Shows this function:

def find_cube_root(n):
    lo = 0
    hi = 1 << ((n.bit_length() + 2) // 3)
    while lo < hi:
        mid = (lo+hi)//2
        if mid**3 < n:
            lo = mid+1
            hi = mid
    return lo

My input for the function is m3 the message cubed so that is why I need this function. The len(n) turns out to be 454 vs. 1507 for bit length.

I kept trying to cap high at num // 2 or num // 3 which was not working but this works. Why does bit length work here?

  • 1
    The part of the question with "I kept trying to cap high at num // 2 or num // 3" is not intelligible, first because high and num are not part of the code, second because initializing with hi = n // 2 or hi = n // 3 results in code that's functional whenever n > 5.
    – fgrieu
    Mar 18 at 13:33

1 Answer 1


The algorithm attempts to compute the cubic root of integer n using bisection. The context is the final step of Håstad's broadcast attack, in which n can be thousands of bits, and is expected to be exactly the cube of an integer if all went well beforehand.

Why does bit length work here?

The expression

hi = 1 << ((n.bit_length() + 2) // 3)

yields a rough approximation of the desired result, by taking the logarithm to base 2, dividing by 3 (with some offset), and exponentiating to base 2. Let's prove the result is always by excess:

  1. For integer n >= 0, by specification of int.bit_length(), n.bit_length() is the smallest non-negative integer x such that n < 2**x.
  2. For every non-negative integer x, if holds x <= ((x + 2) // 3) * 3
  3. The function which for input x yields 2**x (that is two to the xth power) is nondecreasing
  4. Therefore n < 2**(((x + 2) // 3) * 3)
  5. By a standard property of powers, 2**(((x + 2) // 3) * 3)is (2**((x + 2) // 3))**3
  6. For every non-negative integer i, it holds (1 << i) == (2**i)
  7. Therefore the initial value of hi is such that n < hi**3 and hi >= 0.

The loop invariant condition of the bisection algorithm

lo <= hi  and  (lo-1)**3 < n  and  n <= hi**3

is now easily established by induction: it hold before the while loop, and is maintained by the changes made in the loop (the proof uses that the function which for input x yields x**3 is nondecreasing), hence is valid on exit. Bisection narrows the gap between lo and hi by a factor about 2 at each loop, and terminates with lo >= hi. It follows that on output the function returns the smallest integer lo such that lo**3 >= n, which is the integer cubic root of n by excess.

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