As Kevin W. said in a comment, in the future, "if you want someone to review your code... use the codereview stackexchange". However, here are a few suggestions.

Firstly, as something to keep in mind, the problem you have is a lot like calculating the fibonacci sequence, and there are probably plenty of examples of using recursion to calculate members of that sequence.

Secondly, the way you built your recursive function makes it limited to being used only to find the 13th number in the sequence. You begin at the start of the sequence and work your way up to the 13th number, and what you are doing is basically an iterative solution to the problem with minor tweaks to make it work via recursion.

A better approach would be to generalize your function so that you can pass the sequence member number as a parameter, and the function will calculate it via recursion. The way to do this is to start at your target member number and through recursion, get the members required to make that member. This allows the function to be used to calculate any number in the sequence, not just the 13th number. It also has the added benefit that your code can be both shrunk and do more.

This is the code:

```
// index is the member number; it is 1 based e.g. index of 1 gives the first number in the sequence
int find(int index)
{
if (index == 1 || index == 2)
return 3;
return (find(index - 1) * find(index - 2)) - find(2);
}
```

When solving problems with recursion, the method generally used is to start with the problem you want to solve and break it down (as shown in my code above), rather than start with subproblems to find the larger problem (as your code shows).

When applying recursion to a sequence, write out the mathematical definition of the sequence first, and that is what must be returned from the recursive function. For example, in your problem, the definition is

a[n] = (a[n-1] * a[n-2]) - a[2]

Now take a look at the solution I wrote. What I am returning is precisely this sequence definition, just in terms of the recursive function. The base case at the beginning of the function is simply the initial member(s) required to calculate the rest of the sequence. I encourage you to work the algorithm through on paper and play with it to see exactly what is happening.

As a final note, this algorithm is horrendous in terms of run time. There are three recursive calls per call to find(), which means that finding the 13th member is on the order of 3^13, which is exponential. Exponential algorithms are terrible algorithms, and should always be avoided.

If the recursion is examined closely you can see that in order to calculate a[n], the code calculates a[n-1] and a[n-2]. But in order to calculate a[n-1], a[n-2] and a[n-3] are both calculated, meaning that a[n-2] is calculated TWICE. This observation is very important because we only went down one level of recursion. There are a total of about 3^13 member calculations occurring when all there should be are 13 (for the 13 members). All of that time performing the same calculations millions of times is a horrendous waste and is what makes exponential algorithms so awful.

So what if we stored each of the members that the function calculates? This technique is called dynamic programming, and is where answers to subproblems are stored on the way to solving a larger problem so calculations are not performed multiple times. The solution implementing dynamic programming is:

```
// a variable that persists across function calls such as an instance field
int[] array = new int[20]; // just giving some extra memory in case you want to calculate other members
array[0] = -1; //invalid member of the sequence since it is 1-based
array[1] = 3;
array[2] = 3;
//set the rest of the numbers to values letting you know they have not been set/found/calculated yet
for (int i = 3; i < 20; i++)
{
array[i] = -1;
}
// index is the member number; it is 1 based e.g. index of 1 gives the first number in the sequence
int find(int index)
{
if (array[index] != -1) //if already calculated that member, just return it
return array[index];
//store the answer
array[index] = (find(index - 1) * find(index - 2)) - find(2);
return array[index];
}
```

With this code, you can call find() for any number and it will calculate it for you, instead of just the 13th number.

Lastly, and most importantly, as Kevin W. pointed out in a comment, the presence of a negative number as a member means that you are getting numbers too big for ints. Luka Milosevic says that the 13th member is actually a number x10^90, which is too big for a long even. Doubles can work as long as you don't need more than 20 or so digits of precision, but because of at least 90 digits in the answer, doubles are not accurate enough. Fortunately Java has a class called BigInteger, which can store as large of numbers as you want, regardless of size. In order to obtain your answer, you probably have to use them, unless you want to do the math manually. The documentation for BigInteger is here.

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