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/*  Part of SWI-Prolog

    Author:        R.A.O'Keefe, Vitor Santos Costa, Jan Wielemaker
    E-mail:        J.Wielemaker@cs.vu.nl
    WWW:           http://www.swi-prolog.org
    Copyright (C): 1984-2012, VU University Amsterdam

    This program is free software; you can redistribute it and/or
    modify it under the terms of the GNU General Public License
    as published by the Free Software Foundation; either version 2
    of the License, or (at your option) any later version.

    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.

    You should have received a copy of the GNU General Public
    License along with this library; if not, write to the Free Software
    Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA  02110-1301  USA

    As a special exception, if you link this library with other files,
    compiled with a Free Software compiler, to produce an executable, this
    library does not by itself cause the resulting executable to be covered
    by the GNU General Public License. This exception does not however
    invalidate any other reasons why the executable file might be covered by
    the GNU General Public License.

    The original code was distributed in the public domain and YAP
    under the Perl artistic license. The current version is dual
    licences and may be redistributed under the Artistic license,
    version 2.0.
*/



%   $Id$
%
%   File   : GRAPHS.PL
%   Author : R.A.O'Keefe
%   Updated: 20 March 1984
%   Purpose: Graph-processing utilities.

:- module(ugraphs,
	  [ add_edges/3,		% +Graph, +Edges, -NewGraph
	    add_vertices/3,		% +Graph, +Vertices, -NewGraph
	    complement/2,		% +Graph, -NewGraph
	    compose/3,			% +LeftGraph, +RightGraph, -NewGraph
	    del_edges/3,		% +Graph, +Edges, -NewGraph
	    del_vertices/3,		% +Graph, +Vertices, -NewGraph
	    edges/2,			% +Graph, -Edges
	    neighbors/3,		% +Vertex, +Graph, -Vertices
	    neighbours/3,		% +Vertex, +Graph, -Vertices
	    reachable/3,		% +Vertex, +Graph, -Vertices
	    top_sort/2,			% +Graph, -Sort
	    top_sort/3,			% +Graph, -Sort0, -Sort
	    transitive_closure/2,	% +Graph, -Closure
	    transpose/2,		% +Graph, -NewGraph
	    vertices/2,			% +Graph, -Vertices
	    vertices_edges_to_ugraph/3,	% +Vertices, +Edges, -Graph
	    ugraph_union/3		% +Graph1, +Graph2, -Graph
	  ]).

/** <module> Graph manipulation library

The S-representation of a graph is  a list of (vertex-neighbours) pairs,
where the pairs are in standard order   (as produced by keysort) and the
neighbours of each vertex are also  in   standard  order (as produced by
sort). This form is convenient for many calculations.

A   new   UGraph   from    raw    data     can    be    created    using
vertices_edges_to_ugraph/3.

Adapted to support some of  the   functionality  of  the SICStus ugraphs
library by Vitor Santos Costa.

Ported from YAP 5.0.1 to SWI-Prolog by Jan Wielemaker.

@author R.A.O'Keefe
@author Vitor Santos Costa
@author Jan Wielemaker
@license GPL+SWI-exception or Artistic 2.0
*/

:- use_module(library(lists), [
	append/3,
	member/2
   ]).

:- use_module(library(ordsets), [
	ord_add_element/3,
	ord_subtract/3,
	ord_union/3,
	ord_union/4
   ]).


/*

:- public
	p_to_s_graph/2,
	s_to_p_graph/2, % edges
	s_to_p_trans/2,
	p_member/3,
	s_member/3,
	p_transpose/2,
	s_transpose/2,
	compose/3,
	top_sort/2,
	vertices/2,
	warshall/2.

:- mode
	vertices(+, -),
	p_to_s_graph(+, -),
	    p_to_s_vertices(+, -),
	    p_to_s_group(+, +, -),
		p_to_s_group(+, +, -, -),
	s_to_p_graph(+, -),
	    s_to_p_graph(+, +, -, -),
	s_to_p_trans(+, -),
	    s_to_p_trans(+, +, -, -),
	p_member(?, ?, +),
	s_member(?, ?, +),
	p_transpose(+, -),
	s_transpose(+, -),
	    s_transpose(+, -, ?, -),
		transpose_s(+, +, +, -),
	compose(+, +, -),
	    compose(+, +, +, -),
		compose1(+, +, +, -),
		    compose1(+, +, +, +, +, +, +, -),
	top_sort(+, -),
	    vertices_and_zeros(+, -, ?),
	    count_edges(+, +, +, -),
		incr_list(+, +, +, -),
	    select_zeros(+, +, -),
	    top_sort(+, -, +, +, +),
		decr_list(+, +, +, -, +, -),
	warshall(+, -),
	    warshall(+, +, -),
		warshall(+, +, +, -).

*/


%%	vertices(+S_Graph, -Vertices) is det.
%
%	Strips off the  neighbours  lists   of  an  S-representation  to
%	produce  a  list  of  the  vertices  of  the  graph.  (It  is  a
%	characteristic of S-representations that *every* vertex appears,
%	even if it has no  neighbours.).   Vertices  is  in the standard
%	order of terms.

vertices([], []) :- !.
vertices([Vertex-_|Graph], [Vertex|Vertices]) :-
	vertices(Graph, Vertices).


%%	vertices_edges_to_ugraph(+Vertices, +Edges, -UGraph) is det.
%
%	Create a UGraph from Vertices and edges.   Given  a graph with a
%	set of Vertices and a set of   Edges,  Graph must unify with the
%	corresponding S-representation. Note that   the vertices without
%	edges will appear in Vertices but not  in Edges. Moreover, it is
%	sufficient for a vertice to appear in Edges.
%
%	==
%	?- vertices_edges_to_ugraph([],[1-3,2-4,4-5,1-5], L).
%	L = [1-[3,5], 2-[4], 3-[], 4-[5], 5-[]]
%	==
%
%	In this case all  vertices  are   defined  implicitly.  The next
%	example shows three unconnected vertices:
%
%	==
%	?- vertices_edges_to_ugraph([6,7,8],[1-3,2-4,4-5,1-5], L).
%	L = [1-[3,5], 2-[4], 3-[], 4-[5], 5-[], 6-[], 7-[], 8-[]]
%	==

vertices_edges_to_ugraph(Vertices, Edges, Graph) :-
	sort(Edges, EdgeSet),
	p_to_s_vertices(EdgeSet, IVertexBag),
	append(Vertices, IVertexBag, VertexBag),
	sort(VertexBag, VertexSet),
	p_to_s_group(VertexSet, EdgeSet, Graph).


add_vertices(Graph, Vertices, NewGraph) :-
	msort(Vertices, V1),
	add_vertices_to_s_graph(V1, Graph, NewGraph).

add_vertices_to_s_graph(L, [], NL) :- !,
	add_empty_vertices(L, NL).
add_vertices_to_s_graph([], L, L) :- !.
add_vertices_to_s_graph([V1|VL], [V-Edges|G], NGL) :-
	compare(Res, V1, V),
	add_vertices_to_s_graph(Res, V1, VL, V, Edges, G, NGL).

add_vertices_to_s_graph(=, _, VL, V, Edges, G, [V-Edges|NGL]) :-
	add_vertices_to_s_graph(VL, G, NGL).
add_vertices_to_s_graph(<, V1, VL, V, Edges, G, [V1-[]|NGL]) :-
	add_vertices_to_s_graph(VL, [V-Edges|G], NGL).
add_vertices_to_s_graph(>, V1, VL, V, Edges, G, [V-Edges|NGL]) :-
	add_vertices_to_s_graph([V1|VL], G, NGL).

add_empty_vertices([], []).
add_empty_vertices([V|G], [V-[]|NG]) :-
	add_empty_vertices(G, NG).

%%	del_vertices(+Graph, +Vertices, -NewGraph) is det.
%
%	Unify NewGraph with a new graph obtained by deleting the list of
%	Vertices and all the edges that start from  or go to a vertex in
%	Vertices to the Graph. Example:
%
%	==
%	?- del_vertices([1-[3,5],2-[4],3-[],4-[5],5-[],6-[],7-[2,6],8-[]],
%			[2,1],
%			NL).
%	NL = [3-[],4-[5],5-[],6-[],7-[6],8-[]]
%	==
%
%	@compat Upto 5.6.48 the argument order was (+Vertices, +Graph,
%	-NewGraph). Both YAP and SWI-Prolog have changed the argument
%	order for compatibility with recent SICStus as well as
%	consistency with del_edges/3.

del_vertices(Graph, Vertices, NewGraph) :-
	sort(Vertices, V1),		% JW: was msort
	(   V1 = []
	->  Graph = NewGraph
	;   del_vertices(Graph, V1, V1, NewGraph)
	).

del_vertices(G, [], V1, NG) :- !,
	del_remaining_edges_for_vertices(G, V1, NG).
del_vertices([], _, _, []).
del_vertices([V-Edges|G], [V0|Vs], V1, NG) :-
	compare(Res, V, V0),
	split_on_del_vertices(Res, V,Edges, [V0|Vs], NVs, V1, NG, NGr),
	del_vertices(G, NVs, V1, NGr).

del_remaining_edges_for_vertices([], _, []).
del_remaining_edges_for_vertices([V0-Edges|G], V1, [V0-NEdges|NG]) :-
	ord_subtract(Edges, V1, NEdges),
	del_remaining_edges_for_vertices(G, V1, NG).

split_on_del_vertices(<, V, Edges, Vs, Vs, V1, [V-NEdges|NG], NG) :-
	ord_subtract(Edges, V1, NEdges).
split_on_del_vertices(>, V, Edges, [_|Vs], Vs, V1, [V-NEdges|NG], NG) :-
	ord_subtract(Edges, V1, NEdges).
split_on_del_vertices(=, _, _, [_|Vs], Vs, _, NG, NG).

add_edges(Graph, Edges, NewGraph) :-
	p_to_s_graph(Edges, G1),
	ugraph_union(Graph, G1, NewGraph).

%%	ugraph_union(+Set1, +Set2, ?Union)
%
%	Is true when Union is the union of Set1 and Set2. This code is a
%	copy of set union

ugraph_union(Set1, [], Set1) :- !.
ugraph_union([], Set2, Set2) :- !.
ugraph_union([Head1-E1|Tail1], [Head2-E2|Tail2], Union) :-
	compare(Order, Head1, Head2),
	ugraph_union(Order, Head1-E1, Tail1, Head2-E2, Tail2, Union).

ugraph_union(=, Head-E1, Tail1, _-E2, Tail2, [Head-Es|Union]) :-
	ord_union(E1, E2, Es),
	ugraph_union(Tail1, Tail2, Union).
ugraph_union(<, Head1, Tail1, Head2, Tail2, [Head1|Union]) :-
	ugraph_union(Tail1, [Head2|Tail2], Union).
ugraph_union(>, Head1, Tail1, Head2, Tail2, [Head2|Union]) :-
	ugraph_union([Head1|Tail1], Tail2, Union).

del_edges(Graph, Edges, NewGraph) :-
	p_to_s_graph(Edges, G1),
	graph_subtract(Graph, G1, NewGraph).

%%	graph_subtract(+Set1, +Set2, ?Difference)
%
%	Is based on ord_subtract

graph_subtract(Set1, [], Set1) :- !.
graph_subtract([], _, []).
graph_subtract([Head1-E1|Tail1], [Head2-E2|Tail2], Difference) :-
	compare(Order, Head1, Head2),
	graph_subtract(Order, Head1-E1, Tail1, Head2-E2, Tail2, Difference).

graph_subtract(=, H-E1,     Tail1, _-E2,     Tail2, [H-E|Difference]) :-
	ord_subtract(E1,E2,E),
	graph_subtract(Tail1, Tail2, Difference).
graph_subtract(<, Head1, Tail1, Head2, Tail2, [Head1|Difference]) :-
	graph_subtract(Tail1, [Head2|Tail2], Difference).
graph_subtract(>, Head1, Tail1, _,     Tail2, Difference) :-
	graph_subtract([Head1|Tail1], Tail2, Difference).

%%	edges(+UGraph, -Edges) is det.
%
%	Edges is the set of edges in UGraph. Each edge is represented as
%	a pair From-To, where From and To are vertices in the graph.

edges(Graph, Edges) :-
	s_to_p_graph(Graph, Edges).

p_to_s_graph(P_Graph, S_Graph) :-
	sort(P_Graph, EdgeSet),
	p_to_s_vertices(EdgeSet, VertexBag),
	sort(VertexBag, VertexSet),
	p_to_s_group(VertexSet, EdgeSet, S_Graph).


p_to_s_vertices([], []).
p_to_s_vertices([A-Z|Edges], [A,Z|Vertices]) :-
	p_to_s_vertices(Edges, Vertices).


p_to_s_group([], _, []).
p_to_s_group([Vertex|Vertices], EdgeSet, [Vertex-Neibs|G]) :-
	p_to_s_group(EdgeSet, Vertex, Neibs, RestEdges),
	p_to_s_group(Vertices, RestEdges, G).


p_to_s_group([V1-X|Edges], V2, [X|Neibs], RestEdges) :- V1 == V2, !,
	p_to_s_group(Edges, V2, Neibs, RestEdges).
p_to_s_group(Edges, _, [], Edges).



s_to_p_graph([], []) :- !.
s_to_p_graph([Vertex-Neibs|G], P_Graph) :-
	s_to_p_graph(Neibs, Vertex, P_Graph, Rest_P_Graph),
	s_to_p_graph(G, Rest_P_Graph).


s_to_p_graph([], _, P_Graph, P_Graph) :- !.
s_to_p_graph([Neib|Neibs], Vertex, [Vertex-Neib|P], Rest_P) :-
	s_to_p_graph(Neibs, Vertex, P, Rest_P).


transitive_closure(Graph, Closure) :-
	warshall(Graph, Graph, Closure).

warshall([], Closure, Closure) :- !.
warshall([V-_|G], E, Closure) :-
	memberchk(V-Y, E),	%  Y := E(v)
	warshall(E, V, Y, NewE),
	warshall(G, NewE, Closure).


warshall([X-Neibs|G], V, Y, [X-NewNeibs|NewG]) :-
	memberchk(V, Neibs),
	!,
	ord_union(Neibs, Y, NewNeibs),
	warshall(G, V, Y, NewG).
warshall([X-Neibs|G], V, Y, [X-Neibs|NewG]) :- !,
	warshall(G, V, Y, NewG).
warshall([], _, _, []).

%%	transpose(Graph, NewGraph) is det.
%
%	Unify NewGraph with a new graph obtained from Graph by replacing
%	all edges of the form V1-V2 by edges of the form V2-V1. The cost
%	is O(|V|*log(|V|)). Notice that an undirected   graph is its own
%	transpose. Example:
%
%	  ==
%	  ?- transpose([1-[3,5],2-[4],3-[],4-[5],
%	                5-[],6-[],7-[],8-[]], NL).
%	  NL = [1-[],2-[],3-[1],4-[2],5-[1,4],6-[],7-[],8-[]]
%	  ==

transpose(Graph, NewGraph) :-
	edges(Graph, Edges),
	vertices(Graph, Vertices),
	flip_edges(Edges, TransposedEdges),
	vertices_edges_to_ugraph(Vertices, TransposedEdges, NewGraph).

flip_edges([], []).
flip_edges([Key-Val|Pairs], [Val-Key|Flipped]) :-
	flip_edges(Pairs, Flipped).


%%	compose(G1, G2, Composition)
%
%	Calculates the composition of two S-form  graphs, which need not
%	have the same set of vertices.

compose(G1, G2, Composition) :-
	vertices(G1, V1),
	vertices(G2, V2),
	ord_union(V1, V2, V),
	compose(V, G1, G2, Composition).


compose([], _, _, []) :- !.
compose([Vertex|Vertices], [Vertex-Neibs|G1], G2,
	[Vertex-Comp|Composition]) :- !,
	compose1(Neibs, G2, [], Comp),
	compose(Vertices, G1, G2, Composition).
compose([Vertex|Vertices], G1, G2, [Vertex-[]|Composition]) :-
	compose(Vertices, G1, G2, Composition).


compose1([V1|Vs1], [V2-N2|G2], SoFar, Comp) :-
	compare(Rel, V1, V2), !,
	compose1(Rel, V1, Vs1, V2, N2, G2, SoFar, Comp).
compose1(_, _, Comp, Comp).


compose1(<, _, Vs1, V2, N2, G2, SoFar, Comp) :- !,
	compose1(Vs1, [V2-N2|G2], SoFar, Comp).
compose1(>, V1, Vs1, _, _, G2, SoFar, Comp) :- !,
	compose1([V1|Vs1], G2, SoFar, Comp).
compose1(=, V1, Vs1, V1, N2, G2, SoFar, Comp) :-
	ord_union(N2, SoFar, Next),
	compose1(Vs1, G2, Next, Comp).

%%	top_sort(+Graph, -Sorted) is semidet.
%%	top_sort(+Graph, -Sorted, ?Tail) is semidet.
%
%	Sorted is a  topological  sorted  list   of  nodes  in  Graph. A
%	toplogical sort is possible  if  the   graph  is  connected  and
%	acyclic. In the example we show   how  topological sorting works
%	for a linear graph:
%
%	==
%	?- top_sort([1-[2], 2-[3], 3-[]], L).
%	L = [1, 2, 3]
%	==
%
%	The  predicate  top_sort/3  is  a  difference  list  version  of
%	top_sort/2.

top_sort(Graph, Sorted) :-
	vertices_and_zeros(Graph, Vertices, Counts0),
	count_edges(Graph, Vertices, Counts0, Counts1),
	select_zeros(Counts1, Vertices, Zeros),
	top_sort(Zeros, Sorted, Graph, Vertices, Counts1).

top_sort(Graph, Sorted0, Sorted) :-
	vertices_and_zeros(Graph, Vertices, Counts0),
	count_edges(Graph, Vertices, Counts0, Counts1),
	select_zeros(Counts1, Vertices, Zeros),
	top_sort(Zeros, Sorted, Sorted0, Graph, Vertices, Counts1).


vertices_and_zeros([], [], []) :- !.
vertices_and_zeros([Vertex-_|Graph], [Vertex|Vertices], [0|Zeros]) :-
	vertices_and_zeros(Graph, Vertices, Zeros).


count_edges([], _, Counts, Counts) :- !.
count_edges([_-Neibs|Graph], Vertices, Counts0, Counts2) :-
	incr_list(Neibs, Vertices, Counts0, Counts1),
	count_edges(Graph, Vertices, Counts1, Counts2).


incr_list([], _, Counts, Counts) :- !.
incr_list([V1|Neibs], [V2|Vertices], [M|Counts0], [N|Counts1]) :-
	V1 == V2, !,
	N is M+1,
	incr_list(Neibs, Vertices, Counts0, Counts1).
incr_list(Neibs, [_|Vertices], [N|Counts0], [N|Counts1]) :-
	incr_list(Neibs, Vertices, Counts0, Counts1).


select_zeros([], [], []) :- !.
select_zeros([0|Counts], [Vertex|Vertices], [Vertex|Zeros]) :- !,
	select_zeros(Counts, Vertices, Zeros).
select_zeros([_|Counts], [_|Vertices], Zeros) :-
	select_zeros(Counts, Vertices, Zeros).



top_sort([], [], Graph, _, Counts) :- !,
	vertices_and_zeros(Graph, _, Counts).
top_sort([Zero|Zeros], [Zero|Sorted], Graph, Vertices, Counts1) :-
	graph_memberchk(Zero-Neibs, Graph),
	decr_list(Neibs, Vertices, Counts1, Counts2, Zeros, NewZeros),
	top_sort(NewZeros, Sorted, Graph, Vertices, Counts2).

top_sort([], Sorted0, Sorted0, Graph, _, Counts) :- !,
	vertices_and_zeros(Graph, _, Counts).
top_sort([Zero|Zeros], [Zero|Sorted], Sorted0, Graph, Vertices, Counts1) :-
	graph_memberchk(Zero-Neibs, Graph),
	decr_list(Neibs, Vertices, Counts1, Counts2, Zeros, NewZeros),
	top_sort(NewZeros, Sorted, Sorted0, Graph, Vertices, Counts2).

graph_memberchk(Element1-Edges, [Element2-Edges2|_]) :-
	Element1 == Element2, !,
	Edges = Edges2.
graph_memberchk(Element, [_|Rest]) :-
        graph_memberchk(Element, Rest).


decr_list([], _, Counts, Counts, Zeros, Zeros) :- !.
decr_list([V1|Neibs], [V2|Vertices], [1|Counts1], [0|Counts2], Zi, Zo) :-
	V1 == V2, !,
	decr_list(Neibs, Vertices, Counts1, Counts2, [V2|Zi], Zo).
decr_list([V1|Neibs], [V2|Vertices], [N|Counts1], [M|Counts2], Zi, Zo) :-
	V1 == V2, !,
	M is N-1,
	decr_list(Neibs, Vertices, Counts1, Counts2, Zi, Zo).
decr_list(Neibs, [_|Vertices], [N|Counts1], [N|Counts2], Zi, Zo) :-
	decr_list(Neibs, Vertices, Counts1, Counts2, Zi, Zo).


%%	neighbors(+Vertex, +Graph, -Neigbours) is det.
%%	neighbours(+Vertex, +Graph, -Neigbours) is det.
%
%	Neigbours is a sorted list of the neighbours of Vertex in Graph.

neighbors(Vertex, Graph, Neig) :-
	neighbours(Vertex, Graph, Neig).

neighbours(V,[V0-Neig|_],Neig) :-
	V == V0, !.
neighbours(V,[_|G],Neig) :-
	neighbours(V,G,Neig).


%
% Simple two-step algorithm. You could be smarter, I suppose.
%
complement(G, NG) :-
	vertices(G,Vs),
	complement(G,Vs,NG).

complement([], _, []).
complement([V-Ns|G], Vs, [V-INs|NG]) :-
	ord_add_element(Ns,V,Ns1),
	ord_subtract(Vs,Ns1,INs),
	complement(G, Vs, NG).



reachable(N, G, Rs) :-
	reachable([N], G, [N], Rs).

reachable([], _, Rs, Rs).
reachable([N|Ns], G, Rs0, RsF) :-
	neighbours(N, G, Nei),
	ord_union(Rs0, Nei, Rs1, D),
	append(Ns, D, Nsi),
	reachable(Nsi, G, Rs1, RsF).