What you have in mind is called **memoization**: A pure function (i.e. a function whose return value depends only on the argument values) can remember the result for arguments that it has previously encountered.

Memoization is performed by some high-level special-purpose languages like Maple. However, general-purpose languages don't have this (rather complex) behaviour by default.

However, in your case this isn't necessary. Rather than using recursion, your algorithm is better implemented as *iteration*. Binary exponentiation by repeated squaring is the standard algorithm.

Here's some C-like pseudo-code (my Java isn't 100%):

```
// compute pow(base, exponent)
int result = 1;
int term = base;
while (exponent != 0)
{
if (exponent % 2 != 0) { result *= term; }
term = term * term;
exponent /= 2;
}
return result;
```

For some examples, 7 is 111 in binary, so *b*^{7} = *b*^{1} × *b*^{2} × *b*^{4}, and we only need to keep track of *one* copy of the running term. Another one: 5 = 101b, so *b*^{5} = *b*^{1} × 1 × *b*^{4}.

_{In C++ it's quite easy to build a generic memoizing wrapper for any function R f(T1, T2, ..., TN) that stores the memory in a hash map std::unordered_map<std::tuple<T1, ..., TN>, R>; upon invocation the wrapper checks if the argument-tuple already exists, and if yes, it returns the value from the map, and if no it performs the computation and inserts the result into the map. I'm sure something similar can be rigged up in Java.}

`power`

was nondeterministic? – Jeffrey Nov 26 '11 at 2:22