Simplifiy your problem, using a bit of math.

Note that `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:

```
import math
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.

`1e309`

means `10**309`

, and `3.1415e209`

means `3.1415 * 10**209`

. This is a standard programming convention.

`math.sqrt`

returns`inf`

for anything larger than 10^308`gmpy2.isqrt`

can calculate the integer square root of a 1,000,0000 digit number in less than 25 ms.`isqrt`

calculates the integer square root.`sqrt`

returns a multiple precision floating point value but you can increase the precision to any number of bits.9more comments