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Statically sized vectors in Haskell are shown in Oleg Kiselyov's Number-parameterized types and can also be found in the Data.Param.FSVec type from the parameterized-data module on Hackage:

data Nat s => FSVec s a

FSVec is not an instance of the Monad type class.

The monad instance for lists, can be used to remove or duplicate elements:

Prelude> [1,2,3] >>= \i -> case i of 1 -> [1,1]; 2 -> []; _ -> [i]

Whether similar to the list version or not, is it possible to construct a monad from a fixed length vector?

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up vote 7 down vote accepted

Yes it is possible, if not natural.

The monad has to 'diagonalize' the result in order to satisfy the monad laws.

That is to say, you can look at a vector as a tabulated function from [0..n-1] -> a and then adapt the monad instance for functions.

The resulting join operation takes a square matrix in the form of a vector of vectors and returns its diagonal.


tabulate :: Pos n => (forall m. (Nat m, m :<: n) => m -> a) -> FSVec n a


instance Pos n => Monad (FSVec n) where
     return = copy (toNum undefined)
     v >>= f = tabulate (\i -> f (v ! i) ! i)

Sadly uses of this monad are somewhat limited.

I have a half-dozen variations on the theme in my streams package and Jeremy Gibbons wrote a blog post on this monad.

Equivalently, you can view a FSVec n as a representable functor with its representation being natural numbers bounded by n, then use the definitions of bindRep and pureRep in my representable-functors package to get the definition automatically.

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Thanks. Alternatively, I imagine taking the nth element of each vector would break a monad law. I'll look for Jeremy's article. – user2023370 Apr 27 '11 at 13:16
Correct. The second monad law would break because m >>= return would not equal m – Edward KMETT Apr 27 '11 at 14:32
The idea of a representable functor (when translated into Haskell) is that the functor f is isomorphic to a function from some type x. We usually call that type x along with the isomorphism the representation of f. representable-functors witnesses this isomorphism with two functions: tabulate :: (x -> a) -> f a and index :: f a -> (x -> a). Any example is the Functor given by data Pair a = Pair a a which is representable by Bool. In this case tabulate f = Pair (f False) (f True); and index (Pair _ f) False = f; index (Pair t _) True = t. – Edward KMETT Apr 28 '11 at 15:07
Given tabulate and index as inverses you can say an awful lot about f. Since it is isomorphic to (->) x, you can borrow the instances for (->) x. Since (->) x is a right adjoint, it preserves limits, which means it is an instance of Distributive, but (->) x is also a Functor, Applicative, Monad, etc. This is why there are so many different fooRep methods that provide default definitions for various methods from other classes for any Representable. – Edward KMETT Apr 28 '11 at 15:10
tabulate and index together are more powerful (when available) than return and (>>=). As you can see from Gibbons' article the definition of the monad for fixed length or always-infinite vectors is a bit hairy, and if you look at the asymptotic performance of the two it is the same. But had Oleg chosen to use a fixed length array rather than a [a] behind the scenes, the tabulate version of (>>=) could be faster. An example of how to define something similar to this iteratively is in… – Edward KMETT Apr 28 '11 at 15:18

That seems impossible given that any monad has a join function. If the vector size is not exactly zero or one this would change the vector size. You can make it a Functor and Applicative, though.

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It is possible if somewhat strange. See my response. Jeremy Gibbons wrote a nice article on this monad at some point. – Edward KMETT Apr 27 '11 at 12:44

Sure you can do that. Just write

instance Monad (FSVec s) where
      -- your definition of return
      -- your definition of >>=
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