I have a program I'm writing in which the user has the option to choose between solving a cubic function for either second or third degree polynomials. Once choosing, the program applies a number of formulas, including: solving the 2nd degree discriminant, the quadratic formula, the formula for polynomials of the second degree, Cardano's analogous method of third degree polynomials, and the standard cubic formula (basically, the first four formulas on this page).

Here's my code:

```
import math
def deg3():
print("This is a third degree polynomial calculator.")
print("Please enter four numbers.")
a = int(input())
b = int(input())
c = int(input())
d = int(input())
# Apply Cardano's compressed method to find x root, broken up into different variables.
p = (-1 * b)/(3 * a)
q = p ** 3 + (b * c - (3 * a * d))/ (6 * (a ** 2))
r = c / (3 * a)
x = (q + (q**2 + (r - p**2)**3) **1/2) **1/3 + (q + (q**2 + (r - p**2)**3) **1/2) **1/3 + p
print("The root is:", x)
# Applies final cubic formula, and returns.
total = (a * x**3) + (b * x**2) + (c * x) + d
total = round(total, 3)
return total
# If discr > 0, then the equation has three distinct real roots.
# If discr = 0, then the equation has a multiple root and all its roots are real.
# If discr < 0, then the equation has one real root and
# two nonreal complex conjugate roots.
```

Now it easily returns a total. The computation is correct, but I'm still trying to wrap my brain around the analogous formula. What is the discriminant part of the equation? How do I find potential roots, like I do with the quadratic formula? Probably a no-brainer question, but I want to understand the process better.

`cubic`

function (none of the others) and a single line calling it (like`cubic(1, 2, 3, 4)`

). Making your exampleminimalwill get answers much faster. – David Robinson Nov 11 '12 at 4:47