How does this definition of ArrowLoop.loop work?

The function instance for `ArrowLoop` contains

``````loop :: ((b,d) -> (c,d)) -> (b -> c)
loop f b = let (c,d) = f (b,d) in c
``````

First I have a problem with the signature: How can we possibly get `b -> c` from `(b,d) -> (c,d)`? I mean, the `c` in the resulting tuple may depend on both elements of the input, how is it possible to "cut off" the influence of `d`?

Second I don't get how the `let` works here. Doesn't contain `(c,d) = f (b,d)` a cyclic definition for `d`? Where does `d` come from? To be honest, I'm surprised this is valid syntax, as it looks like we would kind of redefine `d`.

I mean in mathematics this would make kind of sense, e.g. f could be a complex function, but I would provide only the real part b, and I would need to chose the imaginary part d in a way that it doesn't change when I evaluate f (b,d), which would make it some kind of fixed point. But if this analogy holds, the `let` expression must somehow "search" for that fixed point for d (and there could be more than one). Which looks close to magic to me. Or do I think too complicated?

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This works the same way the standard definition of `fix` works:

``````fix f = let x = f x in x
``````

i.e., it's finding a fixed point in the exact same way `fix` does: recursively.

For instance, as a trivial example, consider `loop (\((),xs) -> (xs, 1:xs)) ()`. This is just like `fix (\xs -> 1:xs)`; we ignore our input, and use the `d` output (here `xs`) as our main output. The extra element in the tuple that `loop` has is just to contain the input parameter and output value, since arrows can't do currying. Consider how you'd define a factorial function with `fix` — you'd end up using currying, but when using arrows you'd use the extra parameter and output that `loop` gives you.

Basically, `loop` ties a knot, giving a arrow access to an auxiliary output of itself, just like `fix` ties a knot, giving a function access to its own output as an input.

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"Search for the fixed point" is exactly what this does. This is Haskell's laziness in action. See more at Wikipedia.

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