# Monad instance of a number-parameterised vector?

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]
[1,1,3]
``````

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

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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.

Given

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

then

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

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 hackage.haskell.org/packages/archive/streams/0.6.1.1/doc/html/… – 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