# Calculating the digits of pi

I've used the GMP library and C++ to code an implementation of the Gauss-Legendre algorithm to calculate the digits of pi.

It has correct output, but the problem is I don't know at which point the output "turns bad", since I have to specify the precision in the code.

Here is the output using 64-bit precision: 3.141592653589793238*35*, the last two digits being incorrect.

My question is, if I want n digits of pi, how many bits of precision b, and how many iterations of the algorithm i will be needed?

Thank You

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Yeah, have can go to chat.stackoverflow.com/rooms/10/loungec to ping Mysticial. If only there was a similar method for Dietmar Kühl for iostream questions... – Mooing Duck Jan 4 '13 at 18:58

The Gauss-Legendre algorithm (aka the AGM algorithm) requires full precision all the way through.

Unlike Newton's Method iterations, AGM iterations aren't self-correcting. So you need full precision from the start. Furthermore, you need extra guard digits.

My question is, if I want `n` digits of pi, how many bits of precision `b` will be needed?

First you need to convert the `n` (decimal) digits into `b` binary bits. So that would be:

``````        log(10)
b = n ---------- + epsilon
log(2)
``````

Where `epsilon` is the number of guard digits. How much you need depends on the implementation and rounding behavior, but typically 100 bits is more than enough for any # of iterations.

As for how many iterations you need. This can be found by empirical evidence.

Here's the output of a small app I wrote that compute Pi to 100 million digits using the Gauss-Legendre algorithm:

``````================================================================
Computing pi to 100000000 digits:

Starting AGM...         1.394965 seconds
Starting Iteration 0...    -3 (error in decimal digits)
Starting Iteration 1...    -9
Starting Iteration 2...    -20
Starting Iteration 3...    -42
Starting Iteration 4...    -85
Starting Iteration 5...    -173
Starting Iteration 6...    -347
Starting Iteration 7...    -696
Starting Iteration 8...    -1395
Starting Iteration 9...    -2792
Starting Iteration 10...    -5586
Starting Iteration 11...    -11175
Starting Iteration 12...    -22352
Starting Iteration 13...    -44706
Starting Iteration 14...    -89414
Starting Iteration 15...    -178829
Starting Iteration 16...    -357661
Starting Iteration 17...    -715324
Starting Iteration 18...    -1430650
Starting Iteration 19...    -2861302
Starting Iteration 20...    -5722607
Starting Iteration 21...    -11445216
Starting Iteration 22...    -22890435
Starting Iteration 23...    -45780871
Starting Iteration 24...    -91561745
Starting Iteration 25...    -183123492
AGM:                    118.796792 seconds
Finishing...            3.033239   seconds

Total Wall Time:        126.151086 seconds

CPU Utilization:        495.871%
CPU Efficiency:         61.984%

Writing to "pi.txt"...  Done
``````

So 25 iterations is sufficient for 183 million digits. Likewise, it doubles with each iteration, so you can run some basic logarithm math to figure out how many iterations you need.

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Thank you, I have a basic implementation working, but it's really slow. I did the obvious improvement of avoiding re-computing the factorials on each iteration, but overall the code is still pretty slow. For example, 10000 digits takes 8 seconds. Here's my code if anyone wants to take a look: pastebin.com/9Bs2WHRV EDIT: Sorry that is my Chudnovsky implementation, the Gauss-Legendre implementation is okay. – Sam Kennedy Jan 5 '13 at 3:40
Yeah, Chudnovsky is a different animal. It's more difficult to implement since you need to combine it with Binary Splitting. But it is very fast if done correctly. – Mysticial Jan 5 '13 at 9:15
How is the error calculated? What do the 8 separate threads do? The square root operation is quite expensive so I could see why that would be put in a separate thread, but the rest of the operations take relatively little time. – Sam Kennedy Jan 9 '13 at 8:46
The error is calculated as double the difference from the previous iteration. The threads aren't relevant. This app uses the same back-end as y-cruncher which parallelizes within the large multiplications. It doesn't use GMP at all. There's actually no parallelism done at the top level. – Mysticial Jan 9 '13 at 20:17
What's the starting error? It looks like 2.something but I can't find anywhere where it's mentioned. – Sam Kennedy Jan 11 '13 at 17:57