There are a lot of interesting concerns going on here. Let me attack them all.

You're reading in the data just fine for a line-oriented language. Later on you'll see `Data.ByteString`

and `Data.Text`

replace `String`

for efficiency. You'll also see `Parsec`

for parsing. Those can wait, though. Revisit them in time.

Your graph representation is fine. Adjacency lists are a common and useful representation.

Now, the real trick you have is here. Let's take a look at `addNode`

and `addEdge`

. Each is a somewhat challenging function to produce in a pure functional language because they want to *modify* a graph... but we don't have state.

The most important way to modify-without-state is to mutate. The kind of function you're looking for is thus

```
addNode :: Node -> Graph -> Graph
```

where the returned `Graph`

is identical to the input `Graph`

except with one more edge. You should note immediately that there's something wrong here---adjacency lists assume that there are no orphan nodes. We can't add just a single node to the graph.

There are two solutions. One, we could "link" the node in to the graph (which is really `addEdge`

in disguise) or two we could extend the graph representation to include orphan nodes. Let's do (2).

```
data Graph = Graph [Edge] [Int] -- orphans
```

Now let's implement adding an edge. Assume you can have duplicate edges, adding an edge to the adjacency list is easy, just append it

```
addEdge0 :: Edge -> Graph -> Graph
addEdge0 e (Graph adj orph) = Graph (e:adj) orph
```

but that's not good enough---we want our orphan list to only include truly orphaned nodes. We'll filter it.

```
addEdge :: Edge -> Graph -> Graph
addEdge (n1,n2) (Graph adj orph) =
Graph ((n1,n2):adj) (filter (/=n1) . filter (/=n2) $ orph)
```

`getEdges`

is trivial since we're already storing the list of edges

```
getEdges :: Graph -> [Edge]
getEdges (Graph edges _) = edges
```

`getNodes`

just needs to append all of our nodes from the adjacency list to the orphan list. We could use `Data.List.nub`

to get only the unique nodes.

```
getNodes :: Graph -> [Int]
getNotes (Graph adj orph) = nub (orph ++ adjNodes adj) where
adjNodes [] = []
adjNodes ((n1,n2):rest) = n1 : n2 : adjNodes rest
```

Hopefully these give you some indication of how to think in a functional language. You'll hava to dig into them a little bit to see how they work, but I've introduced a large number of interesting concepts here.

Next steps here might include trying to use the `State`

monad to recapture imperative state modification and to chain these `Graph`

-modifying functions together.