public interface DmiOverview
DMI Scripts
, which allows you
to place code directly into the
XML file instead of in a separate .java file; this is a useful approach when DMI code is
short.
When using DMI, request data from the UI is translated to Java objects and passed to the Java method you designate with an XML declaration. Your Java method simply declares the parameters it needs and they are automatically provided (see "Method Invocation" below). The return value of your method is automatically wrapped as a valid response and delivered to the browser.
DMI requires the Smart GWT Server
. Note that Smart
GWT also supports
several approaches for interacting with non-Java
backends
and/or
Java backends not running the ISC server.
DataSource DMI
See also Server DataSource Integration
overview.
To enable DMI for a given DataSource, simply include a <serverObject>
configuration block in that DataSource's configuration either at
serverObject
or on a particular
operationBinding via
OperationBinding.serverObject
. The ServerObject specifies the target of the method
invocation and OperationBinding.serverMethod
specifies the method that will be
called.
For example, the following Datasource DMI declaration would route "fetch" operations for this DataSource to the method "fetch" on an object stored in the servlet session under the name "beanFetcher":
<DataSource> <operationBindings> <binding operationType="fetch" serverMethod="fetch"> <serverObject lookupStyle="attribute" attributeScope="session" attributeName="beanFetcher"/> </binding> </operationBindings> ... </DataSource>Method overloading is not supported - there must be exactly one method on the target class with the name specified in
OperationBinding.serverMethod
.
The method must be public,
but can be either an instance or static method. If no operationBinding is specified or the
operationBinding does not specify a serverMethod
then it defaults to the name of
the operation (eg "fetch").
By default, the DSResponse data sent back by DataSource DMIs is filtered to just the set of
fields specified on the DataSource. This allows you to simply return beans that potentially
have getter methods for fields other than are defined in the DataSource without that
(potentially private) data being sent to the client. If you want to disable this
functionality, you can do so on a per-operation basis by setting
ServerObject.dropExtraFields
, on a per-DataSource level by setting
dropExtraFields
, or globally by
setting the config parameter
DMI.dropExtraFields
to false
in
[webroot]/WEB-INF/classes/server.properties
.
Non-DMI DSResponse data is, by
default, not filtered in this manner for backward compatibility reasons. If you want to
enable this type of filtering for non-DMI DSResponse data, you can do so by setting the
config parameter DSResponse.dropExtraFields
to true
in
[webroot]/WEB-INF/classes/server.properties
.
DMI.dropExtraFields
and DSResponse.dropExtraFields
can be enabled/disabled independently of each
other - that is, setting one does not side-effect the other. server.properties
settings can be overridden by an explicit setting in dropExtraFields
which
in turn can be overridden by an explicit setting in ServerObject.dropExtraFields
(this
last one for DMI only since non-DMI operations don't have a serverObject context).
DataSource DMI and regular RPCManager dispatch
It is possible to use DMI to incorporate your own code into what is otherwise the regular
process flow of an ordinary, non-DMI DataSource request. This is particularly valuable if
you are using the built-in SQL or Hibernate DataSources, because it allows you to inject
extra functionality (validations, processing steps, messages to other systems, anything you
can code) into a fetch or update request that is otherwise handled for you by the Smart GWT
Server.
To do this, just configure an operationBinding for DMI, as described above. Then, in your
server-side method, invoke execute()
on the DSRequest
your method
is passed. If you create a DMI method that does nothing but invoke
dsRequest.execute()
, then you have a DMI method that behaves exactly like the
normal RPCManager dispatch code. Customizing "normal RPCManager dispatch code" is now a
simple matter of adding logic to your DMI method. See
this example of this technique in the Feature Explorer.
RPC DMI
RPC DMI makes a set of methods from a server-side class available as client-side methods for
direct invocation (via DMI.call()). This provides a way to perform arbitrary
client/server interactions outside of the DataSource subsystem.
RPC DMI is an alternative approach to using the RPCManager
class directly to send
requests to some actionURL
where your server code would receive a generalized
request object
, to be routed to appropriate
methods yourself. Which interface (DMI or RPCManager) you choose is largely a matter of
preference - they provide equivalent functionality.
RPC DMI also uses a ServerObject
configuration block
to specify
the server-side DMI end-point, but in the case of RPCs, the ServerObject
definition
goes into an rpcBindings
section of an
Application definition
in a
*.app.xml
file.
The only difference between the RPC DMI
ServerObject definition and the DataSource DMI version is the addition of the
ServerObject.visibleMethods
block that specifies which methods are callable on this
ServerObject. This section is not consulted for DataSource DMIs because the
OperationBinding.serverMethod
is used to specify the callable method in that case.
Method Invocation
Smart GWT can pass a set of stock context variables to your DMI method and also performs
some type adaptation logic to make this interface more flexible. For DataSource DMI, you
can declare your method to take any number of the following types of arguments and they will
be passed to you:
List
instead,
but this won't work for large datasets.
So, for example, all of the following DataSource DMI method signatures are valid:
public List myFetch(Map criteria) public List myFetch(SupplyItem criteria) public DSResponse myAdd(HttpSession session, DataSource ds, DSRequest dsRequest)
See the supplyItemDMI example for an example of DataSource DMI.
RPC DMIs work slightly differently. Unlike DataSource DMIs, RPC DMIs can have an arbitrary
number of required arguments, and also some optional context arguments. For example, let's
say you call a method from the client like so
:
List someList = new ArrayList(); someList.add(1); someList.add(2); DMI.call("myApp", "com.sample.MyClass", "doSomething", new RPCCallback() { @Override public void execute(RPCResponse response, Object rawData, RPCRequest request) { SC.say("raw data from server method:" + rawData.toString()); } }, new Object[] {1, "zoo", someList});The server-side implementation of the method invoked must have a signature that will accept the arguments passed in from the client. In the example above
com.sample.MyClass.doSomething
should accept a Number, String,
and a List as arguments. Smart GWT will try to adapt arguments where possible -
so for example the first argument can be a Long or an Integer, or a native type
(long
or int
) instead and the
invocation will still work.
If a Map is passed from the client to the server it will
be automatically applied to a bean if the method argument takes a Bean in that position.
See data
for a table of type conversions.
In addition to the parameters explicitly passed from the client, your method signature can include some additional arguments to pick up information about the request passed in. If your server side method is declared with arguments of the following type they will be passed to your DMI method.
Your server side method can return a RPCResponse
object giving you full
control over the response sent to the server. If your method does not return a response,
one will be created automatically and the return value from the server method will become the
data
value on the response.
See data
for an overview of how server side
java data types are mapped
to client side values.