Okay, so I am actually working on this one for homework. *Recursive solutions implement - or use - a base case against which the need to continue is determined*. Now, you might say, "What on Earth does that mean?" Well, in laymen's terms, it means we can simplify our code (and, in the real world, save our software some overhead) - about which I will explain, later. Now, a part of the issue is understanding some basic math, namely, **a negative plus a negative is a negative** or **minus a positive** ( -1 + -1 = -2) depending upon the math teacher to whom you speak (we'll see that come into play in the code, below).

Now, there **is** some debate to be had, here. About which I will write, later.

Here is my code:

```
public static int multiply(int a, int b)
{
if (a == 0)
{
return result;
}
else if (a < 0) // Here, we only test to see whether the first param.
// is a negative
{
return -b + multiply(a + 1, b); // Here, remember, neg. + neg. is a neg.
} // so we force b to be negative.
else
{
result = result + b;
return multiply(Math.abs(a - 1), b);
}
}
```

Notice there are a two things done differently, here:

The code above does not test the second parameter to see whether the second parameter is negative (`a < 0`

) because of the mathematical principle in the first paragraph (see **bold text** in first paragraph). Essentially, if I know I am multiplying (*y*) by a negative number (*-n*), I know I am taking *-n* and adding it together *y* number of times; therefore, if the multiplicand or multiplier is negative, I know I can take either of the numbers, make the number negative, and add the number to itself over and over again, e.g. -3 * 7 could be written (-3) + (-3) + (-3) + (-3)... etc. *OR* (-7) + (-7) + (-7)

**NOW HERE IS WHAT'S UP FOR DEBATE:** That above code does not test to see whether the second number (`int b`

) is `0`

, i.e. multiplying by `0`

. Why? Well, that's personal choice (sort of). The debate here must weigh the relative significance of something: the overhead for each choice (of either running an equals-zero test or not). If we *do* test to see if one side is zero, each time the recursive call to multiply is made, the code must evaluate the expression; however, if we do *not* test for equals zero, then the code adds a bunch of zeros together *n* number of times. In reality, both methods "weigh" the same - so, to save memory, I leave out the code.

`one or both being negative.`

– Nandkumar Tekale Oct 5 '12 at 7:07