I am learning Adapter pattern, and used following link to see code. Difference in my code and example code is, I removed ITarget interface, and directly created object in Client.
I know importance of using Interface, but is it really necessary to use interface, more specifically, by not creating interface, am I violating Adapter Pattern rule?
Adapter Pattern Example
My Code (without interface)
class Program
{
static void Main(string[] args)
{
Adapter obj = new Adapter();
Client client = new Client(obj);
client.MakeRequest();
}
}
public class Client
{
private Adapter _target;
public Client(Adapter target)
{
_target = target;
}
public void MakeRequest()
{
_target.MethodA();
}
}
public class Adaptee
{
public void MethodB()
{
Console.WriteLine("MethodB called");
}
}
public class Adapter
{
Adaptee _adaptee = new Adaptee();
public void MethodA()
{
_adaptee.MethodB();
}
}
Thanks.
The whole point of an adapter is that the adaptee can be used wherever a certain type is needed which is not the adaptee's type.
Assume that you have a method MyMethod(MyParameterType m). This method expects a parameter of type MyParameterType. But you don't have an object of this type. Instead you have an object that has similar functionality (maybe from a third-party library). However, this object is not of type MyParameterType, but of type MyOtherType. Of course, you can't directly pass the object to the method. That's where the adapter comes into play.
You need an object to pass to the method. Hence, it is essential that this object is of type MyParameterType; may it be an interface or class. So the Adapter has to implement or inherit this type. Otherwise, it does not make sense. You would just have another class with the same functionality as the object of type MyOtherType, but you can't use it anywhere.
Summarizing, the adapter is used to bridge architectural mismatch. This often occurs when you have several libraries that need to play together but were not supposed to do so. If you have only code that has been developed by yourself, adapters are rarely necessary because you can let the objects just implement the interface you need. This is not possible in third-party code. So you introduce adapters for that. So in the end, the adapter disguises an object to look familiar to a client, even if it is not. The interface is necessary to make it familiar. So yes, your code is not an adapter.
The problem here is you've explicitly coupled Client to the Adapter and implicitly to the behavior of how that adapter works.
Interfaces and this pattern pay off when you start using dependency injection.
Assume I have:
public Client(IAdapter target) ...
Now I can change the behavior of the adapter implementation without the Client class being changed at all:
interface IAdapter
{
void MethodA();
}
interface IAdaptee
{
void MethodB();
}
class Adapter<TAdaptee> : IAdapter where TAdaptee : IAdaptee, new()
{
private TAdaptee _adaptee;
public Adapter()
{
_adaptee = new TAdaptee();
}
public void MethodA()
{
_adaptee.MethodB();
}
}
class AdapteeA : IAdaptee
{
public void MethodB()
{
Console.WriteLine("AdapteeA");
}
}
class AdapteeB : IAdaptee
{
public void MethodB()
{
Console.WriteLine("AdapteeB");
}
}
Then with something like NInject you bind up your system:
class Program
{
private static StandardKernel _kernel;
static void Main(string[] args)
{
_kernel = new StandardKernel();
_kernel.Bind<IAdapter>().To<Adapter<AdapteeA>>();
var adapter = _kernel.Get<IAdapter>();
adapter.MethodA();
}
}
You can change your adapter and your adaptee, without client ever knowing the difference. i.e. Client is decoupled from both.
Again to make this point I can change to AdapteeB:
_kernel.Bind<IAdapter>().To<Adapter<AdapteeB>>();
It does go further too, with things like contra-variance, but that is beyond scope.
Related
For my project purpose I need to send metrics to AWS.
I have main class called SendingMetrics.
private CPUMetric _cpuMetric;
private RAMMetric _ramMetric;
private HDDMetric _hddMetric;
private CloudWatchClient _cloudWatchClient(); //AWS Client which contains method Send() that sends metrics to AWS
public SendingMetrics()
{
_cpuMetric = new CPUMetric();
_ramMetric = new RAMMetric();
_hddMetric = new HDDMetric();
_cloudwatchClient = new CloudwatchClient();
InitializeTimer();
}
private void InitializeTimer()
{
//here I initialize Timer object which will call method SendMetrics() each 60 seconds.
}
private void SendMetrics()
{
SendCPUMetric();
SendRAMMetric();
SendHDDMetric();
}
private void SendCPUMetric()
{
_cloudwatchClient.Send("CPU_Metric", _cpuMetric.GetValue());
}
private void SendRAMMetric()
{
_cloudwatchClient.Send("RAM_Metric", _ramMetric.GetValue());
}
private void SendHDDMetric()
{
_cloudwatchClient.Send("HDD_Metric", _hddMetric.GetValue());
}
Also I have CPUMetric, RAMMetric and HDDMetric classes that looks pretty much similar so I will just show code of one class.
internal sealed class CPUMetric
{
private int _cpuThreshold;
public CPUMetric()
{
_cpuThreshold = 95;
}
public int GetValue()
{
var currentCpuLoad = ... //logic for getting machine CPU load
if(currentCpuLoad > _cpuThreshold)
{
return 1;
}
else
{
return 0;
}
}
}
So the problem I have is that clean coding is not satisfied in my example. I have 3 metrics to send and if I need to introduce new metric I will need to create new class, initialize it in SendingMetrics class and modify that class and that is not what I want. I want to satisfy Open Closed principle, so it is open for extensions but closed for modifications.
What is the right way to do it? I would move those send methods (SendCPUMetric, SendRAMMetric, SendHDDMetric) to corresponding classes (SendCPUMetric method to CPUMetric class, SendRAMMEtric to RAMMetric, etc) but how to modfy SendingMetrics class so it is closed for modifications and if I need to add new metric to not change that class.
In object oriented languages like C# the Open Closed Principle (OCP) is usually achieved by using the concept of polymorphism. That is that objects of the same kind react different to one and the same message. Looking at your class "SendingMetrics" it's obvious that the class works with different types of "Metrics". The good thing is that your class "SendingMetrics" talks to a all types of metrics in the same way by sending the message "getData". Hence you can introduce a new abstraction by creating an Interface "IMetric" that is implemented by the concrete types of metrics. That way you decouple your "SendingMetrics" class from the concrete metric types wich means the class does not know about the specific metric types. It only knows IMetric and treats them all in the same way wich makes it possible to add any new collaborator (type of metric) that implements the IMetric interface (open for extension) without the need to change the "SendingMetrics" class (closed for modification). This also requires that the objects of the different types of metrics are not created within the "SendingMetrics" class but e.g. by a factory or outside of the class and being injected as IMetrics.
In addition to using inheritance to enable polymorphism and achiving OCP by introducing the interface IMetric you can also use inheritance to remove redundancy. Which means you can introduce an abstract base class for all metric types that implements common behaviour that is used by all types of metrics.
Your design is almost correct. You got 3 data retriever and 1 data sender. So it's easy to add more metric (more retriever) (open for extensions) without affecting current metrics (closed for modifications), you just need a bit more refactor to reduce duplicated code.
Instead of have 3 metrics classes look very similar. Only below line is different
var currentCpuLoad = ... //logic for getting machine CPU load
You can create a generic metric like this
internal interface IGetMetric
{
int GetData();
}
internal sealed class Metric
{
private int _threshold;
private IGetMetric _getDataService;
public Metric(IGetMetric getDataService)
{
_cpuThreshold = 95;
_getDataService = getDataService;
}
public int GetValue()
{
var currentCpuLoad = _getDataService.GetData();
if(currentCpuLoad > _cpuThreshold)
{
return 1;
}
else
{
return 0;
}
}
}
Then just create 3 GetMetric classes to implement that interface. This is just 1 way to reduce the code duplication. You can also use inheritance (but I don't like inheritance). Or you can use a Func param.
UPDATED: added class to get CPU metric
internal class CPUMetricService : IGetMetric
{
public int GetData() { return ....; }
}
internal class RAMMetricService : IGetMetric
{
public int GetData() { return ....; }
}
public class AllMetrics
{
private List<Metric> _metrics = new List<Metric>()
{
new Metric(new CPUMetricService());
new Metric(new RAMMetricService());
}
public void SendMetrics()
{
_metrics.ForEach(m => ....);
}
}
I have an interface:
interface ISqlite
{
void insert();
void update();
void delete();
void select();
}
And custom service class:
class SqliteService
{
public SQLiteDatabase driver;
public SqliteService() {
SqliteConnection(new SQLiteDatabase());
}
public void SqliteConnection(SQLiteDatabase driver)
{
this.driver = driver;
}
public void select(ISqlite select) {
select.select();
}
public void insert(ISqlite insert) {
insert.insert();
}
public void delete(ISqlite delete)
{
delete.delete();
}
}
And last class Pacients that realizes ISqlite interface:
class Pacients: ISqlite
{
public List<ClientJson> pacients;
public Pacients() {
this.pacients = new List<ClientJson>();
}
public void add(ClientJson data) {
this.pacients.Add(data);
}
public void insert()
{
throw new NotImplementedException();
}
/* Others methos from interface */
}
I try to use my code like as:
/* Create instance of service class */
SqliteService serviceSqlite = new SqliteService();
/* Create instance of class */
Pacients pacient = new Pacients();
pacient.add(client);
serviceSqlite.insert(pacient);
As you can see above I send object pacient that realizes interface ISqlite to service. It means that will be called method insert from object pacient.
Problem is that I dont understand how to add data in this method using external class: SQLiteDatabase()? How to get access to this.driver in service class from object pacient?
Edit 1
I think I must move instance of connection new SQLiteDatabase() to db inside Pacients class is not it?
Generally speaking, I would favor a solution where the data objects themselves don't know anything about how they're stored, i.e. they have no knowledge of the class that communicates with the database. Many ORMs do just that.
Of course it might not be easy depending on the specifics of your situation... Try to examine what your methods on each object actually need; generally speaking they need the values of properties, and what column each property corresponds to, right? So any external class can do this if it knows these bits of information. You can specify the name of the column with a custom attribute on each property (and if the attribute isn't there, the column must have the same name as the property).
And again, this is the most basic thing that ORMs (Object Relational Mappers) do, and in addition they also manage more complicated things like relationships between objects/tables. I'm sure there are many ORMs that work with SqlLite. If you're OK with taking the time to learn the specifics of an ORM, that's what I would recommend using - although they're not silver bullets and will never satisfy all possible requirements, they are in my opinion perfect for automating the most common day to day things.
More to the point of the question, you can of course make it work like that if you pass the SQLiteDatabase object to the methods, or keep it in a private field and require it in the constructor or otherwise make sure that it's available when you need it; there's no other simple solution I can think of. And like you pointed out, it implies a certain degree of coupling.
You can change the signature of interface's methods to pass an SQLiteDatabase object.
interface ISqlite
{
void insert(SQLiteDatabase driver);
void update(SQLiteDatabase driver);
void delete(SQLiteDatabase driver);
void select(SQLiteDatabase driver);
}
Example call from the service:
public void insert(ISqlite insert)
{
insert.insert(driver);
}
I think you can figure out the rest by yourself.
I have two .NET parties who needs be bound by a contract. Now, party1 and party2 need to be able call some methods on each other (most of it is calls and reporting result back). I have duplex contract in mind, but the parties are not using WCF.
Is there a design pattern for this?
Edit
The parties are part of the same application. I create the application (party1) and someone else creates a dll (party2) that I load dynamically. Now, both of us should be able to call methods on each other. So, I am out to create an interface contract between us. The intent is to know whether there is a know pattern to do that?
A common solution is to use some kind of pub/sub pattern. By doing so you can avoid circular dependencies.
Basically you create some kind of class which are used to subscribe on events (and publish them).
So both your classes does something like this (but with different events):
public class ClassA : IEventHandler<UserCreated>
{
IEventManager _eventManager
public ClassA(IEventManager manager)
{
// I subscribe on this event (which is published by the other class)
manager.Subscribe<UserCreated>(this);
_eventManager = manager;
}
public void Handle(UserCreated theEvent)
{
//gets invoked when the event is published by the other class
}
private void SomeInternalMethod()
{
//some business logic
//and I publish this event
_eventManager.Publish(new EmailSent(someFields));
}
}
The event manager (simplified and not thread safe):
public class EventManager
{
List<Subscriber> _subscribers = new List<Subscriber>();
public void Subscribe<T>(IEventHandler<T> subscriber)
{
_subscribers.Add(new Subscriber{ EventType = typeof(T), Subscriber = subscriber});
}
public void Publish<T>(T theEvent)
{
foreach (var wrapper in subscribers.Where(x => x == typeof(theEvent)))
{
((IEventHandler<T>)wrapper.Subscriber).Handle(theEvent);
}
}
}
The small wrapper:
public class Subscriber
{
public Type EventType;
public object Subscriber;
}
Voila. the two classes are now loosely coupled from each other (while still being able to communicate with each other)
If you use an inversion of control container it get's easier since you can simplify the event manager and just use the container (service location) to resolve all subscribers:
public class EventManager
{
IYourContainer _container;
public EventManager(IYourContainer container)
{
_container = container;
}
public void Publish<T>(T theEvent)
{
foreach (var subscriber in _container.ResolveAll<IEventHandler<T>>())
{
subscriber.Handle(theEvent);
}
}
}
I think you can use next logic:
Class1: Interface1 , Class2:Interface2,
class Manager{
public Manager(Interface1 managedPart1,Interface2 managedPart2){
... some logic for connect to interfaces
}
}
This way reminds me pattern Bridge, but this is very subjective
I chose to expose some new behavior using composition vs. injecting a new object into my consumers code OR making the consumer provide their own implementation of this new behavior. Did I make a bad design decision?
I had new requirements that said that I needed to implement some special behavior in only certain circumstances. I chose to define a new interface, implement the new interface in a concrete class that was solely responsible for carrying out the behavior. Finally, in the concrete class that the consumer has a reference to, I implemented the new interface and delegate down to the class that does the work.
Here are the assumptions that I was working with...
I haven an interface, named IFileManager that allows implementors to manage various types of files
I have a factory that returns a concrete implementation of IFileManager
I have 3 implementations of IFileManager, these are (LocalFileManager, DfsFileManager, CloudFileManager)
I have a new requirements that says that I need to manage permissions for only the files being managed by the CloudFileManager, so the behavior for managing permissions is unique to the CloudFileManager
Here is the test that led me to the code that I wrote...
[TestFixture]
public class UserFilesRepositoryTest
{
public interface ITestDouble : IFileManager, IAclManager { }
[Test]
public void CreateResume_AddsPermission()
{
factory.Stub(it => it.GetManager("cloudManager")).Return(testDouble);
repository.CreateResume();
testDouble.AssertWasCalled(it => it.AddPermission());
}
[SetUp]
public void Setup()
{
testDouble = MockRepository.GenerateStub<ITestDouble>();
factory = MockRepository.GenerateStub<IFileManagerFactory>();
repository = new UserFileRepository(factory);
}
private IFileManagerFactory factory;
private UserFileRepository repository;
private ITestDouble testDouble;
}
Here is the shell of my design (this is just the basic outline not the whole shibang)...
public class UserFileRepository
{
// this is the consumer of my code...
public void CreateResume()
{
var fileManager = factory.GetManager("cloudManager");
fileManager.AddFile();
// some would argue that I should inject a concrete implementation
// of IAclManager into the repository, I am not sure that I agree...
var permissionManager = fileManager as IAclManager;
if (permissionManager != null)
permissionManager.AddPermission();
else
throw new InvalidOperationException();
}
public UserFileRepository(IFileManagerFactory factory)
{
this.factory = factory;
}
private IFileManagerFactory factory;
}
public interface IFileManagerFactory
{
IFileManager GetManager(string managerName);
}
public class FileManagerFactory : IFileManagerFactory
{
public IFileManager GetManager(string managerName)
{
IFileManager fileManager = null;
switch (managerName) {
case "cloudManager":
fileManager = new CloudFileManager();
break;
// other managers would be created here...
}
return fileManager;
}
}
public interface IFileManager
{
void AddFile();
void DeleteFile();
}
public interface IAclManager
{
void AddPermission();
void RemovePermission();
}
/// <summary>
/// this class has "special" behavior
/// </summary>
public class CloudFileManager : IFileManager, IAclManager
{
public void AddFile() {
// implementation elided...
}
public void DeleteFile(){
// implementation elided...
}
public void AddPermission(){
// delegates to the real implementation
aclManager.AddPermission();
}
public void RemovePermission() {
// delegates to the real implementation
aclManager.RemovePermission();
}
public CloudFileManager(){
aclManager = new CloudAclManager();
}
private IAclManager aclManager;
}
public class LocalFileManager : IFileManager
{
public void AddFile() { }
public void DeleteFile() { }
}
public class DfsFileManager : IFileManager
{
public void AddFile() { }
public void DeleteFile() { }
}
/// <summary>
/// this class exists to manage permissions
/// for files in the cloud...
/// </summary>
public class CloudAclManager : IAclManager
{
public void AddPermission() {
// real implementation elided...
}
public void RemovePermission() {
// real implementation elided...
}
}
Your approach to add your new behavior only saved you an initialization in the grand scheme of things because you to implemented CloudAclManager as separate from CloudFileManager anyways. I disagree with some things with how this integrates with your existing design (which isn't bad)...
What's Wrong With This?
You separated your file managers and made use of IFileManager, but you didn't do the same with IAclManager. While you have a factory to create various file managers, you automatically made CloudAclManager the IAclManager of CloudFileManager. So then, what's the point of having IAclManager?
To make matters worse, you
initialize a new CloudAclManager
inside of CloudFileManager every time you try to get its ACL
manager - you just gave factory
responsibilities to your
CloudFileManager.
You have CloudFileManager implement IAclManager on top of having it as a property. You just moved the rule that permissions are unique to CloudFileManager into your model layer rather than your business rule layer. This also results in supporting the unnecessary
potential of circular referencing between self and property.
Even if you wanted
CloudFileManager to delegate the
permission functionality to
CloudAclManager, why mislead other
classes into thinking that
CloudFileManager handles its own
permission sets? You just made your
model class look like a facade.
Ok, So What Should I Do Instead?
First, you named your class CloudFileManager, and rightly so because its only responsibility is to manage files for a cloud. Now that permission sets must also be managed for a cloud, is it really right for a CloudFileManager to take on these new responsibilities? The answer is no.
This is not to say that you can't have code to manage files and code to manage permissions in the same class. However, it would then make more sense for the class to be named something more general like CloudFileSystemManager as its responsibilities would not be limited to just files or permissions.
Unfortunately, if you rename your class it would have a negative effect on those currently using your class. So how about still using composition, but not changing CloudFileManager?
My suggestion would be to do the following:
1. Keep your IAclManager and create IFileSystemManager
public interface IFileSystemManager {
public IAclManager AclManager { get; }
public IFileManager FileManager { get; }
}
or
public interface IFileSystemManager : IAclManager, IFileManager {
}
2. Create CloudFileSystemManager
public class CloudFileSystemManager : IFileSystemManager {
// implement IFileSystemManager
//
// How each manager is set is up to you (i.e IoC, DI, simple setters,
// constructor parameter, etc.).
//
// Either way you can just delegate to the actual IAclManager/IFileManager
// implementations.
}
Why?
This will allow you to use your new behavior with minimal impact to your current code base / functionality without affecting those who are using your original code. File management and permission management can also coincide (i.e. check permissions before attempting an actual file action). It's also extensible if you need any other permission set manager or any other type of managers for that matter.
EDIT - Including asker's clarification questions
If I create IFileSystemManager : IFileManager, IAclManager, would the repository still use the FileManagerFactory and return an instance of CloudFileSystemManager?
No, a FileManagerFactory should not return a FileSystemManager. Your shell would have to update to use the new interfaces/classes. Perhaps something like the following:
private IAclManagerFactory m_aclMgrFactory;
private IFileManagerFactory m_fileMgrFactory;
public UserFileRepository(IAclManagerFactory aclMgrFactory, IFileManagerFactory fileMgrFactory) {
this.m_aclMgrFactory = aclMgrFactory;
this.m_fileMgrFactory = fileMgrFactory;
}
public void CreateResume() {
// I understand that the determination of "cloudManager"
// is non-trivial, but that part doesn't change. For
// your example, say environment = "cloudManager"
var environment = GetEnvMgr( ... );
var fileManager = m_fileMgrFactory.GetManager(environment);
fileManager.AddFile();
// do permission stuff - see below
}
As for invoking permission stuff to be done, you have a couple options:
// can use another way of determining that a "cloud" environment
// requires permission stuff to be done
if(environment == "cloudManager") {
var permissionManager = m_aclMgrFactory.GetManager(environment);
permissionManager.AddPermission();
}
or
// assumes that if no factory exists for the environment that
// no permission stuff needs to be done
var permissionManager = m_aclMgrFactory.GetManager(environment);
if (permissionManager != null) {
permissionManager.AddPermission();
}
I think that composition is exactly the right means to to this kind of trick. But I think you should keep it more simple (KISS) and just make an IAclManager property in the IFileManager and set it to null by default and set the SecurityManager implementation for the cloud service there.
This has different upsides:
You can check if permissions need to be checked by nullchecking the securityManager property. This way, if there doesn't need to be permissionsManaging done (as with localfile system), you don't have exceptions popping up. Like this:
if (fileManager.permissionsManager != null)
fileManager.permissionsManager.addPermission();
When you then carry out the task (to add or delete a file), you can check again if there's a permissionsManager and if the permission is given, if not throw exception (as you'll want to throw the exception when a permission to do an action is missing, not if a permission is missing in general if you're not going to add or delete files).
You can later on implement more IAclManagers for the other IFileManagers when your customer changes the requirements next time the same way as you would now.
Oh, and then you won't have such a confusing hierarchy when somebody else looks at the code ;-)
In general it looks good, but I do have a few suggestions. It seems that your CreateResume() method implementation demands a IFileManager that is also an IAclManager (or else it throws an exception).
If that is the case, you may want to consider adding an overload to your GetManager() method in which you can specify the interface that you require, and the factory can have the code that throws an exception if it doesn't find the right file manager. To accompolish this you can add another interface that is empty but implements both IAclManager and IFileManager:
public interface IAclFileManager : IFileManager, IAclManager {}
And then add the following method to the factory:
public T GetManager<T>(string name){ /* implementation */}
GetManager will throw an exception if the manager with the name given doesn't implement T (you can also check if it derives from or is of type T also).
All that being said, if AddPermissions doesn't take any parameters (not sure if you just did this for the post), why not just call AddPermissions() from CloudFileManager.AddFile() method and have it completely encapsulated from the user (removing the need for the new IAclManager interface)?
In any event, doesn't seem like a good idea to call AddFile in the CreateResume() method and only then throw the exception (since you now you have now created a file without the correct permissions which could be a security issue and also the consumer got an exception so he may assume that AddFile didn't succeed, as opposed to AddPermission).
Good luck!
Let's say you have two different C# classes A and B that while not deriving from the same base class do share some of the same names for methods. For example, both classes have a connect and a disconnect method, as well as several others. I want to be able to write code once that will work with both types.
Here is a simplified example of what I would like to do:
public void make_connection(Object x)
{
x.connect() ;
// Do some more stuff...
x.disconnect() ;
return ;
}
Of course, this does not compile as the Object class does not have a connect or disconnect method.
Is there a way to do this?
UPDATE. I should have made this clear from the start: I only have the DLLs for A and B and not the source.
You can use an interface to accomplish what you want to do.
interface IConnectable
{
void Connect();
void Disconnect();
}
Both A and B should implement IConnectable. Then use IConnectable instead of Object as the parameter type for your method and you should be all set.
public void MakeConnection(IConnectable connectable)
{
connectable.Connect();
// Do some more stuff...
connectable.Disconnect();
}
Edit: Since you don't have the source code, you have a couple of options:
Use Max's solution of using the dynamic keyword, (if you are using .NET 4.0)
Use Steve's solution of using casting and if/else statements
Create wrapper classes for A and B and have them implement the interface (or use common abstract base class for them)
For example:
class AWrapper : IConnectable
{
private A obj;
public AWrapper(A obj)
{
this.obj = obj;
}
public void Connect()
{
this.obj.Connect();
}
public void Disconnect()
{
this.obj.Disconnect();
}
// other methods as necessary
}
(BWrapper would be similar, just using B instead of A)
Then you could create the wrappers and pass them into MakeConnection. It's up to you how you want to do it. Depending on your situation, one method may be easier than the others.
This will work in C# 4:
public void make_connection(dynamic x)
{
x.connect() ;
// Do some more stuff...
x.disconnect() ;
return ;
}
Try using an Interface rather.
Have a look at interface (C# Reference) and Interfaces (C# Programming Guide)
So something like
public interface IConnections
{
void connect();
void disconnect();
}
public class A : IConnections
{
public void connect()
{
//do something
}
public void disconnect()
{
//do something
}
}
public class B : IConnections
{
public void connect()
{
//do something
}
public void disconnect()
{
//do something
}
}
public void make_connection(IConnections x)
{
x.connect();
// Do some more stuff...
x.disconnect();
return;
}
There is a OOAD concept of 'Programe to an interface not to an implementation' which let's you avoid the chain of inheritance hierarchies
1- You can create a interfcae
interface IConnection
{
void Connect();
void Disconnect();
}
2- And let your classes implement this interface as shown below.
class A : IConnection
{
#region IConnection Members
public void Connect()
{
// your connect method implementation goes here.
}
public void Disconnect()
{
// your disconnect method implementation goes here.
}
#endregion
}
class B : IConnection
{
#region IConnection Members
public void Connect()
{
// your connect method implementation goes here.
}
public void Disconnect()
{
// your disconnect method implementation goes here.
}
#endregion
}
3- Once you done with the implementation than you can make your function accepting an argument of IConnection as shown below.
public void makeConnection(IConnection con)
{
con.Connect();
con.Disconnect();
}
4- And from your client code , you can pass the object of classes which implements IConnect Interface.
If the interface solution is not possible (e.g you don't have source code), another less effecient solution is to use reflection.
As others have said, re-factoring to use interfaces or using the dynamic approach are probably the most elegant ways.
If this is not possible you could cast the object to your types. I'd suggest using as and then checking that the cast worked, an unchecked cast would be dangerous if someone called this with a type that failed to cast.
E.g. If types A and B both have a method called DoSomething() then this will work...
public static void CallDoSomething(object o)
{
A aObject = o as A;
if (aObject != null)
{
aObject.DoSomething();
return;
}
B bObject = o as B;
if (bObject != null)
{
bObject.DoSomething();
return;
}
}
BUT this is pretty ugly to be honest... I'd really try and refactor to interfaces.
Either you will have to use an Interface (or Base class) as shown by Zach and astander, or you will have to case the object before using:
public void make_connection(Object x)
{
((A)x).connect() ;
// Do some more stuff...
x.disconnect() ;
return ;
}
You could also use reflection to invoke the methods
What you want is called Duck Typing.
From Wikipedia:
Duck typing is a style of dynamic typing in which an object's current set of methods and properties determines the valid semantics, rather than its inheritance from a particular class or implementation of a specific interface.
C# 4.0 allows this, as other have said, using the dynamic keyword