Simplifiy your problem, using a bit of math.
sqrt(a*b) = sqrt(a) * sqrt(b) (for real, positive numbers at least).
So, any number larger than, say, 10^100, divide by 10^100. That's
a, and the result of the division is
b, so that your original number =
a * b.
Then use the square root of 10^100 (= 10^50), multiply that by the square root of
b, and you have your answer.
With your example:
x = 10**309
a = 1e100
b = 1e209 # Note: you can't calculate this within Python; just use plain math here
y = 1e50 * math.sqrt(1e209)
Example for a not-so-round number:
x = 3.1415 * 1e309
a = 1e100
b = 3.1415e209 # Again, just subtract the exponent: 309 - 100
y = 1e50 * math.sqrt(3.1415e209)
Or for an integer that's not a power of 10, fully written out:
x = 707070
x = 70.707 * 1e4 # note: even number in exponent
x = 70.707e4
a = 1e2 # sqrt(1e2) = 1e1 = 10
b = 70.707e2
y = 10 * sqrt(70.707e2)
A few notes:
Python handles ridiculously large integer numbers without problems. For floating point numbers, it uses standard (C) conventions, and limits itself to 64 bit precision. You almost always get floating point numbers when taking a square root of something.
3.1415 * 10**209. This is a standard programming convention.
inffor anything larger than 10^308
gmpy2.isqrtcan calculate the integer square root of a 1,000,0000 digit number in less than 25 ms.
isqrtcalculates the integer square root.
sqrtreturns a multiple precision floating point value but you can increase the precision to any number of bits.