Given n dice, each of 'a' sides and a sum b, return the number of ways in which the sum b can be obtained. How can you reduce the time complexity and space complexity? This was asked in a Google interview and I am unsure of the answer.

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## closed as not a real question by Michael Petrotta, PengOne, Cody Gray, Hans Olsson, Shawn ChinDec 21 '11 at 17:28

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Are you allowed to Google the answer? –  Kerrek SB Dec 21 '11 at 3:41
Does "n dice, each of 'a' sides" mean that each die has values 1 through a? Or does it merely mean that each die has a values, and you have to examine a total of n × a values from a 2D array or something? –  ruakh Dec 21 '11 at 3:44
Hmm, no matter how I try to divide the problem, I can't get space complexity below O(n). –  Windows programmer Dec 21 '11 at 3:47
@ruakh: I think it means that you have `n` `a`-sided dice –  Jacob Dec 21 '11 at 3:51
@Jacob: Yeah, I got that part, thanks. ;-) –  ruakh Dec 21 '11 at 4:00

This is asking you to find the number of ways to write `b` as a sum of `n` positive integers. The answer is the number of compositions of `b` into `n` parts, which is `(b-1 choose n-1)`.

Now if we take into account the constraint that the size of the parts is limited to `a`, the problem gets a little more interesting. I recommend using generating functions for this. The answer will be the coefficient of `x^b` in the product `(x+x^2+...+x^a)^n`. Why? Because for each die (the singular of dice), you have a number between `1` and `a`, and this is represented by the exponent of `x`. When you take one `x^i` from each of the `n` terms, this is equivalent to the number `i` coming up on that die. The sum of the exponents must be the sum you are after, namely `b`.

We can even simplify the problem a bit using the multinomial theorem which states:

``````(x + x^2 + ... + x^a)^n = sum_{k1+k2+...+ka=n} (n multichoose k1,k2,...,ka) x^{k1+2*k2+...+a*ka}
``````

where all `ki >= 0`. So the answer is that the number of ways is

``````sum_{k1+k2+...+ka=n & k1+2*k2+...+a*ka=b} (n multichoose k1,k2,...,ka)
``````
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"which is (b-1 choose n-1)." is wrong,,its (b+n-1 choose n-1) –  FUD Dec 21 '11 at 5:21
@ChingPing No, the formula is correct as I've written it. The formula you give is if you take compositions into at most `n` parts. –  PengOne Dec 21 '11 at 5:22
agreed..you should have stated that :) –  FUD Dec 21 '11 at 5:24
@ChingPing I did: "...the number of compositions of b into n parts..." –  PengOne Dec 21 '11 at 5:25
"...the number of compositions of b into n 'non zero' parts... –  FUD Dec 21 '11 at 5:26

I would have an array `hits[max + 1]` which counts the number of possible combination for each value. `max` is `n * a` and of course `hits[0]` to `hits[n - 1]` will remain empty.

The dumb way would be to do `n` for-loop (one for each die) and register a hit in `hits` for the current sum of the dice.

The less dumb way is to use a bit of combinatorics, where I write out the number of combinations for each ordered shuffle:

there is 1 combination of 1111 (sum = 4)
there are 4 combination of 1112 (sum = 5)
there are 4 combination of 1113 (sum = 6)
...
there are 4 * 3 / 2 combinations of 1123 (sum = 7)
...
there are 4 * 3 * 2 combinations of 1234 (sum = 10)
...
there is 1 combination of `aaaa` (sum = `n * a`)

You need to spend much less times in the for-loops than the dumb solution.
You get many hits for each iteration instead of just one hit with the dumb method.

Those for-loops just move the (n - 1) partition separations over (1, 2, 3, 4, ..., `a`). The separations can be on the same spot (e.g. they are all between 1 and 2 for the case 1111), but you must not have a separation below 1 or above `a`.

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Assuming a is large enough( to be specific a>=b-n), this boils down to

``````x1+x2+x3+...+xn=b
``````

which is the typical problem of distributing 'b' candies amongst 'n' kids. if you want to avoid 0 faced dies it should be easy to see that

``````(y1+1)+(y2+1)...+(yn+1)=b
y1+y2+...+yn=b-n
``````

so a general solution to z1+z2+...zk=n is C(n+k-1,k-1)

Assuming we have limit on 'a' i.e. b-n>a, we can formulate it as a DP problem where

``````dp[k][j] is no. of ways to get a sum of j using dices 1 to k inclusive
dp[1][j] is 0 if j>a or j==0 else 1
``````

then we can have evaluate following relation

``````from k = 2 to n
from j = 1 to b
from x = 1 to a
dp[k][j] += dp[k-1][j-x] where x is from 1 to a at max and x<j
``````

and answer should be dp[n][b] The storage if of order n*b and runtime O(n*b*a)

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why did the interviewer ask for time and space complexity ? –  princess of persia Dec 21 '11 at 4:53
This isn't right because your solution doesn't take into account that dice have a maximum value. –  Ben Alpert Dec 21 '11 at 4:55
it should be x1+x2+....+xn = b cause there are n die and each die can maximum upto a on its face, how do you take care of that ? you conveniently ignored 'a' that is maximum each of n die can show up –  princess of persia Dec 21 '11 at 5:06