I have a function with type below:

``````union :: a -> a -> a
``````

And `a` has additivity property. So we can regard `union` as a version of `(+)`

Say, we have `[a]`, and want to perform a parallel `"folding"`, for non-parallel foldling we can do only:

``````foldl1' union [a]
``````

But how to perform it in parallel? I can demonstrate problem on `Num` values and `(+)` function.

For example, we have a list `[1,2,3,4,5,6]` and `(+)` In parallel we should split

``````[1,2,3] (+) [4,5,6]
[1,2] (+) [3] (+) [4,5] (+) [6]
([1] (+) [2]) (+) ([3] (+) [4]) (+) ([5] (+) [6])
``````

then each `(+)` operation we want to perform in parallel, and combine to answer

``````[3] (+) [7] (+) [11] = 21
``````

Note, that we split list, or perform operations in any order, because of `a` additivity.

Is there any ways to do that using any standard library?

-
–  dg123 Oct 1 '13 at 13:53

You need to generalize your `union` to any associative binary operator ⊕ such that (a ⊕ b) ⊕ c == a ⊕ (b ⊕ c). If at the same time you even have a unit element that is neutral with respect to ⊕, you have a monoid.

The important aspect of associativity is that you can arbitrarily group chunks of consecutive elements in a list, and ⊕ them in any order, since a ⊕ (b ⊕ (c ⊕ d)) == (a ⊕ b) ⊕ (c ⊕ d) - each bracket can be computed in parallel; then you'd need to "reduce" the "sums" of all brackets, and you've got your map-reduce sorted.

In order for this parallellisation to make sense, you need the chunking operation to be faster than ⊕ - otherwise, doing ⊕ sequentially is better than chunking. One such case is when you have a random access "list" - say, an array. Data.Array.Repa has plenty of parallellized folding functions.

If you are thinking of practicising to implement one yourself, you need to pick a good complex function ⊕ such that the benefit will show.

For example:

``````import Control.Parallel
import Data.List

pfold :: (Num a, Enum a) => (a -> a -> a) -> [a] -> a
pfold _ [x] = x
pfold mappend xs  = (ys `par` zs) `pseq` (ys `mappend` zs) where
len = length xs
(ys', zs') = splitAt (len `div` 2) xs
ys = pfold mappend ys'
zs = pfold mappend zs'

main = print \$ pfold (+) [ foldl' (*) 1 [1..x] | x <- [1..5000] ]
-- need a more complicated computation than (+) of numbers
-- so we produce a list of products of many numbers
``````

Here I deliberately use a associative operation, which is called `mappend` only locally, to show it can work for a weaker notion than a monoid - only associativity matters for parallelism; since parallelism makes sense only for non-empty lists anyway, no need for `mempty`.

``````ghc -O2 -threaded a.hs
a +RTS -N1 -s
``````

Gives 8.78 seconds total run time, whereas

``````a +RTS -N2 -s
``````

Gives 5.89 seconds total run time on my dual core laptop. Obviously, no point trying more than -N2 on this machine.

-
This solution is cool, thank you –  Sergey Sosnin Oct 4 '13 at 20:12

What you've described is essentially a monoid. In GHCI:

``````Prelude> :m + Data.Monoid
Prelude Data.Monoid> :info Monoid
class Monoid a where
mempty :: a
mappend :: a -> a -> a
mconcat :: [a] -> a
``````

As you can see a monoid has three associated functions:

1. The `mempty` function is sort of like the identity function of the monoid. For example a `Num` can behave as a monoid apropos two operations: sum and product. For a sum `mempty` is defined as `0`. For a product `mempty` is defined as `1`.

``````mempty `mappend` a = a
a `mappend` mempty = a
``````
2. The `mappend` function is similar to your `union` function. For exampe for a sum of `Num`s `mappend` is defined as `(+)` and for a product of `Num`s `mappend` is defined as `(*)`.

3. The `mconcat` function is similar to a fold. However because of the properties of a monoid it doesn't matter whether we fold from the left, fold from the right or fold from an arbitrary position. This is because `mappend` is supposed to be associative:

``````(a `mappend` b) `mappend` c =  a `mappend` (b `mappend` c)
``````

Note however that Haskell doesn't enforce the monoid laws. Hence if you make a type an instance of the `Monoid` typeclass then you're responsible to ensure that it satisfies the monoid laws.

In your case it's difficult to understand how `union` behaves from its type signature: `a -> a -> a`. Surely you can't make a type variable an instance of a typeclass. That's not allowed. You need to be more specific. What does `union` actually do?

To give you an example of how to make a type an instance of the monoid typeclass:

``````newtype Sum a = Sum { getSum :: a }

instance Num a => Monoid (Sum a) where
mempty = 0
mappend = (+)
``````

That's it. We don't need to define the `mconcat` function because that has a default implementation that depends upon `mempty` and `mappend`. Hence when we define `mempty` and `mappend` we get `mconcat` for free.

Now you can use `Sum` as follows:

``````getSum . mconcat \$ map Sum [1..6]
``````

This is what's happening:

1. You're mapping the `Sum` constructor over `[1..6]` to produce `[Sum 1, Sum 2, Sum 3, Sum 4, Sum 5, Sum 6]`.
2. You give the resulting list to `mconcat` which folds it to `Sum 21`.
3. You use `getSum` to extract the `Num` from `Sum 21`.

Note however that the default implementation of `mconcat` is `foldr mappend mempty` (i.e. it's a right fold). For most cases the default implementation is sufficient. However in your case you might want to override the default implementation:

``````foldParallel :: Monoid a => [a] -> a
foldParallel []  = mempty
foldParallel [a] = a
foldParallel xs  = foldParallel left `mappend` foldParallel right
where size = length xs
index = (size + size `mod` 2) `div` 2
(left, right) = splitAt index xs
``````

Now we can create a new instance of `Monoid` as follows:

``````data Something a = Something { getSomething :: a }

instance Monoid (Something a) where
mempty  = unionEmpty
mappend = union
mconcat = foldParallel
``````

We use it as follows:

``````getSomething . mconcat \$ map Something [1..6]
``````

Note that I defined `mempty` as `unionEmpty`. I don't know what type of data the `union` function acts on. Hence I don't know what `mempty` should be defined as. Thus I'm simply calling it `unionEmpty`. Define it as you see fit.

-
I am not clear what is parallel about foldParallel. Using associativity law is only the enabler. You need to make sure splitting is faster than mappend, too. –  Sassa NF Oct 1 '13 at 15:49
Indeed. The additional overhead of splitting the list must be compensated by the time saved by executing the fold in parallel. Otherwise it won't make any sense to use `foldParallel` over a normal fold. There's nothing inherently parallel about the `foldParallel` function. However because it divides the list into two and processes each sub list recursively Haskell can make an optimization and process each sub list on a different core. Hence it enables parallelism. It doesn't guarantee it. –  Aadit M Shah Oct 1 '13 at 18:19
AFAIK GHC will never 'make an optimization and process each sub list on a different core'. Parallelism is always explicit. –  jtobin Oct 1 '13 at 20:25
Parallel Term / Graph reduction is, of course, possible, but how much of it happens in practice? If some Haskell compiler does this without a hint, that would be a great example to add to your answer. –  Sassa NF Oct 2 '13 at 1:28