**EDIT**

So it seems I "underestimated" what varying length numbers meant. I didn't even think about situations where the operands are 100 digits long. In that case, my proposed algorithm is definitely not efficient. I'd probably need an implementation who's complexity depends on the # of digits in each operands as opposed to its numerical value, right?

As suggested below, I will look into the Karatsuba algorithm...

*Write the pseudocode of an algorithm that takes in two arbitrary length numbers (provided as strings), and computes the product of these numbers. Use an efficient procedure for multiplication of large numbers of arbitrary length. Analyze the efficiency of your algorithm.*

I decided to take the (semi) easy way out and use the Russian Peasant Algorithm. It works like this:

```
a * b = a/2 * 2b if a is even
a * b = (a-1)/2 * 2b + a if a is odd
```

My pseudocode is:

```
rpa(x, y){
if x is 1
return y
if x is even
return rpa(x/2, 2y)
if x is odd
return rpa((x-1)/2, 2y) + y
}
```

I have 3 questions:

- Is this efficient for arbitrary length numbers? I implemented it in C and tried varying length numbers. The run-time in was near-instant in all cases so it's hard to tell empirically...
- Can I apply the Master's Theorem to understand the complexity...?
- a = # subproblems in recursion = 1 (max 1 recursive call across all states)
- n / b = size of each subproblem = n / 1 -> b = 1 (problem doesn't change size...?)
- f(n^d) = work done outside recursive calls = 1 -> d = 0 (the addition when a is odd)
- a = 1, b^d = 1, a = b^d ->
**complexity is in n^d*log(n) = log(n)** - this makes sense logically since we are halving the problem at each step, right?

- What might my professor mean by providing arbitrary length numbers "as strings". Why do that?

Many thanks in advance