# The following program finds the correct answer if summation is done via loop but incorrect if done via formula for GP. Why?

the following code is my solution to the problem : http://codeforces.com/contest/327/problem/C

The first part where I perform summation via loop (therefore having a bad time complexity) gives the correct answer.

The second part where I use formula of geometric progression returns incorrect answer for a lot of test cases even though I think the formula used is correct.

What am I doing wrong? (Edit:- Problem identified. Explained at the end)

``````#include<stdio.h>
#include<string>
#include<vector>
#include<iostream>
typedef long long int lli;

using namespace std;

lli power(lli base, lli exponent)
{
lli result=1;
while(exponent)
{
if(exponent & 1)
result=(result*base)%1000000007;
exponent>>=1;
base=(base*base)%1000000007;
}
return result%1000000007;
}
int main()
{
string n;
cin>>n;
lli k;
cin>>k;
vector<int> position;
for(int i=0;i<n.length();i++)
if(n[i]=='5' || n[i]=='0')
position.push_back(i);
lli m=0;
for(int i=0;i<position.size();i++)
m=(m+power(2,position[i]))%1000000007;
lli l=n.length();

// part1
// the following is finding summation via loop
for(int i=1;i<=k;i++)

//part2
// the following finds the sum by using gp formula (1st_term*(ratio^no_of_terms-1)/(ratio-1))
return 0;
}
``````

Couple of sample inputs and outputs

Input1:

4555000 3

Output1:

2080638 2080638

Input2:

4555000 8

Output2:

907276560 529323732

Edit:- I have figured out the problem. Modulo over division is not defined. The power function returns power modulo K where K=1000000007. Let us call this new value the reduced value. I am dividing two reduced values. Hence, the final answer is also less than the actual answer. Now that I've identified he problem, I still do not know how to overcome this.

Edit2:- Changing the second part to the following works (found it online). I have no idea why.

``````answer=(power(power(2,l),k) - 1);
``````
-

interesting; thanks for the question and posting the fix. fyi, here's the explanation of what you're doing:

you can probably see that you've replace division by x (ie multiplication by 1/x) with multiplication by x^(K-2). so the question is: why K-2?

and the answer is basically fermat's little theorem which says that when you're doing multiplication modulo a prime K (and 100000007 is a prime) then x^(K-1) = 1. if you divide both sides of that by x then you get x^(K-2) = 1/x.

and i hope you can see how that explains why your code works - on one side you have your K-2, on the other division by x. so raising to the power K-2 is equivalent, modulo K, to taking the reciprocal.

for example, consider working modulo 5 (which is prime) and dividing 9 by 3.

9/3 = 3 and 3%5 = 3 which is what we want, but division can be a problem:

(9%5)/3 = 4/3 = ? what does this mean modulo 5? (this was your bug)

so let's used the K-2 trick: 9*(3^(5-2)) = 9*(3^3) = 9*27 = 243 and 243%5 = 3

alternatively, (9%5) * (3^(5-2)) = 4*(3^3) = 4*27 = 108 and 108%5 = 3

-
Thanks for the detailed explanation. :) –  Nikhar Agrawal Jul 29 '13 at 5:23

In your `long long int` expressions you need to make sure that your literal constants are also `long long int` (currently you are using `int` for literal constants). So for example change:

``````    base=(base*base)%1000000007;
``````

to:

``````    base=(base*base)%1000000007LL;
``````

Better still, you should not litter your code with hard-coded constants, but instead just define a single constant and use that, e.g.

``````const long long int K = 1000000007LL;

....

base=(base*base)%K;
``````
-
Thanks for the info. :) However, the problem still remains. Here's the new version which still gives the same outputs:- ideone.com/SNQSCH –  Nikhar Agrawal Jul 28 '13 at 19:54
Also, had that been the problem, I believe it should have given wrong answer in both parts. –  Nikhar Agrawal Jul 28 '13 at 19:56
Have identified the problem. Made a corresponding edit. –  Nikhar Agrawal Jul 28 '13 at 20:44

Modulo operator % precedes *= operator

-
Thanks for the info. The problem remains though. Here's the updated version ideone.com/SNQSCH –  Nikhar Agrawal Jul 28 '13 at 19:55