After reading this article on Clojure (http://blog.podsnap.com/ducers2.html) introducing transducers, I'm confused on what a transducer is. Is a partially applied `map`

in Haskell, such as `map (+1)`

a transducer? At first I thought this was a Clojure way of using partial application, but then the article goes on to implement it in Haskell with an explicit type. What use does it have in Haskell?

In Clojure `(map inc)`

is a transducer, but not in Haskell, because Haskell has to obey currying but an untyped Lisp can break that curry-by-default convention. The type of transducers is instead:

```
type Transducer a b = forall r . (b -> r -> r) -> (a -> r -> r)
```

We say that the transducer 'turns `a`

into `b`

'. Yes, the `a`

and the `b`

seem "backwards" on the right hand side. The `forall`

means that a Transducer must leave `r`

as a general type variable but is totally allowed to specialize on `a`

and `b`

.

Let me reverse two of the arguments in foldr:

```
-- cf. with foldr :: (x -> r -> r) -> r -> [x] -> r
ffoldr :: (x -> r -> r) -> [x] -> r -> r
ffoldr = flip . foldr
```

(we can also use `foldl`

but it will tend to reverse things later). This means that a `Transducer`

can be used to transform the first argument of `ffoldr`

from `x`

to `y`

, so that we can instead process an `[x]`

with a `y -> r -> r`

using `foldr`

. Transducers 'sit between' the inputs `([x], r)`

and the final processor `(y, r) -> r`

.

I've flipped the second two arguments to emphasize also that, surprisingly, `ffoldr :: Transducer [x] x`

. By using the symmetry of the arguments we also have a generic composition of transducers, which happens to be just function composition:

```
(.) :: Transducer a b -> Transducer b c -> Transducer a c
```

(If you think it's cool that giving these `forall r`

terms lets us reverse how you normally use `.`

, you can do it arbitrarily via a technique called "continuation passing".)

For example, here is the filter transducer:

```
tfilter :: (a -> Bool) -> (a -> r -> r) -> a -> r -> r
-- or: (a -> Bool) -> Transducer a a
tfilter predicate f a = if predicate a then f a else id
```

This applies the reduction function `f`

to `a`

and `r`

only if the predicate holds. There is also a mapping transducer:

```
tmap :: (a -> b) -> (b -> r -> r) -> a -> r -> r
tmap ba f a = f (ba a)
```

This gives composable map/filter semantics for any 'transducable' type: one map/filter fn can work for multiple contexts.

The Transducer type has a cute isomorphism: it turns out that the `foldr`

of a list `forall r. (x -> r -> r) -> r -> r`

is perfectly equivalent to that list `[x]`

(it is the "Church encoding" of that list), and therefore swapping the argument `a`

to the very front of the transducer definition gives us the (IMO much easier to understand!) type `type TransL a b = a -> [b]`

. And this is much easier to understand:

```
tl_map f = \a -> [f a]
tl_filter predicate = \a -> if predicate a then [a] else []
```

To run these on a list, use `concatMap`

... which happens to be just `>>=`

! So you just write `collection >>= transducer`

and you have the transduced collection. The meaning of `TransL a b`

is then, "take each element of the original list of `a`

, and give me 0 or more elements of type `b`

to splice into my outgoing list." It filters by splicing 0 elements when the predicate doesn't work; it maps by yielding 1 output element for each input element; another operation `tl_dupe = \a -> [a, a]`

is a transducer which duplicates the elements in a list, `[1,2,3] >>= tl_dupe`

becomes `[1,1,2,2,3,3]`

.

Where `foldr`

appears to be a `Transducer [x] x`

it is now seen to be identical to `id :: TransL [x] x`

which has a way of simply performing a `concat`

operation in the middle of a computation; the identity function in this algebra is actually `return = \a -> [a]`

, also written `(:[])`

. The **only** loss is that we can no longer use `.`

to compose these, but in fact the same composition is provided in `Control.Monad`

as the Kleisli composition operator `>=>`

.

So long story short, transducers are functions `a -> [b]`

cleverly transformed with a bit of Church encoding so that the Kleisli composition operator for these Kleisli arrows of the list monad, becomes simply `(.)`

.

`map (+1)`

is a transducer, but not in Haskell, because an untyped Lisp can break those sorts of conventions. A transducer is a function`(r -> a -> r) -> r -> b -> r`

which leaves`r`

as a type variable but may specialize on`a`

and`b`

. For example,`tfilter pred f r b = if pred b then f r b else r`

is a transducer filter (when partially applied to`pred`

) as it applies the reducer`f`

only if the element matches the predicate. This gives composable map/filter semantics for any 'transducable' function: one map/filter fn can work for multiple contexts. – CR Drost Oct 30 '14 at 15:55