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Continuing on in the tutorial, in section A more complex side effect: Random Numbers I come to this:

bind :: (a → StdGen → (b,StdGen)) → (StdGen → (a,StdGen)) → (StdGen → (b,StdGen))

when the type of the "randomised function" (as the author calls it) is as follows:

a → StdGen -> (b,StdGen)

Furthermore, the bind is defined as:

bind f x seed = let (x',seed') = x seed in f x' seed'

Question: Why does the bind have an extra StdGen the end of it's signature? Shouldn't it be:

bind :: (a → StdGen → (b,StdGen)) → (StdGen → (a,StdGen)) → (b,StdGen)

My reasoning goes as follows:

  1. Bind takes a function f:: a -> StdGen -> (b,StdGen) and the "output" StdGen -> (a,StdGen).
  2. It applies the f to the a and StdGen, and returns whatever the signature of f says it would - which is just (b, StdGen):

    f::a -> StdGen -> (b,StdGen)
    
  3. Even following bind implementation, f is applied to both a value x' and a seed' of type StdGen, so it's result MUST be a tuple!

     bind f x seed = let (x',seed') = x seed in f x' seed'
    

Anywhere I went wrong there? Any help appreciated!

N.B.: For future readers, the author's definition of bind is equivalent to standard one except with the arguments flipped: flip . >>=

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1 Answer

up vote 3 down vote accepted

Let's take your type:

bind :: (a → StdGen → (b,StdGen)) → (StdGen → (a,StdGen)) → (b,StdGen)

Now, I'm 100% with you on your first point:

Bind takes a function f :: a -> StdGen -> (b,StdGen) and the "output" StdGen -> (a,StdGen).

But your second worries me:

It applies the f to the a and StdGen.

Where did you get a value of type a from? Where did you get a value of type StdGen from?

The answer to both of these questions is "you don't have one lying about"; however, since you do have a StdGen -> (a,StdGen) lying about, you could get both if only you had one more StdGen parameter. And that's where the extra parameter comes from.

Now, a slightly higher-level explanation. Part of the problem (I think) is that these type signatures are a bit too cluttered to read comfortably. We need some abstractions. What we're trying to model here are probability distributions, which we're modeling as their sampling functions. So, we can say a distribution over a is a function that knows how to sample from the distribution and return an a:

type Dist a = StdGen -> (a, StdGen)

Now, not all distributions are so flat as all that. For example, the Bernoulli distribution is "sort of" a Dist Bool, but it's also parameterized on the probability of choosing False. We can write its type thus:

bernoulli :: Double -> Dist Bool

So, we can model parameterized distributions as functions that return distributions; equivalently, we can think of functions that return distributions as parameterized distributions.

Now with this high-level interpretation in mind, the type of bind becomes much more readable:

bind :: (a -> Dist b) -> (Dist a -> Dist b)

This says that bind is the function that tells how to first sample from an a distribution, then use that a as a parameter when sampling from the b distribution. Not only that, but with this type alias, it almost becomes unthinkable to write a type for bind that doesn't have the "extra" argument.

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