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My apologies if it is quite confusing.

I have this two main interfaces. First the ISensor interface:

public interface ISensor<TReading>
    where TReading : ISensorReading<ISensor<TReading>>
    event SensorReadingCompletedEH<ISensor<TReading>, TReading> ReadCompleted;
    TReading Read();

And the second interface: ISensorReading:

public interface ISensorReading<TSensor>
    where TSensor : ISensor<ISensorReading<TSensor>>
    TSensor Sensor { get; }

It leads to the following errors:

The type ISensor<TReading> must be convertible to
ISensor<ISensorReading<ISensor<TReading>>> in order to use it as parameter TSensor in the generic type or method ISensorReading<TSensor>


The type ISensorReading<TSensor> must be convertible to
ISensorReading<ISensor<ISensorReading<TSensor>>> in order to use it as parameter TReading in the generic type or method ISensor<TReading>

I fear it is due to an insolvable circular reference at compile time; however I want to ensure congruence for derived types like TelemetricSensor : ISensor<TelemetricReading> and TelemetricReading : ISensorReading<TelemetricSensor>

Which other aproaches should I use to allow simple casting and type safe?

I am using .NET 2.0 and VS2005

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3 Answers 3

You are right- you can't define them using generic type constraints this way, because it leads to infinite nesting.

What you can do is have a concrete implementation of one or the other, for instance:

public interface ITelemetricSensorReading : ISensorReading

and then constrain the sensor to enforce an implementation of that:

public interface ITelemetricSensor<TReading> : ISensor<TReading> where TReading : ITelemetricSensorReading
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Say, you define your two types:

    class AReading : ISensorReading<ASensor> { }
    class ASensor : ISensor<AReading> { }

Now, declaration ISensorReading<ASensor> is illegal, because ASensor does NOT implement ISensor<ISensorReading<ASensor>>. Instead, it implements ISensor<Areading>, which is different.

See, in .NET, the statement A : B does not generally imply statement I<A> : I<B>. And if you think about it carefully, this is not necessarily true - depends on the nature of I.

The feature(s) you're looking for are called "Covariance" and "Contravariance". That is another feature of C#, where you can tell the compiler that for your particular interface I, the above implication does, in fact, hold (covariance), or that the reverse implication I<B> : I<A> holds (contravariance).

The first one you achieve by using the out keyword:

    interface I<out T> { ... }

The second - by using the in keyword:

    interface I<in T> { ... }

Unfortunately, however, covariance and contravariance in generic type parameters has only been introduced in C# 4.0, so you're out of luck here.

You could upgrade to C# 4.0 (which is what I strongly recommend), or you could rely on your unit tests to make sure all types stay coherent.

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Indeed some times covariance and contravariance causes headache. Unfortunately my applications must be as compatible as possible with MONO and upgrade to C# 4.0 is not an option. Also I've noticed .NET 4.0 is not as eficient as .NET 2.0 – Gzork Jan 21 '12 at 21:43
.net 4.0 is less efficient than 2.0? How, exactly? – Chris Shain Jan 21 '12 at 23:27
up vote 0 down vote accepted

Thanks all for your answers.

Finally this is the solution I choose for the problem. Hope to be usefull. If you have comments or know a way to impriove it without change the framework, let me know.

First I created an ISensor interface with the minimal requirements. After that I defined a new ISensor generic interface as follows:

public delegate void SensorErrorEventHandler<TSensor>(TSensor sensor, ISensorError error)
    where TSensor : ISensor;

public delegate void SensorReadingCompletedEventHandler<TSensor, TReading>(TSensor sensor, TReading[] read)
    where TSensor : ISensor
    where TReading : ISensorReading<TSensor>;

public interface ISensor : IDisposable
    bool IsOpen { get; }
    bool Started { get; }
    void Connect();
    void Disconnect();
    void Start();
    void Stop();

public interface ISensor<TSensor, TReading> : ISensor
    where TSensor : ISensor
    where TReading : ISensorReading<TSensor>
    TReading[] LastReadings { get; }
    event SensorErrorEventHandler<TSensor> Error;
    event SensorReadingCompletedEventHandler<TSensor, TReading> ReadCompleted;
    bool Read(out TReading[] readings);

public interface ISensorReading<TSensor> where TSensor : ISensor
    TSensor Sensor { get; }
    bool Mistaken { get; }

With theese interfaces defined and following the same structures, I was able to made the first implementation: A TelemetricSensor class with its correspondient ITelemetricReading

public delegate void TelemetricSensorThresholdExceededEventHandler<TSensor>(TSensor sensor)
    where TSensor : ITelemetricSensor;

public interface ITelemetricSensor : ISensor
    /* Properties, events and methods */

public interface ITelemetricReading : ISensorReading<ITelemetricSensor>
    /* Properties, events and methods */

public abstract class TelemetricSensor<TSensor, TReading> : ITelemetricSensor, ISensor<TSensor, TReading>
    where TSensor : ITelemetricSensor
    where TReading : ITelemetricReading, ISensorReading<TSensor>
    public abstract TReading[] LastReadings { get; }
    public event SensorErrorEventHandler<TSensor> Error;
    public event SensorReadingCompletedEventHandler<TSensor, TReading> ReadCompleted;

    public abstract bool Read(out TReading[] readings);

Here TReading of the TelemetricSensor abstract class is interesting. It is defined as

TReading : ITelemetricReading, ISensorReading<TSensor>

which may appear to be redundant because ITelemetricReading inherits from ISensorReading, but it is required to get the code compile and met the requirement for both

TReading[] LastReadings { get; }

property and

bool Read(out TReading[] readings);

method. Finally to skip tedious casting (and perhaps some errors) mutiple overloads of Read(...) can be done so each provides the data casted correctly and also met all interface implementations.

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