Your current solution is `O(NK^2)`

(assuming `K > log N`

). With some analysis, I believe you can reduce this to `O(NK)`

.

The closest set of size K will consist of elements that are adjacent in the sorted list. You essentially have to first sort the array, so the subsequent analysis will assume that each sequence of `K`

numbers is sorted, which allows the double sum to be simplified.

Assuming that the array is sorted such that `x[j] >= x[i]`

when `j > i`

, we can rewrite your closeness metric to eliminate the absolute value:

Next we rewrite your notation into a double summation with simple bounds:

Notice that we can rewrite the inner distance between `x[i]`

and `x[j]`

as a third summation:

where I've used `d[l]`

to simplify the notation going forward:

Notice that `d[l]`

is the distance between each adjacent element in the list. Look at the structure of the inner two summations for a fixed `i`

:

```
j=i+1 d[i]
j=i+2 d[i] + d[i+1]
j=i+3 d[i] + d[i+1] + d[i+2]
...
j=K=i+(K-i) d[i] + d[i+1] + d[i+2] + ... + d[K-1]
```

Notice the triangular structure of the inner two summations. This allows us to rewrite the inner two summations as a single summation in terms of the distances of adjacent terms:

```
total: (K-i)*d[i] + (K-i-1)*d[i+1] + ... + 2*d[K-2] + 1*d[K-1]
```

which reduces the total sum to:

Now we can look at the structure of this double summation:

```
i=1 (K-1)*d[1] + (K-2)*d[2] + (K-3)*d[3] + ... + 2*d[K-2] + d[K-1]
i=2 (K-2)*d[2] + (K-3)*d[3] + ... + 2*d[K-2] + d[K-1]
i=3 (K-3)*d[3] + ... + 2*d[K-2] + d[K-1]
...
i=K-2 2*d[K-2] + d[K-1]
i=K-1 d[K-1]
```

Again, notice the triangular pattern. The total sum then becomes:

```
1*(K-1)*d[1] + 2*(K-2)*d[2] + 3*(K-3)*d[3] + ... + (K-2)*2*d[K-2]
+ (K-1)*1*d[K-1]
```

Or, written as a single summation:

This compact single summation of adjacent differences is the basis for a more efficient algorithm:

- Sort the array, order
`O(N log N)`

- Compute the differences of each adjacent element, order
`O(N)`

- Iterate over each
`N-K`

sequence of differences and calculate the above sum, order `O(NK)`

Note that the second and third step could be combined, although with Python your mileage may vary.

The code:

```
def closeness(diff,K):
acc = 0.0
for (i,v) in enumerate(diff):
acc += (i+1)*(K-(i+1))*v
return acc
def closest(a,K):
a.sort()
N = len(a)
diff = [ a[i+1] - a[i] for i in xrange(N-1) ]
min_ind = 0
min_val = closeness(diff[0:K-1],K)
for ind in xrange(1,N-K+1):
cl = closeness(diff[ind:ind+K-1],K)
if cl < min_val:
min_ind = ind
min_val = cl
return a[min_ind:min_ind+K]
```

`a.sort()`

is explicit enough for me. – Waleed Khan Oct 20 '13 at 20:17