Forgive me my lack of proper terminology - I don't know anything about -morphisms, etc., but I have the feeling that the concept I am trying to express could be described by some term of that sort.

Map, reduce, and filter, the classical higher-order functions, all have the general structure of taking a function `f`

and a list of data `xs`

and doing something with that `f`

to all the `xs`

. Now, for each of them, I can imagine a 'functionised' version - call them mapf, reducef, and filterf - that instead takes a piece of data `x`

and a list of functions `fs`

and does each of the functions `fs`

to the data `x`

. Specifically, mapf would give you back a list of `f1(x), f2(x), ...`

, reducef would give you `f3 (f2 (f1 (x)))`

or `f1 (f2 (f3 (x)))`

(depending on whether it was left or right), and filterf would test whether each of `f1(x), f2(x), ...`

was true and return only the `fs`

that were.

My question is this: is it possible to write a general function, `functionise`

, that takes map, reduce, or filter as its argument and produces the corresponding mapf, reducef, or filterf function? (In an elegant way of course, not just as a series of case expressions.)

I don't mind what programming language is used; in my own experimentation I have been using Haskell, and what led me to this question was that I noticed that all three of the functions can be defined in a *very* similar way:

```
rev = \x y -> y x
mapf :: a -> [a -> b] -> [b]
mapf x fs = map (rev x) fs
reducef :: a -> [a -> a] -> a
reducef x fs = foldl rev x fs
filterf :: a -> [a -> Bool] -> [a -> Bool]
filterf x fs = filter (rev x) fs
```

I am tantalised by the similarity of them, so I'd like to either find out that it is possible, and to see how, or to be shown that it isn't possible, and see why. As I said, the programming language isn't crucial, so I don't mind if it's possible in language A but not in language B because of language B's type system - that'd be interesting.

Thank you!