I'd like to calculate the square root of a number bigger than 10^2000 in Python. If I treat this number like a normal integer, I will always get this result back:

Traceback (most recent call last):
  File "...", line 3, in <module>
    print( q*(0.5)  )
OverflowError: int too large to convert to float

How do I fix this? Or does a possibilty other than using Python exist to calculate this square root?

  • 1
    Do you mean 10^2000 or 10**2000?
    – RoadRunner
    Dec 17, 2017 at 11:36
  • 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? Oct 13, 2023 at 3:27

4 Answers 4


Just use the decimal module:

>>> from decimal import *
>>> Decimal(10**2000).sqrt()
>>> Decimal(10**200000).sqrt()
>>> Decimal(15**35315).sqrt()

You can also use the gmpy2 library.

>>> import gmpy2
>>> n = gmpy2.mpz(99999999999999999999999999999999999999999999999999999999999999999999999999999999999999999999999982920000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000726067)
>>> gmpy2.get_context().precision=2048
>>> x = gmpy2.sqrt(n)

Useful links:

  1. Decimal - Python Documentation
  • If you are looking for an integer result and are going to use gmpy2, the simplest and best way is just `gmpy2.isqrt().
    – casevh
    Dec 17, 2017 at 16:09
  • @casevh note: isqrt will not round the square root correctly--it gives the floor of the square root instead of the nearest integer. Oct 15, 2023 at 2:32
  • @HansBrende Then take a look at gmpy2.isqrt_rem(). It also returns the remainder and that can be used to calculate the ceiling or nearest integer.
    – casevh
    Oct 15, 2023 at 14:08

The usual square root methods convert the parameter to a float value before doing the calculation. As you saw, this does not work well with very large integers.

So use a function that is designed to work on arbitrarily large integers. Here is one, guaranteed to return correct integer part of the square root of any positive integer. This function drops the fractional part of the result, which may or may not be what you want. Since this function uses iteration it is also slower than the built-in square root routines. The Decimal module works on larger integers than the built-in routines but the precision of the values must be defined in advance so it does not work on arbitrarily large values.

import math

_1_50 = 1 << 50  # 2**50 == 1,125,899,906,842,624

def isqrt(x):
    """Return the integer part of the square root of x, even for very
    large integer values."""
    if x < 0:
        raise ValueError('square root not defined for negative numbers')
    if x < _1_50:
        return int(math.sqrt(x))  # use math's sqrt() for small parameters
    n = int(x)
    if n <= 1:
        return n  # handle sqrt(0)==0, sqrt(1)==1
    # Make a high initial estimate of the result (a little lower is slower!!!)
    r = 1 << ((n.bit_length() + 1) >> 1)
    while True:
        newr = (r + n // r) >> 1  # next estimate by Newton-Raphson
        if newr >= r:
            return r
        r = newr
  • "guaranteed to return correct integer part of the square root of any positive integer" — it appears that it is not true for my case: isqrt(178533196125860586848256)=422531887702 != math.sqrt(178533196125860586848256)=422531887703. My calculator also gives 422531887703. I tried it with Python 3.5.2 x64
    – Dmitry
    Aug 15, 2019 at 19:13
  • 1
    @Dmitry: As I check your comment, I see that my isqrt is correct and the othe calculations are wrong. You can see that mine is correct by evaluating 422531887702**2 <= 178533196125860586848256 < 422531887703**2 in Python. That evaluates to True. However, 422531887703**2 <= 178533196125860586848256 evaluates to False. If the other methods say the correct square root is 422531887703 then they are wrong. Please check for yourself. If you find an actual error in my code, I would love to know, so please tell me. Aug 15, 2019 at 21:21
  • @RoryDaulton thank you for the check. Yes, you are correct — your implementation gives accurate whole part while math.sqrt behaves very strange with big numbers: math.sqrt(178533196125860602616209) == math.sqrt(178533196125860586848256) returns True!
    – Dmitry
    Aug 16, 2019 at 13:04
  • 1
    @J.Win.: My isqrt returns a number different from the one you show. Your number ends 903 while my isqrt returned number ends 003. The rest of the digits agree. My testing shows my result to be correct. Please double-check the results that you get and your tests on the results. Oct 23, 2020 at 23:30
  • 1
    @RoryDaulton @Dmitry as regards 422531887703, that is in fact the correct square root. 422531887702 is the correct isqrt. They are two different things! The reason for the discrepancy is that the former is correctly rounded, while the latter is not... such is the nature of isqrt. Oct 15, 2023 at 2:18

When using sqrt from the library math, before it proceeds to square root it, it will convert the value to a float.

If we manually try to convert the 10**2000 to a float, it also triggers an error

>>> float(10**2000)
OverflowError                             Traceback (most recent call last)
<ipython-input-14-6ac81f63106d> in <module>
----> 1 math.sqrt(10**2000)

OverflowError: int too large to convert to float

If we were speaking of a big number, but with the square equals or less than 308, the Decimal module would do the work as follows

>>> from decimal import Decimal
>>> Decimal(math.sqrt(10**308))

However, as the number is way square is way bigger than 308, in this case, 2000, one would have to do as follows

>>> from decimal import Decimal
>>> Decimal(10**2000).sqrt()

Let's see the output if one tries to convert the Decimal(10**2000) to float

>>> float(Decimal(10**2000))

One might also use the decimal module when working with factorials, as they tend to get large really fast.


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)

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