**Dropping IConvertible**

Let's start with the 'easy part': dropping the `IConvertible`

. The reason you need it is because you want this code to work on all types, which means you cannot always influence that it has a certain member (`Implies`

). What you would like to do is what they call in C++: template specialization, but unfortunately isn't available (yet?) in C#:

```
static bool Implies<T>(T premise, T conclusion) where T : IConvertible
{
var x = premise.ToUInt64(null);
return x == (x & conclusion.ToUInt64(null));
}
static bool Implies<T>(T premise, T conclusion) where T : Foobar
{
// other fancy logic
}
// and so on
```

The easiest way to solve this is by using multimethods. You can use the 'dynamic' keyword for this:

```
public partial class Implications
{
internal static bool CheckImplies<T>(T lhs, T rhs)
{
return Implies((dynamic)lhs, (dynamic)rhs);
}
public static bool Implies(int lhs, int rhs)
{
return lhs == (lhs & rhs);
}
// your other implies thingies implement this same partial class
}
public static partial class LogicExtensions
{
public static bool Implies<T>(this T premise, T conclusion, Paradox<T> predicate = null)
{
if (null == predicate)
return conclusion.Infers(premise, Implies);
if (Infers != predicate)
return predicate(premise, conclusion);
return Implications.CheckImplies(premise, conclusion);
}
public static bool Infers<T>(this T premise, T conclusion, Paradox<T> predicate = null)
{
if (null == predicate)
return premise.Implies(conclusion, Infers);
if (Implies != predicate)
return predicate(premise, conclusion);
return Implications.CheckImplies(premise, conclusion);
}
}
```

**And if you have a 'third' method, you can simply call it**

I've been looking a couple of minutes at the strange recursive definition and it doesn't really make sense to me... if you have a third helper method anyways, why not simply call it directly? :-)

```
public static bool Implies<T>(this T premise, T conclusion)
{
return Implications.CheckImplies(premise, conclusion);
}
public static bool Infers<T>(this T premise, T conclusion)
{
return Implications.CheckImplies(conclusion, premise);
}
```

**The not(not(T)) problem**

While the above didn't make much sense to me, I find it perfectly reasonable to use the type system and the language to help you out a bit. Well, surely you can do that and this is how I would do that... :-)

Let's introduce a 'Not' class with a generic:

```
public class Not<T>
{
public Not(T val)
{
this.not = val;
}
internal T not;
}
```

If we have a Not> situation here, we want to give - otherwise, we want to use directly. Well, we can do that quite easy with some extensions:

```
public static T Optimize<T>(this Not<Not<T>> var)
{
return Optimize(var.not.not);
}
public static T Optimize<T>(this T var)
{
return var;
}
```

To test it, you can do a similar thing:

```
var val = new Not<Not<int>>(new Not<int>(2));
var result = val.Optimize();
```

This works, because overload resolution will pick the correct Optimize call, which ensures you will optimize the Not>>>> into the T value and so on.

It also works, because we wrap the 'Not' in a wrapper class and then use the type system to our advantage.

**Going back to the original problem**

Instead of directly evaluating 'Implies' and 'Infers', why not use a temporary object to do your evil work. You can use operator overloading (implicit conversion to be precise) to specify how Implies and Infers relate. The only catch is that it has its limits with extension methods.

C# operator overloading will then pick the best matching method. In the first case this will be the exact match, in the second case, the method will be implicitly converted and afterwards Evaluate will be called. In other words, it will not stack overflow, simply because it will do its evaluation lazy. Ready for the code? :-)

```
public class Implies<T>
{
public Implies(T premise, T conclusion)
{
this.premise = premise;
this.conclusion = conclusion;
}
public T premise;
public T conclusion;
public static implicit operator Infers<T>(Implies<T> src)
{
return new Infers<T>(src.conclusion, src.premise);
}
}
public class Infers<T>
{
public Infers(T premise, T conclusion)
{
this.premise = premise;
this.conclusion = conclusion;
}
public T premise;
public T conclusion;
public static implicit operator Implies<T>(Infers<T> src)
{
return new Implies<T>(src.conclusion, src.premise);
}
}
public static partial class LogicExtensions
{
public static Implies<T> Implies<T>(this T premise, T conclusion)
{
return new Implies<T>(premise, conclusion);
}
public static Infers<T> Infers<T>(this T premise, T conclusion)
{
return new Infers<T>(premise, conclusion);
}
}
public class Foo
{
// The things you wish to implement :-)
public static bool Evaluate(Implies<int> impl)
{
return impl.premise == (impl.conclusion & impl.premise);
}
static void Main(string[] args)
{
Implies<int> impl= 0.Implies(2); // will be called directly
Infers<int> impl2 = 0.Infers(2); // will be converted
Console.WriteLine("Res: {0} {1}", Evaluate(impl), Evaluate(impl2));
Console.ReadLine();
}
}
```

Paradox<T>... – ta.speot.is Mar 27 '13 at 11:48doessomething, it doesn'texpressanything. – Stefan Steinegger Mar 27 '13 at 12:09