Abstract type of graphs

Vertices have type V.t and are labeled with type V.label (note that an implementation may identify the vertex with its label)

Edges have type E.t and are labeled with type E.label. src (resp. dst) returns the origin (resp. the destination) of a given edge.

Is this an implementation of directed graphs?

out_degree g v returns the out-degree of v in g.

• raises Invalid_argument

  if v is not in g.

in_degree g v returns the in-degree of v in g.

• raises Invalid_argument

  if v is not in g.

find_edge g v1 v2 returns the edge from v1 to v2 if it exists. Unspecified behaviour if g has several edges from v1 to v2.

• raises Not_found

  if no such edge exists.

find_all_edges g v1 v2 returns all the edges from v1 to v2.

• since ocamlgraph 1.8

succ g v returns the successors of v in g.

• raises Invalid_argument

  if v is not in g.

pred g v returns the predecessors of v in g.

• raises Invalid_argument

  if v is not in g.

succ_e g v returns the edges going from v in g.

• raises Invalid_argument

  if v is not in g.

pred_e g v returns the edges going to v in g.

• raises Invalid_argument

  if v is not in g.

Iter on all vertices of a graph.

Fold on all vertices of a graph.

Iter on all edges of a graph. Edge label is ignored.

Fold on all edges of a graph. Edge label is ignored.

Iter on all edges of a graph.

Fold on all edges of a graph.

Map on all vertices of a graph.

The current implementation requires the supplied function to be injective. Said otherwise, map_vertex cannot be used to contract a graph by mapping several vertices to the same vertex. To contract a graph, use instead create, add_vertex, and add_edge.

create () returns an empty graph. Optionally, a size can be given, which should be on the order of the expected number of vertices that will be in the graph (for hash tables-based implementations). The graph grows as needed, so size is just an initial guess.

Remove all vertices and edges from the given graph.

• since ocamlgraph 1.4

copy g returns a copy of g. Vertices and edges (and eventually marks, see module Mark) are duplicated.

add_vertex g v adds the vertex v to the graph g. Do nothing if v is already in g.

remove g v removes the vertex v from the graph g (and all the edges going from v in g). Do nothing if v is not in g.

<b>Time complexity for ocamlgraph implementations:</b> O(|V|*ln(D)) for unlabeled graphs and O(|V|*D) for labeled graphs. D is the maximal degree of the graph.

add_edge g v1 v2 adds an edge from the vertex v1 to the vertex v2 in the graph g. Add also v1 (resp. v2) in g if v1 (resp. v2) is not in g. Do nothing if this edge is already in g.

add_edge_e g e adds the edge e in the graph g. Add also E.src e (resp. E.dst e) in g if E.src e (resp. E.dst e) is not in g. Do nothing if e is already in g.

remove_edge g v1 v2 removes the edge going from v1 to v2 from the graph g. If the graph is labelled, all the edges going from v1 to v2 are removed from g. Do nothing if this edge is not in g.

• raises Invalid_argument

  if v1 or v2 are not in g.

remove_edge_e g e removes the edge e from the graph g. Do nothing if e is not in g.

• raises Invalid_argument

  if E.src e or E.dst e are not in g.

add_transitive_closure ?reflexive g replaces g by its transitive closure. Meaningless for persistent implementations (then acts as transitive_closure).

transitive_reduction ?reflexive g returns the transitive reduction of g (as a new graph). This is a subgraph of g with the same transitive closure as g. When g is acyclic, its transitive reduction contains as few edges as possible and is unique. Loops (i.e. edges from a vertex to itself) are removed only if reflexive is true (default is false). Note: Only meaningful for directed graphs.

replace_by_transitive_reduction ?reflexive g replaces g by its transitive reduction. Meaningless for persistent implementations (then acts as transitive_reduction).

mirror g returns a new graph which is the mirror image of g: each edge from u to v has been replaced by an edge from v to u. For undirected graphs, it simply returns g. Note: Vertices are shared between g and mirror g; you may need to make a copy of g before using mirror

complement g returns a new graph which is the complement of g: each edge present in g is not present in the resulting graph and vice-versa. Edges of the returned graph are unlabeled.

intersect g1 g2 returns a new graph which is the intersection of g1 and g2: each vertex and edge present in g1 *and* g2 is present in the resulting graph.

union g1 g2 returns a new graph which is the union of g1 and g2: each vertex and edge present in g1 *or* g2 is present in the resulting graph.