(Quick Reference)
6 Object Relational Mapping (GORM) - Reference Documentation
Authors: Graeme Rocher, Peter Ledbrook, Marc Palmer, Jeff Brown, Luke Daley, Burt Beckwith
Version: 2.2.5
6 Object Relational Mapping (GORM)
Domain classes are core to any business application. They hold state about business processes and hopefully also implement behavior. They are linked together through relationships; one-to-one, one-to-many, or many-to-many.
GORM is Grails' object relational mapping (ORM) implementation. Under the hood it uses Hibernate 3 (a very popular and flexible open source ORM solution) and thanks to the dynamic nature of Groovy with its static and dynamic typing, along with the convention of Grails, there is far less configuration involved in creating Grails domain classes.
You can also write Grails domain classes in Java. See the section on Hibernate Integration for how to write domain classes in Java but still use dynamic persistent methods. Below is a preview of GORM in action:
def book = Book.findByTitle("Groovy in Action")book
.addToAuthors(name:"Dierk Koenig")
.addToAuthors(name:"Guillaume LaForge")
.save()
6.1 Quick Start Guide
A domain class can be created with the
create-domain-class command:
grails create-domain-class helloworld.Person
If no package is specified with the create-domain-class script, Grails automatically uses the application name as the package name.
This will create a class at the location
grails-app/domain/helloworld/Person.groovy
such as the one below:
package helloworldclass Person {
}
If you have the dbCreate
property set to "update", "create" or "create-drop" on your DataSource, Grails will automatically generate/modify the database tables for you.
You can customize the class by adding properties:
class Person {
String name
Integer age
Date lastVisit
}
Once you have a domain class try and manipulate it with the
shell or
console by typing:
This loads an interactive GUI where you can run Groovy commands with access to the Spring ApplicationContext, GORM, etc.
6.1.1 Basic CRUD
Try performing some basic CRUD (Create/Read/Update/Delete) operations.
Create
To create a domain class use Map constructor to set its properties and call
save:
def p = new Person(name: "Fred", age: 40, lastVisit: new Date())
p.save()
The
save method will persist your class to the database using the underlying Hibernate ORM layer.
Read
Grails transparently adds an implicit
id
property to your domain class which you can use for retrieval:
def p = Person.get(1)
assert 1 == p.id
This uses the
get method that expects a database identifier to read the
Person
object back from the database.
You can also load an object in a read-only state by using the
read method:
In this case the underlying Hibernate engine will not do any dirty checking and the object will not be persisted. Note that
if you explicitly call the
save method then the object is placed back into a read-write state.
In addition, you can also load a proxy for an instance by using the
load method:
This incurs no database access until a method other than getId() is called. Hibernate then initializes the proxied instance, or
throws an exception if no record is found for the specified id.
Update
To update an instance, change some properties and then call
save again:
def p = Person.get(1)
p.name = "Bob"
p.save()
Delete
To delete an instance use the
delete method:
def p = Person.get(1)
p.delete()
6.2 Domain Modelling in GORM
When building Grails applications you have to consider the problem domain you are trying to solve. For example if you were building an
Amazon-style bookstore you would be thinking about books, authors, customers and publishers to name a few.
These are modeled in GORM as Groovy classes, so a
Book
class may have a title, a release date, an ISBN number and so on. The next few sections show how to model the domain in GORM.
To create a domain class you run the
create-domain-class command as follows:
grails create-domain-class org.bookstore.Book
The result will be a class at
grails-app/domain/org/bookstore/Book.groovy
:
package org.bookstoreclass Book {
}
This class will map automatically to a table in the database called
book
(the same name as the class). This behaviour is customizable through the
ORM Domain Specific LanguageNow that you have a domain class you can define its properties as Java types. For example:
package org.bookstoreclass Book {
String title
Date releaseDate
String ISBN
}
Each property is mapped to a column in the database, where the convention for column names is all lower case separated by underscores. For example
releaseDate
maps onto a column
release_date
. The SQL types are auto-detected from the Java types, but can be customized with
Constraints or the
ORM DSL.
6.2.1 Association in GORM
Relationships define how domain classes interact with each other. Unless specified explicitly at both ends, a relationship exists only in the direction it is defined.
6.2.1.1 Many-to-one and one-to-one
A many-to-one relationship is the simplest kind, and is defined with a property of the type of another domain class. Consider this example:
Example A
In this case we have a unidirectional many-to-one relationship from
Face
to
Nose
. To make this relationship bidirectional define the other side as follows (and see the section on controlling the ends of the association just below):
Example B
class Nose {
static belongsTo = [face:Face]
}
In this case we use the
belongsTo
setting to say that
Nose
"belongs to"
Face
. The result of this is that we can create a
Face
, attach a
Nose
instance to it and when we save or delete the
Face
instance, GORM will save or delete the
Nose
. In other words, saves and deletes will cascade from
Face
to the associated
Nose
:
new Face(nose:new Nose()).save()
The example above will save both face and nose. Note that the inverse
is not true and will result in an error due to a transient
Face
:
new Nose(face:new Face()).save() // will cause an error
Now if we delete the
Face
instance, the
Nose
will go too:
def f = Face.get(1)
f.delete() // both Face and Nose deleted
To make the relationship a true one-to-one, use the
hasOne
property on the owning side, e.g.
Face
:
Example C
class Face {
static hasOne = [nose:Nose]
}
Note that using this property puts the foreign key on the inverse table to the previous example, so in this case the foreign key column is stored in the
nose
table inside a column called
face_id
. Also,
hasOne
only works with bidirectional relationships.
Finally, it's a good idea to add a unique constraint on one side of the one-to-one relationship:
class Face {
static hasOne = [nose:Nose] static constraints = {
nose unique: true
}
}
Controlling the ends of the association
Occasionally you may find yourself with domain classes that have multiple properties of the same type. They may even be self-referential, i.e. the association property has the same type as the domain class it's in. Such situations can cause problems because Grails may guess incorrectly the type of the association. Consider this simple class:
class Person {
String name
Person parent static belongsTo = [ supervisor: Person ] static constraints = { supervisor nullable: true }
}
As far as Grails is concerned, the
parent
and
supervisor
properties are two directions of the same association. So when you set the
parent
property on a
Person
instance, Grails will automatically set the
supervisor
property on the other
Person
instance. This may be what you want, but if you look at the class, what we in fact have are two unidirectional relationships.
To guide Grails to the correct mapping, you can tell it that a particular association is unidirectional through the
mappedBy
property:
class Person {
String name
Person parent static belongsTo = [ supervisor: Person ] static mappedBy = [ supervisor: "none", parent: "none" ] static constraints = { supervisor nullable: true }
}
You can also replace "none" with any property name of the target class. And of course this works for normal domain classes too, not just self-referential ones. Nor is the
mappedBy
property limited to many-to-one and one-to-one associations: it also works for one-to-many and many-to-many associations as you'll see in the next section.
If you have a property called "none" on your domain class, this approach won't work currently! The "none" property will be treated as the reverse direction of the association (or the "back reference"). Fortunately, "none" is not a common domain class property name.
6.2.1.2 One-to-many
A one-to-many relationship is when one class, example
Author
, has many instances of another class, example
Book
. With Grails you define such a relationship with the
hasMany
setting:
class Author {
static hasMany = [books: Book] String name
}
class Book {
String title
}
In this case we have a unidirectional one-to-many. Grails will, by default, map this kind of relationship with a join table.
The ORM DSL allows mapping unidirectional relationships using a foreign key association instead
Grails will automatically inject a property of type
java.util.Set
into the domain class based on the
hasMany
setting. This can be used to iterate over the collection:
def a = Author.get(1)for (book in a.books) {
println book.title
}
The default fetch strategy used by Grails is "lazy", which means that the collection will be lazily initialized on first access. This can lead to the n+1 problem if you are not careful.If you need "eager" fetching you can use the ORM DSL or specify eager fetching as part of a query
The default cascading behaviour is to cascade saves and updates, but not deletes unless a
belongsTo
is also specified:
class Author {
static hasMany = [books: Book] String name
}
class Book {
static belongsTo = [author: Author]
String title
}
If you have two properties of the same type on the many side of a one-to-many you have to use
mappedBy
to specify which the collection is mapped:
class Airport {
static hasMany = [flights: Flight]
static mappedBy = [flights: "departureAirport"]
}
class Flight {
Airport departureAirport
Airport destinationAirport
}
This is also true if you have multiple collections that map to different properties on the many side:
class Airport {
static hasMany = [outboundFlights: Flight, inboundFlights: Flight]
static mappedBy = [outboundFlights: "departureAirport",
inboundFlights: "destinationAirport"]
}
class Flight {
Airport departureAirport
Airport destinationAirport
}
6.2.1.3 Many-to-many
Grails supports many-to-many relationships by defining a
hasMany
on both sides of the relationship and having a
belongsTo
on the owned side of the relationship:
class Book {
static belongsTo = Author
static hasMany = [authors:Author]
String title
}
class Author {
static hasMany = [books:Book]
String name
}
Grails maps a many-to-many using a join table at the database level. The owning side of the relationship, in this case
Author
, takes responsibility for persisting the relationship and is the only side that can cascade saves across.
For example this will work and cascade saves:
new Author(name:"Stephen King")
.addToBooks(new Book(title:"The Stand"))
.addToBooks(new Book(title:"The Shining"))
.save()
However this will only save the
Book
and not the authors!
new Book(name:"Groovy in Action")
.addToAuthors(new Author(name:"Dierk Koenig"))
.addToAuthors(new Author(name:"Guillaume Laforge"))
.save()
This is the expected behaviour as, just like Hibernate, only one side of a many-to-many can take responsibility for managing the relationship.
Grails' Scaffolding feature does not currently support many-to-many relationship and hence you must write the code to manage the relationship yourself
6.2.1.4 Basic Collection Types
As well as associations between different domain classes, GORM also supports mapping of basic collection types.
For example, the following class creates a
nicknames
association that is a
Set
of
String
instances:
class Person {
static hasMany = [nicknames: String]
}
GORM will map an association like the above using a join table. You can alter various aspects of how the join table is mapped using the
joinTable
argument:
class Person { static hasMany = [nicknames: String] static mapping = {
hasMany joinTable: [name: 'bunch_o_nicknames',
key: 'person_id',
column: 'nickname',
type: "text"]
}
}
The example above will map to a table that looks like the following:
bunch_o_nicknames Table
---------------------------------------------
| person_id | nickname |
---------------------------------------------
| 1 | Fred |
---------------------------------------------
6.2.2 Composition in GORM
As well as
association, Grails supports the notion of composition. In this case instead of mapping classes onto separate tables a class can be "embedded" within the current table. For example:
class Person {
Address homeAddress
Address workAddress
static embedded = ['homeAddress', 'workAddress']
}class Address {
String number
String code
}
The resulting mapping would looking like this:
If you define the Address
class in a separate Groovy file in the grails-app/domain
directory you will also get an address
table. If you don't want this to happen use Groovy's ability to define multiple classes per file and include the Address
class below the Person
class in the grails-app/domain/Person.groovy
file
6.2.3 Inheritance in GORM
GORM supports inheritance both from abstract base classes and concrete persistent GORM entities. For example:
class Content {
String author
}
class BlogEntry extends Content {
URL url
}
class Book extends Content {
String ISBN
}
class PodCast extends Content {
byte[] audioStream
}
In the above example we have a parent
Content
class and then various child classes with more specific behaviour.
Considerations
At the database level Grails by default uses table-per-hierarchy mapping with a discriminator column called
class
so the parent class (
Content
) and its subclasses (
BlogEntry
,
Book
etc.), share the
same table.
Table-per-hierarchy mapping has a down side in that you
cannot have non-nullable properties with inheritance mapping. An alternative is to use table-per-subclass which can be enabled with the
ORM DSLHowever, excessive use of inheritance and table-per-subclass can result in poor query performance due to the use of outer join queries. In general our advice is if you're going to use inheritance, don't abuse it and don't make your inheritance hierarchy too deep.
Polymorphic Queries
The upshot of inheritance is that you get the ability to polymorphically query. For example using the
list method on the
Content
super class will return all subclasses of
Content
:
def content = Content.list() // list all blog entries, books and podcasts
content = Content.findAllByAuthor('Joe Bloggs') // find all by authordef podCasts = PodCast.list() // list only podcasts
6.2.4 Sets, Lists and Maps
Sets of Objects
By default when you define a relationship with GORM it is a
java.util.Set
which is an unordered collection that cannot contain duplicates. In other words when you have:
class Author {
static hasMany = [books: Book]
}
The books property that GORM injects is a
java.util.Set
. Sets guarantee uniquenes but not order, which may not be what you want. To have custom ordering you configure the Set as a
SortedSet
:
class Author { SortedSet books static hasMany = [books: Book]
}
In this case a
java.util.SortedSet
implementation is used which means you must implement
java.lang.Comparable
in your Book class:
class Book implements Comparable { String title
Date releaseDate = new Date() int compareTo(obj) {
releaseDate.compareTo(obj.releaseDate)
}
}
The result of the above class is that the Book instances in the books collection of the Author class will be ordered by their release date.
Lists of Objects
To keep objects in the order which they were added and to be able to reference them by index like an array you can define your collection type as a
List
:
class Author { List books static hasMany = [books: Book]
}
In this case when you add new elements to the books collection the order is retained in a sequential list indexed from 0 so you can do:
author.books[0] // get the first book
The way this works at the database level is Hibernate creates a
books_idx
column where it saves the index of the elements in the collection to retain this order at the database level.
When using a
List
, elements must be added to the collection before being saved, otherwise Hibernate will throw an exception (
org.hibernate.HibernateException
: null index column for collection):
// This won't work!
def book = new Book(title: 'The Shining')
book.save()
author.addToBooks(book)// Do it this way instead.
def book = new Book(title: 'Misery')
author.addToBooks(book)
author.save()
Bags of Objects
If ordering and uniqueness aren't a concern (or if you manage these explicitly) then you can use the Hibernate
Bag type to represent mapped collections.
The only change required for this is to define the collection type as a
Collection
:
class Author { Collection books static hasMany = [books: Book]
}
Since uniqueness and order aren't managed by Hibernate, adding to or removing from collections mapped as a Bag don't trigger a load of all existing instances from the database, so this approach will perform better and require less memory than using a
Set
or a
List
.
Maps of Objects
If you want a simple map of string/value pairs GORM can map this with the following:
class Author {
Map books // map of ISBN:book names
}def a = new Author()
a.books = ["1590597583":"Grails Book"]
a.save()
In this case the key and value of the map MUST be strings.
If you want a Map of objects then you can do this:
class Book { Map authors static hasMany = [authors: Author]
}def a = new Author(name:"Stephen King")def book = new Book()
book.authors = [stephen:a]
book.save()
The static
hasMany
property defines the type of the elements within the Map. The keys for the map
must be strings.
A Note on Collection Types and Performance
The Java
Set
type doesn't allow duplicates. To ensure uniqueness when adding an entry to a
Set
association Hibernate has to load the entire associations from the database. If you have a large numbers of entries in the association this can be costly in terms of performance.
The same behavior is required for
List
types, since Hibernate needs to load the entire association to maintain order. Therefore it is recommended that if you anticipate a large numbers of records in the association that you make the association bidirectional so that the link can be created on the inverse side. For example consider the following code:
def book = new Book(title:"New Grails Book")
def author = Author.get(1)
book.author = author
book.save()
In this example the association link is being created by the child (Book) and hence it is not necessary to manipulate the collection directly resulting in fewer queries and more efficient code. Given an
Author
with a large number of associated
Book
instances if you were to write code like the following you would see an impact on performance:
def book = new Book(title:"New Grails Book")
def author = Author.get(1)
author.addToBooks(book)
author.save()
You could also model the collection as a Hibernate Bag as described above.
6.3 Persistence Basics
A key thing to remember about Grails is that under the surface Grails is using
Hibernate for persistence. If you are coming from a background of using
ActiveRecord or
iBatis/MyBatis, Hibernate's "session" model may feel a little strange.
Grails automatically binds a Hibernate session to the currently executing request. This lets you use the
save and
delete methods as well as other GORM methods transparently.
Transactional Write-Behind
A useful feature of Hibernate over direct JDBC calls and even other frameworks is that when you call
save or
delete it does not necessarily perform any SQL operations
at that point. Hibernate batches up SQL statements and executes them as late as possible, often at the end of the request when flushing and closing the session. This is typically done for you automatically by Grails, which manages your Hibernate session.
Hibernate caches database updates where possible, only actually pushing the changes when it knows that a flush is required, or when a flush is triggered programmatically. One common case where Hibernate will flush cached updates is when performing queries since the cached information might be included in the query results. But as long as you're doing non-conflicting saves, updates, and deletes, they'll be batched until the session is flushed. This can be a significant performance boost for applications that do a lot of database writes.
Note that flushing is not the same as committing a transaction. If your actions are performed in the context of a transaction, flushing will execute SQL updates but the database will save the changes in its transaction queue and only finalize the updates when the transaction commits.
6.3.1 Saving and Updating
An example of using the
save method can be seen below:
def p = Person.get(1)
p.save()
This save will be not be pushed to the database immediately - it will be pushed when the next flush occurs. But there are occasions when you want to control when those statements are executed or, in Hibernate terminology, when the session is "flushed". To do so you can use the flush argument to the save method:
def p = Person.get(1)
p.save(flush: true)
Note that in this case
all pending SQL statements including previous saves, deletes, etc. will be synchronized with the database. This also lets you catch any exceptions, which is typically useful in highly concurrent scenarios involving
optimistic locking:
def p = Person.get(1)
try {
p.save(flush: true)
}
catch (org.springframework.dao.DataIntegrityViolationException e) {
// deal with exception
}
Another thing to bear in mind is that Grails
validates a domain instance every time you save it. If that validation fails the domain instance will
not be persisted to the database. By default,
save()
will simply return
null
in this case, but if you would prefer it to throw an exception you can use the
failOnError
argument:
def p = Person.get(1)
try {
p.save(failOnError: true)
}
catch (ValidationException e) {
// deal with exception
}
You can even change the default behaviour with a setting in
Config.groovy
, as described in the
section on configuration. Just remember that when you are saving domain instances that have been bound with data provided by the user, the likelihood of validation exceptions is quite high and you won't want those exceptions propagating to the end user.
You can find out more about the subtleties of saving data in
this article - a must read!
6.3.2 Deleting Objects
An example of the
delete method can be seen below:
def p = Person.get(1)
p.delete()
As with saves, Hibernate will use transactional write-behind to perform the delete; to perform the delete in-place you can use the
flush
argument:
def p = Person.get(1)
p.delete(flush: true)
Using the
flush
argument lets you catch any errors that occur during a delete. A common error that may occur is if you violate a database constraint, although this is normally down to a programming or schema error. The following example shows how to catch a
DataIntegrityViolationException
that is thrown when you violate the database constraints:
def p = Person.get(1)try {
p.delete(flush: true)
}
catch (org.springframework.dao.DataIntegrityViolationException e) {
flash.message = "Could not delete person ${p.name}"
redirect(action: "show", id: p.id)
}
Note that Grails does not supply a
deleteAll
method as deleting data is discouraged and can often be avoided through boolean flags/logic.
If you really need to batch delete data you can use the
executeUpdate method to do batch DML statements:
Customer.executeUpdate("delete Customer c where c.name = :oldName",
[oldName: "Fred"])
6.3.3 Understanding Cascading Updates and Deletes
It is critical that you understand how cascading updates and deletes work when using GORM. The key part to remember is the
belongsTo
setting which controls which class "owns" a relationship.
Whether it is a one-to-one, one-to-many or many-to-many, defining
belongsTo
will result in updates cascading from the owning class to its dependant (the other side of the relationship), and for many-/one-to-one and one-to-many relationships deletes will also cascade.
If you
do not define
belongsTo
then no cascades will happen and you will have to manually save each object (except in the case of the one-to-many, in which case saves will cascade automatically if a new instance is in a
hasMany
collection).
Here is an example:
class Airport {
String name
static hasMany = [flights: Flight]
}
class Flight {
String number
static belongsTo = [airport: Airport]
}
If I now create an
Airport
and add some
Flight
s to it I can save the
Airport
and have the updates cascaded down to each flight, hence saving the whole object graph:
new Airport(name: "Gatwick")
.addToFlights(new Flight(number: "BA3430"))
.addToFlights(new Flight(number: "EZ0938"))
.save()
Conversely if I later delete the
Airport
all
Flight
s associated with it will also be deleted:
def airport = Airport.findByName("Gatwick")
airport.delete()
However, if I were to remove
belongsTo
then the above cascading deletion code
would not work. To understand this better take a look at the summaries below that describe the default behaviour of GORM with regards to specific associations. Also read
part 2 of the GORM Gotchas series of articles to get a deeper understanding of relationships and cascading.
Bidirectional one-to-many with belongsTo
class A { static hasMany = [bees: B] }
class B { static belongsTo = [a: A] }
In the case of a bidirectional one-to-many where the many side defines a
belongsTo
then the cascade strategy is set to "ALL" for the one side and "NONE" for the many side.
Unidirectional one-to-many
class A { static hasMany = [bees: B] }
In the case of a unidirectional one-to-many where the many side defines no belongsTo then the cascade strategy is set to "SAVE-UPDATE".
Bidirectional one-to-many, no belongsTo
class A { static hasMany = [bees: B] }
In the case of a bidirectional one-to-many where the many side does not define a
belongsTo
then the cascade strategy is set to "SAVE-UPDATE" for the one side and "NONE" for the many side.
Unidirectional one-to-one with belongsTo
class B { static belongsTo = [a: A] }
In the case of a unidirectional one-to-one association that defines a
belongsTo
then the cascade strategy is set to "ALL" for the owning side of the relationship (A->B) and "NONE" from the side that defines the
belongsTo
(B->A)
Note that if you need further control over cascading behaviour, you can use the
ORM DSL.
6.3.4 Eager and Lazy Fetching
Associations in GORM are by default lazy. This is best explained by example:
class Airport {
String name
static hasMany = [flights: Flight]
}
class Flight {
String number
Location destination
static belongsTo = [airport: Airport]
}
class Location {
String city
String country
}
Given the above domain classes and the following code:
def airport = Airport.findByName("Gatwick")
for (flight in airport.flights) {
println flight.destination.city
}
GORM will execute a single SQL query to fetch the
Airport
instance, another to get its flights, and then 1 extra query for
each iteration over the
flights
association to get the current flight's destination. In other words you get N+1 queries (if you exclude the original one to get the airport).
Configuring Eager Fetching
An alternative approach that avoids the N+1 queries is to use eager fetching, which can be specified as follows:
class Airport {
String name
static hasMany = [flights: Flight]
static mapping = {
flights lazy: false
}
}
In this case the
flights
association will be loaded at the same time as its
Airport
instance, although a second query will be executed to fetch the collection. You can also use
fetch: 'join'
instead of
lazy: false
, in which case GORM will only execute a single query to get the airports and their flights. This works well for single-ended associations, but you need to be careful with one-to-manys. Queries will work as you'd expect right up to the moment you add a limit to the number of results you want. At that point, you will likely end up with fewer results than you were expecting. The reason for this is quite technical but ultimately the problem arises from GORM using a left outer join.
So, the recommendation is currently to use
fetch: 'join'
for single-ended associations and
lazy: false
for one-to-manys.
Be careful how and where you use eager loading because you could load your entire database into memory with too many eager associations. You can find more information on the mapping options in the
section on the ORM DSL.
Using Batch Fetching
Although eager fetching is appropriate for some cases, it is not always desirable. If you made everything eager you could quite possibly load your entire database into memory resulting in performance and memory problems. An alternative to eager fetching is to use batch fetching. You can configure Hibernate to lazily fetch results in "batches". For example:
class Airport {
String name
static hasMany = [flights: Flight]
static mapping = {
flights batchSize: 10
}
}
In this case, due to the
batchSize
argument, when you iterate over the
flights
association, Hibernate will fetch results in batches of 10. For example if you had an
Airport
that had 30 flights, if you didn't configure batch fetching you would get 1 query to fetch the
Airport
and then
30
queries to fetch each flight. With batch fetching you get 1 query to fetch the
Airport
and 3 queries to fetch each
Flight
in batches of 10. In other words, batch fetching is an optimization of the lazy fetching strategy. Batch fetching can also be configured at the class level as follows:
class Flight {
…
static mapping = {
batchSize 10
}
}
Check out
part 3 of the GORM Gotchas series for more in-depth coverage of this tricky topic.
6.3.5 Pessimistic and Optimistic Locking
Optimistic Locking
By default GORM classes are configured for optimistic locking. Optimistic locking is a feature of Hibernate which involves storing a version value in a special
version
column in the database that is incremented after each update.
The
version
column gets read into a
version
property that contains the current versioned state of persistent instance which you can access:
def airport = Airport.get(10)println airport.version
When you perform updates Hibernate will automatically check the version property against the version column in the database and if they differ will throw a
StaleObjectException. This will roll back the transaction if one is active.
This is useful as it allows a certain level of atomicity without resorting to pessimistic locking that has an inherit performance penalty. The downside is that you have to deal with this exception if you have highly concurrent writes. This requires flushing the session:
def airport = Airport.get(10)try {
airport.name = "Heathrow"
airport.save(flush: true)
}
catch (org.springframework.dao.OptimisticLockingFailureException e) {
// deal with exception
}
The way you deal with the exception depends on the application. You could attempt a programmatic merge of the data or go back to the user and ask them to resolve the conflict.
Alternatively, if it becomes a problem you can resort to pessimistic locking.
The version
will only be updated after flushing the session.
Pessimistic Locking
Pessimistic locking is equivalent to doing a SQL "SELECT * FOR UPDATE" statement and locking a row in the database. This has the implication that other read operations will be blocking until the lock is released.
In Grails pessimistic locking is performed on an existing instance with the
lock method:
def airport = Airport.get(10)
airport.lock() // lock for update
airport.name = "Heathrow"
airport.save()
Grails will automatically deal with releasing the lock for you once the transaction has been committed. However, in the above case what we are doing is "upgrading" from a regular SELECT to a SELECT..FOR UPDATE and another thread could still have updated the record in between the call to
get()
and the call to
lock()
.
To get around this problem you can use the static
lock method that takes an id just like
get:
def airport = Airport.lock(10) // lock for update
airport.name = "Heathrow"
airport.save()
In this case only SELECT..FOR UPDATE is issued.
As well as the
lock method you can also obtain a pessimistic locking using queries. For example using a dynamic finder:
def airport = Airport.findByName("Heathrow", [lock: true])
Or using criteria:
def airport = Airport.createCriteria().get {
eq('name', 'Heathrow')
lock true
}
6.3.6 Modification Checking
Once you have loaded and possibly modified a persistent domain class instance, it isn't straightforward to retrieve the original values. If you try to reload the instance using
get Hibernate will return the current modified instance from its Session cache. Reloading using another query would trigger a flush which could cause problems if your data isn't ready to be flushed yet. So GORM provides some methods to retrieve the original values that Hibernate caches when it loads the instance (which it uses for dirty checking).
isDirty
You can use the
isDirty method to check if any field has been modified:
def airport = Airport.get(10)
assert !airport.isDirty()airport.properties = params
if (airport.isDirty()) {
// do something based on changed state
}
isDirty()
does not currently check collection associations, but it does check all other persistent properties and associations.
You can also check if individual fields have been modified:
def airport = Airport.get(10)
assert !airport.isDirty()airport.properties = params
if (airport.isDirty('name')) {
// do something based on changed name
}
getDirtyPropertyNames
You can use the
getDirtyPropertyNames method to retrieve the names of modified fields; this may be empty but will not be null:
def airport = Airport.get(10)
assert !airport.isDirty()airport.properties = params
def modifiedFieldNames = airport.getDirtyPropertyNames()
for (fieldName in modifiedFieldNames) {
// do something based on changed value
}
getPersistentValue
You can use the
getPersistentValue method to retrieve the value of a modified field:
def airport = Airport.get(10)
assert !airport.isDirty()airport.properties = params
def modifiedFieldNames = airport.getDirtyPropertyNames()
for (fieldName in modifiedFieldNames) {
def currentValue = airport."$fieldName"
def originalValue = airport.getPersistentValue(fieldName)
if (currentValue != originalValue) {
// do something based on changed value
}
}
6.4 Querying with GORM
GORM supports a number of powerful ways to query from dynamic finders, to criteria to Hibernate's object oriented query language HQL. Depending on the complexity of the query you have the following options in order of flexibility and power:
- Dynamic Finders
- Where Queries
- Criteria Queries
- Hibernate Query Language (HQL)
In addition, Groovy's ability to manipulate collections with
GPath and methods like sort, findAll and so on combined with GORM results in a powerful combination.
However, let's start with the basics.
Listing instances
Use the
list method to obtain all instances of a given class:
The
list method supports arguments to perform pagination:
def books = Book.list(offset:10, max:20)
as well as sorting:
def books = Book.list(sort:"title", order:"asc")
Here, the
sort
argument is the name of the domain class property that you wish to sort on, and the
order
argument is either
asc
for
ascending or
desc
for
descending.
Retrieval by Database Identifier
The second basic form of retrieval is by database identifier using the
get method:
You can also obtain a list of instances for a set of identifiers using
getAll:
def books = Book.getAll(23, 93, 81)
6.4.1 Dynamic Finders
GORM supports the concept of
dynamic finders. A dynamic finder looks like a static method invocation, but the methods themselves don't actually exist in any form at the code level.
Instead, a method is auto-magically generated using code synthesis at runtime, based on the properties of a given class. Take for example the
Book
class:
class Book {
String title
Date releaseDate
Author author
}
class Author {
String name
}
The
Book
class has properties such as
title
,
releaseDate
and
author
. These can be used by the
findBy and
findAllBy methods in the form of "method expressions":
def book = Book.findByTitle("The Stand")book = Book.findByTitleLike("Harry Pot%")book = Book.findByReleaseDateBetween(firstDate, secondDate)book = Book.findByReleaseDateGreaterThan(someDate)book = Book.findByTitleLikeOrReleaseDateLessThan("%Something%", someDate)
Method Expressions
A method expression in GORM is made up of the prefix such as
findBy followed by an expression that combines one or more properties. The basic form is:
Book.findBy([Property][Comparator][Boolean Operator])?[Property][Comparator]
The tokens marked with a '?' are optional. Each comparator changes the nature of the query. For example:
def book = Book.findByTitle("The Stand")book = Book.findByTitleLike("Harry Pot%")
In the above example the first query is equivalent to equality whilst the latter, due to the
Like
comparator, is equivalent to a SQL
like
expression.
The possible comparators include:
InList
- In the list of given values
LessThan
- less than a given value
LessThanEquals
- less than or equal a give value
GreaterThan
- greater than a given value
GreaterThanEquals
- greater than or equal a given value
Like
- Equivalent to a SQL like expression
Ilike
- Similar to a Like
, except case insensitive
NotEqual
- Negates equality
Between
- Between two values (requires two arguments)
IsNotNull
- Not a null value (doesn't take an argument)
IsNull
- Is a null value (doesn't take an argument)
Notice that the last three require different numbers of method arguments compared to the rest, as demonstrated in the following example:
def now = new Date()
def lastWeek = now - 7
def book = Book.findByReleaseDateBetween(lastWeek, now)books = Book.findAllByReleaseDateIsNull()
books = Book.findAllByReleaseDateIsNotNull()
Boolean logic (AND/OR)
Method expressions can also use a boolean operator to combine two or more criteria:
def books = Book.findAllByTitleLikeAndReleaseDateGreaterThan(
"%Java%", new Date() - 30)
In this case we're using
And
in the middle of the query to make sure both conditions are satisfied, but you could equally use
Or
:
def books = Book.findAllByTitleLikeOrReleaseDateGreaterThan(
"%Java%", new Date() - 30)
You can combine as many criteria as you like, but they must all be combined with
And
or all
Or
. If you need to combine
And
and
Or
or if the number of criteria creates a very long method name, just convert the query to a
Criteria or
HQL query.
Querying Associations
Associations can also be used within queries:
def author = Author.findByName("Stephen King")def books = author ? Book.findAllByAuthor(author) : []
In this case if the
Author
instance is not null we use it in a query to obtain all the
Book
instances for the given
Author
.
Pagination and Sorting
The same pagination and sorting parameters available on the
list method can also be used with dynamic finders by supplying a map as the final parameter:
def books = Book.findAllByTitleLike("Harry Pot%",
[max: 3, offset: 2, sort: "title", order: "desc"])
6.4.2 Where Queries
The
where
method, introduced in Grails 2.0, builds on the support for
Detached Criteria by providing an enhanced, compile-time checked query DSL for common queries. The
where
method is more flexible than dynamic finders, less verbose than criteria and provides a powerful mechanism to compose queries.
Basic Querying
The
where
method accepts a closure that looks very similar to Groovy's regular collection methods. The closure should define the logical criteria in regular Groovy syntax, for example:
def query = Person.where {
firstName == "Bart"
}
Person bart = query.find()
The returned object is a
DetachedCriteria
instance, which means it is not associated with any particular database connection or session. This means you can use the
where
method to define common queries at the class level:
class Person {
static simpsons = where {
lastName == "Simpson"
}
…
}
…
Person.simpsons.each {
println it.firstname
}
Query execution is lazy and only happens upon usage of the
DetachedCriteria instance. If you want to execute a where-style query immediately there are variations of the
findAll
and
find
methods to accomplish this:
def results = Person.findAll {
lastName == "Simpson"
}
def results = Person.findAll(sort:"firstName") {
lastName == "Simpson"
}
Person p = Person.find { firstName == "Bart" }
Each Groovy operator maps onto a regular criteria method. The following table provides a map of Groovy operators to methods:
Operator | Criteria Method | Description |
---|
== | eq | Equal to |
!= | ne | Not equal to |
> | gt | Greater than |
< | lt | Less than |
>= | ge | Greater than or equal to |
<= | le | Less than or equal to |
in | inList | Contained within the given list |
==~ | like | Like a given string |
=~ | ilike | Case insensitive like |
It is possible use regular Groovy comparison operators and logic to formulate complex queries:
def query = Person.where {
(lastName != "Simpson" && firstName != "Fred") || (firstName == "Bart" && age > 9)
}
def results = query.list(sort:"firstName")
The Groovy regex matching operators map onto like and ilike queries unless the expression on the right hand side is a
Pattern
object, in which case they map onto an
rlike
query:
def query = Person.where {
firstName ==~ ~/B.+/
}
Note that rlike
queries are only supported if the underlying database supports regular expressions
A
between
criteria query can be done by combining the
in
keyword with a range:
def query = Person.where {
age in 18..65
}
Finally, you can do
isNull
and
isNotNull
style queries by using
null
with regular comparison operators:
def query = Person.where {
middleName == null
}
Query Composition
Since the return value of the
where
method is a
DetachedCriteria instance you can compose new queries from the original query:
def query = Person.where {
lastName == "Simpson"
}
def bartQuery = query.where {
firstName == "Bart"
}
Person p = bartQuery.find()
Note that you cannot pass a closure defined as a variable into the
where
method unless it has been explicitly cast to a
DetachedCriteria
instance. In other words the following will produce an error:
def callable = {
lastName == "Simpson"
}
def query = Person.where(callable)
The above must be written as follows:
import grails.gorm.DetachedCriteriadef callable = {
lastName == "Simpson"
} as DetachedCriteria<Person>
def query = Person.where(callable)
As you can see the closure definition is cast (using the Groovy
as
keyword) to a
DetachedCriteria instance targeted at the
Person
class.
Conjunction, Disjunction and Negation
As mentioned previously you can combine regular Groovy logical operators (
||
and
&&
) to form conjunctions and disjunctions:
def query = Person.where {
(lastName != "Simpson" && firstName != "Fred") || (firstName == "Bart" && age > 9)
}
You can also negate a logical comparison using
!
:
def query = Person.where {
firstName == "Fred" && !(lastName == 'Simpson')
}
Property Comparison Queries
If you use a property name on both the left hand and right side of a comparison expression then the appropriate property comparison criteria is automatically used:
def query = Person.where {
firstName == lastName
}
The following table described how each comparison operator maps onto each criteria property comparison method:
Operator | Criteria Method | Description |
---|
== | eqProperty | Equal to |
!= | neProperty | Not equal to |
> | gtProperty | Greater than |
< | ltProperty | Less than |
>= | geProperty | Greater than or equal to |
<= | leProperty | Less than or equal to |
Querying Associations
Associations can be queried by using the dot operator to specify the property name of the association to be queried:
def query = Pet.where {
owner.firstName == "Joe" || owner.firstName == "Fred"
}
You can group multiple criterion inside a closure method call where the name of the method matches the association name:
def query = Person.where {
pets { name == "Jack" || name == "Joe" }
}
This technique can be combined with other top-level criteria:
def query = Person.where {
pets { name == "Jack" } || firstName == "Ed"
}
For collection associations it is possible to apply queries to the size of the collection:
def query = Person.where {
pets.size() == 2
}
The following table shows which operator maps onto which criteria method for each size() comparison:
Operator | Criteria Method | Description |
---|
== | sizeEq | The collection size is equal to |
!= | sizeNe | The collection size is not equal to |
> | sizeGt | The collection size is greater than |
< | sizeLt | The collection size is less than |
>= | sizeGe | The collection size is greater than or equal to |
<= | sizeLe | The collection size is less than or equal to |
Subqueries
It is possible to execute subqueries within where queries. For example to find all the people older than the average age the following query can be used:
final query = Person.where {
age > avg(age)
}
The following table lists the possible subqueries:
Method | Description |
---|
avg | The average of all values |
sum | The sum of all values |
max | The maximum value |
min | The minimum value |
count | The count of all values |
property | Retrieves a property of the resulting entities |
You can apply additional criteria to any subquery by using the
of
method and passing in a closure containing the criteria:
def query = Person.where {
age > avg(age).of { lastName == "Simpson" } && firstName == "Homer"
}
Since the
property
subquery returns multiple results, the criterion used compares all results. For example the following query will find all people younger than people with the surname "Simpson":
Person.where {
age < property(age).of { lastName == "Simpson" }
}
Other Functions
There are several functions available to you within the context of a query. These are summarized in the table below:
Method | Description |
---|
second | The second of a date property |
minute | The minute of a date property |
hour | The hour of a date property |
day | The day of the month of a date property |
month | The month of a date property |
year | The year of a date property |
lower | Converts a string property to upper case |
upper | Converts a string property to lower case |
length | The length of a string property |
trim | Trims a string property |
Currently functions can only be applied to properties or associations of domain classes. You cannot, for example, use a function on a result of a subquery.
For example the following query can be used to find all pet's born in 2011:
def query = Pet.where {
year(birthDate) == 2011
}
You can also apply functions to associations:
def query = Person.where {
year(pets.birthDate) == 2009
}
Batch Updates and Deletes
Since each
where
method call returns a
DetachedCriteria instance, you can use
where
queries to execute batch operations such as batch updates and deletes. For example, the following query will update all people with the surname "Simpson" to have the surname "Bloggs":
def query = Person.where {
lastName == 'Simpson'
}
int total = query.updateAll(lastName:"Bloggs")
Note that one limitation with regards to batch operations is that join queries (queries that query associations) are not allowed.
To batch delete records you can use the
deleteAll
method:
def query = Person.where {
lastName == 'Simpson'
}
int total = query.deleteAll()
6.4.3 Criteria
Criteria is an advanced way to query that uses a Groovy builder to construct potentially complex queries. It is a much better approach than building up query strings using a
StringBuffer
.
Criteria can be used either with the
createCriteria or
withCriteria methods. The builder uses Hibernate's Criteria API. The nodes on this builder map the static methods found in the
Restrictions class of the Hibernate Criteria API. For example:
def c = Account.createCriteria()
def results = c {
between("balance", 500, 1000)
eq("branch", "London")
or {
like("holderFirstName", "Fred%")
like("holderFirstName", "Barney%")
}
maxResults(10)
order("holderLastName", "desc")
}
This criteria will select up to 10
Account
objects in a List matching the following criteria:
balance
is between 500 and 1000
branch
is 'London'
holderFirstName
starts with 'Fred' or 'Barney'
The results will be sorted in descending order by
holderLastName
.
If no records are found with the above criteria, an empty List is returned.
Conjunctions and Disjunctions
As demonstrated in the previous example you can group criteria in a logical OR using an
or { }
block:
or {
between("balance", 500, 1000)
eq("branch", "London")
}
This also works with logical AND:
and {
between("balance", 500, 1000)
eq("branch", "London")
}
And you can also negate using logical NOT:
not {
between("balance", 500, 1000)
eq("branch", "London")
}
All top level conditions are implied to be AND'd together.
Querying Associations
Associations can be queried by having a node that matches the property name. For example say the
Account
class had many
Transaction
objects:
class Account {
…
static hasMany = [transactions: Transaction]
…
}
We can query this association by using the property name
transactions
as a builder node:
def c = Account.createCriteria()
def now = new Date()
def results = c.list {
transactions {
between('date', now - 10, now)
}
}
The above code will find all the
Account
instances that have performed
transactions
within the last 10 days.
You can also nest such association queries within logical blocks:
def c = Account.createCriteria()
def now = new Date()
def results = c.list {
or {
between('created', now - 10, now)
transactions {
between('date', now - 10, now)
}
}
}
Here we find all accounts that have either performed transactions in the last 10 days OR have been recently created in the last 10 days.
Querying with Projections
Projections may be used to customise the results. Define a "projections" node within the criteria builder tree to use projections. There are equivalent methods within the projections node to the methods found in the Hibernate
Projections class:
def c = Account.createCriteria()def numberOfBranches = c.get {
projections {
countDistinct('branch')
}
}
When multiple fields are specified in the projection, a List of values will be returned. A single value will be returned otherwise.
SQL Projections
The criteria DSL provides access to Hibernate's SQL projection API.
// Box is a domain class…
class Box {
int width
int height
}
// Use SQL projections to retrieve the perimeter and area of all of the Box instances…
def c = Box.createCriteria()def results = c.list {
projections {
sqlProjection '(2 * (width + height)) as perimeter, (width * height) as area', ['perimeter', 'area'], [INTEGER, INTEGER]
}
}
The first argument to the
sqlProjection
method is the SQL which defines the projections. The second argument is a list of
Strings which represent column aliases corresponding to the projected values expressed in the SQL. The third argument
is a list of
org.hibernate.type.Type
instances which correspond to the projected values expressed in the SQL. The API
supports all
org.hibernate.type.Type
objects but constants like INTEGER, LONG, FLOAT etc. are provided by the DSL which
correspond to all of the types defined in
org.hibernate.type.StandardBasicTypes
.
Consider that the following table represents the data in the
BOX
table.
The query above would return results like this:
[[18, 14], [20, 16], [22, 18], [26, 36]]
Each of the inner lists contains the 2 projected values for each
Box
, perimeter and area.
Note that if there are other references in scope wherever your criteria query is expressed that have names that conflict
with any of the type constants described above, the code in your criteria will refer to those references, not the type
constants provided by the DSL. In the unlikely event of that happening you can disambiguate the conflict by referring
to the fully qualified Hibernate type. For example StandardBasicTypes.INTEGER
instead of INTEGER
.
If only 1 value is being projected, the alias and the type do not need to be included in a list.
def results = c.list {
projections {
sqlProjection 'sum(width * height) as totalArea', 'totalArea', INTEGER
}
}
That query would return a single result with the value of 84 as the total area of all of the
Box
instances.
The DSL supports grouped projections with the
sqlGroupProjection
method.
def results = c.list {
projections {
sqlGroupProjection 'width, sum(height) as combinedHeightsForThisWidth', 'width', ['width', 'combinedHeightsForThisWidth'], [INTEGER, INTEGER]
}
}
The first argument to the
sqlProjection
method is the SQL which defines the projections. The second argument represents the
group by clause that should be part of the query. That string may be single column name or a comma separated list of column
names. The third argument is a list of
Strings which represent column aliases corresponding to the projected values expressed in the SQL. The fourth argument
is a list of
org.hibernate.type.Type
instances which correspond to the projected values expressed in the SQL.
The query above is projecting the combined heights of boxes grouped by width and would return results that look like this:
Each of the inner lists contains 2 values. The first value is a box width and the second value is the sum of the heights
of all of the boxes which have that width.
Using SQL Restrictions
You can access Hibernate's SQL Restrictions capabilities.
def c = Person.createCriteria()def peopleWithShortFirstNames = c.list {
sqlRestriction "char_length(first_name) <= 4"
}
SQL Restrictions may be parameterized to deal with SQL injection vulnerabilities related to dynamic restrictions.
def c = Person.createCriteria()def peopleWithShortFirstNames = c.list {
sqlRestriction "char_length(first_name) < ? AND char_length(first_name) > ?", [maxValue, minValue]
}
Note that the parameter there is SQL. The first_name
attribute referenced in the example refers to the persistence model, not the object model like in HQL queries. The Person
property named firstName
is mapped to the first_name
column in the database and you must refer to that in the sqlRestriction
string.Also note that the SQL used here is not necessarily portable across databases.
Using Scrollable Results
You can use Hibernate's
ScrollableResults feature by calling the scroll method:
def results = crit.scroll {
maxResults(10)
}
def f = results.first()
def l = results.last()
def n = results.next()
def p = results.previous()def future = results.scroll(10)
def accountNumber = results.getLong('number')
To quote the documentation of Hibernate ScrollableResults:
A result iterator that allows moving around within the results by arbitrary increments. The Query / ScrollableResults pattern is very similar to the JDBC PreparedStatement/ ResultSet pattern and the semantics of methods of this interface are similar to the similarly named methods on ResultSet.
Contrary to JDBC, columns of results are numbered from zero.
Setting properties in the Criteria instance
If a node within the builder tree doesn't match a particular criterion it will attempt to set a property on the Criteria object itself. This allows full access to all the properties in this class. This example calls
setMaxResults
and
setFirstResult
on the
Criteria instance:
import org.hibernate.FetchMode as FM
…
def results = c.list {
maxResults(10)
firstResult(50)
fetchMode("aRelationship", FM.JOIN)
}
Querying with Eager Fetching
In the section on
Eager and Lazy Fetching we discussed how to declaratively specify fetching to avoid the N+1 SELECT problem. However, this can also be achieved using a criteria query:
def criteria = Task.createCriteria()
def tasks = criteria.list{
eq "assignee.id", task.assignee.id
join 'assignee'
join 'project'
order 'priority', 'asc'
}
Notice the usage of the
join
method: it tells the criteria API to use a
JOIN
to fetch the named associations with the
Task
instances. It's probably best not to use this for one-to-many associations though, because you will most likely end up with duplicate results. Instead, use the 'select' fetch mode:
import org.hibernate.FetchMode as FM
…
def results = Airport.withCriteria {
eq "region", "EMEA"
fetchMode "flights", FM.SELECT
}
Although this approach triggers a second query to get the
flights
association, you will get reliable results - even with the
maxResults
option.
fetchMode
and join
are general settings of the query and can only be specified at the top-level, i.e. you cannot use them inside projections or association constraints.
An important point to bear in mind is that if you include associations in the query constraints, those associations will automatically be eagerly loaded. For example, in this query:
def results = Airport.withCriteria {
eq "region", "EMEA"
flights {
like "number", "BA%"
}
}
the
flights
collection would be loaded eagerly via a join even though the fetch mode has not been explicitly set.
Method Reference
If you invoke the builder with no method name such as:
The build defaults to listing all the results and hence the above is equivalent to:
Method | Description |
---|
list | This is the default method. It returns all matching rows. |
get | Returns a unique result set, i.e. just one row. The criteria has to be formed that way, that it only queries one row. This method is not to be confused with a limit to just the first row. |
scroll | Returns a scrollable result set. |
listDistinct | If subqueries or associations are used, one may end up with the same row multiple times in the result set, this allows listing only distinct entities and is equivalent to DISTINCT_ROOT_ENTITY of the CriteriaSpecification class. |
count | Returns the number of matching rows. |
6.4.4 Detached Criteria
Detached Criteria are criteria queries that are not associated with any given database session/connection. Supported since Grails 2.0, Detached Criteria queries have many uses including allowing you to create common reusable criteria queries, execute subqueries and execute batch updates/deletes.
Building Detached Criteria Queries
The primary point of entry for using the Detached Criteria is the
grails.gorm.DetachedCriteria
class which accepts a domain class as the only argument to its constructor:
import grails.gorm.*
…
def criteria = new DetachedCriteria(Person)
Once you have obtained a reference to a detached criteria instance you can execute
where queries or criteria queries to build up the appropriate query. To build a normal criteria query you can use the
build
method:
def criteria = new DetachedCriteria(Person).build {
eq 'lastName', 'Simpson'
}
Note that methods on the
DetachedCriteria
instance
do not mutate the original object but instead return a new query. In other words, you have to use the return value of the
build
method to obtain the mutated criteria object:
def criteria = new DetachedCriteria(Person).build {
eq 'lastName', 'Simpson'
}
def bartQuery = criteria.build {
eq 'firstName', 'Bart'
}
Executing Detached Criteria Queries
Unlike regular criteria, Detached Criteria are lazy, in that no query is executed at the point of definition. Once a Detached Criteria query has been constructed then there are a number of useful query methods which are summarized in the table below:
Method | Description |
---|
list | List all matching entities |
get | Return a single matching result |
count | Count all matching records |
exists | Return true if any matching records exist |
deleteAll | Delete all matching records |
updateAll(Map) | Update all matching records with the given properties |
As an example the following code will list the first 4 matching records sorted by the
firstName
property:
def criteria = new DetachedCriteria(Person).build {
eq 'lastName', 'Simpson'
}
def results = criteria.list(max:4, sort:"firstName")
You can also supply additional criteria to the list method:
def results = criteria.list(max:4, sort:"firstName") {
gt 'age', 30
}
To retrieve a single result you can use the
get
or
find
methods (which are synonyms):
Person p = criteria.find() // or criteria.get()
The
DetachedCriteria
class itself also implements the
Iterable
interface which means that it can be treated like a list:
def criteria = new DetachedCriteria(Person).build {
eq 'lastName', 'Simpson'
}
criteria.each {
println it.firstName
}
In this case the query is only executed when the
each
method is called. The same applies to all other Groovy collection iteration methods.
You can also execute dynamic finders on
DetachedCriteria
just like on domain classes. For example:
def criteria = new DetachedCriteria(Person).build {
eq 'lastName', 'Simpson'
}
def bart = criteria.findByFirstName("Bart")
Using Detached Criteria for Subqueries
Within the context of a regular criteria query you can use
DetachedCriteria
to execute subquery. For example if you want to find all people who are older than the average age the following query will accomplish that:
def results = Person.withCriteria {
gt "age", new DetachedCriteria(Person).build {
projections {
avg "age"
}
}
order "firstName"
}
Notice that in this case the subquery class is the same as the original criteria query class (ie.
Person
) and hence the query can be shortened to:
def results = Person.withCriteria {
gt "age", {
projections {
avg "age"
}
}
order "firstName"
}
If the subquery class differs from the original criteria query then you will have to use the original syntax.
In the previous example the projection ensured that only a single result was returned (the average age). If your subquery returns multiple results then there are different criteria methods that need to be used to compare the result. For example to find all the people older than the ages 18 to 65 a
gtAll
query can be used:
def results = Person.withCriteria {
gtAll "age", {
projections {
property "age"
}
between 'age', 18, 65
} order "firstName"
}
The following table summarizes criteria methods for operating on subqueries that return multiple results:
Method | Description |
---|
gtAll | greater than all subquery results |
geAll | greater than or equal to all subquery results |
ltAll | less than all subquery results |
leAll | less than or equal to all subquery results |
eqAll | equal to all subquery results |
neAll | not equal to all subquery results |
Batch Operations with Detached Criteria
The
DetachedCriteria
class can be used to execute batch operations such as batch updates and deletes. For example, the following query will update all people with the surname "Simpson" to have the surname "Bloggs":
def criteria = new DetachedCriteria(Person).build {
eq 'lastName', 'Simpson'
}
int total = criteria.updateAll(lastName:"Bloggs")
Note that one limitation with regards to batch operations is that join queries (queries that query associations) are not allowed within the DetachedCriteria
instance.
To batch delete records you can use the
deleteAll
method:
def criteria = new DetachedCriteria(Person).build {
eq 'lastName', 'Simpson'
}
int total = criteria.deleteAll()
6.4.5 Hibernate Query Language (HQL)
GORM classes also support Hibernate's query language HQL, a very complete reference for which can be found
in the Hibernate documentation of the Hibernate documentation.
GORM provides a number of methods that work with HQL including
find,
findAll and
executeQuery. An example of a query can be seen below:
def results =
Book.findAll("from Book as b where b.title like 'Lord of the%'")
Positional and Named Parameters
In this case the value passed to the query is hard coded, however you can equally use positional parameters:
def results =
Book.findAll("from Book as b where b.title like ?", ["The Shi%"])
def author = Author.findByName("Stephen King")
def books = Book.findAll("from Book as book where book.author = ?",
[author])
Or even named parameters:
def results =
Book.findAll("from Book as b " +
"where b.title like :search or b.author like :search",
[search: "The Shi%"])
def author = Author.findByName("Stephen King")
def books = Book.findAll("from Book as book where book.author = :author",
[author: author])
Multiline Queries
Use the line continuation character to separate the query across multiple lines:
def results = Book.findAll("\
from Book as b, \
Author as a \
where b.author = a and a.surname = ?", ['Smith'])
Triple-quoted Groovy multiline Strings will NOT work with HQL queries.
Pagination and Sorting
You can also perform pagination and sorting whilst using HQL queries. To do so simply specify the pagination options as a Map at the end of the method call and include an "ORDER BY" clause in the HQL:
def results =
Book.findAll("from Book as b where " +
"b.title like 'Lord of the%' " +
"order by b.title asc",
[max: 10, offset: 20])
6.5 Advanced GORM Features
The following sections cover more advanced usages of GORM including caching, custom mapping and events.
6.5.1 Events and Auto Timestamping
GORM supports the registration of events as methods that get fired when certain events occurs such as deletes, inserts and updates. The following is a list of supported events:
beforeInsert
- Executed before an object is initially persisted to the database
beforeUpdate
- Executed before an object is updated
beforeDelete
- Executed before an object is deleted
beforeValidate
- Executed before an object is validated
afterInsert
- Executed after an object is persisted to the database
afterUpdate
- Executed after an object has been updated
afterDelete
- Executed after an object has been deleted
onLoad
- Executed when an object is loaded from the database
To add an event simply register the relevant closure with your domain class.
Do not attempt to flush the session within an event (such as with obj.save(flush:true)). Since events are fired during flushing this will cause a StackOverflowError.
Event types
The beforeInsert event
Fired before an object is saved to the database
class Person {
private static final Date NULL_DATE = new Date(0) String firstName
String lastName
Date signupDate = NULL_DATE def beforeInsert() {
if (signupDate == NULL_DATE) {
signupDate = new Date()
}
}
}
The beforeUpdate event
Fired before an existing object is updated
class Person { def securityService String firstName
String lastName
String lastUpdatedBy static constraints = {
lastUpdatedBy nullable: true
} def beforeUpdate() {
lastUpdatedBy = securityService.currentAuthenticatedUsername()
}
}
The beforeDelete event
Fired before an object is deleted.
class Person {
String name def beforeDelete() {
ActivityTrace.withNewSession {
new ActivityTrace(eventName: "Person Deleted", data: name).save()
}
}
}
Notice the usage of
withNewSession
method above. Since events are triggered whilst Hibernate is flushing using persistence methods like
save()
and
delete()
won't result in objects being saved unless you run your operations with a new
Session
.
Fortunately the
withNewSession
method lets you share the same transactional JDBC connection even though you're using a different underlying
Session
.
The beforeValidate event
Fired before an object is validated.
class Person {
String name static constraints = {
name size: 5..45
} def beforeValidate() {
name = name?.trim()
}
}
The
beforeValidate
method is run before any validators are run.
Validation may run more often than you think. It is triggered by the validate()
and save()
methods as you'd expect, but it is also typically triggered just before the view is rendered as well. So when writing beforeValidate()
implementations, make sure that they can handle being called multiple times with the same property values.
GORM supports an overloaded version of
beforeValidate
which accepts a
List
parameter which may include
the names of the properties which are about to be validated. This version of
beforeValidate
will be called
when the
validate
method has been invoked and passed a
List
of property names as an argument.
class Person {
String name
String town
Integer age static constraints = {
name size: 5..45
age range: 4..99
} def beforeValidate(List propertiesBeingValidated) {
// do pre validation work based on propertiesBeingValidated
}
}def p = new Person(name: 'Jacob Brown', age: 10)
p.validate(['age', 'name'])
Note that when validate
is triggered indirectly because of a call to the save
method that
the validate
method is being invoked with no arguments, not a List
that includes all of
the property names.
Either or both versions of
beforeValidate
may be defined in a domain class. GORM will
prefer the
List
version if a
List
is passed to
validate
but will fall back on the
no-arg version if the
List
version does not exist. Likewise, GORM will prefer the
no-arg version if no arguments are passed to
validate
but will fall back on the
List
version if the no-arg version does not exist. In that case,
null
is passed to
beforeValidate
.
The onLoad/beforeLoad event
Fired immediately before an object is loaded from the database:
class Person {
String name
Date dateCreated
Date lastUpdated def onLoad() {
log.debug "Loading ${id}"
}
}
beforeLoad()
is effectively a synonym for
onLoad()
, so only declare one or the other.
The afterLoad event
Fired immediately after an object is loaded from the database:
class Person {
String name
Date dateCreated
Date lastUpdated def afterLoad() {
name = "I'm loaded"
}
}
Custom Event Listeners
As of Grails 2.0 there is a new API for plugins and applications to register and listen for persistence events. This API is not tied to Hibernate and also works for other persistence plugins such as the
MongoDB plugin for GORM.
To use this API you need to subclass
AbstractPersistenceEventListener
(in package
org.grails.datastore.mapping.engine.event ) and implement the methods
onPersistenceEvent
and
supportsEventType
. You also must provide a reference to the datastore to the listener. The simplest possible implementation can be seen below:
public MyPersistenceListener(final Datastore datastore) {
super(datastore)
}@Override
protected void onPersistenceEvent(final AbstractPersistenceEvent event) {
switch(event.eventType) {
case PreInsert:
println "PRE INSERT ${event.entityObject}"
break
case PostInsert:
println "POST INSERT ${event.entityObject}"
break
case PreUpdate:
println "PRE UPDATE ${event.entityObject}"
break;
case PostUpdate:
println "POST UPDATE ${event.entityObject}"
break;
case PreDelete:
println "PRE DELETE ${event.entityObject}"
break;
case PostDelete:
println "POST DELETE ${event.entityObject}"
break;
case PreLoad:
println "PRE LOAD ${event.entityObject}"
break;
case PostLoad:
println "POST LOAD ${event.entityObject}"
break;
}
}@Override
public boolean supportsEventType(Class<? extends ApplicationEvent> eventType) {
return true
}
The
AbstractPersistenceEvent
class has many subclasses (
PreInsertEvent
,
PostInsertEvent
etc.) that provide further information specific to the event. A
cancel()
method is also provided on the event which allows you to veto an insert, update or delete operation.
Once you have created your event listener you need to register it with the
ApplicationContext
. This can be done in
BootStrap.groovy
:
def init = {
application.mainContext.eventTriggeringInterceptor.datastores.each { k, datastore ->
applicationContext.addApplicationListener new MyPersistenceListener(datastore)
}
}
or use this in a plugin:
def doWithApplicationContext = { applicationContext ->
application.mainContext.eventTriggeringInterceptor.datastores.each { k, datastore ->
applicationContext.addApplicationListener new MyPersistenceListener(datastore)
}
}
Hibernate Events
It is generally encouraged to use the non-Hibernate specific API described above, but if you need access to more detailed Hibernate events then you can define custom Hibernate-specific event listeners.
You can also register event handler classes in an application's
grails-app/conf/spring/resources.groovy
or in the
doWithSpring
closure in a plugin descriptor by registering a Spring bean named
hibernateEventListeners
. This bean has one property,
listenerMap
which specifies the listeners to register for various Hibernate events.
The values of the Map are instances of classes that implement one or more Hibernate listener interfaces. You can use one class that implements all of the required interfaces, or one concrete class per interface, or any combination. The valid Map keys and corresponding interfaces are listed here:
For example, you could register a class
AuditEventListener
which implements
PostInsertEventListener
,
PostUpdateEventListener
, and
PostDeleteEventListener
using the following in an application:
beans = { auditListener(AuditEventListener) hibernateEventListeners(HibernateEventListeners) {
listenerMap = ['post-insert': auditListener,
'post-update': auditListener,
'post-delete': auditListener]
}
}
or use this in a plugin:
def doWithSpring = { auditListener(AuditEventListener) hibernateEventListeners(HibernateEventListeners) {
listenerMap = ['post-insert': auditListener,
'post-update': auditListener,
'post-delete': auditListener]
}
}
Automatic timestamping
If you define a
dateCreated
property it will be set to the current date for you when you create new instances. Likewise, if you define a
lastUpdated
property it will be automatically be updated for you when you change persistent instances.
If this is not the behaviour you want you can disable this feature with:
class Person {
Date dateCreated
Date lastUpdated
static mapping = {
autoTimestamp false
}
}
If you have nullable: false
constraints on either dateCreated
or lastUpdated
, your domain instances will fail validation - probably not what you want. Omit constraints from these properties unless you disable automatic timestamping.
6.5.2 Custom ORM Mapping
Grails domain classes can be mapped onto many legacy schemas with an Object Relational Mapping DSL (domain specific language). The following sections takes you through what is possible with the ORM DSL.
None of this is necessary if you are happy to stick to the conventions defined by GORM for table names, column names and so on. You only needs this functionality if you need to tailor the way GORM maps onto legacy schemas or configures caching
Custom mappings are defined using a static
mapping
block defined within your domain class:
class Person {
…
static mapping = {
version false
autoTimestamp false
}
}
You can also configure global mappings in Config.groovy (or an external config file) using this setting:
grails.gorm.default.mapping = {
version false
autoTimestamp false
}
It has the same syntax as the standard
mapping
block but it applies to all your domain classes! You can then override these defaults within the
mapping
block of a domain class.
6.5.2.1 Table and Column Names
Table names
The database table name which the class maps to can be customized using the
table
method:
class Person {
…
static mapping = {
table 'people'
}
}
In this case the class would be mapped to a table called
people
instead of the default name of
person
.
Column names
It is also possible to customize the mapping for individual columns onto the database. For example to change the name you can do:
class Person { String firstName static mapping = {
table 'people'
firstName column: 'First_Name'
}
}
Here
firstName
is a dynamic method within the
mapping
Closure that has a single Map parameter. Since its name corresponds to a domain class persistent field, the parameter values (in this case just
"column"
) are used to configure the mapping for that property.
Column type
GORM supports configuration of Hibernate types with the DSL using the type attribute. This includes specifing user types that implement the Hibernate
org.hibernate.usertype.UserType interface, which allows complete customization of how a type is persisted. As an example if you had a
PostCodeType
you could use it as follows:
class Address { String number
String postCode static mapping = {
postCode type: PostCodeType
}
}
Alternatively if you just wanted to map it to one of Hibernate's basic types other than the default chosen by Grails you could use:
class Address { String number
String postCode static mapping = {
postCode type: 'text'
}
}
This would make the
postCode
column map to the default large-text type for the database you're using (for example TEXT or CLOB).
See the Hibernate documentation regarding
Basic Types for further information.
Many-to-One/One-to-One Mappings
In the case of associations it is also possible to configure the foreign keys used to map associations. In the case of a many-to-one or one-to-one association this is exactly the same as any regular column. For example consider the following:
class Person { String firstName
Address address static mapping = {
table 'people'
firstName column: 'First_Name'
address column: 'Person_Address_Id'
}
}
By default the
address
association would map to a foreign key column called
address_id
. By using the above mapping we have changed the name of the foreign key column to
Person_Adress_Id
.
One-to-Many Mapping
With a bidirectional one-to-many you can change the foreign key column used by changing the column name on the many side of the association as per the example in the previous section on one-to-one associations. However, with unidirectional associations the foreign key needs to be specified on the association itself. For example given a unidirectional one-to-many relationship between
Person
and
Address
the following code will change the foreign key in the
address
table:
class Person { String firstName static hasMany = [addresses: Address] static mapping = {
table 'people'
firstName column: 'First_Name'
addresses column: 'Person_Address_Id'
}
}
If you don't want the column to be in the
address
table, but instead some intermediate join table you can use the
joinTable
parameter:
class Person { String firstName static hasMany = [addresses: Address] static mapping = {
table 'people'
firstName column: 'First_Name'
addresses joinTable: [name: 'Person_Addresses',
key: 'Person_Id',
column: 'Address_Id']
}
}
Many-to-Many Mapping
Grails, by default maps a many-to-many association using a join table. For example consider this many-to-many association:
class Group {
…
static hasMany = [people: Person]
}
class Person {
…
static belongsTo = Group
static hasMany = [groups: Group]
}
In this case Grails will create a join table called
group_person
containing foreign keys called
person_id
and
group_id
referencing the
person
and
group
tables. To change the column names you can specify a column within the mappings for each class.
class Group {
…
static mapping = {
people column: 'Group_Person_Id'
}
}
class Person {
…
static mapping = {
groups column: 'Group_Group_Id'
}
}
You can also specify the name of the join table to use:
class Group {
…
static mapping = {
people column: 'Group_Person_Id',
joinTable: 'PERSON_GROUP_ASSOCIATIONS'
}
}
class Person {
…
static mapping = {
groups column: 'Group_Group_Id',
joinTable: 'PERSON_GROUP_ASSOCIATIONS'
}
}
6.5.2.2 Caching Strategy
Setting up caching
Hibernate features a second-level cache with a customizable cache provider. This needs to be configured in the
grails-app/conf/DataSource.groovy
file as follows:
hibernate {
cache.use_second_level_cache=true
cache.use_query_cache=true
cache.provider_class='org.hibernate.cache.EhCacheProvider'
}
You can customize any of these settings, for example to use a distributed caching mechanism.
For further reading on caching and in particular Hibernate's second-level cache, refer to the Hibernate documentation on the subject.
Caching instances
Call the
cache
method in your mapping block to enable caching with the default settings:
class Person {
…
static mapping = {
table 'people'
cache true
}
}
This will configure a 'read-write' cache that includes both lazy and non-lazy properties. You can customize this further:
class Person {
…
static mapping = {
table 'people'
cache usage: 'read-only', include: 'non-lazy'
}
}
Caching associations
As well as the ability to use Hibernate's second level cache to cache instances you can also cache collections (associations) of objects. For example:
class Person { String firstName static hasMany = [addresses: Address] static mapping = {
table 'people'
version false
addresses column: 'Address', cache: true
}
}
class Address {
String number
String postCode
}
This will enable a 'read-write' caching mechanism on the
addresses
collection. You can also use:
cache: 'read-write' // or 'read-only' or 'transactional'
to further configure the cache usage.
Caching Queries
You can cache queries such as dynamic finders and criteria. To do so using a dynamic finder you can pass the
cache
argument:
def person = Person.findByFirstName("Fred", [cache: true])
In order for the results of the query to be cached, you must enable caching in your mapping as discussed in the previous section.
You can also cache criteria queries:
def people = Person.withCriteria {
like('firstName', 'Fr%')
cache true
}
Cache usages
Below is a description of the different cache settings and their usages:
read-only
- If your application needs to read but never modify instances of a persistent class, a read-only cache may be used.
read-write
- If the application needs to update data, a read-write cache might be appropriate.
nonstrict-read-write
- If the application only occasionally needs to update data (ie. if it is very unlikely that two transactions would try to update the same item simultaneously) and strict transaction isolation is not required, a nonstrict-read-write
cache might be appropriate.
transactional
- The transactional
cache strategy provides support for fully transactional cache providers such as JBoss TreeCache. Such a cache may only be used in a JTA environment and you must specify hibernate.transaction.manager_lookup_class
in the grails-app/conf/DataSource.groovy
file's hibernate
config.
6.5.2.3 Inheritance Strategies
By default GORM classes use
table-per-hierarchy
inheritance mapping. This has the disadvantage that columns cannot have a
NOT-NULL
constraint applied to them at the database level. If you would prefer to use a
table-per-subclass
inheritance strategy you can do so as follows:
class Payment {
Integer amount static mapping = {
tablePerHierarchy false
}
}class CreditCardPayment extends Payment {
String cardNumber
}
The mapping of the root
Payment
class specifies that it will not be using
table-per-hierarchy
mapping for all child classes.
6.5.2.4 Custom Database Identity
You can customize how GORM generates identifiers for the database using the DSL. By default GORM relies on the native database mechanism for generating ids. This is by far the best approach, but there are still many schemas that have different approaches to identity.
To deal with this Hibernate defines the concept of an id generator. You can customize the id generator and the column it maps to as follows:
class Person {
…
static mapping = {
table 'people'
version false
id generator: 'hilo',
params: [table: 'hi_value',
column: 'next_value',
max_lo: 100]
}
}
In this case we're using one of Hibernate's built in 'hilo' generators that uses a separate table to generate ids.
For more information on the different Hibernate generators refer to the Hibernate reference documentation
Although you don't typically specify the
id
field (Grails adds it for you) you can still configure its mapping like the other properties. For example to customise the column for the id property you can do:
class Person {
…
static mapping = {
table 'people'
version false
id column: 'person_id'
}
}
6.5.2.5 Composite Primary Keys
GORM supports the concept of composite identifiers (identifiers composed from 2 or more properties). It is not an approach we recommend, but is available to you if you need it:
import org.apache.commons.lang.builder.HashCodeBuilderclass Person implements Serializable { String firstName
String lastName boolean equals(other) {
if (!(other instanceof Person)) {
return false
} other.firstName == firstName && other.lastName == lastName
} int hashCode() {
def builder = new HashCodeBuilder()
builder.append firstName
builder.append lastName
builder.toHashCode()
} static mapping = {
id composite: ['firstName', 'lastName']
}
}
The above will create a composite id of the
firstName
and
lastName
properties of the Person class. To retrieve an instance by id you use a prototype of the object itself:
def p = Person.get(new Person(firstName: "Fred", lastName: "Flintstone"))
println p.firstName
Domain classes mapped with composite primary keys must implement the
Serializable
interface and override the
equals
and
hashCode
methods, using the properties in the composite key for the calculations. The example above uses a
HashCodeBuilder
for convenience but it's fine to implement it yourself.
Another important consideration when using composite primary keys is associations. If for example you have a many-to-one association where the foreign keys are stored in the associated table then 2 columns will be present in the associated table.
For example consider the following domain class:
class Address {
Person person
}
In this case the
address
table will have an additional two columns called
person_first_name
and
person_last_name
. If you wish the change the mapping of these columns then you can do so using the following technique:
class Address {
Person person
static mapping = {
person {
column: "FirstName"
column: "LastName"
}
}
}
6.5.2.6 Database Indices
To get the best performance out of your queries it is often necessary to tailor the table index definitions. How you tailor them is domain specific and a matter of monitoring usage patterns of your queries. With GORM's DSL you can specify which columns are used in which indexes:
class Person {
String firstName
String address
static mapping = {
table 'people'
version false
id column: 'person_id'
firstName column: 'First_Name', index: 'Name_Idx'
address column: 'Address', index: 'Name_Idx,Address_Index'
}
}
Note that you cannot have any spaces in the value of the
index
attribute; in this example
index:'Name_Idx, Address_Index'
will cause an error.
6.5.2.7 Optimistic Locking and Versioning
As discussed in the section on
Optimistic and Pessimistic Locking, by default GORM uses optimistic locking and automatically injects a
version
property into every class which is in turn mapped to a
version
column at the database level.
If you're mapping to a legacy schema that doesn't have version columns (or there's some other reason why you don't want/need this feature) you can disable this with the
version
method:
class Person {
…
static mapping = {
table 'people'
version false
}
}
If you disable optimistic locking you are essentially on your own with regards to concurrent updates and are open to the risk of users losing data (due to data overriding) unless you use pessimistic locking
Version columns types
By default Grails maps the
version
property as a
Long
that gets incremented by one each time an instance is updated. But Hibernate also supports using a
Timestamp
, for example:
import java.sql.Timestampclass Person { …
Timestamp version static mapping = {
table 'people'
}
}
There's a slight risk that two updates occurring at nearly the same time on a fast server can end up with the same timestamp value but this risk is very low. One benefit of using a
Timestamp
instead of a
Long
is that you combine the optimistic locking and last-updated semantics into a single column.
6.5.2.8 Eager and Lazy Fetching
Lazy Collections
As discussed in the section on
Eager and Lazy fetching, GORM collections are lazily loaded by default but you can change this behaviour with the ORM DSL. There are several options available to you, but the most common ones are:
- lazy: false
- fetch: 'join'
and they're used like this:
class Person { String firstName
Pet pet static hasMany = [addresses: Address] static mapping = {
addresses lazy: false
pet fetch: 'join'
}
}
class Address {
String street
String postCode
}
class Pet {
String name
}
The first option,
lazy: false
, ensures that when a
Person
instance is loaded, its
addresses
collection is loaded at the same time with a second SELECT. The second option is basically the same, except the collection is loaded with a JOIN rather than another SELECT. Typically you want to reduce the number of queries, so
fetch: 'join'
is the more appropriate option. On the other hand, it could feasibly be the more expensive approach if your domain model and data result in more and larger results than would otherwise be necessary.
For more advanced users, the other settings available are:
- batchSize: N
- lazy: false, batchSize: N
where N is an integer. These let you fetch results in batches, with one query per batch. As a simple example, consider this mapping for
Person
:
class Person { String firstName
Pet pet static mapping = {
pet batchSize: 5
}
}
If a query returns multiple
Person
instances, then when we access the first
pet
property, Hibernate will fetch that
Pet
plus the four next ones. You can get the same behaviour with eager loading by combining
batchSize
with the
lazy: false
option. You can find out more about these options in the
Hibernate user guide and this
primer on fetching strategies. Note that ORM DSL does not currently support the "subselect" fetching strategy.
Lazy Single-Ended Associations
In GORM, one-to-one and many-to-one associations are by default lazy. Non-lazy single ended associations can be problematic when you load many entities because each non-lazy association will result in an extra SELECT statement. If the associated entities also have non-lazy associations, the number of queries grows significantly!
Use the same technique as for lazy collections to make a one-to-one or many-to-one association non-lazy/eager:
class Person {
String firstName
}
class Address { String street
String postCode static belongsTo = [person: Person] static mapping = {
person lazy: false
}
}
Here we configure GORM to load the associated
Person
instance (through the
person
property) whenever an
Address
is loaded.
Lazy Single-Ended Associations and Proxies
Hibernate uses runtime-generated proxies to facilitate single-ended lazy associations; Hibernate dynamically subclasses the entity class to create the proxy.
Consider the previous example but with a lazily-loaded
person
association: Hibernate will set the
person
property to a proxy that is a subclass of
Person
. When you call any of the getters (except for the
id
property) or setters on that proxy, Hibernate will load the entity from the database.
Unfortunately this technique can produce surprising results. Consider the following example classes:
class Pet {
String name
}
class Dog extends Pet {
}
class Person {
String name
Pet pet
}
and assume that we have a single
Person
instance with a
Dog
as the
pet
. The following code will work as you would expect:
def person = Person.get(1)
assert person.pet instanceof Dog
assert Pet.get(person.petId) instanceof Dog
But this won't:
def person = Person.get(1)
assert person.pet instanceof Dog
assert Pet.list()[0] instanceof Dog
The second assertion fails, and to add to the confusion, this will work:
assert Pet.list()[0] instanceof Dog
What's going on here? It's down to a combination of how proxies work and the guarantees that the Hibernate session makes. When you load the
Person
instance, Hibernate creates a proxy for its
pet
relation and attaches it to the session. Once that happens, whenever you retrieve that
Pet
instance with a query, a
get()
, or the
pet
relation
within the same session , Hibernate gives you the proxy.
Fortunately for us, GORM automatically unwraps the proxy when you use
get()
and
findBy*()
, or when you directly access the relation. That means you don't have to worry at all about proxies in the majority of cases. But GORM doesn't do that for objects returned with a query that returns a list, such as
list()
and
findAllBy*()
. However, if Hibernate hasn't attached the proxy to the session, those queries will return the real instances - hence why the last example works.
You can protect yourself to a degree from this problem by using the
instanceOf
method by GORM:
def person = Person.get(1)
assert Pet.list()[0].instanceOf(Dog)
However, it won't help here if casting is involved. For example, the following code will throw a
ClassCastException
because the first pet in the list is a proxy instance with a class that is neither
Dog
nor a sub-class of
Dog
:
def person = Person.get(1)
Dog pet = Pet.list()[0]
Of course, it's best not to use static types in this situation. If you use an untyped variable for the pet instead, you can access any
Dog
properties or methods on the instance without any problems.
These days it's rare that you will come across this issue, but it's best to be aware of it just in case. At least you will know why such an error occurs and be able to work around it.
6.5.2.9 Custom Cascade Behaviour
As described in the section on
cascading updates, the primary mechanism to control the way updates and deletes cascade from one association to another is the static
belongsTo property.
However, the ORM DSL gives you complete access to Hibernate's
transitive persistence capabilities using the
cascade
attribute.
Valid settings for the cascade attribute include:
merge
- merges the state of a detached association
save-update
- cascades only saves and updates to an association
delete
- cascades only deletes to an association
lock
- useful if a pessimistic lock should be cascaded to its associations
refresh
- cascades refreshes to an association
evict
- cascades evictions (equivalent to discard()
in GORM) to associations if set
all
- cascade all operations to associations
all-delete-orphan
- Applies only to one-to-many associations and indicates that when a child is removed from an association then it should be automatically deleted. Children are also deleted when the parent is.
It is advisable to read the section in the Hibernate documentation on transitive persistence to obtain a better understanding of the different cascade styles and recommendations for their usage
To specify the cascade attribute simply define one or more (comma-separated) of the aforementioned settings as its value:
class Person { String firstName static hasMany = [addresses: Address] static mapping = {
addresses cascade: "all-delete-orphan"
}
}
class Address {
String street
String postCode
}
6.5.2.10 Custom Hibernate Types
You saw in an earlier section that you can use composition (with the
embedded
property) to break a table into multiple objects. You can achieve a similar effect with Hibernate's custom user types. These are not domain classes themselves, but plain Java or Groovy classes. Each of these types also has a corresponding "meta-type" class that implements
org.hibernate.usertype.UserType.
The
Hibernate reference manual has some information on custom types, but here we will focus on how to map them in Grails. Let's start by taking a look at a simple domain class that uses an old-fashioned (pre-Java 1.5) type-safe enum class:
class Book { String title
String author
Rating rating static mapping = {
rating type: RatingUserType
}
}
All we have done is declare the
rating
field the enum type and set the property's type in the custom mapping to the corresponding
UserType
implementation. That's all you have to do to start using your custom type. If you want, you can also use the other column settings such as "column" to change the column name and "index" to add it to an index.
Custom types aren't limited to just a single column - they can be mapped to as many columns as you want. In such cases you explicitly define in the mapping what columns to use, since Hibernate can only use the property name for a single column. Fortunately, Grails lets you map multiple columns to a property using this syntax:
class Book { String title
Name author
Rating rating static mapping = {
author type: NameUserType, {
column name: "first_name"
column name: "last_name"
}
rating type: RatingUserType
}
}
The above example will create "first_name" and "last_name" columns for the
author
property. You'll be pleased to know that you can also use some of the normal column/property mapping attributes in the column definitions. For example:
column name: "first_name", index: "my_idx", unique: true
The column definitions do
not support the following attributes:
type
,
cascade
,
lazy
,
cache
, and
joinTable
.
One thing to bear in mind with custom types is that they define the
SQL types for the corresponding database columns. That helps take the burden of configuring them yourself, but what happens if you have a legacy database that uses a different SQL type for one of the columns? In that case, override the column's SQL type using the
sqlType
attribute:
class Book { String title
Name author
Rating rating static mapping = {
author type: NameUserType, {
column name: "first_name", sqlType: "text"
column name: "last_name", sqlType: "text"
}
rating type: RatingUserType, sqlType: "text"
}
}
Mind you, the SQL type you specify needs to still work with the custom type. So overriding a default of "varchar" with "text" is fine, but overriding "text" with "yes_no" isn't going to work.
6.5.2.11 Derived Properties
A derived property is one that takes its value from a SQL expression, often but not necessarily based on the value of one or more other persistent properties. Consider a Product class like this:
class Product {
Float price
Float taxRate
Float tax
}
If the
tax
property is derived based on the value of
price
and
taxRate
properties then is probably no need to persist the
tax
property. The SQL used to derive the value of a derived property may be expressed in the ORM DSL like this:
class Product {
Float price
Float taxRate
Float tax static mapping = {
tax formula: 'PRICE * TAX_RATE'
}
}
Note that the formula expressed in the ORM DSL is SQL so references to other properties should relate to the persistence model not the object model, which is why the example refers to
PRICE
and
TAX_RATE
instead of
price
and
taxRate
.
With that in place, when a Product is retrieved with something like
Product.get(42)
, the SQL that is generated to support that will look something like this:
select
product0_.id as id1_0_,
product0_.version as version1_0_,
product0_.price as price1_0_,
product0_.tax_rate as tax4_1_0_,
product0_.PRICE * product0_.TAX_RATE as formula1_0_
from
product product0_
where
product0_.id=?
Since the
tax
property is derived at runtime and not stored in the database it might seem that the same effect could be achieved by adding a method like
getTax()
to the
Product
class that simply returns the product of the
taxRate
and
price
properties. With an approach like that you would give up the ability query the database based on the value of the
tax
property. Using a derived property allows exactly that. To retrieve all
Product
objects that have a
tax
value greater than 21.12 you could execute a query like this:
Product.findAllByTaxGreaterThan(21.12)
Derived properties may be referenced in the Criteria API:
Product.withCriteria {
gt 'tax', 21.12f
}
The SQL that is generated to support either of those would look something like this:
select
this_.id as id1_0_,
this_.version as version1_0_,
this_.price as price1_0_,
this_.tax_rate as tax4_1_0_,
this_.PRICE * this_.TAX_RATE as formula1_0_
from
product this_
where
this_.PRICE * this_.TAX_RATE>?
Because the value of a derived property is generated in the database and depends on the execution of SQL code, derived properties may not have GORM constraints applied to them. If constraints are specified for a derived property, they will be ignored.
6.5.2.12 Custom Naming Strategy
By default Grails uses Hibernate's
ImprovedNamingStrategy
to convert domain class Class and field names to SQL table and column names by converting from camel-cased Strings to ones that use underscores as word separators. You can customize these on a per-class basis in the
mapping
closure but if there's a consistent pattern you can specify a different
NamingStrategy
class to use.
Configure the class name to be used in
grails-app/conf/DataSource.groovy
in the
hibernate
section, e.g.
dataSource {
pooled = true
dbCreate = "create-drop"
…
}hibernate {
cache.use_second_level_cache = true
…
naming_strategy = com.myco.myproj.CustomNamingStrategy
}
You can also specify the name of the class and it will be loaded for you:
hibernate {
…
naming_strategy = 'com.myco.myproj.CustomNamingStrategy'
}
A third option is to provide an instance if there is some configuration required beyond calling the default constructor:
hibernate {
…
def strategy = new com.myco.myproj.CustomNamingStrategy()
// configure as needed
naming_strategy = strategy
}
You can use an existing class or write your own, for example one that prefixes table names and column names:
package com.myco.myprojimport org.hibernate.cfg.ImprovedNamingStrategy
import org.hibernate.util.StringHelperclass CustomNamingStrategy extends ImprovedNamingStrategy { String classToTableName(String className) {
"table_" + StringHelper.unqualify(className)
} String propertyToColumnName(String propertyName) {
"col_" + StringHelper.unqualify(propertyName)
}
}
6.5.3 Default Sort Order
You can sort objects using query arguments such as those found in the
list method:
def airports = Airport.list(sort:'name')
However, you can also declare the default sort order for a collection in the mapping:
class Airport {
…
static mapping = {
sort "name"
}
}
The above means that all collections of
Airport
instances will by default be sorted by the airport name. If you also want to change the sort
order , use this syntax:
class Airport {
…
static mapping = {
sort name: "desc"
}
}
Finally, you can configure sorting at the association level:
class Airport {
…
static hasMany = [flights: Flight] static mapping = {
flights sort: 'number', order: 'desc'
}
}
In this case, the
flights
collection will always be sorted in descending order of flight number.
These mappings will not work for default unidirectional one-to-many or many-to-many relationships because they involve a join table. See this issue for more details. Consider using a SortedSet
or queries with sort parameters to fetch the data you need.
6.6 Programmatic Transactions
Grails is built on Spring and uses Spring's Transaction abstraction for dealing with programmatic transactions. However, GORM classes have been enhanced to make this simpler with the
withTransaction method. This method has a single parameter, a Closure, which has a single parameter which is a Spring
TransactionStatus instance.
Here's an example of using
withTransaction
in a controller methods:
def transferFunds() {
Account.withTransaction { status ->
def source = Account.get(params.from)
def dest = Account.get(params.to) def amount = params.amount.toInteger()
if (source.active) {
if (dest.active) {
source.balance -= amount
dest.amount += amount
}
else {
status.setRollbackOnly()
}
}
}
}
In this example we rollback the transaction if the destination account is not active. Also, if an unchecked
Exception
or
Error
(but not a checked
Exception
, even though Groovy doesn't require that you catch checked exceptions) is thrown during the process the transaction will automatically be rolled back.
You can also use "save points" to rollback a transaction to a particular point in time if you don't want to rollback the entire transaction. This can be achieved through the use of Spring's
SavePointManager interface.
The
withTransaction
method deals with the begin/commit/rollback logic for you within the scope of the block.
6.7 GORM and Constraints
Although constraints are covered in the
Validation section, it is important to mention them here as some of the constraints can affect the way in which the database schema is generated.
Where feasible, Grails uses a domain class's constraints to influence the database columns generated for the corresponding domain class properties.
Consider the following example. Suppose we have a domain model with the following properties:
String name
String description
By default, in MySQL, Grails would define these columns as
Column | Data Type |
---|
name | varchar(255) |
description | varchar(255) |
But perhaps the business rules for this domain class state that a description can be up to 1000 characters in length. If that were the case, we would likely define the column as follows
if we were creating the table with an SQL script.
Column | Data Type |
---|
description | TEXT |
Chances are we would also want to have some application-based validation to make sure we don't exceed that 1000 character limit
before we persist any records. In Grails, we achieve this validation with
constraints. We would add the following constraint declaration to the domain class.
static constraints = {
description maxSize: 1000
}
This constraint would provide both the application-based validation we want and it would also cause the schema to be generated as shown above. Below is a description of the other constraints that influence schema generation.
Constraints Affecting String Properties
If either the
maxSize
or the
size
constraint is defined, Grails sets the maximum column length based on the constraint value.
In general, it's not advisable to use both constraints on the same domain class property. However, if both the
maxSize
constraint and the
size
constraint are defined, then Grails sets the column length to the minimum of the
maxSize
constraint and the upper bound of the size constraint. (Grails uses the minimum of the two, because any length that exceeds that minimum will result in a validation error.)
If the
inList
constraint is defined (and the
maxSize
and the
size
constraints are not defined), then Grails sets the maximum column length based on the length of the longest string in the list of valid values. For example, given a list including values "Java", "Groovy", and "C++", Grails would set the column length to 6 (i.e., the number of characters in the string "Groovy").
Constraints Affecting Numeric Properties
If the
max
,
min
, or
range
constraint is defined, Grails attempts to set the column precision based on the constraint value. (The success of this attempted influence is largely dependent on how Hibernate interacts with the underlying DBMS.)
In general, it's not advisable to combine the pair
min
/
max
and
range
constraints together on the same domain class property. However, if both of these constraints is defined, then Grails uses the minimum precision value from the constraints. (Grails uses the minimum of the two, because any length that exceeds that minimum precision will result in a validation error.)
If the scale constraint is defined, then Grails attempts to set the column
scale based on the constraint value. This rule only applies to floating point numbers (i.e.,
java.lang.Float
,
java.Lang.Double
,
java.lang.BigDecimal
, or subclasses of
java.lang.BigDecimal
). The success of this attempted influence is largely dependent on how Hibernate interacts with the underlying DBMS.
The constraints define the minimum/maximum numeric values, and Grails derives the maximum number of digits for use in the precision. Keep in mind that specifying only one of
min
/
max
constraints will not affect schema generation (since there could be large negative value of property with max:100, for example), unless the specified constraint value requires more digits than default Hibernate column precision is (19 at the moment). For example:
someFloatValue max: 1000000, scale: 3
would yield:
someFloatValue DECIMAL(19, 3) // precision is default
but
someFloatValue max: 12345678901234567890, scale: 5
would yield:
someFloatValue DECIMAL(25, 5) // precision = digits in max + scale
and
someFloatValue max: 100, min: -100000
would yield:
someFloatValue DECIMAL(8, 2) // precision = digits in min + default scale