The decimal module is fine but involves the added overhead of converting from base 2 to base 10 and back, plus it is non-obvious how much decimal precision is necessary to get the result back into base 2, correctly rounded.

Without using decimal, it is slightly trickier to compute the square root since this is not built-in functionality, but it's still possible using `math.isqrt`

instead! Here's a function I came up with that calculates the square root of any number to arbitrary precision, *correctly rounded*:

```
def sqrt(x: Union[int, float, Fraction], precision: int = 53) -> Fraction:
a, b = x.as_integer_ratio()
la, lb = a.bit_length(), b.bit_length()
s = max(precision - (la + lb - (a << lb < b << la) >> 1), 0)
ab = a * b << (s << 1)
n0 = math.isqrt(ab)
n1 = n0 + 1
return Fraction(n1 if n0 * n1 < ab else n0, b << s)
```

More precisely, the following are guaranteed to hold:

`|√(x) - sqrt(x, p)| < 0.5ulpₚ(√(x))`

`float(sqrt(x, 53)) == math.sqrt(x)`

if `math.sqrt(x)`

doesn't overflow
`sqrt(x * x) == x`

, avoiding this problem

If you need the result as a `float`

instead of a `Fraction`

, just do `float(sqrt(x))`

(although this may lose precision or overflow if the final result is too big for a float).

**Note:** if you know in advance that you will only be taking the square root of integers, there is a slightly simpler function that does the same thing, but only works on integers. The above function is equivalent to this one for any integer or `Fraction`

with a denominator of 1:

```
def sqrt_of_int(x: int, precision: int = 53) -> Fraction:
s = max(precision - (x.bit_length() + 1 >> 1), 0)
x <<= s << 1
n0 = math.isqrt(x)
n1 = n0 + 1
return Fraction(n1 if n0 * n1 < x else n0, 1 << s)
```

`10^2000`

or`10**2000`

?`math.isqrt()`

gives the truncated integer square root of an integer argument, even if the argument is too big to fit in a float. Does that meet your requirements?