# Calculating Pi using for loop

I have just made a program which calculates pi. However, even with 10 million iterations my result is kinda off. I get 3.1415927535897831, whereas already early on is it wrong. It is supposed to be 3.141592653589793238...

So my question is: What is the required amount of iterations to get at least an accurate answer all the way up to 10^-16

Here is my code if anyone is interested:

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

int main()
{
long double pi = 4.0;
long double tempPi;
for (int i = 1, j = 3; i <= 10000000; i++, j+=2)
{
tempPi = static_cast<double>(4)/j;
if (i%2 != 0)
{
pi -= tempPi;
}
else if (i%2 == 0)
{
pi += tempPi;
}
}
cout << "Pi has the value of: " << setprecision(16) << fixed << pi << endl;
system("pause");
return 0;
``````

}

Any performance related tips would also be appreciated.

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How accurate is the algorithm? By that I mean in the strictest mathematical sense. –  Jörgen Sigvardsson Jul 8 '11 at 15:50
It is one of many methods to calculate pi. The algorithm is sound, although I suspect it is not the most efficient mean of calculating pi. The equation it derives from is pi = 4 - 4/3 + 4/5 - 4/7 + 4/9... into infinity. I suppose that is why my method did not work since its original intentions were to calculate forever... :) –  E.O. Jul 8 '11 at 15:57
Nitpick: When talking large numbers, prefer C scientific notation: `1.0E-15` than `10^-16`. The `^` symbol can have various meaning such as exclusive-OR or exponentiation. –  Thomas Matthews Jul 8 '11 at 17:28

You are using the Leibniz series, which is very, very slow to converge. In an alternating series such as the one you are using, the first omitted term provides a good estimate of the error in the estimate. Your first omitted term is 4/2000005, so you should expect less than six significant digits of precision here.

Note well: Rounding errors, use of double precision numbers has nothing to do with the lack of precision here. The sole factor is that you are using a crappy algorithm.

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Hehe... Agreed. This algorithm was provided by a book I am reading, and it asked me to make a code which iterated 1000 times. I thought that was kinda inaccurate so I tried 10 million times. That too was inaccurate, so now I am trying 10 billion times. This however seems like to much for my pc since it has been calculating for some time now... I should probably switch algorithm. –  E.O. Jul 8 '11 at 16:06

There are lots of methods for calculating pi. Some converge faster than others.

Also see "Modern Formulae"

``````the sequence 1 / a converges quartically to pi, giving about 100 digits in three steps and over a trillion digits after 20 steps.
``````
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can you add some really simple and nice code ? –  zinking Nov 1 '13 at 5:23

The problem is that `double` is not nearly as accurate as you hope. You can't even represent decimal 1.2 with 100% accuracy.

I didn't look at the code closely to see if there are other problems.

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This is not the problem here. –  David Hammen Jul 8 '11 at 16:07
It may not be the technical reason for his observation, but any algorithm will never live to see more than a few digits of precision using a `double` datatype. There is no fix that will improve his accuracy as long is we stick with `double`. –  tenfour Jul 8 '11 at 16:10
Sure there is. Use a different algorithm. The Leibniz series has logarithmic (i.e., sublinear) convergence. Contrast that to the very first term of the Chudnovsky series, (426880*sqrt(10005))/13591409, which gives almost 14 digits of accuracy. Want more precision? Just one more term adds another 14 digits (which is a lot more than a double can handle). –  David Hammen Jul 8 '11 at 16:29
Yes, and for maximum precision just use a literal value. –  tenfour Jul 8 '11 at 16:57