# Python: Calculate sine/cosine with a precision of up to 1 million digits

Question is pretty self-explanatory. I've seen a couple of examples for pi but not for trigo functions. Maybe one could use a Taylor series as done here but I'm not entirely sure how to implement that in python. Especially how to store so many digits. I should mention: this ideally would run on vanilla python i.e. no numpy etc.

Thanks!

Edit: as said, I know the question has been asked before but it's in java and I was looking for a python implementation :)

Edit 2: wow I wasn't aware people here can be so self-absorbed. I did try several approaches but none would work. I thought this a place you can ask for advice, guess I was wrong

last edit: For anyone who might find this useful: many angles can be calculated as a multiple of sqrt(2), sqrt(3) and Phi (1.61803..) Since those numbers are widely available with a precision up to 10mio digits, it's useful to have them in a file and read them in your program directly

• you should check the `decimal` module. Jul 18, 2017 at 14:29
• Possible duplicate of calculate sine and cosine functions with precision Jul 18, 2017 at 14:31
• Can you demonstrate any effort at implementing the algorithm you linked to? Jul 18, 2017 at 14:32
• Two first duckduckgo hits for "python arbitrary precision" are mpmath.org and pythonhosted.org/bigfloat . It looks like you did not even bother to search the web before asking. Jul 18, 2017 at 14:46
• Scott Hunter and euxodos: maybe read before posting, I said it should run on vanilla python, no extra modules. Jul 18, 2017 at 14:54

mpmath is the way:

``````from mpmath import mp
precision = 1000000
mp.dps = precision
mp.cos(0.1)
``````

If unable to install mpmath or any other module you could try polynomial approximation as suggested.

where Rn is the Lagrange Remainder

Note that Rn grows fast as soon as x moves away from the center x0, so be careful using Maclaurin series (Taylor series centered in 0) when trying to calculate sin(x) or cos(x) of arbitrary x.

Try this

``````import math
from decimal import *

def sin_taylor(x, decimals):
p = 0
getcontext().prec = decimals
for n in range(decimals):
p += Decimal(((-1)**n)*(x**(2*n+1)))/(Decimal(math.factorial(2*n+1)))
return p

def cos_taylor(x, decimals):
p = 0
getcontext().prec = decimals
for n in range(decimals):
p += Decimal(((-1)**n)*(x**(2*n)))/(Decimal(math.factorial(2*n)))
return p

if __name__ == "__main__":
ang = 0.1
decimals = 1000000
print('sin:', sin_taylor(ang, decimals))
print('cos:', cos_taylor(ang, decimals))
``````
``````import math
x = .5
def sin(x):
sum = 0
for a in range(0,50): #this number (50) to be changed for more accurate results
sum+=(math.pow(-1,a))/(math.factorial(2*a+1))*(math.pow(x,2*a+1))
return sum

ans = sin(x)
print('{0:.15f}'.format(ans)) #change the 15 for more decimal places
``````

Here is an example of implementing the Taylor series using python as you suggested above. Changing to cos wouldn't be too hard after that.

EDIT:

Added in the formatting of the last line in order to actual print out more decimal places.

• OverflowError: long int too large to convert to float when trying your code with range 0 to 500 :( Jul 18, 2017 at 14:52