# Python - How to avoid discrepancy of base y**log base y of x, in gmpy2

The Following code examples my problem which does not occur between 10 power 10 and 10 power 11, but does for the example given in code and above it.

I can't see where in my code I am not properly handling the retrieval of the original value. May be I have just missed something simple.

I need to be sure that I can recover `x` from `log x` for various bases. Rather than rely on a library function such as `gmpy2`, is there any reverse anti-log algorithm which guarantees that for say `2**log2(x)` it will give `x`.

I can see how to directly develop a log, but not how to get back, eg, Taylor series needs a lot of terms... How can I write a power function myself? and @dan04 reply. Code follows.

``````from gmpy2 import gcd, floor, next_prime, is_prime
from gmpy2 import factorial, sqrt, exp, log,log2,log10,exp2,exp10
from gmpy2 import mpz, mpq, mpfr, mpc, f_mod, c_mod,lgamma
from time import clock
import random
from decimal import getcontext
x=getcontext().prec=1000 #also tried 56, 28
print(getcontext())

def rint():#check accuracy of exp(log(x))
e=exp(1)
l2=log(2)
l10=log(10)
#x=random.randint(10**20,10**21) --replaced with an actual value on next line
x=481945878080003762113
# logs to different bases
x2=log2(x)
x10=log10(x)
xe=log(x)
# logs back to base e
x2e=xe/l2
x10e=xe/l10
#
e2=round(2**x2)
e10=round(10**x10)
ex=round(e**xe)
#
ex2e=round(2**x2e)
ex10e=round(10**x10e)
error=5*x-(e2+e10+ex+ex2e+ex10e)
print(x,"error sum",error)
#print(x,x2,x10,xe)
#print(x2e,x10e)
print(e2,e10,ex)
print(ex2e,ex10e)
rint()
``````
• First, I don't know how you got `random.randint` to work with these limits. It doesn't on my machine... But anyway I suspect this is related to float arithmetic accuracy. – Aguy Jul 27 '16 at 10:40
• I think you are right, in which case my question is, how do i get round that, either in python or gmpy2 or some other library? – ocopa Jul 27 '16 at 13:00
• I can get the anti-log by method described at en.wikipedia.org/wiki/Exponentiation_by_squaring, so for log 2 it is a matter of not going via natural log, but directly computing log base 2. – ocopa Jul 27 '16 at 13:23

Note: I maintain the `gmpy2` library.

In your example, you are using `getcontext()` from the `decimal` module. You are not changing the precision used by `gmpy2`. Since the default precision of `gmpy2` is 53 bits and your value of x requires 69 bits, it is expected that you have an error.

Here is a corrected version of your example that illustrates how the accumulated error changes as you increase the precision.

``````import gmpy2

def rint(n):
gmpy2.get_context().precision = n
# check accuracy of exp(log(x))
e = gmpy2.exp(1)
l2 = gmpy2.log(2)
l10 = gmpy2.log(10)
x = 481945878080003762113
# logs to different bases
x2 = gmpy2.log2(x)
x10 = gmpy2.log10(x)
xe = gmpy2.log(x)
# logs back to base e
x2e = xe/l2
x10e = xe/l10
#
e2 = round(2**x2)
e10 = round(10**x10)
ex = round(e**xe)
#
ex2e = round(2**x2e)
ex10e = round(10**x10e)
error = 5 * x - (e2 + e10 + ex + ex2e + ex10e)
print("precision", n, "value", x, "error sum", error)

for n in range(65, 81):
rint(n)
``````

And here are the results.

``````precision 65 value 481945878080003762113 error sum 1061
precision 66 value 481945878080003762113 error sum 525
precision 67 value 481945878080003762113 error sum -219
precision 68 value 481945878080003762113 error sum 181
precision 69 value 481945878080003762113 error sum -79
precision 70 value 481945878080003762113 error sum 50
precision 71 value 481945878080003762113 error sum -15
precision 72 value 481945878080003762113 error sum -14
precision 73 value 481945878080003762113 error sum 0
precision 74 value 481945878080003762113 error sum -2
precision 75 value 481945878080003762113 error sum 1
precision 76 value 481945878080003762113 error sum 0
precision 77 value 481945878080003762113 error sum 0
precision 78 value 481945878080003762113 error sum 0
precision 79 value 481945878080003762113 error sum 0
precision 80 value 481945878080003762113 error sum 0
``````

As long as you set the decimal module accuracy, the usual suggestion is to use Decimal datatype

``````from decimal import Decimal, getcontext

getcontext().prec = 1000

# Just a different method to get the random number:
x = Decimal(round(10**20 * (1 + 9 * random.random())))

x10 = Decimal.log10(x)
e10 = 10**x10

e10 - x
#outputs: Decimal('5.2E-978')
``````

For different bases you may want to use the logarithmic formula:

``````x2 = Decimal.log10(x) / Decimal.log10(Decimal('2'))
e2 = 2**x2

e2 - x
#outputs: Decimal('3.9E-978')
``````
• OK, thanks, this works for Decimal, log10, but what works in general for "various bases", ie different bases, any integer base other than natural log, eg 2, to recover x? – ocopa Jul 27 '16 at 22:54
• @ocopa - see my edit regarding different bases. Just use log10(x)/log10(base). – Aguy Jul 28 '16 at 3:22
• Yes, i knew that but i was trying to work out why i was getting the wrong answer from gmpy2, and what was the underlying code. It seems gmpy2 is using log base e behind the scene or maybe there is a float accuracy issue as we thought. i will mark this as answered after i post a couple of useful references, shortly. – ocopa Jul 28 '16 at 5:49
• Useful Logarithm references en.wikipedia.org/wiki/Binary_logarithm answer by Dan04 at stackoverflow.com/questions/2882706/… answer by log0 at stackoverflow.com/questions/3719631/… – ocopa Jul 28 '16 at 6:09

Aguy solved my problem, as acknowledged. I had not taken account of needing more than 15 digits of precision. This answer to another question covers that ground. gmpy2 log2 not accurate after 16 digits