Does F# have the same problem as C# where you can't directly use arithmetic operators with generic T types?
Can you write a generic Sum function that would return the sum of any value that supports the arithmetic addition?
As brian mentioned, there is some built-in support for generic arithmethic and you can use 'static constraints' which allow you to define some generic functions yourself (although this is a bit limited).
In addition to this, you can also use dynamic 'numeric associations', which is a bit slower when using in a function, but it can be nicely used for example to define your own vector or matrix type. Here is an example:
We first need to reference F# PowerPack library which contains the functionality. Then we define a generic function with a signature
When you define your own numeric type, you can define its numeric operations and register them using
F# has some limited support for this. A good general solution probably involves type classes, which are not supported by the CLR in general, or F# in particular.
F# has overloaded arithmetic operators using 'static member constraints' and 'inline' functions. This is the magic that enables e.g. the
See also the 'static member constraints' and 'simulate type classes' part of this answer:
as well as various bits of the library like
You could do something like this.
However if I try
The best mechanism I'm aware of for performing generic arithmetic is type classes, which sadly neither C#, F#, nor the .Net runtime in general support. However, you can simulate them yourself by hand, as mentioned in this blog post:
That technique should work in C# 2.0 or later (using anonymous delegates / lambdas).
Often people turn to interfaces, but run into a couple problems
An interface declares that, for all implementations, all the methods on that interface take the same implicit 'this' parameter type. If Foo implements some interface, then obviously the 'this' parameter must be of type Foo for that implementation. But there's no way to require that other method parameters also be of type Foo.
Type classes allow you to (among other things) perform this kind of constraint on all method parameters, not just the first parameter.
As mentioned in the article cited earlier, you can simulate type classes by passing function tables as explicit arguments.
(Community wiki: would post an example from that article translated into C# here, but ran out of time with long-winded explaination)