I would like to optimize a part of my program where I'm calculating the sum of Binomial Coefficients up to K. i.e.

```
C(N,0) + C(N,1) + ... + C(N,K)
```

Since the values go beyond the data type (long long) can support, I'm to calculate values mod `M`

and was looking for procedures to do that.

Currently, I've done it with Pascal's Triangle but it seems to be taking a bit of load. so, I was wondering if there's any other efficient way to do this. I've considered Lucas' Theorem, although M I have is already large enough so that C(N,k) goes out of hand!

Any pointers as how can I do this differently, maybe calculate the whole sum altogether with some other neat expression of teh sum. If not I'll leave it with the Pascal's Triangle method itself.

Thank you,

Here is what I have so far `O(N^2)`

:

```
#define MAX 1000000007
long long NChooseK_Sum(int N, int K){
vector<long long> prevV, V;
prevV.push_back(1); prevV.push_back(1);
for(int i=2;i<=N;++i){
V.clear();
V.push_back(1);
for(int j=0;j<(i-1);++j){
long long val = prevV[j] + prevV[j+1];
if(val >= MAX)
val %= MAX;
V.push_back(val);
}
V.push_back(1);
prevV = V;
}
long long res=0;
for(int i=0;i<=K;++i){
res+=V[i];
if(res >= MAX)
res %= MAX;
}
return res;
}
```

N,KandM? Also, can you read SML-caml-F#? I have code in F# if that works for you at all. – kkm Feb 21 '12 at 0:44`K`

is much smaller than`N`

, you can gain quite a bit by stopping the inner loop at`K`

, also if`K`

is close to`N`

, by stopping at`N-K`

and using the fact that the sum of all binomial coefficients is`2^N`

. But if you really need it fast, part deux' suggestion (with the modular inverses) gets you the sum (modulo`MAX`

) in O(K*log(min(K,MAX))) steps. (Some care is needed if`K >= MAX`

.) – Daniel Fischer Feb 21 '12 at 1:21