The MongoDB support contains a wide range of features which are summarized below.
Spring configuration support using Java based @Configuration classes or an XML namespace for a Mongo driver instance and replica sets
MongoTemplate helper class that increases productivity performing common Mongo operations. Includes integrated object mapping between documents and POJOs.
Exception translation into Spring's portable Data Access Exception hierarchy
Feature Rich Object Mapping integrated with Spring's Conversion Service
Annotation based mapping metadata but extensible to support other metadata formats
Persistence and mapping lifecycle events
Java based Query, Criteria, and Update DSLs
Automatic implementation of Repository interfaces including support for custom finder methods.
QueryDSL integration to support type-safe queries.
Cross-store persistance - support for JPA Entities with fields transparently persisted/retrieved using MongoDB
Log4j log appender
GeoSpatial integration
For most tasks you will find yourself using
MongoTemplate or the Repository support that both
leverage the rich mapping functionality. MongoTemplate is the place to look
for accessing functionality such as incrementing counters or ad-hoc CRUD
operations. MongoTemplate also provides callback methods so that it is easy
for you to get a hold of the low level API artifacts such as
org.mongo.DB to communicate directly with MongoDB. The
goal with naming conventions on various API artifacts is to copy those in
the base MongoDB Java driver so you can easily map your existing knowledge
onto the Spring APIs.
Spring MongoDB support requires MongoDB 1.4 or higher and Java SE 5 or higher. The latest production release (2.4.9 as of this writing) is recommended. An easy way to bootstrap setting up a working environment is to create a Spring based project in STS.
First you need to set up a running Mongodb server. Refer to the
Mongodb
Quick Start guide for an explanation on how to startup a MongoDB
instance. Once installed starting MongoDB is typically a matter of
executing the following command:
MONGO_HOME/bin/mongod
To create a Spring project in STS go to File -> New -> Spring Template Project -> Simple Spring Utility Project -> press Yes when prompted. Then enter a project and a package name such as org.spring.mongodb.example.
Then add the following to pom.xml dependencies section.
<dependencies> <!-- other dependency elements omitted --> <dependency> <groupId>org.springframework.data</groupId> <artifactId>spring-data-mongodb</artifactId> <version>1.4.1.RELEASE</version> </dependency> </dependencies>
Also change the version of Spring in the pom.xml to be
<spring.framework.version>3.2.8.RELEASE</spring.framework.version>
You will also need to add the location of the Spring Milestone repository for maven to your pom.xml which is at the same level of your <dependencies/> element
<repositories> <repository> <id>spring-milestone</id> <name>Spring Maven MILESTONE Repository</name> <url>http://repo.spring.io/libs-milestone</url> </repository> </repositories>
The repository is also browseable here.
You may also want to set the logging level to DEBUG to
see some additional information, edit the log4j.properties file to
have
log4j.category.org.springframework.data.document.mongodb=DEBUG
log4j.appender.stdout.layout.ConversionPattern=%d{ABSOLUTE} %5p %40.40c:%4L - %m%nCreate a simple Person class to persist
package org.spring.mongodb.example; public class Person { private String id; private String name; private int age; public Person(String name, int age) { this.name = name; this.age = age; } public String getId() { return id; } public String getName() { return name; } public int getAge() { return age; } @Override public String toString() { return "Person [id=" + id + ", name=" + name + ", age=" + age + "]"; } }
And a main application to run
package org.spring.mongodb.example; import static org.springframework.data.mongodb.core.query.Criteria.where; import org.apache.commons.logging.Log; import org.apache.commons.logging.LogFactory; import org.springframework.data.mongodb.core.MongoOperations; import org.springframework.data.mongodb.core.MongoTemplate; import org.springframework.data.mongodb.core.query.Query; import com.mongodb.Mongo; public class MongoApp { private static final Log log = LogFactory.getLog(MongoApp.class); public static void main(String[] args) throws Exception { MongoOperations mongoOps = new MongoTemplate(new Mongo(), "database"); mongoOps.insert(new Person("Joe", 34)); log.info(mongoOps.findOne(new Query(where("name").is("Joe")), Person.class)); mongoOps.dropCollection("person"); } }
This will produce the following output
10:01:32,062 DEBUG apping.MongoPersistentEntityIndexCreator: 80 - Analyzing class class org.spring.example.Person for index information.
10:01:32,265 DEBUG ramework.data.mongodb.core.MongoTemplate: 631 - insert DBObject containing fields: [_class, age, name] in collection: Person
10:01:32,765 DEBUG ramework.data.mongodb.core.MongoTemplate:1243 - findOne using query: { "name" : "Joe"} in db.collection: database.Person
10:01:32,953 INFO org.spring.mongodb.example.MongoApp: 25 - Person [id=4ddbba3c0be56b7e1b210166, name=Joe, age=34]
10:01:32,984 DEBUG ramework.data.mongodb.core.MongoTemplate: 375 - Dropped collection [database.person]Even in this simple example, there are few things to take notice of
You can instantiate the central helper class of Spring Mongo,
MongoTemplate, using the standardcom.mongodb.Mongoobject and the name of the database to use.The mapper works against standard POJO objects without the need for any additional metadata (though you can optionally provide that information. See here.).
Conventions are used for handling the id field, converting it to be a ObjectId when stored in the database.
Mapping conventions can use field access. Notice the Person class has only getters.
If the constructor argument names match the field names of the stored document, they will be used to instantiate the object
There is an github repository with several examples that you can download and play around with to get a feel for how the library works.
One of the first tasks when using MongoDB and Spring is to create a
com.mongodb.Mongo object using the IoC container.
There are two main ways to do this, either using Java based bean metadata
or XML based bean metadata. These are discussed in the following sections.
![[Note]](images/note.png) | Note |
|---|---|
For those not familiar with how to configure the Spring container using Java based bean metadata instead of XML based metadata see the high level introduction in the reference docs here as well as the detailed documentation here. |
An example of using Java based bean metadata to register an
instance of a com.mongodb.Mongo is shown below
Example 4.1. Registering a com.mongodb.Mongo object using Java based bean metadata
@Configuration public class AppConfig { /* * Use the standard Mongo driver API to create a com.mongodb.Mongo instance. */ public @Bean Mongo mongo() throws UnknownHostException { return new Mongo("localhost"); } }
This approach allows you to use the standard
com.mongodb.Mongo API that you may already be
used to using but also pollutes the code with the UnknownHostException
checked exception. The use of the checked exception is not desirable as
Java based bean metadata uses methods as a means to set object
dependencies, making the calling code cluttered.
An alternative is to register an instance of
com.mongodb.Mongo instance with the container
using Spring's MongoFactoryBean. As
compared to instantiating a com.mongodb.Mongo
instance directly, the FactoryBean approach does not throw a checked
exception and has the added advantage of also providing the container
with an ExceptionTranslator implementation that translates MongoDB
exceptions to exceptions in Spring's portable
DataAccessException hierarchy for data access
classes annoated with the @Repository annotation.
This hierarchy and use of @Repository is described in
Spring's
DAO support features.
An example of a Java based bean metadata that supports exception
translation on @Repository annotated classes is
shown below:
Example 4.2. Registering a com.mongodb.Mongo object using Spring's MongoFactoryBean and enabling Spring's exception translation support
@Configuration public class AppConfig { /* * Factory bean that creates the com.mongodb.Mongo instance */ public @Bean MongoFactoryBean mongo() { MongoFactoryBean mongo = new MongoFactoryBean(); mongo.setHost("localhost"); return mongo; } }
To access the com.mongodb.Mongo object
created by the MongoFactoryBean in other
@Configuration or your own classes, use a
"private @Autowired Mongo mongo;" field.
While you can use Spring's traditional
<beans/> XML namespace to register an instance
of com.mongodb.Mongo with the container, the XML
can be quite verbose as it is general purpose. XML namespaces are a
better alternative to configuring commonly used objects such as the
Mongo instance. The mongo namespace alows you to create a Mongo instance
server location, replica-sets, and options.
To use the Mongo namespace elements you will need to reference the Mongo schema:
Example 4.3. XML schema to configure MongoDB
<?xml version="1.0" encoding="UTF-8"?> <beans xmlns="http://www.springframework.org/schema/beans" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" xmlns:context="http://www.springframework.org/schema/context" xmlns:mongo="http://www.springframework.org/schema/data/mongo" xsi:schemaLocation= "http://www.springframework.org/schema/context http://www.springframework.org/schema/context/spring-context-3.0.xsd http://www.springframework.org/schema/data/mongo http://www.springframework.org/schema/data/mongo/spring-mongo-1.0.xsd http://www.springframework.org/schema/beans http://www.springframework.org/schema/beans/spring-beans-3.0.xsd"> <!-- Default bean name is 'mongo' --> <mongo:mongo host="localhost" port="27017"/> </beans>
A more advanced configuration with MongoOptions is shown below (note these are not recommended values)
Example 4.4. XML schema to configure a com.mongodb.Mongo object with MongoOptions
<beans> <mongo:mongo host="localhost" port="27017"> <mongo:options connections-per-host="8" threads-allowed-to-block-for-connection-multiplier="4" connect-timeout="1000" max-wait-time="1500}" auto-connect-retry="true" socket-keep-alive="true" socket-timeout="1500" slave-ok="true" write-number="1" write-timeout="0" write-fsync="true"/> </mongo:mongo/> </beans>
A configuration using replica sets is shown below.
Example 4.5. XML schema to configure com.mongodb.Mongo object with Replica Sets
<mongo:mongo id="replicaSetMongo" replica-set="127.0.0.1:27017,localhost:27018"/>
While com.mongodb.Mongo is the entry point
to the MongoDB driver API, connecting to a specific MongoDB database
instance requires additional information such as the database name and
an optional username and password. With that information you can obtain
a com.mongodb.DB object and access all the functionality of a specific
MongoDB database instance. Spring provides the
org.springframework.data.mongodb.core.MongoDbFactory
interface shown below to bootstrap connectivity to the database.
public interface MongoDbFactory { DB getDb() throws DataAccessException; DB getDb(String dbName) throws DataAccessException; }
The following sections show how you can use the container with
either Java or the XML based metadata to configure an instance of the
MongoDbFactory interface. In turn, you can use
the MongoDbFactory instance to configure
MongoTemplate.
The class
org.springframework.data.mongodb.core.SimpleMongoDbFactory
provides implements the MongoDbFactory interface and is created with a
standard com.mongodb.Mongo instance, the database
name and an optional
org.springframework.data.authentication.UserCredentials
constructor argument.
Instead of using the IoC container to create an instance of MongoTemplate, you can just use them in standard Java code as shown below.
public class MongoApp { private static final Log log = LogFactory.getLog(MongoApp.class); public static void main(String[] args) throws Exception { MongoOperations mongoOps = new MongoTemplate(new SimpleMongoDbFactory(new Mongo(), "database")); mongoOps.insert(new Person("Joe", 34)); log.info(mongoOps.findOne(new Query(where("name").is("Joe")), Person.class)); mongoOps.dropCollection("person"); } }
The code in bold highlights the use of SimpleMongoDbFactory and is the only difference between the listing shown in the getting started section.
To register a MongoDbFactory instance with the container, you write code much like what was highlighted in the previous code listing. A simple example is shown below
@Configuration public class MongoConfiguration { public @Bean MongoDbFactory mongoDbFactory() throws Exception { return new SimpleMongoDbFactory(new Mongo(), "database"); } }
To define the username and password create an instance of
org.springframework.data.authentication.UserCredentials
and pass it into the constructor as shown below. This listing also shows
using MongoDbFactory register an instance of
MongoTemplate with the container.
@Configuration public class MongoConfiguration { public @Bean MongoDbFactory mongoDbFactory() throws Exception { UserCredentials userCredentials = new UserCredentials("joe", "secret"); return new SimpleMongoDbFactory(new Mongo(), "database", userCredentials); } public @Bean MongoTemplate mongoTemplate() throws Exception { return new MongoTemplate(mongoDbFactory()); } }
The mongo namespace provides a convient way to create a
SimpleMongoDbFactory as compared to using
the<beans/> namespace. Simple usage is shown
below
<mongo:db-factory dbname="database">
In the above example a com.mongodb.Mongo
instance is created using the default host and port number. The
SimpleMongoDbFactory registered with the
container is identified by the id 'mongoDbFactory' unless a value for
the id attribute is specified.
You can also provide the host and port for the underlying
com.mongodb.Mongo instance as shown below, in
addition to username and password for the database.
<mongo:db-factory id="anotherMongoDbFactory" host="localhost" port="27017" dbname="database" username="joe" password="secret"/>
If you need to configure additional options on the
com.mongodb.Mongo instance that is used to create
a SimpleMongoDbFactory you can refer to an
existing bean using the mongo-ref attribute as shown
below. To show another common usage pattern, this listing show the use
of a property placeholder to parameterise the configuration and creating
MongoTemplate.
<context:property-placeholder location="classpath:/com/myapp/mongodb/config/mongo.properties"/> <mongo:mongo host="${mongo.host}" port="${mongo.port}"> <mongo:options connections-per-host="${mongo.connectionsPerHost}" threads-allowed-to-block-for-connection-multiplier="${mongo.threadsAllowedToBlockForConnectionMultiplier}" connect-timeout="${mongo.connectTimeout}" max-wait-time="${mongo.maxWaitTime}" auto-connect-retry="${mongo.autoConnectRetry}" socket-keep-alive="${mongo.socketKeepAlive}" socket-timeout="${mongo.socketTimeout}" slave-ok="${mongo.slaveOk}" write-number="1" write-timeout="0" write-fsync="true"/> </mongo:mongo> <mongo:db-factory dbname="database" mongo-ref="mongo"/> <bean id="anotherMongoTemplate" class="org.springframework.data.mongodb.core.MongoTemplate"> <constructor-arg name="mongoDbFactory" ref="mongoDbFactory"/> </bean>
Activating auditing functionality is just a matter of adding the
Spring Data Mongo auditing namespace element to your
configuration:
Example 4.6. Activating auditing using XML configuration
<mongo:auditing mapping-context-ref="customMappingContext" auditor-aware-ref="yourAuditorAwareImpl"/>
Since Spring Data MongoDB 1.4 auditing can be enabled by annotating
a configuration class with the @EnableMongoAuditing
annotation.
Example 4.7. Activating auditing using JavaConfig
@Configuration @EnableMongoAuditing class Config { @Bean public AuditorAware<AuditableUser> myAuditorProvider() { return new AuditorAwareImpl(); } }
If you expose a bean of type
AuditorAware to the
ApplicationContext, the auditing
infrastructure will pick it up automatically and use it to determine the
current user to be set on domain types. If you have multiple
implementations registered in the
ApplicationContext, you can select the one
to be used by explicitly setting the auditorAwareRef
attribute of @EnableJpaAuditing.
The class MongoTemplate, located in the
package org.springframework.data.document.mongodb, is
the central class of the Spring's MongoDB support providng a rich feature
set to interact with the database. The template offers convenience
operations to create, update, delete and query for MongoDB documents and
provides a mapping between your domain objects and MongoDB
documents.
| Note |
|---|---|
Once configured, |
The mapping between MongoDB documents and domain classes is done by
delegating to an implementation of the interface
MongoConverter. Spring provides two
implementations, SimpleMappingConverter and
MongoMappingConverter, but you can also write your
own converter. Please refer to the section on MongoCoverters for more
detailed information.
The MongoTemplate class implements the
interface MongoOperations. In as much as
possible, the methods on MongoOperations
are named after methods available on the MongoDB driver
Collection object as as to make the API familiar to
existing MongoDB developers who are used to the driver API. For example,
you will find methods such as "find", "findAndModify", "findOne",
"insert", "remove", "save", "update" and "updateMulti". The design goal
was to make it as easy as possible to transition between the use of the
base MongoDB driver and MongoOperations. A
major difference in between the two APIs is that MongOperations can be
passed domain objects instead of DBObject and there
are fluent APIs for Query,
Criteria, and Update
operations instead of populating a DBObject to
specify the parameters for those operatiosn.
| Note |
|---|---|
The preferred way to reference the operations on
|
The default converter implementation used by
MongoTemplate is MongoMappingConverter. While the
MongoMappingConverter can make use of additional
metadata to specify the mapping of objects to documents it is also capable
of converting objects that contain no additonal metadata by using some
conventions for the mapping of IDs and collection names. These conventions
as well as the use of mapping annotations is explained in the Mapping chapter.
| Note |
|---|---|
In the M2 release |
Another central feature of MongoTemplate is exception translation of exceptions thrown in the MongoDB Java driver into Spring's portable Data Access Exception hierarchy. Refer to the section on exception translation for more information.
While there are many convenience methods on
MongoTemplate to help you easily perform common
tasks if you should need to access the MongoDB driver API directly to
access functionality not explicitly exposed by the MongoTemplate you can
use one of several Execute callback methods to access underlying driver
APIs. The execute callbacks will give you a reference to either a
com.mongodb.Collection or a
com.mongodb.DB object. Please see the section
Execution Callbacks for more
information.
Now let's look at a examples of how to work with the
MongoTemplate in the context of the Spring
container.
You can use Java to create and register an instance of MongoTemplate as shown below.
Example 4.8. Registering a com.mongodb.Mongo object and enabling Spring's exception translation support
@Configuration public class AppConfig { public @Bean Mongo mongo() throws Exception { return new Mongo("localhost"); } public @Bean MongoTemplate mongoTemplate() throws Exception { return new MongoTemplate(mongo(), "mydatabase"); } }
There are several overloaded constructors of MongoTemplate. These are
MongoTemplate
(Mongo mongo, String databaseName)- takes thecom.mongodb.Mongoobject and the default database name to operate against.MongoTemplate
(Mongo mongo, String databaseName, UserCredentials userCredentials)- adds the username and password for authenticating with the database.MongoTemplate
(MongoDbFactory mongoDbFactory)- takes a MongoDbFactory object that encapsulated thecom.mongodb.Mongoobject, database name, and username and password.MongoTemplate
(MongoDbFactory mongoDbFactory, MongoConverter mongoConverter)- adds a MongoConverter to use for mapping.
You can also configure a MongoTemplate using Spring's XML <beans/> schema.
<mongo:mongo host="localhost" port="27017"/> <bean id="mongoTemplate" class="org.springframework.data.mongodb.core.MongoTemplate"> <constructor-arg ref="mongo"/> <constructor-arg name="databaseName" value="geospatial"/> </bean>
Other optional properties that you might like to set when creating
a MongoTemplate are the default
WriteResultCheckingPolicy,
WriteConcern, and
ReadPreference.
| Note |
|---|---|
The preferred way to reference the operations on
|
When in development it is very handy to either log or throw an
exception if the com.mongodb.WriteResult
returned from any MongoDB operation contains an error. It is quite
common to forget to do this during development and then end up with an
application that looks like it runs successfully but in fact the
database was not modified according to your expectations. Set
MongoTemplate's WriteResultChecking property to
an enum with the following values, LOG, EXCEPTION, or NONE to either
log the error, throw and exception or do nothing. The default is to
use a WriteResultChecking value of NONE.
You can set the com.mongodb.WriteConcern
property that the MongoTemplate will use for
write operations if it has not yet been specified via the driver at a
higher level such as com.mongodb.Mongo. If
MongoTemplate's WriteConcern property is not
set it will default to the one set in the MongoDB driver's DB or
Collection setting.
For more advanced cases where you want to set different
WriteConcern values on a per-operation basis
(for remove, update, insert and save operations), a strategy interface
called WriteConcernResolver can be
configured on MongoTemplate. Since
MongoTemplate is used to persist POJOs, the
WriteConcernResolver lets you create a
policy that can map a specific POJO class to a
WriteConcern value. The
WriteConcernResolver interface is shown
below.
public interface WriteConcernResolver { WriteConcern resolve(MongoAction action); }
The passed in argument, MongoAction, is what you use to
determine the WriteConcern value to be used or
to use the value of the Template itself as a default.
MongoAction contains the collection name being
written to, the java.lang.Class of the POJO,
the converted DBObject, as well as the
operation as an enumeration
(MongoActionOperation: REMOVE, UPDATE, INSERT,
INSERT_LIST, SAVE) and a few other pieces of contextual information.
For example,
private class MyAppWriteConcernResolver implements WriteConcernResolver {
public WriteConcern resolve(MongoAction action) {
if (action.getEntityClass().getSimpleName().contains("Audit")) {
return WriteConcern.NONE;
} else if (action.getEntityClass().getSimpleName().contains("Metadata")) {
return WriteConcern.JOURNAL_SAFE;
}
return action.getDefaultWriteConcern();
}
}MongoTemplate provides a simple way for you
to save, update, and delete your domain objects and map those objects to
documents stored in MongoDB.
Given a simple class such as Person
public class Person { private String id; private String name; private int age; public Person(String name, int age) { this.name = name; this.age = age; } public String getId() { return id; } public String getName() { return name; } public int getAge() { return age; } @Override public String toString() { return "Person [id=" + id + ", name=" + name + ", age=" + age + "]"; } }
You can save, update and delete the object as shown below.
| Note |
|---|---|
|
package org.spring.example; import static org.springframework.data.mongodb.core.query.Criteria.where; import static org.springframework.data.mongodb.core.query.Update.update; import static org.springframework.data.mongodb.core.query.Query.query; import java.util.List; import org.apache.commons.logging.Log; import org.apache.commons.logging.LogFactory; import org.springframework.data.mongodb.core.MongoOperations; import org.springframework.data.mongodb.core.MongoTemplate; import org.springframework.data.mongodb.core.SimpleMongoDbFactory; import com.mongodb.Mongo; public class MongoApp { private static final Log log = LogFactory.getLog(MongoApp.class); public static void main(String[] args) throws Exception { MongoOperations mongoOps = new MongoTemplate(new SimpleMongoDbFactory(new Mongo(), "database")); Person p = new Person("Joe", 34); // Insert is used to initially store the object into the database. mongoOps.insert(p); log.info("Insert: " + p); // Find p = mongoOps.findById(p.getId(), Person.class); log.info("Found: " + p); // Update mongoOps.updateFirst(query(where("name").is("Joe")), update("age", 35), Person.class); p = mongoOps.findOne(query(where("name").is("Joe")), Person.class); log.info("Updated: " + p); // Delete mongoOps.remove(p); // Check that deletion worked List<Person> people = mongoOps.findAll(Person.class); log.info("Number of people = : " + people.size()); mongoOps.dropCollection(Person.class); } }
This would produce the following log output (including debug
messages from MongoTemplate itself)
DEBUG apping.MongoPersistentEntityIndexCreator: 80 - Analyzing class class org.spring.example.Person for index information.
DEBUG work.data.mongodb.core.MongoTemplate: 632 - insert DBObject containing fields: [_class, age, name] in collection: person
INFO org.spring.example.MongoApp: 30 - Insert: Person [id=4ddc6e784ce5b1eba3ceaf5c, name=Joe, age=34]
DEBUG work.data.mongodb.core.MongoTemplate:1246 - findOne using query: { "_id" : { "$oid" : "4ddc6e784ce5b1eba3ceaf5c"}} in db.collection: database.person
INFO org.spring.example.MongoApp: 34 - Found: Person [id=4ddc6e784ce5b1eba3ceaf5c, name=Joe, age=34]
DEBUG work.data.mongodb.core.MongoTemplate: 778 - calling update using query: { "name" : "Joe"} and update: { "$set" : { "age" : 35}} in collection: person
DEBUG work.data.mongodb.core.MongoTemplate:1246 - findOne using query: { "name" : "Joe"} in db.collection: database.person
INFO org.spring.example.MongoApp: 39 - Updated: Person [id=4ddc6e784ce5b1eba3ceaf5c, name=Joe, age=35]
DEBUG work.data.mongodb.core.MongoTemplate: 823 - remove using query: { "id" : "4ddc6e784ce5b1eba3ceaf5c"} in collection: person
INFO org.spring.example.MongoApp: 46 - Number of people = : 0
DEBUG work.data.mongodb.core.MongoTemplate: 376 - Dropped collection [database.person]There was implicit conversion using the
MongoConverter between a
String and ObjectId as
stored in the database and recognizing a convention of the property "Id"
name.
| Note |
|---|---|
This example is meant to show the use of save, update and remove operations on MongoTemplate and not to show complex mapping functionality |
The query syntax used in the example is explained in more detail in the section Querying Documents.
MongoDB requires that you have an '_id' field for all documents.
If you don't provide one the driver will assign a
ObjectId with a generated value. When using the
MongoMappingConverter there are certain rules
that govern how properties from the Java class is mapped to this '_id'
field.
The following outlines what property will be mapped to the '_id' document field:
A property or field annotated with
@Id(org.springframework.data.annotation.Id) will be mapped to the '_id' field.A property or field without an annotation but named
idwill be mapped to the '_id' field.
The following outlines what type conversion, if any, will be done
on the property mapped to the _id document field when using the
MappingMongoConverter, the default for
MongoTemplate.
An id property or field declared as a String in the Java class will be converted to and stored as an
ObjectIdif possible using a SpringConverter<String, ObjectId>. Valid conversion rules are delegated to the MongoDB Java driver. If it cannot be converted to an ObjectId, then the value will be stored as a string in the database.An id property or field declared as
BigIntegerin the Java class will be converted to and stored as anObjectIdusing a SpringConverter<BigInteger, ObjectId>.
If no field or property specified above is present in the Java class then an implicit '_id' file will be generated by the driver but not mapped to a property or field of the Java class.
When querying and updating MongoTemplate
will use the converter to handle conversions of the
Query and Update objects
that correspond to the above rules for saving documents so field names
and types used in your queries will be able to match what is in your
domain classes.
As MongoDB collections can contain documents that represent
instances of a variety of types. A great example here is if you store a
hierarchy of classes or simply have a class with a property of type
Object. In the latter case the values held inside
that property have to be read in correctly when retrieving the object.
Thus we need a mechanism to store type information alongside the actual
document.
To achieve that the MappingMongoConverter
uses a MongoTypeMapper abstraction with
DefaultMongoTypeMapper as it's main
implementation. It's default behaviour is storing the fully qualified
classname under _class inside the document for the
top-level document as well as for every value if it's a complex type and
a subtype of the property type declared.
Example 4.9. Type mapping
public class Sample { Contact value; } public abstract class Contact { … } public class Person extends Contact { … } Sample sample = new Sample(); sample.value = new Person(); mongoTemplate.save(sample); { "_class" : "com.acme.Sample", "value" : { "_class" : "com.acme.Person" } }
As you can see we store the type information for the actual root
class persistent as well as for the nested type as it is complex and a
subtype of Contact. So if you're now using
mongoTemplate.findAll(Object.class, "sample")
we are able to find out that the document stored shall be a
Sample instance. We are also able to find out
that the value property shall be a Person
actually.
In case you want to avoid writing the entire Java class name as
type information but rather like to use some key you can use the
@TypeAlias annotation at the entity
class being persisted. If you need to customize the mapping even more
have a look at the
TypeInformationMapper interface. An
instance of that interface can be configured at the
DefaultMongoTypeMapper which can be configured
in turn on MappingMongoConverter.
Example 4.10. Defining a TypeAlias for an Entity
@TypeAlias("pers") class Person { }
Note that the resulting document will contain
"pers" as the value in the _class
Field.
The following example demonstrates how to configure a custom
MongoTypeMapper in
MappingMongoConverter.
Example 4.11. Configuring a custom MongoTypeMapper via Spring Java Config
class CustomMongoTypeMapper extends DefaultMongoTypeMapper { //implement custom type mapping here }
@Configuration class SampleMongoConfiguration extends AbstractMongoConfiguration { @Override protected String getDatabaseName() { return "database"; } @Override public Mongo mongo() throws Exception { return new Mongo(); } @Bean @Override public MappingMongoConverter mappingMongoConverter() throws Exception { MappingMongoConverter mmc = super.mappingMongoConverter(); mmc.setTypeMapper(customTypeMapper()); return mmc; } @Bean public MongoTypeMapper customTypeMapper() { return new CustomMongoTypeMapper(); } }
Note that we are extending the
AbstractMongoConfiguration class and override
the bean definition of the
MappingMongoConverter where we configure our
custom MongoTypeMapper.
Example 4.12. Configuring a custom MongoTypeMapper via XML
<mongo:mapping-converter type-mapper-ref="customMongoTypeMapper"/> <bean name="customMongoTypeMapper" class="com.bubu.mongo.CustomMongoTypeMapper"/>
There are several convenient methods on
MongoTemplate for saving and inserting your
objects. To have more fine grained control over the conversion process
you can register Spring converters with the
MappingMongoConverter, for example
Converter<Person, DBObject> and
Converter<DBObject, Person>.
| Note |
|---|---|
The difference between insert and save operations is that a save operation will perform an insert if the object is not already present. |
The simple case of using the save operation is to save a POJO. In this case the collection name will be determined by name (not fully qualfied) of the class. You may also call the save operation with a specific collection name. The collection to store the object can be overriden using mapping metadata.
When inserting or saving, if the Id property is not set, the
assumption is that its value will be auto-generated by the database. As
such, for auto-generation of an ObjectId to succeed the type of the Id
property/field in your class must be either a
String, ObjectId, or
BigInteger.
Here is a basic example of using the save operation and retrieving its contents.
Example 4.13. Inserting and retrieving documents using the MongoTemplate
import static org.springframework.data.mongodb.core.query.Criteria.where; import static org.springframework.data.mongodb.core.query.Criteria.query; … Person p = new Person("Bob", 33); mongoTemplate.insert(p); Person qp = mongoTemplate.findOne(query(where("age").is(33)), Person.class);
The insert/save operations available to you are listed below.
voidsave(Object objectToSave)Save the object to the default collection.voidsave(Object objectToSave, String collectionName)Save the object to the specified collection.
A similar set of insert operations is listed below
voidinsert(Object objectToSave)Insert the object to the default collection.voidinsert(Object objectToSave, String collectionName)Insert the object to the specified collection.
There are two ways to manage the collection name that is used
for operating on the documents. The default collection name that is
used is the class name changed to start with a lower-case letter. So a
com.test.Person class would be stored in the
"person" collection. You can customize this by providing a different
collection name using the @Document annotation. You can also override
the collection name by providing your own collection name as the last
parameter for the selected MongoTemplate method calls.
The MongoDB driver supports inserting a collection of documents in one operation. The methods in the MongoOperations interface that support this functionality are listed below
insert
insertAll Takes a
Collectionof objects as the first parameter. This method inspects each object and inserts it to the appropriate collection based on the rules specified above.save Save the object overwriting any object that might exist with the same id.
The MongoDB driver supports inserting a collection of documents in one operation. The methods in the MongoOperations interface that support this functionality are listed below
insert
methods that take a Collectionas the first argument.This inserts a list of objects in a single batch write to the database.
For updates we can elect to update the first document found using
MongoOperation's method
updateFirst or we can update all documents that were
found to match the query using the method
updateMulti. Here is an example of an update of all
SAVINGS accounts where we are adding a one time $50.00 bonus to the
balance using the $inc operator.
Example 4.14. Updating documents using the MongoTemplate
import static org.springframework.data.mongodb.core.query.Criteria.where; import static org.springframework.data.mongodb.core.query.Query; import static org.springframework.data.mongodb.core.query.Update; ... WriteResult wr = mongoTemplate.updateMulti(new Query(where("accounts.accountType").is(Account.Type.SAVINGS)), new Update().inc("accounts.$.balance", 50.00), Account.class);
In addition to the Query discussed above we
provide the update definition using an Update
object. The Update class has methods that match
the update modifiers available for MongoDB.
As you can see most methods return the
Update object to provide a fluent style for the
API.
updateFirst Updates the first document that matches the query document criteria with the provided updated document.
updateMulti Updates all objects that match the query document criteria with the provided updated document.
The Update class can be used with a little 'syntax sugar' as its
methods are meant to be chained together and you can kick-start the
creation of a new Update instance via the static method
public static Update update(String key, Object
value) and using static imports.
Here is a listing of methods on the Update class
UpdateaddToSet(String key, Object value)Update using the$addToSetupdate modifierUpdateinc(String key, Number inc)Update using the$incupdate modifierUpdatepop(String key, Update.Position pos)Update using the$popupdate modifierUpdatepull(String key, Object value)Update using the$pullupdate modifierUpdatepullAll(String key, Object[] values)Update using the$pullAllupdate modifierUpdatepush(String key, Object value)Update using the$pushupdate modifierUpdatepushAll(String key, Object[] values)Update using the$pushAllupdate modifierUpdaterename(String oldName, String newName)Update using the$renameupdate modifierUpdateset(String key, Object value)Update using the$setupdate modifierUpdateunset(String key)Update using the$unsetupdate modifier
Related to performing an updateFirst
operations, you can also perform an upsert operation which will perform
an insert if no document is found that matches the query. The document
that is inserted is a combination of the query document and the update
document. Here is an example
template.upsert(query(where("ssn").is(1111).and("firstName").is("Joe").and("Fraizer").is("Update")), update("address", addr), Person.class);The findAndModify(…) method on
DBCollection can update a document and return either the old or newly
updated document in a single operation.
MongoTemplate provides a findAndModify method
that takes Query and
Update classes and converts from
DBObject to your POJOs. Here are the
methods
<T> T findAndModify(Query query, Update update, Class<T> entityClass); <T> T findAndModify(Query query, Update update, Class<T> entityClass, String collectionName); <T> T findAndModify(Query query, Update update, FindAndModifyOptions options, Class<T> entityClass); <T> T findAndModify(Query query, Update update, FindAndModifyOptions options, Class<T> entityClass, String collectionName);
As an example usage, we will insert of few
Person objects into the container and perform a
simple findAndUpdate operation
mongoTemplate.insert(new Person("Tom", 21)); mongoTemplate.insert(new Person("Dick", 22)); mongoTemplate.insert(new Person("Harry", 23)); Query query = new Query(Criteria.where("firstName").is("Harry")); Update update = new Update().inc("age", 1); Person p = mongoTemplate.findAndModify(query, update, Person.class); // return's old person object assertThat(p.getFirstName(), is("Harry")); assertThat(p.getAge(), is(23)); p = mongoTemplate.findOne(query, Person.class); assertThat(p.getAge(), is(24)); // Now return the newly updated document when updating p = template.findAndModify(query, update, new FindAndModifyOptions().returnNew(true), Person.class); assertThat(p.getAge(), is(25));
The FindAndModifyOptions lets you set the
options of returnNew, upsert, and remove. An example extending off the
previous code snippit is shown below
Query query2 = new Query(Criteria.where("firstName").is("Mary")); p = mongoTemplate.findAndModify(query2, update, new FindAndModifyOptions().returnNew(true).upsert(true), Person.class); assertThat(p.getFirstName(), is("Mary")); assertThat(p.getAge(), is(1));
You can use several overloaded methods to remove an object from the database.
remove Remove the given document based on one of the following: a specific object instance, a query document criteria combined with a class or a query document criteria combined with a specific collection name.
You can express your queries using the Query
and Criteria classes which have method names that
mirror the native MongoDB operator names such as lt,
lte, is, and others. The
Query and Criteria classes
follow a fluent API style so that you can easily chain together multiple
method criteria and queries while having easy to understand code. Static
imports in Java are used to help remove the need to see the 'new' keyword
for creating Query and
Criteria instances so as to improve readability. If
you like to create Query instances from a plain
JSON String use BasicQuery.
Example 4.15. Creating a Query instance from a plain JSON String
BasicQuery query = new BasicQuery("{ age : { $lt : 50 }, accounts.balance : { $gt : 1000.00 }}"); List<Person> result = mongoTemplate.find(query, Person.class);
GeoSpatial queries are also supported and are described more in the section GeoSpatial Queries.
Map-Reduce operations are also supported and are described more in the section Map-Reduce.
We saw how to retrieve a single document using the findOne and findById methods on MongoTemplate in previous sections which return a single domain object. We can also query for a collection of documents to be returned as a list of domain objects. Assuming that we have a number of Person objects with name and age stored as documents in a collection and that each person has an embedded account document with a balance. We can now run a query using the following code.
Example 4.16. Querying for documents using the MongoTemplate
import static org.springframework.data.mongodb.core.query.Criteria.where; import static org.springframework.data.mongodb.core.query.Query.query; … List<Person> result = mongoTemplate.find(query(where("age").lt(50) .and("accounts.balance").gt(1000.00d)), Person.class);
All find methods take a Query object as a
parameter. This object defines the criteria and options used to perform
the query. The criteria is specified using a
Criteria object that has a static factory method
named where used to instantiate a new
Criteria object. We recommend using a static
import for
org.springframework.data.mongodb.core.query.Criteria.where
and Query.query to make the query more
readable.
This query should return a list of Person
objects that meet the specified criteria. The
Criteria class has the following methods that
correspond to the operators provided in MongoDB.
As you can see most methods return the
Criteria object to provide a fluent style for the
API.
Criteriaall(Object o)Creates a criterion using the$alloperatorCriteriaand(String key)Adds a chainedCriteriawith the specifiedkeyto the currentCriteriaand returns the newly created oneCriteriaandOperator(Criteria... criteria)Creates an and query using the$andoperator for all of the provided criteria (requires MongoDB 2.0 or later)CriteriaelemMatch(Criteria c)Creates a criterion using the$elemMatchoperatorCriteriaexists(boolean b)Creates a criterion using the$existsoperatorCriteriagt(Object o)Creates a criterion using the$gtoperatorCriteriagte(Object o)Creates a criterion using the$gteoperatorCriteriain(Object... o)Creates a criterion using the$inoperator for a varargs argument.Criteriain(Collection<?> collection)Creates a criterion using the$inoperator using a collectionCriteriais(Object o)Creates a criterion using the$isoperatorCriterialt(Object o)Creates a criterion using the$ltoperatorCriterialte(Object o)Creates a criterion using the$lteoperatorCriteriamod(Number value, Number remainder)Creates a criterion using the$modoperatorCriteriane(Object o)Creates a criterion using the$neoperatorCriterianin(Object... o)Creates a criterion using the$ninoperatorCriterianorOperator(Criteria... criteria)Creates an nor query using the$noroperator for all of the provided criteriaCriterianot()Creates a criterion using the$notmeta operator which affects the clause directly followingCriteriaorOperator(Criteria... criteria)Creates an or query using the$oroperator for all of the provided criteriaCriteriaregex(String re)Creates a criterion using a$regexCriteriasize(int s)Creates a criterion using the$sizeoperatorCriteriatype(int t)Creates a criterion using the$typeoperator
There are also methods on the Criteria class for geospatial queries. Here is a listing but look at the section on GeoSpatial Queries to see them in action.
CriteriawithinCenter(Circle circle)Creates a geospatial criterion using$within $centeroperatorsCriteriawithinCenterSphere(Circle circle)Creates a geospatial criterion using$within $centeroperators. This is only available for MongoDB 1.7 and higher.CriteriawithinBox(Box box)Creates a geospatial criterion using a$within $boxoperationCriterianear(Point point)Creates a geospatial criterion using a$nearoperationCriterianearSphere(Point point)Creates a geospatial criterion using$nearSphere$centeroperations. This is only available for MongoDB 1.7 and higher.CriteriamaxDistance(double maxDistance)Creates a geospatial criterion using the$maxDistanceoperation, for use with $near.
The Query class has some additional methods
used to provide options for the query.
QueryaddCriteria(Criteria criteria)used to add additional criteria to the queryFieldfields()used to define fields to be included in the query resultsQuerylimit(int limit)used to limit the size of the returned results to the provided limit (used for paging)Queryskip(int skip)used to skip the provided number of documents in the results (used for paging)Sortsort()used to provide sort definition for the results
The query methods need to specify the target type T that will be returned and they are also overloaded with an explicit collection name for queries that should operate on a collection other than the one indicated by the return type.
findAll Query for a list of objects of type T from the collection.
findOne Map the results of an ad-hoc query on the collection to a single instance of an object of the specified type.
findById Return an object of the given id and target class.
find Map the results of an ad-hoc query on the collection to a List of the specified type.
findAndRemove Map the results of an ad-hoc query on the collection to a single instance of an object of the specified type. The first document that matches the query is returned and also removed from the collection in the database.
MongoDB supports GeoSpatial queries through the use of operators
such as $near, $within, and
$nearSphere. Methods specific to geospatial queries
are available on the Criteria class. There are
also a few shape classes, Box,
Circle, and Point that are
used in conjunction with geospatial related
Criteria methods.
To understand how to perform GeoSpatial queries we will use the
following Venue class taken from the integration tests.which relies on
using the rich MappingMongoConverter.
@Document(collection="newyork") public class Venue { @Id private String id; private String name; private double[] location; @PersistenceConstructor Venue(String name, double[] location) { super(); this.name = name; this.location = location; } public Venue(String name, double x, double y) { super(); this.name = name; this.location = new double[] { x, y }; } public String getName() { return name; } public double[] getLocation() { return location; } @Override public String toString() { return "Venue [id=" + id + ", name=" + name + ", location=" + Arrays.toString(location) + "]"; } }
To find locations within a Circle, the
following query can be used.
Circle circle = new Circle(-73.99171, 40.738868, 0.01); List<Venue> venues = template.find(new Query(Criteria.where("location").withinCenter(circle)), Venue.class);
To find venues within a Circle using
spherical coordinates the following query can be used
Circle circle = new Circle(-73.99171, 40.738868, 0.003712240453784); List<Venue> venues = template.find(new Query(Criteria.where("location").withinCenterSphere(circle)), Venue.class);
To find venues within a Box the following
query can be used
//lower-left then upper-right Box box = new Box(new Point(-73.99756, 40.73083), new Point(-73.988135, 40.741404)); List<Venue> venues = template.find(new Query(Criteria.where("location").withinBox(box)), Venue.class);
To find venues near a Point, the following
query can be used
Point point = new Point(-73.99171, 40.738868); List<Venue> venues = template.find(new Query(Criteria.where("location").near(point).maxDistance(0.01)), Venue.class);
To find venues near a Point using spherical
coordines the following query can be used
Point point = new Point(-73.99171, 40.738868); List<Venue> venues = template.find(new Query( Criteria.where("location").nearSphere(point).maxDistance(0.003712240453784)), Venue.class);
MongoDB supports querying the database for geo locations and
calculation the distance from a given origin at the very same time.
With geo-near queries it's possible to express queries like: "find all
restaurants in the surrounding 10 miles". To do so
MongoOperations provides
geoNear(…) methods taking a
NearQuery as argument as well as the already
familiar entity type and collection
Point location = new Point(-73.99171, 40.738868); NearQuery query = NearQuery.near(location).maxDistance(new Distance(10, Metrics.MILES)); GeoResults<Restaurant> = operations.geoNear(query, Restaurant.class);
As you can see we use the NearQuery
builder API to set up a query to return all
Restaurant instances surrounding the given
Point by 10 miles maximum. The
Metrics enum used here actually implements an
interface so that other metrics could be plugged into a distance as
well. A Metric is backed by a
multiplier to transform the distance value of the given metric into
native distances. The sample shown here would consider the 10 to be
miles. Using one of the pre-built in metrics (miles and kilometers)
will automatically trigger the spherical flag to be set on the query.
If you want to avoid that, simply hand in plain
double values into
maxDistance(…). For more information see the
JavaDoc of NearQuery and
Distance.
The geo near operations return a
GeoResults wrapper object that encapsulates
GeoResult instances. The wrapping
GeoResults allows to access the average
distance of all results. A single GeoResult
object simply carries the entity found plus its distance from the
origin.
You can query MongoDB using Map-Reduce which is useful for batch processing, data aggregation, and for when the query language doesn't fulfill your needs.
Spring provides integration with MongoDB's map reduce by providing methods on MongoOperations to simplify the creation and execution of Map-Reduce operations. It can convert the results of a Map-Reduce operation to a POJO also integrates with Spring's Resource abstraction abstraction. This will let you place your JavaScript files on the file system, classpath, http server or any other Spring Resource implementation and then reference the JavaScript resources via an easy URI style syntax, e.g. 'classpath:reduce.js;. Externalizing JavaScript code in files is often preferable to embedding them as Java strings in your code. Note that you can still pass JavaScript code as Java strings if you prefer.
To understand how to perform Map-Reduce operations an example from the book 'MongoDB - The definitive guide' is used. In this example we will create three documents that have the values [a,b], [b,c], and [c,d] respectfully. The values in each document are associated with the key 'x' as shown below. For this example assume these documents are in the collection named "jmr1".
{ "_id" : ObjectId("4e5ff893c0277826074ec533"), "x" : [ "a", "b" ] }
{ "_id" : ObjectId("4e5ff893c0277826074ec534"), "x" : [ "b", "c" ] }
{ "_id" : ObjectId("4e5ff893c0277826074ec535"), "x" : [ "c", "d" ] }
A map function that will count the occurance of each letter in the array for each document is shown below
function () {
for (var i = 0; i < this.x.length; i++) {
emit(this.x[i], 1);
}
}The reduce function that will sum up the occurance of each letter across all the documents is shown below
function (key, values) {
var sum = 0;
for (var i = 0; i < values.length; i++)
sum += values[i];
return sum;
}Executing this will result in a collection as shown below.
{ "_id" : "a", "value" : 1 }
{ "_id" : "b", "value" : 2 }
{ "_id" : "c", "value" : 2 }
{ "_id" : "d", "value" : 1 }Assuming that the map and reduce functions are located in map.js and reduce.js and bundled in your jar so they are available on the classpath, you can execute a map-reduce operation and obtain the results as shown below
MapReduceResults<ValueObject> results = mongoOperations.mapReduce("jmr1", "classpath:map.js", "classpath:reduce.js", ValueObject.class); for (ValueObject valueObject : results) { System.out.println(valueObject); }
The output of the above code is
ValueObject [id=a, value=1.0] ValueObject [id=b, value=2.0] ValueObject [id=c, value=2.0] ValueObject [id=d, value=1.0]
The MapReduceResults class
implements Iterable and provides access to the
raw output, as well as timing and count statistics. The
ValueObject class is simply
public class ValueObject { private String id; private float value; public String getId() { return id; } public float getValue() { return value; } public void setValue(float value) { this.value = value; } @Override public String toString() { return "ValueObject [id=" + id + ", value=" + value + "]"; } }
By default the output type of INLINE is used so you don't
have to specify an output collection. To specify additional map-reduce
options use an overloaded method that takes an additional
MapReduceOptions argument. The class
MapReduceOptions has a fluent API so adding
additional options can be done in a very compact syntax. Here an example
that sets the output collection to "jmr1_out". Note that setting only
the output collection assumes a default output type of REPLACE.
MapReduceResults<ValueObject> results = mongoOperations.mapReduce("jmr1", "classpath:map.js", "classpath:reduce.js", new MapReduceOptions().outputCollection("jmr1_out"), ValueObject.class);
There is also a static import import static
org.springframework.data.mongodb.core.mapreduce.MapReduceOptions.options;
that can be used to make the syntax slightly more compact
MapReduceResults<ValueObject> results = mongoOperations.mapReduce("jmr1", "classpath:map.js", "classpath:reduce.js", options().outputCollection("jmr1_out"), ValueObject.class);
You can also specify a query to reduce the set of data that will be used to feed into the map-reduce operation. This will remove the document that contains [a,b] from consideration for map-reduce operations.
Query query = new Query(where("x").ne(new String[] { "a", "b" })); MapReduceResults<ValueObject> results = mongoOperations.mapReduce(query, "jmr1", "classpath:map.js", "classpath:reduce.js", options().outputCollection("jmr1_out"), ValueObject.class);
Note that you can specify additional limit and sort values as well on the query but not skip values.
As an alternative to using Map-Reduce to perform data aggregation,
you can use the group
operation which feels similar to using SQL's group by query style,
so it may feel more approachable vs. using Map-Reduce. Using the group
operations does have some limitations, for example it is not supported in
a shareded environment and it returns the full result set in a single BSON
object, so the result should be small, less than 10,000 keys.
Spring provides integration with MongoDB's group operation by providing methods on MongoOperations to simplify the creation and execution of group operations. It can convert the results of the group operation to a POJO and also integrates with Spring's Resource abstraction abstraction. This will let you place your JavaScript files on the file system, classpath, http server or any other Spring Resource implementation and then reference the JavaScript resources via an easy URI style syntax, e.g. 'classpath:reduce.js;. Externalizing JavaScript code in files if often preferable to embedding them as Java strings in your code. Note that you can still pass JavaScript code as Java strings if you prefer.
In order to understand how group operations work the following example is used, which is somewhat artificial. For a more realistic example consult the book 'MongoDB - The definitive guide'. A collection named "group_test_collection" created with the following rows.
{ "_id" : ObjectId("4ec1d25d41421e2015da64f1"), "x" : 1 }
{ "_id" : ObjectId("4ec1d25d41421e2015da64f2"), "x" : 1 }
{ "_id" : ObjectId("4ec1d25d41421e2015da64f3"), "x" : 2 }
{ "_id" : ObjectId("4ec1d25d41421e2015da64f4"), "x" : 3 }
{ "_id" : ObjectId("4ec1d25d41421e2015da64f5"), "x" : 3 }
{ "_id" : ObjectId("4ec1d25d41421e2015da64f6"), "x" : 3 }We would like to group by the only field in each row, the 'x' field and aggregate the number of times each specific value of 'x' occurs. To do this we need to create an initial document that contains our count variable and also a reduce function which will increment it each time it is encountered. The Java code to execute the group operation is shown below
GroupByResults<XObject> results = mongoTemplate.group("group_test_collection", GroupBy.key("x").initialDocument("{ count: 0 }").reduceFunction("function(doc, prev) { prev.count += 1 }"), XObject.class);
The first argument is the name of the collection to run the group
operation over, the second is a fluent API that specifies properties of
the group operation via a GroupBy class. In this
example we are using just the intialDocument
and reduceFunction methods. You can also
specify a key-function, as well as a finalizer as part of the fluent
API. If you have multiple keys to group by, you can pass in a comma
separated list of keys.
The raw results of the group operation is a JSON document that looks like this
{
"retval" : [ { "x" : 1.0 , "count" : 2.0} ,
{ "x" : 2.0 , "count" : 1.0} ,
{ "x" : 3.0 , "count" : 3.0} ] ,
"count" : 6.0 ,
"keys" : 3 ,
"ok" : 1.0
}The document under the "retval" field is mapped onto the third argument in the group method, in this case XObject which is shown below.
public class XObject { private float x; private float count; public float getX() { return x; } public void setX(float x) { this.x = x; } public float getCount() { return count; } public void setCount(float count) { this.count = count; } @Override public String toString() { return "XObject [x=" + x + " count = " + count + "]"; } }
You can also obtain the raw result as a
DbObject by calling the method
getRawResults on the
GroupByResults class.
There is an additional method overload of the group method on
MongoOperations which lets you specify a
Criteria object for selecting a subset of the
rows. An example which uses a Criteria object,
with some syntax sugar using static imports, as well as referencing a
key-function and reduce function javascript files via a Spring Resource
string is shown below.
import static org.springframework.data.mongodb.core.mapreduce.GroupBy.keyFunction;
import static org.springframework.data.mongodb.core.query.Criteria.where;
GroupByResults<XObject> results = mongoTemplate.group(where("x").gt(0),
"group_test_collection",
keyFunction("classpath:keyFunction.js").initialDocument("{ count: 0 }").reduceFunction("classpath:groupReduce.js"), XObject.class);Spring Data MongoDB provides support for the Aggregation Framework introduced to MongoDB in version 2.2.
The MongoDB Documentation describes the Aggregation Framework as follows:“The MongoDB aggregation framework provides a means to calculate aggregated values without having to use map-reduce. While map-reduce is powerful, it is often more difficult than necessary for many simple aggregation tasks, such as totaling or averaging field values.”
For further information see the full reference documentation of the aggregation framework and other data aggregation tools for MongoDB.
The Aggregation Framework support in Spring Data MongoDB is based
on the following key abstractions Aggregation,
AggregationOperation and
AggregationResults.
AggregationAn Aggregation represents a MongoDB
aggregateoperation and holds the description of the aggregation pipline instructions. Aggregations are created by inoking the appropriatenewAggregation(…)static factory Method of theAggregationclass which takes the list ofAggregateOperationas a parameter next to the optional input class.The actual aggregate operation is executed by the
aggregatemethod of theMongoTemplatewhich also takes the desired output class as parameter.AggregationOperationAn
AggregationOperationrepresents a MongoDB aggregation pipeline operation and describes the processing that should be performed in this aggregation step. Although one could manually create anAggregationOperationthe recommended way to construct anAggregateOperationis to use the static factory methods provided by theAggregateclass.AggregationResultsAggregationResultsis the container for the result of an aggregate operation. It provides access to the raw aggregation result in the form of anDBObject, to the mapped objects and information which performed the aggregation.
The canonical example for using the Spring Data MongoDB support for the MongoDB Aggregation Framework looks as follows:
import static org.springframework.data.mongodb.core.aggregation.Aggregation.*; Aggregation agg = newAggregation( pipelineOP1(), pipelineOP2(), pipelineOPn() ); AggregationResults<OutputType> results = mongoTemplate.aggregate(agg, "INPUT_COLLECTION_NAME", OutputType.class); List<OutputType> mappedResult = results.getMappedResults();
Note that if you provide an input class as the first parameter to
the newAggregation method the
MongoTemplate will derive the name of the input
collection from this class. Otherwise if you don't not specify an input
class you must provide the name of the input collection explicitly. If
an input-class and an input-collection is provided the latter takes
precedence.
The MongoDB Aggregation Framework provides the following types of Aggregation Operations:
Pipeline Aggregation Operators
Group Aggregation Operators
Boolean Aggregation Operators
Comparison Aggregation Operators
Arithmetic Aggregation Operators
String Aggregation Operators
Date Aggregation Operators
Conditional Aggregation Operators
At the time of this writing we provide support for the following Aggregation Operations in Spring Data MongoDB.
Table 4.1. Aggregation Operations currently supported by Spring Data MongoDB
| Pipeline Aggregation Operators | project, skip, limit, unwind, group, sort, geoNear |
| Group Aggregation Operators | addToSet, first, last, max, min, avg, push, sum, (*count) |
| Arithmetic Aggregation Operators | add (*via plus), subtract (*via minus), multiply, divide, mod |
| Comparison Aggregation Operators | eq (*via: is), gt, gte, lt, lte, ne |
Note that the aggregation operations not listed here are currently
not supported by Spring Data MongoDB. Comparison aggregation operators
are expressed as Criteria expressions.
*) The operation is mapped or added by Spring Data MongoDB.
Projection expressions are used to define the fields that are the
outcome of a particular aggregation step. Projection expressions can be
defined via the project method of the
Aggregate class.
Example 4.17. Projection expression examples
project("name", "netPrice") // will generate {$project: {name: 1, netPrice: 1}} project().and("foo").as("bar") // will generate {$project: {bar: $foo}} project("a","b").and("foo").as("bar") // will generate {$project: {a: 1, b: 1, bar: $foo}}
Note that more examples for project operations can be found in
the AggregationTests class.
Note that further details regarding the projection expressions can be found in the corresponding section of the MongoDB Aggregation Framework reference documentation.
As of Version 1.4.0 we support the use of SpEL expression in
projection expressions via the andExpression
method of the ProjectionOperation class. This
allows you to define the desired expression as a SpEL expression which
is translated into a corresponding MongoDB projection expression part
on query execution. This makes it much easier to express complex
calculations.
Example 4.18. Complex calculations with SpEL expressions
The following SpEL expression:
1 + (q + 1) / (q - 1)
will be translated into the following projection expression part:
{ "$add" : [ 1, {
"$divide" : [ {
"$add":["$q", 1]}, {
"$subtract":[ "$q", 1]}
]
}]}Have a look at an example in more context in Example 4.23, “Aggregation Framework Example 5” and Example 4.24, “Aggregation Framework Example 6”. You can find more
usage examples for supported SpEL expression constructs in
SpelExpressionTransformerUnitTests.
The following examples demonstrate the usage patterns for the MongoDB Aggregation Framework with Spring Data MongoDB.
Example 4.19. Aggregation Framework Example 1
In this introductory example we want to aggregate a list of tags
to get the occurrence count of a particular tag from a MongoDB
collection called "tags" sorted by the occurrence count
in descending order. This example demonstrates the usage of grouping,
sorting, projections (selection) and unwinding (result
splitting).
class TagCount { String tag; int n; }
import static org.springframework.data.mongodb.core.aggregation.Aggregation.*; Aggregation agg = newAggregation( project("tags"), unwind("tags"), group("tags").count().as("n"), project("n").and("tag").previousOperation(), sort(DESC, "n") ); AggregationResults<TagCount> results = mongoTemplate.aggregate(agg, "tags", TagCount.class); List<TagCount> tagCount = results.getMappedResults();
In order to do this we first create a new aggregation via the
newAggregationstatic factory method to which we pass a list of aggregation operations. These aggregate operations define the aggregation pipeline of ourAggregation.As a second step we select the
"tags"field (which is an array of strings) from the input collection with theprojectoperation.In a third step we use the
unwindoperation to generate a new document for each tag within the"tags"array.In the forth step we use the
groupoperation to define a group for each"tags"-value for which we aggregate the occurrence count via thecountaggregation operator and collect the result in a new field called"n".As a fifth step we select the field
"n"and create an alias for the id-field generated from the previous group operation (hence the call topreviousOperation()) with the name"tag".As the sixth step we sort the resulting list of tags by their occurrence count in descending order via the
sortoperation.Finally we call the
aggregateMethod on the MongoTemplate in order to let MongoDB perform the acutal aggregation operation with the createdAggregationas an argument.
Note that the input collection is explicitly specified as the
"tags" parameter to the aggregate
Method. If the name of the input collection is not specified explicitly,
it is derived from the input-class passed as first parameter to the
newAggreation Method.
Example 4.20. Aggregation Framework Example 2
This example is based on the Largest and Smallest Cities by State example from the MongoDB Aggregation Framework documentation. We added additional sorting to produce stable results with different MongoDB versions. Here we want to return the smallest and largest cities by population for each state, using the aggregation framework. This example demonstrates the usage of grouping, sorting and projections (selection).
class ZipInfo { String id; String city; String state; @Field("pop") int population; @Field("loc") double[] location; } class City { String name; int population; } class ZipInfoStats { String id; String state; City biggestCity; City smallestCity; }
import static org.springframework.data.mongodb.core.aggregation.Aggregation.*; TypedAggregation<ZipInfo> aggregation = newAggregation(ZipInfo.class, group("state", "city") .sum("population").as("pop"), sort(ASC, "pop", "state", "city"), group("state") .last("city").as("biggestCity") .last("pop").as("biggestPop") .first("city").as("smallestCity") .first("pop").as("smallestPop"), project() .and("state").previousOperation() .and("biggestCity") .nested(bind("name", "biggestCity").and("population", "biggestPop")) .and("smallestCity") .nested(bind("name", "smallestCity").and("population", "smallestPop")), sort(ASC, "state") ); AggregationResults<ZipInfoStats> result = mongoTemplate.aggregate(aggregation, ZipInfoStats.class); ZipInfoStats firstZipInfoStats = result.getMappedResults().get(0);
The class
ZipInfomaps the structure of the given input-collection. The classZipInfoStatsdefines the structure in the desired output format.As a first step we use the
groupoperation to define a group from the input-collection. The grouping criteria is the combination of the fields"state"and"city"which forms the id structure of the group. We aggregate the value of the"population"property from the grouped elements with by using thesumoperator saving the result in the field"pop".In a second step we use the
sortoperation to sort the intermediate-result by the fields"pop","state"and"city"in ascending order, such that the smallest city is at the top and the biggest city is at the bottom of the result. Note that the sorting on "state" and"city"is implicitly performed against the group id fields which Spring Data MongoDB took care of.In the third step we use a
groupoperation again to group the intermediate result by"state". Note that"state"again implicitly references an group-id field. We select the name and the population count of the biggest and smallest city with calls to thelast(…)andfirst(...)operator respectively via theprojectoperation.As the forth step we select the
"state"field from the previousgroupoperation. Note that"state"again implicitly references an group-id field. As we do not want an implicit generated id to appear, we exclude the id from the previous operation viaand(previousOperation()).exclude(). As we want to populate the nestedCitystructures in our output-class accordingly we have to emit appropriate sub-documents with the nested method.Finally as the fifth step we sort the resulting list of
StateStatsby their state name in ascending order via thesortoperation.
Note that we derive the name of the input-collection from the
ZipInfo-class passed as first parameter to the
newAggregation-Method.
Example 4.21. Aggregation Framework Example 3
This example is based on the States with Populations Over 10 Million example from the MongoDB Aggregation Framework documentation. We added additional sorting to produce stable results with different MongoDB versions. Here we want to return all states with a population greater than 10 million, using the aggregation framework. This example demonstrates the usage of grouping, sorting and matching (filtering).
class StateStats { @Id String id; String state; @Field("totalPop") int totalPopulation; }
import static org.springframework.data.mongodb.core.aggregation.Aggregation.*; TypedAggregation<ZipInfo> agg = newAggregation(ZipInfo.class, group("state").sum("population").as("totalPop"), sort(ASC, previousOperation(), "totalPop"), match(where("totalPop").gte(10 * 1000 * 1000)) ); AggregationResults<StateStats> result = mongoTemplate.aggregate(agg, StateStats.class); List<StateStats> stateStatsList = result.getMappedResults();
As a first step we group the input collection by the
"state"field and calculate the sum of the"population"field and store the result in the new field"totalPop".In the second step we sort the intermediate result by the id-reference of the previous group operation in addition to the
"totalPop"field in ascending order.Finally in the third step we filter the intermediate result by using a
matchoperation which accepts aCriteriaquery as an argument.
Note that we derive the name of the input-collection from the
ZipInfo-class passed as first parameter to the
newAggregation-Method.
Example 4.22. Aggregation Framework Example 4
This example demonstrates the use of simple arithmetic operations in the projection operation.
class Product { String id; String name; double netPrice; int spaceUnits; }
import static org.springframework.data.mongodb.core.aggregation.Aggregation.*; TypedAggregation<Product> agg = newAggregation(Product.class, project("name", "netPrice") .and("netPrice").plus(1).as("netPricePlus1") .and("netPrice").minus(1).as("netPriceMinus1") .and("netPrice").multiply(1.19).as("grossPrice") .and("netPrice").divide(2).as("netPriceDiv2") .and("spaceUnits").mod(2).as("spaceUnitsMod2") ); AggregationResults<DBObject> result = mongoTemplate.aggregate(agg, DBObject.class); List<DBObject> resultList = result.getMappedResults();
Note that we derive the name of the input-collection from the
Product-class passed as first parameter to the
newAggregation-Method.
Example 4.23. Aggregation Framework Example 5
This example demonstrates the use of simple arithmetic operations derived from SpEL Expressions in the projection operation.
class Product { String id; String name; double netPrice; int spaceUnits; }
import static org.springframework.data.mongodb.core.aggregation.Aggregation.*; TypedAggregation<Product> agg = newAggregation(Product.class, project("name", "netPrice") .andExpression("netPrice + 1").as("netPricePlus1") .andExpression("netPrice - 1").as("netPriceMinus1") .andExpression("netPrice / 2").as("netPriceDiv2") .andExpression("netPrice * 1.19").as("grossPrice") .andExpression("spaceUnits % 2").as("spaceUnitsMod2") .andExpression("(netPrice * 0.8 + 1.2) * 1.19").as("grossPriceIncludingDiscountAndCharge") ); AggregationResults<DBObject> result = mongoTemplate.aggregate(agg, DBObject.class); List<DBObject> resultList = result.getMappedResults();
Example 4.24. Aggregation Framework Example 6
This example demonstrates the use of complex arithmetic operations derived from SpEL Expressions in the projection operation.
Note: The additional parameters passed to the
addExpression Method can be referenced via
indexer expressions according to their position. In this example we
reference the parameter shippingCosts which is the
first parameter of the parameters array via [0]. External
parameter expressions are replaced with their respective values when
the SpEL expression is transformed into a MongoDB aggregation
framework expression.
class Product { String id; String name; double netPrice; int spaceUnits; }
import static org.springframework.data.mongodb.core.aggregation.Aggregation.*; double shippingCosts = 1.2; TypedAggregation<Product> agg = newAggregation(Product.class, project("name", "netPrice") .andExpression("(netPrice * (1-discountRate) + [0]) * (1+taxRate)", shippingCosts).as("salesPrice") ); AggregationResults<DBObject> result = mongoTemplate.aggregate(agg, DBObject.class); List<DBObject> resultList = result.getMappedResults();
Note that we can also refer to other fields of the document within the SpEL expression.
In order to have more fine grained control over the mapping process
you can register Spring converters with the
MongoConverter implementations such as the
MappingMongoConverter.
The MappingMongoConverter checks to see if
there are any Spring converters that can handle a specific class before
attempting to map the object itself. To 'hijack' the normal mapping
strategies of the MappingMongoConverter, perhaps
for increased performance or other custom mapping needs, you first need to
create an implementation of the Spring
Converter interface and then register it
with the MappingConverter.
| Note |
|---|---|
For more information on the Spring type conversion service see the reference docs here. |
An example implementation of the
Converter that converts from a Person
object to a com.mongodb.DBObject is shown
below
import org.springframework.core.convert.converter.Converter; import com.mongodb.BasicDBObject; import com.mongodb.DBObject; public class PersonWriteConverter implements Converter<Person, DBObject> { public DBObject convert(Person source) { DBObject dbo = new BasicDBObject(); dbo.put("_id", source.getId()); dbo.put("name", source.getFirstName()); dbo.put("age", source.getAge()); return dbo; } }
An example implementation of a Converter that converts from a DBObject ot a Person object is shownn below
public class PersonReadConverter implements Converter<DBObject, Person> { public Person convert(DBObject source) { Person p = new Person((ObjectId) source.get("_id"), (String) source.get("name")); p.setAge((Integer) source.get("age")); return p; } }
The Mongo Spring namespace provides a convenience way to register
Spring Converters with the
MappingMongoConverter. The configuration snippet
below shows how to manually register converter beans as well as
configuring the wrapping MappingMongoConverter
into a MongoTemplate.
<mongo:db-factory dbname="database"/> <mongo:mapping-converter> <mongo:custom-converters> <mongo:converter ref="readConverter"/> <mongo:converter> <bean class="org.springframework.data.mongodb.test.PersonWriteConverter"/> </mongo:converter> </mongo:custom-converters> </mongo:mapping-converter> <bean id="readConverter" class="org.springframework.data.mongodb.test.PersonReadConverter"/> <bean id="mongoTemplate" class="org.springframework.data.mongodb.core.MongoTemplate"> <constructor-arg name="mongoDbFactory" ref="mongoDbFactory"/> <constructor-arg name="mongoConverter" ref="mappingConverter"/> </bean>
You can also use the base-package attribute of the
custom-converters element to enable classpath scanning for all
Converter and
GenericConverter implementations below
the given package.
<mongo:mapping-converter> <mongo:custom-converters base-package="com.acme.**.converters" /> </mongo:mapping-converter>
Generally we inspect the Converter
implementations for the source and target types they convert from and
to. Depending on whether one of those is a type MongoDB can handle
natively we will register the converter instance as reading or writing
one. Have a look at the following samples:
// Write converter as only the target type is one Mongo can handle natively class MyConverter implements Converter<Person, String> { … } // Read converter as only the source type is one Mongo can handle natively class MyConverter implements Converter<String, Person> { … }
In case you write a Converter whose
source and target type are native Mongo types there's no way for us to
determine whether we should consider it as reading or writing converter.
Registering the converter instance as both might lead to unwanted
results then. E.g. a Converter<String,
Long> is ambiguous although it probably does not make
sense to try to convert all Strings into
Longs when writing. To be generally able to force
the infrastructure to register a converter for one way only we provide
@ReadingConverter as well as
@WritingConverter to be used at the
converter implementation.
MongoTemplate provides a few methods for
managing indexes and collections. These are collected into a helper
interface called IndexOperations. You
access these operations by calling the method
indexOps and pass in either the collection name
or the java.lang.Class of your entity (the collection
name will be derived from the .class either by name or via annotation
metadata).
The IndexOperations interface is
shown below
public interface IndexOperations { void ensureIndex(IndexDefinition indexDefinition); void dropIndex(String name); void dropAllIndexes(); void resetIndexCache(); List<IndexInfo> getIndexInfo(); }
We can create an index on a collection to improve query performance.
Example 4.25. Creating an index using the MongoTemplate
mongoTemplate.indexOps(Person.class).ensureIndex(new Index().on("name",Order.ASCENDING));
ensureIndex Ensure that an index for the provided IndexDefinition exists for the collection.
You can create both standard indexes and geospatial indexes using
the classes IndexDefinition and
GeoSpatialIndex respectfully. For example, given
the Venue class defined in a previous section, you would declare a
geospatial query as shown below
mongoTemplate.indexOps(Venue.class).ensureIndex(new GeospatialIndex("location"));
The IndexOperations interface has the method getIndexInfo that returns a list of IndexInfo objects. This contains all the indexes defined on the collectcion. Here is an example that defines an index on the Person class that has age property.
template.indexOps(Person.class).ensureIndex(new Index().on("age", Order.DESCENDING).unique(Duplicates.DROP)); List<IndexInfo> indexInfoList = template.indexOps(Person.class).getIndexInfo(); // Contains // [IndexInfo [fieldSpec={_id=ASCENDING}, name=_id_, unique=false, dropDuplicates=false, sparse=false], // IndexInfo [fieldSpec={age=DESCENDING}, name=age_-1, unique=true, dropDuplicates=true, sparse=false]]
It's time to look at some code examples showing how to use the
MongoTemplate. First we look at creating our
first collection.
Example 4.26. Working with collections using the MongoTemplate
DBCollection collection = null; if (!mongoTemplate.getCollectionNames().contains("MyNewCollection")) { collection = mongoTemplate.createCollection("MyNewCollection"); } mongoTemplate.dropCollection("MyNewCollection");
getCollectionNames Returns a set of collection names.
collectionExists Check to see if a collection with a given name exists.
createCollection Create an uncapped collection
dropCollection Drop the collection
getCollection Get a collection by name, creating it if it doesn't exist.
You can also get at the MongoDB driver's DB.command(
) method using the executeCommand(…)
methods on MongoTemplate. These will also perform
exception translation into Spring's
DataAccessException hierarchy.
Built into the MongoDB mapping framework are several
org.springframework.context.ApplicationEvent events
that your application can respond to by registering special beans in the
ApplicationContext. By being based off Spring's
ApplicationContext event infastructure this enables other products, such
as Spring Integration, to easily receive these events as they are a well
known eventing mechanism in Spring based applications.
To intercept an object before it goes through the conversion process
(which turns your domain object into a
com.mongodb.DBObject), you'd register a subclass of
AbstractMongoEventListener that overrides the
onBeforeConvert method. When the event is dispatched, your
listener will be called and passed the domain object before it goes into
the converter.
Example 4.27.
public class BeforeConvertListener extends AbstractMongoEventListener<Person> { @Override public void onBeforeConvert(Person p) { ... does some auditing manipulation, set timestamps, whatever ... } }
To intercept an object before it goes into the database, you'd
register a subclass of
org.springframework.data.mongodb.core.mapping.event.AbstractMongoEventListener
that overrides the onBeforeSave method. When the event is
dispatched, your listener will be called and passed the domain object and
the converted com.mongodb.DBObject.
Example 4.28.
public class BeforeSaveListener extends AbstractMongoEventListener<Person> { @Override public void onBeforeSave(Person p, DBObject dbo) { … change values, delete them, whatever … } }
Simply declaring these beans in your Spring ApplicationContext will cause them to be invoked whenever the event is dispatched.
The list of callback methods that are present in AbstractMappingEventListener are
onBeforeConvert- called in MongoTemplate insert, insertList and save operations before the object is converted to a DBObject using a MongoConveter.onBeforeSave- called in MongoTemplate insert, insertList and save operations before inserting/saving the DBObject in the database.onAfterSave- called in MongoTemplate insert, insertList and save operations after inserting/saving the DBObject in the database.onAfterLoad- called in MongoTempnlate find, findAndRemove, findOne and getCollection methods after the DBObject is retrieved from the database.onAfterConvert- called in MongoTempnlate find, findAndRemove, findOne and getCollection methods after the DBObject retrieved from the database was converted to a POJO.
The Spring framework provides exception translation for a wide
variety of database and mapping technologies. This has traditionally been
for JDBC and JPA. The Spring support for MongoDB extends this feature to
the MongoDB Database by providing an implementation of the
org.springframework.dao.support.PersistenceExceptionTranslator
interface.
The motivation behind mapping to Spring's consistent
data access exception hierarchy is that you are then able to write
portable and descriptive exception handling code without resorting to
coding against MongoDB error
codes. All of Spring's data access exceptions are inherited from
the root DataAccessException class so you can be
sure that you will be able to catch all database related exception within
a single try-catch block. Note, that not all exceptions thrown by the
MongoDB driver inherit from the MongoException class. The inner exception
and message are preserved so no information is lost.
Some of the mappings performed by the
MongoExceptionTranslator are: com.mongodb.Network
to DataAccessResourceFailureException and
MongoException error codes 1003, 12001, 12010,
12011, 12012 to InvalidDataAccessApiUsageException.
Look into the implementation for more details on the mapping.
One common design feature of all Spring template classes is that all
functionality is routed into one of the templates execute callback
methods. This helps ensure that exceptions and any resource management
that maybe required are performed consistency. While this was of much
greater need in the case of JDBC and JMS than with MongoDB, it still
offers a single spot for exception translation and logging to occur. As
such, using thexe execute callback is the preferred way to access the
MongoDB driver's DB and
DBCollection objects to perform uncommon operations
that were not exposed as methods on
MongoTemplate.
Here is a list of execute callback methods.
<T> Texecute(Class<?> entityClass, CollectionCallback<T> action)Executes the given CollectionCallback for the entity collection of the specified class.<T> Texecute(String collectionName, CollectionCallback<T> action)Executes the given CollectionCallback on the collection of the given name.<T> Texecute(DbCallback<T> action) Spring Data MongoDB provides support for the Aggregation Framework introduced to MongoDB in version 2.2.Executes a DbCallback translating any exceptions as necessary.<T> Texecute(String collectionName, DbCallback<T> action)Executes a DbCallback on the collection of the given name translating any exceptions as necessary.<T> TexecuteInSession(DbCallback<T> action)Executes the given DbCallback within the same connection to the database so as to ensure consistency in a write heavy environment where you may read the data that you wrote.
Here is an example that uses the
CollectionCallback to return information
about an index
boolean hasIndex = template.execute("geolocation", new CollectionCallbackBoolean>() { public Boolean doInCollection(Venue.class, DBCollection collection) throws MongoException, DataAccessException { List<DBObject> indexes = collection.getIndexInfo(); for (DBObject dbo : indexes) { if ("location_2d".equals(dbo.get("name"))) { return true; } } return false; } });
MongoDB supports storing binary files inside it's filesystem GridFS.
Spring Data MongoDB provides a
GridFsOperations interface as well as the
according implementation GridFsTemplate to easily
interact with the filesystem. You can setup a
GridFsTemplate instance by handing it a
MongoDbFactory as well as a
MongoConverter:
Example 4.29. JavaConfig setup for a GridFsTemplate
class GridFsConfiguration extends AbstractMongoConfiguration { // … further configuration omitted @Bean public GridFsTemplate gridFsTemplate() { return new GridFsTemplate(mongoDbFactory(), mappingMongoConverter()); } }
An according XML configuration looks like this:
Example 4.30. XML configuration for a GridFsTemplate
<?xml version="1.0" encoding="UTF-8"?> <beans xmlns="http://www.springframework.org/schema/beans" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" xmlns:mongo="http://www.springframework.org/schema/data/mongo" xsi:schemaLocation="http://www.springframework.org/schema/data/mongo http://www.springframework.org/schema/data/mongo/spring-mongo.xsd http://www.springframework.org/schema/beans http://www.springframework.org/schema/beans/spring-beans.xsd"> <mongo:db-factory id="mongoDbFactory" dbname="database" /> <mongo:mapping-converter id="converter" /> <bean class="org.springframework.data.mongodb.gridfs.GridFsTemplate"> <constructor-arg ref="mongoDbFactory" /> <constructor-arg ref="converter" /> </bean> </beans>
The template can now be injected and used to perform storage and retrieval operations.
Example 4.31. Using GridFsTemplate to store files
class GridFsClient { @Autowired GridFsOperations operations; @Test public void storeFileToGridFs { FileMetadata metadata = new FileMetadata(); // populate metadata Resource file = … // lookup File or Resource operations.store(file.getInputStream(), "filename.txt", metadata); } }
The store(…) operations take an
InputStream, a filename and optionally
metadata information about the file to store. The metadata can be an
arbitrary object which will be marshalled by the
MongoConverter configured with the
GridFsTemplate. Alternatively you can also provide
a DBObject as well.
Reading files from the filesystem can either be achieved through the
find(…) or
getResources(…) methods. Let's have a look at the
find(…) methods first. You can either find a
single file matching a Query or multiple ones. To
easily define file queries we provide the
GridFsCriteria helper class. It provides static
factory methods to encapsulate default metadata fields (e.g.
whereFilename(),
whereContentType()) or the custom one through
whereMetaData().
Example 4.32. Using GridFsTemplate to query for files
class GridFsClient { @Autowired GridFsOperations operations; @Test public void findFilesInGridFs { List<GridFSDBFile> result = operations.find(query(whereFilename().is("filename.txt"))) } }
| Note |
|---|---|
Currently MongoDB does not support defining sort criterias when
retrieving files from GridFS. Thus any sort criterias defined on the
|
The other option to read files from the GridFs is using the methods
introduced by the ResourcePatternResolver
interface. They allow handing an Ant path into the method ar thus retrieve
files matching the given pattern.
Example 4.33. Using GridFsTemplate to read files
class GridFsClient { @Autowired GridFsOperations operations; @Test public void readFilesFromGridFs { GridFsResources[] txtFiles = operations.getResources("*.txt"); } }
GridFsOperations extending
ResourcePatternResolver allows the
GridFsTemplate e.g. to be plugged into an
ApplicationContext to read Spring Config
files from a MongoDB.