Preface
Validating data is a common task that occurs throughout all application layers, from the presentation to the persistence layer. Often the same validation logic is implemented in each layer which is time consuming and error-prone. To avoid duplication of these validations, developers often bundle validation logic directly into the domain model, cluttering domain classes with validation code which is really metadata about the class itself.
JSR 380 - Bean Validation 2.0 - defines a metadata model and API for entity and method validation. The default metadata source are annotations, with the ability to override and extend the meta-data through the use of XML. The API is not tied to a specific application tier nor programming model. It is specifically not tied to either web or persistence tier, and is available for both server-side application programming, as well as rich client Swing application developers.
Hibernate Validator is the reference implementation of this JSR 380. The implementation itself as well as the Bean Validation API and TCK are all provided and distributed under the Apache Software License 2.0.
Hibernate Validator 6 and Bean Validation 2.0 require Java 8 or later.
1. Getting started
This chapter will show you how to get started with Hibernate Validator, the reference implementation (RI) of Bean Validation. For the following quick-start you need:
A JDK 8
An Internet connection (Maven has to download all required libraries)
1.1. Project set up
In order to use Hibernate Validator within a Maven project, simply add the following dependency to your pom.xml:
<dependency>
<groupId>org.hibernate.validator</groupId>
<artifactId>hibernate-validator</artifactId>
<version>6.0.9.Final</version>
</dependency>
This transitively pulls in the dependency to the Bean Validation API (javax.validation:validation-api:2.0.1.Final
).
1.1.1. Unified EL
Hibernate Validator requires an implementation of the Unified Expression Language (JSR 341) for evaluating dynamic expressions in constraint violation messages (see Section 4.1, “Default message interpolation”). When your application runs in a Java EE container such as JBoss AS, an EL implementation is already provided by the container. In a Java SE environment, however, you have to add an implementation as dependency to your POM file. For instance you can add the following dependency to use the JSR 341 reference implementation:
<dependency>
<groupId>org.glassfish</groupId>
<artifactId>javax.el</artifactId>
<version>3.0.1-b09</version>
</dependency>
For environments where one cannot provide a EL implementation Hibernate Validator is offering aSection 12.9, “ |
1.1.2. CDI
Bean Validation defines integration points with CDI (Contexts and Dependency Injection for Java TM EE, JSR 346). If your application runs in an environment which does not provide this integration out of the box, you may use the Hibernate Validator CDI portable extension by adding the following Maven dependency to your POM:
<dependency>
<groupId>org.hibernate.validator</groupId>
<artifactId>hibernate-validator-cdi</artifactId>
<version>6.0.9.Final</version>
</dependency>
Note that adding this dependency is usually not required for applications running on a Java EE application server. You can learn more about the integration of Bean Validation and CDI in Section 11.3, “CDI”.
1.1.3. Running with a security manager
Hibernate Validator supports running with a security manager being enabled. To do so, you must assign several permissions to the code bases of Hibernate Validator, the Bean Validation API, Classmate and JBoss Logging and also to the code base calling Bean Validation. The following shows how to do this via a policy file as processed by the Java default policy implementation:
grant codeBase "file:path/to/hibernate-validator-6.0.9.Final.jar" {
permission java.lang.reflect.ReflectPermission "suppressAccessChecks";
permission java.lang.RuntimePermission "accessDeclaredMembers";
permission java.lang.RuntimePermission "setContextClassLoader";
permission org.hibernate.validator.HibernateValidatorPermission "accessPrivateMembers";
// Only needed when working with XML descriptors (validation.xml or XML constraint mappings)
permission java.util.PropertyPermission "mapAnyUriToUri", "read";
};
grant codeBase "file:path/to/validation-api-2.0.1.Final.jar" {
permission java.io.FilePermission "path/to/hibernate-validator-6.0.9.Final.jar", "read";
};
grant codeBase "file:path/to/jboss-logging-3.3.2.Final.jar" {
permission java.util.PropertyPermission "org.jboss.logging.provider", "read";
permission java.util.PropertyPermission "org.jboss.logging.locale", "read";
};
grant codeBase "file:path/to/classmate-1.3.4.jar" {
permission java.lang.RuntimePermission "accessDeclaredMembers";
};
grant codeBase "file:path/to/validation-caller-x.y.z.jar" {
permission org.hibernate.validator.HibernateValidatorPermission "accessPrivateMembers";
};
1.1.4. Updating Hibernate Validator in WildFly
The WildFly application server contains Hibernate Validator out of the box. In order to update the server modules for Bean Validation API and Hibernate Validator to the latest and greatest, the patch mechanism of WildFly can be used.
You can download the patch file from SourceForge or from Maven Central using the following dependency:
<dependency>
<groupId>org.hibernate.validator</groupId>
<artifactId>hibernate-validator-modules</artifactId>
<version>6.0.9.Final</version>
<classifier>wildfly-12.0.0.Final-patch</classifier>
<type>zip</type>
</dependency>
We also provide a patch for WildFly 11.0.0.Final:
<dependency>
<groupId>org.hibernate.validator</groupId>
<artifactId>hibernate-validator-modules</artifactId>
<version>6.0.9.Final</version>
<classifier>wildfly-11.0.0.Final-patch</classifier>
<type>zip</type>
</dependency>
Having downloaded the patch file, you can apply it to WildFly by running this command:
$JBOSS_HOME/bin/jboss-cli.sh patch apply hibernate-validator-modules-6.0.9.Final-wildfly-12.0.0.Final-patch.zip
In case you want to undo the patch and go back to the version of Hibernate Validator originally coming with the server, run the following command:
$JBOSS_HOME/bin/jboss-cli.sh patch rollback --reset-configuration=true
1.1.5. Running on Java 9
As of Hibernate Validator 6.0.9.Final, support for Java 9 and the Java Platform Module System (JPMS) is experimental. There are no JPMS module descriptors provided yet, but Hibernate Validator is usable as automatic modules.
These are the module names as declared using the Automatic-Module-Name
header:
Bean Validation API:
java.validation
Hibernate Validator core:
org.hibernate.validator
Hibernate Validator CDI extension:
org.hibernate.validator.cdi
Hibernate Validator test utilities:
org.hibernate.validator.testutils
Hibernate Validator annotation processor:
org.hibernate.validator.annotationprocessor
These module names are preliminary and may be changed when providing real module descriptors in a future release.
When using Bean Validation XML descriptors (META-INF/validation.xml and/or constraint mapping files), the java.xml.bind
module must be enabled. Do so by appending --add-modules java.xml.bind
to your java invocation.
When using Hibernate Validator with CDI, be careful to not enable the Instead, add the full JSR 250 API to the unnamed module (i.e. the classpath), e.g. by pulling in the javax.annotation:javax.annotation-api dependency (there already is a transitive dependency to the JSR 250 API when depending on org.hibernate.validator:hibernate-validator-cdi). If you need to enable the |
1.2. Applying constraints
Let’s dive directly into an example to see how to apply constraints.
package org.hibernate.validator.referenceguide.chapter01;
import javax.validation.constraints.Min;
import javax.validation.constraints.NotNull;
import javax.validation.constraints.Size;
public class Car {
@NotNull
private String manufacturer;
@NotNull
@Size(min = 2, max = 14)
private String licensePlate;
@Min(2)
private int seatCount;
public Car(String manufacturer, String licencePlate, int seatCount) {
this.manufacturer = manufacturer;
this.licensePlate = licencePlate;
this.seatCount = seatCount;
}
//getters and setters ...
}
The @NotNull
, @Size
and @Min
annotations are used to declare the constraints which should be applied to the fields of a Car instance:
manufacturer
must never benull
licensePlate
must never benull
and must be between 2 and 14 characters longseatCount
must be at least 2
You can find the complete source code of all examples used in this reference guide in the Hibernate Validator source repository on GitHub. |
1.3. Validating constraints
To perform a validation of these constraints, you use a Validator
instance. Let’s have a look at a unit test for Car
:
package org.hibernate.validator.referenceguide.chapter01;
import java.util.Set;
import javax.validation.ConstraintViolation;
import javax.validation.Validation;
import javax.validation.Validator;
import javax.validation.ValidatorFactory;
import org.junit.BeforeClass;
import org.junit.Test;
import static org.junit.Assert.assertEquals;
public class CarTest {
private static Validator validator;
@BeforeClass
public static void setUpValidator() {
ValidatorFactory factory = Validation.buildDefaultValidatorFactory();
validator = factory.getValidator();
}
@Test
public void manufacturerIsNull() {
Car car = new Car( null, "DD-AB-123", 4 );
Set<ConstraintViolation<Car>> constraintViolations =
validator.validate( car );
assertEquals( 1, constraintViolations.size() );
assertEquals( "must not be null", constraintViolations.iterator().next().getMessage() );
}
@Test
public void licensePlateTooShort() {
Car car = new Car( "Morris", "D", 4 );
Set<ConstraintViolation<Car>> constraintViolations =
validator.validate( car );
assertEquals( 1, constraintViolations.size() );
assertEquals(
"size must be between 2 and 14",
constraintViolations.iterator().next().getMessage()
);
}
@Test
public void seatCountTooLow() {
Car car = new Car( "Morris", "DD-AB-123", 1 );
Set<ConstraintViolation<Car>> constraintViolations =
validator.validate( car );
assertEquals( 1, constraintViolations.size() );
assertEquals(
"must be greater than or equal to 2",
constraintViolations.iterator().next().getMessage()
);
}
@Test
public void carIsValid() {
Car car = new Car( "Morris", "DD-AB-123", 2 );
Set<ConstraintViolation<Car>> constraintViolations =
validator.validate( car );
assertEquals( 0, constraintViolations.size() );
}
}
In the setUp()
method a Validator
object is retrieved from the ValidatorFactory
. A Validator
instance is thread-safe and may be reused multiple times. It thus can safely be stored in a static field and be used in the test methods to validate the different Car
instances.
The validate()
method returns a set of ConstraintViolation
instances, which you can iterate over in order to see which validation errors occurred. The first three test methods show some expected constraint violations:
The
@NotNull
constraint onmanufacturer
is violated inmanufacturerIsNull()
The
@Size
constraint onlicensePlate
is violated inlicensePlateTooShort()
The
@Min
constraint onseatCount
is violated inseatCountTooLow()
If the object validates successfully, validate()
returns an empty set as you can see in carIsValid()
.
Note that only classes from the package javax.validation
are used. These are provided from the Bean Validation API. No classes from Hibernate Validator are directly referenced, resulting in portable code.
1.4. Where to go next?
That concludes the 5 minutes tour through the world of Hibernate Validator and Bean Validation. Continue exploring the code examples or look at further examples referenced in Chapter 14, Further reading.
To learn more about the validation of beans and properties, just continue reading Chapter 2, Declaring and validating bean constraints. If you are interested in using Bean Validation for the validation of method pre- and postcondition refer to Chapter 3, Declaring and validating method constraints. In case your application has specific validation requirements have a look at Chapter 6, Creating custom constraints.
2. Declaring and validating bean constraints
In this chapter you will learn how to declare (see Section 2.1, “Declaring bean constraints”) and validate (see Section 2.2, “Validating bean constraints”) bean constraints. Section 2.3, “Built-in constraints” provides an overview of all built-in constraints coming with Hibernate Validator.
If you are interested in applying constraints to method parameters and return values, refer to Chapter 3, Declaring and validating method constraints.
2.1. Declaring bean constraints
Constraints in Bean Validation are expressed via Java annotations. In this section you will learn how to enhance an object model with these annotations. There are four types of bean constraints:
field constraints
property constraints
container element constraints
class constraints
Not all constraints can be placed on all of these levels. In fact, none of the default constraints defined by Bean Validation can be placed at class level. The |
2.1.1. Field-level constraints
Constraints can be expressed by annotating a field of a class. Example 2.1, “Field-level constraints” shows a field level configuration example:
package org.hibernate.validator.referenceguide.chapter02.fieldlevel;
public class Car {
@NotNull
private String manufacturer;
@AssertTrue
private boolean isRegistered;
public Car(String manufacturer, boolean isRegistered) {
this.manufacturer = manufacturer;
this.isRegistered = isRegistered;
}
//getters and setters...
}
When using field-level constraints field access strategy is used to access the value to be validated. This means the validation engine directly accesses the instance variable and does not invoke the property accessor method even if such an accessor exists.
Constraints can be applied to fields of any access type (public, private etc.). Constraints on static fields are not supported, though.
When validating byte code enhanced objects, property level constraints should be used, because the byte code enhancing library won’t be able to determine a field access via reflection. |
2.1.2. Property-level constraints
If your model class adheres to the JavaBeans standard, it is also possible to annotate the properties of a bean class instead of its fields. Example 2.2, “Property-level constraints” uses the same entity as in Example 2.1, “Field-level constraints”, however, property level constraints are used.
package org.hibernate.validator.referenceguide.chapter02.propertylevel;
public class Car {
private String manufacturer;
private boolean isRegistered;
public Car(String manufacturer, boolean isRegistered) {
this.manufacturer = manufacturer;
this.isRegistered = isRegistered;
}
@NotNull
public String getManufacturer() {
return manufacturer;
}
public void setManufacturer(String manufacturer) {
this.manufacturer = manufacturer;
}
@AssertTrue
public boolean isRegistered() {
return isRegistered;
}
public void setRegistered(boolean isRegistered) {
this.isRegistered = isRegistered;
}
}
The property’s getter method has to be annotated, not its setter. That way also read-only properties can be constrained which have no setter method. |
When using property level constraints property access strategy is used to access the value to be validated, i.e. the validation engine accesses the state via the property accessor method.
It is recommended to stick either to field or property annotations within one class. It is not recommended to annotate a field and the accompanying getter method as this would cause the field to be validated twice. |
2.1.3. Container element constraints
It is possible to specify constraints directly on the type argument of a parameterized type: these constraints are called container element constraints.
This requires that ElementType.TYPE_USE
is specified via @Target
in the constraint definition. As of Bean Validation 2.0, built-in Bean Validation as well as Hibernate Validator specific constraints specify ElementType.TYPE_USE
and can be used directly in this context.
Hibernate Validator validates container element constraints specified on the following standard Java containers:
implementations of
java.util.Iterable
(e.g.List
s,Set
s),implementations of
java.util.Map
, with support for keys and values,java.util.Optional
,java.util.OptionalInt
,java.util.OptionalDouble
,java.util.OptionalLong
,the various implementations of JavaFX’s
javafx.beans.observable.ObservableValue
.
It also supports container element constraints on custom container types (see Chapter 7, Value extraction).
In versions prior to 6, a subset of container element constraints were supported. A |
We present below a couple of examples illustrating container element constraints on various Java types.
In these examples, @ValidPart
is a custom constraint allowed to be used in the TYPE_USE
context.
2.1.3.1. With Iterable
When applying constraints on an Iterable
type argument, Hibernate Validator will validate each element. Example 2.3, “Container element constraint on Set
” shows an example of a Set
with a container element constraint.
Set
package org.hibernate.validator.referenceguide.chapter02.containerelement.set;
import java.util.HashSet;
import java.util.Set;
public class Car {
private Set<@ValidPart String> parts = new HashSet<>();
public void addPart(String part) {
parts.add( part );
}
//...
}
Car car = new Car();
car.addPart( "Wheel" );
car.addPart( null );
Set<ConstraintViolation<Car>> constraintViolations = validator.validate( car );
assertEquals( 1, constraintViolations.size() );
ConstraintViolation<Car> constraintViolation =
constraintViolations.iterator().next();
assertEquals(
"'null' is not a valid car part.",
constraintViolation.getMessage()
);
assertEquals( "parts[].<iterable element>",
constraintViolation.getPropertyPath().toString() );
Note how the property path clearly states that the violation comes from an element of the iterable.
2.1.3.2. With List
When applying constraints on a List
type argument, Hibernate Validator will validate each element. Example 2.4, “Container element constraint on List
” shows an example of a List
with a container element constraint.
List
package org.hibernate.validator.referenceguide.chapter02.containerelement.list;
public class Car {
private List<@ValidPart String> parts = new ArrayList<>();
public void addPart(String part) {
parts.add( part );
}
//...
}
Car car = new Car();
car.addPart( "Wheel" );
car.addPart( null );
Set<ConstraintViolation<Car>> constraintViolations = validator.validate( car );
assertEquals( 1, constraintViolations.size() );
ConstraintViolation<Car> constraintViolation =
constraintViolations.iterator().next();
assertEquals(
"'null' is not a valid car part.",
constraintViolation.getMessage()
);
assertEquals( "parts[1].<list element>",
constraintViolation.getPropertyPath().toString() );
Here, the property path also contains the index of the invalid element.
2.1.3.3. With Map
Container element constraints are also validated on map keys and values. Example 2.5, “Container element constraint on map keys and values” shows an example of a Map
with a constraint on the key and a constraint on the value.
package org.hibernate.validator.referenceguide.chapter02.containerelement.map;
import java.util.HashMap;
import java.util.Map;
import javax.validation.constraints.NotNull;
public class Car {
public enum FuelConsumption {
CITY,
HIGHWAY
}
private Map<@NotNull FuelConsumption, @MaxAllowedFuelConsumption Integer> fuelConsumption = new HashMap<>();
public void setFuelConsumption(FuelConsumption consumption, int value) {
fuelConsumption.put( consumption, value );
}
//...
}
Car car = new Car();
car.setFuelConsumption( Car.FuelConsumption.HIGHWAY, 20 );
Set<ConstraintViolation<Car>> constraintViolations = validator.validate( car );
assertEquals( 1, constraintViolations.size() );
ConstraintViolation<Car> constraintViolation =
constraintViolations.iterator().next();
assertEquals(
"20 is outside the max fuel consumption.",
constraintViolation.getMessage()
);
assertEquals(
"fuelConsumption[HIGHWAY].<map value>",
constraintViolation.getPropertyPath().toString()
);
Car car = new Car();
car.setFuelConsumption( null, 5 );
Set<ConstraintViolation<Car>> constraintViolations = validator.validate( car );
assertEquals( 1, constraintViolations.size() );
ConstraintViolation<Car> constraintViolation =
constraintViolations.iterator().next();
assertEquals(
"must not be null",
constraintViolation.getMessage()
);
assertEquals(
"fuelConsumption<K>[].<map key>",
constraintViolation.getPropertyPath().toString()
);
The property paths of the violations are particularly interesting:
The key of the invalid element is included in the property path (in the second example, the key is
null
).In the first example, the violation concerns the
<map value>
, in the second one, the<map key>
.In the second example, you might have noticed the presence of the type argument
<K>
, more on this later.
2.1.3.4. With java.util.Optional
When applying a constraint on the type argument of Optional
, Hibernate Validator will automatically unwrap the type and validate the internal value. Example 2.6, “Container element constraint on Optional” shows an example of an Optional
with a container element constraint.
package org.hibernate.validator.referenceguide.chapter02.containerelement.optional;
public class Car {
private Optional<@MinTowingCapacity(1000) Integer> towingCapacity = Optional.empty();
public void setTowingCapacity(Integer alias) {
towingCapacity = Optional.of( alias );
}
//...
}
Car car = new Car();
car.setTowingCapacity( 100 );
Set<ConstraintViolation<Car>> constraintViolations = validator.validate( car );
assertEquals( 1, constraintViolations.size() );
ConstraintViolation<Car> constraintViolation = constraintViolations.iterator().next();
assertEquals(
"Not enough towing capacity.",
constraintViolation.getMessage()
);
assertEquals(
"towingCapacity",
constraintViolation.getPropertyPath().toString()
);
Here, the property path only contains the name of the property as we are considering Optional
as a "transparent" container.
2.1.3.5. With custom container types
Container element constraints can also be used with custom containers.
A ValueExtractor
must be registered for the custom type allowing to retrieve the value(s) to validate (see Chapter 7, Value extraction for more information about how to implement your own ValueExtractor
and how to register it).
Example 2.7, “Container element constraint on custom container type” shows an example of a custom parameterized type with a type argument constraint.
package org.hibernate.validator.referenceguide.chapter02.containerelement.custom;
public class Car {
private GearBox<@MinTorque(100) Gear> gearBox;
public void setGearBox(GearBox<Gear> gearBox) {
this.gearBox = gearBox;
}
//...
}
package org.hibernate.validator.referenceguide.chapter02.containerelement.custom;
public class GearBox<T extends Gear> {
private final T gear;
public GearBox(T gear) {
this.gear = gear;
}
public Gear getGear() {
return this.gear;
}
}
package org.hibernate.validator.referenceguide.chapter02.containerelement.custom;
public class Gear {
private final Integer torque;
public Gear(Integer torque) {
this.torque = torque;
}
public Integer getTorque() {
return torque;
}
public static class AcmeGear extends Gear {
public AcmeGear() {
super( 60 );
}
}
}
package org.hibernate.validator.referenceguide.chapter02.containerelement.custom;
public class GearBoxValueExtractor implements ValueExtractor<GearBox<@ExtractedValue ?>> {
@Override
public void extractValues(GearBox<@ExtractedValue ?> originalValue, ValueExtractor.ValueReceiver receiver) {
receiver.value( null, originalValue.getGear() );
}
}
Car car = new Car();
car.setGearBox( new GearBox<>( new Gear.AcmeGear() ) );
Set<ConstraintViolation<Car>> constraintViolations = validator.validate( car );
assertEquals( 1, constraintViolations.size() );
ConstraintViolation<Car> constraintViolation =
constraintViolations.iterator().next();
assertEquals(
"Gear is not providing enough torque.",
constraintViolation.getMessage()
);
assertEquals(
"gearBox",
constraintViolation.getPropertyPath().toString()
);
2.1.3.6. Nested container elements
Constraints are also supported on nested container elements.
When validating a Car
object as presented in Example 2.8, “Constraints on nested container elements”, both the @NotNull
constraints on Part
and Manufacturer
will be enforced.
package org.hibernate.validator.referenceguide.chapter02.containerelement.nested;
import java.util.HashMap;
import java.util.List;
import java.util.Map;
import javax.validation.constraints.NotNull;
public class Car {
private Map<@NotNull Part, List<@NotNull Manufacturer>> partManufacturers =
new HashMap<>();
//...
}
2.1.4. Class-level constraints
Last but not least, a constraint can also be placed on the class level. In this case not a single property is subject of the validation but the complete object. Class-level constraints are useful if the validation depends on a correlation between several properties of an object.
The Car
class in Example 2.9, “Class-level constraint” has the two attributes seatCount
and passengers
and it should be ensured that the list of passengers does not have more entries than available seats. For that purpose the @ValidPassengerCount
constraint is added on the class level. The validator of that constraint has access to the complete Car
object, allowing to compare the numbers of seats and passengers.
Refer to Section 6.2, “Class-level constraints” to learn in detail how to implement this custom constraint.
package org.hibernate.validator.referenceguide.chapter02.classlevel;
@ValidPassengerCount
public class Car {
private int seatCount;
private List<Person> passengers;
//...
}
2.1.5. Constraint inheritance
When a class implements an interface or extends another class, all constraint annotations declared on the super-type apply in the same manner as the constraints specified on the class itself. To make things clearer let’s have a look at the following example:
package org.hibernate.validator.referenceguide.chapter02.inheritance;
public class Car {
private String manufacturer;
@NotNull
public String getManufacturer() {
return manufacturer;
}
//...
}
package org.hibernate.validator.referenceguide.chapter02.inheritance;
public class RentalCar extends Car {
private String rentalStation;
@NotNull
public String getRentalStation() {
return rentalStation;
}
//...
}
Here the class RentalCar
is a subclass of Car
and adds the property rentalStation
. If an instance of RentalCar
is validated, not only the @NotNull
constraint on rentalStation
is evaluated, but also the constraint on manufacturer
from the parent class.
The same would be true, if Car
was not a superclass but an interface implemented by RentalCar
.
Constraint annotations are aggregated if methods are overridden. So if RentalCar
overrode the getManufacturer()
method from Car
, any constraints annotated at the overriding method would be evaluated in addition to the @NotNull
constraint from the superclass.
2.1.6. Object graphs
The Bean Validation API does not only allow to validate single class instances but also complete object graphs (cascaded validation). To do so, just annotate a field or property representing a reference to another object with @Valid
as demonstrated in Example 2.11, “Cascaded validation”.
package org.hibernate.validator.referenceguide.chapter02.objectgraph;
public class Car {
@NotNull
@Valid
private Person driver;
//...
}
package org.hibernate.validator.referenceguide.chapter02.objectgraph;
public class Person {
@NotNull
private String name;
//...
}
If an instance of Car
is validated, the referenced Person
object will be validated as well, as the driver
field is annotated with @Valid
. Therefore the validation of a Car
will fail if the name
field of the referenced Person
instance is null
.
The validation of object graphs is recursive, i.e. if a reference marked for cascaded validation points to an object which itself has properties annotated with @Valid
, these references will be followed up by the validation engine as well. The validation engine will ensure that no infinite loops occur during cascaded validation, for example if two objects hold references to each other.
Note that null
values are getting ignored during cascaded validation.
As constraints, object graph validation also works for container elements. That means any type argument of a container can be annotated with @Valid
, which will cause each contained element to be validated when the parent object is validated.
Cascaded validation is also supported for nested container elements. |
package org.hibernate.validator.referenceguide.chapter02.objectgraph.containerelement;
public class Car {
private List<@NotNull @Valid Person> passengers = new ArrayList<Person>();
private Map<@Valid Part, List<@Valid Manufacturer>> partManufacturers = new HashMap<>();
//...
}
package org.hibernate.validator.referenceguide.chapter02.objectgraph.containerelement;
public class Part {
@NotNull
private String name;
//...
}
package org.hibernate.validator.referenceguide.chapter02.objectgraph.containerelement;
public class Manufacturer {
@NotNull
private String name;
//...
}
When validating an instance of the Car
class shown in Example 2.12, “Cascaded validation of containers”, aConstraintViolation
will be created:
if any of the
Person
objects contained in the passengers list has anull
name;if any of the
Part
objects contained in the map keys has anull
name;if any of the
Manufacturer
objects contained in the list nested in the map values has anull
name.
In versions prior to 6, Hibernate Validator supported cascaded validation for a subset of container elements and it was implemented at the container level (e.g. you would use This is still supported but is not recommended. Please use container element level |
2.2. Validating bean constraints
The Validator
interface is the most important object in Bean Validation. The next section shows how to obtain a Validator
instance. Afterwards you’ll learn how to use the different methods of the Validator
interface.
2.2.1. Obtaining a Validator
instance
The first step towards validating an entity instance is to get hold of a Validator
instance. The road to this instance leads via the Validation
class and a ValidatorFactory
. The easiest way is to use the static method Validation#buildDefaultValidatorFactory()
:
Validation#buildDefaultValidatorFactory()
ValidatorFactory factory = Validation.buildDefaultValidatorFactory();
validator = factory.getValidator();
This bootstraps a validator in the default configuration. Refer to Chapter 9, Bootstrapping to learn more about the different bootstrapping methods and how to obtain a specifically configured Validator
instance.
2.2.2. Validator methods
The Validator
interface contains three methods that can be used to either validate entire entities or just single properties of the entity.
All three methods return a Set<ConstraintViolation>
. The set is empty, if the validation succeeds. Otherwise a ConstraintViolation
instance is added for each violated constraint.
All the validation methods have a var-args parameter which can be used to specify which validation groups shall be considered when performing the validation. If the parameter is not specified, the default validation group (javax.validation.groups.Default
) is used. The topic of validation groups is discussed in detail in Chapter 5, Grouping constraints.
2.2.2.1. Validator#validate()
Use the validate()
method to perform validation of all constraints of a given bean. Example 2.14, “Using Validator#validate()
” shows the validation of an instance of the Car
class from Example 2.2, “Property-level constraints” which fails to satisfy the @NotNull
constraint on the manufacturer
property. The validation call therefore returns one ConstraintViolation
object.
Validator#validate()
Car car = new Car( null, true );
Set<ConstraintViolation<Car>> constraintViolations = validator.validate( car );
assertEquals( 1, constraintViolations.size() );
assertEquals( "must not be null", constraintViolations.iterator().next().getMessage() );
2.2.2.2. Validator#validateProperty()
With help of the validateProperty()
you can validate a single named property of a given object. The property name is the JavaBeans property name.
Validator#validateProperty()
Car car = new Car( null, true );
Set<ConstraintViolation<Car>> constraintViolations = validator.validateProperty(
car,
"manufacturer"
);
assertEquals( 1, constraintViolations.size() );
assertEquals( "must not be null", constraintViolations.iterator().next().getMessage() );
2.2.2.3. Validator#validateValue()
By using the validateValue()
method you can check whether a single property of a given class can be validated successfully, if the property had the specified value:
Validator#validateValue()
Set<ConstraintViolation<Car>> constraintViolations = validator.validateValue(
Car.class,
"manufacturer",
null
);
assertEquals( 1, constraintViolations.size() );
assertEquals( "must not be null", constraintViolations.iterator().next().getMessage() );
|
Validator#validateProperty()
is for example used in the integration of Bean Validation into JSF 2 (see Section 11.2, “JSF & Seam”) to perform a validation of the values entered into a form before they are propagated to the model.
2.2.3. ConstraintViolation
2.2.3.1. ConstraintViolation
methods
Now it is time to have a closer look at what a ConstraintViolation
is. Using the different methods of ConstraintViolation
a lot of useful information about the cause of the validation failure can be determined. The following gives an overview of these methods. The values under "Example" column refer to Example 2.14, “Using Validator#validate()
”.
getMessage()
-
The interpolated error message
- Example
-
"must not be null"
getMessageTemplate()
-
The non-interpolated error message
- Example
-
"{… NotNull.message}"
getRootBean()
-
The root bean being validated
- Example
-
car
getRootBeanClass()
-
The class of the root bean being validated
- Example
-
Car.class
getLeafBean()
-
If a bean constraint, the bean instance the constraint is applied on; if a property constraint, the bean instance hosting the property the constraint is applied on
- Example
-
car
getPropertyPath()
-
The property path to the validated value from root bean
- Example
-
contains one node with kind
PROPERTY
and name "manufacturer"
getInvalidValue()
-
The value failing to pass the constraint
- Example
-
null
getConstraintDescriptor()
-
Constraint metadata reported to fail
- Example
-
descriptor for
@NotNull
2.2.3.2. Exploiting the property path
To determine the element that triggered the violation, you need to exploit the result of the getPropertyPath()
method.
The returned Path
is composed of Node
s describing the path to the element.
More information about the structure of the Path
and the various types of Node
s can be found in the ConstraintViolation
section of the Bean Validation specification.
2.3. Built-in constraints
Hibernate Validator comprises a basic set of commonly used constraints. These are foremost the constraints defined by the Bean Validation specification (see Section 2.3.1, “Bean Validation constraints”). Additionally, Hibernate Validator provides useful custom constraints (see Section 2.3.2, “Additional constraints”).
2.3.1. Bean Validation constraints
Below you can find a list of all constraints specified in the Bean Validation API. All these constraints apply to the field/property level, there are no class-level constraints defined in the Bean Validation specification. If you are using the Hibernate object-relational mapper, some of the constraints are taken into account when creating the DDL for your model (see "Hibernate metadata impact").
Hibernate Validator allows some constraints to be applied to more data types than required by the Bean Validation specification (e.g. |
@AssertFalse
-
Checks that the annotated element is false
- Supported data types
-
Boolean
,boolean
- Hibernate metadata impact
-
None
@AssertTrue
-
Checks that the annotated element is true
- Supported data types
-
Boolean
,boolean
- Hibernate metadata impact
-
None
@DecimalMax(value=, inclusive=)
-
Checks whether the annotated value is less than the specified maximum, when
inclusive
=false. Otherwise whether the value is less than or equal to the specified maximum. The parameter value is the string representation of the max value according to theBigDecimal
string representation.- Supported data types
-
BigDecimal
,BigInteger
,CharSequence
,byte
,short
,int
,long
and the respective wrappers of the primitive types; additionally supported by HV: any sub-type ofNumber
andjavax.money.MonetaryAmount
(if the JSR 354 APIand an implementation is on the class path) - Hibernate metadata impact
-
None
@DecimalMin(value=, inclusive=)
-
Checks whether the annotated value is larger than the specified minimum, when
inclusive
=false. Otherwise whether the value is larger than or equal to the specified minimum. The parameter value is the string representation of the min value according to theBigDecimal
string representation.- Supported data types
-
BigDecimal
,BigInteger
,CharSequence
,byte
,short
,int
,long
and the respective wrappers of the primitive types; additionally supported by HV: any sub-type ofNumber
andjavax.money.MonetaryAmount
- Hibernate metadata impact
-
None
@Digits(integer=, fraction=)
-
Checks whether the annotated value is a number having up to
integer
digits andfraction
fractional digits- Supported data types
-
BigDecimal,
BigInteger
,CharSequence
,byte
,short
,int
,long
and the respective wrappers of the primitive types; additionally supported by HV: any sub-type ofNumber
- Hibernate metadata impact
-
Defines column precision and scale
@Email
-
Checks whether the specified character sequence is a valid email address. The optional parameters
regexp
andflags
allow to specify an additional regular expression (including regular expression flags) which the email must match.- Supported data types
-
CharSequence
- Hibernate metadata impact
-
None
@Future
-
Checks whether the annotated date is in the future
- Supported data types
-
java.util.Date
,java.util.Calendar
,java.time.Instant
,java.time.LocalDate
,java.time.LocalDateTime
,java.time.LocalTime
,java.time.MonthDay
,java.time.OffsetDateTime
,java.time.OffsetTime
,java.time.Year
,java.time.YearMonth
,java.time.ZonedDateTime
,java.time.chrono.HijrahDate
,java.time.chrono.JapaneseDate
,java.time.chrono.MinguoDate
,java.time.chrono.ThaiBuddhistDate
; additionally supported by HV, if the Joda Time date/time API is on the classpath: any implementations ofReadablePartial
andReadableInstant
- Hibernate metadata impact
-
None
@FutureOrPresent
-
Checks whether the annotated date is in the present or in the future
- Supported data types
-
java.util.Date
,java.util.Calendar
,java.time.Instant
,java.time.LocalDate
,java.time.LocalDateTime
,java.time.LocalTime
,java.time.MonthDay
,java.time.OffsetDateTime
,java.time.OffsetTime
,java.time.Year
,java.time.YearMonth
,java.time.ZonedDateTime
,java.time.chrono.HijrahDate
,java.time.chrono.JapaneseDate
,java.time.chrono.MinguoDate
,java.time.chrono.ThaiBuddhistDate
; additionally supported by HV, if the Joda Time date/time API is on the classpath: any implementations ofReadablePartial
andReadableInstant
- Hibernate metadata impact
-
None
@Max(value=)
-
Checks whether the annotated value is less than or equal to the specified maximum
- Supported data types
-
BigDecimal
,BigInteger
,byte
,short
,int
,long
and the respective wrappers of the primitive types; additionally supported by HV: any sub-type ofCharSequence
(the numeric value represented by the character sequence is evaluated), any sub-type ofNumber
andjavax.money.MonetaryAmount
- Hibernate metadata impact
-
Adds a check constraint on the column
@Min(value=)
-
Checks whether the annotated value is higher than or equal to the specified minimum
- Supported data types
-
BigDecimal
,BigInteger
,byte
,short
,int
,long
and the respective wrappers of the primitive types; additionally supported by HV: any sub-type ofCharSequence
(the numeric value represented by the character sequence is evaluated), any sub-type ofNumber
andjavax.money.MonetaryAmount
- Hibernate metadata impact
-
Adds a check constraint on the column
@NotBlank
-
Checks that the annotated character sequence is not null and the trimmed length is greater than 0. The difference to
@NotEmpty
is that this constraint can only be applied on character sequences and that trailing white-spaces are ignored.- Supported data types
-
CharSequence
- Hibernate metadata impact
-
None
@NotEmpty
-
Checks whether the annotated element is not null nor empty
- Supported data types
-
CharSequence
,Collection
,Map
and arrays - Hibernate metadata impact
-
None
@NotNull
-
Checks that the annotated value is not
null
- Supported data types
-
Any type
- Hibernate metadata impact
-
Column(s) are not nullable
@Negative
-
Checks if the element is strictly negative. Zero values are considered invalid.
- Supported data types
-
BigDecimal
,BigInteger
,byte
,short
,int
,long
and the respective wrappers of the primitive types; additionally supported by HV: any sub-type ofCharSequence
(the numeric value represented by the character sequence is evaluated), any sub-type ofNumber
andjavax.money.MonetaryAmount
- Hibernate metadata impact
-
None
@NegativeOrZero
-
Checks if the element is negative or zero.
- Supported data types
-
BigDecimal
,BigInteger
,byte
,short
,int
,long
and the respective wrappers of the primitive types; additionally supported by HV: any sub-type ofCharSequence
(the numeric value represented by the character sequence is evaluated), any sub-type ofNumber
andjavax.money.MonetaryAmount
- Hibernate metadata impact
-
None
@Null
-
Checks that the annotated value is
null
- Supported data types
-
Any type
- Hibernate metadata impact
-
None
@Past
-
Checks whether the annotated date is in the past
- Supported data types
-
java.util.Date
,java.util.Calendar
,java.time.Instant
,java.time.LocalDate
,java.time.LocalDateTime
,java.time.LocalTime
,java.time.MonthDay
,java.time.OffsetDateTime
,java.time.OffsetTime
,java.time.Year
,java.time.YearMonth
,java.time.ZonedDateTime
,java.time.chrono.HijrahDate
,java.time.chrono.JapaneseDate
,java.time.chrono.MinguoDate
,java.time.chrono.ThaiBuddhistDate
; Additionally supported by HV, if the Joda Time date/time API is on the classpath: any implementations ofReadablePartial
andReadableInstant
- Hibernate metadata impact
-
None
@PastOrPresent
-
Checks whether the annotated date is in the past or in the present
- Supported data types
-
java.util.Date
,java.util.Calendar
,java.time.Instant
,java.time.LocalDate
,java.time.LocalDateTime
,java.time.LocalTime
,java.time.MonthDay
,java.time.OffsetDateTime
,java.time.OffsetTime
,java.time.Year
,java.time.YearMonth
,java.time.ZonedDateTime
,java.time.chrono.HijrahDate
,java.time.chrono.JapaneseDate
,java.time.chrono.MinguoDate
,java.time.chrono.ThaiBuddhistDate
; Additionally supported by HV, if the Joda Time date/time API is on the classpath: any implementations ofReadablePartial
andReadableInstant
- Hibernate metadata impact
-
None
@Pattern(regex=, flags=)
-
Checks if the annotated string matches the regular expression
regex
considering the given flagmatch
- Supported data types
-
CharSequence
- Hibernate metadata impact
-
None
@Positive
-
Checks if the element is strictly positive. Zero values are considered invalid.
- Supported data types
-
BigDecimal
,BigInteger
,byte
,short
,int
,long
and the respective wrappers of the primitive types; additionally supported by HV: any sub-type ofCharSequence
(the numeric value represented by the character sequence is evaluated), any sub-type ofNumber
andjavax.money.MonetaryAmount
- Hibernate metadata impact
-
None
@PositiveOrZero
-
Checks if the element is positive or zero.
- Supported data types
-
BigDecimal
,BigInteger
,byte
,short
,int
,long
and the respective wrappers of the primitive types; additionally supported by HV: any sub-type ofCharSequence
(the numeric value represented by the character sequence is evaluated), any sub-type ofNumber
andjavax.money.MonetaryAmount
- Hibernate metadata impact
-
None
@Size(min=, max=)
-
Checks if the annotated element’s size is between
min
andmax
(inclusive)- Supported data types
-
CharSequence
,Collection
,Map
and arrays - Hibernate metadata impact
-
Column length will be set to
max
On top of the parameters listed above each constraint has the parameters message, groups and payload. This is a requirement of the Bean Validation specification. |
2.3.2. Additional constraints
In addition to the constraints defined by the Bean Validation API, Hibernate Validator provides several useful custom constraints which are listed below. With one exception also these constraints apply to the field/property level, only @ScriptAssert
is a class-level constraint.
@CreditCardNumber(ignoreNonDigitCharacters=)
-
Checks that the annotated character sequence passes the Luhn checksum test. Note, this validation aims to check for user mistakes, not credit card validity! See also Anatomy of a credit card number.
ignoreNonDigitCharacters
allows to ignore non digit characters. The default isfalse
.- Supported data types
-
CharSequence
- Hibernate metadata impact
-
None
@Currency(value=)
-
Checks that the currency unit of the annotated
javax.money.MonetaryAmount
is part of the specified currency units.- Supported data types
-
any sub-type of
javax.money.MonetaryAmount
(if the JSR 354 API and an implementation is on the class path) - Hibernate metadata impact
-
None
@DurationMax(days=, hours=, minutes=, seconds=, millis=, nanos=, inclusive=)
-
Checks that annotated
java.time.Duration
element is not greater than the one constructed from annotation parameters. Equality is allowed ifinclusive
flag is set totrue
.- Supported data types
-
java.time.Duration
- Hibernate metadata impact
-
None
@DurationMin(days=, hours=, minutes=, seconds=, millis=, nanos=, inclusive=)
-
Checks that annotated
java.time.Duration
element is not less than the one constructed from annotation parameters. Equality is allowed ifinclusive
flag is set totrue
.- Supported data types
-
java.time.Duration
- Hibernate metadata impact
-
None
@EAN
-
Checks that the annotated character sequence is a valid EAN barcode. type determines the type of barcode. The default is EAN-13.
- Supported data types
-
CharSequence
- Hibernate metadata impact
-
None
@ISBN
-
Checks that the annotated character sequence is a valid ISBN.
type
determines the type of ISBN. The default is ISBN-13.- Supported data types
-
CharSequence
- Hibernate metadata impact
-
None
@Length(min=, max=)
-
Validates that the annotated character sequence is between
min
andmax
included- Supported data types
-
CharSequence
- Hibernate metadata impact
-
Column length will be set to max
@CodePointLength(min=, max=, normalizationStrategy=)
-
Validates that code point length of the annotated character sequence is between
min
andmax
included. Validates normalized value ifnormalizationStrategy
is set.- Supported data types
-
CharSequence
- Hibernate metadata impact
-
None
@LuhnCheck(startIndex= , endIndex=, checkDigitIndex=, ignoreNonDigitCharacters=)
-
Checks that the digits within the annotated character sequence pass the Luhn checksum algorithm (see also Luhn algorithm).
startIndex
andendIndex
allow to only run the algorithm on the specified sub-string.checkDigitIndex
allows to use an arbitrary digit within the character sequence as the check digit. If not specified it is assumed that the check digit is part of the specified range. Last but not least,ignoreNonDigitCharacters
allows to ignore non digit characters.- Supported data types
-
CharSequence
- Hibernate metadata impact
-
None
@Mod10Check(multiplier=, weight=, startIndex=, endIndex=, checkDigitIndex=, ignoreNonDigitCharacters=)
-
Checks that the digits within the annotated character sequence pass the generic mod 10 checksum algorithm.
multiplier
determines the multiplier for odd numbers (defaults to 3),weight
the weight for even numbers (defaults to 1).startIndex
andendIndex
allow to only run the algorithm on the specified sub-string.checkDigitIndex
allows to use an arbitrary digit within the character sequence as the check digit. If not specified it is assumed that the check digit is part of the specified range. Last but not least,ignoreNonDigitCharacters
allows to ignore non digit characters.- Supported data types
-
CharSequence
- Hibernate metadata impact
-
None
@Mod11Check(threshold=, startIndex=, endIndex=, checkDigitIndex=, ignoreNonDigitCharacters=, treatCheck10As=, treatCheck11As=)
-
Checks that the digits within the annotated character sequence pass the mod 11 checksum algorithm.
threshold
specifies the threshold for the mod11 multiplier growth; if no value is specified the multiplier will grow indefinitely.treatCheck10As
andtreatCheck11As
specify the check digits to be used when the mod 11 checksum equals 10 or 11, respectively. Default to X and 0, respectively.startIndex
,endIndex
checkDigitIndex
andignoreNonDigitCharacters
carry the same semantics as in@Mod10Check
.- Supported data types
-
CharSequence
- Hibernate metadata impact
-
None
@Range(min=, max=)
-
Checks whether the annotated value lies between (inclusive) the specified minimum and maximum
- Supported data types
-
BigDecimal
,BigInteger
,CharSequence
,byte
,short
,int
,long
and the respective wrappers of the primitive types - Hibernate metadata impact
-
None
@SafeHtml(whitelistType= , additionalTags=, additionalTagsWithAttributes=, baseURI=)
-
Checks whether the annotated value contains potentially malicious fragments such as
<script/>
. In order to use this constraint, the jsoup library must be part of the class path. With thewhitelistType
attribute a predefined whitelist type can be chosen which can be refined viaadditionalTags
oradditionalTagsWithAttributes
. The former allows to add tags without any attributes, whereas the latter allows to specify tags and optionally allowed attributes as well as accepted protocols for the attributes using the annotation@SafeHtml.Tag
. In addition,baseURI
allows to specify the base URI used to resolve relative URIs.- Supported data types
-
CharSequence
- Hibernate metadata impact
-
None
@ScriptAssert(lang=, script=, alias=, reportOn=)
-
Checks whether the given script can successfully be evaluated against the annotated element. In order to use this constraint, an implementation of the Java Scripting API as defined by JSR 223 ("Scripting for the JavaTM Platform") must be a part of the class path. The expressions to be evaluated can be written in any scripting or expression language, for which a JSR 223 compatible engine can be found in the class path. Even though this is a class-level constraint, one can use the
reportOn
attribute to report a constraint violation on a specific property rather than the whole object.- Supported data types
-
Any type
- Hibernate metadata impact
-
None
@UniqueElements
-
Checks that the annotated collection only contains unique elements. The equality is determined using the
equals()
method. The default message does not include the list of duplicate elements but you can include it by overriding the message and using the{duplicates}
message parameter. The list of duplicate elements is also included in the dynamic payload of the constraint violation.- Supported data types
-
Collection
- Hibernate metadata impact
-
None
@URL(protocol=, host=, port=, regexp=, flags=)
-
Checks if the annotated character sequence is a valid URL according to RFC2396. If any of the optional parameters
protocol
,host
orport
are specified, the corresponding URL fragments must match the specified values. The optional parametersregexp
andflags
allow to specify an additional regular expression (including regular expression flags) which the URL must match. Per default this constraint used thejava.net.URL
constructor to verify whether a given string represents a valid URL. A regular expression based version is also available -RegexpURLValidator
- which can be configured via XML (see Section 8.2, “Mapping constraints viaconstraint-mappings
”) or the programmatic API (see Section 12.13.2, “Adding constraint definitions programmatically”).- Supported data types
-
CharSequence
- Hibernate metadata impact
-
None
2.3.2.1. Country specific constraints
Hibernate Validator offers also some country specific constraints, e.g. for the validation of social security numbers.
If you have to implement a country specific constraint, consider making it a contribution to Hibernate Validator! |
@CNPJ
-
Checks that the annotated character sequence represents a Brazilian corporate tax payer registry number (Cadastro de Pessoa Juríeddica)
- Supported data types
-
CharSequence
- Hibernate metadata impact
-
None
- Country
-
Brazil
@CPF
-
Checks that the annotated character sequence represents a Brazilian individual taxpayer registry number (Cadastro de Pessoa Fídsica)
- Supported data types
-
CharSequence
- Hibernate metadata impact
-
None
- Country
-
Brazil
@TituloEleitoral
-
Checks that the annotated character sequence represents a Brazilian voter ID card number (Título Eleitoral)
- Supported data types
-
CharSequence
- Hibernate metadata impact
-
None
- Country
-
Brazil
@NIP
-
Checks that the annotated character sequence represents a Polish VAT identification number (NIP)
- Supported data types
-
CharSequence
- Hibernate metadata impact
-
None
- Country
-
Poland
@PESEL
-
Checks that the annotated character sequence represents a Polish national identification number (PESEL)
- Supported data types
-
CharSequence
- Hibernate metadata impact
-
None
- Country
-
Poland
@REGON
-
Checks that the annotated character sequence represents a Polish taxpayer identification number (REGON). Can be applied to both 9 and 14 digits versions of REGON
- Supported data types
-
CharSequence
- Hibernate metadata impact
-
None
- Country
-
Poland
In some cases neither the Bean Validation constraints nor the custom constraints provided by Hibernate Validator will fulfill your requirements. In this case you can easily write your own constraint. You can find more information in Chapter 6, Creating custom constraints. |
3. Declaring and validating method constraints
As of Bean Validation 1.1, constraints can not only be applied to JavaBeans and their properties, but also to the parameters and return values of the methods and constructors of any Java type. That way Bean Validation constraints can be used to specify
the preconditions that must be satisfied by the caller before a method or constructor may be invoked (by applying constraints to the parameters of an executable)
the postconditions that are guaranteed to the caller after a method or constructor invocation returns (by applying constraints to the return value of an executable)
For the purpose of this reference guide, the term method constraint refers to both, method and constructor constraints, if not stated otherwise. Occasionally, the term executable is used when referring to methods and constructors. |
This approach has several advantages over traditional ways of checking the correctness of parameters and return values:
the checks don’t have to be performed manually (e.g. by throwing
IllegalArgumentException
or similar), resulting in less code to write and maintainan executable’s pre- and postconditions don’t have to be expressed again in its documentation, since the constraint annotations will automatically be included in the generated JavaDoc. This avoids redundancies and reduces the chance of inconsistencies between implementation and documentation
In order to make annotations show up in the JavaDoc of annotated elements, the annotation types themselves must be annotated with the meta annotation @Documented. This is the case for all built-in constraints and is considered a best practice for any custom constraints. |
In the remainder of this chapter you will learn how to declare parameter and return value constraints and how to validate them using the ExecutableValidator
API.
3.1. Declaring method constraints
3.1.1. Parameter constraints
You specify the preconditions of a method or constructor by adding constraint annotations to its parameters as demonstrated in Example 3.1, “Declaring method and constructor parameter constraints”.
package org.hibernate.validator.referenceguide.chapter03.parameter;
public class RentalStation {
public RentalStation(@NotNull String name) {
//...
}
public void rentCar(
@NotNull Customer customer,
@NotNull @Future Date startDate,
@Min(1) int durationInDays) {
//...
}
}
The following preconditions are declared here:
The
name
passed to theRentalCar
constructor must not benull
When invoking the
rentCar()
method, the givencustomer
must not benull
, the rental’s start date must not benull
as well as be in the future and finally the rental duration must be at least one day
Note that declaring method or constructor constraints itself does not automatically cause their validation upon invocation of the executable. Instead, the ExecutableValidator
API (see Section 3.2, “Validating method constraints”) must be used to perform the validation, which is often done using a method interception facility such as AOP, proxy objects etc.
Constraints may only be applied to instance methods, i.e. declaring constraints on static methods is not supported. Depending on the interception facility you use for triggering method validation, additional restrictions may apply, e.g. with respect to the visibility of methods supported as target of interception. Refer to the documentation of the interception technology to find out whether any such limitations exist.
3.1.1.1. Cross-parameter constraints
Sometimes validation does not only depend on a single parameter but on several or even all parameters of a method or constructor. This kind of requirement can be fulfilled with help of a cross-parameter constraint.
Cross-parameter constraints can be considered as the method validation equivalent to class-level constraints. Both can be used to implement validation requirements which are based on several elements. While class-level constraints apply to several properties of a bean, cross-parameter constraints apply to several parameters of an executable.
In contrast to single-parameter constraints, cross-parameter constraints are declared on the method or constructor as you can see in Example 3.2, “Declaring a cross-parameter constraint”. Here the cross- parameter constraint @LuggageCountMatchesPassengerCount
declared on the load()
method is used to ensure that no passenger has more than two pieces of luggage.
package org.hibernate.validator.referenceguide.chapter03.crossparameter;
public class Car {
@LuggageCountMatchesPassengerCount(piecesOfLuggagePerPassenger = 2)
public void load(List<Person> passengers, List<PieceOfLuggage> luggage) {
//...
}
}
As you will learn in the next section, return value constraints are also declared on the method level. In order to distinguish cross-parameter constraints from return value constraints, the constraint target is configured in the ConstraintValidator
implementation using the @SupportedValidationTarget
annotation. You can find out about the details in Section 6.3, “Cross-parameter constraints” which shows how to implement your own cross-parameter constraint.
In some cases a constraint can be applied to an executable’s parameters (i.e. it is a cross- parameter constraint), but also to the return value. One example for this are custom constraints which allow to specify validation rules using expression or script languages.
Such constraints must define a member validationAppliesTo()
which can be used at declaration time to specify the constraint target. As shown in Example 3.3, “Specifying a constraint’s target” you apply the constraint to an executable’s parameters by specifying validationAppliesTo = ConstraintTarget.PARAMETERS
, while ConstraintTarget.RETURN_VALUE
is used to apply the constraint to the executable return value.
package org.hibernate.validator.referenceguide.chapter03.crossparameter.constrainttarget;
public class Garage {
@ELAssert(expression = "...", validationAppliesTo = ConstraintTarget.PARAMETERS)
public Car buildCar(List<Part> parts) {
//...
return null;
}
@ELAssert(expression = "...", validationAppliesTo = ConstraintTarget.RETURN_VALUE)
public Car paintCar(int color) {
//...
return null;
}
}
Although such a constraint is applicable to the parameters and return value of an executable, the target can often be inferred automatically. This is the case, if the constraint is declared on
a void method with parameters (the constraint applies to the parameters)
an executable with return value but no parameters (the constraint applies to the return value)
neither a method nor a constructor, but a field, parameter etc. (the constraint applies to the annotated element)
In these situations you don’t have to specify the constraint target. It is still recommended to do so if it increases readability of the source code. If the constraint target is not specified in situations where it can’t be determined automatically, a ConstraintDeclarationException
is raised.
3.1.2. Return value constraints
The postconditions of a method or constructor are declared by adding constraint annotations to the executable as shown in Example 3.4, “Declaring method and constructor return value constraints”.
package org.hibernate.validator.referenceguide.chapter03.returnvalue;
public class RentalStation {
@ValidRentalStation
public RentalStation() {
//...
}
@NotNull
@Size(min = 1)
public List<@NotNull Customer> getCustomers() {
//...
return null;
}
}
The following constraints apply to the executables of RentalStation
:
Any newly created
RentalStation
object must satisfy the@ValidRentalStation
constraintThe customer list returned by
getCustomers()
must not benull
and must contain at least on elementThe customer list returned by
getCustomers()
must no containnull
objects
As you can see in the above example, container element constraints are supported on method return value. They are also supported on method parameters. |
3.1.3. Cascaded validation
Similar to the cascaded validation of JavaBeans properties (see Section 2.1.6, “Object graphs”), the @Valid
annotation can be used to mark executable parameters and return values for cascaded validation. When validating a parameter or return value annotated with @Valid
, the constraints declared on the parameter or return value object are validated as well.
In Example 3.5, “Marking executable parameters and return values for cascaded validation”, the car
parameter of the method Garage#checkCar()
as well as the return value of the Garage
constructor are marked for cascaded validation.
package org.hibernate.validator.referenceguide.chapter03.cascaded;
public class Garage {
@NotNull
private String name;
@Valid
public Garage(String name) {
this.name = name;
}
public boolean checkCar(@Valid @NotNull Car car) {
//...
return false;
}
}
package org.hibernate.validator.referenceguide.chapter03.cascaded;
public class Car {
@NotNull
private String manufacturer;
@NotNull
@Size(min = 2, max = 14)
private String licensePlate;
public Car(String manufacturer, String licencePlate) {
this.manufacturer = manufacturer;
this.licensePlate = licencePlate;
}
//getters and setters ...
}
When validating the arguments of the checkCar()
method, the constraints on the properties of the passed Car
object are evaluated as well. Similarly, the @NotNull
constraint on the name field of Garage
is checked when validating the return value of the Garage
constructor.
Generally, the cascaded validation works for executables in exactly the same way as it does for JavaBeans properties.
In particular, null
values are ignored during cascaded validation (naturally this can’t happen during constructor return value validation) and cascaded validation is performed recursively, i.e. if a parameter or return value object which is marked for cascaded validation itself has properties marked with @Valid
, the constraints declared on the referenced elements will be validated as well.
Same as for fields and properties, cascaded validation can also be declared on container elements (e.g. elements of collections, maps or custom containers) of return values and parameters.
In this case, each element contained by the container gets validated. So when validating the arguments of the checkCars()
method in Example 3.6, “Container elements of method parameter marked for cascaded validation”, each element instance of the passed list will be validated and a ConstraintViolation
created when any of the contained Car
instances is invalid.
package org.hibernate.validator.referenceguide.chapter03.cascaded.containerelement;
public class Garage {
public boolean checkCars(@NotNull List<@Valid Car> cars) {
//...
return false;
}
}
3.1.4. Method constraints in inheritance hierarchies
When declaring method constraints in inheritance hierarchies, it is important to be aware of the following rules:
The preconditions to be satisfied by the caller of a method may not be strengthened in subtypes
The postconditions guaranteed to the caller of a method may not be weakened in subtypes
These rules are motivated by the concept of behavioral subtyping which requires that wherever a type T
is used, also a subtype S
of T
may be used without altering the program’s behavior.
As an example, consider a class invoking a method on an object with the static type T
. If the runtime type of that object was S
and S
imposed additional preconditions, the client class might fail to satisfy these preconditions as is not aware of them. The rules of behavioral subtyping are also known as the Liskov substitution principle.
The Bean Validation specification implements the first rule by disallowing parameter constraints on methods which override or implement a method declared in a supertype (superclass or interface). Example 3.7, “Illegal method parameter constraint in subtype” shows a violation of this rule.
package org.hibernate.validator.referenceguide.chapter03.inheritance.parameter;
public interface Vehicle {
void drive(@Max(75) int speedInMph);
}
package org.hibernate.validator.referenceguide.chapter03.inheritance.parameter;
public class Car implements Vehicle {
@Override
public void drive(@Max(55) int speedInMph) {
//...
}
}
The @Max
constraint on Car#drive()
is illegal since this method implements the interface method Vehicle#drive()
. Note that parameter constraints on overriding methods are also disallowed, if the supertype method itself doesn’t declare any parameter constraints.
Furthermore, if a method overrides or implements a method declared in several parallel supertypes (e.g. two interfaces not extending each other or a class and an interface not implemented by that class), no parameter constraints may be specified for the method in any of the involved types. The types in Example 3.8, “Illegal method parameter constraint in parallel types of a hierarchy” demonstrate a violation of that rule. The method RacingCar#drive()
overrides Vehicle#drive()
as well as Car#drive()
. Therefore the constraint on Vehicle#drive()
is illegal.
package org.hibernate.validator.referenceguide.chapter03.inheritance.parallel;
public interface Vehicle {
void drive(@Max(75) int speedInMph);
}
package org.hibernate.validator.referenceguide.chapter03.inheritance.parallel;
public interface Car {
void drive(int speedInMph);
}
package org.hibernate.validator.referenceguide.chapter03.inheritance.parallel;
public class RacingCar implements Car, Vehicle {
@Override
public void drive(int speedInMph) {
//...
}
}
The previously described restrictions only apply to parameter constraints. In contrast, return value constraints may be added in methods overriding or implementing any supertype methods.
In this case, all the method’s return value constraints apply for the subtype method, i.e. the constraints declared on the subtype method itself as well as any return value constraints on overridden/implemented supertype methods. This is legal as putting additional return value constraints in place may never represent a weakening of the postconditions guaranteed to the caller of a method.
So when validating the return value of the method Car#getPassengers()
shown in Example 3.9, “Return value constraints on supertype and subtype method”, the @Size
constraint on the method itself as well as the @NotNull
constraint on the implemented interface method Vehicle#getPassengers()
apply.
package org.hibernate.validator.referenceguide.chapter03.inheritance.returnvalue;
public interface Vehicle {
@NotNull
List<Person> getPassengers();
}
package org.hibernate.validator.referenceguide.chapter03.inheritance.returnvalue;
public class Car implements Vehicle {
@Override
@Size(min = 1)
public List<Person> getPassengers() {
//...
return null;
}
}
If the validation engine detects a violation of any of the aforementioned rules, a ConstraintDeclarationException
will be raised.
The rules described in this section only apply to methods but not constructors. By definition, constructors never override supertype constructors. Therefore, when validating the parameters or the return value of a constructor invocation only the constraints declared on the constructor itself apply, but never any constraints declared on supertype constructors. |
Enforcement of these rules may be relaxed by setting the configuration parameters contained in the |
3.2. Validating method constraints
The validation of method constraints is done using the ExecutableValidator
interface.
In Section 3.2.1, “Obtaining an ExecutableValidator
instance” you will learn how to obtain an ExecutableValidator
instance while Section 3.2.2, “ExecutableValidator
methods” shows how to use the different methods offered by this interface.
Instead of calling the ExecutableValidator
methods directly from within application code, they are usually invoked via a method interception technology such as AOP, proxy objects, etc. This causes executable constraints to be validated automatically and transparently upon method or constructor invocation. Typically a ConstraintViolationException
is raised by the integration layer in case any of the constraints is violated.
3.2.1. Obtaining an ExecutableValidator
instance
You can retrieve an ExecutableValidator
instance via Validator#forExecutables()
as shown in Example 3.10, “Obtaining an ExecutableValidator
instance”.
ExecutableValidator
instanceValidatorFactory factory = Validation.buildDefaultValidatorFactory();
executableValidator = factory.getValidator().forExecutables();
In the example the executable validator is retrieved from the default validator factory, but if required you could also bootstrap a specifically configured factory as described in Chapter 9, Bootstrapping, for instance in order to use a specific parameter name provider (see Section 9.2.4, “ParameterNameProvider
”).
3.2.2. ExecutableValidator
methods
The ExecutableValidator
interface offers altogether four methods:
validateParameters()
andvalidateReturnValue()
for method validationvalidateConstructorParameters()
andvalidateConstructorReturnValue()
for constructor validation
Just as the methods on Validator
, all these methods return a Set<ConstraintViolation>
which contains a ConstraintViolation
instance for each violated constraint and which is empty if the validation succeeds. Also all the methods have a var-args groups parameter by which you can pass the validation groups to be considered for validation.
The examples in the following sections are based on the methods on constructors of the Car
class shown in Example 3.11, “Class Car
with constrained methods and constructors”.
Car
with constrained methods and constructorspackage org.hibernate.validator.referenceguide.chapter03.validation;
public class Car {
public Car(@NotNull String manufacturer) {
//...
}
@ValidRacingCar
public Car(String manufacturer, String team) {
//...
}
public void drive(@Max(75) int speedInMph) {
//...
}
@Size(min = 1)
public List<Passenger> getPassengers() {
//...
return Collections.emptyList();
}
}
3.2.2.1. ExecutableValidator#validateParameters()
The method validateParameters()
is used to validate the arguments of a method invocation. Example 3.12, “Using ExecutableValidator#validateParameters()
” shows an example. The validation results in a violation of the @Max
constraint on the parameter of the drive()
method.
ExecutableValidator#validateParameters()
Car object = new Car( "Morris" );
Method method = Car.class.getMethod( "drive", int.class );
Object[] parameterValues = { 80 };
Set<ConstraintViolation<Car>> violations = executableValidator.validateParameters(
object,
method,
parameterValues
);
assertEquals( 1, violations.size() );
Class<? extends Annotation> constraintType = violations.iterator()
.next()
.getConstraintDescriptor()
.getAnnotation()
.annotationType();
assertEquals( Max.class, constraintType );
Note that validateParameters()
validates all the parameter constraints of a method, i.e. constraints on individual parameters as well as cross-parameter constraints.
3.2.2.2. ExecutableValidator#validateReturnValue()
Using validateReturnValue()
the return value of a method can be validated. The validation in Example 3.13, “Using ExecutableValidator#validateReturnValue()
” yields one constraint violation since the getPassengers()
method is expected to return at least one Passenger
instance.
ExecutableValidator#validateReturnValue()
Car object = new Car( "Morris" );
Method method = Car.class.getMethod( "getPassengers" );
Object returnValue = Collections.<Passenger>emptyList();
Set<ConstraintViolation<Car>> violations = executableValidator.validateReturnValue(
object,
method,
returnValue
);
assertEquals( 1, violations.size() );
Class<? extends Annotation> constraintType = violations.iterator()
.next()
.getConstraintDescriptor()
.getAnnotation()
.annotationType();
assertEquals( Size.class, constraintType );
3.2.2.3. ExecutableValidator#validateConstructorParameters()
The arguments of constructor invocations can be validated with validateConstructorParameters()
as shown in method Example 3.14, “Using ExecutableValidator#validateConstructorParameters()
”. Due to the @NotNull
constraint on the manufacturer
parameter, the validation call returns one constraint violation.
ExecutableValidator#validateConstructorParameters()
Constructor<Car> constructor = Car.class.getConstructor( String.class );
Object[] parameterValues = { null };
Set<ConstraintViolation<Car>> violations = executableValidator.validateConstructorParameters(
constructor,
parameterValues
);
assertEquals( 1, violations.size() );
Class<? extends Annotation> constraintType = violations.iterator()
.next()
.getConstraintDescriptor()
.getAnnotation()
.annotationType();
assertEquals( NotNull.class, constraintType );
3.2.2.4. ExecutableValidator#validateConstructorReturnValue()
Finally, by using validateConstructorReturnValue()
you can validate a constructor’s return value. In Example 3.15, “Using ExecutableValidator#validateConstructorReturnValue()
”, validateConstructorReturnValue()
returns one constraint violation, since the Car
instance returned by the constructor doesn’t satisfy the @ValidRacingCar
constraint (not shown).
ExecutableValidator#validateConstructorReturnValue()
//constructor for creating racing cars
Constructor<Car> constructor = Car.class.getConstructor( String.class, String.class );
Car createdObject = new Car( "Morris", null );
Set<ConstraintViolation<Car>> violations = executableValidator.validateConstructorReturnValue(
constructor,
createdObject
);
assertEquals( 1, violations.size() );
Class<? extends Annotation> constraintType = violations.iterator()
.next()
.getConstraintDescriptor()
.getAnnotation()
.annotationType();
assertEquals( ValidRacingCar.class, constraintType );
3.2.3. ConstraintViolation
methods for method validation
In addition to the methods introduced in Section 2.2.3, “ConstraintViolation
”, ConstraintViolation
provides two more methods specific to the validation of executable parameters and return values.
ConstraintViolation#getExecutableParameters()
returns the validated parameter array in case of method or constructor parameter validation, while ConstraintViolation#getExecutableReturnValue()
provides access to the validated object in case of return value validation.
All the other ConstraintViolation
methods generally work for method validation in the same way as for validation of beans. Refer to the JavaDoc to learn more about the behavior of the individual methods and their return values during bean and method validation.
Note that getPropertyPath()
can be very useful in order to obtain detailed information about the validated parameter or return value, e.g. for logging purposes. In particular, you can retrieve name and argument types of the concerned method as well as the index of the concerned parameter from the path nodes. How this can be done is shown in Example 3.16, “Retrieving method and parameter information”.
Car object = new Car( "Morris" );
Method method = Car.class.getMethod( "drive", int.class );
Object[] parameterValues = { 80 };
Set<ConstraintViolation<Car>> violations = executableValidator.validateParameters(
object,
method,
parameterValues
);
assertEquals( 1, violations.size() );
Iterator<Node> propertyPath = violations.iterator()
.next()
.getPropertyPath()
.iterator();
MethodNode methodNode = propertyPath.next().as( MethodNode.class );
assertEquals( "drive", methodNode.getName() );
assertEquals( Arrays.<Class<?>>asList( int.class ), methodNode.getParameterTypes() );
ParameterNode parameterNode = propertyPath.next().as( ParameterNode.class );
assertEquals( "speedInMph", parameterNode.getName() );
assertEquals( 0, parameterNode.getParameterIndex() );
The parameter name is determined using the current ParameterNameProvider
(see Section 9.2.4, “ParameterNameProvider
”).
3.3. Built-in method constraints
In addition to the built-in bean and property-level constraints discussed in Section 2.3, “Built-in constraints”, Hibernate Validator currently provides one method-level constraint, @ParameterScriptAssert
. This is a generic cross-parameter constraint which allows to implement validation routines using any JSR 223 compatible ("Scripting for the JavaTMPlatform") scripting language, provided an engine for this language is available on the classpath.
To refer to the executable’s parameters from within the expression, use their name as obtained from the active parameter name provider (see Section 9.2.4, “ParameterNameProvider
”). Example 3.17, “Using @ParameterScriptAssert
” shows how the validation logic of the @LuggageCountMatchesPassengerCount
constraint from Example 3.2, “Declaring a cross-parameter constraint” could be expressed with the help of @ParameterScriptAssert
.
@ParameterScriptAssert
package org.hibernate.validator.referenceguide.chapter03.parameterscriptassert;
public class Car {
@ParameterScriptAssert(lang = "javascript", script = "luggage.size() <= passengers.size() * 2")
public void load(List<Person> passengers, List<PieceOfLuggage> luggage) {
//...
}
}
4. Interpolating constraint error messages
Message interpolation is the process of creating error messages for violated Bean Validation constraints. In this chapter you will learn how such messages are defined and resolved and how you can plug in custom message interpolators in case the default algorithm is not sufficient for your requirements.
4.1. Default message interpolation
Constraint violation messages are retrieved from so called message descriptors. Each constraint defines its default message descriptor using the message attribute. At declaration time, the default descriptor can be overridden with a specific value as shown in Example 4.1, “Specifying a message descriptor using the message attribute”.
package org.hibernate.validator.referenceguide.chapter04;
public class Car {
@NotNull(message = "The manufacturer name must not be null")
private String manufacturer;
//constructor, getters and setters ...
}
If a constraint is violated, its descriptor will be interpolated by the validation engine using the currently configured MessageInterpolator
. The interpolated error message can then be retrieved from the resulting constraint violation by calling ConstraintViolation#getMessage()
.
Message descriptors can contain message parameters as well as message expressions which will be resolved during interpolation. Message parameters are string literals enclosed in {}
, while message expressions are string literals enclosed in ${}
. The following algorithm is applied during method interpolation:
Resolve any message parameters by using them as key for the resource bundle ValidationMessages. If this bundle contains an entry for a given message parameter, that parameter will be replaced in the message with the corresponding value from the bundle. This step will be executed recursively in case the replaced value again contains message parameters. The resource bundle is expected to be provided by the application developer, e.g. by adding a file named ValidationMessages.properties to the classpath. You can also create localized error messages by providing locale specific variations of this bundle, such as ValidationMessages_en_US.properties. By default, the JVM’s default locale (
Locale#getDefault()
) will be used when looking up messages in the bundle.Resolve any message parameters by using them as key for a resource bundle containing the standard error messages for the built-in constraints as defined in Appendix B of the Bean Validation specification. In the case of Hibernate Validator, this bundle is named
org.hibernate.validator.ValidationMessages
. If this step triggers a replacement, step 1 is executed again, otherwise step 3 is applied.Resolve any message parameters by replacing them with the value of the constraint annotation member of the same name. This allows to refer to attribute values of the constraint (e.g.
Size#min()
) in the error message (e.g. "must be at least ${min}").Resolve any message expressions by evaluating them as expressions of the Unified Expression Language. See Section 4.1.2, “Interpolation with message expressions” to learn more about the usage of Unified EL in error messages.
You can find the formal definition of the interpolation algorithm in section 6.3.1.1 of the Bean Validation specification. |
4.1.1. Special characters
Since the characters {
, }
and $
have a special meaning in message descriptors, they need to be escaped if you want to use them literally. The following rules apply:
\{
is considered as the literal{
\}
is considered as the literal}
\$
is considered as the literal$
\\
is considered as the literal\
4.1.2. Interpolation with message expressions
As of Hibernate Validator 5 (Bean Validation 1.1) it is possible to use the Unified Expression Language (as defined by JSR 341) in constraint violation messages. This allows to define error messages based on conditional logic and also enables advanced formatting options. The validation engine makes the following objects available in the EL context:
the attribute values of the constraint mapped to the attribute names
the currently validated value (property, bean, method parameter etc.) under the name validatedValue
a bean mapped to the name formatter exposing the var-arg method
format(String format, Object… args)
which behaves likejava.util.Formatter.format(String format, Object… args)
.
The following section provides several examples for using EL expressions in error messages.
4.1.3. Examples
Example 4.2, “Specifying message descriptors” shows how to make use of the different options for specifying message descriptors.
package org.hibernate.validator.referenceguide.chapter04.complete;
public class Car {
@NotNull
private String manufacturer;
@Size(
min = 2,
max = 14,
message = "The license plate '${validatedValue}' must be between {min} and {max} characters long"
)
private String licensePlate;
@Min(
value = 2,
message = "There must be at least {value} seat${value > 1 ? 's' : ''}"
)
private int seatCount;
@DecimalMax(
value = "350",
message = "The top speed ${formatter.format('%1$.2f', validatedValue)} is higher " +
"than {value}"
)
private double topSpeed;
@DecimalMax(value = "100000", message = "Price must not be higher than ${value}")
private BigDecimal price;
public Car(
String manufacturer,
String licensePlate,
int seatCount,
double topSpeed,
BigDecimal price) {
this.manufacturer = manufacturer;
this.licensePlate = licensePlate;
this.seatCount = seatCount;
this.topSpeed = topSpeed;
this.price = price;
}
//getters and setters ...
}
Validating an invalid Car
instance yields constraint violations with the messages shown by the assertions in Example 4.3, “Expected error messages”:
the
@NotNull
constraint on themanufacturer
field causes the error message "must not be null", as this is the default message defined by the Bean Validation specification and no specific descriptor is given in the message attributethe
@Size
constraint on thelicensePlate
field shows the interpolation of message parameters ({min}
,{max}
) and how to add the validated value to the error message using the EL expression${validatedValue}
the
@Min
constraint onseatCount
demonstrates how to use an EL expression with a ternary expression to dynamically choose singular or plural form, depending on an attribute of the constraint ("There must be at least 1 seat" vs. "There must be at least 2 seats")the message for the
@DecimalMax
constraint ontopSpeed
shows how to format the validated value using the formatter instancefinally, the
@DecimalMax
constraint onprice
shows that parameter interpolation has precedence over expression evaluation, causing the$
sign to show up in front of the maximum price
Only actual constraint attributes can be interpolated using message parameters in the form |
Car car = new Car( null, "A", 1, 400.123456, BigDecimal.valueOf( 200000 ) );
String message = validator.validateProperty( car, "manufacturer" )
.iterator()
.next()
.getMessage();
assertEquals( "must not be null", message );
message = validator.validateProperty( car, "licensePlate" )
.iterator()
.next()
.getMessage();
assertEquals(
"The license plate 'A' must be between 2 and 14 characters long",
message
);
message = validator.validateProperty( car, "seatCount" ).iterator().next().getMessage();
assertEquals( "There must be at least 2 seats", message );
message = validator.validateProperty( car, "topSpeed" ).iterator().next().getMessage();
assertEquals( "The top speed 400.12 is higher than 350", message );
message = validator.validateProperty( car, "price" ).iterator().next().getMessage();
assertEquals( "Price must not be higher than $100000", message );
4.2. Custom message interpolation
If the default message interpolation algorithm does not fit your requirements, it is also possible to plug in a custom MessageInterpolator
implementation.
Custom interpolators must implement the interface javax.validation.MessageInterpolator
. Note that implementations must be thread-safe. It is recommended that custom message interpolators delegate final implementation to the default interpolator, which can be obtained viaConfiguration#getDefaultMessageInterpolator()
.
In order to use a custom message interpolator it must be registered either by configuring it in the Bean Validation XML descriptor META-INF/validation.xml (see Section 8.1, “Configuring the validator factory in validation.xml”) or by passing it when bootstrapping a ValidatorFactory
or Validator
(see Section 9.2.1, “MessageInterpolator
” and Section 9.3, “Configuring a Validator”, respectively).
4.2.1. ResourceBundleLocator
In some use cases, you want to use the message interpolation algorithm as defined by the Bean Validation specification, but retrieve error messages from other resource bundles than ValidationMessages. In this situation Hibernate Validator’s ResourceBundleLocator
SPI can help.
The default message interpolator in Hibernate Validator, ResourceBundleMessageInterpolator
, delegates retrieval of resource bundles to that SPI. Using an alternative bundle only requires passing an instance of PlatformResourceBundleLocator
with the bundle name when bootstrapping the ValidatorFactory
as shown in Example 4.4, “Using a specific resource bundle”.
Validator validator = Validation.byDefaultProvider()
.configure()
.messageInterpolator(
new ResourceBundleMessageInterpolator(
new PlatformResourceBundleLocator( "MyMessages" )
)
)
.buildValidatorFactory()
.getValidator();
Of course you also could implement a completely different ResourceBundleLocator
, which for instance returns bundles backed by records in a database. In this case, you can obtain the default locator viaHibernateValidatorConfiguration#getDefaultResourceBundleLocator()
, which you e.g. could use as fall-back for your custom locator.
Besides PlatformResourceBundleLocator
, Hibernate Validator provides another resource bundle locator implementation out of the box, namely AggregateResourceBundleLocator
, which allows to retrieve error messages from more than one resource bundle. You could for instance use this implementation in a multi-module application where you want to have one message bundle per module. Example 4.5, “Using AggregateResourceBundleLocator
”shows how to use AggregateResourceBundleLocator
.
AggregateResourceBundleLocator
Validator validator = Validation.byDefaultProvider()
.configure()
.messageInterpolator(
new ResourceBundleMessageInterpolator(
new AggregateResourceBundleLocator(
Arrays.asList(
"MyMessages",
"MyOtherMessages"
)
)
)
)
.buildValidatorFactory()
.getValidator();
Note that the bundles are processed in the order as passed to the constructor. That means if several bundles contain an entry for a given message key, the value will be taken from the first bundle in the list containing the key.
5. Grouping constraints
All validation methods on Validator
and ExecutableValidator
discussed in earlier chapters also take a var-arg argument groups
. So far we have been ignoring this parameter, but it is time to have a closer look.
5.1. Requesting groups
Groups allow you to restrict the set of constraints applied during validation. One use case for validation groups are UI wizards where in each step only a specified subset of constraints should get validated. The groups targeted are passed as var-arg parameters to the appropriate validate method.
Let’s have a look at an example. The class Person
in Example 5.1, “Example class Person
” has a @NotNull
constraint on name
. Since no group is specified for this annotation the default group javax.validation.groups.Default
is assumed.
When more than one group is requested, the order in which the groups are evaluated is not deterministic. If no group is specified the default group |
Person
package org.hibernate.validator.referenceguide.chapter05;
public class Person {
@NotNull
private String name;
public Person(String name) {
this.name = name;
}
// getters and setters ...
}
The class Driver
in Example 5.2, “Driver” extends Person
and adds the properties age
and hasDrivingLicense
. Drivers must be at least 18 years old (@Min(18)
) and have a driving license (@AssertTrue
). Both constraints defined on these properties belong to the group DriverChecks
which is just a simple tagging interface.
Using interfaces makes the usage of groups type-safe and allows for easy refactoring. It also means that groups can inherit from each other via class inheritance. See Section 5.2, “Group inheritance”. |
package org.hibernate.validator.referenceguide.chapter05;
public class Driver extends Person {
@Min(
value = 18,
message = "You have to be 18 to drive a car",
groups = DriverChecks.class
)
public int age;
@AssertTrue(
message = "You first have to pass the driving test",
groups = DriverChecks.class
)
public boolean hasDrivingLicense;
public Driver(String name) {
super( name );
}
public void passedDrivingTest(boolean b) {
hasDrivingLicense = b;
}
public int getAge() {
return age;
}
public void setAge(int age) {
this.age = age;
}
}
package org.hibernate.validator.referenceguide.chapter05;
public interface DriverChecks {
}
Finally the class Car
(Example 5.3, “Car”) has some constraints which are part of the default group as well as @AssertTrue
in the group CarChecks
on the property passedVehicleInspection
which indicates whether a car passed the road worthy tests.
package org.hibernate.validator.referenceguide.chapter05;
public class Car {
@NotNull
private String manufacturer;
@NotNull
@Size(min = 2, max = 14)
private String licensePlate;
@Min(2)
private int seatCount;
@AssertTrue(
message = "The car has to pass the vehicle inspection first",
groups = CarChecks.class
)
private boolean passedVehicleInspection;
@Valid
private Driver driver;
public Car(String manufacturer, String licencePlate, int seatCount) {
this.manufacturer = manufacturer;
this.licensePlate = licencePlate;
this.seatCount = seatCount;
}
public boolean isPassedVehicleInspection() {
return passedVehicleInspection;
}
public void setPassedVehicleInspection(boolean passedVehicleInspection) {
this.passedVehicleInspection = passedVehicleInspection;
}
public Driver getDriver() {
return driver;
}
public void setDriver(Driver driver) {
this.driver = driver;
}
// getters and setters ...
}
package org.hibernate.validator.referenceguide.chapter05;
public interface CarChecks {
}
Overall three different groups are used in the example:
The constraints on
Person.name
,Car.manufacturer
,Car.licensePlate
andCar.seatCount
all belong to theDefault
groupThe constraints on
Driver.age
andDriver.hasDrivingLicense
belong toDriverChecks
The constraint on
Car.passedVehicleInspection
belongs to the groupCarChecks
Example 5.4, “Using validation groups” shows how passing different group combinations to the Validator#validate()
method results in different validation results.
// create a car and check that everything is ok with it.
Car car = new Car( "Morris", "DD-AB-123", 2 );
Set<ConstraintViolation<Car>> constraintViolations = validator.validate( car );
assertEquals( 0, constraintViolations.size() );
// but has it passed the vehicle inspection?
constraintViolations = validator.validate( car, CarChecks.class );
assertEquals( 1, constraintViolations.size() );
assertEquals(
"The car has to pass the vehicle inspection first",
constraintViolations.iterator().next().getMessage()
);
// let's go to the vehicle inspection
car.setPassedVehicleInspection( true );
assertEquals( 0, validator.validate( car, CarChecks.class ).size() );
// now let's add a driver. He is 18, but has not passed the driving test yet
Driver john = new Driver( "John Doe" );
john.setAge( 18 );
car.setDriver( john );
constraintViolations = validator.validate( car, DriverChecks.class );
assertEquals( 1, constraintViolations.size() );
assertEquals(
"You first have to pass the driving test",
constraintViolations.iterator().next().getMessage()
);
// ok, John passes the test
john.passedDrivingTest( true );
assertEquals( 0, validator.validate( car, DriverChecks.class ).size() );
// just checking that everything is in order now
assertEquals(
0, validator.validate(
car,
Default.class,
CarChecks.class,
DriverChecks.class
).size()
);
The first validate()
call in Example 5.4, “Using validation groups” is done using no explicit group. There are no validation errors, even though the property passedVehicleInspection
is per default false
as the constraint defined on this property does not belong to the default group.
The next validation using the CarChecks
group fails until the car passes the vehicle inspection. Adding a driver to the car and validating against DriverChecks
again yields one constraint violation due to the fact that the driver has not yet passed the driving test. Only after setting passedDrivingTest
to true
the validation against DriverChecks
passes.
The last validate()
call finally shows that all constraints are passing by validating against all defined groups.
5.2. Group inheritance
In Example 5.4, “Using validation groups”, we need to call validate()
for each validation group, or specify all of them one by one.
In some situations, you may want to define a group of constraints which includes another group. You can do that using group inheritance.
In Example 5.5, “SuperCar”, we define a SuperCar
and a group RaceCarChecks
that extends the Default
group. A SuperCar
must have safety belts to be allowed to run in races.
package org.hibernate.validator.referenceguide.chapter05.groupinheritance;
public class SuperCar extends Car {
@AssertTrue(
message = "Race car must have a safety belt",
groups = RaceCarChecks.class
)
private boolean safetyBelt;
// getters and setters ...
}
package org.hibernate.validator.referenceguide.chapter05.groupinheritance;
import javax.validation.groups.Default;
public interface RaceCarChecks extends Default {
}
In the example below, we will check if a SuperCar
with one seat and no security belts is a valid car and if it is a valid race-car.
// create a supercar and check that it's valid as a generic Car
SuperCar superCar = new SuperCar( "Morris", "DD-AB-123", 1 );
assertEquals( "must be greater than or equal to 2", validator.validate( superCar ).iterator().next().getMessage() );
// check that this supercar is valid as generic car and also as race car
Set<ConstraintViolation<SuperCar>> constraintViolations = validator.validate( superCar, RaceCarChecks.class );
assertThat( constraintViolations ).extracting( "message" ).containsOnly(
"Race car must have a safety belt",
"must be greater than or equal to 2"
);
On the first call to validate()
, we do not specify a group. There is one validation error because a car must have at least one seat. It is the constraint from the Default
group.
On the second call, we specify only the group RaceCarChecks
. There are two validation errors: one about the missing seat from the Default
group, another one about the fact that there is no safety belts coming from the RaceCarChecks
group.
5.3. Defining group sequences
By default, constraints are evaluated in no particular order, regardless of which groups they belong to. In some situations, however, it is useful to control the order in which constraints are evaluated.
In the example from Example 5.4, “Using validation groups” it could for instance be required that first all default car constraints are passing before checking the road worthiness of the car. Finally, before driving away, the actual driver constraints should be checked.
In order to implement such a validation order you just need to define an interface and annotate it with @GroupSequence
, defining the order in which the groups have to be validated (see Example 5.7, “Defining a group sequence”). If at least one constraint fails in a sequenced group, none of the constraints of the following groups in the sequence get validated.
package org.hibernate.validator.referenceguide.chapter05;
import javax.validation.GroupSequence;
import javax.validation.groups.Default;
@GroupSequence({ Default.class, CarChecks.class, DriverChecks.class })
public interface OrderedChecks {
}
Groups defining a sequence and groups composing a sequence must not be involved in a cyclic dependency either directly or indirectly, either through cascaded sequence definition or group inheritance. If a group containing such a circularity is evaluated, a |
You then can use the new sequence as shown in in Example 5.8, “Using a group sequence”.
Car car = new Car( "Morris", "DD-AB-123", 2 );
car.setPassedVehicleInspection( true );
Driver john = new Driver( "John Doe" );
john.setAge( 18 );
john.passedDrivingTest( true );
car.setDriver( john );
assertEquals( 0, validator.validate( car, OrderedChecks.class ).size() );
5.4. Redefining the default group sequence
5.4.1. @GroupSequence
Besides defining group sequences, the @GroupSequence
annotation also allows to redefine the default group for a given class. To do so, just add the @GroupSequence
annotation to the class and specify the sequence of groups which substitute Default
for this class within the annotation.
Example 5.9, “Class RentalCar
with redefined default group” introduces a new class RentalCar
with a redefined default group.
RentalCar
with redefined default grouppackage org.hibernate.validator.referenceguide.chapter05;
@GroupSequence({ RentalChecks.class, CarChecks.class, RentalCar.class })
public class RentalCar extends Car {
@AssertFalse(message = "The car is currently rented out", groups = RentalChecks.class)
private boolean rented;
public RentalCar(String manufacturer, String licencePlate, int seatCount) {
super( manufacturer, licencePlate, seatCount );
}
public boolean isRented() {
return rented;
}
public void setRented(boolean rented) {
this.rented = rented;
}
}
package org.hibernate.validator.referenceguide.chapter05;
public interface RentalChecks {
}
With this definition you can evaluate the constraints belonging to RentalChecks
, CarChecks
and RentalCar
by just requesting the Default
group as seen in Example 5.10, “Validating an object with redefined default group”.
RentalCar rentalCar = new RentalCar( "Morris", "DD-AB-123", 2 );
rentalCar.setPassedVehicleInspection( true );
rentalCar.setRented( true );
Set<ConstraintViolation<RentalCar>> constraintViolations = validator.validate( rentalCar );
assertEquals( 1, constraintViolations.size() );
assertEquals(
"Wrong message",
"The car is currently rented out",
constraintViolations.iterator().next().getMessage()
);
rentalCar.setRented( false );
constraintViolations = validator.validate( rentalCar );
assertEquals( 0, constraintViolations.size() );
Since there must be no cyclic dependency in the group and group sequence definitions, one cannot just add |
The Default
group sequence overriding is local to the class it is defined on and is not propagated to associated objects. For the example, this means that adding DriverChecks
to the default group sequence of RentalCar
would not have any effects. Only the group Default
will be propagated to the driver association.
Note that you can control the propagated group(s) by declaring a group conversion rule (see Section 5.5, “Group conversion”).
5.4.2. @GroupSequenceProvider
In addition to statically redefining default group sequences via @GroupSequence
, Hibernate Validator also provides an SPI for the dynamic redefinition of default group sequences depending on the object state.
For that purpose, you need to implement the interface DefaultGroupSequenceProvider
and register this implementation with the target class via the @GroupSequenceProvider
annotation. In the rental car scenario, you could for instance dynamically add the CarChecks
as seen in Example 5.11, “Implementing and using a default group sequence provider”.
package org.hibernate.validator.referenceguide.chapter05.groupsequenceprovider;
public class RentalCarGroupSequenceProvider
implements DefaultGroupSequenceProvider<RentalCar> {
@Override
public List<Class<?>> getValidationGroups(RentalCar car) {
List<Class<?>> defaultGroupSequence = new ArrayList<Class<?>>();
defaultGroupSequence.add( RentalCar.class );
if ( car != null && !car.isRented() ) {
defaultGroupSequence.add( CarChecks.class );
}
return defaultGroupSequence;
}
}
package org.hibernate.validator.referenceguide.chapter05.groupsequenceprovider;
@GroupSequenceProvider(RentalCarGroupSequenceProvider.class)
public class RentalCar extends Car {
@AssertFalse(message = "The car is currently rented out", groups = RentalChecks.class)
private boolean rented;
public RentalCar(String manufacturer, String licencePlate, int seatCount) {
super( manufacturer, licencePlate, seatCount );
}
public boolean isRented() {
return rented;
}
public void setRented(boolean rented) {
this.rented = rented;
}
}
5.5. Group conversion
What if you wanted to validate the car related checks together with the driver checks? Of course you could pass the required groups to the validate call explicitly, but what if you wanted to make these validations occur as part of the Default
group validation? Here @ConvertGroup
comes into play which allows you to use a different group than the originally requested one during cascaded validation.
Let’s have a look at Example 5.12, “@ConvertGroup
usage”. Here @GroupSequence({ CarChecks.class, Car.class })
is used to combine the car related constraints under the Default
group (see Section 5.4, “Redefining the default group sequence”). There is also a @ConvertGroup(from = Default.class, to = DriverChecks.class)
which ensures the Default
group gets converted to the DriverChecks
group during cascaded validation of the driver association.
@ConvertGroup
usagepackage org.hibernate.validator.referenceguide.chapter05.groupconversion;
public class Driver {
@NotNull
private String name;
@Min(
value = 18,
message = "You have to be 18 to drive a car",
groups = DriverChecks.class
)
public int age;
@AssertTrue(
message = "You first have to pass the driving test",
groups = DriverChecks.class
)
public boolean hasDrivingLicense;
public Driver(String name) {
this.name = name;
}
public void passedDrivingTest(boolean b) {
hasDrivingLicense = b;
}
public int getAge() {
return age;
}
public void setAge(int age) {
this.age = age;
}
// getters and setters ...
}
package org.hibernate.validator.referenceguide.chapter05.groupconversion;
@GroupSequence({ CarChecks.class, Car.class })
public class Car {
@NotNull
private String manufacturer;
@NotNull
@Size(min = 2, max = 14)
private String licensePlate;
@Min(2)
private int seatCount;
@AssertTrue(
message = "The car has to pass the vehicle inspection first",
groups = CarChecks.class
)
private boolean passedVehicleInspection;
@Valid
@ConvertGroup(from = Default.class, to = DriverChecks.class)
private Driver driver;
public Car(String manufacturer, String licencePlate, int seatCount) {
this.manufacturer = manufacturer;
this.licensePlate = licencePlate;
this.seatCount = seatCount;
}
public boolean isPassedVehicleInspection() {
return passedVehicleInspection;
}
public void setPassedVehicleInspection(boolean passedVehicleInspection) {
this.passedVehicleInspection = passedVehicleInspection;
}
public Driver getDriver() {
return driver;
}
public void setDriver(Driver driver) {
this.driver = driver;
}
// getters and setters ...
}
As a result the validation in Example 5.13, “Test case for @ConvertGroup
” succeeds, even though the constraint on hasDrivingLicense
belongs to the DriverChecks
group and only the Default
group is requested in the validate()
call.
@ConvertGroup
// create a car and validate. The Driver is still null and does not get validated
Car car = new Car( "VW", "USD-123", 4 );
car.setPassedVehicleInspection( true );
Set<ConstraintViolation<Car>> constraintViolations = validator.validate( car );
assertEquals( 0, constraintViolations.size() );
// create a driver who has not passed the driving test
Driver john = new Driver( "John Doe" );
john.setAge( 18 );
// now let's add a driver to the car
car.setDriver( john );
constraintViolations = validator.validate( car );
assertEquals( 1, constraintViolations.size() );
assertEquals(
"The driver constraint should also be validated as part of the default group",
constraintViolations.iterator().next().getMessage(),
"You first have to pass the driving test"
);
You can define group conversions wherever @Valid
can be used, namely associations as well as method and constructor parameters and return values. Multiple conversions can be specified using @ConvertGroup.List
.
However, the following restrictions apply:
@ConvertGroup
must only be used in combination with@Valid
. If used without, aConstraintDeclarationException
is thrown.It is not legal to have multiple conversion rules on the same element with the same from value. In this case, a
ConstraintDeclarationException
is raised.The
from
attribute must not refer to a group sequence. AConstraintDeclarationException
is raised in this situation.
Rules are not executed recursively. The first matching conversion rule is used and subsequent rules are ignored. For example if a set of |
6. Creating custom constraints
The Bean Validation API defines a whole set of standard constraint annotations such as @NotNull
, @Size
etc. In cases where these built-in constraints are not sufficient, you can easily create custom constraints tailored to your specific validation requirements.
6.1. Creating a simple constraint
To create a custom constraint, the following three steps are required:
Create a constraint annotation
Implement a validator
Define a default error message
6.1.1. The constraint annotation
This section shows how to write a constraint annotation which can be used to ensure that a given string is either completely upper case or lower case. Later on, this constraint will be applied to the licensePlate
field of the Car
class from Chapter 1, Getting started to ensure that the field is always an upper-case string.
The first thing needed is a way to express the two case modes. While you could use String
constants, a better approach is using an enum for that purpose:
CaseMode
to express upper vs. lower casepackage org.hibernate.validator.referenceguide.chapter06;
public enum CaseMode {
UPPER,
LOWER;
}
The next step is to define the actual constraint annotation. If you’ve never designed an annotation before, this may look a bit scary, but actually it’s not that hard:
@CheckCase
constraint annotationpackage org.hibernate.validator.referenceguide.chapter06;
import static java.lang.annotation.ElementType.ANNOTATION_TYPE;
import static java.lang.annotation.ElementType.FIELD;
import static java.lang.annotation.ElementType.METHOD;
import static java.lang.annotation.ElementType.PARAMETER;
import static java.lang.annotation.ElementType.TYPE_USE;
import static java.lang.annotation.RetentionPolicy.RUNTIME;
@Target({ FIELD, METHOD, PARAMETER, ANNOTATION_TYPE, TYPE_USE })
@Retention(RUNTIME)
@Constraint(validatedBy = CheckCaseValidator.class)
@Documented
@Repeatable(List.class)
public @interface CheckCase {
String message() default "{org.hibernate.validator.referenceguide.chapter06.CheckCase." +
"message}";
Class<?>[] groups() default { };
Class<? extends Payload>[] payload() default { };
CaseMode value();
@Target({ FIELD, METHOD, PARAMETER, ANNOTATION_TYPE })
@Retention(RUNTIME)
@Documented
@interface List {
CheckCase[] value();
}
}
An annotation type is defined using the @interface
keyword. All attributes of an annotation type are declared in a method-like manner. The specification of the Bean Validation API demands, that any constraint annotation defines:
an attribute
message
that returns the default key for creating error messages in case the constraint is violatedan attribute
groups
that allows the specification of validation groups, to which this constraint belongs (see Chapter 5, Grouping constraints). This must default to an empty array of type Class<?>.-
an attribute
payload
that can be used by clients of the Bean Validation API to assign custom payload objects to a constraint. This attribute is not used by the API itself. An example for a custom payload could be the definition of a severity:public class Severity {
public interface Info extends Payload {
} public interface Error extends Payload {
}
}public class ContactDetails {
@NotNull(message = "Name is mandatory", payload = Severity.Error.class)
private String name; @NotNull(message = "Phone number not specified, but not mandatory",
payload = Severity.Info.class)
private String phoneNumber; // ...
}Now a client can after the validation of a
ContactDetails
instance access the severity of a constraint usingConstraintViolation.getConstraintDescriptor().getPayload()
and adjust its behavior depending on the severity.
Besides these three mandatory attributes there is another one, value
, allowing for the required case mode to be specified. The name value
is a special one, which can be omitted when using the annotation, if it is the only attribute specified, as e.g. in @CheckCase(CaseMode.UPPER)
.
In addition, the constraint annotation is decorated with a couple of meta annotations:
-
@Target({ FIELD, METHOD, PARAMETER, ANNOTATION_TYPE, TYPE_USE})
: Defines the supported target element types for the constraint.@CheckCase
may be used on fields (element typeFIELD
), JavaBeans properties as well as method return values (METHOD
), method/constructor parameters (PARAMETER
) and type argument of parameterized types (TYPE_USE
). The element typeANNOTATION_TYPE
allows for the creation of composed constraints (see Section 6.4, “Constraint composition”) based on@CheckCase
.When creating a class-level constraint (see Section 2.1.4, “Class-level constraints”), the element type
TYPE
would have to be used. Constraints targeting the return value of a constructor need to support the element typeCONSTRUCTOR
. Cross-parameter constraints (see Section 6.3, “Cross-parameter constraints”) which are used to validate all the parameters of a method or constructor together, must supportMETHOD
orCONSTRUCTOR
, respectively. @Retention(RUNTIME)
: Specifies, that annotations of this type will be available at runtime by the means of reflection@Constraint(validatedBy = CheckCaseValidator.class)
: Marks the annotation type as constraint annotation and specifies the validator to be used to validate elements annotated with@CheckCase
. If a constraint may be used on several data types, several validators may be specified, one for each data type.@Documented
: Says, that the use of@CheckCase
will be contained in the JavaDoc of elements annotated with it@Repeatable(List.class)
: Indicates that the annotation can be repeated several times at the same place, usually with a different configuration.List
is the containing annotation type.
This containing annotation type named List
is also shown in the example. It allows to specify several @CheckCase
annotations on the same element, e.g. with different validation groups and messages. While another name could be used, the Bean Validation specification recommends to use the name List
and make the annotation an inner annotation of the corresponding constraint type.
6.1.2. The constraint validator
Having defined the annotation, you need to create a constraint validator, which is able to validate elements with a @CheckCase
annotation. To do so, implement the Bean Validation interface ConstraintValidator
as shown below:
@CheckCase
package org.hibernate.validator.referenceguide.chapter06;
public class CheckCaseValidator implements ConstraintValidator<CheckCase, String> {
private CaseMode caseMode;
@Override
public void initialize(CheckCase constraintAnnotation) {
this.caseMode = constraintAnnotation.value();
}
@Override
public boolean isValid(String object, ConstraintValidatorContext constraintContext) {
if ( object == null ) {
return true;
}
if ( caseMode == CaseMode.UPPER ) {
return object.equals( object.toUpperCase() );
}
else {
return object.equals( object.toLowerCase() );
}
}
}
The ConstraintValidator
interface defines two type parameters which are set in the implementation. The first one specifies the annotation type to be validated (CheckCase
), the second one the type of elements, which the validator can handle (String
). In case a constraint supports several data types, a ConstraintValidator
for each allowed type has to be implemented and registered at the constraint annotation as shown above.
The implementation of the validator is straightforward. The initialize()
method gives you access to the attribute values of the validated constraint and allows you to store them in a field of the validator as shown in the example.
The isValid()
method contains the actual validation logic. For @CheckCase
this is the check whether a given string is either completely lower case or upper case, depending on the case mode retrieved in initialize()
. Note that the Bean Validation specification recommends to consider null values as being valid. If null
is not a valid value for an element, it should be annotated with @NotNull
explicitly.
6.1.2.1. The ConstraintValidatorContext
Example 6.3, “Implementing a constraint validator for the constraint @CheckCase
” relies on the default error message generation by just returning true
or false
from the isValid()
method. Using the passed ConstraintValidatorContext
object, it is possible to either add additional error messages or completely disable the default error message generation and solely define custom error messages. The ConstraintValidatorContext
API is modeled as fluent interface and is best demonstrated with an example:
ConstraintValidatorContext
to define custom error messagespackage org.hibernate.validator.referenceguide.chapter06.constraintvalidatorcontext;
public class CheckCaseValidator implements ConstraintValidator<CheckCase, String> {
private CaseMode caseMode;
@Override
public void initialize(CheckCase constraintAnnotation) {
this.caseMode = constraintAnnotation.value();
}
@Override
public boolean isValid(String object, ConstraintValidatorContext constraintContext) {
if ( object == null ) {
return true;
}
boolean isValid;
if ( caseMode == CaseMode.UPPER ) {
isValid = object.equals( object.toUpperCase() );
}
else {
isValid = object.equals( object.toLowerCase() );
}
if ( !isValid ) {
constraintContext.disableDefaultConstraintViolation();
constraintContext.buildConstraintViolationWithTemplate(
"{org.hibernate.validator.referenceguide.chapter06." +
"constraintvalidatorcontext.CheckCase.message}"
)
.addConstraintViolation();
}
return isValid;
}
}
Example 6.4, “Using ConstraintValidatorContext
to define custom error messages” shows how you can disable the default error message generation and add a custom error message using a specified message template. In this example the use of the ConstraintValidatorContext
results in the same error message as the default error message generation.
It is important to add each configured constraint violation by calling |
Refer to Section 6.2.1, “Custom property paths” to learn how to use the ConstraintValidatorContext
API to control the property path of constraint violations for class-level constraints.
6.1.2.2. The HibernateConstraintValidator
extension
Hibernate Validator provides an extension to the ConstraintValidator
contract: HibernateConstraintValidator
.
The purpose of this extension is to provide more contextual information to the initialize()
method as, in the current ConstraintValidator
contract, only the annotation is passed as parameter.
The initialize()
method of HibernateConstraintValidator
takes two parameters:
The
ConstraintDescriptor
of the constraint at hand. You can get access to the annotation usingConstraintDescriptor#getAnnotation()
.The
HibernateConstraintValidatorInitializationContext
which provides useful helpers and contextual information, such as the clock provider or the temporal validation tolerance.
This extension is marked as incubating so it might be subject to change. The plan is to standardize it and to include it in Bean Validation in the future.
The example below shows how to base your validators on HibernateConstraintValidator
:
HibernateConstraintValidator
contractpackage org.hibernate.validator.referenceguide.chapter06;
public class MyFutureValidator implements HibernateConstraintValidator<MyFuture, Instant> {
private Clock clock;
private boolean orPresent;
@Override
public void initialize(ConstraintDescriptor<MyFuture> constraintDescriptor,
HibernateConstraintValidatorInitializationContext initializationContext) {
this.orPresent = constraintDescriptor.getAnnotation().orPresent();
this.clock = initializationContext.getClockProvider().getClock();
}
@Override
public boolean isValid(Instant instant, ConstraintValidatorContext constraintContext) {
//...
return false;
}
}
You should only implement one of the |
6.1.2.3. Passing a payload to the constraint validator
From time to time, you might want to condition the constraint validator behavior on some external parameters.
For instance, your zip code validator could vary depending on the locale of your application instance if you have one instance per country. Another requirement could be to have different behaviors on specific environments: the staging environment may not have access to some external production resources necessary for the correct functioning of a validator.
The notion of constraint validator payload was introduced for all these use cases. It is an object passed from the Validator
instance to each constraint validator via the HibernateConstraintValidatorContext
.
The example below shows how to set a constraint validator payload during the ValidatorFactory
initialization. Unless you override this default value, all the Validator
s created by this ValidatorFactory
will have this constraint validator payload value set.
ValidatorFactory
initializationValidatorFactory validatorFactory = Validation.byProvider( HibernateValidator.class )
.configure()
.constraintValidatorPayload( "US" )
.buildValidatorFactory();
Validator validator = validatorFactory.getValidator();
Another option is to set the constraint validator payload per Validator
using a context:
Validator
contextHibernateValidatorFactory hibernateValidatorFactory = Validation.byDefaultProvider()
.configure()
.buildValidatorFactory()
.unwrap( HibernateValidatorFactory.class );
Validator validator = hibernateValidatorFactory.usingContext()
.constraintValidatorPayload( "US" )
.getValidator();
// [...] US specific validation checks
validator = hibernateValidatorFactory.usingContext()
.constraintValidatorPayload( "FR" )
.getValidator();
// [...] France specific validation checks
Once you have set the constraint validator payload, it can be used in your constraint validators as shown in the example below:
package org.hibernate.validator.referenceguide.chapter06.constraintvalidatorpayload;
public class ZipCodeValidator implements ConstraintValidator<ZipCode, String> {
public String countryCode;
@Override
public boolean isValid(String object, ConstraintValidatorContext constraintContext) {
if ( object == null ) {
return true;
}
boolean isValid = false;
String countryCode = constraintContext.unwrap( HibernateConstraintValidatorContext.class )
.getConstraintValidatorPayload( String.class );
if ( "US".equals( countryCode ) ) {
// checks specific to the United States
}
else if ( "FR".equals( countryCode ) ) {
// checks specific to France
}
else {
// ...
}
return isValid;
}
}
HibernateConstraintValidatorContext#getConstraintValidatorPayload()
has a type parameter and returns the payload only if the payload is of the given type.
It is important to note that the constraint validator payload is different from the dynamic payload you can include in the constraint violation raised. The whole purpose of this constraint validator payload is to be used to condition the behavior of your constraint validators. It is not included in the constraint violations, unless a specific |
6.1.3. The error message
The last missing building block is an error message which should be used in case a @CheckCase
constraint is violated. To define this, create a file ValidationMessages.properties with the following contents (see also Section 4.1, “Default message interpolation”):
CheckCase
constraintorg.hibernate.validator.referenceguide.chapter06.CheckCase.message=Case mode must be {value}.
If a validation error occurs, the validation runtime will use the default value, that you specified for the message attribute of the @CheckCase
annotation to look up the error message in this resource bundle.
6.1.4. Using the constraint
You can now use the constraint in the Car
class from the Chapter 1, Getting started chapter to specify that the licensePlate
field should only contain upper-case strings:
@CheckCase
constraintpackage org.hibernate.validator.referenceguide.chapter06;
public class Car {
@NotNull
private String manufacturer;
@NotNull
@Size(min = 2, max = 14)
@CheckCase(CaseMode.UPPER)
private String licensePlate;
@Min(2)
private int seatCount;
public Car(String manufacturer, String licencePlate, int seatCount) {
this.manufacturer = manufacturer;
this.licensePlate = licencePlate;
this.seatCount = seatCount;
}
//getters and setters ...
}
Finally, Example 6.11, “Validating objects with the @CheckCase
constraint” demonstrates how validating a Car
instance with an invalid license plate causes the @CheckCase
constraint to be violated.
@CheckCase
constraint//invalid license plate
Car car = new Car( "Morris", "dd-ab-123", 4 );
Set<ConstraintViolation<Car>> constraintViolations =
validator.validate( car );
assertEquals( 1, constraintViolations.size() );
assertEquals(
"Case mode must be UPPER.",
constraintViolations.iterator().next().getMessage()
);
//valid license plate
car = new Car( "Morris", "DD-AB-123", 4 );
constraintViolations = validator.validate( car );
assertEquals( 0, constraintViolations.size() );
6.2. Class-level constraints
As discussed earlier, constraints can also be applied on the class level to validate the state of an entire object. Class-level constraints are defined in the same way as are property constraints. Example 6.12, “Implementing a class-level constraint”shows constraint annotation and validator of the @ValidPassengerCount
constraint you already saw in use in Example 2.9, “Class-level constraint”.
package org.hibernate.validator.referenceguide.chapter06.classlevel;
@Target({ TYPE, ANNOTATION_TYPE })
@Retention(RUNTIME)
@Constraint(validatedBy = { ValidPassengerCountValidator.class })
@Documented
public @interface ValidPassengerCount {
String message() default "{org.hibernate.validator.referenceguide.chapter06.classlevel." +
"ValidPassengerCount.message}";
Class<?>[] groups() default { };
Class<? extends Payload>[] payload() default { };
}
package org.hibernate.validator.referenceguide.chapter06.classlevel;
public class ValidPassengerCountValidator
implements ConstraintValidator<ValidPassengerCount, Car> {
@Override
public void initialize(ValidPassengerCount constraintAnnotation) {
}
@Override
public boolean isValid(Car car, ConstraintValidatorContext context) {
if ( car == null ) {
return true;
}
return car.getPassengers().size() <= car.getSeatCount();
}
}
As the example demonstrates, you need to use the element type TYPE
in the @Target
annotation. This allows the constraint to be put on type definitions. The validator of the constraint in the example receives a Car
in the isValid()
method and can access the complete object state to decide whether the given instance is valid or not.
6.2.1. Custom property paths
By default the constraint violation for a class-level constraint is reported on the level of the annotated type, e.g. Car
.
In some cases it is preferable though that the violation’s property path refers to one of the involved properties. For instance you might want to report the @ValidPassengerCount
constraint against the passengers property instead of the Car
bean.
Example 6.13, “Adding a new ConstraintViolation
with custom property path” shows how this can be done by using the constraint validator context passed to isValid()
to build a custom constraint violation with a property node for the property passengers. Note that you also could add several property nodes, pointing to a sub-entity of the validated bean.
ConstraintViolation
with custom property pathpackage org.hibernate.validator.referenceguide.chapter06.custompath;
public class ValidPassengerCountValidator
implements ConstraintValidator<ValidPassengerCount, Car> {
@Override
public void initialize(ValidPassengerCount constraintAnnotation) {
}
@Override
public boolean isValid(Car car, ConstraintValidatorContext constraintValidatorContext) {
if ( car == null ) {
return true;
}
boolean isValid = car.getPassengers().size() <= car.getSeatCount();
if ( !isValid ) {
constraintValidatorContext.disableDefaultConstraintViolation();
constraintValidatorContext
.buildConstraintViolationWithTemplate( "{my.custom.template}" )
.addPropertyNode( "passengers" ).addConstraintViolation();
}
return isValid;
}
}
6.3. Cross-parameter constraints
Bean Validation distinguishes between two different kinds of constraints.
Generic constraints (which have been discussed so far) apply to the annotated element, e.g. a type, field, container element, method parameter or return value etc. Cross-parameter constraints, in contrast, apply to the array of parameters of a method or constructor and can be used to express validation logic which depends on several parameter values.
In order to define a cross-parameter constraint, its validator class must be annotated with@SupportedValidationTarget(ValidationTarget.PARAMETERS)
. The type parameter T
from theConstraintValidator
interface must resolve to either Object
or Object[]
in order to receive the array of method/constructor arguments in the isValid()
method.
The following example shows the definition of a cross-parameter constraint which can be used to check that two Date
parameters of a method are in the correct order:
package org.hibernate.validator.referenceguide.chapter06.crossparameter;
@Constraint(validatedBy = ConsistentDateParametersValidator.class)
@Target({ METHOD, CONSTRUCTOR, ANNOTATION_TYPE })
@Retention(RUNTIME)
@Documented
public @interface ConsistentDateParameters {
String message() default "{org.hibernate.validator.referenceguide.chapter04." +
"crossparameter.ConsistentDateParameters.message}";
Class<?>[] groups() default { };
Class<? extends Payload>[] payload() default { };
}
The definition of a cross-parameter constraint isn’t any different from defining a generic constraint, i.e. it must specify the members message()
, groups()
and payload()
and be annotated with @Constraint
. This meta annotation also specifies the corresponding validator, which is shown in Example 6.15, “Generic and cross-parameter constraint”. Note that besides the element types METHOD
and CONSTRUCTOR
also ANNOTATION_TYPE
is specified as target of the annotation, in order to enable the creation of composed constraints based on @ConsistentDateParameters
(see Section 6.4, “Constraint composition”).
Cross-parameter constraints are specified directly on the declaration of a method or constructor, which is also the case for return value constraints. In order to improve code readability, it is therefore recommended to choose constraint names - such as |
package org.hibernate.validator.referenceguide.chapter06.crossparameter;
@SupportedValidationTarget(ValidationTarget.PARAMETERS)
public class ConsistentDateParametersValidator implements
ConstraintValidator<ConsistentDateParameters, Object[]> {
@Override
public void initialize(ConsistentDateParameters constraintAnnotation) {
}
@Override
public boolean isValid(Object[] value, ConstraintValidatorContext context) {
if ( value.length != 2 ) {
throw new IllegalArgumentException( "Illegal method signature" );
}
//leave null-checking to @NotNull on individual parameters
if ( value[0] == null || value[1] == null ) {
return true;
}
if ( !( value[0] instanceof Date ) || !( value[1] instanceof Date ) ) {
throw new IllegalArgumentException(
"Illegal method signature, expected two " +
"parameters of type Date."
);
}
return ( (Date) value[0] ).before( (Date) value[1] );
}
}
As discussed above, the validation target PARAMETERS
must be configured for a cross-parameter validator by using the @SupportedValidationTarget
annotation. Since a cross-parameter constraint could be applied to any method or constructor, it is considered a best practice to check for the expected number and types of parameters in the validator implementation.
As with generic constraints, null
parameters should be considered valid and @NotNull
on the individual parameters should be used to make sure that parameters are not null
.
Similar to class-level constraints, you can create custom constraint violations on single parameters instead of all parameters when validating a cross-parameter constraint. Just obtain a node builder from the |
In rare situations a constraint is both, generic and cross-parameter. This is the case if a constraint has a validator class which is annotated with @SupportedValidationTarget({ValidationTarget.PARAMETERS, ValidationTarget.ANNOTATED_ELEMENT})
or if it has a generic and a cross-parameter validator class.
When declaring such a constraint on a method which has parameters and also a return value, the intended constraint target can’t be determined. Constraints which are generic and cross-parameter at the same time must therefore define a member validationAppliesTo()
which allows the constraint user to specify the constraint’s target as shown in Example 6.16, “Generic and cross-parameter constraint”.
package org.hibernate.validator.referenceguide.chapter06.crossparameter;
@Constraint(validatedBy = {
ScriptAssertObjectValidator.class,
ScriptAssertParametersValidator.class
})
@Target({ TYPE, FIELD, PARAMETER, METHOD, CONSTRUCTOR, ANNOTATION_TYPE })
@Retention(RUNTIME)
@Documented
public @interface ScriptAssert {
String message() default "{org.hibernate.validator.referenceguide.chapter04." +
"crossparameter.ScriptAssert.message}";
Class<?>[] groups() default { };
Class<? extends Payload>[] payload() default { };
String script();
ConstraintTarget validationAppliesTo() default ConstraintTarget.IMPLICIT;
}
The @ScriptAssert
constraint has two validators (not shown), a generic and a cross-parameter one and thus defines the member validationAppliesTo()
. The default value IMPLICIT
allows to derive the target automatically in situations where this is possible (e.g. if the constraint is declared on a field or on a method which has parameters but no return value).
If the target can not be determined implicitly, it must be set by the user to either PARAMETERS
or RETURN_VALUE
as shown in Example 6.17, “Specifying the target for a generic and cross-parameter constraint”.
@ScriptAssert(script = "arg1.size() <= arg0", validationAppliesTo = ConstraintTarget.PARAMETERS)
public Car buildCar(int seatCount, List<Passenger> passengers) {
//...
return null;
}
6.4. Constraint composition
Looking at the licensePlate
field of the Car
class in Example 6.10, “Applying the @CheckCase
constraint”, you see three constraint annotations already. In more complex scenarios, where even more constraints could be applied to one element, this might easily become a bit confusing. Furthermore, if there was a licensePlate
field in another class, you would have to copy all constraint declarations to the other class as well, violating the DRY principle.
You can address this kind of problem by creating higher level constraints, composed from several basic constraints. Example 6.18, “Creating a composing constraint @ValidLicensePlate
” shows a composed constraint annotation which comprises the constraints @NotNull
, @Size
and @CheckCase
:
@ValidLicensePlate
package org.hibernate.validator.referenceguide.chapter06.constraintcomposition;
@NotNull
@Size(min = 2, max = 14)
@CheckCase(CaseMode.UPPER)
@Target({ METHOD, FIELD, ANNOTATION_TYPE, TYPE_USE })
@Retention(RUNTIME)
@Constraint(validatedBy = { })
@Documented
public @interface ValidLicensePlate {
String message() default "{org.hibernate.validator.referenceguide.chapter06." +
"constraintcomposition.ValidLicensePlate.message}";
Class<?>[] groups() default { };
Class<? extends Payload>[] payload() default { };
}
To create a composed constraint, simply annotate the constraint declaration with its comprising constraints. If the composed constraint itself requires a validator, this validator is to be specified within the @Constraint
annotation. For composed constraints which don’t need an additional validator such as @ValidLicensePlate
, just set validatedBy()
to an empty array.
Using the new composed constraint at the licensePlate
field is fully equivalent to the previous version, where the three constraints were declared directly at the field itself:
ValidLicensePlate
package org.hibernate.validator.referenceguide.chapter06.constraintcomposition;
public class Car {
@ValidLicensePlate
private String licensePlate;
//...
}
The set of ConstraintViolation
s retrieved when validating a Car
instance will contain an entry for each violated composing constraint of the @ValidLicensePlate
constraint. If you rather prefer a single ConstraintViolation
in case any of the composing constraints is violated, the @ReportAsSingleViolation
meta constraint can be used as follows:
package org.hibernate.validator.referenceguide.chapter06.constraintcomposition.reportassingle;
//...
@ReportAsSingleViolation
public @interface ValidLicensePlate {
String message() default "{org.hibernate.validator.referenceguide.chapter06." +
"constraintcomposition.reportassingle.ValidLicensePlate.message}";
Class<?>[] groups() default { };
Class<? extends Payload>[] payload() default { };
}
7. Value extraction
Value extraction is the process of extracting values from a container so that they can be validated.
It is used when dealing with container element constraints and cascaded validation inside containers.
7.1. Built-in value extractors
Hibernate Validator comes with built-in value extractors for the usual Java container types so, except if you are using your own custom container types (or the ones of external libraries such as Guava's Multimap
), you should not have to add your own value extractors.
Built-in value extractors are present for all the following container types:
java.util.Iterable
;java.util.List
;java.util.Map
: for keys and values;java.util.Optional
,java.util.OptionalInt
,java.util.OptionalLong
andjava.util.OptionalDouble
;JavaFX's
ObservableValue
(see Section 7.4, “JavaFX value extractors” for more details).
The complete list of built-in value extractors with all the details on how they behave can be found in the Bean Validation specification.
7.2. Implementing a ValueExtractor
To extract values from a custom container, one needs to implement a ValueExtractor
.
Implementing a |
ValueExtractor
is a very simple API as the only purpose of a value extractor is to provide the extracted values to a ValueReceiver
.
For instance, let’s consider the case of Guava’s Optional
. It is an easy example as we can shape its value extractor after the java.util.Optional
one:
ValueExtractor
for Guava’s Optional
package org.hibernate.validator.referenceguide.chapter07.valueextractor;
public class OptionalValueExtractor
implements ValueExtractor<Optional<@ExtractedValue ?>> {
@Override
public void extractValues(Optional<?> originalValue, ValueReceiver receiver) {
receiver.value( null, originalValue.orNull() );
}
}
Some explanations are in order:
The
@ExtractedValue
annotation marks the type argument under consideration: it is going to be used to resolve the type of the validated value;We use the
value()
method of the receiver asOptional
is a pure wrapper type;We don’t want to add a node to the property path of the constraint violation as we want the violation to be reported as if it were directly on the property so we pass a
null
node name tovalue()
.
A more interesting example is the case of Guava’s Multimap
: we would like to be able to validate both the keys and the values of this container type.
Let’s first consider the case of the values. A value extractor extracting them is required:
ValueExtractor
for Multimap
valuespackage org.hibernate.validator.referenceguide.chapter07.valueextractor;
public class MultimapValueValueExtractor
implements ValueExtractor<Multimap<?, @ExtractedValue ?>> {
@Override
public void extractValues(Multimap<?, ?> originalValue, ValueReceiver receiver) {
for ( Entry<?, ?> entry : originalValue.entries() ) {
receiver.keyedValue( "<multimap value>", entry.getKey(), entry.getValue() );
}
}
}
It allows to validate constraints for the values of the Multimap
:
Multimap
private Multimap<String, @NotBlank String> map1;
Another value extractor is required to be able to put constraints on the keys of a Multimap
:
ValueExtractor
for Multimap
keyspackage org.hibernate.validator.referenceguide.chapter07.valueextractor;
public class MultimapKeyValueExtractor
implements ValueExtractor<Multimap<@ExtractedValue ?, ?>> {
@Override
public void extractValues(Multimap<?, ?> originalValue, ValueReceiver receiver) {
for ( Object key : originalValue.keySet() ) {
receiver.keyedValue( "<multimap key>", key, key );
}
}
}
Once these two value extractors are registered, you can declare constraints on the keys and values of a Multimap
:
Multimap
private Multimap<@NotBlank String, @NotBlank String> map2;
The differences between the two value extractors may be a bit subtle at a first glance so let’s shed some light on them:
The
@ExtractedValue
annotation marks the targeted type argument (eitherK
orV
in this case).We use different node names (
<multimap key>
vs.<multimap value>
).In one case, we pass the values to the receiver (third argument of the
keyedValue()
call), in the other, we pass the keys.
Depending on your container type, you should choose the ValueReceiver
method fitting the best:
value()
-
for a simple wrapping container - it is used for
Optional
s iterableValue()
-
for an iterable container - it is used for
Set
s indexedValue()
-
for a container containing indexed values - it is used for
List
s keyedValue()
-
for a container containing keyed values - it is used for
Map
s. It is used for both the keys and the values. In the case of keys, the key is also passed as the validated value.
For all these methods, you need to pass a node name: it is the name included in the node added to the property path of the constraint violation. As mentioned earlier, if the node name is null
, no node is added to the property path: it is be useful for pure wrapper types similar to Optional
.
The choice of the method used is important as it adds contextual information to the property path of the constraint violation e.g. the index or the key of the validated value.
7.3. Non generic containers
You might have noticed that, until now, we only implemented value extractors for generic containers.
Hibernate Validator also supports value extraction for non generic containers.
Let’s take the case of java.util.OptionalInt
which wraps a primitive int
into an Optional
-like container.
A first attempt at a value extractor for OptionalInt
would look like:
ValueExtractor
for OptionalInt
package org.hibernate.validator.referenceguide.chapter07.nongeneric;
public class OptionalIntValueExtractor
implements ValueExtractor<@ExtractedValue(type = Integer.class) OptionalInt> {
@Override
public void extractValues(OptionalInt originalValue, ValueReceiver receiver) {
receiver.value( null, originalValue.isPresent() ? originalValue.getAsInt() : null );
}
}
There is an obvious thing missing for a non generic container: we don’t have a type parameter. It has two consequences:
we cannot determine the type of the validated value using the type argument;
we cannot add constraints on the type argument (e.g.
Container<@NotNull String>
).
First things first, we need a way to tell Hibernate Validator that the value extracted from an OptionalInt
is of type Integer
. As you can see in the above example, the type
attribute of the @ExtractedValue
annotation allows to provide this information to the validation engine.
Then you have to tell the validation engine that the Min
constraint you want to add to the OptionalInt
property relates to the wrapped value and not the wrapper.
Bean Validation provides the Unwrapping.Unwrap
payload for this situation:
Unwrapping.Unwrap
payload@Min(value = 5, payload = Unwrapping.Unwrap.class)
private OptionalInt optionalInt1;
If we take a step back, most - if not all - the constraints we would like to add to an OptionalInt
property would be applied to the wrapped value so having a way to make it the default would be nice.
This is exactly what the @UnwrapByDefault
annotation is for:
ValueExtractor
for OptionalInt
marked with @UnwrapByDefault
package org.hibernate.validator.referenceguide.chapter07.nongeneric;
@UnwrapByDefault
public class UnwrapByDefaultOptionalIntValueExtractor
implements ValueExtractor<@ExtractedValue(type = Integer.class) OptionalInt> {
@Override
public void extractValues(OptionalInt originalValue, ValueReceiver receiver) {
receiver.value( null, originalValue.isPresent() ? originalValue.getAsInt() : null );
}
}
When declaring this value extractor for OptionalInt
, constraint annotations will by default be applied to the wrapped value:
@UnwrapByDefault
@Min(5)
private OptionalInt optionalInt2;
Note that you can still declare an annotation for the wrapper itself by using the Unwrapping.Skip
payload:
Unwrapping.Skip
@NotNull(payload = Unwrapping.Skip.class)
@Min(5)
private OptionalInt optionalInt3;
The |
7.4. JavaFX value extractors
Bean properties in JavaFX are typically not of simple data types like String
or int
, but are wrapped in Property
types which allows to make them observable, use them for data binding etc.
Thus, value extraction is required to be able to apply constraints on the wrapped values.
The JavaFX ObservableValue
value extractor is marked with @UnwrapByDefault
. As such, the constraints hosted on the container target the wrapped value by default.
Thus, you can constrain a StringProperty
as below:
StringProperty
@NotBlank
private StringProperty stringProperty;
Or a LongProperty
:
LongProperty
@Min(5)
private LongProperty longProperty;
The iterable property types, namely ReadOnlyListProperty
, ListProperty
and their Set
and Map
counterparts are generic and, as such, container element constraints can be used. Thus, they have specific value extractors that are not marked with @UnwrapByDefault
.
A ReadOnlyListProperty
would naturally be constrained as a List
:
ReadOnlyListProperty
@Size(min = 1)
private ReadOnlyListProperty<@NotBlank String> listProperty;
7.5. Registering a ValueExtractor
Hibernate Validator does not detect automatically the value extractors in the classpath so they have to be registered.
There are several ways to register value extractors (in increasing order of priority):
- Provided by the validation engine itself
- Via the Java service loader mechanism
-
The file
META-INF/services/javax.validation.valueextraction.ValueExtractor
must be provided, with the fully-qualified names of one or more value extractor implementations as its contents, each on a separate line. - In the
META-INF/validation.xml
file -
See Section 8.1, “Configuring the validator factory in validation.xml” for more information about how to register value extractors in the XML configuration.
- By calling
Configuration#addValueExtractor(ValueExtractor<?>)
-
See Section 9.2.6, “Registering
ValueExtractor
s” for more information. - By invoking
ValidatorContext#addValueExtractor(ValueExtractor<?>)
-
It only declares the value extractor for this
Validator
instance.
A value extractor for a given type and type parameter specified at a higher priority overrides any other extractors for the same type and type parameter given at lower priorities.
7.6. Resolution algorithms
In most cases, you should not have to worry about this but, if you are overriding existing value extractors, you can find a detailed description of the value extractors resolution algorithms in the Bean Validation specification:
for cascaded validation,
and for implicit unwrapping.
One important thing to have in mind is that:
for container element constraints, the declared type is used to resolve the value extractors;
for cascaded validation, it is the runtime type.
8. Configuring via XML
So far we have used the default configuration source for Bean Validation, namely annotations. However, there also exist two kinds of XML descriptors allowing configuration via XML. The first descriptor describes general Bean Validation behaviour and is provided as META-INF/validation.xml. The second one describes constraint declarations and closely matches the constraint declaration approach via annotations. Let’s have a look at these two document types.
The XSD files are available via http://xmlns.jcp.org/xml/ns/validation/configuration andhttp://xmlns.jcp.org/xml/ns/validation/mapping. More information about the XML schemas can be found on the Bean Validation website. |
8.1. Configuring the validator factory in validation.xml
The key to enable XML configuration for Hibernate Validator is the file META-INF/validation.xml. If this file exists on the classpath its configuration will be applied when the ValidatorFactory
gets created. Figure 1, “Validation configuration schema” shows a model view of the XML schema to which validation.xml has to adhere.
Example 8.1, “validation.xml
” shows the several configuration options of validation.xml. All settings are optional and the same configuration options are also available programmatically through javax.validation.Configuration
. In fact, the XML configuration will be overridden by values explicitly specified via the programmatic API. It is even possible to ignore the XML configuration completely via Configuration#ignoreXmlConfiguration()
. See also Section 9.2, “Configuring a ValidatorFactory
”.
validation.xml
<validation-config
xmlns="http://xmlns.jcp.org/xml/ns/validation/configuration"
xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance"
xsi:schemaLocation="http://xmlns.jcp.org/xml/ns/validation/configuration
http://xmlns.jcp.org/xml/ns/validation/configuration/validation-configuration-2.0.xsd"
version="2.0">
<default-provider>com.acme.ValidationProvider</default-provider>
<message-interpolator>com.acme.MessageInterpolator</message-interpolator>
<traversable-resolver>com.acme.TraversableResolver</traversable-resolver>
<constraint-validator-factory>
com.acme.ConstraintValidatorFactory
</constraint-validator-factory>
<parameter-name-provider>com.acme.ParameterNameProvider</parameter-name-provider>
<clock-provider>com.acme.ClockProvider</clock-provider>
<value-extractor>com.acme.ContainerValueExtractor</value-extractor>
<executable-validation enabled="true">
<default-validated-executable-types>
<executable-type>CONSTRUCTORS</executable-type>
<executable-type>NON_GETTER_METHODS</executable-type>
<executable-type>GETTER_METHODS</executable-type>
</default-validated-executable-types>
</executable-validation>
<constraint-mapping>META-INF/validation/constraints-car.xml</constraint-mapping>
<property name="hibernate.validator.fail_fast">false</property>
</validation-config>
There must only be one file named META-INF/validation.xml on the classpath. If more than one is found an exception is thrown. |
The node default-provider
allows to choose the Bean Validation provider. This is useful if there is more than one provider on the classpath. message-interpolator
, traversable-resolver
, constraint-validator-factory
, parameter-name-provider
and clock-provider
allow to customize the used implementations for the interfaces MessageInterpolator
, TraversableResolver
, ConstraintValidatorFactory
, ParameterNameProvider
and ClockProvider
defined in the javax.validation
package. See the sub-sections of Section 9.2, “Configuring a ValidatorFactory
” for more information about these interfaces.
value-extractor
allows to declare additional value extractors either to extract values from custom container types or to override the built-in value extractors. See Chapter 7, Value extraction for more information about how to implement javax.validation.valueextraction.ValueExtractor
.
executable-validation
and its subnodes define defaults for method validation. The Bean Validation specification defines constructor and non getter methods as defaults. The enabled attribute acts as global switch to turn method validation on and off (see also Chapter 3, Declaring and validating method constraints).
Via the constraint-mapping
element you can list an arbitrary number of additional XML files containing the actual constraint configuration. Mapping file names must be specified using their fully-qualified name on the classpath. Details on writing mapping files can be found in the next section.
Last but not least, you can specify provider specific properties via the property
nodes. In the example, we are using the Hibernate Validator specific hibernate.validator.fail_fast
property (see Section 12.2, “Fail fast mode”).
8.2. Mapping constraints via constraint-mappings
Expressing constraints in XML is possible via files adhering to the schema seen in Figure 2, “Validation mapping schema”. Note that these mapping files are only processed if listed via constraint-mapping in validation.xml.
Example 8.2, “Bean constraints configured via XML” shows how the classes Car and RentalCar from Example 5.3, “Car”resp. Example 5.9, “Class RentalCar
with redefined default group” could be mapped in XML.
<constraint-mappings
xmlns="http://xmlns.jcp.org/xml/ns/validation/mapping"
xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance"
xsi:schemaLocation="http://xmlns.jcp.org/xml/ns/validation/mapping
http://xmlns.jcp.org/xml/ns/validation/mapping/validation-mapping-2.0.xsd"
version="2.0">
<default-package>org.hibernate.validator.referenceguide.chapter05</default-package>
<bean class="Car" ignore-annotations="true">
<field name="manufacturer">
<constraint annotation="javax.validation.constraints.NotNull"/>
</field>
<field name="licensePlate">
<constraint annotation="javax.validation.constraints.NotNull"/>
</field>
<field name="seatCount">
<constraint annotation="javax.validation.constraints.Min">
<element name="value">2</element>
</constraint>
</field>
<field name="driver">
<valid/>
</field>
<field name="partManufacturers">
<container-element-type type-argument-index="0">
<valid/>
</container-element-type>
<container-element-type type-argument-index="1">
<container-element-type>
<valid/>
<constraint annotation="javax.validation.constraints.NotNull"/>
</container-element-type>
</container-element-type>
</field>
<getter name="passedVehicleInspection" ignore-annotations="true">
<constraint annotation="javax.validation.constraints.AssertTrue">
<message>The car has to pass the vehicle inspection first</message>
<groups>
<value>CarChecks</value>
</groups>
<element name="max">10</element>
</constraint>
</getter>
</bean>
<bean class="RentalCar" ignore-annotations="true">
<class ignore-annotations="true">
<group-sequence>
<value>RentalCar</value>
<value>CarChecks</value>
</group-sequence>
</class>
</bean>
<constraint-definition annotation="org.mycompany.CheckCase">
<validated-by include-existing-validators="false">
<value>org.mycompany.CheckCaseValidator</value>
</validated-by>
</constraint-definition>
</constraint-mappings>
Example 8.3, “Method constraints configured via XML” shows how the constraints from Example 3.1, “Declaring method and constructor parameter constraints”, Example 3.4, “Declaring method and constructor return value constraints” and Example 3.3, “Specifying a constraint’s target” can be expressed in XML.
<constraint-mappings
xmlns="http://xmlns.jcp.org/xml/ns/validation/mapping"
xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance"
xsi:schemaLocation="http://xmlns.jcp.org/xml/ns/validation/mapping
http://xmlns.jcp.org/xml/ns/validation/mapping/validation-mapping-2.0.xsd"
version="2.0">
<default-package>org.hibernate.validator.referenceguide.chapter08</default-package>
<bean class="RentalStation" ignore-annotations="true">
<constructor>
<return-value>
<constraint annotation="ValidRentalStation"/>
</return-value>
</constructor>
<constructor>
<parameter type="java.lang.String">
<constraint annotation="javax.validation.constraints.NotNull"/>
</parameter>
</constructor>
<method name="getCustomers">
<return-value>
<constraint annotation="javax.validation.constraints.NotNull"/>
<constraint annotation="javax.validation.constraints.Size">
<element name="min">1</element>
</constraint>
</return-value>
</method>
<method name="rentCar">
<parameter type="Customer">
<constraint annotation="javax.validation.constraints.NotNull"/>
</parameter>
<parameter type="java.util.Date">
<constraint annotation="javax.validation.constraints.NotNull"/>
<constraint annotation="javax.validation.constraints.Future"/>
</parameter>
<parameter type="int">
<constraint annotation="javax.validation.constraints.Min">
<element name="value">1</element>
</constraint>
</parameter>
</method>
<method name="addCars">
<parameter type="java.util.List">
<container-element-type>
<valid/>
<constraint annotation="javax.validation.constraints.NotNull"/>
</container-element-type>
</parameter>
</method>
</bean>
<bean class="Garage" ignore-annotations="true">
<method name="buildCar">
<parameter type="java.util.List"/>
<cross-parameter>
<constraint annotation="ELAssert">
<element name="expression">...</element>
<element name="validationAppliesTo">PARAMETERS</element>
</constraint>
</cross-parameter>
</method>
<method name="paintCar">
<parameter type="int"/>
<return-value>
<constraint annotation="ELAssert">
<element name="expression">...</element>
<element name="validationAppliesTo">RETURN_VALUE</element>
</constraint>
</return-value>
</method>
</bean>
</constraint-mappings>
The XML configuration is closely mirroring the programmatic API. For this reason it should suffice to just add some comments. default-package
is used for all fields where a class name is expected. If the specified class is not fully qualified the configured default package will be used. Every mapping file can then have several bean nodes, each describing the constraints on the entity with the specified class name.
A given class can only be configured once across all configuration files. The same applies for constraint definitions for a given constraint annotation. It can only occur in one mapping file. If these rules are violated a |
Setting ignore-annotations
to true
means that constraint annotations placed on the configured bean are ignored. The default for this value is true. ignore-annotations
is also available for the nodes class
, fields
, getter
, constructor
, method
, parameter
, cross-parameter
and return-value
. If not explicitly specified on these levels the configured bean value applies.
The nodes class
, field
, getter
, container-element-type
, constructor
and method
(and its sub node parameter) determine on which level the constraint gets placed. The valid
node is used to enable cascaded validation and the constraint
node to add a constraint on the corresponding level. Each constraint definition must define the class via the annotation
attribute. The constraint attributes required by the Bean Validation specification (message
, groups
andpayload
) have dedicated nodes. All other constraint specific attributes are configured using the element
node.
|
The class
node also allows to reconfigure the default group sequence (see Section 5.4, “Redefining the default group sequence”) via the group-sequence
node. Not shown in the example is the use of convert-group
to specify group conversions (see Section 5.5, “Group conversion”). This node is available on field
, getter
, container-element-type
, parameter
and return-value
and specifies a from
and a to
attributes to specify the groups.
Last but not least, the list of ConstraintValidator
instances associated to a given constraint can be altered via the constraint-definition
node. The annotation attribute represents the constraint annotation being altered. The validated-by
element represent the (ordered) list of ConstraintValidator
implementations associated to the constraint. If include-existing-validator
is set to false
, validators defined on the constraint annotation are ignored. If set to true
, the list of constraint validators described in XML is concatenated to the list of validators specified on the annotation.
One use case for constraint-definition is to change the default constraint definition for Using XML to register a regular expression based constraint definition for
@URL
|
9. Bootstrapping
In Section 2.2.1, “Obtaining a Validator
instance”, you already saw one way of creating a Validator
instance - viaValidation#buildDefaultValidatorFactory()
. In this chapter, you will learn how to use the other methods in javax.validation.Validation
in order to bootstrap specifically configured validators.
9.1. Retrieving ValidatorFactory
and Validator
You obtain a Validator
by retrieving a ValidatorFactory
via one of the static methods onjavax.validation.Validation
and calling getValidator()
on the factory instance.
Example 9.1, “Bootstrapping default ValidatorFactory
and Validator
” shows how to obtain a validator from the default validator factory:
ValidatorFactory
and Validator
ValidatorFactory validatorFactory = Validation.buildDefaultValidatorFactory();
Validator validator = validatorFactory.getValidator();
The generated |
Bean Validation supports working with several providers such as Hibernate Validator within one application. If more than one provider is present on the classpath, it is not guaranteed which one is chosen when creating a factory via buildDefaultValidatorFactory()
.
In this case, you can explicitly specify the provider to use via Validation#byProvider()
, passing the provider’s ValidationProvider
class as shown in Example 9.2, “Bootstrapping ValidatorFactory
and Validator
using a specific provider”.
ValidatorFactory
and Validator
using a specific providerValidatorFactory validatorFactory = Validation.byProvider( HibernateValidator.class )
.configure()
.buildValidatorFactory();
Validator validator = validatorFactory.getValidator();
Note that the configuration object returned by configure()
allows to specifically customize the factory before calling buildValidatorFactory()
. The available options are discussed later in this chapter.
Similarly you can retrieve the default validator factory for configuration which is demonstrated in Example 9.3, “Retrieving the default ValidatorFactory
for configuration”.
ValidatorFactory
for configurationValidatorFactory validatorFactory = Validation.byDefaultProvider()
.configure()
.buildValidatorFactory();
Validator validator = validatorFactory.getValidator();
If a |
9.1.1. ValidationProviderResolver
By default, available Bean Validation providers are discovered using the Java Service Provider mechanism.
For that purpose, each provider includes the file META- INF/services/javax.validation.spi.ValidationProvider, containing the fully qualified classname of its ValidationProvider
implementation. In the case of Hibernate Validator, this isorg.hibernate.validator.HibernateValidator
.
Depending on your environment and its classloading specifics, provider discovery via the Java’s service loader mechanism might not work. In this case, you can plug in a custom ValidationProviderResolver
implementation which performs the provider retrieval. An example is OSGi, where you could implement a provider resolver which uses OSGi services for provider discovery.
To use a custom provider resolver, pass it via providerResolver()
as shown in Example 9.4, “Using a custom ValidationProviderResolver
”.
ValidationProviderResolver
package org.hibernate.validator.referenceguide.chapter09;
public class OsgiServiceDiscoverer implements ValidationProviderResolver {
@Override
public List<ValidationProvider<?>> getValidationProviders() {
//...
return null;
}
}
ValidatorFactory validatorFactory = Validation.byDefaultProvider()
.providerResolver( new OsgiServiceDiscoverer() )
.configure()
.buildValidatorFactory();
Validator validator = validatorFactory.getValidator();
9.2. Configuring a ValidatorFactory
By default, validator factories retrieved from Validation
and any validators they create are configured as per the XML descriptor META-INF/validation.xml (see Chapter 8, Configuring via XML), if present.
If you want to disable the XML based configuration, you can do so by invokingConfiguration#ignoreXmlConfiguration()
.
The different values of the XML configuration can be accessed via Configuration#getBootstrapConfiguration()
. This can for instance be helpful if you want to integrate Bean Validation into a managed environment and want to create managed instances of the objects configured via XML.
Using the fluent configuration API, you can override one or more of the settings when bootstrapping the factory. The following sections show how to make use of the different options. Note that the Configuration
class exposes the default implementations of the different extension points which can be useful if you want to use these as delegates for your custom implementations.
9.2.1. MessageInterpolator
Message interpolators are used by the validation engine to create user readable error messages from constraint message descriptors.
In case the default message interpolation algorithm described in Chapter 4, Interpolating constraint error messages is not sufficient for your needs, you can pass in your own implementation of the MessageInterpolator
interface via Configuration#messageInterpolator()
as shown in Example 9.5, “Using a custom MessageInterpolator
”.
MessageInterpolator
package org.hibernate.validator.referenceguide.chapter09;
public class MyMessageInterpolator implements MessageInterpolator {
@Override
public String interpolate(String messageTemplate, Context context) {
//...
return null;
}
@Override
public String interpolate(String messageTemplate, Context context, Locale locale) {
//...
return null;
}
}
ValidatorFactory validatorFactory = Validation.byDefaultProvider()
.configure()
.messageInterpolator( new MyMessageInterpolator() )
.buildValidatorFactory();
Validator validator = validatorFactory.getValidator();
9.2.2. TraversableResolver
In some cases the validation engine should not access the state of a bean property. The most obvious example for that is a lazily loaded property or association of a JPA entity. Validating this lazy property or association would mean that its state would have to be accessed, triggering a load from the database.
Which properties can be accessed and which ones not is controlled by querying the TraversableResolver
interface. Example 9.6, “Using a custom TraversableResolver
” shows how to use a custom traversable resolver implementation.
TraversableResolver
package org.hibernate.validator.referenceguide.chapter09;
public class MyTraversableResolver implements TraversableResolver {
@Override
public boolean isReachable(
Object traversableObject,
Node traversableProperty,
Class<?> rootBeanType,
Path pathToTraversableObject,
ElementType elementType) {
//...
return false;
}
@Override
public boolean isCascadable(
Object traversableObject,
Node traversableProperty,
Class<?> rootBeanType,
Path pathToTraversableObject,
ElementType elementType) {
//...
return false;
}
}
ValidatorFactory validatorFactory = Validation.byDefaultProvider()
.configure()
.traversableResolver( new MyTraversableResolver() )
.buildValidatorFactory();
Validator validator = validatorFactory.getValidator();
If no specific traversable resolver has been configured, the default behavior is to consider all properties as reachable and cascadable. When using Hibernate Validator together with a JPA 2 provider such as Hibernate ORM, only those properties will be considered reachable which already have been loaded by the persistence provider and all properties will be considered cascadable.
By default, the traversable resolver calls are cached per validation call. This is especially important in a JPA environment where calling isReachable()
has a significant cost.
This caching adds some overhead. In the case your custom traversable resolver is very fast, it might be better to consider turning off the cache.
You can disable the cache either via the XML configuration:
TraversableResolver
result cache via the XML configuration<?xml version="1.0" encoding="UTF-8"?>
<validation-config
xmlns="http://xmlns.jcp.org/xml/ns/validation/configuration"
xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance"
xsi:schemaLocation="http://xmlns.jcp.org/xml/ns/validation/configuration validation-configuration-2.0.xsd"
version="2.0">
<default-provider>org.hibernate.validator.HibernateValidator</default-provider>
<property name="hibernate.validator.enable_traversable_resolver_result_cache">false</property>
</validation-config>
or via the programmatic API:
TraversableResolver
result cache via the programmatic APIValidatorFactory validatorFactory = Validation.byProvider( HibernateValidator.class )
.configure()
.traversableResolver( new MyFastTraversableResolver() )
.enableTraversableResolverResultCache( false )
.buildValidatorFactory();
Validator validator = validatorFactory.getValidator();
9.2.3. ConstraintValidatorFactory
ConstraintValidatorFactory
is the extension point for customizing how constraint validators are instantiated and released.
The default ConstraintValidatorFactory
provided by Hibernate Validator requires a public no-arg constructor to instantiate ConstraintValidator
instances (see Section 6.1.2, “The constraint validator”). Using a custom ConstraintValidatorFactory
offers for example the possibility to use dependency injection in constraint validator implementations.
To configure a custom constraint validator factory call Configuration#constraintValidatorFactory()
(see Example 9.9, “Using a custom ConstraintValidatorFactory
”.
ConstraintValidatorFactory
package org.hibernate.validator.referenceguide.chapter09;
public class MyConstraintValidatorFactory implements ConstraintValidatorFactory {
@Override
public <T extends ConstraintValidator<?, ?>> T getInstance(Class<T> key) {
//...
return null;
}
@Override
public void releaseInstance(ConstraintValidator<?, ?> instance) {
//...
}
}
ValidatorFactory validatorFactory = Validation.byDefaultProvider()
.configure()
.constraintValidatorFactory( new MyConstraintValidatorFactory() )
.buildValidatorFactory();
Validator validator = validatorFactory.getValidator();
Any constraint implementations relying on |
|
9.2.4. ParameterNameProvider
In case a method or constructor parameter constraint is violated, the ParameterNameProvider
interface is used to retrieve the parameter name and make it available to the user via the property path of the constraint violation.
The default implementation returns parameter names as obtained through the Java reflection API. If you compile your sources using the -parameters
compiler flag, the actual parameter names as in the source code will be returned. Otherwise synthetic names in the form of arg0
, arg1
etc. will be used.
To use a custom parameter name provider either pass an instance of the provider during bootstrapping as shown in Example 9.10, “Using a custom ParameterNameProvider
”, or specify the fully qualified class name of the provider as value for the <parameter-name-provider>
element in the META-INF/validation.xml file (see Section 8.1, “Configuring the validator factory in validation.xml”). This is demonstrated in Example 9.10, “Using a custom ParameterNameProvider
”.
ParameterNameProvider
package org.hibernate.validator.referenceguide.chapter09;
public class MyParameterNameProvider implements ParameterNameProvider {
@Override
public List<String> getParameterNames(Constructor<?> constructor) {
//...
return null;
}
@Override
public List<String> getParameterNames(Method method) {
//...
return null;
}
}
ValidatorFactory validatorFactory = Validation.byDefaultProvider()
.configure()
.parameterNameProvider( new MyParameterNameProvider() )
.buildValidatorFactory();
Validator validator = validatorFactory.getValidator();
Hibernate Validator comes with a custom |
9.2.5. ClockProvider
and temporal validation tolerance
For time related validation (@Past
and @Future
constraints for instance), it might be useful to define what is considered now
.
This is especially important when you want to test your constraints in a reliable manner.
The reference time is defined by the ClockProvider
contract. The responsibility of the ClockProvider
is to provide a java.time.Clock
defining now
for time related validators.
ClockProvider
package org.hibernate.validator.referenceguide.chapter09;
import java.time.Clock;
import java.time.ZonedDateTime;
import javax.validation.ClockProvider;
public class FixedClockProvider implements ClockProvider {
private Clock clock;
public FixedClockProvider(ZonedDateTime dateTime) {
clock = Clock.fixed( dateTime.toInstant(), dateTime.getZone() );
}
@Override
public Clock getClock() {
return clock;
}
}
ValidatorFactory validatorFactory = Validation.byDefaultProvider()
.configure()
.clockProvider( new FixedClockProvider( ZonedDateTime.of( 2016, 6, 15, 0, 0, 0, 0, ZoneId.of( "Europe/Paris" ) ) ) )
.buildValidatorFactory();
Validator validator = validatorFactory.getValidator();
Alternatively, you can specify the fully-qualified classname of a ClockProvider
implementation using the <clock-provider>
element when configuring the default validator factory via META-INF/validation.xml (see Chapter 8, Configuring via XML).
When validating You can obtain the For instance, this might be useful if you want to replace the default message of the |
When dealing with distributed architectures, you might need some tolerance when applying temporal constraints such as @Past
or @Future
.
You can set a temporal validation tolerance by bootstrapping your ValidatorFactory
as below:
ValidatorFactory validatorFactory = Validation.byProvider( HibernateValidator.class )
.configure()
.temporalValidationTolerance( Duration.ofMillis( 10 ) )
.buildValidatorFactory();
Validator validator = validatorFactory.getValidator();
Alternatively, you can define it in the XML configuration by setting the hibernate.validator.temporal_validation_tolerance
property in your META-INF/validation.xml.
The value of this property must be a long
defining the tolerance in milliseconds.
When implementing your own temporal constraints, you might need to have access to the temporal validation tolerance. It can be obtained by calling the Note that to get access to this context at initialization, your constraint validator has to implement the |
9.2.6. Registering ValueExtractor
s
As mentioned in Chapter 7, Value extraction, additional value extractors can be registered during bootstrapping (see Section 7.5, “Registering a ValueExtractor
” for the other ways to register a value extractor).
Example 9.13, “Registering additional value extractors” shows how we would register the value extractors we previously created to extract the keys and the values of Guava’s Multimap
.
ValidatorFactory validatorFactory = Validation.byDefaultProvider()
.configure()
.addValueExtractor( new MultimapKeyValueExtractor() )
.addValueExtractor( new MultimapValueValueExtractor() )
.buildValidatorFactory();
Validator validator = validatorFactory.getValidator();
9.2.7. Adding mapping streams
As discussed earlier, you can configure the constraints applied to your Java beans using XML based constraint mappings.
Besides the mapping files specified in META-INF/validation.xml, you can add further mappings viaConfiguration#addMapping()
(see Example 9.14, “Adding constraint mapping streams”). Note that the passed input stream(s) must adhere to the XML schema for constraint mappings presented in Section 8.2, “Mapping constraints via constraint-mappings
”.
InputStream constraintMapping1 = null;
InputStream constraintMapping2 = null;
ValidatorFactory validatorFactory = Validation.byDefaultProvider()
.configure()
.addMapping( constraintMapping1 )
.addMapping( constraintMapping2 )
.buildValidatorFactory();
Validator validator = validatorFactory.getValidator();
You should close any passed input stream after the validator factory has been created.
9.2.8. Provider-specific settings
Via the configuration object returned by Validation#byProvider()
, provider specific options can be configured.
In the case of Hibernate Validator, this e.g. allows you to enable the fail fast mode and pass one or more programmatic constraint mappings as demonstrated in Example 9.15, “Setting Hibernate Validator specific options”.
ValidatorFactory validatorFactory = Validation.byProvider( HibernateValidator.class )
.configure()
.failFast( true )
.addMapping( (ConstraintMapping) null )
.buildValidatorFactory();
Validator validator = validatorFactory.getValidator();
Alternatively, provider-specific options can be passed via Configuration#addProperty()
. Hibernate Validator supports enabling the fail fast mode that way, too:
addProperty()
ValidatorFactory validatorFactory = Validation.byProvider( HibernateValidator.class )
.configure()
.addProperty( "hibernate.validator.fail_fast", "true" )
.buildValidatorFactory();
Validator validator = validatorFactory.getValidator();
Refer to Section 12.2, “Fail fast mode” and Section 12.4, “Programmatic constraint definition and declaration” to learn more about the fail fast mode and the constraint declaration API.
9.2.9. Configuring the ScriptEvaluatorFactory
For constraints like @ScriptAssert
and @ParameterScriptAssert
, it might be useful to configure how the script engines are initialized and how the script evaluators are built. This can be done by setting a custom implementation of ScriptEvaluatorFactory
.
In particular, this is important for modular environments (e.g. OSGi), where user might face issues with modular class loading and JSR 223. It also allows to use any custom script engine, not necessarily based on the JSR 223 (e.g. Spring Expression Language).
9.2.9.1. XML configuration
To specify the ScriptEvaluatorFactory
via XML, you need to define the hibernate.validator.script_evaluator_factory
property.
ScriptEvaluatorFactory
via XML<validation-config
xmlns="http://xmlns.jcp.org/xml/ns/validation/configuration"
xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance"
xsi:schemaLocation="http://xmlns.jcp.org/xml/ns/validation/configuration
http://xmlns.jcp.org/xml/ns/validation/configuration/validation-configuration-2.0.xsd"
version="2.0">
<property name="hibernate.validator.script_evaluator_factory">
org.hibernate.validator.referenceguide.chapter09.CustomScriptEvaluatorFactory
</property>
</validation-config>
In this case, the specified ScriptEvaluatorFactory
must have a no-arg constructor.
9.2.9.2. Programmatic configuration
To configure it programmatically, you need to pass an instance of ScriptEvaluatorFactory
to the ValidatorFactory
. This gives more flexibility in the configuration of the ScriptEvaluatorFactory
. Example 9.18, “Defining the ScriptEvaluatorFactory
programmatically” shows how this can be done.
ScriptEvaluatorFactory
programmaticallyValidatorFactory validatorFactory = Validation.byProvider( HibernateValidator.class )
.configure()
.scriptEvaluatorFactory( new CustomScriptEvaluatorFactory() )
.buildValidatorFactory();
Validator validator = validatorFactory.getValidator();
9.2.9.3. Custom ScriptEvaluatorFactory
implementation examples
This section shows a couple of custom ScriptEvaluatorFactory
implementations that can be used in modular environments as well as one using the Spring Expression Language for writing constraint scripts.
Problems with modular environments and JSR 223 come from the class loading. The class loader where the script engine is available might be different from the one of Hibernate Validator. Thus the script engine wouldn’t be found using the default strategy.
To solve this issue, the MultiClassLoaderScriptEvaluatorFactory
class below can be introduced:
/*
* Hibernate Validator, declare and validate application constraints
*
* License: Apache License, Version 2.0
* See the license.txt file in the root directory or <http://www.apache.org/licenses/LICENSE-2.0>.
*/
package org.hibernate.validator.osgi.scripting;
import javax.script.ScriptEngine;
import javax.script.ScriptEngineManager;
import org.hibernate.validator.spi.scripting.AbstractCachingScriptEvaluatorFactory;
import org.hibernate.validator.spi.scripting.ScriptEngineScriptEvaluator;
import org.hibernate.validator.spi.scripting.ScriptEvaluationException;
import org.hibernate.validator.spi.scripting.ScriptEvaluator;
import org.hibernate.validator.spi.scripting.ScriptEvaluatorFactory;
/**
* {@link ScriptEvaluatorFactory} that allows you to pass multiple {@link ClassLoader}s that will be used
* to search for {@link ScriptEngine}s. Useful in environments similar to OSGi, where script engines can be
* found only in {@link ClassLoader}s different from default one.
*
* @author Marko Bekhta
*/
public class MultiClassLoaderScriptEvaluatorFactory extends AbstractCachingScriptEvaluatorFactory {
private final ClassLoader[] classLoaders;
public MultiClassLoaderScriptEvaluatorFactory(ClassLoader... classLoaders) {
if ( classLoaders.length == 0 ) {
throw new IllegalArgumentException( "No class loaders were passed" );
}
this.classLoaders = classLoaders;
}
@Override
protected ScriptEvaluator createNewScriptEvaluator(String languageName) {
for ( ClassLoader classLoader : classLoaders ) {
ScriptEngine engine = new ScriptEngineManager( classLoader ).getEngineByName( languageName );
if ( engine != null ) {
return new ScriptEngineScriptEvaluator( engine );
}
}
throw new ScriptEvaluationException( "No JSR 223 script engine found for language " + languageName );
}
}
and then declared with:
Validator validator = Validation.byProvider( HibernateValidator.class )
.configure()
.scriptEvaluatorFactory(
new MultiClassLoaderScriptEvaluatorFactory( GroovyScriptEngineFactory.class.getClassLoader() )
)
.buildValidatorFactory()
.getValidator();
This way, it is possible to pass multiple ClassLoader
instances: typically the class loaders of the wanted ScriptEngine
s.
An alternative approach for OSGi environments can be to use the OsgiScriptEvaluatorFactory
defined below:
/*
* Hibernate Validator, declare and validate application constraints
*
* License: Apache License, Version 2.0
* See the license.txt file in the root directory or <http://www.apache.org/licenses/LICENSE-2.0>.
*/
package org.hibernate.validator.osgi.scripting;
import java.io.BufferedReader;
import java.io.IOException;
import java.io.InputStreamReader;
import java.net.URL;
import java.util.Arrays;
import java.util.Collections;
import java.util.Enumeration;
import java.util.List;
import java.util.Objects;
import java.util.stream.Collectors;
import java.util.stream.Stream;
import javax.script.ScriptEngineFactory;
import javax.script.ScriptEngineManager;
import javax.validation.ValidationException;
import org.hibernate.validator.spi.scripting.AbstractCachingScriptEvaluatorFactory;
import org.hibernate.validator.spi.scripting.ScriptEngineScriptEvaluator;
import org.hibernate.validator.spi.scripting.ScriptEvaluator;
import org.hibernate.validator.spi.scripting.ScriptEvaluatorFactory;
import org.hibernate.validator.spi.scripting.ScriptEvaluatorNotFoundException;
import org.osgi.framework.Bundle;
import org.osgi.framework.BundleContext;
/**
* {@link ScriptEvaluatorFactory} suitable for OSGi environments. It is created
* based on the {@code BundleContext} which is used to iterate through {@code Bundle}s and find all {@link ScriptEngineFactory}
* candidates.
*
* @author Marko Bekhta
*/
public class OsgiScriptEvaluatorFactory extends AbstractCachingScriptEvaluatorFactory {
private final List<ScriptEngineManager> scriptEngineManagers;
public OsgiScriptEvaluatorFactory(BundleContext context) {
this.scriptEngineManagers = Collections.unmodifiableList( findManagers( context ) );
}
@Override
protected ScriptEvaluator createNewScriptEvaluator(String languageName) throws ScriptEvaluatorNotFoundException {
return scriptEngineManagers.stream()
.map( manager -> manager.getEngineByName( languageName ) )
.filter( Objects::nonNull )
.map( engine -> new ScriptEngineScriptEvaluator( engine ) )
.findFirst()
.orElseThrow( () -> new ValidationException( String.format( "Unable to find script evaluator for '%s'.", languageName ) ) );
}
private List<ScriptEngineManager> findManagers(BundleContext context) {
return findFactoryCandidates( context ).stream()
.map( className -> {
try {
return new ScriptEngineManager( Class.forName( className ).getClassLoader() );
}
catch (ClassNotFoundException e) {
throw new ValidationException( "Unable to instantiate '" + className + "' based engine factory manager.", e );
}
} ).collect( Collectors.toList() );
}
/**
* Iterates through all bundles to get the available {@link ScriptEngineFactory} classes
*
* @return the names of the available ScriptEngineFactory classes
*
* @throws IOException
*/
private List<String> findFactoryCandidates(BundleContext context) {
return Arrays.stream( context.getBundles() )
.filter( Objects::nonNull ).filter( bundle ->!"system.bundle".equals( bundle.getSymbolicName())).flatMap(this::toStreamOfResourcesURL ).filter(Objects::nonNull ).flatMap( url -> toListOfFactoryCandidates( url ).stream()).collect(Collectors.toList());}privateStream<URL> toStreamOfResourcesURL(Bundle bundle){Enumeration<URL> entries = bundle.findEntries("META-INF/services","javax.script.ScriptEngineFactory",false);return entries !=null?Collections.list( entries ).stream():Stream.empty();}privateList<String> toListOfFactoryCandidates(URL url){try(BufferedReader reader =newBufferedReader(newInputStreamReader( url.openStream(),"UTF-8"))){return reader.lines().map(String::trim ).filter( line ->!line.isEmpty()).filter( line ->!line.startsWith("#")).collect(Collectors.toList());}catch(IOException e){thrownewValidationException("Unable to read the ScriptEngineFactory resource file", e );}}}
and then declared with:
Validator validator = Validation.byProvider( HibernateValidator.class )
.configure()
.scriptEvaluatorFactory(
new OsgiScriptEvaluatorFactory( FrameworkUtil.getBundle( this.getClass() ).getBundleContext() )
)
.buildValidatorFactory()
.getValidator();
It is designed specifically for OSGi environments and allows you to pass the BundleContext
which will be used to search for ScriptEngineFactory
as a parameter.
As already mentioned, you can also use script engines that are not based on JSR 223.
For instance, to use the Spring Expression Language, you can define a SpringELScriptEvaluatorFactory
as:
package org.hibernate.validator.referenceguide.chapter09;
public class SpringELScriptEvaluatorFactory extends AbstractCachingScriptEvaluatorFactory {
@Override
public ScriptEvaluator createNewScriptEvaluator(String languageName) {
if ( !"spring".equalsIgnoreCase( languageName ) ) {
throw new IllegalStateException( "Only Spring EL is supported" );
}
return new SpringELScriptEvaluator();
}
private static class SpringELScriptEvaluator implements ScriptEvaluator {
private final ExpressionParser expressionParser = new SpelExpressionParser();
@Override
public Object evaluate(String script, Map<String, Object> bindings) throws ScriptEvaluationException {
try {
Expression expression = expressionParser.parseExpression( script );
EvaluationContext context = new StandardEvaluationContext( bindings.values().iterator().next() );
for ( Entry<String, Object> binding : bindings.entrySet() ) {
context.setVariable( binding.getKey(), binding.getValue() );
}
return expression.getValue( context );
}
catch (ParseException | EvaluationException e) {
throw new ScriptEvaluationException( "Unable to evaluate SpEL script", e );
}
}
}
}
This factory allows to use Spring Expression Language in ScriptAssert
and ParameterScriptAssert
constraints:
@ScriptAssert(script = "value > 0", lang = "spring")
public class Foo {
private final int value;
private Foo(int value) {
this.value = value;
}
public int getValue() {
return value;
}
}
9.3. Configuring a Validator
When working with a configured validator factory it can occasionally be required to apply a different configuration to a single Validator
instance. Example 9.25, “Configuring a Validator
instance via usingContext()
” shows how this can be achieved by calling ValidatorFactory#usingContext()
.
Validator
instance via usingContext()
ValidatorFactory validatorFactory = Validation.buildDefaultValidatorFactory();
Validator validator = validatorFactory.usingContext()
.messageInterpolator( new MyMessageInterpolator() )
.traversableResolver( new MyTraversableResolver() )
.getValidator();
10. Using constraint metadata
The Bean Validation specification provides not only a validation engine, but also an API for retrieving constraint metadata in a uniform way, no matter whether the constraints are declared using annotations or via XML mappings. Read this chapter to learn more about this API and its possibilities. You can find all the metadata API types in the package javax.validation.metadata
.
The examples presented in this chapter are based on the classes and constraint declarations shown in Example 10.1, “Example classes”.
package org.hibernate.validator.referenceguide.chapter10;
public class Person {
public interface Basic {
}
@NotNull
private String name;
//getters and setters ...
}
package org.hibernate.validator.referenceguide.chapter10;
public interface Vehicle {
public interface Basic {
}
@NotNull(groups = Vehicle.Basic.class)
String getManufacturer();
}
package org.hibernate.validator.referenceguide.chapter10;
@ValidCar
public class Car implements Vehicle {
public interface SeverityInfo extends Payload {
}
private String manufacturer;
@NotNull
@Size(min = 2, max = 14)
private String licensePlate;
private Person driver;
private String modelName;
public Car() {
}
public Car(
@NotNull String manufacturer,
String licencePlate,
Person driver,
String modelName) {
this.manufacturer = manufacturer;
this.licensePlate = licencePlate;
this.driver = driver;
this.modelName = modelName;
}
public void driveAway(@Max(75) int speed) {
//...
}
@LuggageCountMatchesPassengerCount(
piecesOfLuggagePerPassenger = 2,
validationAppliesTo = ConstraintTarget.PARAMETERS,
payload = SeverityInfo.class,
message = "There must not be more than {piecesOfLuggagePerPassenger} pieces " +
"of luggage per passenger."
)
public void load(List<Person> passengers, List<PieceOfLuggage> luggage) {
//...
}
@Override
@Size(min = 3)
public String getManufacturer() {
return manufacturer;
}
public void setManufacturer(String manufacturer) {
this.manufacturer = manufacturer;
}
@Valid
@ConvertGroup(from = Default.class, to = Person.Basic.class)
public Person getDriver() {
return driver;
}
//further getters and setters...
}
package org.hibernate.validator.referenceguide.chapter10;
public class Library {
@NotNull
private String name;
private List<@NotNull @Valid Book> books;
//getters and setters ...
}
package org.hibernate.validator.referenceguide.chapter10;
public class Book {
@NotEmpty
private String title;
@NotEmpty
private String author;
//getters and setters ...
}
10.1. BeanDescriptor
The entry point into the metadata API is the method Validator#getConstraintsForClass()
, which returns an instance of the BeanDescriptor
interface. Using this descriptor, you can obtain metadata for constraints declared directly on the bean itself (class- or property-level), but also retrieve metadata descriptors representing single properties, methods and constructors.
Example 10.2, “Using BeanDescriptor
” demonstrates how to retrieve a BeanDescriptor
for the Car
class and how to use this descriptor in form of assertions.
If a constraint declaration hosted by the requested class is invalid, a |
BeanDescriptor
BeanDescriptor carDescriptor = validator.getConstraintsForClass( Car.class );
assertTrue( carDescriptor.isBeanConstrained() );
//one class-level constraint
assertEquals( 1, carDescriptor.getConstraintDescriptors().size() );
//manufacturer, licensePlate, driver
assertEquals( 3, carDescriptor.getConstrainedProperties().size() );
//property has constraint
assertNotNull( carDescriptor.getConstraintsForProperty( "licensePlate" ) );
//property is marked with @Valid
assertNotNull( carDescriptor.getConstraintsForProperty( "driver" ) );
//constraints from getter method in interface and implementation class are returned
assertEquals(
2,
carDescriptor.getConstraintsForProperty( "manufacturer" )
.getConstraintDescriptors()
.size()
);
//property is not constrained
assertNull( carDescriptor.getConstraintsForProperty( "modelName" ) );
//driveAway(int), load(List<Person>, List<PieceOfLuggage>)
assertEquals( 2, carDescriptor.getConstrainedMethods( MethodType.NON_GETTER ).size() );
//driveAway(int), getManufacturer(), getDriver(), load(List<Person>, List<PieceOfLuggage>)
assertEquals(
4,
carDescriptor.getConstrainedMethods( MethodType.NON_GETTER, MethodType.GETTER )
.size()
);
//driveAway(int)
assertNotNull( carDescriptor.getConstraintsForMethod( "driveAway", int.class ) );
//getManufacturer()
assertNotNull( carDescriptor.getConstraintsForMethod( "getManufacturer" ) );
//setManufacturer() is not constrained
assertNull( carDescriptor.getConstraintsForMethod( "setManufacturer", String.class ) );
//Car(String, String, Person, String)
assertEquals( 1, carDescriptor.getConstrainedConstructors().size() );
//Car(String, String, Person, String)
assertNotNull(
carDescriptor.getConstraintsForConstructor(
String.class,
String.class,
Person.class,
String.class
)
);
You can determine whether the specified class hosts any class- or property-level constraints via isBeanConstrained()
. Method or constructor constraints are not considered by isBeanConstrained()
.
The method getConstraintDescriptors()
is common to all descriptors derived from ElementDescriptor
(see Section 10.4, “ElementDescriptor
”) and returns a set of descriptors representing the constraints directly declared on the given element. In case of BeanDescriptor
, the bean’s class- level constraints are returned. More details on ConstraintDescriptor
can be found in Section 10.7, “ConstraintDescriptor
”.
Via getConstraintsForProperty()
, getConstraintsForMethod()
and getConstraintsForConstructor()
you can obtain a descriptor representing one given property or executable element, identified by its name and, in case of methods and constructors, parameter types. The different descriptor types returned by these methods are described in the following sections.
Note that these methods consider constraints declared at super-types according to the rules for constraint inheritance as described in Section 2.1.5, “Constraint inheritance”. An example is the descriptor for the manufacturer
property, which provides access to all constraints defined on Vehicle#getManufacturer()
and the implementing method Car#getManufacturer()
. null
is returned in case the specified element does not exist or is not constrained.
The methods getConstrainedProperties()
, getConstrainedMethods()
and getConstrainedConstructors()
return (potentially empty) sets with all constrained properties, methods and constructors, respectively. An element is considered constrained if it has at least one constraint or is marked for cascaded validation. When invoking getConstrainedMethods()
, you can specify the type of the methods to be returned (getters, non-getters or both).
10.2. PropertyDescriptor
The interface PropertyDescriptor
represents one given property of a class. It is transparent whether constraints are declared on a field or a property getter, provided the JavaBeans naming conventions are respected. Example 10.3, “Using PropertyDescriptor
” shows how to use the PropertyDescriptor
interface.
PropertyDescriptor
PropertyDescriptor licensePlateDescriptor = carDescriptor.getConstraintsForProperty(
"licensePlate"
);
//"licensePlate" has two constraints, is not marked with @Valid and defines no group conversions
assertEquals( "licensePlate", licensePlateDescriptor.getPropertyName() );
assertEquals( 2, licensePlateDescriptor.getConstraintDescriptors().size() );
assertTrue( licensePlateDescriptor.hasConstraints() );
assertFalse( licensePlateDescriptor.isCascaded() );
assertTrue( licensePlateDescriptor.getGroupConversions().isEmpty() );
PropertyDescriptor driverDescriptor = carDescriptor.getConstraintsForProperty( "driver" );
//"driver" has no constraints, is marked with @Valid and defines one group conversion
assertEquals( "driver", driverDescriptor.getPropertyName() );
assertTrue( driverDescriptor.getConstraintDescriptors().isEmpty() );
assertFalse( driverDescriptor.hasConstraints() );
assertTrue( driverDescriptor.isCascaded() );
assertEquals( 1, driverDescriptor.getGroupConversions().size() );
Using getConstraintDescriptors()
, you can retrieve a set of ConstraintDescriptors
providing more information on the individual constraints of a given property. The method isCascaded()
returns true
if the property is marked for cascaded validation (either using the @Valid
annotation or via XML), false
otherwise. Any configured group conversions are returned by getGroupConversions()
. See Section 10.6, “GroupConversionDescriptor
” for more details on GroupConversionDescriptor
.
10.3. MethodDescriptor
and ConstructorDescriptor
Constrained methods and constructors are represented by the interfaces MethodDescriptor
ConstructorDescriptor
, respectively. Example 10.4, “Using MethodDescriptor
and ConstructorDescriptor
” demonstrates how to work with these descriptors.
MethodDescriptor
and ConstructorDescriptor
//driveAway(int) has a constrained parameter and an unconstrained return value
MethodDescriptor driveAwayDescriptor = carDescriptor.getConstraintsForMethod(
"driveAway",
int.class
);
assertEquals( "driveAway", driveAwayDescriptor.getName() );
assertTrue( driveAwayDescriptor.hasConstrainedParameters() );
assertFalse( driveAwayDescriptor.hasConstrainedReturnValue() );
//always returns an empty set; constraints are retrievable by navigating to
//one of the sub-descriptors, e.g. for the return value
assertTrue( driveAwayDescriptor.getConstraintDescriptors().isEmpty() );
ParameterDescriptor speedDescriptor = driveAwayDescriptor.getParameterDescriptors()
.get( 0 );
//The "speed" parameter is located at index 0, has one constraint and is not cascaded
//nor does it define group conversions
assertEquals( "speed", speedDescriptor.getName() );
assertEquals( 0, speedDescriptor.getIndex() );
assertEquals( 1, speedDescriptor.getConstraintDescriptors().size() );
assertFalse( speedDescriptor.isCascaded() );
assert speedDescriptor.getGroupConversions().isEmpty();
//getDriver() has no constrained parameters but its return value is marked for cascaded
//validation and declares one group conversion
MethodDescriptor getDriverDescriptor = carDescriptor.getConstraintsForMethod(
"getDriver"
);
assertFalse( getDriverDescriptor.hasConstrainedParameters() );
assertTrue( getDriverDescriptor.hasConstrainedReturnValue() );
ReturnValueDescriptor returnValueDescriptor = getDriverDescriptor.getReturnValueDescriptor();
assertTrue( returnValueDescriptor.getConstraintDescriptors().isEmpty() );
assertTrue( returnValueDescriptor.isCascaded() );
assertEquals( 1, returnValueDescriptor.getGroupConversions().size() );
//load(List<Person>, List<PieceOfLuggage>) has one cross-parameter constraint
MethodDescriptor loadDescriptor = carDescriptor.getConstraintsForMethod(
"load",
List.class,
List.class
);
assertTrue( loadDescriptor.hasConstrainedParameters() );
assertFalse( loadDescriptor.hasConstrainedReturnValue() );
assertEquals(
1,
loadDescriptor.getCrossParameterDescriptor().getConstraintDescriptors().size()
);
//Car(String, String, Person, String) has one constrained parameter
ConstructorDescriptor constructorDescriptor = carDescriptor.getConstraintsForConstructor(
String.class,
String.class,
Person.class,
String.class
);
assertEquals( "Car", constructorDescriptor.getName() );
assertFalse( constructorDescriptor.hasConstrainedReturnValue() );
assertTrue( constructorDescriptor.hasConstrainedParameters() );
assertEquals(
1,
constructorDescriptor.getParameterDescriptors()
.get( 0 )
.getConstraintDescriptors()
.size()
);
getName()
returns the name of the given method or constructor. The methods hasConstrainedParameters()
and hasConstrainedReturnValue()
can be used to perform a quick check whether an executable element has any parameter constraints (either constraints on single parameters or cross-parameter constraints) or return value constraints.
Note that constraints are not directly exposed on MethodDescriptor
and ConstructorDescriptor
, but rather on dedicated descriptors representing an executable’s parameters, its return value and its cross-parameter constraints. To get hold of one of these descriptors, invoke getParameterDescriptors()
, getReturnValueDescriptor()
or getCrossParameterDescriptor()
, respectively.
These descriptors provide access to the element’s constraints (getConstraintDescriptors()
) and, in the case of parameters and return value, to its configuration for cascaded validation (isValid()
and getGroupConversions()
). For parameters, you also can retrieve the index and the name, as returned by the currently used parameter name provider (see Section 9.2.4, “ParameterNameProvider
”) via getName()
and getIndex()
.
Getter methods following the JavaBeans naming conventions are considered as bean properties but also as constrained methods. That means you can retrieve the related metadata either by obtaining a |
10.4. ElementDescriptor
The ElementDescriptor
interface is the common base class for the individual descriptor types such as BeanDescriptor
, PropertyDescriptor
etc. Besides getConstraintDescriptors()
it provides some more methods common to all descriptors.
hasConstraints()
allows for a quick check whether an element has any direct constraints (e.g. class- level constraints in case of BeanDescriptor
).
getElementClass()
returns the Java type of the element represented by a given descriptor. More specifically, the method returns
the object type when invoked on
BeanDescriptor
,the type of a property or parameter when invoked on
PropertyDescriptor
orParameterDescriptor
respectively,Object[].class
when invoked onCrossParameterDescriptor
,the return type when invoked on
ConstructorDescriptor
,MethodDescriptor
orReturnValueDescriptor
.void.class
will be returned for methods which don’t have a return value.
Example 10.5, “Using ElementDescriptor methods
” shows how these methods are used.
ElementDescriptor methods
PropertyDescriptor manufacturerDescriptor = carDescriptor.getConstraintsForProperty(
"manufacturer"
);
assertTrue( manufacturerDescriptor.hasConstraints() );
assertEquals( String.class, manufacturerDescriptor.getElementClass() );
CrossParameterDescriptor loadCrossParameterDescriptor = carDescriptor.getConstraintsForMethod(
"load",
List.class,
List.class
).getCrossParameterDescriptor();
assertTrue( loadCrossParameterDescriptor.hasConstraints() );
assertEquals( Object[].class, loadCrossParameterDescriptor.getElementClass() );
Finally, ElementDescriptor
offers access to the ConstraintFinder
API which allows you to query for constraint metadata in a fine grained way. Example 10.6, “Usage of ConstraintFinder
” shows how to retrieve aConstraintFinder
instance via findConstraints()
and use the API to query for constraint metadata.
ConstraintFinder
PropertyDescriptor manufacturerDescriptor = carDescriptor.getConstraintsForProperty(
"manufacturer"
);
//"manufacturer" constraints are declared on the getter, not the field
assertTrue(
manufacturerDescriptor.findConstraints()
.declaredOn( ElementType.FIELD )
.getConstraintDescriptors()
.isEmpty()
);
//@NotNull on Vehicle#getManufacturer() is part of another group
assertEquals(
1,
manufacturerDescriptor.findConstraints()
.unorderedAndMatchingGroups( Default.class )
.getConstraintDescriptors()
.size()
);
//@Size on Car#getManufacturer()
assertEquals(
1,
manufacturerDescriptor.findConstraints()
.lookingAt( Scope.LOCAL_ELEMENT )
.getConstraintDescriptors()
.size()
);
//@Size on Car#getManufacturer() and @NotNull on Vehicle#getManufacturer()
assertEquals(
2,
manufacturerDescriptor.findConstraints()
.lookingAt( Scope.HIERARCHY )
.getConstraintDescriptors()
.size()
);
//Combining several filter options
assertEquals(
1,
manufacturerDescriptor.findConstraints()
.declaredOn( ElementType.METHOD )
.lookingAt( Scope.HIERARCHY )
.unorderedAndMatchingGroups( Vehicle.Basic.class )
.getConstraintDescriptors()
.size()
);
Via declaredOn()
you can search for ConstraintDescriptors
declared on certain element types. This is useful to find property constraints declared on either fields or getter methods.
unorderedAndMatchingGroups()
restricts the resulting constraints to those matching the given validation group(s).
lookingAt()
allows to distinguish between constraints directly specified on the element (Scope.LOCAL_ELEMENT
) or constraints belonging to the element but hosted anywhere in the class hierarchy (Scope.HIERARCHY
).
You can also combine the different options as shown in the last example.
Order is not respected by |
10.5. ContainerDescriptor
and ContainerElementTypeDescriptor
The ContainerDescriptor
interface is the common interface for all the elements that support container element constraints and cascading validation (PropertyDescriptor
, ParameterDescriptor
, ReturnValueDescriptor
).
It has a single method getConstrainedContainerElementTypes()
that returns a set of ContainerElementTypeDescriptor
.
ContainerElementTypeDescriptor
extends ContainerDescriptor
to support nested container element constraints.
ContainerElementTypeDescriptor
contains the information about the container, the constraints and the cascading validation.
Example 10.7, “Using ContainerElementTypeDescriptor
” shows how to use getConstrainedContainerElementTypes()
to retrieve the set of ContainerElementTypeDescriptor
.
ContainerElementTypeDescriptor
PropertyDescriptor booksDescriptor = libraryDescriptor.getConstraintsForProperty(
"books"
);
Set<ContainerElementTypeDescriptor> booksContainerElementTypeDescriptors =
booksDescriptor.getConstrainedContainerElementTypes();
ContainerElementTypeDescriptor booksContainerElementTypeDescriptor =
booksContainerElementTypeDescriptors.iterator().next();
assertTrue( booksContainerElementTypeDescriptor.hasConstraints() );
assertTrue( booksContainerElementTypeDescriptor.isCascaded() );
assertEquals(
0,
booksContainerElementTypeDescriptor.getTypeArgumentIndex().intValue()
);
assertEquals(
List.class,
booksContainerElementTypeDescriptor.getContainerClass()
);
Set<ConstraintDescriptor<?>> constraintDescriptors =
booksContainerElementTypeDescriptor.getConstraintDescriptors();
ConstraintDescriptor<?> constraintDescriptor =
constraintDescriptors.iterator().next();
assertEquals(
NotNull.class,
constraintDescriptor.getAnnotation().annotationType()
);
10.6. GroupConversionDescriptor
All those descriptor types that represent elements which can be subject of cascaded validation (i.e., PropertyDescriptor
, ParameterDescriptor
and ReturnValueDescriptor
) provide access to the element’s group conversions via getGroupConversions()
. The returned set contains a GroupConversionDescriptor
for each configured conversion, allowing to retrieve source and target groups of the conversion. Example 10.8, “Using GroupConversionDescriptor
” shows an example.
GroupConversionDescriptor
PropertyDescriptor driverDescriptor = carDescriptor.getConstraintsForProperty( "driver" );
Set<GroupConversionDescriptor> groupConversions = driverDescriptor.getGroupConversions();
assertEquals( 1, groupConversions.size() );
GroupConversionDescriptor groupConversionDescriptor = groupConversions.iterator()
.next();
assertEquals( Default.class, groupConversionDescriptor.getFrom() );
assertEquals( Person.Basic.class, groupConversionDescriptor.getTo() );
10.7. ConstraintDescriptor
Last but not least, the ConstraintDescriptor
interface describes a single constraint together with its composing constraints. Via an instance of this interface you get access to the constraint annotation and its parameters.
Example 10.9, “Using ConstraintDescriptor
” shows how to retrieve default constraint attributes (such as message template, groups etc.) as well as custom constraint attributes (piecesOfLuggagePerPassenger
) and other metadata such as the constraint’s annotation type and its validators from a ConstraintDescriptor
.
ConstraintDescriptor
//descriptor for the @LuggageCountMatchesPassengerCount constraint on the
//load(List<Person>, List<PieceOfLuggage>) method
ConstraintDescriptor<?> constraintDescriptor = carDescriptor.getConstraintsForMethod(
"load",
List.class,
List.class
).getCrossParameterDescriptor().getConstraintDescriptors().iterator().next();
//constraint type
assertEquals(
LuggageCountMatchesPassengerCount.class,
constraintDescriptor.getAnnotation().annotationType()
);
//standard constraint attributes
assertEquals( SeverityInfo.class, constraintDescriptor.getPayload().iterator().next() );
assertEquals(
ConstraintTarget.PARAMETERS,
constraintDescriptor.getValidationAppliesTo()
);
assertEquals( Default.class, constraintDescriptor.getGroups().iterator().next() );
assertEquals(
"There must not be more than {piecesOfLuggagePerPassenger} pieces of luggage per " +
"passenger.",
constraintDescriptor.getMessageTemplate()
);
//custom constraint attribute
assertEquals(
2,
constraintDescriptor.getAttributes().get( "piecesOfLuggagePerPassenger" )
);
//no composing constraints
assertTrue( constraintDescriptor.getComposingConstraints().isEmpty() );
//validator class
assertEquals(
Arrays.<Class<?>>asList( LuggageCountMatchesPassengerCount.Validator.class ),
constraintDescriptor.getConstraintValidatorClasses()
);
11. Integrating with other frameworks
Hibernate Validator is intended to be used to implement multi-layered data validation, where constraints are expressed in a single place (the annotated domain model) and checked in various different layers of the application. For this reason there are multiple integration points with other technologies.
11.1. ORM integration
Hibernate Validator integrates with both Hibernate ORM and all pure Java Persistence providers.
When lazy loaded associations are supposed to be validated it is recommended to place the constraint on the getter of the association. Hibernate ORM replaces lazy loaded associations with proxy instances which get initialized/loaded when requested via the getter. If, in such a case, the constraint is placed on field level, the actual proxy instance is used which will lead to validation errors. |
11.1.1. Database schema-level validation
Out of the box, Hibernate ORM will translate the constraints you have defined for your entities into mapping metadata. For example, if a property of your entity is annotated @NotNull
, its columns will be declared as not null
in the DDL schema generated by Hibernate ORM.
If, for some reason, the feature needs to be disabled, set hibernate.validator.apply_to_ddl
to false
. See also Section 2.3.1, “Bean Validation constraints” and Section 2.3.2, “Additional constraints”.
You can also limit the DDL constraint generation to a subset of the defined constraints by setting the property org.hibernate.validator.group.ddl
. The property specifies the comma-separated, fully specified class names of the groups a constraint has to be part of in order to be considered for DDL schema generation.
11.1.2. Hibernate ORM event-based validation
Hibernate Validator has a built-in Hibernate event listener -org.hibernate.cfg.beanvalidation.BeanValidationEventListener
- which is part of Hibernate ORM. Whenever a PreInsertEvent
, PreUpdateEvent
or PreDeleteEvent
occurs, the listener will verify all constraints of the entity instance and throw an exception if any constraint is violated. Per default, objects will be checked before any inserts or updates are made by Hibernate ORM. Pre deletion events will per default not trigger a validation. You can configure the groups to be validated per event type using the properties javax.persistence.validation.group.pre-persist
,javax.persistence.validation.group.pre-update
and javax.persistence.validation.group.pre-remove
. The values of these properties are the comma-separated fully specified class names of the groups to validate. Example 11.1, “Manual configuration of BeanValidationEvenListener
” shows the default values for these properties. In this case they could also be omitted.
On constraint violation, the event will raise a runtime ConstraintViolationException
which contains a set of ConstraintViolation
instances describing each failure.
If Hibernate Validator is present in the classpath, Hibernate ORM will use it transparently. To avoid validation even though Hibernate Validator is in the classpath, set javax.persistence.validation.mode
to none.
If the beans are not annotated with validation annotations, there is no runtime performance cost. |
In case you need to manually set the event listeners for Hibernate ORM, use the following configuration in hibernate.cfg.xml:
BeanValidationEvenListener
<hibernate-configuration>
<session-factory>
...
<property name="javax.persistence.validation.group.pre-persist">
javax.validation.groups.Default
</property>
<property name="javax.persistence.validation.group.pre-update">
javax.validation.groups.Default
</property>
<property name="javax.persistence.validation.group.pre-remove"></property>
...
<event type="pre-update">
<listener class="org.hibernate.cfg.beanvalidation.BeanValidationEventListener"/>
</event>
<event type="pre-insert">
<listener class="org.hibernate.cfg.beanvalidation.BeanValidationEventListener"/>
</event>
<event type="pre-delete">
<listener class="org.hibernate.cfg.beanvalidation.BeanValidationEventListener"/>
</event>
</session-factory>
</hibernate-configuration>
11.1.3. JPA
If you are using JPA 2 and Hibernate Validator is in the classpath, the JPA2 specification requires that Bean Validation gets enabled. The properties javax.persistence.validation.group.pre-persist
,javax.persistence.validation.group.pre-update
and javax.persistence.validation.group.pre-remove
as described in Section 11.1.2, “Hibernate ORM event-based validation” can in this case be configured in persistence.xml. persistence.xml also defines a node validation-mode which can be set to AUTO
, CALLBACK
or NONE
. The default is AUTO
.
11.2. JSF & Seam
When working with JSF2 or JBoss Seam and Hibernate Validator (Bean Validation) is present in the runtime environment, validation is triggered for every field in the application. Example 11.2, “Usage of Bean Validation within JSF2” shows an example of the f:validateBean
tag in a JSF page. The validationGroups
attribute is optional and can be used to specify a comma separated list of validation groups. The default is javax.validation.groups.Default
. For more information refer to the Seam documentation or the JSF 2 specification.
<h:form>
<f:validateBean validationGroups="javax.validation.groups.Default">
<h:inputText value=#{model.property}/>
<h:selectOneRadio value=#{model.radioProperty}> ... </h:selectOneRadio>
<!-- other input components here -->
</f:validateBean>
</h:form>
The integration between JSF 2 and Bean Validation is described in the "Bean Validation Integration" chapter of JSR-314. It is interesting to know that JSF 2 implements a custom javax.faces.validator.BeanValidator.MESSAGE={1}: {0} The default is: javax.faces.validator.BeanValidator.MESSAGE={0} |
11.3. CDI
As of version 1.1, Bean Validation is integrated with CDI (Contexts and Dependency Injection for JavaTM EE).
This integration provides CDI managed beans for Validator
and ValidatorFactory
and enables dependency injection in constraint validators as well as custom message interpolators, traversable resolvers, constraint validator factories, parameter name providers, clock providers and value extractors.
Furthermore, parameter and return value constraints on the methods and constructors of CDI managed beans will automatically be validated upon invocation.
When your application runs on a Java EE container, this integration is enabled by default. When working with CDI in a Servlet container or in a pure Java SE environment, you can use the CDI portable extension provided by Hibernate Validator. To do so, add the portable extension to your class path as described in Section 1.1.2, “CDI”.
11.3.1. Dependency injection
CDI’s dependency injection mechanism makes it very easy to retrieve ValidatorFactory
and Validator
instances and use them in your managed beans. Just annotate instance fields of your bean with @javax.inject.Inject
as shown in Example 11.3, “Retrieving validator factory and validator via @Inject
”.
@Inject
package org.hibernate.validator.referenceguide.chapter11.cdi.validator;
@ApplicationScoped
public class RentalStation {
@Inject
private ValidatorFactory validatorFactory;
@Inject
private Validator validator;
//...
}
The injected beans are the default validator factory and validator instances. In order to configure them - e.g. to use a custom message interpolator - you can use the Bean Validation XML descriptors as discussed in Chapter 8, Configuring via XML.
If you are working with several Bean Validation providers, you can make sure that factory and validator from Hibernate Validator are injected by annotating the injection points with the @HibernateValidator
qualifier which is demonstrated in Example 11.4, “Using the @HibernateValidator
qualifier annotation”.
@HibernateValidator
qualifier annotationpackage org.hibernate.validator.referenceguide.chapter11.cdi.validator.qualifier;
@ApplicationScoped
public class RentalStation {
@Inject
@HibernateValidator
private ValidatorFactory validatorFactory;
@Inject
@HibernateValidator
private Validator validator;
//...
}
The fully-qualified name of the qualifier annotation is |
Via @Inject
you also can inject dependencies into constraint validators and other Bean Validation objects such as MessageInterpolator
implementations etc.
Example 11.5, “Constraint validator with injected bean” demonstrates how an injected CDI bean is used in a ConstraintValidator
implementation to determine whether the given constraint is valid or not. As the example shows, you also can work with the @PostConstruct
and @PreDestroy
callbacks to implement any required construction and destruction logic.
package org.hibernate.validator.referenceguide.chapter11.cdi.injection;
public class ValidLicensePlateValidator
implements ConstraintValidator<ValidLicensePlate, String> {
@Inject
private VehicleRegistry vehicleRegistry;
@PostConstruct
public void postConstruct() {
//do initialization logic...
}
@PreDestroy
public void preDestroy() {
//do destruction logic...
}
@Override
public void initialize(ValidLicensePlate constraintAnnotation) {
}
@Override
public boolean isValid(String licensePlate, ConstraintValidatorContext constraintContext) {
return vehicleRegistry.isValidLicensePlate( licensePlate );
}
}
11.3.2. Method validation
The method interception facilities of CDI allow for a very tight integration with Bean Validation’s method validation functionality. Just put constraint annotations to the parameters and return values of the executables of your CDI beans and they will be validated automatically before (parameter constraints) and after (return value constraints) a method or constructor is invoked.
Note that no explicit interceptor binding is required, instead the required method validation interceptor will automatically be registered for all managed beans with constrained methods and constructors.
The interceptor |
You can see an example in Example 11.6, “CDI managed beans with method-level constraints”.
package org.hibernate.validator.referenceguide.chapter11.cdi.methodvalidation;
@ApplicationScoped
public class RentalStation {
@Valid
public RentalStation() {
//...
}
@NotNull
@Valid
public Car rentCar(
@NotNull Customer customer,
@NotNull @Future Date startDate,
@Min(1) int durationInDays) {
//...
return null;
}
@NotNull
List<Car> getAvailableCars() {
//...
return null;
}
}
package org.hibernate.validator.referenceguide.chapter11.cdi.methodvalidation;
@RequestScoped
public class RentCarRequest {
@Inject
private RentalStation rentalStation;
public void rentCar(String customerId, Date startDate, int duration) {
//causes ConstraintViolationException
rentalStation.rentCar( null, null, -1 );
}
}
Here the RentalStation
bean hosts several method constraints. When invoking one of the RentalStation
methods from another bean such as RentCarRequest
, the constraints of the invoked method are automatically validated. If any illegal parameter values are passed as in the example, a ConstraintViolationException
will be thrown by the method interceptor, providing detailed information on the violated constraints. The same is the case if the method’s return value violates any return value constraints.
Similarly, constructor constraints are validated automatically upon invocation. In the example the RentalStation
object returned by the constructor will be validated since the constructor return value is marked with @Valid
.
11.3.2.1. Validated executable types
Bean Validation allows for a fine-grained control of the executable types which are automatically validated. By default, constraints on constructors and non-getter methods are validated. Therefore the @NotNull
constraint on the method RentalStation#getAvailableCars()
in Example 11.6, “CDI managed beans with method-level constraints” does not get validated when the method is invoked.
You have the following options to configure which types of executables are validated upon invocation:
Configure the executable types globally via the XML descriptor META-INF/validation.xml; see Section 8.1, “Configuring the validator factory in validation.xml” for an example
Use the
@ValidateOnExecution
annotation on the executable or type level
If several sources of configuration are specified for a given executable, @ValidateOnExecution
on the executable level takes precedence over @ValidateOnExecution
on the type level and @ValidateOnExecution
generally takes precedence over the globally configured types in META- INF/validation.xml.
Example 11.7, “Using @ValidateOnExecution
” shows how to use the @ValidateOnExecution
annotation:
@ValidateOnExecution
package org.hibernate.validator.referenceguide.chapter11.cdi.methodvalidation.configuration;
@ApplicationScoped
@ValidateOnExecution(type = ExecutableType.ALL)
public class RentalStation {
@Valid
public RentalStation() {
//...
}
@NotNull
@Valid
@ValidateOnExecution(type = ExecutableType.NONE)
public Car rentCar(
@NotNull Customer customer,
@NotNull @Future Date startDate,
@Min(1) int durationInDays) {
//...
return null;
}
@NotNull
public List<Car> getAvailableCars() {
//...
return null;
}
}
Here the method rentCar()
won’t be validated upon invocation because it is annotated with@ValidateOnExecution(type = ExecutableType.NONE)
. In contrast, the constructor and the method getAvailableCars()
will be validated due to @ValidateOnExecution(type = ExecutableType.ALL)
being given on the type level. ExecutableType.ALL
is a more compact form for explicitly specifying all the types CONSTRUCTORS
, GETTER_METHODS
and NON_GETTER_METHODS
.
Executable validation can be turned off globally by specifying |
Note that when a method overrides or implements a super-type method, the configuration will be taken from that overridden or implemented method (as given via @ValidateOnExecution
on the method itself or on the super-type). This protects a client of the super-type method from an unexpected alteration of the configuration, e.g. disabling validation of an overridden executable in a sub-type.
In case a CDI managed bean overrides or implements a super-type method and this super-type method hosts any constraints, it can happen that the validation interceptor is not properly registered with the bean, resulting in the bean’s methods not being validated upon invocation. In this case you can specify the executable type IMPLICIT
on the sub-class as shown in Example 11.8, “Using ExecutableType.IMPLICIT
”, which makes sure that all required metadata is discovered and the validation interceptor kicks in when the methods on ExpressRentalStation
are invoked.
ExecutableType.IMPLICIT
package org.hibernate.validator.referenceguide.chapter11.cdi.methodvalidation.implicit;
@ValidateOnExecution(type = ExecutableType.ALL)
public interface RentalStation {
@NotNull
@Valid
Car rentCar(
@NotNull Customer customer,
@NotNull @Future Date startDate,
@Min(1) int durationInDays);
@NotNull
List<Car> getAvailableCars();
}
package org.hibernate.validator.referenceguide.chapter11.cdi.methodvalidation.implicit;
@ApplicationScoped
@ValidateOnExecution(type = ExecutableType.IMPLICIT)
public class ExpressRentalStation implements RentalStation {
@Override
public Car rentCar(Customer customer, Date startDate, @Min(1) int durationInDays) {
//...
return null;
}
@Override
public List<Car> getAvailableCars() {
//...
return null;
}
}
11.4. Java EE
When your application runs on a Java EE application server such as WildFly, you also can obtain Validator
and ValidatorFactory
instances via @Resource
injection in managed objects such as EJBs etc., as shown in Example 11.9, “Retrieving Validator
and ValidatorFactory
via @Resource
injection”.
Validator
and ValidatorFactory
via @Resource
injectionpackage org.hibernate.validator.referenceguide.chapter11.javaee;
public class RentalStationBean {
@Resource
private ValidatorFactory validatorFactory;
@Resource
private Validator validator;
//...
}
Alternatively you can obtain a validator and a validator factory from JNDI under the names "java:comp/Validator" and "java:comp/ValidatorFactory", respectively.
Similar to CDI-based injection via @Inject
, these objects represent default validator and validator factory and thus can be configured using the XML descriptor META-INF/validation.xml (see Chapter 8, Configuring via XML).
When your application is CDI-enabled, the injected objects are CDI-aware as well and e.g. support dependency injection in constraint validators.
11.5. JavaFX
Hibernate Validator also provides support for the unwrapping of JavaFX properties. If JavaFX is present on the classpath, ValueExtractor
s for JavaFX properties are automatically registered. See Section 7.4, “JavaFX value extractors” for examples and further discussion.
12. Hibernate Validator Specifics
In this chapter you will learn how to make use of several features provided by Hibernate Validator in addition to the functionality defined by the Bean Validation specification. This includes the fail fast mode, the API for programmatic constraint configuration and the boolean composition of constraints.
New APIs or SPIs are tagged with the org.hibernate.validator.Incubating
annotation as long as they are under development. This means that such elements (e.g. packages, types, methods, constants etc.) may be incompatibly altered - or removed - in subsequent releases. Usage of incubating API/SPI members is encouraged (so the development team can get feedback on these new features) but you should be prepared for updating code which is using them as needed when upgrading to a new version of Hibernate Validator.
Using the features described in the following sections may result in application code which is not portable between Bean Validation providers. |
12.1. Public API
Let’s start, however, with a look at the public API of Hibernate Validator. Below you can find a list of all packages belonging to this API and their purpose. Note that when a package is part of the public API this is not necessarily true for its sub-packages.
org.hibernate.validator
-
Classes used by the Bean Validation bootstrap mechanism (eg. validation provider, configuration class); for more details see Chapter 9, Bootstrapping.
-
org.hibernate.validator.cfg
,org.hibernate.validator.cfg.context
,org.hibernate.validator.cfg.defs
,org.hibernate.validator.spi.cfg
-
Hibernate Validator’s fluent API for constraint declaration; in
org.hibernate.validator.cfg
you will find theConstraintMapping
interface, inorg.hibernate.validator.cfg.defs
all constraint definitions and inorg.hibernate.validator.spi.cfg
a callback for using the API for configuring the default validator factory. Refer to Section 12.4, “Programmatic constraint definition and declaration” for the details. -
org.hibernate.validator.constraints
,org.hibernate.validator.constraints.br
,org.hibernate.validator.constraints.pl
-
Some useful custom constraints provided by Hibernate Validator in addition to the built-in constraints defined by the Bean Validation specification; the constraints are described in detail in Section 2.3.2, “Additional constraints”.
org.hibernate.validator.constraintvalidation
-
Extended constraint validator context which allows to set custom attributes for message interpolation. Section 12.11.1, “
HibernateConstraintValidatorContext
” describes how to make use of that feature. -
org.hibernate.validator.group
,org.hibernate.validator.spi.group
-
The group sequence provider feature which allows you to define dynamic default group sequences in function of the validated object state; the specifics can be found in Section 5.4, “Redefining the default group sequence”.
-
org.hibernate.validator.messageinterpolation
,org.hibernate.validator.resourceloading
,org.hibernate.validator.spi.resourceloading
-
Classes related to constraint message interpolation; the first package contains Hibernate Validator’s default message interpolator,
ResourceBundleMessageInterpolator
. The latter two packages provide theResourceBundleLocator
SPI for the loading of resource bundles (see Section 4.2.1, “ResourceBundleLocator
”) and its default implementation. org.hibernate.validator.parameternameprovider
-
A
ParameterNameProvider
based on the Paranamer library, see Section 12.12, “Paranamer basedParameterNameProvider
”. org.hibernate.validator.propertypath
-
Extensions to the
javax.validation.Path
API, see Section 12.7, “Extensions of the Path API”. org.hibernate.validator.spi.constraintdefinition
-
An SPI for registering additional constraint validators programmatically, see Section 12.13, “Providing constraint definitions”.
The public packages of Hibernate Validator fall into two categories: while the actual API parts are intended to be invoked or used by clients (e.g. the API for programmatic constraint declaration or the custom constraints), the SPI (service provider interface) packages contain interfaces which are intended to be implemented by clients (e.g. |
Any packages not listed in that table are internal packages of Hibernate Validator and are not intended to be accessed by clients. The contents of these internal packages can change from release to release without notice, thus possibly breaking any client code relying on it.
12.2. Fail fast mode
Using the fail fast mode, Hibernate Validator allows to return from the current validation as soon as the first constraint violation occurs. This can be useful for the validation of large object graphs where you are only interested in a quick check whether there is any constraint violation at all.
Example 12.1, “Using the fail fast validation mode” shows how to bootstrap and use a fail fast enabled validator.
package org.hibernate.validator.referenceguide.chapter12.failfast;
public class Car {
@NotNull
private String manufacturer;
@AssertTrue
private boolean isRegistered;
public Car(String manufacturer, boolean isRegistered) {
this.manufacturer = manufacturer;
this.isRegistered = isRegistered;
}
//getters and setters...
}
Validator validator = Validation.byProvider( HibernateValidator.class )
.configure()
.failFast( true )
.buildValidatorFactory()
.getValidator();
Car car = new Car( null, false );
Set<ConstraintViolation<Car>> constraintViolations = validator.validate( car );
assertEquals( 1, constraintViolations.size() );
Here the validated object actually fails to satisfy both the constraints declared on the Car
class, yet the validation call yields only one ConstraintViolation
since the fail fast mode is enabled.
There is no guarantee in which order the constraints are evaluated, i.e. it is not deterministic whether the returned violation originates from the |
Refer to Section 9.2.8, “Provider-specific settings” to learn about the different ways of enabling the fail fast mode when bootstrapping a validator.
12.3. Relaxation of requirements for method validation in class hierarchies
The Bean Validation specification defines a set of preconditions which apply when defining constraints on methods within class hierarchies. These preconditions are defined in section 5.6.5 of the Bean Validation 2.0 specification. See also Section 3.1.4, “Method constraints in inheritance hierarchies” in this guide.
As per specification, a Bean Validation provider is allowed to relax these preconditions. With Hibernate Validator you can do this in one of two ways.
First you can use the configuration properties hibernate.validator.allow_parameter_constraint_override,hibernate.validator.allow_multiple_cascaded_validation_on_result andhibernate.validator.allow_parallel_method_parameter_constraint in validation.xml. See example Example 12.2, “Configuring method validation behaviour in class hierarchies via properties”.
<?xml version="1.0" encoding="UTF-8"?>
<validation-config
xmlns="http://xmlns.jcp.org/xml/ns/validation/configuration"
xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance"
xsi:schemaLocation="http://xmlns.jcp.org/xml/ns/validation/configuration validation-configuration-2.0.xsd"
version="2.0">
<default-provider>org.hibernate.validator.HibernateValidator</default-provider>
<property name="hibernate.validator.allow_parameter_constraint_override">true</property>
<property name="hibernate.validator.allow_multiple_cascaded_validation_on_result">true</property>
<property name="hibernate.validator.allow_parallel_method_parameter_constraint">true</property>
</validation-config>
Alternatively these settings can be applied during programmatic bootstrapping.
HibernateValidatorConfiguration configuration = Validation.byProvider( HibernateValidator.class ).configure();
configuration.allowMultipleCascadedValidationOnReturnValues( true )
.allowOverridingMethodAlterParameterConstraint( true )
.allowParallelMethodsDefineParameterConstraints( true );
By default, all of these properties are false, implementing the default behavior as defined in the Bean Validation specification.
Changing the default behaviour for method validation will result in non specification-conforming and non portable application. Make sure to understand what you are doing and that your use case really requires changes to the default behaviour. |
12.4. Programmatic constraint definition and declaration
As per the Bean Validation specification, you can define and declare constraints using Java annotations and XML based constraint mappings.
In addition, Hibernate Validator provides a fluent API which allows for the programmatic configuration of constraints. Use cases include the dynamic addition of constraints at runtime depending on some application state or tests where you need entities with different constraints in different scenarios but don’t want to implement actual Java classes for each test case.
By default, constraints added via the fluent API are additive to constraints configured via the standard configuration capabilities. But it is also possible to ignore annotation and XML configured constraints where required.
The API is centered around the ConstraintMapping
interface. You obtain a new mapping viaHibernateValidatorConfiguration#createConstraintMapping()
which you then can configure in a fluent manner as shown in Example 12.4, “Programmatic constraint declaration”.
HibernateValidatorConfiguration configuration = Validation
.byProvider( HibernateValidator.class )
.configure();
ConstraintMapping constraintMapping = configuration.createConstraintMapping();
constraintMapping
.type( Car.class )
.property( "manufacturer", FIELD )
.constraint( new NotNullDef() )
.property( "licensePlate", FIELD )
.ignoreAnnotations( true )
.constraint( new NotNullDef() )
.constraint( new SizeDef().min( 2 ).max( 14 ) )
.type( RentalCar.class )
.property( "rentalStation", METHOD )
.constraint( new NotNullDef() );
Validator validator = configuration.addMapping( constraintMapping )
.buildValidatorFactory()
.getValidator();
Constraints can be configured on multiple classes and properties using method chaining. The constraint definition classes NotNullDef
and SizeDef are helper classes which allow to configure constraint parameters in a type-safe fashion. Definition classes exist for all built-in constraints in the org.hibernate.validator.cfg.defs
package. By calling ignoreAnnotations()
any constraints configured via annotations or XML are ignored for the given element.
Each element (type, property, method etc.) may only be configured once within all the constraint mappings used to set up one validator factory. Otherwise a |
It is not supported to add constraints to non-overridden supertype properties and methods by configuring a subtype. Instead you need to configure the supertype in this case. |
Having configured the mapping, you must add it back to the configuration object from which you then can obtain a validator factory.
For custom constraints, you can either create your own definition classes extending ConstraintDef
or you can use GenericConstraintDef
as seen in Example 12.5, “Programmatic declaration of a custom constraint”.
ConstraintMapping constraintMapping = configuration.createConstraintMapping();
constraintMapping
.type( Car.class )
.property( "licensePlate", FIELD )
.constraint( new GenericConstraintDef<>( CheckCase.class )
.param( "value", CaseMode.UPPER )
);
Container element constraints are supported by the programmatic API, using containerElementType()
.
Example 12.6, “Programmatic declaration of a nested container element constraint” show an example where constraints are declared on nested container elements.
ConstraintMapping constraintMapping = configuration.createConstraintMapping();
constraintMapping
.type( Car.class )
.property( "manufacturer", FIELD )
.constraint( new NotNullDef() )
.property( "licensePlate", FIELD )
.ignoreAnnotations( true )
.constraint( new NotNullDef() )
.constraint( new SizeDef().min( 2 ).max( 14 ) )
.property( "partManufacturers", FIELD )
.containerElementType( 0 )
.constraint( new NotNullDef() )
.containerElementType( 1, 0 )
.constraint( new NotNullDef() )
.type( RentalCar.class )
.property( "rentalStation", METHOD )
.constraint( new NotNullDef() );
As demonstrated, the parameters passed to containerElementType()
are the path of type argument indexes used to obtain the desired nested container element type.
By invoking valid()
you can mark a member for cascaded validation which is equivalent to annotating it with @Valid
. Configure any group conversions to be applied during cascaded validation using the convertGroup()
method (equivalent to @ConvertGroup
). An example can be seen in Example 12.7, “Marking a property for cascaded validation”.
ConstraintMapping constraintMapping = configuration.createConstraintMapping();
constraintMapping
.type( Car.class )
.property( "driver", FIELD )
.constraint( new NotNullDef() )
.valid()
.convertGroup( Default.class ).to( PersonDefault.class )
.property( "partManufacturers", FIELD )
.containerElementType( 0 )
.valid()
.containerElementType( 1, 0 )
.valid()
.type( Person.class )
.property( "name", FIELD )
.constraint( new NotNullDef().groups( PersonDefault.class ) );
You can not only configure bean constraints using the fluent API but also method and constructor constraints. As shown in Example 12.8, “Programmatic declaration of method and constructor constraints” constructors are identified by their parameter types and methods by their name and parameter types. Having selected a method or constructor, you can mark its parameters and/or return value for cascaded validation and add constraints as well as cross-parameter constraints.
As shown in the example, valid()
can be also invoked on a container element type.
ConstraintMapping constraintMapping = configuration.createConstraintMapping();
constraintMapping
.type( Car.class )
.constructor( String.class )
.parameter( 0 )
.constraint( new SizeDef().min( 3 ).max( 50 ) )
.returnValue()
.valid()
.method( "drive", int.class )
.parameter( 0 )
.constraint( new MaxDef().value( 75 ) )
.method( "load", List.class, List.class )
.crossParameter()
.constraint( new GenericConstraintDef<>(
LuggageCountMatchesPassengerCount.class ).param(
"piecesOfLuggagePerPassenger", 2
)
)
.method( "getDriver" )
.returnValue()
.constraint( new NotNullDef() )
.valid();
Last but not least you can configure the default group sequence or the default group sequence provider of a type as shown in the following example.
ConstraintMapping constraintMapping = configuration.createConstraintMapping();
constraintMapping
.type( Car.class )
.defaultGroupSequence( Car.class, CarChecks.class )
.type( RentalCar.class )
.defaultGroupSequenceProviderClass( RentalCarGroupSequenceProvider.class );
12.5. Applying programmatic constraint declarations to the default validator factory
If you are not bootstrapping a validator factory manually but work with the default factory as configured via META-INF/validation.xml (see Chapter 8, Configuring via XML), you can add one or more constraint mappings by creating one or several constraint mapping contributors. To do so, implement the ConstraintMappingContributor
contract:
ConstraintMappingContributor
implementationpackage org.hibernate.validator.referenceguide.chapter12.constraintapi;
public class MyConstraintMappingContributor implements ConstraintMappingContributor {
@Override
public void createConstraintMappings(ConstraintMappingBuilder builder) {
builder.addConstraintMapping()
.type( Marathon.class )
.property( "name", METHOD )
.constraint( new NotNullDef() )
.property( "numberOfHelpers", FIELD )
.constraint( new MinDef().value( 1 ) );
builder.addConstraintMapping()
.type( Runner.class )
.property( "paidEntryFee", FIELD )
.constraint( new AssertTrueDef() );
}
}
You then need to specify the fully-qualified class name of the contributor implementation in META-INF/validation.xml, using the property key hibernate.validator.constraint_mapping_contributors
. You can specify several contributors by separating them with a comma.
12.6. Advanced constraint composition features
12.6.1. Validation target specification for purely composed constraints
In case you specify a purely composed constraint - i.e. a constraint which has no validator itself but is solely made up from other, composing constraints - on a method declaration, the validation engine cannot determine whether that constraint is to be applied as a return value constraint or as a cross-parameter constraint.
Hibernate Validator allows to resolve such ambiguities by specifying the @SupportedValidationTarget
annotation on the declaration of the composed constraint type as shown in Example 12.11, “Specifying the validation target of a purely composed constraint”. The @ValidInvoiceAmount
does not declare any validator, but it is solely composed by the @Min
and @NotNull
constraints. The @SupportedValidationTarget
ensures that the constraint is applied to the method return value when given on a method declaration.
package org.hibernate.validator.referenceguide.chapter12.purelycomposed;
@Min(value = 0)
@NotNull
@Target({ METHOD, FIELD, ANNOTATION_TYPE, CONSTRUCTOR, PARAMETER })
@Retention(RUNTIME)
@Documented
@Constraint(validatedBy = {})
@SupportedValidationTarget(ValidationTarget.ANNOTATED_ELEMENT)
@ReportAsSingleViolation
public @interface ValidInvoiceAmount {
String message() default "{org.hibernate.validator.referenceguide.chapter11.purelycomposed."
+ "ValidInvoiceAmount.message}";
Class<?>[] groups() default {};
Class<? extends Payload>[] payload() default {};
@OverridesAttribute(constraint = Min.class, name = "value")
long value();
}
12.6.2. Boolean composition of constraints
Bean Validation specifies that the constraints of a composed constraint (see Section 6.4, “Constraint composition”) are all combined via a logical AND. This means all of the composing constraints need to return true to obtain an overall successful validation.
Hibernate Validator offers an extension to this and allows you to compose constraints via a logical OR or NOT. To do so, you have to use the ConstraintComposition annotation and the enum CompositionType with its values AND, OR and ALL_FALSE.
Example 12.12, “OR composition of constraints” shows how to build a composed constraint @PatternOrSize
where only one of the composing constraints needs to be valid in order to pass the validation. Either the validated string is all lower-cased or it is between two and three characters long.
package org.hibernate.validator.referenceguide.chapter12.booleancomposition;
@ConstraintComposition(OR)
@Pattern(regexp = "[a-z]")
@Size(min = 2, max = 3)
@ReportAsSingleViolation
@Target({ METHOD, FIELD })
@Retention(RUNTIME)
@Constraint(validatedBy = { })
public @interface PatternOrSize {
String message() default "{org.hibernate.validator.referenceguide.chapter11." +
"booleancomposition.PatternOrSize.message}";
Class<?>[] groups() default { };
Class<? extends Payload>[] payload() default { };
}
Using ALL_FALSE as composition type implicitly enforces that only a single violation will get reported in case validation of the constraint composition fails. |
12.7. Extensions of the Path API
Hibernate Validator provides an extension to the javax.validation.Path
API. For nodes of ElementKind.PROPERTY
and ElementKind.CONTAINER_ELEMENT
it allows to obtain the value of the represented property. To do so, narrow down a given node to the type org.hibernate.validator.path.PropertyNode
ororg.hibernate.validator.path.ContainerElementNode
respectively using Node#as()
, as shown in the following example:
Building building = new Building();
// Assume the name of the person violates a @Size constraint
Person bob = new Person( "Bob" );
Apartment bobsApartment = new Apartment( bob );
building.getApartments().add( bobsApartment );
Set<ConstraintViolation<Building>> constraintViolations = validator.validate( building );
Path path = constraintViolations.iterator().next().getPropertyPath();
Iterator<Path.Node> nodeIterator = path.iterator();
Path.Node node = nodeIterator.next();
assertEquals( node.getName(), "apartments" );
assertSame( node.as( PropertyNode.class ).getValue(), bobsApartment );
node = nodeIterator.next();
assertEquals( node.getName(), "resident" );
assertSame( node.as( PropertyNode.class ).getValue(), bob );
node = nodeIterator.next();
assertEquals( node.getName(), "name" );
assertEquals( node.as( PropertyNode.class ).getValue(), "Bob" );
This is also very useful to obtain the element of Set
properties on the property path (e.g. apartments
in the example) which otherwise could not be identified (unlike for Map
and List
, there is no key nor index in this case).
12.8. Dynamic payload as part of ConstraintViolation
In some cases automatic processing of violations can be aided, if the constraint violation provides additional data - a so called dynamic payload. This dynamic payload could for example contain hints to the user on how to resolve the violation.
Dynamic payloads can be set in custom constraints using HibernateConstraintValidatorContext
. This is shown in example Example 12.14, “ConstraintValidator
implementation setting a dynamic payload” where thejavax.validation.ConstraintValidatorContext
is unwrapped to HibernateConstraintValidatorContext
in order to call withDynamicPayload
.
ConstraintValidator
implementation setting a dynamic payloadpackage org.hibernate.validator.referenceguide.chapter12.dynamicpayload;
import static org.hibernate.validator.internal.util.CollectionHelper.newHashMap;
public class ValidPassengerCountValidator implements ConstraintValidator<ValidPassengerCount, Car> {
private static final Map<Integer, String> suggestedCars = newHashMap();
static {
suggestedCars.put( 2, "Chevrolet Corvette" );
suggestedCars.put( 3, "Toyota Volta" );
suggestedCars.put( 4, "Maserati GranCabrio" );
suggestedCars.put( 5, " Mercedes-Benz E-Class" );
}
@Override
public void initialize(ValidPassengerCount constraintAnnotation) {
}
@Override
public boolean isValid(Car car, ConstraintValidatorContext context) {
if ( car == null ) {
return true;
}
int passengerCount = car.getPassengers().size();
if ( car.getSeatCount() >= passengerCount ) {
return true;
}
else {
if ( suggestedCars.containsKey( passengerCount ) ) {
HibernateConstraintValidatorContext hibernateContext = context.unwrap(
HibernateConstraintValidatorContext.class
);
hibernateContext.withDynamicPayload( suggestedCars.get( passengerCount ) );
}
return false;
}
}
}
On the constraint violation processing side, a javax.validation.ConstraintViolation
can then in turn be unwrapped to HibernateConstraintViolation
in order to retrieve the dynamic payload for further processing.
ConstraintViolation
's dynamic payloadCar car = new Car( 2 );
car.addPassenger( new Person() );
car.addPassenger( new Person() );
car.addPassenger( new Person() );
Set<ConstraintViolation<Car>> constraintViolations = validator.validate( car );
assertEquals( 1, constraintViolations.size() );
ConstraintViolation<Car> constraintViolation = constraintViolations.iterator().next();
@SuppressWarnings("unchecked")
HibernateConstraintViolation<Car> hibernateConstraintViolation = constraintViolation.unwrap(
HibernateConstraintViolation.class
);
String suggestedCar = hibernateConstraintViolation.getDynamicPayload( String.class );
assertEquals( "Toyota Volta", suggestedCar );
12.9. ParameterMessageInterpolator
Hibernate Validator requires per default an implementation of the Unified EL (see Section 1.1.1, “Unified EL”) to be available. This is needed to allow the interpolation of constraint error messages using EL expressions as defined by the Bean Validation specification.
For environments where you cannot or do not want to provide an EL implementation, Hibernate Validator offers a non EL based message interpolator - org.hibernate.validator.messageinterpolation.ParameterMessageInterpolator
.
Refer to Section 4.2, “Custom message interpolation” to see how to plug in custom message interpolator implementations.
Constraint messages containing EL expressions will be returned un-interpolated by |
12.10. ResourceBundleLocator
With ResourceBundleLocator
, Hibernate Validator provides an additional SPI which allows to retrieve error messages from other resource bundles than ValidationMessages while still using the actual interpolation algorithm as defined by the specification. Refer to Section 4.2.1, “ResourceBundleLocator
” to learn how to make use of that SPI.
12.11. Custom contexts
The Bean Validation specification offers at several points in its API the possibility to unwrap a given interface to an implementor specific subtype. In the case of constraint violation creation in ConstraintValidator
implementations as well as message interpolation in MessageInterpolator
instances, there exist unwrap()
methods for the provided context instances - ConstraintValidatorContext
respectively MessageInterpolatorContext
. Hibernate Validator provides custom extensions for both of these interfaces.
12.11.1. HibernateConstraintValidatorContext
HibernateConstraintValidatorContext
is a subtype of ConstraintValidatorContext
which allows you to:
-
set arbitrary parameters for interpolation via the Expression Language message interpolation facility using
HibernateConstraintValidatorContext#addExpressionVariable(String, Object)
.Example 150. Custom@Future
validator with message parameterspackage org.hibernate.validator.referenceguide.chapter12.context; import java.time.Instant; import javax.validation.ConstraintValidator;
import javax.validation.ConstraintValidatorContext;
import javax.validation.constraints.Future; import org.hibernate.validator.constraintvalidation.HibernateConstraintValidatorContext; public class MyFutureValidator implements ConstraintValidator<Future, Instant> { @Override
public void initialize(Future constraintAnnotation) {
} @Override
public boolean isValid(Instant value, ConstraintValidatorContext context) {
if ( value == null ) {
return true;
} HibernateConstraintValidatorContext hibernateContext = context.unwrap(
HibernateConstraintValidatorContext.class
); Instant now = Instant.now( context.getClockProvider().getClock() ); if ( !value.isAfter( now ) ) {
hibernateContext.disableDefaultConstraintViolation();
hibernateContext.addExpressionVariable( "now", now )
.buildConstraintViolationWithTemplate( "Must be after ${now}" )
.addConstraintViolation(); return false;
} return true;
}
}Note that the parameters specified via
addExpressionVariable(String, Object)
are global and apply to all constraint violations created by thisisValid()
invocation. This includes the default constraint violation, but also all violations created by theConstraintViolationBuilder
. You can, however, update the parameters between invocations ofConstraintViolationBuilder#addConstraintViolation()
. set an arbitrary dynamic payload - see Section 12.8, “Dynamic payload as part of
ConstraintViolation
”
12.11.2. HibernateMessageInterpolatorContext
Hibernate Validator also offers a custom extension of MessageInterpolatorContext
, namelyHibernateMessageInterpolatorContext
(see Example 12.16, “HibernateMessageInterpolatorContext
”). This subtype was introduced to allow a better integration of Hibernate Validator into Glassfish. The root bean type was in this case needed to determine the right class loader for the message resource bundle. If you have any other use cases, let us know.
HibernateMessageInterpolatorContext
* @author Guillaume Smet
* @since 5.0
*/
public interface HibernateMessageInterpolatorContext extends MessageInterpolator.Context {
/**
* Returns the currently validated root bean type.
*
* @return The currently validated root bean type.
12.12. Paranamer based ParameterNameProvider
Hibernate Validator comes with a ParameterNameProvider
implementation which leverages the Paranamer library.
This library provides several ways for obtaining parameter names at runtime, e.g. based on debug symbols created by the Java compiler, constants with the parameter names woven into the bytecode in a post-compile step or annotations such as the @Named
annotation from JSR 330.
In order to use ParanamerParameterNameProvider
, either pass an instance when bootstrapping a validator as shown in Example 9.10, “Using a custom ParameterNameProvider
” or specifyorg.hibernate.validator.parameternameprovider.ParanamerParameterNameProvider
as value for the<parameter-name-provider>
element in the META-INF/validation.xml file.
When using this parameter name provider, you need to add the Paranamer library to your classpath. It is available in the Maven Central repository with the group id |
By default ParanamerParameterNameProvider
retrieves parameter names from constants added to the byte code at build time (via DefaultParanamer
) and debug symbols (via BytecodeReadingParanamer
). Alternatively you can specify a Paranamer
implementation of your choice when creating a ParanamerParameterNameProvider
instance.
12.13. Providing constraint definitions
Bean Validation allows to (re-)define constraint definitions via XML in its constraint mapping files. See Section 8.2, “Mapping constraints via constraint-mappings
” for more information and Example 8.2, “Bean constraints configured via XML” for an example. While this approach is sufficient for many use cases, it has its shortcomings in others. Imagine for example a constraint library wanting to contribute constraint definitions for custom types. This library could provide a mapping file with their library, but this file still would need to be referenced by the user of the library. Luckily there are better ways.
The following concepts are considered experimental at this time. Let us know whether you find them useful and whether they meet your needs. |
12.13.1. Constraint definitions via ServiceLoader
Hibernate Validator allows to utilize Java’s ServiceLoader mechanism to register additional constraint definitions. All you have to do is to add the file javax.validation.ConstraintValidator to META-INF/services. In this service file you list the fully qualified classnames of your constraint validator classes (one per line). Hibernate Validator will automatically infer the constraint types they apply to. See Constraint definition via service file for an example.
# Assuming a custom constraint annotation @org.mycompany.CheckCase
org.mycompany.CheckCaseValidator
To contribute default messages for your custom constraints, place a file ContributorValidationMessages.properties and/or its locale-specific specializations at the root of your JAR. Hibernate Validator will consider the entries from all the bundles with this name found on the classpath in addition to those given in ValidationMessages.properties.
This mechanism is also helpful when creating large multi-module applications: instead of putting all the constraint messages into one single bundle, you can have one resource bundle per module containing only those messages of that module.
We highly recommend the reading of this blog post by Marko Bekhta, guiding you step by step through the process of creating an independent JAR that contains your custom constraints and declares them via the |
12.13.2. Adding constraint definitions programmatically
While the service loader approach works in many scenarios, but not in all (think for example OSGi where service files are not visible), there is yet another way of contributing constraint definitions. You can use the programmatic constraint declaration API - see Example 12.18, “Adding constraint definitions through the programmatic API”.
ConstraintMapping constraintMapping = configuration.createConstraintMapping();
constraintMapping
.constraintDefinition( ValidPassengerCount.class )
.validatedBy( ValidPassengerCountValidator.class );
If your validator implementation is rather simple (i.e. no initialization from the annotation is needed, and ConstraintValidatorContext
is not used), you also can use this alternative API to specify the constraint logic using a Lambda expression or method reference:
ConstraintMapping constraintMapping = configuration.createConstraintMapping();
constraintMapping
.constraintDefinition( ValidPassengerCount.class )
.validateType( Bus.class )
.with( b -> b.getSeatCount() >= b.getPassengers().size() );
Instead of directly adding a constraint mapping to the configuration object, you may use a ConstraintMappingContributor
as detailed in Section 12.5, “Applying programmatic constraint declarations to the default validator factory”. This can be useful when configuring the default validator factory using META-INF/validation.xml (see Chapter 8, Configuring via XML).
One use case for registering constraint definitions through the programmatic API is the ability to specify an alternative constraint validator for the Using the programmatic constraint declaration API to register a regular expression based constraint definition for
@URL
|
12.14. Customizing class-loading
There are several cases in which Hibernate Validator needs to load resources or classes given by name:
XML descriptors (META-INF/validation.xml as well as XML constraint mappings)
classes specified by name in XML descriptors (e.g. custom message interpolators etc.)
the ValidationMessages resource bundle
the
ExpressionFactory
implementation used for expression based message interpolation
By default, Hibernate Validator tries to load these resources via the current thread context class loader. If that’s not successful, Hibernate Validator’s own class loader will be tried as a fallback.
For cases where this strategy is not appropriate (e.g. modularized environments such as OSGi), you may provide a specific class loader for loading these resources when bootstrapping the validator factory:
Validator validator = Validation.byProvider( HibernateValidator.class )
.configure()
.externalClassLoader( classLoader )
.buildValidatorFactory()
.getValidator();
In the case of OSGi, you could e.g. pass the loader of a class from the bundle bootstrapping Hibernate Validator or a custom class loader implementation which delegates to Bundle#loadClass()
etc.
Call |
13. Annotation Processor
Have you ever caught yourself by unintentionally doing things like
specifying constraint annotations at unsupported data types (e.g. by annotating a String with
@Past
)annotating the setter of a JavaBeans property (instead of the getter method)
annotating static fields/methods with constraint annotations (which is not supported)?
Then the Hibernate Validator Annotation Processor is the right thing for you. It helps preventing such mistakes by plugging into the build process and raising compilation errors whenever constraint annotations are incorrectly used.
You can find the Hibernate Validator Annotation Processor as part of the distribution bundle onSourceforge or in the usual Maven repositories such as Maven Central under the GAV |
13.1. Prerequisites
The Hibernate Validator Annotation Processor is based on the "Pluggable Annotation Processing API" as defined by JSR 269 which is part of the Java Platform.
13.2. Features
As of Hibernate Validator 6.0.9.Final the Hibernate Validator Annotation Processor checks that:
constraint annotations are allowed for the type of the annotated element
only non-static fields or methods are annotated with constraint annotations
only non-primitive fields or methods are annotated with
@Valid
only such methods are annotated with constraint annotations which are valid JavaBeans getter methods (optionally, see below)
only such annotation types are annotated with constraint annotations which are constraint annotations themselves
definition of dynamic default group sequence with
@GroupSequenceProvider
is validannotation parameter values are meaningful and valid
method parameter constraints in inheritance hierarchies respect the inheritance rules
method return value constraints in inheritance hierarchies respect the inheritance rules
13.3. Options
The behavior of the Hibernate Validator Annotation Processor can be controlled using the following processor options:
diagnosticKind
-
Controls how constraint problems are reported. Must be the string representation of one of the values from the enum
javax.tools.Diagnostic.Kind
, e.g.WARNING
. A value ofERROR
will cause compilation to halt whenever the AP detects a constraint problem. Defaults toERROR
. methodConstraintsSupported
-
Controls whether constraints are allowed at methods of any kind. Must be set to
true
when working with method level constraints as supported by Hibernate Validator. Can be set tofalse
to allow constraints only at JavaBeans getter methods as defined by the Bean Validation API. Defaults totrue
. verbose
-
Controls whether detailed processing information shall be displayed or not, useful for debugging purposes. Must be either
true
orfalse
. Defaults tofalse
.
13.4. Using the Annotation Processor
This section shows in detail how to integrate the Hibernate Validator Annotation Processor into command line builds (Maven, Ant, javac) as well as IDE-based builds (Eclipse, IntelliJ IDEA, NetBeans).
13.4.1. Command line builds
13.4.1.1. Maven
For using the Hibernate Validator annotation processor with Maven, set it up via the annotationProcessorPaths
option like this:
<project>
[...]
<build>
[...]
<plugins>
[...]
<plugin>
<groupId>org.apache.maven.plugins</groupId>
<artifactId>maven-compiler-plugin</artifactId>
<version>3.6.1</version>
<configuration>
<source>1.8</source>
<target>1.8</target>
<annotationProcessorPaths>
<path>
<groupId>org.hibernate.validator</groupId>
<artifactId>hibernate-validator-annotation-processor</artifactId>
<version>6.0.9.Final</version>
</path>
</annotationProcessorPaths>
</configuration>
</plugin>
[...]
</plugins>
[...]
</build>
[...]
</project>
13.4.1.2. Apache Ant
Similar to directly working with javac, the annotation processor can be added as as compiler argument when invoking the javac task for Apache Ant:
<javac srcdir="src/main"
destdir="build/classes"
classpath="/path/to/validation-api-2.0.1.Final.jar">
<compilerarg value="-processorpath" />
<compilerarg value="/path/to/hibernate-validator-annotation-processor-6.0.9.Final.jar"/>
</javac>
13.4.1.3. javac
When compiling on the command line using javac, specify the JAR hibernate-validator-annotation-processor-6.0.9.Final.jarusing the "processorpath" option as shown in the following listing. The processor will be detected automatically by the compiler and invoked during compilation.
javac src/main/java/org/hibernate/validator/ap/demo/Car.java \
-cp /path/to/validation-api-2.0.1.Final.jar \
-processorpath /path/to/hibernate-validator-annotation-processor-6.0.9.Final.jar
13.4.2. IDE builds
13.4.2.1. Eclipse
The annotation processor will automatically be set up for Maven projects configured as described above, provided you have the M2E Eclipse plug-in installed.
For plain Eclipse projects follow these steps to set up the annotation processor:
Right-click your project, choose "Properties"
Go to "Java Compiler" and make sure, that "Compiler compliance level" is set to "1.8". Otherwise the processor won’t be activated
Go to "Java Compiler - Annotation Processing" and choose "Enable annotation processing"
Go to "Java Compiler - Annotation Processing - Factory Path" and add the JAR hibernate-validator-annotation-processor-6.0.9.Final.jar
Confirm the workspace rebuild
You now should see any annotation problems as regular error markers within the editor and in the "Problem" view:
13.4.2.2. IntelliJ IDEA
The following steps must be followed to use the annotation processor within IntelliJ IDEA (version 9 and above):
Go to "File", then "Settings",
Expand the node "Compiler", then "Annotation Processors"
Choose "Enable annotation processing" and enter the following as "Processor path": /path/to/hibernate-validator-annotation-processor-6.0.9.Final.jar
Add the processor’s fully qualified name org.hibernate.validator.ap.ConstraintValidationProcessor to the "Annotation Processors" list
If applicable add you module to the "Processed Modules" list
Rebuilding your project then should show any erroneous constraint annotations:
13.4.2.3. NetBeans
The NetBeans IDE supports using annotation processors within the IDE build. To do so, do the following:
Right-click your project, choose "Properties"
Go to "Libraries", tab "Processor", and add the JAR hibernate-validator-annotation-processor-6.0.9.Final.jar
Go to "Build - Compiling", select "Enable Annotation Processing" and "Enable Annotation Processing in Editor". Add the annotation processor by specifying its fully qualified name org.hibernate.validator.ap.ConstraintValidationProcessor
Any constraint annotation problems will then be marked directly within the editor:
13.5. Known issues
The following known issues exist as of July 2017:
Container element constraints are not supported for now.
Constraints applied to a container but in reality applied to the container elements (be it via the
Unwrapping.Unwrap
payload or via a value extractor marked with@UnwrapByDefault
) are not supported correctly.HV-308: Additional validators registered for a constraint using XML are not evaluated by the annotation processor.
Sometimes custom constraints can’t be properly evaluated when using the processor within Eclipse. Cleaning the project can help in these situations. This seems to be an issue with the Eclipse JSR 269 API implementation, but further investigation is required here.
When using the processor within Eclipse, the check of dynamic default group sequence definitions doesn’t work. After further investigation, it seems to be an issue with the Eclipse JSR 269 API implementation.
14. Further reading
Last but not least, a few pointers to further information.
A great source for examples is the Bean Validation TCK which is available for anonymous access on GitHub. In particular the TCK’s tests might be of interest. The JSR 380 specification itself is also a great way to deepen your understanding of Bean Validation and Hibernate Validator.
If you have any further questions about Hibernate Validator or want to share some of your use cases, have a look at the Hibernate Validator Wiki, the Hibernate Validator Forum and the Hibernate Validator tag on Stack Overflow.
In case you would like to report a bug use Hibernate’s Jira instance. Feedback is always welcome!
https://docs.jboss.org/hibernate/stable/validator/reference/en-US/html_single/#validator-annotationprocessor-prerequisites