# Probability: No of ways to win if you have n dice with m faces each

You are given a number of dices n, each with a number of faces m. You roll all the n dices and note the sum of all the throws you get from rolling each dice. If you get a sum >= x, you win, otherwise you lose. Find the probability that you win.

I thought of generating all combinations of 1 to m ( of size n ) and keeping count of only those whose sum is more then x . Total no of ways are m^n

After that its just the divison of both.

Is there a better way ?

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[EDIT: As noted by jpalacek, the time complexity was wrong -- I've now fixed this.]

You can solve this more efficiently with dynamic programming, by first changing it into the question:

How many ways can I get at least x from n dice?

Express this as f(x, n). Then it must be that

f(x, n) = sum(f(x - i, n - 1)) for all 1 <= i <= m.

I.e. if the first die has 1, the remaining n - 1 dice must add up to at least x - 1; if the first die has 2, the remaining n - 1 dice must add up to at least x - 2; and so on.

There are m terms in the sum, so if you memoise this function, it will be O(m^2*n^2), since it will be required to do this summing work at most (m * n) * n times (i.e. once per unique set of inputs to the function, assuming that the first parameter x <= m * n).

As a final step to get a probability, just divide the result of f(x, n) by the total number of possible outcomes, i.e. m^n.

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Your analysis is slightly flawed: To calculate `f(x,n)`, you need to calculate more than `m*n` function values (rather something like `x*n`, but surely less than that). So in the end it will result in something like `O(x*n*m)` –  jpalecek Jan 6 '13 at 13:57
@jpalecek: Good catch, thanks. Assuming x <= n*m (since otherwise the answer is trivially 0), a bound of O(m^2 * n^2) should be OK -- I'll update the answer. –  j_random_hacker Jan 6 '13 at 14:00

Just to add up on @j_random_hacker's basically correct answer, you can make it even faster when you note that

f(x, n) = f(x-1, n) - f(x-m-1, n-1) + f(x-1, n-1) if x>m+1

This way, you'll only spend `O(1)` time calculating each of the `f` value.

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Very nice, +1! Had to stare at it for a while before it clicked: all the terms in the sum I gave are shared with the calculation for the previous value of x except for the first and last, so just subtract and add them respectively. –  j_random_hacker Jan 6 '13 at 14:19

//Passing curFace value will disallow duplicate combinations
//For 3 dices - and sum 8 - 2 4 2 and 2 2 4 are the same combination - so should be counted as one

``````int sums(int totSum,int noDices,int mFaces,int curFace,HashMap<String,Integer> map)
{

int count=0;

if (noDices<=0 || totSum<=0)
return 0;

if (noDices==1)
{
if (totSum>=1 & totSum<=mFaces)
return 1;
else
return 0;
}
if (map.containsKey(noDices+"-"+totSum))
return map.get(noDices+"-"+totSum);

for (int i=curFace;i<=mFaces;i++)
{

count+=sums(totSum-i,noDices-1,mFaces,i,map);
}

map.put(noDices+"-" +totSum,count);

return count;
}
``````
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