Code Golf: Shortest code to find a weighted median?

My try at code golfing.

The problem of finding the minimum value of `∑W_i*|X-X_i|` reduces to finding the weighted median of a list of `x[i]` with weights `w[i]` (see below for definition). How will you do that with a shortest, simplest and most beautiful program?

Here's how my code looked originally (explanation is in the answer to the question and short version is posted as one of the answers below).

``````    #define zero(x) ( abs(x) < 1e-10 )  /* because == doesn't work for floats */

float sum = 0;
int i;

for (i = 0; i < n; i++)
sum += w[i];
while (sum > 0)
sum -= 2*w[--i];

right = x[i]             // the rightmost minimum point
left  = ( zero(sum) && zero(w[i]-w[i-1]) ) ? x[i-1] : right;
answer = (left + right) / 2;
``````

(Actually, it's been already heavily optimized as you see variables `i` and `sum` reused)

Rules

Floats and integers: different languages have different floating point arithmetic standards, so I reformulate the problem to have `x[i]` and `w[i]` to be integers and you can return twice the value of the answer (which is always integer) if you prefer. You can return, print or assign the answer to variable.

Definition of weighted median and clarifications:

• Median of sorted array `x[i]` of length `n` is either `x[n/2]` or `(x[n/2-1/2]+x[n/2+1/2])/2` depending on whether `n` is odd or even
• Median of unsorted array is the median of array after sort (true, but our array is sorted)
• Weighted median of `x[i]` with integer positive weights `w[i]` is defined as the median of larger array where each occurrence of `x[i]` has been changed into `w[i]` occurrences of `x[i]`.

What I hope to see

One of the reasons for asking is that I assume the most suitable language will have trivial array summation and iteration with lambdas. I thought a functional language could be reasonable, but I'm not sure about that - so it's part of the question. My hope is to see something like

``````    // standard function   add  :=  (a,b) :-> a + b
myreduce := w.reduce
until: (value) :-> 2*value >= (w.reduce with:add)
answer = x [myreduce  from:Begin] + x [myreduce  from:End]
``````

Dunno if there's any language where this is possible and is actually shorter.

Test data

``````static int n = 10;
for (int j = 0; j < n; j++) {
w[j] = j + 1;
x[j] = j;
}
``````

``````static int n = 9;
int w[n], x[n] ;
for (int j = 0; j < n; j++) {
w[j] = j + ((j<6) ? 1 : 0);
x[j] = j + 1;
}
``````

-
[functional-programming] Inigo Montoya says "You keep using that word. I do no think it means what you think it means." –  dmckee Jun 8 '09 at 20:44
... can you make your code a little more readable? –  CookieOfFortune Jun 8 '09 at 20:45
Code golf questions should be CW. –  Zifre Jun 8 '09 at 20:47
Clarified that x[i] is sorted. BTW, what is CW? –  ilya n. Jun 8 '09 at 20:58
You can still change it to community wiki (I think). –  Nosredna Jun 8 '09 at 21:11

J

Go ahead and type this directly into the interpreter. The prompt is three spaces, so the indented lines are user input.

``````   m=:-:@+/@(((2*+/\)I.+/)"1@(,:(\:i.@#))@[{"0 1(,:(\:i.@#))@])
``````

The test data I used in my other answer:

``````   1 1 1 1 m 1 2 3 4
2.5
1 1 2 1 m 1 2 3 4
3
1 2 2 5 m 1 2 3 4
3.5
1 2 2 6 m 1 2 3 4
4
``````

The test data added to the question:

``````   (>:,:[)i.10
1 2 3 4 5 6 7 8 9 10
0 1 2 3 4 5 6 7 8  9
(>:m[)i.10
6
(([+<&6),:>:)i.9
1 2 3 4 5 6 6 7 8
1 2 3 4 5 6 7 8 9
(([+<&6)m>:)i.9
6.5
``````

``````   i =: (2 * +/\) I. +/
``````

First index such that total sum is greater than or equal to double the accumulated sum.

``````   j =: ,: (\: i.@#)
``````

List and its reverse.

``````   k =: i"1 @ j @ [
``````

First indices such that -see above- of the left argument and its reverse.

``````   l =: k {"(0 1) j @ ]
``````

Those indices extracted from the right argument and its reverse, respectively.

``````   m =: -: @ +/ @ l
``````

Half the sum of the resulting list.

-
good one, i've still a lot to learn about J :P –  Andrea Ambu Jun 9 '09 at 8:00
Cool, very much what I wanted. There's something wrong with the Newton's method: the answer should always be half-integer. –  ilya n. Jun 9 '09 at 11:46
Hmm, it appears that comparisons are quite long. If there's a simple way to flop the array, it could be easier to find j in the same way as i but from the other side. Then (x[i]+x[j])/2 is always an answer (actually, x[i]+x[j] is a good answer since I modified the rules to stay within integers). Also, I give up on this one: why is the function with two arguments defined with 4 and 0? –  ilya n. Jun 9 '09 at 12:05
Never mind about m =:4 :0, I read how that's just a syntax for dyads. –  ilya n. Jun 9 '09 at 12:10
Still, could the third line be made shorter, like second? –  ilya n. Jun 9 '09 at 20:16

So, here's how I could squeeze my own solution:, still leaving some whitespaces:

``````    int s = 0, i = 0;
for (; i < n; s += w[i++]) ;
while ( (s -= 2*w[--i] ) > 0) ;
a  =  x[i]  +  x[ !s && (w[i]==w[i-1]) ? i-1 : i ];
``````
-

Haskell code, ungolfed: trying for a reasonable functional solution.

``````import Data.List (zip4)
import Data.Maybe (listToMaybe)

mid :: (Num a, Ord a) => [a] -> (Int, Bool)
mid w = (i, total == part && maybe False (l ==) r) where
(i, l, r, part):_ = dropWhile less . zip4 [0..] w v \$ map (2*) sums
_:sums = scanl (+) 0 w; total = last sums; less (_,_,_,x) = x < total
v = map Just w ++ repeat Nothing

wmedian :: (Num a, Ord a) => [a] -> [a] -> (a, Maybe a)
wmedian w x = (left, if rem then listToMaybe rest else Nothing) where
(i, rem) = mid w; left:rest = drop i x
``````
```> wmedian [1,1,1,1] [1,2,3,4]
(2,Just 3)
> wmedian [1,1,2,1] [1,2,3,4]
(3,Nothing)
> wmedian [1,2,2,5] [1,2,3,4]
(3,Just 4)
> wmedian [1,2,2,6] [1,2,3,4]
(4,Nothing)
```
```> wmedian [1..10] [0..9]
(6,Nothing)
> wmedian ([1..6]++[6..8]) [1..9]
(6,Just 7)
```

My original J solution was a straightforward translation of the above Haskell code.

Here's a Haskell translation of the current J code:

``````{-# LANGUAGE ParallelListComp #-}
import Data.List (find); import Data.Maybe (fromJust)
w&x=foldr((+).fst.fromJust.find((>=sum w).snd))0[f.g(+)0\$map
(2*)w|f<-[zip x.tail,reverse.zip x]|g<-[scanl,scanr]]/2
``````

Yeah… please don't write code like this.

```> [1,1,1,1]&[1,2,3,4]
2.5
> [1,1,2,1]&[1,2,3,4]
3
> [1,2,2,5]&[1,2,3,4]
3.5
> [1,2,2,6]&[1,2,3,4]
4
> [1..10]&[0..9]
6
> ([1..6]++[6..8])&[1..9]
6.5
```
-
Looks interesting, I'm parsing it... (I actually wrote I wanted to see some Haskell from the start, but was snubbed by functional languages crowd, so removed the idea...) –  ilya n. Jun 9 '09 at 0:43

short, and does what you'd expect. Not particularly space-efficient.

``````def f(l,i):
x,y=[],sum(i)
map(x.extend,([m]*n for m,n in zip(l,i)))
return (x[y/2]+x[(y-1)/2])/2.
``````

here's the constant-space version using itertools. it still has to iterate sum(i)/2 times so it won't beat the index-calculating algorithms.

``````from itertools import *
def f(l,i):
y=sum(i)-1
return sum(islice(
chain(*([m]*n for m,n in zip(l,i))),
y/2,
(y+1)/2+1
))/(y%2+1.)
``````
-
Yes, using sum(i) amount of space might be an overkill... maybe in the future python arrays will be smart enough to not allocate the space? –  ilya n. Jun 19 '09 at 19:27

Python:

``````a=sum([[X]*W for X,W in zip(x,w)],[]);l=len(a);a[l/2]+a[(l-1)/2]
``````
-

Something like this? O(n) running time.

``````for(int i = 0; i < x.length; i++)
{
sum += x[i] * w[i];
sums.push(sum);
}

median = sum/2;

for(int i = 0; i < array.length - 1; i++)
{
if(median > sums[element] and median < sums[element+1]
return x[i];
if(median == sums[element])
return (x[i] + x[i+1])/2
}
``````

Not sure how you can get two answers for the median, do you mean if sum/2 is exactly equal to a boundary?

EDIT: After looking at your formatted code, my code does essentially the same thing, did you want a MORE efficient method?

EDIT2: The search part can be done using a modified binary search, that would make it slightly faster.

``````index = sums.length /2;
finalIndex = binarySearch(index);

int binarySearch(i)
{
if(median > sums[i+1])
{
i += i/2
return binarySearch(i);
}
else if(median < sums[i])
{
i -= i/2
return binarySearch(i);
}
return i;
}
``````

Will have to do some checking to make sure it doesn't go on infinitely on edge cases.

-
In my understanding of the tradition of code golfing, I was thinking about the shortest program. That's why mine reuses variables suma nd i for two cycles :) –  ilya n. Jun 8 '09 at 21:03
Are you looking for shortest or fastest? –  CookieOfFortune Jun 8 '09 at 21:12
Shortest! Anyway, your code and mine appears to be identical as for performance, and in general it's not possible to compare performance in different languages beyond O(...) –  ilya n. Jun 8 '09 at 21:24
yeah, it's going to have to be O(n) because of the sum, let me rethink this about writing it shorter, though... not really a practical reason for doing that. –  CookieOfFortune Jun 8 '09 at 21:26
All of solutions, including yours, will be likely O(n). –  ilya n. Jun 8 '09 at 21:27
show 1 more comment

Just a comment about your code : I really hope I will not have to maintain it, unless you also wrote all the unit tests that are required here :-)

It is not related to your question of course, but usually, the "shortest way to code" is also the "hardest way to maintain". For scientific applications, it is probably not a show stopper. But for IT applications, it is.

I think it has to be said. All the best.

-
Sorry for misunderstanding. I wrote a long answer to somebody else's question (my answer is also linked now) and tried to write a very readable code. But now I'm thinking about code golfing, so I am also trying to produce a minimum version. –  ilya n. Jun 8 '09 at 20:55
@Sylvain: but it's code golf! –  Nosredna Jun 8 '09 at 20:56
@Sylvain - the point of code golf isn't to produce production-quality code. It's more like a brain-teaser - fun and challenging, but not to be used to real life projects. –  Erik Forbes Jun 8 '09 at 21:42
You are right, misplaced answer. Sorry Ilya... :o) –  SRO Jun 9 '09 at 12:36