# Euler's number expansion

``````#include <iostream>
#include <iomanip>
using namespace std;

int a[8], e[8];
void term (int n)
{
a[0]=1;
for (int i=0; i<8; i++)
{
if (i<7)
{
a[i+1]+=(a[i]%n)*100000;
}
/* else
{
a[i+1]+=((a[i]/640)%(n/640))*100000;
}
*/
a[i]=a[i]/(n);
}
}

void sum ()
{

}

int factorial(int x, int result = 1)
{
if (x == 1)
return result;
else return factorial(x - 1, x * result);
}

int main()
{
int n=1;
for (int i=1; i<=30; i++)
{
term(n);

cout << a[0] << " "<< a[1] << " " << a[2] <<  " "
<< a[3] <<  " " << a[4] << " " << a[5]<< " "
<< " " << a[6] << " " << a[7] << endl;
n++;
for (int j=1; j<8; j++)
a[j]=0;
}
return 0;
}
``````

That what I have above is the code that I have thus far. the Sum and the rest are left purposely uncompleted because that is still in the building phase.

Now, I need to make an expansion of euler' number, This is supposed to make you use series like x[n] in order to divide a result into multiple parts and use functions to calculate the results and such.

According to it, I need to find the specific part of the Maclaurin's Expansion and calculate it.

So the X in e=1+x+(1/2!)*x and so on is always 1 Giving us e=1+1+1/2!+1/3!+1/n! to calculate

The program should calculate it in order of the N

so If N is 1 it will calculate only the corresponding factorial division part; meaning that one part of the variable will hold the result of the calculation which will be x=1.00000000~ and the other will hold the actual sum up until now which is e=2.000000~

For N=2 x=1/2!, e=previous e+x

for N=3 x=1/3!, e=previous e+x

The maximum number of N is 29 each time the result is calculated, it needs to hold all the numbers after the dot into separate variables like `x[1] x[2] x[3]` until all the 30~35 digits of precision are filled with them. so when printing out, in the case of N=2

x[0].x[1]x[2]x[3]~ should come out as 0.50000000000000000000 where x[0] should hold the value above the dot and `x[1~3]` would be holding the rest in 5 digits each.

Well yeah Sorry if my explanation sucks but This is what its asking. All the arrays must be in Int and I cannot use others And I cant use bigint as it defeats the purpose

The other problem I have is, while doing the operations, it goes well till the 7th. Starting from the 8th and so on It wont continue without giving me negative numbers.

`for N=8` It should be 00002480158730158730158730. Instead I get 00002 48015 -19220 -41904 30331 53015 -19220

That is obviously due to int's limit and since at that part it does 1936000000%40320 in order to get `a[3]`'s value which then is 35200 which is then multiplied by 100000 giving us a 3520000000/40320, though the value of a[3] exceeds the limit of integer, any way to fix this? I cannot use doubles or Bigints for this so if anyone has a workaround for this, it would be appreciated.

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Is this homework? – RoundTower Jul 17 '11 at 12:24
technically yes – t3h_lolz Jul 17 '11 at 12:33
Then technically you should have marked this with the homework tag. I did that for you this time. – David Hammen Jul 17 '11 at 12:39
As a starter, you might want to call the function `factorial`. You define it but never use it. – David Hammen Jul 17 '11 at 12:45
Yeah, the later part of my post which says it exceeds the limit is when I start calling the factorial. – t3h_lolz Jul 17 '11 at 22:34

## 3 Answers

You cannot use floating point or bigint, but what about other compiler intrinsic integral types like long long, unsigned long long, etc.? To make it explicit you could use `<stdint.h>`'s int64_t and uint64_t (or `<cstdint>`'s std::int64_t and std::uint64_t, though this header is not officially standard yet but is supported on many compilers).

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I don't know if this is of any use, but you can find the code I wrote to calculate Euler's number here: http://41j.com/blog/2011/10/program-for-calculating-e/

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32bit int limits fact to 11!

• so you have to store all the above facts divided by some number
• 12!/10000
• 13!/10000
• when it does not fit anymore use 10000^2 and so on
• when using the division result is just shifted to next four decimals ... (as i assumed was firstly intended)
• of course you do not divide 1/n!
• on integers that will be zero instead divide 10000
• but that limits the n! to only 9999 so if you want more add zeroes everywhere and the result are decimals
• also i think there can be some overflow so you should also carry on to upper digits
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