There is absolutely no need to calculate 3 x n^3 cosine values.

We can assume that x ≤ y ≤ z. Therefore x can be any integer in the range from 1 to n/3. y can be any integer in the range from x to (n - x) / 2. And z must be equal to n - x - y. This alone reduces the number of triples (x, y, z) that you try out from n^3 to about n^2 / 6.

Next assume that you found three numbers with a total of 2.749. And you try an x with cosine (x) = 0.748. Any total involving this x cannot be more than 2.748, so you can reject x outright. Once you found one good sum, you can reject many values of x.

To make this more effective, you sort the values x from highest to lowest value of cosine(x), because that makes it more likely you find a high total which allows you to remove more values.

And calculating cos(x) is slow, so you store the values into a table.

So:

```
Set c[i] = cos (i) for 1 ≤ i ≤ n.
Set x[i] = integers 1 to n/3, sorted in descending order by value of c[i].
Set (bestx, besty, bestz) = (1, 1, n-2) and total = c[bestx] + c [besty] + c [bestz].
for x = elements of array x where c[x] + 2 ≥ bestTotal
for y = x to (n-x)/2
z = n - x - y
total = c[x] + c[]y] + c[z]
if total > bestTotal
(bestx, besty, bestz) = (x, y, z)
bestTotal = total
```

You can improve on this with a bit of maths. If the sum of y + z is constant, like here where y + z = n - x, the sum of cos(y) + cos (z) is limited. Let P be the integer closest to (n - x) / 2pi, and let d = (n - x) - P * 2pi, then the largest possible sum of cos (y) + cos (z) is 2 * cos (d/2).

So for every x, 1 ≤ x ≤ n/3, we calculate this value d and cos (x) + 2 * cos (d/2), store these values as the maximum total that can be achieved with some x, sort x so that these values will be in descending order, and ignore those x where the achievable total is less than the best total so far.

If n is really large (say a billion), then you can use Euclid's algorithm to find all integers y that are close to 2k*pi + d quickly, but that will be a bit complicated.

```
for x in 1 to n/3
let s = n - x
let P = s / 2pi, rounded to the nearest integer
let d = (s - P * 2pi) / 2
let maxSum [x] = cos(x) + 2*cos(d)
Set x[i] = integers 1 to n/3, sorted in descending order by value of maxSum[i].
Set (bestx, besty, bestz) = (1, 1, n-2)
Set bestTotal = c[bestx] + c [besty] + c [bestz].
for x = elements of array x where maxSum[x] ≥ bestTotal
for y = x to (n-x)/2
z = n - x - y
total = c[x] + c[]y] + c[z]
if total > bestTotal
(bestx, besty, bestz) = (x, y, z)
bestTotal = total
```

PS. I actually tried this for some values of N around 100 million. It turns out, I can either sort the array to try the most promising values for x first, which takes a long time, but often the first value for x is the only one that gets tried. Or I can use x = 1, 2, 3 etc. which means a few dozens values for x will be tried, which is faster than sorting.

`x`

,`y`

and`z`

? – iGian Dec 1 '18 at 19:13uniqueintegers? – MSalters Dec 1 '18 at 23:03