Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

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?

share|improve this question
1  
are you trying to print these combinations or get the number of them? –  amit Feb 9 '12 at 7:38
1  
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
1  
@dlev - well, not all of us are american... our football has but one point goals. –  WeaselFox Feb 9 '12 at 8:18
1  
@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
1  
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

3 Answers 3

up vote 3 down vote accepted

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.

share|improve this answer

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

share|improve this answer

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..

share|improve this answer
    
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

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.