The mapping of Slice interfaces revolves around the idea that, to invoke a remote operation, you call a member function on a local class instance that is a proxy for the remote object. This makes the mapping easy and intuitive to use because making a remote procedure call is no different from making a local procedure call (apart from error semantics).
On this page:
Java Classes Generated for an Interface
The compiler generates quite a few source files for each Slice interface. In general, for an interface <interface-name>
, the following source files are created by the compiler:
<interface-name>.java
This source file declares the<interface-name>
Java interface.
<interface-name>Holder.java
This source file defines a holder type for the interface.
<interface-name>Prx.java
This source file defines the proxy interface<interface-name>Prx
.
<interface-name>PrxHelper.java
This source file defines the helper type for the interface's proxy.
<interface-name>PrxHolder.java
This source file defines the holder type for the interface's proxy.
_<interface-name>Operations.java
_<interface-name>OperationsNC.java
These source files each define an interface that contains the operations corresponding to the Slice interface. TheOperations
interface is used for tie classes.
These are the files that contain code that is relevant to the client side. The compiler also generates a file that is specific to the server side, plus three additional files:
_<interface-name>Disp.java
This file contains the definition of the server-side skeleton class.
_<interface-name>Del.java
_<interface-name>DelD.java
_<interface-name>DelM.java
These files contain code that is internal to the Java mapping; they do not contain any functions of relevance to application programmers.
Proxy Interfaces in Java
On the client side, a Slice interface maps to a Java interface with methods that correspond to the operations on that interface. Consider the following simple interface:
interface Simple { void op(); }
The Slice compiler generates the following definition for use by the client:
public interface SimplePrx extends ObjectPrx { public void op(); public void op(java.util.Map<String, String> context); }
As you can see, the compiler generates a proxy interface SimplePrx
. In general, the generated name is <interface-name>Prx
. If an interface is nested in a module M
, the generated class is part of package M
, so the fully-qualified name is M.<interface-name>Prx
.
In the client's address space, an instance of SimplePrx
is the local ambassador for a remote instance of the Simple
interface in a server and is known as a proxy instance. All the details about the server-side object, such as its address, what protocol to use, and its object identity are encapsulated in that instance.
Note that SimplePrx
inherits from ObjectPrx
. This reflects the fact that all Ice interfaces implicitly inherit from Ice::Object
.
For each operation in the interface, the proxy class has a method of the same name. For the preceding example, we find that the operation op
has been mapped to the method op
. Also note that op
is overloaded: the second version of op
has a parameter context
of type java.util.Map<String, String>
. This parameter is for use by the Ice run time to store information about how to deliver a request. You normally do not need to use it. (We examine the context
parameter in detail in Request Contexts. The parameter is also used by IceStorm.)
Because all the <interface-name>Prx
types are interfaces, you cannot instantiate an object of such a type. Instead, proxy instances are always instantiated on behalf of the client by the Ice run time, so client code never has any need to instantiate a proxy directly. The proxy references handed out by the Ice run time are always of type <interface-name>Prx
; the concrete implementation of the interface is part of the Ice run time and does not concern application code.
A value of null
denotes the null proxy. The null proxy is a dedicated value that indicates that a proxy points "nowhere" (denotes no object).
Interface Inheritance in Java
Inheritance relationships among Slice interfaces are maintained in the generated Java classes. For example:
interface A { ... } interface B { ... } interface C extends A, B { ... }
The generated code for CPrx
reflects the inheritance hierarchy:
public interface CPrx extends APrx, BPrx { ... }
Given a proxy for C
, a client can invoke any operation defined for interface C
, as well as any operation inherited from C
's base interfaces.
The ObjectPrx
Interface in Java
All Ice objects have Object
as the ultimate ancestor type, so all proxies inherit from ObjectPrx
. ObjectPrx
provides a number of methods:
public interface ObjectPrx { boolean equals(java.lang.Object r); Identity ice_getIdentity(); boolean ice_isA(String id); boolean ice_isA(String id, java.util.Map<String, String> context); String[] ice_ids(); String[] ice_ids(java.util.Map<String, String> context); String ice_id(); String ice_id(java.util.Map<String, String> context); void ice_ping(); void ice_ping(java.util.Map<String, String> context); // ... }
The methods behave as follows:
equals
This operation compares two proxies for equality. Note that all aspects of proxies are compared by this operation, such as the communication endpoints for the proxy. This means that, in general, if two proxies compare unequal, that does not imply that they denote different objects. For example, if two proxies denote the same Ice object via different transport endpoints,equals
returnsfalse
even though the proxies denote the same object.
ice_getIdentity
This method returns the identity of the object denoted by the proxy. The identity of an Ice object has the following Slice type:Slicemodule Ice { struct Identity { string name; string category; } }
To see whether two proxies denote the same object, first obtain the identity for each object and then compare the identities:
Java CompatObjectPrx o1 = ...; ObjectPrx o2 = ...; Identity i1 = o1.ice_getIdentity(); Identity i2 = o2.ice_getIdentity(); if(i1.equals(i2)) { // o1 and o2 denote the same object } else { // o1 and o2 denote different objects }
ice_isA
Theice_isA
method determines whether the object denoted by the proxy supports a specific interface. The argument toice_isA
is a type ID. For example, to see whether a proxy of typeObjectPrx
denotes aPrinter
object, we can write:Java CompatObjectPrx o = ...; if(o != null && o.ice_isA("::Printer")) { // o denotes a Printer object } else { // o denotes some other type of object }
Note that we are testing whether the proxy is null before attempting to invoke the
ice_isA
method. This avoids getting aNullPointerException
if the proxy is null.
ice_ids
Theice_ids
method returns an array of strings representing all of the type IDs that the object denoted by the proxy supports.
ice_id
Theice_id
method returns the type ID of the object denoted by the proxy. Note that the type returned is the type of the actual object, which may be more derived than the static type of the proxy. For example, if we have a proxy of typeBasePrx
, with a static type ID of::Base
, the return value ofice_id
might be::Base
, or it might something more derived, such as::Derived
.
ice_ping
Theice_ping
method provides a basic reachability test for the object. If the object can physically be contacted (that is, the object exists and its server is running and reachable), the call completes normally; otherwise, it throws an exception that indicates why the object could not be reached, such asObjectNotExistException
orConnectTimeoutException
.
The ice_isA
, ice_ids
, ice_id
, and ice_ping
methods are remote operations and therefore support an additional overloading that accepts a request context. Also note that there are other methods in ObjectPrx
, not shown here. These methods provide different ways to dispatch a call and also provide access to an object's facets.
Proxy Helper Methods in Java
For each Slice interface, the Slice-to-Java compiler generates static helper methods that support down-casting and type discovery:
public static SimplePrx checkedCast(ObjectPrx b); public static SimplePrx checkedCast(ObjectPrx b, java.util.Map<String, String> context); public static SimplePrx checkedCast(ObjectPrx b, String facet); public static SimplePrx checkedCast(ObjectPrx b, String facet, java.util.Map<String, String> context); public static SimplePrx uncheckedCast(ObjectPrx b); public static SimplePrx uncheckedCast(ObjectPrx b, String facet); public static String ice_staticId();
For checkedCast
, if the passed proxy is for an object of type Simple
, or a proxy for an object with a type derived from Simple
, the cast returns a non-null reference to a proxy of type SimplePrx
; otherwise, if the passed proxy denotes an object of a different type (or if the passed proxy is null), the cast returns a null reference. Overloaded methods allow you to optionally specify a facet and a request context.
For the default Java mapping, these helper methods are generated in SimplePrx
. For the Java Compat mapping, these helper methods are generated in SimplePrxHelper
.
Given a proxy of any type, you can use a checkedCast
to determine whether the corresponding object supports a given type, for example:
ObjectPrx obj = ...; // Get a proxy from somewhere... SimplePrx simple = SimplePrxHelper.checkedCast(obj); if(simple != null) { // Object supports the Simple interface... } else { // Object is not of type Simple... }
Note that a checkedCast
contacts the server. This is necessary because only the implementation of an object in the server has definite knowledge of the type of an object. As a result, a checkedCast
may throw a ConnectTimeoutException
or an ObjectNotExistException
. (This also explains the need for the helper method: the Ice run time must contact the server, so we cannot use a simple Java down-cast.)
In contrast, an uncheckedCast
does not contact the server and unconditionally returns a proxy of the requested type. However, if you do use an uncheckedCast
, you must be certain that the proxy really does support the type you are casting to; otherwise, if you get it wrong, you will most likely get a run-time exception when you invoke an operation on the proxy. The most likely error for such a type mismatch is OperationNotExistException
. However, other exceptions, such as a marshaling exception are possible as well. And, if the object happens to have an operation with the correct name, but different parameter types, no exception may be reported at all and you simply end up sending the invocation to an object of the wrong type; that object may do rather nonsensical things. To illustrate this, consider the following two interfaces:
interface Process { void launch(int stackSize, int dataSize); } // ... interface Rocket { void launch(float xCoord, float yCoord); }
Suppose you expect to receive a proxy for a Process
object and use an uncheckedCast
to down-cast the proxy:
ObjectPrx obj = ...; // Get proxy... ProcessPrx process = ProcessPrxHelper.uncheckedCast(obj); // No worries... process.launch(40, 60); // Oops...
If the proxy you received actually denotes a Rocket
object, the error will go undetected by the Ice run time: because int
and float
have the same size and because the Ice protocol does not tag data with its type on the wire, the implementation of Rocket::launch
will simply misinterpret the passed integers as floating-point numbers.
In fairness, this example is somewhat contrived. For such a mistake to go unnoticed at run time, both objects must have an operation with the same name and, in addition, the run-time arguments passed to the operation must have a total marshaled size that matches the number of bytes that are expected by the unmarshaling code on the server side. In practice, this is extremely rare and an incorrect uncheckedCast
typically results in a run-time exception.
A final warning about down-casts: you must use either a checkedCast
or an uncheckedCast
to down-cast a proxy. If you use a Java cast, the behavior is undefined.
Another method generated for every interface is ice_staticId
, which returns the type ID string corresponding to the interface. As an example, for the Slice interface Simple
in module M
, the string returned by ice_staticId
is "::M::Simple"
.
Using Proxy Methods in Java
The base proxy class ObjectPrx
supports a variety of methods for customizing a proxy. Since proxies are immutable, each of these "factory methods" returns a copy of the original proxy that contains the desired modification. For example, you can obtain a proxy configured with a ten second invocation timeout as shown below:
ObjectPrx proxy = communicator.stringToProxy(...); proxy = proxy.ice_invocationTimeout(10000);
A factory method returns a new proxy object if the requested modification differs from the current proxy, otherwise it returns the current proxy. With few exceptions, factory methods return a proxy of the same type as the current proxy, therefore it is generally not necessary to repeat a checkedCast
or uncheckedCast
after using a factory method. However, the Java Compat mapping still requires a regular cast as shown in the example below:
ObjectPrx base = communicator.stringToProxy(...); HelloPrx hello = HelloPrxHelper.checkedCast(base); hello = (HelloPrx)hello.ice_invocationTimeout(10000); // Type is preserved but a down-cast is required hello.sayHello();
The only exceptions are the factory methods ice_facet
and ice_identity
. Calls to either of these methods may produce a proxy for an object of an unrelated type, therefore they return a base proxy that you must subsequently down-cast to an appropriate type using checkedCast
or uncheckedCast
.
Object Identity and Proxy Comparison in Java
Proxies provide an equals
method that compares proxies:
interface ObjectPrx { boolean equals(java.lang.Object r); }
Note that proxy comparison with equals
uses all of the information in a proxy for the comparison. This means that not only the object identity must match for a comparison to succeed, but other details inside the proxy, such as the protocol and endpoint information, must be the same. In other words, comparison with equals
tests for proxy identity, not object identity. A common mistake is to write code along the following lines:
ObjectPrx p1 = ...; // Get a proxy... ObjectPrx p2 = ...; // Get another proxy... if(!p1.equals(p2)) { // p1 and p2 denote different objects // WRONG! } else { // p1 and p2 denote the same object // Correct }
Even though p1
and p2
differ, they may denote the same Ice object. This can happen because, for example, both p1
and p2
embed the same object identity, but each use a different protocol to contact the target object. Similarly, the protocols may be the same, but denote different endpoints (because a single Ice object can be contacted via several different transport endpoints). In other words, if two proxies compare equal with equals
, we know that the two proxies denote the same object (because they are identical in all respects); however, if two proxies compare unequal with equals
, we know absolutely nothing: the proxies may or may not denote the same object.
To compare the object identities of two proxies, you can use a helper function in the Util
class:
public final class Util { public static int proxyIdentityCompare(ObjectPrx lhs, ObjectPrx rhs); public static int proxyIdentityAndFacetCompare(ObjectPrx lhs, ObjectPrx rhs); // ... }
proxyIdentityCompare
allows you to correctly compare proxies for identity:
ObjectPrx p1 = ...; // Get a proxy... ObjectPrx p2 = ...; // Get another proxy... if(Util.proxyIdentityCompare(p1, p2) != 0) { // p1 and p2 denote different objects // Correct } else { // p1 and p2 denote the same object // Correct }
The function returns 0 if the identities are equal, -1
if p1
is less than p2
, and 1 if p1
is greater than p2
. (The comparison uses name
as the major and category
as the minor sort key.)
The proxyIdentityAndFacetCompare
function behaves similarly, but compares both the identity and the facet name.
In addition, the Java mapping provides two wrapper classes that allow you to wrap a proxy for use as the key of a hashed collection:
public class ProxyIdentityKey { public ProxyIdentityKey(ObjectPrx proxy); public int hashCode(); public boolean equals(java.lang.Object obj); public Ice.ObjectPrx getProxy(); } public class ProxyIdentityFacetKey { public ProxyIdentityFacetKey(ObjectPrx proxy); public int hashCode(); public boolean equals(java.lang.Object obj); public Ice.ObjectPrx getProxy(); }
The constructor caches the identity and the hash code of the passed proxy, so calls to hashCode
and equals
can be evaluated efficiently. The getProxy
method returns the proxy that was passed to the constructor.
As for the comparison functions, ProxyIdentityKey
only uses the proxy's identity, whereas ProxyIdentityFacetKey
also includes the facet name.
Deserializing Proxies in Java
Proxy objects implement the java.io.Serializable
interface that enables serialization of proxies to and from a byte stream. You can use the standard class java.io.ObjectInputStream
to deserialize all Slice types except proxies; proxies are a special case because they must be created by a communicator.
To supply a communicator for use in deserializing proxies, an application must use the Ice-provided class ObjectInputStream
:
public class ObjectInputStream extends java.io.ObjectInputStream { public ObjectInputStream(Communicator communicator, java.io.InputStream stream) throws java.io.IOException; public Communicator getCommunicator(); }
The code shown below demonstrates how to use this class:
Communicator communicator = ... byte[] bytes = ... // data to be deserialized java.io.ByteArrayInputStream byteStream = new java.io.ByteArrayInputStream(bytes); ObjectInputStream in = new ObjectInputStream(communicator, byteStream); ObjectPrx proxy = (ObjectPrx)in.readObject();
Ice raises java.io.IOException
if an application attempts to deserialize a proxy without supplying a communicator.