To answer your question, "What is the main difference between a list representation and matrix representation of a matrix?"

A **list representation** of a graph is usually a list of tuples, where each element of the list is a node, and the tuples are the nodes connected to it. Say we have 3 nodes `A`

, `B`

, `C`

, so we will have a list of length 3. Say there is a node from `A`

->`B`

, then element in the `A`

th position, say the first element, will contain the node `B`

. Say there is also a link from `A`

->`C`

, the first element will contain `B`

and `C`

. The total space required for an adjacency list is (space to represent a node) * (number of edges).

On the other hand, a **matrix representation** is a matrix, usually implemented as a 2-d array, where every node is listed on both the row and column axis. If there is a link between 2 nodes, then mark that spot in the matrix. For example, if we have 3 nodes `A`

, `B`

, `C`

, we have a 3x3 array `array`

. Let's call `A`

=index `0`

, `B`

=index `1`

, `C`

=index `2`

, and suppose we have a link from `A`

-> `B`

, then fill in a `1`

at `array[0][1]`

. If our graph was undirected, we'd also add a `1`

to the spot at `array[1][0]`

. Total space required is the number of nodes N^2 times the space required by each link (can be done with 1 bit, `0`

or `1`

), so total = N^2.

A list is good for **sparse** graphs because it doesn't require any extra storage. That is, links that don't exist aren't represented by anything. By contrast, if our graph is very dense, then a **matrix** representation is better because every possible link is denoted by only 1 bit (0 or 1). As you can see from the examples above, the total space required by a list representation is a **function of the number of edges**, while the space for a matrix representation is a **function of the number of nodes**.

Now think about your specific problem. How many total nodes would you have? Total edges? Does that seem sparse or dense?