**objects and pointers**

These are just basic datastructures like hammar said in the other answer, in `Java`

you would represent this with classes like edges and vertices. For example an edge connects two vertices and can either be directed or undirected and it can contain a weight. A vertex can have an ID, name etc. Mostly both of them have additional properties. So you can construct your graph with them like

```
Vertex a = new Vertex(1);
Vertex b = new Vertex(2);
Edge edge = new Edge(a,b, 30); // init an edge between ab and be with weight 30
```

This approach is commonly used for object oriented implementations, since it is more readable and convenient for object oriented users ;).

**matrix**

A matrix is just a simple 2 dimensional array. Assuming you have vertex ID's that can be represented as an int array like this:

```
int[][] adjacencyMatrix = new int[SIZE][SIZE]; // SIZE is the number of vertices in our graph
adjacencyMatrix[0][1] = 30; // sets the weight of a vertex 0 that is adjacent to vertex 1
```

This is commonly used for dense graphs where index access is necessary. You can represent a un/directed and weighted structure with this.

**adjacency list**

This is just a simple datastructure mix, I usually implement this using a `HashMap<Vertex, List<Vertex>>`

. Similar used can be the `HashMultimap`

in Guava.

This approach is cool, because you have O(1) (amortized) vertex lookup and it returns me a list of all adjacent vertices to this particular vertex I demanded.

```
ArrayList<Vertex> list = new ArrayList<>();
list.add(new Vertex(2));
list.add(new Vertex(3));
map.put(new Vertex(1), list); // vertex 1 is adjacent to 2 and 3
```

This is used for representing sparse graphs, if you are applying at Google, you should know that the webgraph is sparse. You can deal with them in a more scalable way using a BigTable.

Oh and BTW, here is a very good summary of this post with fancy pictures ;)