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?

• – DJG
Commented Oct 1, 2013 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.

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. Commented Oct 1, 2013 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. Commented Oct 1, 2013 at 18:19
• AFAIK GHC will never 'make an optimization and process each sub list on a different core'. Parallelism is always explicit. Commented Oct 1, 2013 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. Commented Oct 2, 2013 at 1:28

I know it's a long time after the OP, but I've just happened upon this and thought my experiences might be of help.

If we think about the problem, we can see that:

• A fold is essentially a function that takes a list of items, and converts them to a single item which may be the same type as the items in the list, but doesn't have to be: so its type is `([a] -> b)`.

• A parallel fold splits its input list into chunks, folds each chunk separately (in parallel), and then combines the results to derive the final result. For that we need:

• A chunk size. This could be calculated with reference to the size of the input list, but that has a significant drawback: in order to determine the size of the list we have to process it, which loses the benefit of laziness. So it is better to make all chunks the same size; this could be hard-coded, but in a generic function it would be better to expose it as a parameter so that it can be varied and tuned to suit the needs of the calling application.

• A function that knows how to combine results. This has the type `(b -> b -> b)`.

A suitable generic parallel fold function is thus:

``````import Control.Parallel

foldParallel :: Int -> ([a] -> b) -> (b -> b -> b) -> [a] -> b
foldParallel _ fold _ [] = fold []
foldParallel chunkSize fold combine xs = par lf \$ combine lf rf
where
(left, right) = splitAt chunkSize xs
lf = fold left
rf = foldParallel chunkSize fold combine right
``````

The parallel processing is done explicitly, using the `par` function which kicks off the evaluation of its first operand, in parallel, and returns the second operand.

It took a while - for an ancient, imperative-programming dinosaur like me - to get my head around the fact that the definitions in the `where` block don't actually evaluate anything, but just set up things that can be evaluated; hence the fold named as `lf` can be referenced in both operands of `par` but is only evaluated once.

The difference that `par` makes is that if the function just returns `combine lf rf`, when that is evaluated `lf` needs to be evaluated, then `rf`, then `combine lf rf`. But `par lf \$ combine lf rf` means that `lf` is already wholly or partly evaluated (in parallel) by the time its value is needed. And because `rf` is itself a parallel fold, the same is true of the folding of each subsequent chunk.