There are two ways to do this without using concurrency, both with caveats.

The first way is that if `pipe1`

and `pipe2`

are just simple `Consumer`

s that loop forever like:

```
p1 = for cat f -- i.e. p1 = forever $ await >>= f
p2 = for cat g -- i.e. p2 = forever $ await >>= g
```

... then the easy way to solve this is to just write:

```
for P.stdinLn $ \str -> do
f str
g str
```

For example, if `p1`

is just `print`

ing every value:

```
p1 = for cat (lift . print)
```

... and `p2`

is just writing that value to a handle:

```
p2 = for cat (lift . hPutStrLn h)
```

... then you would combine them like so:

```
for P.stdinLn $ \str -> do
lift $ print str
lift $ hPutStrLn h str
```

However, this simplification only works for `Consumer`

s that trivially loop. There's another solution that is more general, which is to define an `ArrowChoice`

instance for pipes. I believe that pull-based `Pipe`

s do not permit a correct law-abiding instance, but push-based `Pipe`

s do:

```
newtype Edge m r a b = Edge { unEdge :: a -> Pipe a b m r }
instance (Monad m) => Category (Edge m r) where
id = Edge push
(Edge p2) . (Edge p1) = Edge (p1 >~> p2)
instance (Monad m) => Arrow (Edge m r) where
arr f = Edge (push />/ respond . f)
first (Edge p) = Edge $ \(b, d) ->
evalStateP d $ (up \>\ unsafeHoist lift . p />/ dn) b
where
up () = do
(b, d) <- request ()
lift $ put d
return b
dn c = do
d <- lift get
respond (c, d)
instance (Monad m) => ArrowChoice (Edge m r) where
left (Edge k) = Edge (bef >=> (up \>\ (k />/ dn)))
where
bef x = case x of
Left b -> return b
Right d -> do
_ <- respond (Right d)
x2 <- request ()
bef x2
up () = do
x <- request ()
bef x
dn c = respond (Left c)
```

This requires a newtype so that the type parameters are in the order that `ArrowChoice`

expects.

If you're unfamiliar with the term push-based `Pipe`

, it's basically a `Pipe`

that begins from the most upstream pipe instead of the most downstream pipe, and they all have the following shape:

```
a -> Pipe a b m r
```

Think of it as a `Pipe`

that cannot "go" until it receives at least one value from upstream.

These push-based `Pipe`

s are the "dual" to conventional pull-based `Pipe`

s, complete with their own composition operator and identity:

```
(>~>) :: (Monad m)
=> (a -> Pipe a b m r)
-> (b -> Pipe b c m r)
-> (a -> Pipe a c m r)
push :: (Monad m)
-> a -> Pipe a a m r
```

... but the unidirectional `Pipes`

API does not export this by default. You can only get these operators from `Pipes.Core`

(and you may want to study that module more closely to build an intuition for how they work). That module shows that both push-based `Pipe`

s and pull-based `Pipe`

s are both special cases of more general bidirectional versions, and understanding the bidirectional case is how you learn why they are duals of each other.

Once you have an `Arrow`

instance for push-based pipes, you can write something like:

```
p >>> bifurcate >>> (p1 +++ p2)
where
bifurcate = Edge $ pull ~> \a -> do
yield (Left a) -- First give `p1` the value
yield (Right a) -- Then give `p2` the value
```

Then you would use `runEdge`

to convert that to a pull-based pipe when you are done.

This approach has one major draw-back, which is that you can't automatically upgrade a pull-based pipe to a push-based pipe (but usually it's not hard to figure out how to do it manually). For example, to upgrade `Pipes.Prelude.map`

to be a push-based `Pipe`

, you would write:

```
mapPush :: (Monad m) => (a -> b) -> (a -> Pipe a b m r)
mapPush f a = do
yield (f a)
Pipes.Prelude.map f
```

Then that has the right type to be wrapped up in the `Arrow`

:

```
mapEdge :: (Monad m) => (a -> b) -> Edge m r a b
mapEdge f = Edge (mapPush f)
```

Of course, an even simpler way would be just to write it from scratch:

```
mapEdge f = Edge $ push ~> yield . f
```

Use whichever approach suits you best.

In fact, I came up with the `Arrow`

and `ArrowChoice`

instances precisely because I was trying to answer the exact same question as you: how do you solve these kinds of problems without using concurrency? I wrote up a long answer about this more general subject in another Stack Overflow answer here, where I describe how you can use these `Arrow`

and `ArrowChoice`

instances to distill concurrent systems into equivalent pure ones.