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:
Threads: 8
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
Radix Conversion... 2.924844 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.