# Average value using fold

How would I calculate the average of a list of numbers using map and reduce.

Ideally I want to call reduce on a list and get an average back. You may optionally map and filter that list first.

A skeleton LISP attempt:

``````(defun average (list)
(reduce ... list))
``````

A skeleton JS attempt:

``````function average (array) {
return array.reduce(function() {
..
}, 0);
}
``````

If you post an answer with actual code in a language please explain it as if I'm a beginner in that langauge (which I probably will be).

I want to avoid the trivial answer of

``````function average (array) {
return sum(array) / array.length;
}
``````

This uses division at the end rather then a reduce statement. I consider this "cheating".

[]

Solved my own problem. If anyone has an elegant solution using syntactic sugar from LISP or Haskell I would be interested.

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Better suited for CodeGolf.SE perhaps? – ircmaxell May 12 '11 at 20:15
A simple `reduce` aka `fold` is not `mapreduce` (as in, the Google framework). Not even if you `map` the input beforehand. – delnan May 12 '11 at 20:18
@delnan sorry I got my terminology confused. – Raynos May 12 '11 at 20:19
The first step should be working out the maths behind the solution. Can you think about an iterative algorithm that gives you what you want? Turning that into a `fold` shouldn't be too hard. – abesto May 12 '11 at 20:23
@abesto the solution seems so simple now. I wasn't thinking thank you. – Raynos May 12 '11 at 20:32

## 5 Answers

Here's a version in common lisp:

``````(defun running-avg (r v)
(let* ((avg (car r))
(weight (cdr r))
(new-weight (1+ weight)))
(cons (/ (+ (* avg weight) v) new-weight) new-weight)))

(car (reduce 'running-avg '(3 6 5 7 9) :initial-value '(0 . 0)))
;; evaluates to 6
``````

It keeps track of a running average and weight, and calculates the new average as the `((previous average * weight) + new value)`.

-
could you explain `1+` and `weight`. I know nothing of LISP. Also `* (car r) (cdr r)` Is `r` a tuple? – Raynos May 12 '11 at 21:25
`1+` is a function that adds 1 to the argument. `weight` is just a local variable name. Yes, `r` is a tuple; I've cleaned it up a bit by creating some meaningful names. – ataylor May 12 '11 at 21:26
it's reasonably obvouis what `:initial-value` does but could you explain the semantics of that syntax? – Raynos May 12 '11 at 21:33
It's an optional keyword argument to `reduce`. Common Lisp functions can take named arguments, where the name is a lisp symbol. The leading colon is just the lisp syntax for symbols. With an initial value, the first call of the function is with `(initial-value, element0)` instead of `(element0, element1)`. – ataylor May 12 '11 at 21:36
Now that I understand the code I prefer the original version because it has that classic LISP terseness :) – Raynos May 12 '11 at 21:40

As @abesto mentioned it requires an iterative algorithm.

``````Let counter be 0
For each [value, index] in list
let sum be (counter * index) + value
let counter be sum / (index + 1)

return counter
``````

A javascript implementation would be

``````var average = function(list) {
// returns counter
return list.reduce(function(memo, val, key) {
// memo is counter
// memo * key + val is sum. sum / index is counter, counter is returned
return ((memo * key) + val) / (key + 1)
// let counter be 0
}, 0);
}
``````
-

calculate the average of a list of numbers using map and reduce

There's no `map` needed. Just a unfold to generate the list, and a fold to reduce it to a mean value:

``````mean n m = uncurry (/) . foldr g (0, 0) . unfoldr f \$ n
where
f b | b > m     = Nothing
| otherwise = Just (b, b+1)

g x (s,n) = (s+x, n+1)
``````

An efficient implementation

This structure (`fold . unfold`) allows for the fusion optimization to occur. A particularly efficient implementation will fuse the unfold (list generation) with the fold (the list reduction). Here, in Haskell, GHC combines the two phases (unfold == `enumFromN`) and the fold via stream fusion:

``````import Data.Vector.Unboxed

data Pair = Pair !Int !Double

mean :: Vector Double -> Double
mean xs = s / fromIntegral n
where
Pair n s       = foldl' k (Pair 0 0) xs
k (Pair n s) x = Pair (n+1) (s+x)

main = print (mean \$ enumFromN 1 (10^7))
``````

Which the compiler converts from a composition of two functions, into a recursive loop:

``````main_loop a d e n =
case ># a 0 of
False -> (# I# n, D# e #);
True -> main_loop (-# a 1) (+## d 1.0) (+## e d) (+# n 1)
``````

which reduces to this `goto` in assembly (the C backend to the compiler):

``````Main_mainzuzdszdwfoldlMzqzuloop_info:
leaq    32(%r12), %rax
cmpq    %rax, 144(%r13)
movq    %r12, %rdx
movq    %rax, %r12
jb      .L198
testq   %r14, %r14
jle     .L202
.L199:
movapd  %xmm5, %xmm0
leaq    -1(%r14), %r14
movsd   .LC0(%rip), %xmm5
addq    \$1, %rsi
addsd   %xmm0, %xmm6
movq    %rdx, %r12
addsd   %xmm0, %xmm5
jmp     Main_mainzuzdszdwfoldlMzqzuloop_info
``````

More efficient, but more confusing implementations result from LLVM (about 2x faster).

-

A description of an apporach in Haskell that allows a compositional approach to folds: http://conal.net/blog/posts/another-lovely-example-of-type-class-morphisms/

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That article would mean something if I went to the "Haskell for beginners course". – Raynos May 12 '11 at 21:26
The linked "beautiful folding" post is somewhat more accessible. – sclv May 12 '11 at 21:52

In Mathematica

``````mean[l_List]:=
Fold[{First@#1+1,(#2 +#1[[2]](First@#1-1))/First@#1}&,{1,1},l][[2]]

In[23]:= mean[{a,b,c}]
Out[23]= 1/3 (a+b+c)
``````
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That's completely unreadable to me :) – Raynos May 13 '11 at 7:41