# Algorithm to get all combinations of (American) football point-accumulations necessary to get a certain score N

It was one of my interview question, and I could not think of the good way to get number N. (plus, I did not understand the American football scoring system as well)

``````6 points for the touchdown
1 point for the extra point (kicked)
2 points for a safety or a conversion (extra try after a touchdown)
3 points for a field goal
``````

What would be an efficient algorithm to get all combinations of point-accumulations necessary to get a certain score N?

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are you trying to print these combinations or get the number of them? –  amit Feb 9 '12 at 7:38
The answers below are good, but ignore the fact that the 1-point play can only come following a touchdown. As such, you'll need to tweak the answers to account for that. –  dlev Feb 9 '12 at 8:02
@dlev - well, not all of us are american... our football has but one point goals. –  WeaselFox Feb 9 '12 at 8:18
@dlev: To adjust for special rules such as "1 may only follow a 6", you can simply change the 1 to a 7 so that it includes the 6 that must come before it. –  tom Feb 9 '12 at 9:34
Should a touch down followed by a field goal be counted differently from a field goal followed by a touch down? Also, must a safety or a conversion follow a touch down immediately? These will drastically change the solution.. –  aelguindy Feb 9 '12 at 10:17

Assuming here you are looking for a way to get number of possibilities and not the actual possibilities.

First let's find a recursive function:

`f(n) = (f(n-6) >= 0? f(n-6) : 0) + (f(n-1) >= 0 ? f(n-1) : 0) + (f(n-2) >= 0 ? f(n-2) : 0) + (f(n-3) >= 0 ? f(n-3) : 0)`

base: `f(0) = 1` and `f(n) = -infinity [n<0]`

The idea behind it is: You can always get to `0`, by a no scoring game. If you can get to `f(n-6)`, you can also get to `f(n)`, and so on for each possibility.

Using the above formula one can easily create a recursive solution.

Note that you can even use dynamic programming with it, initialize a table with [-5,n], init `f[0] = 0` and `f[-1] = f[-2] = f[-3] = f[-4] = f[-5] = -infinity` and iterate over indexes `[1,n]` to achieve the number of possibilities based on the the recursive formula above.

EDIT:
I just realized that a simplified version of the above formula could be:
`f(n) = f(n-6) + f(n-1) + f(n-2) + f(n-3)`
and base will be: `f(0) = 1`, `f(n) = 0 [n<0]`
The two formulas will yield exactly the same result.

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This is identical to the coin change problem, apart from the specific numbers used. See this question for a variety of answers.

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You could use dynamic programming loop from 1 to n, here is some pseudo code:

``````results[1] = 1
for i from 1 to n :
results[i+1]   += results[i]
results[i+2]   += results[i]
results[i+3]   += results[i]
results[i+6]   += results[i]
``````

this way complexity is O(N), instead of exponential complexity if you compute recursively by subtracting from the final score... like computing a Fibonacci series.

I hope my explanation is understandable enough..

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Top-down DP (normal recursion) can be turned to O(n) with caching, so that's not an issue. The advantage of your bottom-up DP is that a sliding window can be used to make the space complexity O(m), where m is the maximum of the goal points (in this case 6). –  tom Feb 9 '12 at 9:25