# Discrete logarithm algorithm

I've often seen that the discrete logarithm is a hard problem. However, I don't quite see how this could be. It seems to me that a regular binary search would do just fine to serve this purpose. For example,

``````binary_search(base, left, right, target) {
if (pow(base, left) == target)
return left;
if (pow(base, right) == target)
return right;
if (pow(base, (left + right) / 2) < target)
return binary_search(base, (left + right) / 2, right, target);
else
return binary_search(base, left, (left + right) / 2, target);
}

log(base, number) {
left = 1;
right = 2;
while(pow(base, p) < number) {
left = right;
right *= 2;
}
return binary_search(base, left, right, number);
}
``````

If the naive implementation of just incrementing `p` until `pow(base, p)` is O(n), then surely this binary search is O(log(n) ^2).

Or do I not understand how this algorithm is measured?

Edit: I don't usually write binary searches, so if there's some trivial implementation error, kindly just ignore it or edit in a fix.

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What’s the complexity of `pow`? –  Josh Lee Dec 17 '11 at 19:05
@JoshLee: Logarithmic in the power, at most. –  Puppy Dec 17 '11 at 19:06
Try this one en.wikipedia.org/wiki/Baby-step_giant-step –  kilotaras Dec 17 '11 at 19:27