Basically all we need to do is to reimplement `sequence`

, but with `zipSinks`

instead of the original sequencing operation:

```
import Data.Conduit as C
import Data.Conduit.List as C
import Data.Conduit.Util as C
fromPairs
:: (Functor f)
=> f [a] -- ^ an empty list to start with
-> (f a -> f [a] -> f (a, [a])) -- ^ a combining function
-> [f a] -- ^ input list
-> f [a] -- ^ combined list
fromPairs empty comb = g
where
g [] = empty
g (x:xs) = uncurry (:) `fmap` (x `comb` g xs)
```

Now creating `broadcast`

is just applying `fromPairs`

to `zipSinks`

:

```
broadcast :: (Monad m) => [Sink a m b] -> Sink a m [b]
broadcast = fromPairs (return []) zipSinks
```

And we can do something like

```
main = C.sourceList [1..100] $$ broadcast [C.fold (+) 0, C.fold (*) 1]
```

**Update:** We can see that `fromPairs`

looks just `sequenceA`

and so we can push the idea even further. Let's define a zipping applicative functor on conduits similar to `ZipList`

:

```
import Control.Applicative
import Control.Monad
import Data.Conduit
import Data.Conduit.Util
import Data.Traversable (Traversable(..), sequenceA)
newtype ZipSink i m r = ZipSink { getZipSink :: Sink i m r }
instance Monad m => Functor (ZipSink i m) where
fmap f (ZipSink x) = ZipSink (liftM f x)
instance Monad m => Applicative (ZipSink i m) where
pure = ZipSink . return
(ZipSink f) <*> (ZipSink x) =
ZipSink $ liftM (uncurry ($)) $ zipSinks f x
```

Then `broadcast`

becomes as simple as

```
broadcast :: (Traversable f, Monad m) => f (Sink i m r) -> Sink i m (f r)
broadcast = getZipSink . sequenceA . fmap ZipSink
```