**Optimized way to handle the value of n^n (1 ≤ n ≤ 10^9)**

I used `long long int`

but it's not good enough as the value might be (1000^1000)

Searched and found the `GMP library`

http://gmplib.org/ and `BigInt class`

but don't wanna use them. **I am looking for some numerical method to handle this.**

**I need to print the first and last k (1 ≤ k ≤ 9) digits of n^n**

For the first *k* digits I am getting it like shown below (it's bit ugly way of doing it)

```
num = pow(n,n);
while(num){
arr[i++] = num%10;
num /= 10;
digit++;
}
while(digit > 0){
j=digit;
j--;
if(count<k){
printf("%lld",arr[j]);
count++;
}
digit--;
}
```

and for last *k* digits am using `num % 10^k`

like below.

```
findk=pow(10,k);
lastDigits = num % findk;
enter code here
```

**maximum value of k is 9. so i need only 18 digits at max.
I am think of getting those 18 digits without really solving the complete n^n expression.**

Any idea/suggestion??

`length`

entires in the array. After all, if that's all you need for your purposes, why write more? But the fact that you say OPTIMIZED implies you should not make a bigint library and just use a pre-existing one. :) – Patashu May 21 '13 at 5:06`printf()`

. Single values bigger than 64-bit will require some code to be handled. – Havenard May 21 '13 at 5:06`k`

is reasonably sized you could find the least significant`k`

digits using modular arithmetic without a special big integer library. – rliu May 21 '13 at 5:29