Given ξ ∈ ℤ[√2], find t ∈ ℤ[ω] such that t^†t = ξ, if such t exists, or return Nothing otherwise.

Given an element ξ ∈ D[√2], find t ∈ D[ω] such that t^†t = ξ, if such t exists, or return Nothing otherwise.

Given ξ ∈ ℤ[√2], find t ∈ ℤ[ω] such that t^†t ~ ξ, if such t exists, or Nothing otherwise. Unlike diophantine, the equation is only solved up to associates, i.e., up to a unit of the ring.

Given a positive composite integer n, find a non-trivial factor of n using a simple Pollard-rho method. The expected runtime is O(√p), where p is the size of the smallest prime factor. If n is not composite (i.e., if n is prime or 1), this function diverges.

Given a factorization n = ab of some element of a Euclidean domain, find a factorization of n into relatively prime factors,

where m ≥ 2, u is a unit, and c₁, …, c_m are pairwise relatively prime.

While this is not quite a prime factorization of n, it can be a useful intermediate step for computations that proceed by recursion on relatively prime factors (such as Euler's φ-function, the solution of Diophantine equations, etc.).

Modular exponentiation, using the method of repeated squaring. power_mod a k n computes a^k (mod n).

Compute a root of −1 in ℤ_n, where n > 0. If n is a positive prime satisfying n ≡ 1 (mod 4), this succeeds within an expected number of 2 ticks. Otherwise, it probably diverges.

As a special case, if this function notices that n is not prime, then it diverges without doing any additional work.

Compute a root of a in ℤ_n, where n > 0. If n is an odd prime and a is a non-zero square in ℤ_n, then this succeeds in an expected number of 2 ticks. Otherwise, it probably diverges.