Hello, Codeforces!
Today I'm going to talk about an unpopular technique in number theory.
Definition and elementary properties
Def. Let $$$p > 2$$$ be a prime number, then we will call quadratic residues all $$$1 \le x \le p - 1$$$ modulo $$$p$$$ such that the equation $$$a^2 \equiv x \pmod{p}$$$ has solutions and quadratic nonresidues otherwise. Note that $$$0$$$ is neither quadratic residue nor quadratic nonresidue.
Theorem: quadratic residues and quadratic nonresidues are equally divided.
Theorem: Denote by $$$R$$$ a quadratic residue and by $$$N$$$ a quadratic nonresidue, then:
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With these two theorems, we can already solve 103428K - Tiny Stars.
How to check if the number is deductive or non-deductive?
There are several ways to check if a number is quadratic deduction. In this blog, we will look at just one of them, you can read about Gauss's lemma and law of quadratic reciprocity.
Euler's criterion
$$$a$$$ is a quadratic deduction modulo $$$p$$$ if and only if $$$a^{{\frac{p - 1}{2}}} \equiv 1 \pmod{p}$$$, and a quadratic non-deduction if and only if $$$a^{\frac{p - 1}{2}} \equiv -1 \pmod{p}$$$.
Consequence: $$$-1$$$ is quadratically deductible if and only if $$$p = 4k + 1$$$, for some natural $$$k$$$, and quadratically non-deductible if and only if $$$p = 4k + 3$$$, for some natural $$$k$$$.
Clearly, the complexity of the number check is $$$O(\log_2p)$$$.
Finding $$$i$$$ modulo $$$p$$$
Def. $$$i$$$ is such a number that $$$i^2 = -1$$$ $$$\implies$$$ $$$i$$$ modulo $$$p$$$ let us call such a number that $$$i ^ 2 \equiv -1 \pmod{p}$$$.
Algorithm: If $$$p = 4k + 3$$$ for some natural $$$k$$$, then there is no such $$$i$$$. If $$$p = 2$$$, then $$$i = 1$$$. Otherwise consider the quadratic non-deduction of $$$a$$$, by Euler's criterion we know that $$$a^{\frac{p - 1}{2}} \equiv -1 \pmod{p}$$$, then $$$a^{\frac{p - 1}{4}} \equiv i \pmod{p}$$$. All that remains is to find a quadratic non-deduction, for this we take a random $$$1 \le a \le p - 1$$$ and check it for $$$O(\log_2p)$$$, if it is a quadratic deduction then take another random $$$a$$$. Since the deductions and non-deductions are equal, we need $$$O(1)$$$ of such checks, so the total complexity of the algorithm is $$$O(\log_2p)$$$.