# Implements neper number (e) with a recursion function

I want to calculate Neper number(e) with a recursion function. I have the formula to calculate it:

e = (1/0!) + (1/1!) + (1/2!) + (1/3!) +. . .

I have the code but it won't work properly:

#include <iostream>
using namespace std;

double f(double res,int i, int n){

return (i == n) ? res: res = res + (1 /f(res,i+1,n)*i);
}

int main(){
cout << f(1,1,2) << endl;
}


The result of this code is 2.5 but it should be 2. Where is the problem?

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What "doesn't work properly" about it? – BoBTFish Feb 19 '14 at 9:13
The result of this code is't the neper number!!!! – DanialV Feb 19 '14 at 9:14
Soo... what does it print? Have you tried printing each step in f? (Hint: I'm trying to lead you into debugging it yourself, and telling us where you are stuck). – BoBTFish Feb 19 '14 at 9:15
the point is you are mixing 2 different things, and trying to calculate e as if it were a continuous funcion, which is not. you need something like return (i == n) ? res: res + (1 /factorial(i)); where factorial(int i) is an appropriate function calculating i! – dirluca Feb 19 '14 at 9:33
Just add 1/i! as a parameter to f and it can easily compute 1/(i+1)!. Make sure you use a double to store it, because an integer will overflow too quickly. – Klas Lindbäck Feb 19 '14 at 9:39

Still not sure what you want res for. In fact, if I got creative with the sign of n this doesn't need i either.

double f(int i, int n)
{
return (i == 0) ? ((n <= 1) ? 1 : n * f(0,n-1))
: ((n < 1) ? 1 : 1/f(0, n) + f(i,n-1));
}

int main()
{
for (int n=1; n<16; ++n)
std::cout << std::setprecision(16) << f(1,n) << std::endl;
return 0;
}


Output

2
2.5
2.666666666666667
2.708333333333333
2.716666666666666
2.718055555555555
2.718253968253968
2.71827876984127
2.718281525573192
2.718281801146385
2.718281826198493
2.718281828286169
2.718281828446759
2.71828182845823
2.718281828458995


This was what I meant about toying with the sign for n to eliminate i as well:

double f(int n)
{
return (n < 0) ? ((n == -1) ? 1 : -n * f(n+1))
: ((n < 1) ? 1 : 1/f(-n) + f(n-1));
}


The results are the same. In both cases the function is defined to dual-purpose it recursive algorithm. When asked to, it computes 1/n!, otherwise it computes the running sum + the next number down (which is 1/(n-1)!, etc...)

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This is an answer, thanks to WhozCraig. @DanialV: from a coding point of view having a function doing two very different things (Neper number and factorial) depending on the value of one of the parameters is bad, bad, bad. I do not know why you do not want two different functions, could be a perfectly sensible reason I can't think of, but watch out what you are doing – dirluca Feb 19 '14 at 10:24
@dirluca I utterly concur. I can't think of a good reason to do single-function either (save for saying "because I can"), but the OP was pretty set on it for some reason. dual-purposing was the first thing that came to mind, but IRL no way would I do it this way. The latter snippet is especially dreadful, don't you think =) ? – WhozCraig Feb 19 '14 at 10:27
As I said I perfectly like the witty answer, it's the question that puzzles me a bit :-) – dirluca Feb 19 '14 at 11:17
WhozCraig Thanks.Your answer was perfect and @dirluca the reason I said I wanted to calculate it just with one function is that why we should use two function when we can do it perfectly with one function!!! – DanialV Feb 19 '14 at 14:00
As you like @DanialV, but pushing it as far as paradox you could say then that main() is enough for everything and all this OOP is just fuss. Having different functions for different uses makes code readable and maintainable. But I stop it here, this is Q&A site and not theoretical debate site. – dirluca Feb 19 '14 at 15:37

I think you are referring to Napier, the inventor of the logarithm.

To compute 1/0!+1/1!+1/2!+...+1/n! recursively and efficiently, you can refactor it as 2+1/2*(1+1/3*(1+...1/n))) to obtain the recursive definition

h(k,n)=(k==n)?1.0/n:(1.0+h(k+1,n)/k)
f(n)=1+h(2,n)


You will get faster convergence by using the properties of the exponential function, for instance that e=exp(1/8)^8, also known as the strategy of halving-and-squaring.

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