetaData()`. +
You can let Spring auto-discover your javadoc:org.springframework.data.jdbc.core.dialect.JdbcDialect[] by registering a class that implements `org.springframework.data.jdbc.repository.config.DialectResolver$JdbcDialectProvider` through `META-INF/spring.factories`.
`DialectResolver` discovers dialect provider implementations from the class path using Spring's `SpringFactoriesLoader`.
To do so:
. Implement your own `Dialect`.
. Implement a `JdbcDialectProvider` returning the `Dialect`.
. Register the provider by creating a `spring.factories` resource under `META-INF` and perform the registration by adding a line +
`org.springframework.data.jdbc.repository.config.DialectResolver$JdbcDialectProvider=<fully qualified name of your JdbcDialectProvider>`
`org.springframework.data.jdbc.repository.config.DialectResolver$JdbcDialectProvider=<fully qualified name of your JdbcDialectProvider>`.
@ -42,7 +42,7 @@ The properties of the following types are currently supported:
@@ -42,7 +42,7 @@ The properties of the following types are currently supported:
* All primitive types and their boxed types (`int`, `float`, `Integer`, `Float`, and so on)
You should not include attributes in your entities to hold the actual value of a back reference, nor of the key column of maps or lists.
If you want these value to be available in your domain model we recommend to do this in a `AfterConvertCallback` and store the values in transient values.
If you want these values to be available in your domain model we recommend to do this in an `AfterConvertCallback` and store the values in transient values.
:mapped-collection: true
:embedded-entities: true
@ -210,7 +210,7 @@ If you are migrating from an older version of Spring Data JDBC and have `Abstrac
@@ -210,7 +210,7 @@ If you are migrating from an older version of Spring Data JDBC and have `Abstrac
[TIP]
====
If you want to rely on https://spring.io/projects/spring-boot[Spring Boot] to bootstrap Spring Data JDBC, but still want to override certain aspects of the configuration, you may want to expose beans of that type.
For custom conversions you may e.g. choose to register a bean of type `JdbcCustomConversions` that will be picked up the by the Boot infrastructure.
For custom conversions you may e.g. choose to register a bean of type `JdbcCustomConversions` that will be picked up by the Boot infrastructure.
To learn more about this please make sure to read the Spring Boot https://docs.spring.io/spring-boot/docs/current/reference/htmlsingle/#data.sql.jdbc[Reference Documentation].
@ -44,7 +44,7 @@ The following table describes the available MyBatis statements:
@@ -44,7 +44,7 @@ The following table describes the available MyBatis statements:
| Name | Purpose | CrudRepository methods that might trigger this statement | Attributes available in the `MyBatisContext`
| `insert` | Inserts a single entity. This also applies for entities referenced by the aggregate root. | `save`, `saveAll`. |
`getInstance`: the instance to be saved
`getInstance`: the instance to be saved.
`getDomainType`: The type of the entity to be saved.
@ -52,12 +52,12 @@ The following table describes the available MyBatis statements:
@@ -52,12 +52,12 @@ The following table describes the available MyBatis statements:
| `update` | Updates a single entity. This also applies for entities referenced by the aggregate root. | `save`, `saveAll`.|
`getInstance`: The instance to be saved
`getInstance`: The instance to be saved.
`getDomainType`: The type of the entity to be saved.
| `delete` | Deletes a single entity. | `delete`, `deleteById`.|
`getId`: The ID of the instance to be deleted
`getId`: The ID of the instance to be deleted.
`getDomainType`: The type of the entity to be deleted.
This section offers some specific information about the implementation and use of Spring Data JDBC.
Most of the data access operations you usually trigger on a repository result in a query being run against the databases.
Most of the data access operations you usually trigger on a repository result in a query being run against the database.
Defining such a query is a matter of declaring a method on the repository interface, as the following example shows:
.PersonRepository with query methods
@ -143,7 +143,7 @@ NOTE: Query derivation is limited to properties that can be used in a `WHERE` cl
@@ -143,7 +143,7 @@ NOTE: Query derivation is limited to properties that can be used in a `WHERE` cl
The JDBC module supports defining a query manually as a String in a `@Query` annotation or as named query in a property file.
Deriving a query from the name of the method is is currently limited to simple properties, that means properties present in the aggregate root directly.
Deriving a query from the name of the method is currently limited to simple properties, that means properties present in the aggregate root directly.
Also, only select queries are supported by this approach.
For converting the query result into entities the same `RowMapper` is used by default as for the queries Spring Data JDBC generates itself.
The query you provide must match the format the `RowMapper` expects.
Columns for all properties that are used in the constructor of an entity must be provided.
Columns for properties that get set via setter, wither or field access are optional.
Columns for properties that get set via setter or field access are optional.
Properties that don't have a matching column in the result will not be set.
The query is used for populating the aggregate root, embedded entities and one-to-one relationships including arrays of primitive types which get stored and loaded as SQL-array-types.
Separate queries are generated for maps, lists, sets and arrays of entities.
Properties one-to-one relationships must have there name prefixed by the name of the relationship plus `_`.
Properties one-to-one relationships must have their name prefixed by the name of the relationship plus `_`.
For example if the `User` from the example above has an `address` with the property `city` the column for that `city` must be labeled `address_city`.
@ -190,7 +190,7 @@ Person findWithSpEL(PersonRef person);
@@ -190,7 +190,7 @@ Person findWithSpEL(PersonRef person);
----
This can be used to access members of a parameter, as demonstrated in the example above.
For more involved use cases an `EvaluationContextExtension` can be made available in the application context, which in turn can make any object available in to the SpEL.
For more involved use cases an `EvaluationContextExtension` can be made available in the application context, which in turn can make any object available in the SpEL.
The other variant can be used anywhere in the query and the result of evaluating the query will replace the expression in the query string.
Column types are computed from an object implementing the `SqlTypeMapping` strategy interface.
Nullability is inferred from the type and set to `false` if a property type use primitive Java types.
Nullability is inferred from the type and set to `false` if a property type uses primitive Java types.
Schema support can assist you throughout the application development lifecycle.
In differential mode, you provide an existing Liquibase `Database` to the schema writer instance and the schema writer compares existing tables to mapped entities and derives from the difference which tables and columns to create/to drop.
By default, no tables and no columns are dropped unless you configure `dropTableFilter` and `dropColumnFilter`.
Both filter predicate provide the table name respective column name so your code can computer which tables and columns can be dropped.
Both filter predicates provide the table name respective column name so your code can compute which tables and columns can be dropped.
@ -8,7 +8,7 @@ We provide a "`template`" as a high-level abstraction for storing and querying a
@@ -8,7 +8,7 @@ We provide a "`template`" as a high-level abstraction for storing and querying a
This document is the reference guide for Spring Data R2DBC support.
It explains the concepts and semantics and syntax.
This chapter points out the specialties for repository support for JDBC.
This chapter points out the specialties for repository support for R2DBC.
This builds on the core repository support explained in xref:repositories/introduction.adoc[Working with Spring Data Repositories].
You should have a sound understanding of the basic concepts explained there.
Nathan Xu
2 months ago
committed by
Jens Schauder