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?

`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`

willnotbe 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.`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.`