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
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
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()