How (and why) does "Python compute square roots of perfect squares exactly"?

This amazing code golf answer to Is this number Loeschian? in its entirety:

Python, 49 bytes

lambda n:0in[(n-3*i*i+0j)**.5%1for i in range(n)]

Uses the equivalent quadratic form given on OEIS of n == 3*i*i+j*j. Check whether n-3*i*i is a perfect square for any i by taking its square root and checking if it's an integer, i.e. equals 0 modulo 1. Note that Python computes square roots of perfect squares exactly, without floating point error. The +0j makes it a complex number to avoid an error on the square root of a negative.

How does Python do this? Does **.5 "detect" that a given number is a perfect square somehow? Is this only reliable for integer input or will it work on floats up to some size as well?

I've also added a parenthetical Why? to the question; is this something that programmers rely upon? Is it for speed? Does it come with a cost?

• It's required by the IEEE 754 standard. Square root results must be the closest double to the actual square root. For perfect squares, the closest double is an integer. Jun 8 '20 at 4:20
• IEEE 754 does require sqrt to be correctly rounded, but there are an awful lot of gaps to fill in to get from there to z**0.5 being correctly rounded in Python for a complex number z (even a complex number with zero imaginary part), and in general z**0.5 will not be correctly rounded. At least, it's certainly not on my Mac laptop, where math.sqrt(x) == x**0.5 fails for many positive floats x. On a typical machine, you can trace a direct path from math.sqrt to the underlying correctly-rounded hardware sqrt, but the libm pow that underlies x**0.5 is another matter entirely. Jul 14 '20 at 18:00
• BTW, I'm a bit puzzled about how the solution is expected to work, since z%1 isn't valid for a complex number z. (lambda n:0in[(n-3*i*i+0j)**.5%1for i in range(n)])(35) gives me TypeError: can't mod complex numbers. Jul 15 '20 at 8:34
– uhoh
Jul 15 '20 at 12:24
• @uhoh: Good idea; will look at that later when I have time. (I don't think I even have a login there at the moment.) Jul 15 '20 at 14:41

You can check out the source code here. They describe the algorithm they use for computing the (approximate) square root of nonnegative integers, and show that for perfect squares the algorithm gives the exact answer. The code is C, but they give a translation of the code into Python:

def isqrt(n):
"""
Return the integer part of the square root of the input.
"""
n = operator.index(n)
if n < 0:
raise ValueError("isqrt() argument must be nonnegative")
if n == 0:
return 0
c = (n.bit_length() - 1) // 2
a = 1
d = 0
for s in reversed(range(c.bit_length())):
# Loop invariant: (a-1)**2 < (n >> 2*(c - d)) < (a+1)**2
e = d
d = c >> s
a = (a << d - e - 1) + (n >> 2*c - e - d + 1) // a
return a - (a*a > n)

I assume, but haven't yet checked, that when computing a power at runtime, Python first checks that 1. the base is a nonnegative integer, 2. the exponent is exactly 0.5, and if those both hold then it invokes the code I linked to above.

• I'm afraid your assumption isn't correct. For a float x, Python (at least CPython) passes an x**0.5 operation straight down to the underlying C math library. It's conceivable that that math library could special-case an exponent of 0.5 to use the CPU's sqrt instruction (if such exists), which one can reasonably expect to be correctly rounded, but in my experience that doesn't usually happen. It certainly doesn't on my Mac laptop: x**0.5 and math.sqrt(x) give observably different results for many x. Jul 14 '20 at 17:49
• It wouldn't make sense to substitute isqrt(x) for x**0.5, anyway: if x is not a perfect square, the two will usually have quite different values. For example, isqrt(8) is 2, but 8**0.5 is 2.8284271247461903. Jul 14 '20 at 17:51