I know I'm a year late to the thread, but I don't believe any of these answers are correct. OP mentioned in the comments that the edges are unweighted; in this case, the best algorithm runs in $O(n^{\omega}) \log n$ time (where $\omega$ is the exponent for matrix multiplication; currently upper bounded at $2.373$ by Virginia Williams).

The algorithm exploits the following property of unweighted graphs. Let $A$ be the adjacency matrix of the graph with an added self-loop for each node. Then $(A^k)_{ij}$ is nonzero iff $d(i, j) \le k$. We can use this fact to find the graph diameter by computing $\log n$ values of $A^k$.

Here's how the algorithm works: let $A$ be the adjacency matrix of the graph with an added self loop for each node. Set $M_0 = A$. While $M_k$ contains at least one zero, compute $M_{k+1} = M_{k}^2$.

Eventually, you find a matrix $M_{K}$ with all nonzero entries. We know that $K \le \log n$ by the property discussed above; therefore, we have performed matrix multiplication only $O(\log n)$ times so far. We can now continue by binary searching between $M_{K} = A^{2^K}$ and $M_{K-1} = A^{2^{K-1}}$. Set $B = M_{K-1}$ as follows.

Set DIAMETER = $2^{k-1}$. For $i = (K-2 \dots 0)$, perform the following test:

Multiply $B$ by $M_{i}$ and check the resulting matrix for zeroes. If we find any zeroes, then set $B$ to this matrix product, and add $2^i$ to DIAMETER. Otherwise, do nothing.

Finally, return DIAMETER.

As a minor implementation detail, it might be necessary to set all nonzero entries in a matrix to $1$ after each matrix multiplication is performed, so that the values don't get too large and unwieldy to write down in a small amount of time.

`O(log n * (n + e)`

complexity? – omega Mar 26 '13 at 20:14