I'd like to implement the following naive (first order) finite differencing function:

```
finite_difference :: Fractional a => a -> (a -> a) -> a -> a
finite_difference h f x = ((f $ x + h) - (f x)) / h
```

As you may know, there is a subtle problem: one has to make sure that `(x + h)`

and `x`

differ by an exactly representable number. Otherwise, the result has a huge error, leveraged by the fact that `(f $ x + h) - (f x)`

involves catastrophic cancellation (and one has to carefully chose `h`

, but it is not my problem here).

In C or C++, the problem can be solved like this:

```
volatile double temp = x + h;
h = temp - x;
```

and the `volatile`

modifier disables any optimization pertaining to the variable `temp`

, so we are assured that a "clever" compiler will not optimize away those two lines.

I don't know enough Haskell yet to know how to solve this. I'm afraid that

```
let temp = x + h
hh = temp - x
in ((f $ x + hh) - (f x)) / h
```

will get optimized away by Haskell (or the backend it uses). How do I get the equivalent of `volatile`

here (if possible without sacrificing laziness) ? I don't mind GHC specific answers.

`h`

would come from lazy infinite lists. But as far as this particular function is concerned, you are right, I did not think this straight (and I'm trying to get acquainted to the language). – Alexandre C. Apr 12 '11 at 18:27