javax.el.package.html Maven / Gradle / Ivy
Provides the API for the Unified Expression Language 3.0
The Expression Language (EL) is a simple language originally designed to
satisfy the specific needs of web application developers. It has evloved
into its own specification intended for general use inside and outside of the
web containers.
This package contains the classes and interfaces that describe
and define the programmatic access to the Expression Language engine. The API
is logically partitioned as follows:
- EL Context
- Expression Objects
- Creation of Expressions
- Evaluation of Expressions
- Evaluation Listeners
- Resolution of Model Objects and their Properties
- EL Functions
- EL Variables
- EL in Stand-alone environment
EL Context
An important goal of the EL is to ensure it can be used in
a variety of environments. It must therefore provide enough flexibility
to adapt to the specific requirements of the environment where it is
being used.
Class {@link javax.el.ELContext} is what links
the EL with the specific environment where it is being used.
It provides
the mechanism through which all relevant context for creating or
evaluating an expression is specified.
When EL used in a web container, the creation of ELContext
objects is controlled through the underlying technology.
For example, in JSP, the
JspContext.getELContext()
factory method is used. In an
stand-alone environment, a default {@link javax.el.StandardELContext} is
provided.
Some technologies provide the ability to add an {@link javax.el.ELContextListener}
so that applications and frameworks can ensure their own context objects
are attached to any newly created ELContext
.
Expression Objects
At the core of the Expression Language is the notion of an expression
that gets parsed according to the grammar defined by the Expression Language.
There are two types of expressions defined by the EL: value expressions
and method expressions. A {@link javax.el.ValueExpression} such as
"${customer.name}"
can be used either
as an rvalue (return the value associated with property name
of the model object customer
) or as an lvalue
(set the value of the property name
of the model object
customer
).
A {@link javax.el.MethodExpression} such as
"${handler.process}"
makes it possible to invoke a method
(process
) on a specific model object (handler
).
In version 2.2 and later, either type of EL expression can represent a method
invocation, such as ${trader.buy("JAVA")}
, where the arugments to
the method invocation are specified in the expression.
All expression classes extend the base class {@link javax.el.Expression}, making them
serializable and forcing them to implement equals()
and
hashCode()
. Morevover, each method on these expression classes
that actually evaluates an expression receives a parameter
of class {@link javax.el.ELContext},
which provides the context required to evaluate the expression.
Creation of Expressions
An expression is created through the {@link javax.el.ExpressionFactory} class.
The factory provides two creation methods; one for each type of expression
supported by the EL.
To create an expression, one must provide an {@link javax.el.ELContext},
a string representing
the expression, and the expected type (ValueExpression
) or signature
(MethodExpression
).
The ELContext
provides the context necessary to parse an expression.
Specifically, if the expression uses an EL function
(for example ${fn:toUpperCase(customer.name)}
) or an
EL variable, then
{@link javax.el.FunctionMapper} and {@link javax.el.VariableMapper}
objects must be available within the ELContext
so that EL functions and
EL variables are properly mapped.
Evaluation of Expressions
The creation and the evaluation of an expression are done in two separate
steps. At the evaluation of an expression,
the {@link javax.el.ELContext}
provides the context necessary to support property and method resolution
for modal objects.
A deferred expression is one that is created but not immediately evaluated.
In a JSF request processing life cycle, EL expressions are typically created
in the tree building phase and evaluated in the rendering phrase.
Adding parameters to a ValueExpression
further enhances the
power of deferred expressions. The {@link javax.el.LambdaExpression}
encapsulates such a construct. A LambdaExpression
can be
invoked by supplying the actual parameters at evaluation. It plays
an important role in the support for collections operators.
Evaluation Listeners
By registering {@link javax.el.EvaluationListener}s in ELContext, a user can
receive notifications during the EL expression evaluations. There are three
events that trigger the notification:
- Before evaluation
- After evaluation
- When (base, property) is resolved
Resolution of Model Objects and their Properties
Through the {@link javax.el.ELResolver} base class, the EL
features a pluggable mechanism
to resolve model object references as well as properties and method
invocations of these objects.
The EL API provides implementations of ELResolver
supporting
property resolution for common data types which include
arrays ({@link javax.el.ArrayELResolver}), JavaBeans ({@link javax.el.BeanELResolver}), List
s ({@link javax.el.ListELResolver}),
Map
s ({@link javax.el.MapELResolver}), and ResourceBundle
s ({@link javax.el.ResourceBundleELResolver}).
Tools can easily obtain more information about resolvable model objects and their
resolvable properties by calling
method getFeatureDescriptors
on the ELResolver
. This method exposes objects
of type java.beans.FeatureDescriptor
, providing all information of interest
on top-level model objects as well as their properties.
EL Functions
If an EL expression uses a function
(for example ${fn:toUpperCase(customer.name)}
), then a
{@link javax.el.FunctionMapper}
object must also be specified within the ELContext
.
The FunctionMapper
is responsible to map
${prefix:name()}
style functions to
static methods that can execute the specified functions.
EL Variables
Just like {@link javax.el.FunctionMapper} provides
a flexible mechanism to add functions to the EL, {@link javax.el.VariableMapper}
provides a flexible mechanism to support the notion of
EL variables.
An EL variable does not directly refer to a model object that can then
be resolved by an ELResolver
. Instead, it refers to an EL
expression. The evaluation of that EL expression gives the EL variable
its value.
For example, in the following code snippet
<h:inputText value="#{handler.customer.name}"/>
handler
refers to a model object that can be resolved by an EL Resolver.
However, in this other example:
<c:forEach var="item" items="#{model.list}">
<h:inputText value="#{item.name}"/>
</c:forEach>
item
is an EL variable because it does not refer directly to a model
object. Instead, it refers to another EL expression, namely a
specific item in the collection referred to by the EL expression
#{model.list}
.
Assuming that there are three elements in ${model.list}
, this means
that for
each invocation of <h:inputText>
, the following information
about item
must be preserved in the {@link javax.el.VariableMapper}:
first invocation: item
maps to first element in ${model.list}
second invocation: item
maps to second element in ${model.list}
third invocation: item
maps to third element in ${model.list}
VariableMapper
provides the mechanisms required to allow the mapping
of an EL variable to the EL expression from which it gets its value.
EL in Stand-alone environment
EL 3.0 includes APIs for using EL in a stand-alone environment.
{@link javax.el.ELProcessor} provides simple APIs for the direct
evaluations of expressions. It also makes it easy to define functions,
set variables, and define a beans locally.
{@link javax.el.ELManager} provides a lower level APIs for managing the EL
parsing and evaluation environment. It contains a default ELContext
{@link javax.el.StandardELContext}.