Your demand is fast insertion and fast iteration. Asymptotically, there is no difference between `vector<vector<T> >`

and `vector<list<T> >`

:

`list<T>`

is a doubly linked list, so every insert takes `O(1)`

time, and iteration takes `O(1)`

time per element.
`vector<T>`

is an array, implemented such that every insert takes `O(1)`

(amortized) time[1], and iteration takes `O(1)`

time per element.

The constants for the operations are probably different, but that's something you have to find out through profiling.

However, spatial efficiency would favour `vector<vector<T> >`

, because every element in `vector<list<T> >`

also carries a forward and backward pointer. So you probably want to use `vector<vector<T> >`

, but in a way that you avoid the reallocations in the common case (to save time), but don't reserve too much (to save space).

For the outer vector, you can just call `.reserve(n)`

on it, where `n`

is the number of vertices in the graph.

For the inner vector, it's a bit harder, and it really depends on how your data is fed to this procedure.

[1] An implementation of `vector<T>`

should double its capacity every time it reallocates, so the time taken by reallocation is `O(1+2+4+...+n/4+n/2+n) = O(n(1/n+2/n+4/n+...+1/4+1/2+1)) <= O(1+1/2+1/4+...)) = O(2n)`

. So distributed over `n`

elements, insertion takes `O(1)`

(amortized) time.

`vector< vector<vertex>> adj_list(n, vector<vertex>(edges));`

– Nawaz Dec 31 '12 at 20:02`vector<vector<vertex>>`

is probably best but the only way to know for sure is to benchmark your application using different options. – David Brown Dec 31 '12 at 20:02`edges`

is thetotalnumber of edges in the graph. You don't want each list associated to a vertex to be that big. – 6502 Dec 31 '12 at 20:26`std::priority_queue`

to get reasonable performance, or roll your own Fibonacci heap implementation – Nemo Dec 31 '12 at 20:42