# What is an efficient way to create an adjacency list using STL in C++?

I currently use a vector of vectors like following:

``````typedef pair<int, int> vertex;
vector < vector<vertex> > adj_list(n); // n is number of vertices

// Input graph
for (int i = 0; i < edges; i++ )
{
cin >> source >> target >> weight;
vertex v(target, weight);
}
``````

Is vector of list ie.

``````vector < list<vertex> > adj_list(n);
``````

a better option? If yes, why? My primary concern is creating the adjacency list efficiently, and to be able to read all the vertices connected to a particular vertex fast, for implementing Dijkstra's algorithm.

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Allocation-once would be good idea. So this is better : `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
@Nawaz: looking at the code `edges` is the total number 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
Dijsktra's algorithm requires a priority queue, not a list. (I believe it is the reason Fibonacci heaps were invented...) You can use a `std::priority_queue` to get reasonable performance, or roll your own Fibonacci heap implementation –  Nemo Dec 31 '12 at 20:42

For that I would use std::deque<>, since you most likely don't need to remove elements from the middle (which is why someone would ever want to use std::list<>). It should be more efficient than std::vector<> or std::list<>. Having contiguous memory (vector) and removable items (list) has it's price - costly resizes for vector and pointer dereferencing/scattered memory for list.

Note that if you are targeting algorithmic contests, you may be surprised how much memory such STL based data structure can take.

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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.

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`push_back` on `std::vector` is O(1), not (log n) amortized time. –  Nemo Dec 31 '12 at 20:40
`push_back` will cause reallocation when the capacity of a vector is surpassed. Reallocation takes `O(n)` time, because it has to copy the list to the newly reallocated storage. Reallocation only happens `O(log n)` times when you're inserting `n` elements, because the capacity is increased exponentially. If you amortize the total cost `O(n log n)` over every element, you'll see that `push_back` costs `O(log n)` (amortized) time per element. –  Rhymoid Dec 31 '12 at 20:51
Yes, reallocation happens O(log n) times, but each time is twice as large as the previous, so the total work is much smaller. The total is O(n + n/2 + n/4 + ... + 1), which O(n), not O(n log n)... Which is O(1) per element amortized. Trust me on this; you are mistaken. Read any reference for std::vector (including the standard). –  Nemo Dec 31 '12 at 20:54
Ah, yes, I stand corrected: n+n/2+n/4+...+1 < n(1/1+1/2+1/4+...) = n. I'll change my answer. –  Rhymoid Dec 31 '12 at 21:01
I already suspected that my assumption about the cost of reallocation was wrong in some way ;) –  Rhymoid Dec 31 '12 at 21:15