Solve for y as a function of x: http://www.wolframalpha.com/input/?i=x%5E5%2B+xy+-+y%5E2+-+y%5E3

```
y(x) := INSERT_EQUATION_HERE
any((y in setX) for y in y(x) for x in setX)
```

This takes O(|X|), i.e. linear, time.

Alternatively, if you aren't using a language with an `any`

function or list manipulation, then your solution has to be a bit more verbose:

```
for x in setX:
possibleYs = solveForY(x)
for y in possibleYs:
if y in setX:
return SOLUTION:(x,y)
return NO_SOLUTION
```

You don't actually have to solve the 2D polynomial like I showed above. Instead, you can consider each x in the set; this fixes x and gives you a polynomial in y. Then you solve that polynomial in a constant amount of time. For example if x=0, we'd find the 3 solutions to y^2==y^3; if x=1, we'd find the 3 solutions to 2-y^2==y^3, if x=-0.52, we'd etc. The solution is http://en.wikipedia.org/wiki/Cubic_function#General_formula_of_roots

More general version of the problem:

If you consider an arbitrary polynomial, do note that this method can only provide O(1) efficiency in the following case: min(max_x_degree, max_y_degree)<5. This is because, as proven in Galois theory, the only polynomials with certain closed-form solutions are those of degree 4 or less. And in this problem, we can just turn the variable with the highest degree into a constant.

This is not to say that O(1) efficiency could not be obtained by some other method, in cases where min(max_x_degree, max_y_degree)<5.

Things also get more interesting if you increase the number of variables.