I'd like to solve `y = (x+1)**3 - 2`

for `x`

in sympy to find its inverse function.

I tried using `solve`

, but I didn't get what I expected.

Here's what I wrote in IPython console in cmd (sympy 1.0 on Python 3.5.2):

```
In [1]: from sympy import *
In [2]: x, y = symbols('x y')
In [3]: n = Eq(y,(x+1)**3 - 2)
In [4]: solve(n,x)
Out [4]:
[-(-1/2 - sqrt(3)*I/2)*(-27*y/2 + sqrt((-27*y - 54)**2)/2 - 27)**(1/3)/3 - 1,
-(-1/2 + sqrt(3)*I/2)*(-27*y/2 + sqrt((-27*y - 54)**2)/2 - 27)**(1/3)/3 - 1,
-(-27*y/2 + sqrt((-27*y - 54)**2)/2 - 27)**(1/3)/3 - 1]
```

I was looking at the last element in the list in `Out [4]`

, but it doesn't equal `x = (y+2)**(1/3) - 1`

(which I was expecting).

Why did sympy output the wrong result, and what can I do to make sympy output the solution I was looking for?

I tried using `solveset`

, but I got the same results as using `solve`

.

```
In [13]: solveset(n,x)
Out[13]: {-(-1/2 - sqrt(3)*I/2)*(-27*y/2 + sqrt((-27*y - 54)**2)/2 - 27)**(1/3)/
3 - 1, -(-1/2 + sqrt(3)*I/2)*(-27*y/2 + sqrt((-27*y - 54)**2)/2 - 27)**(1/3)/3 -
1, -(-27*y/2 + sqrt((-27*y - 54)**2)/2 - 27)**(1/3)/3 - 1}
```