Is there an algorithm which takes as input a Diophantine equation, returns an integer, and this integer is greater than the number of integer solutions, if the solution set is finite?

Abstract

Let En=xi=1, xi+xj=xk, xi · xj=xk: i,j,k ∈ 1,...,n. For a positive integer n, let f(n) denote the greatest finite total number of solutions of a subsystem of En in integers x1,...,xn. We prove: (1) the function f is strictly increasing, (2) if a non-decreasing function g from positive integers to positive integers satisfies f(n) ≥ g(n) for any n, then a finite-fold Diophantine representation of g does not exist, (3) if the question of the title has a positive answer, then there is a computable strictly increasing function g from positive integers to positive integers such that f(n) ≤ g(n) for any n and a finite-fold Diophantine representation of g does not exist.