My aim is to have a parallel foldr function. At first, it seemed rather straight forward to achieve and this is what I had in mind:

First break up the input list into partitions based on the number of
cores (`numCapabilities`

). Then apply foldr to each partition, which
will result in a list of folded values for each partition. Then do a
foldr again on that list to obtain the final value.

```
listChunkSize = numCapabilities
chunk n [] = []
chunk n xs = ys : chunk n zs
where (ys,zs) = splitAt n xs
parfoldr f z [] = z
parfoldr f z xs = res
where
parts = chunk listChunkSize xs
partsRs = map (foldr f z) parts `using` parList rdeepseq
res = foldr f z partsRs
```

The above code does not work because obviously the definition of
foldr, `(a -> b -> b) -> b -> [a] -> b`

, implies that the input list
type is (well, can be) different from the accumulator and result type.

For example,

1) `foldr (+) 0 [1..10]`

=> list type = accumulator type (Integer)

2) `foldr (\i acc -> (i>5) && acc) True [1..10]`

=> list type (Integer) !
= accumulator type (Bool)

So, looking at my code above, the map will generate a list of type `b`

which is then passed as argument to the second foldr. But the second
foldr accepts list of type `a`

. So, that won't work.

An ugly solution would be to provide a different type signature for
the parfoldr, e.g.
`parfoldr :: (NFData a) => (a -> a -> a) -> a -> [a] -> a`

This will work but then it is not exactly equivalent to foldr. Example 1 above will do just fine, but not example 2. So, question 1 is: how to define parfoldr to have same type signature as foldr?

Comparing the 2 folds:

```
input = [1..1000000]
seqfold = foldr (+) 0
parfold = parfoldr (+) 0
```

I get the foll. times on a dual core machine: (no -threaded flag)

```
$ ./test
seqfold: 4.99s
parfold: 25.16s
```

(-threaded flag on)

```
$ ./test
seqfold: 5.32s
parfold: 25.55s
$ ./test +RTS -N1
seqfold: 5.32s
parfold: 25.53s
$ ./test +RTS -N2
seqfold: 3.48s
parfold: 3.68s
$ ./test +RTS -N3
seqfold: 3.57s
parfold: 2.36s
$ ./test +RTS -N4
seqfold: 3.03s
parfold: 1.70s
```

Observations from these measurements:

foldr seems to give lower runtime when num of cores is increased. why is that?

parfold gives better runtimes for N => 3.

Any suggestions and ideas for improvement is appreciated :)