Can you give any good explanation what is the difference between Proxy and Decorator?
The main difference I see is that when we assume that Proxy uses composition and Decorator uses aggregation then it seems to be clear that by using multiple (one or more) Decorators you can modify/ add functionalities to pre-existing instance (decorate), whereas Proxy has own inner instance of proxied class and delegates to it adding some additional features (proxy behaviour).
The question is - Does Proxy created with aggregation is still Proxy or rather Decorator? Is it allowed (by definition in GoF patterns) to create Proxy with aggregation?
The real difference is not ownership (composition versus aggregation), but rather type-information.
A Decorator is always passed its delegatee. A Proxy might create it himself, or he might have it injected.
But a Proxy always knows the (more) specific type of the delegatee. In other words, the Proxy and its delegatee will have the same base type, but the Proxy points to some derived type. A Decorator points to its own base type. Thus, the difference is in compile-time information about the type of the delegatee.
In a dynamic language, if the delegatee is injected and happens to have the same interface, then there is no difference.
The answer to your question is "Yes".
Decorator Pattern focuses on dynamically adding functions to an object, while Proxy Pattern focuses on controlling access to an object.
EDIT:-
Relationship between a Proxy and the real subject is typically set at compile time, Proxy instantiates it in some way, whereas Decorator is assigned to the subject at runtime, knowing only subject's interface.
Here is the direct quote from the GoF (page 216).
Although decorators can have similar implementations as proxies, decorators have a different purpose. A decorator adds one or more responsibilities to an object, whereas a proxy controls access to an object.
Proxies vary in the degree to which they are implemented like a decorator. A
protection proxy might be implemented exactly like a decorator. On the other
hand, a remote proxy will not contain a direct reference to its real subject but only
an indirect reference, such as "host ID and local address on host." A virtual proxy
will start off with an indirect reference such as a file name but will eventually
obtain and use a direct reference.
Popular answers indicate that a Proxy knows the concrete type of its delegate. From this quote we can see that is not always true.
The difference between Proxy and Decorator according to the GoF is that Proxy restricts the client. Decorator does not. Proxy may restrict what a client does by controlling access to functionality; or it may restrict what a client knows by performing actions that are invisible and unknown to the client. Decorator does the opposite: it enhances what its delegate does in a way that is visible to clients.
We might say that Proxy is a black box while Decorator is a white box.
The composition relationship between wrapper and delegate is the wrong relationship to focus on when contrasting Proxy with Decorator, because composition is the feature these two patterns have in common. The relationship between wrapper and client is what differentiates these two patterns.
Decorator informs and empowers its client.
Proxy restricts and disempowers its client.
Decorator get reference for decorated object (usually through constructor) while Proxy responsible to do that by himself.
Proxy may not instantiate wrapping object at all (like this do ORMs to prevent unnecessary access to DB if object fields/getters are not used) while Decorator always hold link to actual wrapped instance.
Proxy usually used by frameworks to add security or caching/lazing and constructed by framework (not by regular developer itself).
Decorator usually used to add new behavior to old or legacy classes by developer itself based on interface rather then actual class (so it work on wide range of interface instances, Proxy is around concrete class).
Key differences:
Proxy provides the same interface. Decorator provides an enhanced interface.
Decorator and Proxy have different purposes but similar structures. Both describe how to provide a level of indirection to another object, and the implementations keep a reference to the object to which they forward requests.
Decorator can be viewed as a degenerate Composite with only one component. However, a Decorator adds additional responsibilities - it isn't intended for object aggregation.
Decorator supports recursive composition
The Decorator class declares a composition relationship to the LCD (Lowest Class Denominator) interface, and this data member is initialized in its constructor.
Use Proxy for lazy initialization, performance improvement by caching the object and controlling access to the client/caller
Sourcemaking article quotes the similarities and differences in excellent way.
Related SE questions/links:
When to Use the Decorator Pattern?
What is the exact difference between Adapter and Proxy patterns?
Proxy and Decorator differ in purpose and where they focus on the internal implementation. Proxy is for using a remote, cross process, or cross-network object as if it were a local object. Decorator is for adding new behavior to the original interface.
While both patterns are similar in structure, the bulk of the complexity of Proxy lies in ensuring proper communications with the source object. Decorator, on the other hand, focuses on the implementation of the added behavior.
Took a while to figure out this answer and what it really means. A few examples should make it more clear.
Proxy first:
public interface Authorization {
String getToken();
}
And :
// goes to the DB and gets a token for example
public class DBAuthorization implements Authorization {
#Override
public String getToken() {
return "DB-Token";
}
}
And there is a caller of this Authorization, a pretty dumb one:
class Caller {
void authenticatedUserAction(Authorization authorization) {
System.out.println("doing some action with : " + authorization.getToken());
}
}
Nothing un-usual so far, right? Obtain a token from a certain service, use that token. Now comes one more requirement to the picture, add logging: meaning log the token every time. It's simple for this case, just create a Proxy:
public class LoggingDBAuthorization implements Authorization {
private final DBAuthorization dbAuthorization = new DBAuthorization();
#Override
public String getToken() {
String token = dbAuthorization.getToken();
System.out.println("Got token : " + token);
return token;
}
}
How would we use that?
public static void main(String[] args) {
LoggingDBAuthorization loggingDBAuthorization = new LoggingDBAuthorization();
Caller caller = new Caller();
caller.authenticatedUserAction(loggingDBAuthorization);
}
Notice that LoggingDBAuthorization holds an instance of DBAuthorization. Both LoggingDBAuthorization and DBAuthorization implement Authorization.
A proxy will hold some concrete implementation (DBAuthorization) of the base interface (Authorization). In other words a Proxy knows exactly what is being proxied.
Decorator:
It starts pretty much the same as Proxy, with an interface:
public interface JobSeeker {
int interviewScore();
}
and an implementation of it:
class Newbie implements JobSeeker {
#Override
public int interviewScore() {
return 10;
}
}
And now we want to add a more experienced candidate, that adds it's interview score plus the one from another JobSeeker:
#RequiredArgsConstructor
public class TwoYearsInTheIndustry implements JobSeeker {
private final JobSeeker jobSeeker;
#Override
public int interviewScore() {
return jobSeeker.interviewScore() + 20;
}
}
Notice how I said that plus the one from another JobSeeker, not Newbie. A Decorator does not know exactly what it is decorating, it knows just the contract of that decorated instance (it knows about JobSeeker). Take note here that this is unlike a Proxy; that, in contrast, knows exactly what it is decorating.
You might question if there is actually any difference between the two design patterns in this case? What if we tried to write the Decorator as a Proxy?
public class TwoYearsInTheIndustry implements JobSeeker {
private final Newbie newbie = new Newbie();
#Override
public int interviewScore() {
return newbie.interviewScore() + 20;
}
}
This is definitely an option and highlights how close these patterns are; they are still intended for different scenarios as explained in the other answers.
A Decorator adds extra responsibility to an object, while a proxy controls access to an object, they both use composition. If your wrapper class messes with the subject, it is obviously a proxy. Let me explain by a code example in PHP:
Code Example
Given is the following CarRepository:
interface CarRepositoryInterface
{
public function getById(int $id) : Car
}
class CarRepository implements CarRepositoryInterface
{
public function getById(int $id) : Car
{
sleep(3); //... fake some heavy db call
$car = new Car;
$car->setId($id);
$car->setName("Mercedes Benz");
return $car;
}
}
CarRepository-Proxy
A Proxy is often used as lazy loading or a cache proxy:
class CarRepositoryCacheProxy implements CarRepositoryInterface
{
private $carRepository;
private function getSubject() : CarRepositoryInterface
{
if($this->carRepository == null) {
$this->carRepository = new CarRepository();
}
return $this->carRepository;
}
/**
* This method controls the access to the subject
* based on if there is cache available
*/
public function getById(int $id) : Car
{
if($this->hasCache(__METHOD__)) {
return unserialize($this->getCache(__METHOD__));
}
$response = $this->getSubject()->getById($id);
$this->writeCache(__METHOD__, serialize($response));
return $response;
}
private function hasCache(string $key) : bool
{
//... implementation
}
private function getCache(string $key) : string
{
//... implementation
}
private function writeCache(string $key, string $result) : string
{
//... implementation
}
}
CarRepository-Decorator
A Decorator can be used as long as the added behavior does not "control" the subject:
class CarRepositoryEventManagerDecorator implements CarRepositoryInterface
{
private $subject, $eventManager;
/**
* Subjects in decorators are often passed in the constructor,
* where a proxy often takes control over the invocation behavior
* somewhere else
*/
public function __construct(CarRepositoryInterface $subject, EventManager $eventManager)
{
$this->subject = $subject;
$this->eventManager = $eventManager;
}
public function getById(int $id) : Car
{
$this->eventManager->trigger("pre.getById");
//this method takes no control over the subject
$result = $this->subject->getById($id);
$this->eventManager->trigger("post.getById");
return $result;
}
}
Proxy provides the same interface to the wrapped object, Decorator provides it with an enhanced interface, and Proxy usually manages the life cycle of its service object on its own, whereas the composition of Decorators is always controlled by the client.
Let me explain the patterns first and then come to you questions.
From the class diagram and meanings, they are very similar:
Both have the same interface as its delegatee has.
Both add/enhance the behavior of its delegatee.
Both ask the delegatee to perform operations(Should not work with null delegatee).
But they have some difference:
Different intents:
Proxy enhances the behavior of delegatee(passed object) with quite different domain knowledge from its delegatee. Eg, a security proxy adds security control of the delegatee. A proxy to send remote message needs to serialize/deserialize data and has knowlege on network interfacing, but has nothing to do with how to prepare source data.
Decorator helps on the same problem domain the delegatee works on. Eg, BufferedInputStreaman(an IO decorator) works on input, which is the same problem domain(IO) as its delegatee, but it cannot perform without a delegatee which provides IO data.
Dependency is strong or not:
Decorator relies on delegate to finish the behavior, and it cannot finish the behavior without delegatee(Strong). Thus we always use aggration over composition.
Proxy can perform faked behavior even it does not need a delegatee(Weak). Eg, mockito(unit test framework) could mock/spy a behavior just with its interface. Thus we use composition to indicate there's no strong dependency on real object.
Enhance multipletimes(as mentioned in question):
Proxy: we could utilize proxy to wrap real object once not several times.
Decorator: A decorator can wrap the real object several times or can wrap the object which is already wrapped by a decorator(which could be both a different decorator or the same decorator). Eg, for an order system, you can do discount with decorators.
PercentageDiscountDecorator is to cut 50% off, and DeductionAmountDiscountDecorator is to deduct 5$ directly if the amount is greater than 10$(). So,
1). When you want to cut 50% off and deduct 5$, you can do: new DeductionAmountDiscountDecorator(new PercentageDiscountDecorator(delegatee))
2). When you want to deduct 10$, you can do new DeductionAmountDiscountDecorator(new DeductionAmountDiscountDecorator(delegatee)).
The answer to the question has nothing to do with the difference between Proxy and Decorator. Why?
Design patterns just patterns for people who are not good at OO skills to make use of OO solutions. If you are familiar with OO, you don't need to know how many design patterns there(Before design patterns invented, with the same prolbem skilled people could figure out the same solution).
No two leaves are exactly the same, so as the problems you encount. People will always find their problems are different from the problems given by design patterns.
If your specified problem is really different from both problems that Proxy and Decorator work on, and really needs an aggregation, why not to use? I think to apply OO to your problem is much more important than you label it a Proxy or Decorator.
I'm trying to register to implementations of same interface using named instances
kernel.Bind<IRepository>().To<CachedRepository>().InSingletonScope();
kernel.Bind<IRepository>().To<DbRepository>().InSingletonScope().Named("db");
the idea, is that if I not specify the name then the CachedRepository gets created, if I need a DB oriented one then I'd use the Named attribute, but this miserable fails when a simple object would get created
public class TripManagerController : Controller
{
[Inject]
public IRepository Repository { get; set; } // default Cached repo must be created
public TripManagerController()
{
ViewBag.LogedEmail = "test#test.com";
}
}
the error is
Error activating IRepository More than one matching bindings are
available. Activation path: 2) Injection of dependency IRepository
into parameter repository of constructor of type TripManagerController
1) Request for TripManagerController
Suggestions: 1) Ensure that you have defined a binding for
IRepository only once.
Is there a way to achieve what I want without creating a new interface for BD oriented repositories?
Thx
The [Named] attribute as shown in the wiki should work.
BTW stay away from anything other than ctor injection!
It would seem you cannot do what you're trying, I've just come across the same issue and as well as finding your question I also found this one where the author of Ninject Remo Gloor replied.
https://stackoverflow.com/a/4051391/495964
While Remo didn't explicitly say it couldn't be done his answer was to name both bindings (or use custom attribute binding, amounting the same thing).
Following advices from people on the internet about service references, I got rid of them now and split the service/data contracts into a common assembly accesible by both the server and the client. Overall this seems to work really well.
However I’m running into problems when trying to use custom objects, or rather custom subtypes, in the service. Initially I wanted to define only interfaces in the common assembly as the contract for the data. I quickly learned that this won’t work though because the client needs a concrete class to instantiate objects when receiving objects from the service. So instead I used a simple class instead, basically like this:
// (defined in the common assembly)
public class TestObject
{
public string Value { get; set; }
}
Then in the service contract (interface), I have a method that returns such an object.
Now if I simply create such an object in the service implementation and return it, it works just fine. However I want to define a subtype of it in the service (or the underlying business logic), that defines a few more things (for example methods for database access, or just some methods that work on the objects).
So for simplicity, the subtype looks like this:
// (defined on the server)
public class DbTestObject : TestObject
{
public string Value { get; set; }
public DbTestObject(string val)
{
Value = val;
}
}
And in the service, instead of creating a TestObject, I create the subtype and return it:
public TestObject GetTestObject()
{
return new DbTestObject("foobar");
}
If I run this now, and make the client call GetTestObject, then I immediately get a CommunicationException with the following error text: “The socket connection was aborted. This could be caused by an error processing your message or a receive timeout being exceeded by the remote host, or an underlying network resource issue. Local socket timeout was '00:09:59.9380000'.”
I already found out, that the reason for this is that the client does not know how to deserialize the DbTestObject. One solution would be to declare the base type with the KnownTypeAttribute to make it know about the subtype. But that would require the subtype to be moved into the common assembly, which is of course something I want to avoid, as I want the logic separated from the client.
Is there a way to tell the client to only use the TestObject type for deserialization; or would the solution for this be to use data transfer objects anyway?
As #Sixto Saez has pointed out, inheritance and WCF don't tend to go together very well. The reason is that inheritance belongs very much to the OO world and not the messaging passing world.
Having said that, if you are in control of both ends of the service, KnownType permits you to escape the constraints of message passing and leverage the benefits of inheritance. To avoid taking the dependency you can utilise the ability of the KnownTypeAttribute to take a method name, rather than a type parameter. This allows you to dynamically specify the known types at run time.
E.g.
[KnownType("GetKnownTestObjects")]
[DataContract]
public class TestObject
{
[DataMember]
public string Value { get; set; }
public static IEnumerable<Type> GetKnownTestObjects()
{
return Registry.GetKnown<TestObject>();
}
}
Using this technique, you can effectively invert the dependency.
Registry is a simple class that allows other assemblies to register types at run-time as being subtypes of the specified base class. This task can be performed when the application bootstraps itself and if you wish can be done, for instance, by reflecting across the types in the assembly(ies) containing your subtypes.
This achieves your goal of allowing subtypes to be handled correctly without the TestObject assembly needing to take a reference on the subtype assembly(ies).
I have used this technique successfully in 'closed loop' applications where both the client and server are controlled. You should note that this technique is a little slower because calls to your GetKnownTestObjects method have to be made repeatedly at both ends while serialising/deserialising. However, if you're prepared to live with this slight downside it is a fairly clean way of providing generic web services using WCF. It also eliminates the need for all those 'KnownTypeAttributes' specifying actual types.
Is it possible to define a validation method (for businbess rules validation) that will be used by NHibernate.Validator?
I mean something that exists in EntLib:
[HasSelfValidation()]
public class SomeClass
{
//...
[SelfValidation()]
public virtual void DoValidate(ValidationResults results)
{
//...
}
}
Yes, it can be done - but you will be missing a way to communicate more information on which rules were violated in the case of validation errors.
NHibernate Validator, to my knowledge, only provides the ability to specify a text message, the name of the class, and - in the case of property level validation attributes - the name of the violated property.
If your attribute HasSelfValidationAttribute implement IRuleArgs pointing to an IValidator (or IInitializableValidator), it has no way to communicate back anything else but a simple string Message and the name of the class, which would probably be too little information if your demand is to validate "real business rules".
NHibernate Validator is great for simple validation scoped to the properties of a class, but it comes short when you need to do more complex validation.
Have a look at The RulesEngine Project. Your business object won't have to be decorated with any attributes or have to implement any interfaces...
I'm using Unity to resolve types dynamically for a pluggable architecture. I'm also using interception to apply business rule validation via AOP (using ValidationAspects). Finally, I'm using NHibernate as an ORM to persist domain objects.
In order for AOP to work, we use the VirtualMethodInterceptor, as interface interception doesn't work with NHibernate. I have a facade over ISession that handles casting between interface and real types for repository operations.
To make sure that all objects in the graph fetched via NHibernate are properly proxied for AOP, I made an NH IInterceptor implementation and overrode the Instantiate() method, so I could supply NH with created objects rather than have it call new(). I then use Container.Resolve() to get back proxied objects with the validation injected, and give this back to NH to populate. This works OK.
The problem comes when the session flush occurs. NHibernate gets upset because the objects it sees in the graph are of the proxy type rather than the real type. The way we're mapping (all via property, all virtual) NH should be able to get all the values it needs via the proxy, if I could override the type-checking.
What I need to know is: given a transparently proxied object created by Unity with Interception enabled, is there a) any way to obtain a direct reference to the 'real' instance it's proxying, or b) to override NH and tell it to treat objects of a proxy type as if it were of a known mapped type, dynamically at runtime?
We use interception for caching. So in our class, that implements ICallHandler we have code like this:
public IMethodReturn Invoke(IMethodInvocation input, GetNextHandlerDelegate getNext)
{
//...
var nextHandler = getNext();
var realReturn = nextHandler(input, getNext);
var cacheRefreshingItemParameters = new CacheRefreshingItemParameters
{
InterfaceMethod = input.MethodBase,
InterfaceType = input.MethodBase.DeclaringType,
TargetType = input.Target.GetType() //remember original type
};
_cacheProvider.Add(cacheKey, realReturn.ReturnValue, cacheRefreshingItemParameters);
//...
return (cachedReturn);
}
We put cacheRefreshingItemParameters in cache UpdateCallback and then resolve original service:
var service = _unityContainer.Resolve(parameters.TargetType);