Your equation can be simplified as
y = x^4 + 6*x^3 + 11*x^2 + 6x
You can start from x=1 and go upwards to check. We can note a very easy-to-compute upper bound: the 4th root of y (or the square root of the square root of y). Meaning, when you reach that number, you can stop. This is fortunate for you, because luckily for us, 4th roots are very very very very small.
For numbers up to 10,000, this is pretty easy to check, because you're going to check at most ten integers. If your number is under 500, you'll only need to check four integers at most.
At 1,000,000+, you're going to have to start checking 31 and more numbers, so it might start getting less trivial.
UPPER AND LOWER BOUNDS
After some careful refinement due to Wolfram Alpha, two things have been concluded:
- A more refined upper bound of y^0.25 - 1.2
- A definite lower bound of y^0.25 - 1.5
y = num_to_check
k = Math.sqrt(Math.sqrt(y)) # or Math.pow(y,0.25)
lower = int(k-1.5)
upper = int(Math.ceil(k-1.2))
for n in (lower...upper)
if n * (n+1) * (n+2) * (n+3) == y
Note that in this case, there are a maximum of two numbers to be checked for any given y.
edit: after refining x to only the integers, it appears that there is only one number to check, in all cases, as your range reduces to one number. Cool! (thanks to Brian)