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I was thinking of a way to represent algebraic numbers in Haskell as a stream of approximations. You could probably do this by some root finding algorithm. But that's no fun. So you could add x to the polynomial, reducing the problem to finding it's fixed points.

So if you have a function in Haskell like

f :: Double -> Double
f x = x ^ 2 + x

I don't conceptually understand why fix doesn't work, which is to say, I can easily verify for myself that it doesn't work, but isn't 0 the true least fixed point of f? Is there another simple (as in definition size) fixed point function that would work?

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fix finds the least defined fixed point which in many cases is ⊥ (non-termination, error, ...). See also: stackoverflow.com/a/8099449/700253 –  Vitus Jul 26 '13 at 20:03
This is a very good question, but I find it quite difficult to answer without going too abstract. I'm trying to formulate a good answer. –  hivert Jul 26 '13 at 20:19
As vitus says, the ordering where fix finds the least fixed point is domain ordering, rather than the regular ordering on Double. –  augustss Jul 26 '13 at 20:55
If you look at the tag wiki for [fixed-point], you'll see that it's not the tag you were looking for. –  Gabe Jul 28 '13 at 4:10
@Vitrus, thanks for the clarification. I was also wondering if there is a fixed point function that doesn't only find the least fixed point. –  Senjougahara Hitagi Jul 28 '13 at 8:26

1 Answer 1

Here is the implementation of the fix function:

fix :: (a -> a) -> a
fix f = let x = f x in x

It doesn't work for primitive types like Double. It's intended for types that have a more complex structure to them. For instance:

g :: Maybe Int -> Maybe Int
g i = Just $ case i of
    Nothing -> 3
    Just _ -> 4

This function will work with fix because it yields information about its result faster than it reads its input. in other words, the Just portion is known without looking at i at all, which enables it to reach a fixed point.

When your function is Double -> Double, and examines its input, fix won't work because there's no way to partially evaluate a Double.

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