What is better, adjacency lists or adjacency matrix, for graph problems in C++? What are the advantages and disadvantages of each?
It depends on the problem.
- Uses O(n^2) memory
- It is fast to lookup and check for presence or absence of a specific edge
between any two nodes O(1)
- It is slow to iterate over all edges
- It is slow to add/delete a node; a complex operation O(n^2)
- It is fast to add a new edge O(1)
- Memory usage depends on the number of edges (not number of nodes),
which might save a lot of memory if the adjacency matrix is sparse
- Finding the presence or absence of specific edge between any two nodes
is slightly slower than with the matrix O(k); where k is the number of neighbors nodes
- It is fast to iterate over all edges because you can access any node neighbors directly
- It is fast to add/delete a node; easier than the matrix representation
- It fast to add a new edge O(1)
This answer is not just for C++ since everything mentioned is about the data structures themselves, regardless of language. And, my answer is assuming that you know the basic structure of adjacency lists and matrices.
If memory is your primary concern you can follow this formula for a simple graph that allows loops:
An adjacency matrix occupies n2/8 byte space (one bit per entry).
An adjacency list occupies 8e space, where e is the number of edges (32bit computer).
If we define the density of the graph as d = e/n2 (number of edges divided by the maximum number of edges), we can find the "breakpoint" where a list takes up more memory than a matrix:
8e > n2/8 when d > 1/64
So with these numbers (still 32-bit specific) the breakpoint lands at 1/64. If the density (e/n2) is bigger than 1/64, then a matrix is preferable if you want to save memory.
You can read about this at wikipedia (article on adjacency matrices) and a lot of other sites.
Side note: One can improve the space-efficiency of the adjacency matrix by using a hash table where the keys are pairs of vertices (undirected only).
Iteration and lookup
Adjacency lists are a compact way of representing only existing edges. However, this comes at the cost of possibly slow lookup of specific edges. Since each list is as long as the degree of a vertex the worst case lookup time of checking for a specific edge can become O(n), if the list is unordered. However, looking up the neighbours of a vertex becomes trivial, and for a sparse or small graph the cost of iterating through the adjacency lists might be negligible.
Adjacency matrices on the other hand use more space in order to provide constant lookup time. Since every possible entry exists you can check for the existence of an edge in constant time using indexes. However, neighbour lookup takes O(n) since you need to check all possible neighbours. The obvious space drawback is that for sparse graphs a lot of padding is added. See the memory discussion above for more information on this.
If you're still unsure what to use: Most real-world problems produce sparse and/or large graphs, which are better suited for adjacency list representations. They might seem harder to implement but I assure you they aren't, and when you write a BFS or DFS and want to fetch all neighbours of a node they're just one line of code away. However, note that I'm not promoting adjacency lists in general.
Okay, I've compiled the Time and Space complexities of basic operations on graphs.
The image below should be self-explanatory.
Notice how Adjacency Matrix is preferable when we expect the graph to be dense, and how Adjacency List is preferable when we expect the graph to be sparse.
I've made some assumptions. Ask me if a complexity (Time or Space) needs clarification. (For example, For a sparse graph, I've taken En to be a small constant, as I've assumed that addition of a new vertex will add only a few edges, because we expect the graph to remain sparse even after adding that vertex.)
Please tell me if there are any mistakes.
It depends on what you're looking for.
With adjacency matrices you can answer fast to questions regarding if a specific edge between two vertices belongs to the graph, and you can also have quick insertions and deletions of edges. The downside is that you have to use excessive space, especially for graphs with many vertices, which is very inefficient especially if your graph is sparse.
On the other hand, with adjacency lists it is harder to check whether a given edge is in a graph, because you have to search through the appropriate list to find the edge, but they are more space efficient.
Generally though, adjacency lists are the right data structure for most applications of graphs.
Lets assume we have a graph which has n number of nodes and m number of edges,
Adjacency Matrix: We are creating a matrix that has n number of rows and columns so in memory it will take space that is proportional to n2. Checking if two nodes named as u and v has an edge between them will take Θ(1) time. For example checking for (1, 2) is an edge will look like as follows in the code:
if(matrix == 1)
If you want to identify all edges, you have to iterate over matrix at this will require two nested loops and it will take Θ(n2). (You may just use the upper triangular part of the matrix to determine all edges but it will be again Θ(n2))
Adjacency List: We are creating a list that each node also points to another list. Your list will have n elements and each element will point to a list that has number of items that is equal to number of neighbors of this node (look image for better visualization). So it will take space in memory that is proportional to n+m. Checking if (u, v) is an edge will take O(deg(u)) time in which deg(u) equals number of neighbors of u. Because at most, you have to iterate over the list that is pointed by the u. Identifying all edges will take Θ(n+m).
Adjacency list of example graph
If you are looking at graph analysis in C++ probably the first place to start would be the boost graph library, which implements a number of algorithms including BFS.
This previous question on SO will probably help:
This is best answered with examples.
Think of Floyd-Warshall for example. We have to use an adjacency matrix, or the algorithm will be asymptotically slower.
Or what if it's a dense graph on 30,000 vertices? Then an adjacency matrix might make sense, as you'll be storing 1 bit per pair of vertices, rather than the 16 bits per edge (the minimum that you would need for an adjacency list): that's 107 MB, rather than 1.7 GB.
But for algorithms like DFS, BFS (and those that use it, like Edmonds-Karp), Priority-first search (Dijkstra, Prim, A*), etc., an adjacency list is as good as a matrix. Well, a matrix might have a slight edge when the graph is dense, but only by an unremarkable constant factor. (How much? It's a matter of experimenting.)
To add to keyser5053's answer about memory usage.
For any directed graph, an adjacency matrix (at 1 bit per edge) consumes
n^2 * (1) bits of memory.
For a complete graph, an adjacency list (with 64 bit pointers) consumes
n * (n * 64) bits of memory, excluding list overhead.
For an incomplete graph, an adjacency list consumes
0 bits of memory, excluding list overhead.
For an adjacency list, you can use the follow formula to determine the maximum number of edges (
e) before an adjacency matrix is optimal for memory.
edges = n^2 / s to determine the maximum number of edges, where
s is the pointer size of the platform.
If you're graph is dynamically updating, you can maintain this efficiency with an average edge count (per node) of
n / s.
Some examples with 64 bit pointers and dynamic graph (A dynamic graph updates the solution of a problem efficiently after changes, rather than recomputing it from scratch each time after a change has been made.)
For a directed graph, where
n is 300, the optimal number of edges per node using an adjacency list is:
= 300 / 64 = 4
If we plug this into keyser5053's formula,
d = e / n^2 (where
e is the total edge count), we can see we are below the break point (
1 / s):
d = (4 * 300) / (300 * 300) d < 1/64 aka 0.0133 < 0.0156
However, 64 bits for a pointer can be overkill. If you instead use 16bit integers as pointer offsets, we can fit up to 18 edges before breaking point.
= 300 / 16 = 18 d = ((18 * 300) / (300^2)) d < 1/16 aka 0.06 < 0.0625
Each of these examples ignore the overhead of the adjacency lists themselves (
64*2 for a vector and 64 bit pointers).
If you use a hash table instead of either adjacency matrix or list, you'll get better or same big-O run-time and space for all operations (checking for an edge is
O(1), getting all adjacent edges is
There's some constant factor overhead though for both run-time and space (hash table isn't as fast as linked list or array lookup, and takes a decent amount extra space to reduce collisions).
I am just going to touch on overcoming the trade-off of regular adjacency list representation, since other answers have covered other aspects.
It is possible to represent a graph in adjacency list with EdgeExists query in amortized constant time, by taking advantage of Dictionary and HashSet data structures. The idea is to keep vertices in a dictionary, and for each vertex, we keep a hash set referencing to other vertices it has edges with.
One minor trade-off in this implementation is that it will have space complexity O(V + 2E) instead of O(V + E) as in regular adjacency list, since edges are represented twice here (because each vertex have its own hash set of edges). But operations such as AddVertex, AddEdge, RemoveEdge can be done in amortized time O(1) with this implementation, except for RemoveVertex which takes O(V) like adjacency matrix. This would mean that other than implementation simplicity, adjacency matrix don't have any specific advantage. We can save space on sparse graph with almost the same performance in this adjacency list implementation.
Take a look at implementations below in Github C# repository for details. Note that for weighted graph it uses a nested dictionary instead of dictionary-hash set combination so as to accommodate weight value. Similarly for directed graph there is separate hash sets for in & out edges.
Note: I believe using lazy deletion we can further optimize RemoveVertex operation to O(1) amortized, even though I haven't tested that idea. For example, upon deletion just mark the vertex as deleted in dictionary, and then lazily clear orphaned edges during other operations.