# Java maths, working out total combinations [closed]

What's the easiest way I'd work out the total possible combinations of a method? Here is an example class of what I'm trying to work out;

``````class Combinations {

public void generate()
{
final int TOTAL_A = 10;
final int TOTAL_B = 21; // TOTAL_B is used twice
final int TOTAL_C = 17;
final int TOTAL_Z = 20;
int count = 0;
for (int a = 0; a < TOTAL_A; a++)
{
for (int b = 0; b < TOTAL_B; b++)
{
for (int b_two = 0; b_two < TOTAL_B; b_two++)
{
for (int c = 0; c < TOTAL_C; c++)
{
for (int one = 0; one < TOTAL_Z; one++)
for (int two = one + 1; two < TOTAL_Z; two++)
for (int three = two + 1; three < TOTAL_Z; three++)
for (int four = three + 1; four < TOTAL_Z; four++)
for (int five = four + 1; five < TOTAL_Z; five++)
count++;
}
}
}
}
System.out.println("Total combinations: " + count);
}

}
``````

What would be the way to figure out what "count" would be without having to actually do the loops?

-

## closed as not a real question by phant0m, jschoen, Guvante, Andy Hayden, Bhavik AmbaniDec 18 '12 at 0:43

It's difficult to tell what is being asked here. This question is ambiguous, vague, incomplete, overly broad, or rhetorical and cannot be reasonably answered in its current form. For help clarifying this question so that it can be reopened, visit the help center.If this question can be reworded to fit the rules in the help center, please edit the question.

Why don't you explain, in words, what it is exactly that you're trying to count? –  NPE Dec 17 '12 at 17:50
I'm trying to solve a puzzle combination which requires 4 unique objects from the first 4 loops, the second object has the same resource size as the third. After this I have to choose 5 other objects that are unique, as in, they can't have the same object. Which is where the + 1 from the last number comes in. –  ZBScripts Dec 17 '12 at 17:53
A better explanation, if possible? Anyway, you are doing 8 nested for loops, that's probably wrong. –  leonbloy Dec 17 '12 at 17:58
Think multiplication. –  Andrew Campbell Dec 17 '12 at 17:58
Are you asking how many distinct combination exist given the counts A, B1, B2, C and Z, where B1 and B2 are the same size? –  Perception Dec 17 '12 at 18:00

``````|A| * (|B| choose 2) * |C| * (|Z| choose 5) = 553,492,800
``````

Or if you want to choose from two different pools `B1` and `B2` that have the same size:

``````|A| * |B1| * |B2| * |C| * (|Z| choose 5) = 1,162,334,880
``````

where `n choose k` is defined as follows:

``````n!/(k!*(n-k)!)
``````
-
I appreciate your answer and have looked more in-depth into permutation combinations and have found the same array as shown. However, I haven't figured out a way to translate that type of algorithm into Java code, so I will keep this question open for now. Thank you. –  ZBScripts Dec 18 '12 at 2:31
Nevermind, found an Apache library which has a method for calculating this, thanks alot! –  ZBScripts Dec 18 '12 at 2:50

The outer loops, `a, b, b_two, c` do not influence what is done in the inner loops at all, so they just produce a factor of repetitions,

``````TOTAL_A * TOTAL_B² * TOTAL_C
``````

that you multiply with the work of the inner loops.

The inner loops, `one, two, three, four, five` influence or depend on other loops. Each loop determines the range of the enclosed loop, so you'd naturally work inside out.

``````for (int five = four + 1; five < TOTAL_Z; five++)
count++;
``````

So the innermost loops increments `count` a total of `TOTAL_Z - 1 - four` times. Let us denote `TOTAL_Z - 1` by `N` for brevity.

the `four` loop does

``````N - four
``````

increments for `four` ranging from `three+1` to `N`,

``````    N             N-three-1
∑ (N - four) =    ∑ k    = (N-three)*(N-three-1)/2
four=three+1         k=0
``````

The `three` loop does `(N-three)*(N-three-1)/2` increments for `three` ranging from `two+1` to `N`. Setting `j = N - three`, that gives

``````N-two-1
∑    j*(j-1)/2 = (N-two)*(N-two-1)*(N-two-2)/6
j=0
``````

The `two` loop does `(N-two)*(N-two-1)*(N-two-2)/6` increments for `two` ranging from `one+1` to `N`, setting `j = N - two`, that gives

``````N-one-1
∑   j*(j-1)*(j-2)/6 = (N-one)*(N-one-1)*(N-one-2)*(N-one-3)/24
j=0
``````

and finally, the `one` loop does the above amount of increments for `one` ranging from 0 to `N`, giving

``````   N                                            N
∑ (N-one)*(N-one-1)*(N-one-2)*(N-one-3)/24 = ∑ k*(k-1)*(k-2)*(k-3)/24
one=0                                          k=0
=  (N+1)*N*(N-1)*(N-2)*(N-3)/120
``````

(or `(N+1) `choose` 5`) increments in the inner loops together.

`N = TOTAL_Z - 1 = 19`, `20 `choose` 5 = 15504`, multiplying with the constants of the outer loops gives 1162334880 increments of `count` in total.

The crucial fact that allows a simple computation here is that

`````` m
∑   (n+k) `choose` k = (n+m+1) `choose` m
k=0
``````
-