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Suppose there is a given number we should test if it is product of four consecutive numbers?

So if y is our given number we should test if y = x(x+1)(x+2)(x+3) for any arbitrary x?

How to design an algorithm for this problem?

I have done it like this:

import java.util.*;

public class Product 
    public static int product(int i)
         return i * (i+1) * (i+2) * (i+3);

    public static void main(String[] args) 
        Scanner scnr = new Scanner(System.in);
        int x = scnr.nextInt();
        for (int i = 0; i < x/2; i++)
            if (product(i) == x)
                System.out.println("number is product of 4 consecutive numbers");
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Solve for x? Is there a dividebyzero.com in the SO family of sites? –  jball Jul 1 '10 at 20:26
@Paul R - it is clear that only integer solutions are allowed; the term consecutive doesn't quite apply unless you are talking about integers. –  Justin L. Jul 1 '10 at 20:29
mathoverflow.net –  bta Jul 1 '10 at 20:38
@bta: This would be quickly closed on mathoverflow.net -- too elementary for their audience of professional mathematicians. –  Jim Lewis Jul 1 '10 at 20:42
Elementary, my dear Watson, for mathoverflow.net, not stackoverflow.com :) –  Anurag Jul 1 '10 at 20:52

9 Answers 9

up vote 36 down vote accepted

starting with

y = x(x+1)(x+2)(x+3) = x^4 + 6x^3 + 11x^2 + 6x

suppose that

y = z^2 - 1


z^2 = x^4 + 6x^3 + 11x^2 + 6x + 1 

find a such that

z = (x^2 + ax + 1)^2 = x^4 + 2ax^3 + (2+a^2)x^2 + 2ax + 1

therefore a = 3

(the equations above do not require that any of x,y or z is an integer, but will possibly lose complex or negative roots)

so we can solve a quadratic for x:

x^2 + 3x + 1 - sqrt(y+1) = 0


x = -3 +/- sqrt(9 - 4 * (1-sqrt(y+1))) 

  = -3 +/- sqrt(5 + 4 sqrt(y+1)) 

which will be an integer if sqrt(y+1) is a perfect square z, and (5+4z) is also a perfect square (if z is an integer, 5-4z is odd, so its square root, if an integer, is also odd and x will be an integer).

So test whether z = sqrt(y+1) is an integer, then test whether 5+4z is a perfect square.

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This deserves more upvotes then it currently has ! –  ChristopheD Jul 1 '10 at 21:21
... as this is the best solution –  Michał Trybus Jul 1 '10 at 21:35
+1 for a beautiful answer –  Tomer Vromen Jul 2 '10 at 17:58
+1, but it takes a while to figure out why you did what. Consider a sentence at each step to explain. –  Dukeling Apr 20 '13 at 22:40

You only need to test floor(y**(0.25)-1). As y approaches infinity, x approaches y**0.25-1.5 (from underneath).

To some extent, this is rather intuitive. x*(x+1)*(x+2)*(x+3) is a product of four numbers whose average is equal to x+1.5. When x is high, 1.5 looks small.

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I win on simplicity :P –  Brian Jul 1 '10 at 20:57
+1 very nice solution. –  IVlad Jul 1 '10 at 21:01
as (x+1)**4 < y < (x+2)**4 for x>=1, x==floor(y**(0.25)-1) follows –  Robert William Hanks Jul 1 '10 at 23:08

For lots of numbers we can easily see if they might fit a certain X or not:

  • Y must be divisible by 3, since at least one of the consecutive numbers must be divisible by 3
  • Y must be divisible by 4, since at least one of the consecutive numbers must be divisible by 4

So Y must be at least divisible by 12 (3*4). This means that you can easily throw away about 92% of all numbers.

Since the value of Y will contain at least the 4-th power of X, you could start by taking the 4-th root (or how do you call this in English) of Y, then rounding this of to an integer value, calling it X and calculate the result of X(X+1)(X+2)(X+3).

The result will probably be higher (because we omitted the other factors like X to the power of 3, X to the power of 2, ...).

Now subtract 1 from X and perform the same calculations.

As long the result is higher than Y, repeat this until the result is lower, or you exactly obtained Y.

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Y is the product of two even numbers, one of which is a multiple of 4, and hence Y is a multiple of 8, and hence 24. –  David Thornley Jul 1 '10 at 20:41
Good point, now you can even throw away about 95% of the numbers. –  Patrick Jul 1 '10 at 20:44
Good answer, and you're correct (x)^(1/4) is called the "4th root of x" (or "fourth root of x"). Also, no hyphen is needed after the four, but otherwise your English is excellent! –  HalfBrian Jul 1 '10 at 21:24
in general, The product of n consecutive integers is divisible by n! –  Robert William Hanks Jul 1 '10 at 21:31

Count the fourth root of y, round it down and call it a. a(a-1)(a-2)(a-3) is much less than y. Count the fourth root of y, round it up, and call it b. b(b+1)(b+2)(b+3) is much more than y. Now you have three possible numbers to start from: a-2, a-1 and a (note a = b or a = b-1). So it should be enough to check (a-2)(a-1)a(a+1), (a-1)a(a+1)(a+2) and a(a+1)(a+2)(a+3).

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Edit: read the question wrongly, but for what it's worth (a quick way to test if it is not a product of four consecutive integers):

Any product of four consecutive integers is equal to one less than a perfect square.

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thanks for the site! –  Justin L. Jul 1 '10 at 20:32
Is the converse true? I think that's what he needs. If I have 99 (one less than a perfect square) is that a product of 4 consecutive integers? –  Mark Byers Jul 1 '10 at 20:35
No, it is not. 1*2*3*4 = 24, 2*3*4*5 = 120. 99 is inbetween –  Michał Trybus Jul 1 '10 at 20:40
This is a good method to test if it is not a product of four consecutive integers, but perhaps not a good one to test if it is. –  Justin L. Jul 1 '10 at 20:43
+1 It's worth quite a lot, as if you assume it's true, you can reduce it to a quadratic on the square root of y+1, and hence get the simple result Tomex and I give. So this answer was useful. –  Pete Kirkham Jul 1 '10 at 21:33

I'd start by getting the fourth-root of 'y'. This would give you an approximation for the smallest factor of y (ie. 'x') that you could use. Use this as the basis of a standard factorisation algorithm.

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Answer is very simple.
For given number y if y+1 is not perfect square then y is not product of four consecutive numbers. If y+1 is perfect square then y is product of four consecutive number if and only if sqrt(5+4*sqrt(y+1)) is integer.

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Interesting and seems correct in a few quick tests, could you elaborate a bit more on the theory behind this? –  ChristopheD Jul 1 '10 at 21:10
See Pete Kirkham post, he wrote a little bit more about it, but the conclusion is exactly the same. –  Tomek Tarczynski Jul 1 '10 at 21:12
Yep, just noticed it –  ChristopheD Jul 1 '10 at 21:13

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.


After some careful refinement due to Wolfram Alpha, two things have been concluded:

  1. A more refined upper bound of y^0.25 - 1.2
  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
    return n
return nil

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)

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Or he could binary search in 1 .. k. –  IVlad Jul 1 '10 at 20:44
@IVlad : int(k-1.5)-int(k-1.2) <= 2. Why does he need binary search? –  Brian Jul 1 '10 at 21:21
(10*11*12*13)**0.25 = 11.44... . int(11.44 - 1.5 ) != int(11.44 - 1.2). Of course, you only actually need to test one value, because with your number must be higher than the lower bound and lower than the upper bound, whereas int rounds them both down instead of rounding one of them up. –  Brian Jul 1 '10 at 21:24

As others have said, start with the 4th root of y (let's call it z).

Out of the sequence x, x+1,...x+3, we know that some values must be less than z, and some must be greater than z (since they can't all be equal to z).

So, we know that

x <= ceiling(z)
x+3 >= floor(z)

That gives you a very small range of numbers to try for x.

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