If there is a single polynomial equation that needs to solved inside a rectangular domain, then there is a nice algorithm based on
Assume your domain is [0,1]x[0,1], which can be achieved by rescaling. You can convert your polynomial equation into one using the Bernstein polynomials. The 1D case is easiest to describe, for a 2 degree polynomial you can write it as
B(x) = b_0 x^2 + 2 b_1 x (1-x) + b_2 (1-x)^2
What these polynomials give you is a simple convexity test for zeros. If all the coefficients, b_0, b_1, b_2 are positive, then you can guarantee that B(x) is strictly positive in the domain [0,1]. Likewise, if they are all negative, then it is strictly negative. So to have a zero the coefficients must differ in sign, or be zero.
You can then proceed in a recursive fashion, split the domain in half, rescale to fit [0,1] calculate the new Bernstein polynomial and apply the zero test. In this way you can quickly narrow down on where the zeros are, ignoring large parts of the domain.
This algorithm was describe in the 2D case in P. Milne, 1991, Zero set of Multivarient Polynomial Equations, Mathematics of Surfaces IV. I've adapted it to 3D in my paper at A new method for drawing Algebraic Surfaces
https://singsurf.org/papers/algsurf/index.html which describes all the relevant algorithms, and you can see a live demo at Implict curve plotter with code on github.
There is a vast literature on this problem and plenty of other algorithms for it. Marching squares is a popular algorithm.