%% %% %CopyrightBegin% %% %% Copyright Ericsson AB 1996-2016. All Rights Reserved. %% %% Licensed under the Apache License, Version 2.0 (the "License"); %% you may not use this file except in compliance with the License. %% You may obtain a copy of the License at %% %% http://www.apache.org/licenses/LICENSE-2.0 %% %% Unless required by applicable law or agreed to in writing, software %% distributed under the License is distributed on an "AS IS" BASIS, %% WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. %% See the License for the specific language governing permissions and %% limitations under the License. %% %% %CopyrightEnd% %% -module(digraph). -export([new/0, new/1, delete/1, info/1]). -export([add_vertex/1, add_vertex/2, add_vertex/3]). -export([del_vertex/2, del_vertices/2]). -export([vertex/2, no_vertices/1, vertices/1]). -export([source_vertices/1, sink_vertices/1]). -export([add_edge/3, add_edge/4, add_edge/5]). -export([del_edge/2, del_edges/2, del_path/3]). -export([edge/2, no_edges/1, edges/1]). -export([out_neighbours/2, in_neighbours/2]). -export([out_edges/2, in_edges/2, edges/2]). -export([out_degree/2, in_degree/2]). -export([get_path/3, get_cycle/2]). -export([get_short_path/3, get_short_cycle/2]). -export_type([graph/0, d_type/0, vertex/0, edge/0, label/0]). -record(digraph, {vtab = notable :: ets:tab(), etab = notable :: ets:tab(), ntab = notable :: ets:tab(), cyclic = true :: boolean()}). -opaque graph() :: #digraph{}. -type edge() :: term(). -type label() :: term(). -type vertex() :: term(). -type add_edge_err_rsn() :: {'bad_edge', Path :: [vertex()]} | {'bad_vertex', V :: vertex()}. %% %% Type is a list of %% protected | private %% acyclic | cyclic %% %% default is [cyclic,protected] %% -type d_protection() :: 'private' | 'protected'. -type d_cyclicity() :: 'acyclic' | 'cyclic'. -type d_type() :: d_cyclicity() | d_protection(). -spec new() -> graph(). new() -> new([]). -spec new(Type) -> graph() when Type :: [d_type()]. new(Type) -> case check_type(Type, protected, []) of {Access, Ts} -> V = ets:new(vertices, [set, Access]), E = ets:new(edges, [set, Access]), N = ets:new(neighbours, [bag, Access]), ets:insert(N, [{'$vid', 0}, {'$eid', 0}]), set_type(Ts, #digraph{vtab=V, etab=E, ntab=N}); error -> erlang:error(badarg) end. %% %% Check type of graph %% %-spec check_type([d_type()], d_protection(), [{'cyclic', boolean()}]) -> % {d_protection(), [{'cyclic', boolean()}]}. check_type([acyclic|Ts], A, L) -> check_type(Ts, A,[{cyclic,false} | L]); check_type([cyclic | Ts], A, L) -> check_type(Ts, A, [{cyclic,true} | L]); check_type([protected | Ts], _, L) -> check_type(Ts, protected, L); check_type([private | Ts], _, L) -> check_type(Ts, private, L); check_type([], A, L) -> {A, L}; check_type(_, _, _) -> error. %% %% Set graph type %% -spec set_type([{'cyclic', boolean()}], graph()) -> graph(). set_type([{cyclic,V} | Ks], G) -> set_type(Ks, G#digraph{cyclic = V}); set_type([], G) -> G. %% Data access functions -spec delete(G) -> 'true' when G :: graph(). delete(G) -> ets:delete(G#digraph.vtab), ets:delete(G#digraph.etab), ets:delete(G#digraph.ntab). -spec info(G) -> InfoList when G :: graph(), InfoList :: [{'cyclicity', Cyclicity :: d_cyclicity()} | {'memory', NoWords :: non_neg_integer()} | {'protection', Protection :: d_protection()}]. info(G) -> VT = G#digraph.vtab, ET = G#digraph.etab, NT = G#digraph.ntab, Cyclicity = case G#digraph.cyclic of true -> cyclic; false -> acyclic end, Protection = ets:info(VT, protection), Memory = ets:info(VT, memory) + ets:info(ET, memory) + ets:info(NT, memory), [{cyclicity, Cyclicity}, {memory, Memory}, {protection, Protection}]. -spec add_vertex(G) -> vertex() when G :: graph(). add_vertex(G) -> do_add_vertex({new_vertex_id(G), []}, G). -spec add_vertex(G, V) -> vertex() when G :: graph(), V :: vertex(). add_vertex(G, V) -> do_add_vertex({V, []}, G). -spec add_vertex(G, V, Label) -> vertex() when G :: graph(), V :: vertex(), Label :: label(). add_vertex(G, V, D) -> do_add_vertex({V, D}, G). -spec del_vertex(G, V) -> 'true' when G :: graph(), V :: vertex(). del_vertex(G, V) -> do_del_vertex(V, G). -spec del_vertices(G, Vertices) -> 'true' when G :: graph(), Vertices :: [vertex()]. del_vertices(G, Vs) -> do_del_vertices(Vs, G). -spec vertex(G, V) -> {V, Label} | 'false' when G :: graph(), V :: vertex(), Label :: label(). vertex(G, V) -> case ets:lookup(G#digraph.vtab, V) of [] -> false; [Vertex] -> Vertex end. -spec no_vertices(G) -> non_neg_integer() when G :: graph(). no_vertices(G) -> ets:info(G#digraph.vtab, size). -spec vertices(G) -> Vertices when G :: graph(), Vertices :: [vertex()]. vertices(G) -> ets:select(G#digraph.vtab, [{{'$1', '_'}, [], ['$1']}]). -spec source_vertices(graph()) -> [vertex()]. source_vertices(G) -> collect_vertices(G, in). -spec sink_vertices(graph()) -> [vertex()]. sink_vertices(G) -> collect_vertices(G, out). -spec in_degree(G, V) -> non_neg_integer() when G :: graph(), V :: vertex(). in_degree(G, V) -> length(ets:lookup(G#digraph.ntab, {in, V})). -spec in_neighbours(G, V) -> Vertex when G :: graph(), V :: vertex(), Vertex :: [vertex()]. in_neighbours(G, V) -> ET = G#digraph.etab, NT = G#digraph.ntab, collect_elems(ets:lookup(NT, {in, V}), ET, 2). -spec in_edges(G, V) -> Edges when G :: graph(), V :: vertex(), Edges :: [edge()]. in_edges(G, V) -> ets:select(G#digraph.ntab, [{{{in, V}, '$1'}, [], ['$1']}]). -spec out_degree(G, V) -> non_neg_integer() when G :: graph(), V :: vertex(). out_degree(G, V) -> length(ets:lookup(G#digraph.ntab, {out, V})). -spec out_neighbours(G, V) -> Vertices when G :: graph(), V :: vertex(), Vertices :: [vertex()]. out_neighbours(G, V) -> ET = G#digraph.etab, NT = G#digraph.ntab, collect_elems(ets:lookup(NT, {out, V}), ET, 3). -spec out_edges(G, V) -> Edges when G :: graph(), V :: vertex(), Edges :: [edge()]. out_edges(G, V) -> ets:select(G#digraph.ntab, [{{{out, V}, '$1'}, [], ['$1']}]). -spec add_edge(G, V1, V2) -> edge() | {'error', add_edge_err_rsn()} when G :: graph(), V1 :: vertex(), V2 :: vertex(). add_edge(G, V1, V2) -> do_add_edge({new_edge_id(G), V1, V2, []}, G). -spec add_edge(G, V1, V2, Label) -> edge() | {'error', add_edge_err_rsn()} when G :: graph(), V1 :: vertex(), V2 :: vertex(), Label :: label(). add_edge(G, V1, V2, D) -> do_add_edge({new_edge_id(G), V1, V2, D}, G). -spec add_edge(G, E, V1, V2, Label) -> edge() | {'error', add_edge_err_rsn()} when G :: graph(), E :: edge(), V1 :: vertex(), V2 :: vertex(), Label :: label(). add_edge(G, E, V1, V2, D) -> do_add_edge({E, V1, V2, D}, G). -spec del_edge(G, E) -> 'true' when G :: graph(), E :: edge(). del_edge(G, E) -> do_del_edges([E], G). -spec del_edges(G, Edges) -> 'true' when G :: graph(), Edges :: [edge()]. del_edges(G, Es) -> do_del_edges(Es, G). -spec no_edges(G) -> non_neg_integer() when G :: graph(). no_edges(G) -> ets:info(G#digraph.etab, size). -spec edges(G) -> Edges when G :: graph(), Edges :: [edge()]. edges(G) -> ets:select(G#digraph.etab, [{{'$1', '_', '_', '_'}, [], ['$1']}]). -spec edges(G, V) -> Edges when G :: graph(), V :: vertex(), Edges :: [edge()]. edges(G, V) -> ets:select(G#digraph.ntab, [{{{out, V},'$1'}, [], ['$1']}, {{{in, V}, '$1'}, [], ['$1']}]). -spec edge(G, E) -> {E, V1, V2, Label} | 'false' when G :: graph(), E :: edge(), V1 :: vertex(), V2 :: vertex(), Label :: label(). edge(G, E) -> case ets:lookup(G#digraph.etab,E) of [] -> false; [Edge] -> Edge end. %% %% Generate a "unique" edge identifier (relative to this graph) %% -spec new_edge_id(graph()) -> edge(). -dialyzer({no_improper_lists, new_edge_id/1}). new_edge_id(G) -> NT = G#digraph.ntab, [{'$eid', K}] = ets:lookup(NT, '$eid'), true = ets:delete(NT, '$eid'), true = ets:insert(NT, {'$eid', K+1}), ['$e' | K]. %% %% Generate a "unique" vertex identifier (relative to this graph) %% -spec new_vertex_id(graph()) -> vertex(). -dialyzer({no_improper_lists, new_vertex_id/1}). new_vertex_id(G) -> NT = G#digraph.ntab, [{'$vid', K}] = ets:lookup(NT, '$vid'), true = ets:delete(NT, '$vid'), true = ets:insert(NT, {'$vid', K+1}), ['$v' | K]. %% %% Collect elements for a index in a tuple %% collect_elems(Keys, Table, Index) -> collect_elems(Keys, Table, Index, []). collect_elems([{_,Key}|Keys], Table, Index, Acc) -> collect_elems(Keys, Table, Index, [ets:lookup_element(Table, Key, Index)|Acc]); collect_elems([], _, _, Acc) -> Acc. -spec do_add_vertex({vertex(), label()}, graph()) -> vertex(). do_add_vertex({V, _Label} = VL, G) -> ets:insert(G#digraph.vtab, VL), V. %% %% Collect either source or sink vertices. %% collect_vertices(G, Type) -> Vs = vertices(G), lists:foldl(fun(V, A) -> case ets:member(G#digraph.ntab, {Type, V}) of true -> A; false -> [V|A] end end, [], Vs). %% %% Delete vertices %% do_del_vertices([V | Vs], G) -> do_del_vertex(V, G), do_del_vertices(Vs, G); do_del_vertices([], #digraph{}) -> true. do_del_vertex(V, G) -> do_del_nedges(ets:lookup(G#digraph.ntab, {in, V}), G), do_del_nedges(ets:lookup(G#digraph.ntab, {out, V}), G), ets:delete(G#digraph.vtab, V). do_del_nedges([{_, E}|Ns], G) -> case ets:lookup(G#digraph.etab, E) of [{E, V1, V2, _}] -> do_del_edge(E, V1, V2, G), do_del_nedges(Ns, G); [] -> % cannot happen do_del_nedges(Ns, G) end; do_del_nedges([], #digraph{}) -> true. %% %% Delete edges %% do_del_edges([E|Es], G) -> case ets:lookup(G#digraph.etab, E) of [{E,V1,V2,_}] -> do_del_edge(E,V1,V2,G), do_del_edges(Es, G); [] -> do_del_edges(Es, G) end; do_del_edges([], #digraph{}) -> true. do_del_edge(E, V1, V2, G) -> ets:select_delete(G#digraph.ntab, [{{{in, V2}, E}, [], [true]}, {{{out,V1}, E}, [], [true]}]), ets:delete(G#digraph.etab, E). -spec rm_edges([vertex(),...], graph()) -> 'true'. rm_edges([V1, V2|Vs], G) -> rm_edge(V1, V2, G), rm_edges([V2|Vs], G); rm_edges(_, _) -> true. -spec rm_edge(vertex(), vertex(), graph()) -> 'ok'. rm_edge(V1, V2, G) -> Es = out_edges(G, V1), rm_edge_0(Es, V1, V2, G). rm_edge_0([E|Es], V1, V2, G) -> case ets:lookup(G#digraph.etab, E) of [{E, V1, V2, _}] -> do_del_edge(E, V1, V2, G), rm_edge_0(Es, V1, V2, G); _ -> rm_edge_0(Es, V1, V2, G) end; rm_edge_0([], _, _, #digraph{}) -> ok. %% %% Check that endpoints exist %% -spec do_add_edge({edge(), vertex(), vertex(), label()}, graph()) -> edge() | {'error', add_edge_err_rsn()}. do_add_edge({E, V1, V2, Label}, G) -> case ets:member(G#digraph.vtab, V1) of false -> {error, {bad_vertex, V1}}; true -> case ets:member(G#digraph.vtab, V2) of false -> {error, {bad_vertex, V2}}; true -> case other_edge_exists(G, E, V1, V2) of true -> {error, {bad_edge, [V1, V2]}}; false when G#digraph.cyclic =:= false -> acyclic_add_edge(E, V1, V2, Label, G); false -> do_insert_edge(E, V1, V2, Label, G) end end end. other_edge_exists(#digraph{etab = ET}, E, V1, V2) -> case ets:lookup(ET, E) of [{E, Vert1, Vert2, _}] when Vert1 =/= V1; Vert2 =/= V2 -> true; _ -> false end. -spec do_insert_edge(edge(), vertex(), vertex(), label(), graph()) -> edge(). do_insert_edge(E, V1, V2, Label, #digraph{ntab=NT, etab=ET}) -> ets:insert(NT, [{{out, V1}, E}, {{in, V2}, E}]), ets:insert(ET, {E, V1, V2, Label}), E. -spec acyclic_add_edge(edge(), vertex(), vertex(), label(), graph()) -> edge() | {'error', {'bad_edge', [vertex()]}}. acyclic_add_edge(_E, V1, V2, _L, _G) when V1 =:= V2 -> {error, {bad_edge, [V1, V2]}}; acyclic_add_edge(E, V1, V2, Label, G) -> case get_path(G, V2, V1) of false -> do_insert_edge(E, V1, V2, Label, G); Path -> {error, {bad_edge, Path}} end. %% %% Delete all paths from vertex V1 to vertex V2 %% -spec del_path(G, V1, V2) -> 'true' when G :: graph(), V1 :: vertex(), V2 :: vertex(). del_path(G, V1, V2) -> case get_path(G, V1, V2) of false -> true; Path -> rm_edges(Path, G), del_path(G, V1, V2) end. %% %% Find a cycle through V %% return the cycle as list of vertices [V ... V] %% if no cycle exists false is returned %% if only a cycle of length one exists it will be %% returned as [V] but only after longer cycles have %% been searched. %% -spec get_cycle(G, V) -> Vertices | 'false' when G :: graph(), V :: vertex(), Vertices :: [vertex(),...]. get_cycle(G, V) -> case one_path(out_neighbours(G, V), V, [], [V], [V], 2, G, 1) of false -> case lists:member(V, out_neighbours(G, V)) of true -> [V]; false -> false end; Vs -> Vs end. %% %% Find a path from V1 to V2 %% return the path as list of vertices [V1 ... V2] %% if no path exists false is returned %% -spec get_path(G, V1, V2) -> Vertices | 'false' when G :: graph(), V1 :: vertex(), V2 :: vertex(), Vertices :: [vertex(),...]. get_path(G, V1, V2) -> one_path(out_neighbours(G, V1), V2, [], [V1], [V1], 1, G, 1). %% %% prune_short_path (evaluate conditions on path) %% short : if path is too short %% ok : if path is ok %% prune_short_path(Counter, Min) when Counter < Min -> short; prune_short_path(_Counter, _Min) -> ok. one_path([W|Ws], W, Cont, Xs, Ps, Prune, G, Counter) -> case prune_short_path(Counter, Prune) of short -> one_path(Ws, W, Cont, Xs, Ps, Prune, G, Counter); ok -> lists:reverse([W|Ps]) end; one_path([V|Vs], W, Cont, Xs, Ps, Prune, G, Counter) -> case lists:member(V, Xs) of true -> one_path(Vs, W, Cont, Xs, Ps, Prune, G, Counter); false -> one_path(out_neighbours(G, V), W, [{Vs,Ps} | Cont], [V|Xs], [V|Ps], Prune, G, Counter+1) end; one_path([], W, [{Vs,Ps}|Cont], Xs, _, Prune, G, Counter) -> one_path(Vs, W, Cont, Xs, Ps, Prune, G, Counter-1); one_path([], _, [], _, _, _, _, _Counter) -> false. %% %% Like get_cycle/2, but a cycle of length one is preferred. %% -spec get_short_cycle(G, V) -> Vertices | 'false' when G :: graph(), V :: vertex(), Vertices :: [vertex(),...]. get_short_cycle(G, V) -> get_short_path(G, V, V). %% %% Like get_path/3, but using a breadth-first search makes it possible %% to find a short path. %% -spec get_short_path(G, V1, V2) -> Vertices | 'false' when G :: graph(), V1 :: vertex(), V2 :: vertex(), Vertices :: [vertex(),...]. get_short_path(G, V1, V2) -> T = new(), add_vertex(T, V1), Q = queue:new(), Q1 = queue_out_neighbours(V1, G, Q), L = spath(Q1, G, V2, T), delete(T), L. spath(Q, G, Sink, T) -> case queue:out(Q) of {{value, E}, Q1} -> {_E, V1, V2, _Label} = edge(G, E), if Sink =:= V2 -> follow_path(V1, T, [V2]); true -> case vertex(T, V2) of false -> add_vertex(T, V2), add_edge(T, V2, V1), NQ = queue_out_neighbours(V2, G, Q1), spath(NQ, G, Sink, T); _V -> spath(Q1, G, Sink, T) end end; {empty, _Q1} -> false end. follow_path(V, T, P) -> P1 = [V | P], case out_neighbours(T, V) of [N] -> follow_path(N, T, P1); [] -> P1 end. queue_out_neighbours(V, G, Q0) -> lists:foldl(fun(E, Q) -> queue:in(E, Q) end, Q0, out_edges(G, V)).