# What is a good data structure to represent an undirected graph?

I need to construct an undirected graph. I don't need it to do anything too fancy, but ideally it would work like this:

structure UDG = UndirectedGraph
val g = UDG.empty
val g = UDG.addEdges(g, n1, [n2, n4, n7]) (* n1 is connected to n2, n4, and n7 *)
val g = UDG.addEdge(g, n2, n3)
UDG.connected(g, n2) (* returns [n1, n3] *)


Is there a good data structure in SML/NJ to model these relationships? Should I just roll my own?

I've gone ahead and tried rolling my own, but I get a type mismatch error when I try to test it. My experience with SML structures and functors is pretty basic, so I think I'm doing something obviously wrong. How do I get this to work? Also, can you help me make this an 'a graph? That seems to make more sense, semantically.

## Code

signature ORD_NODE =
sig
type node
val compare : node * node -> order
val format : node -> string
end

signature GRAPH =
sig
structure Node : ORD_NODE
type graph
val empty : graph

(* val addEdge : graph * Node.node * Node.node -> graph
*  addEdge (g, x, y) => g with an edge added from x to y. *)
val addEdge : graph * Node.node * Node.node -> graph

val format : graph -> string
end

functor UndirectedGraphFn (Node : ORD_NODE) :> GRAPH =
struct
structure Node = Node
structure Key = struct
type ord_key = Node.node
val compare = Node.compare
end
structure Map = BinaryMapFn(Key)

type graph = Node.node list Map.map (* Adjacency list *)
val empty = Map.empty

fun addEdge (g, x, y) = (* snip *)
fun format g = (* snip *)
end

structure UDG = UndirectedGraphFn(struct
type node = int
val compare = Int.compare
val format = Int.toString
end)


## Error

When I do

structure UDG = UndirectedGraphFn(struct
type node = int
val compare = Int.compare
val format = Int.toString
end)

UDG.addEdge (UDG.empty,1,2)
I get a type mismatch:
Error: operator and operand don't agree [literal]
operator domain: UDG.graph * ?.UDG.node * ?.UDG.node
operand:         UDG.graph * int * int
in expression:

-
hmm in your error message, it says 'UDG.addEdge (UDG.empty..... perhaps its trying to multiply the string 'empty' by UDG.node? sorry not familiar with SML –  Darknight Sep 15 '09 at 14:42

There are several possibilities with differing pros and cons suited to different operations on the graphs. This nice intro gives background and examples of using Adjacency Lists and Adjacency Matrices.

Using them in an undirected fashion involves trade offs (space verses speed). this course material goes into more detail on the adjacency list style and provides some thoughts on the possible alterations for use in undirected usage.

-
would the -1 care to give an indication as to why? –  ShuggyCoUk Sep 15 '09 at 13:25
I'm sorry but I voted down your answer so it wouldn't get auto-accepted. Not that it isn't helpful, it's just that it I don't think it (or the other answers) deserve to be accepted yet. If you go ahead and edit it I will retract my -1. –  Andrew Keeton Sep 15 '09 at 23:12
Fair enough, I don't have much to offer on your error message I'm afraid, SML isn't my forte though I would ask why you rolled your own over using the ones supplied in the linked paper... –  ShuggyCoUk Sep 16 '09 at 7:53
I feel like an ass for not looking at your links; I just assumed they were the standard adjacency list vs matrix stuff. Even though they're not exactly what I was looking for, they were still helpful. –  Andrew Keeton Sep 16 '09 at 10:01
cool, glad it helped –  ShuggyCoUk Sep 16 '09 at 14:06

OK I'm not familiar with this language (please pardon my ignorance):

I'd simply use the following structure:

V.E1.E2.En+1
V2.E1.E2.En+1
Vn+1.E1.E2.En+1


so basically the first digit before the decimal would represent the Vertice, and each Edge would be represented followed by a decimal point (kind of like an IP address)

such that:

could be stored as:

1.2.5

2.1.5.3

3.2.4

4.3.5.6

5.1.2.4

6.4

Then in your code, its simple to add/delete edges, and very easy to parse (because the vertice is always the first number)

-
This is actually a pretty nifty idea. Especially if the data structure is to be filled first, and then used for visualization purposes. I'm doing a hobby project that aims to create such a visualization and I'll definitely try this approach. –  manneorama May 9 '11 at 10:47

A really easy one would be a hashtable, with the key as the source node, and the value as a list of connecting nodes. Then write an add function that does two hashtable insertions, one as (src, tgt), the other as (tgt, src).

In ocaml:

let add n1 n2 =
let aux n1 n2 =
match Hashtbl.find_option tbl n1 with
| None -> Hashtbl.add tbl n1 [n2]
| Some nodes -> Hashtbl.replace tbl n1 (n2::nodes)
in
let _ = aux n1 n2 in
aux n2 n1


This would be a directed graph, it's just you would add both directions on insert. The hashtable lookup function will act as your connected function.

(Actually, in Ocaml hashtables offer multiple values for a key, so you could just use the Hashtbl.find_all function and save the list. But this is the easiest to translate into SML.)

-